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Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus
Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus Marjolly B. Caruso, Monique R.O. Trugilho, Andr´e S. Teixeira-Ferreira, Jonas Perales, Andrea T. Da Poian, Russolina B. Zingali PII: DOI: Reference:
S1874-3919(16)30307-4 doi: 10.1016/j.jprot.2016.07.011 JPROT 2624
To appear in:
Journal of Proteomics
Received date: Revised date: Accepted date:
25 January 2016 27 June 2016 13 July 2016
Please cite this article as: Caruso Marjolly B., Trugilho Monique R.O., Teixeira-Ferreira Andr´e S., Perales Jonas, Da Poian Andrea T., Zingali Russolina B., Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus, Journal of Proteomics (2016), doi: 10.1016/j.jprot.2016.07.011
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ACCEPTED MANUSCRIPT Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus.
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Marjolly B. Carusoa, b, Monique R.O. Trugilhoa, c, d, Luiza M. Higaa, b, ¤, André S. TeixeiraFerreiraa, c, Jonas Peralesa, c, Andrea T. Da Poiana, b, and Russolina B. Zingalia, b, * a
Rede Proteômica do Rio de Janeiro, Brazil Programa de Biologia Estrutural, Instituto de Bioquímica Médica Leopoldo de Meis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ 21941-902, Brazil c Laboratório de Toxinologia, Departamento de Fisiologia e Farmacodinâmica, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, RJ 21045-900, Brazil
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b
d
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Current address: Centro de Desenvolvimento Tecnológico em Saúde (CDTS), Fundação Oswaldo Cruz, Rio de Janeiro, RJ 21045-900, Brazil ¤ Current address: Laboratório de Virologia Molecular, Departamento de Genética, Instituto de Biologia, Universidade Federal do Rio de Janeiro
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* Corresponding author at: Unidade de Espectrometria de Massas e Proteômica (UEMP), Instituto de Bioquímica Médica Leopoldo de Meis, Universidade Federal do Rio de Janeiro - UFRJ, Rio de Janeiro, Brazil. Tel/Fax.: +55 21 39386782. E-mail addresses: [email protected] (R.B. Zingali)
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ABSTRACT
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Secretome analysis can be described as a subset of proteomics studies consisting in the analysis of the molecules secreted by cells or tissues. Dengue virus (DENV)
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infection can lead to a broad spectrum of clinical manifestations, with the severe forms of the disease characterized by hemostasis abnormalities and liver injury. The hepatocytes are a relevant site of viral replication and a major source of plasma proteins. Until now, we had limited information on the small molecules secreted by hepatic cells after infection by DENV. In the present study, we analysed a fraction of the secretome of mock- and DENV-infected hepatic cells (HepG2 cells) containing molecules with less than 10 kDa, using different proteomic approaches. We identified 175 proteins, with 57 detected only in the samples from mock-infected cells, 59 only in samples from DENV-infected cells, and 59 in both conditions. Most of the peptides identified were derived from proteins larger than 10 kDa, suggesting a proteolytic processing of the secreted molecules. Using in silico analysis, we predicted consistent differences between the proteolytic processing occurring in mock and DENV-infected
ACCEPTED MANUSCRIPT samples, raising, for the first time, the hypothesis that differential proteolysis of secreted
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molecules would be involved in the pathogenesis of dengue.
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Key words: dengue virus, hepatic cells, proteome, low molecular mass proteins,
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prediction of proteolytic enzymes, secretome.
Biological Significance
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Since the liver, one of the targets of DENV infection, is responsible for producing molecules involved in distinct biological processes, the identification of proteins and
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peptides secreted by hepatocytes after infection would help to a better understanding of the physiopathology of dengue. Proteomic analyses of molecules with less than 10 kDa secreted by HepG2 cells after infection with DENV revealed differential proteolytic
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processing as an effect of DENV infection.
1. Introduction
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Following the genomic revolution, proteomics rose as a promising approach to give a much wider comprehension of an unlimited number of biological phenomena [1].
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However, as time went by in the early 2000s, proteomics began to be used mostly for hypothesis-free exploratory studies, making many proteomic studies to become reports of lists of proteins expressed in a cell, tissue or organism without introducing the novelty that has been expected [2]. But even in this scenario, with the hypothesis-driven studies generating results of much higher impact, sometimes the exploratory studies reveal completely unexpected findings. This is the case of the work described here. In a previous work, we used an exploratory proteomic approach to analyze the proteins secreted by hepatic cells infected with dengue virus (DENV) [3]. Dengue is endemic in over 100 countries and is considered the most important arthropod-borne disease nowadays, with almost 4 billion people living at risk areas for infection [4-6]. Brazil is one of the most affected countries in Latin America, reporting more than 1,500,000 cases in 2015 with almost 900 deaths [7]. Although the majority of dengue
ACCEPTED MANUSCRIPT cases are asymptomatic, infection may cause a severe life-threatening disease, characterized by several hemostatic disorders [8-13]. Since the liver produces most of the plasmatic proteins, including the coagulation factors and several inflammatory
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cytokines involved in the control of vascular permeability, the evaluation of the panel of
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proteins and peptides secreted by the hepatocytes is of great interest. Additionally, the liver is recognized as a major site of DENV replication [14-17].
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Analyzing the secretome fraction of DENV-infected hepatocytes containing the proteins with molecular masses higher than 10 kDa, we observed the presence of
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several differentially secreted proteins, such as peptidyl-prolyl isomerases A and B, tissue inhibitor of metalloproteinases 1 and 2 and superoxide dismutase, macrophage
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inhibitory factor migration and α-enolase, all of them are potentially involved in the dengue pathogenesis [3]. This study also revealed a surprising finding: the presence of α-enolase, a classic cytoplasmic glycolytic enzyme, among the most abundant secreted
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proteins by infected cells. This finding allowed us to show enolase as a molecule with unconventional secretion pathway that, being a plasminogen activator when secreted,
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may contribute to hemostatic disorders observed in dengue pathogenesis [18].
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Considering that approximately 50% of all human proteins have molecular masses lower than 26.5 kDa [19] or are small proteins or peptides produced by proteolytic processing of larger proteins [20], in the present study we investigated the small
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molecules (< 10 kDa) present on the secretome of hepatic cells after DENV infection. Again, the findings were surprising. Instead of identifying biologically active peptides that could be involved in the disease progression, the results revealed the presence of several fragments from proteins with known high molecular masses. This unexpected observation led us to formulate a new hypothesis: the occurrence of changes in the proteolytic processing of the secreted molecules. More interestingly, in silico analyses revealed that while in mock-infected sample a higher number of peptides result from cleavage by an enzyme similar to thermolysin, in DENV-infected samples we found a higher number of peptides cleaved by an enzyme similar to chymotrypsin and a decrease in the number of peptides resulted from the cleavage by an enzyme similar to trypsin, which could be explained by the presence of serine protease inhibitors, such as neuroserpin and inter-alpha trypsin inhibitor, only observed in the sample from DENV-
ACCEPTED MANUSCRIPT infected cells. The results altogether suggest a differential proteolytic processing during DENV
infection
in hepatocytes,
which may have
a direct
correlation
with
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pathophysiological alterations that occurring in dengue.
2. Materials and methods
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2.1 Separation steps to obtain the low molecular mass samples HepG2 cells were grown in DMEM (Invitrogen Corporation, USA) supplemented
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with 10% fetal bovine serum (FBS). DENV serotype 2 (strain 16681) was propagated in the Aedes albopitcus C6/36 cell line (DENV MOI = 0.1 – 9dpi) [21]. HepG2 cells were
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mock-infected or infected with DENV at MOI 1. After 32 h, cells were extensively washed with PBS and incubated for further 16 h with serum-free DMEM (Invitrogen Corporation, USA). At 48 h post-infection, the conditioned medium containing secreted
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proteins was collected as described elsewhere [3]. In order to ensure that the experimental conditions used to prepare the samples did not cause cell death and
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disruption, MTT, Trypan Blue and LDH assays were performed [3]. Viability assays (MTT and Trypan Blue exclusion) showed less than 3% death cells, both for infected
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and mock-infected cells. Additionally, absence of cell disruption was confirmed by the negligible LDH activity in the conditioned media (1.35% and 1.23% of the total LDH
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activity, for mock-infected and infected cells, respectively). Four independent experiments were conducted to obtain suitable biological replicates (n = 4) for each condition. The conditioned media of the cells were concentrated and fractioned using a 10 kDa cutoff membrane [3]. The fractions containing proteins with molecular masses below 10 kDa were called ultrafiltrate (UF), as shown in figure 1. The UF from mock (M) and DENV-infected (DENV) cells were concentrated by lyophilization and submitted to a desalting step using a Sep-Pak Vac C18 cartridge (Water Corporation Sep-Pak – 1 cc/100 mg), according to the manufacturer’s recommendations, prior to analysis by MS.
2.2 Analysis of the digested molecules from the ultrafiltrate secretome of infected hepatic cells
ACCEPTED MANUSCRIPT 2.2.1 Separation and concentration of the ultrafiltrate samples prior to distinct enzymatic treatments The UF from the M and DENV conditions were filtered as describes in the item
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separation steps (2.1) and concentrated using an Amicon® Ultra-4 Centrifugal Filter Unit (3 kDa), according to the manufacturer´s instructions (Merck Millipore). This step was necessary in order to remove contaminants observed in the standardization stage
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that interfered on the ionization steps of mass spectrometry analysis (data not shown). The samples above 3 kDa were quantified by a bicinchoninic acid assay [22] using BSA
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(Sigma) as a standard. Aliquots containing 10 µg of proteins from each condition were treated with 1 M urea and 10 mM DTT at 56C for 1 hour and 55 mM iodoacetamide at
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room temperature for 45 minutes. At the end of the carbamidomethylation step, each aliquot was submitted to a distinct enzymatic treatment, where the endoproteinases were prepared to a final concentration of 1 µg/µl: trypsin (1 µg), or Lys-C (0.5 µg), or
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trypsin (1 µg) followed by Lys-C (0.5 µg) overnight at 37C. The reactions were
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terminated upon the addition of 0.1% formic acid.
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2.2.2 Mass spectrometry analysis using an Orbitrap Velos The peptides obtained after the enzymatic treatments were desalted and
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solubilized in 20 µl of 0.1% formic acid, and 4 µl of the 5x diluted samples were loaded on a C18 trap column (20 mm x 100 μm, 200 Å, Magic, AQ matrix, 5 µm – Michrom Bioresources, USA), followed by the separation of the samples in a C18 column (100 mm x 75 μm, 200 Å, Magic, AQ matrix, 5 µm - Michrom Bioresources, USA) onto an EASY-nLC-II System (Thermo Scientific, USA) coupled to an Orbitrap Velos. The samples were eluted (0.2 μL/min) using a linear gradient (0 to 60%) of 100% acetonitrile containing 0.1% formic acid for 58 min. The nESI voltage was set at 1.9 kV without the influence of any gas, and the source temperature was 200 °C. The instrument control and data acquisition for the MS and MS/MS were conducted using Xcalibur software (2.0.7 version). The data acquisition was performed using alternating MS for an Orbitrap with a resolution of 60,000 (FWHM @ m/z 400) and using MS2 for a linear trap. A maximum of 10 ions was selected for MS fragmentation using CID. The fragmentation
ACCEPTED MANUSCRIPT had normalized collision energy of 35, and only precursors with a charge state of 2 were selected for MS/MS acquisitions using the CID mode. Precursors with a charge state of
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1 and/or an intensity lower than 10.000 were excluded.
2.3 Analysis of the intact molecules from the ultrafiltrated secretome of infected
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hepatic cells 2.3.1 Desalting step in POROS R2
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The UF (50 µg) from the M and DENV conditions were completely dried using a speed vacuum concentrator system (Thermo Scientific Savant SDP111V) and
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solubilized in 1% trifluoroacetic acid. These samples were subjected to a desalting step using an in-house made column using POROS R2 C8-C18 resin (Applied Biosystems) at 10 mg/ml. The columns were packaged in 10 µl tips (Axygen) using pieces of C8 disc
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(3M Empore) as blockades. The activation solution used was 100% acetonitrile (10 µl), and the equilibration solution was 1% trifluoroacetic acid (two aliquots of 10 µl). The
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elution was performed using sequential solutions, where the first solution contained 20 µl of 0.1% trifluoroacetic acid /70% acetonitrile and the last solution contained 20 µl of
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100% acetonitrile. The eluted molecules were completely dried by a speed vacuum
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concentrator system prior to a strong cationic exchange separation step.
2.3.2 Strong cationic exchange separation The dried samples were solubilized in 100 µl of a solution containing 5 mM KH2PO4/ 25% acetonitrile (pH 3), and the molecules were fractionated using strong cationic exchange Ultra-Micro SpinColumns (Harvard Apparatus). The columns were hydrated in the same solution and centrifuged at 110 g for 2 min. The elution was performed using 150 µl of KCl at increasing concentrations (75, 150 and 300 mM) followed by a centrifugation step at 110 g for 2 min. The eluted fractions were dried by a speed vacuum concentrator system and submitted to a new desalination step using POROS R2 columns. Then, the samples were subjected to mass spectrometry analysis by an LTQ Orbitrap XL.
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2.3.3 Mass spectrometry analysis using the LTQ Orbitrap XL
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The intact samples were desalted and loaded onto an EASY-nLC-II System as
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previously described for the Orbitrap Velos, but in this case coupled to LTQ Orbitrap XL. The nESI voltage was set to 1.9 kV without the influence of any gas, and the source temperature was 200 °C. The instrument control and data acquisition for the MS and
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MS/MS were conducted using Xcalibur software (2.0.7 version). The data acquisition was performed using alternating MS for an Orbitrap with a resolution of 60,000 (FWHM
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@ m/z 400) and using MS2 for a linear trap. A maximum of 10 ions was selected for MS fragmentation using collision-induced dissociation (CID), and a maximum of 3 ions with
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a higher intensity was fragmented using electron transfer dissociation (ETD). Both fragmentations had normalized collision energy of 35. Only precursors with a charge
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state of 2 were selected for MS/MS acquisitions using the CID mode, and only precursors with charge states of 3, 4 and 5 were selected for MS/MS acquisitions in the ETD mode. Precursors with a charge state of 1 and/or an intensity lower than 10.000
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were excluded.
2.4 Computational analysis
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2.4.1 Protein identification and quantification The spectra obtained from the Orbitrap Velos (experimental duplicates) and from LTQ Orbitrap XL analyses (experimental duplicates) were compared with the theoretical spectra using the “PatternLab for Proteomics” software v 3.2 [23] for protein identification. All mass spectrometry data generated for this study is made available at http://max.ioc.fiocruz.br/mtrugilho/CarusoMB2016/. Peptide sequence matching (PSM) was performed using the Comet algorithm [24] against the protein-centric human, from Homo sapiens database (NeXtProt - 20,126 proteins entries) with proteins entries downloaded on January 2015 plus a FASTA file containing Dengue virus dengue virus database (Uniprot - GeneBank taxon number 14). A target-reverse decoy strategy was employed. The search parameters used for the UF samples prior distinct enzymatic
ACCEPTED MANUSCRIPT treatments were as follows: digestion with the endoproteinases trypsin and LysC, spectra fixed modification of cysteine carbamidomethylation and as a variable
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modification the oxidation of methionine. Alternatively, for the analysis of the UF intact
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molecules, the search parameters were: no enzyme, spectra fixed modification of cysteine carbamidomethylation and as a variable modification the oxidation of methionine. The Comet search engine considered a precursor mass tolerance of 10
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ppm for MS spectra and 500 ppm for MS/MS. All identification results are reported with the maximum parsimony principle [25], which is the minimal number of proteins or
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peptides that can be explained when the same peptide sequence is shared by all identified peptides, and less than 1% FDR, both peptide and protein level, by
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PatternLab’s Search Engine Processor (SEPro) module. Spectral counting (SC) for estimation of protein copy number was accomplished using the normalized spectral
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abundance factor (NSAF) [26]. Differentially abundant molecules were pinpointed using PatternLab’s TFold module with a Benjamini–Hochberg q-value of 0.05 [27]. Proteins
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uniquely identified in one condition (mock or DENV-infected HepG2 cells) were
module.
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pinpointed according to PatternLabs Approximate Area Proportional Venn Diagram
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2.4.2 Prediction analysis of proteolytic process Since the results showed the presence of proteolytic fragments of proteins with a molecular mass higher than 10 kDa, we decided to evaluate intrinsic proteolysis in the samples. In order to predict possible differences in the cleavage sites of the molecules present in the ultrafiltrates, we conducted an in silico analysis using the PeptideCutterExPASy program. The program predicts possible sites of cleavage after a simulation of digestion with different types of enzymes. We use the FASTA sequences from the proteins mapped of the identified peptides on intact sample. The sequences of the peptides obtained from the analysis and the FASTA sequence of the equivalent protein were manually compared. The N-terminal sites where the sequence of intact peptides
ACCEPTED MANUSCRIPT and the FASTA sequence for each protein were aligned were manually compared and
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grouped according to the type of enzyme that would be able to act on that site.
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3. Results and discussion
The pathophysiological alterations that occur during severe dengue cases seem
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to involve directly or indirectly vascular, hemostatic and hepatic disturbances. Several reports have described hepatic cells as one of the sites for virus replication during
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dengue infection [28-30]. Since the liver is responsible for the synthesis of numerous molecules, such as plasma proteins and coagulation factors, as cited earlier, the study of the proteins secreted by hepatic cells is important to better understand dengue
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pathogenesis. Previously, our group performed a study of the secretome of DENVinfected HepG2 cells with a focus on the molecules with masses higher than 10 kDa [3].
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However, until now we had limited information on the small molecules secreted during infection, which would contain biologically active peptides involved in disease
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progression. Therefore, we decide to analyze the fraction containing molecules with less than 10 kDa present in that secretome, which we named as ultrafiltrate (UF), as
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depicted in the diagram shown in Figure 1. To confirm the presence of only small molecules in our samples, we initially performed a MS analysis (data not shown), which
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indicates that the majority of molecules from mock-infected and DENV-infected samples have molecular masses below the cutoff used in the separation step, with the exception of one protein with a molecular mass of approximately 24.7 kDa, found in both samples. This initial analysis also revealed similar populations of ions in both samples (data not shown), but no natural peptide was identified. One important limitation of the analysis of intact molecules by mass spectrometry is the difficulty in equally ionizing all the molecules contained in the mixture for further identification. Therefore, the identification of the molecules present in the UF fraction was performed using two complementary mass spectrometry approaches known as bottom-up and top-down analyses. To ensure that the majority of the polypeptides contained in the UFs were identified, we characterized these molecules after enzymatic digestion, the bottom-up
ACCEPTED MANUSCRIPT strategy. Several studies have reported that the diversification of enzymatic treatments improves the amount and diversity of peptides obtained and identified [31]. Therefore, these UFs were subjected to three distinct enzymatic treatments with the
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endoproteinases trypsin, Lys-C and Lys-C followed by trypsin. The peptides generated
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from each digestion were analyzed by LTQ mass spectrometer using an EASY-nLC-II System (Thermo Scientific, USA) coupled to an Orbitrap Velos. The results obtained
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reinforced the relevance of enzymatic diversification since some molecules only had their sequences identified after a specific enzymatic treatment. The number of
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molecules identified after each enzymatic treatment is shown as a Venn diagram for the samples from mock-infected (Figure 2A) and DENV-infected (Figure 2B) cells. The
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combined result of all enzymatic treatments allowed the identification of 135 proteins. Of these molecules, 39 were detected only in the mock condition, 58 only in the DENVinfected condition, and 38 were identified in both conditions (Figure 3A).
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To complement the information regarding the complexity of the polypeptides present in the UFs, we conducted a complementary study of the samples using the top-
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down mass spectrometry strategy. In this approach, the molecules were directly analyzed by mass spectrometry without previous digestion. Before the analysis, the
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intact samples were desalinated, and the eluted fraction was applied to a nESI LTQ Orbitrap XL mass spectrometer (Thermo Scientific, USA). Since the intact molecules
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have intrinsic charge, are larger than peptides produced by enzymatic digestion, and have some limitations regarding the ionization process, we use two complementary fragmentation methodologies, CID (selecting precursors with charge state of +2) and ETD (selecting precursors with multiples charge state such as +3, +4 and +5). This analysis resulted in the identification of 53 molecules. Among them, 18 were detected only in the mock condition, 8 in the DENV-infected condition and 26 were common to both conditions (Figure 3B). By combining all the data obtained by the top-down and bottom-up strategies, we were able to identify a total of 175 proteins, with 57 molecules detected in the mockinfected condition, 59 in the DENV-infected condition and 59 observed in both conditions (Figure 3C). Also, a label free quantification analysis based on the spectral counting (SC) was used to estimate the protein copy number in the PatternLabs
ACCEPTED MANUSCRIPT software. The results were plotted as an Approximate Area Proportional Venn Diagrams in Figure 3 revealing that only 12 molecules were differentially expressed between the studied conditions (considering a q-value of 0.05 using PatternLab’s TFold module with
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a Benjamini–Hochberg). Among these molecules, 4 were observed after enzymatic
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treatment analyses and 8 in the intact samples (Table S2a and S2b). It is interesting to mention that among the 175 identified polypeptides, 33 were only detected during the
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analysis of intact molecules on LTQ Orbitrap XL mass spectrometer. Twelve of them were detected only in the mock condition, 5 only in the DENV-infected condition and 16
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were common to both samples. These data reinforce the relevance of applying complementary strategies to obtain a more complete panel of information about the
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molecules present in the UFs of the studied conditions. A compilation of all the identified molecules, disregarding the strategy adopted, can be found in the Supplementary Data (Table S1b).
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According to the literature, the most challenging event in the study of the secretome is avoiding the action of proteases on secreted proteins because of the
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difficulty in distinguishing natural peptides from those originating from protein degradation as a result of artifactual proteolysis [32]. Most natural bioactive peptides
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present in body fluids are found at reduced concentrations; thus, fragments originating from more abundant proteins would hamper the identification of these natural peptides
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[33-34]. Therefore, the use of protease inhibitors is imperative to lessen the unspecific proteolytic action and to allow the identification of real natural peptides. However, the characterization of the molecules present on the UF showed that even after adding protease inhibitors during sample preparation, the majority of polypeptides (49 out of 52 molecules) found in the intact samples had theoretical molecular masses higher than 10 kDa. Surprisingly, instead of active peptides, the results revealed the presence of several fragments from proteins with known high molecular masses. This unexpected observation led us to formulate the hypothesis of proteolytic processing upon the secreted molecules. As mentioned before, previous data obtained from MS analysis (data not shown) revealed the presence of only one protein with molecular mass higher than 10 kDa in the samples, therefore suggesting that most of the peptides identified correspond to
ACCEPTED MANUSCRIPT fragments of proteolytically processed proteins. Importantly, UF analyses also revealed that some of the peptides derived from proteins with theoretical masses higher than 10 kDa were present in only one of the conditions studied (mock-infected or DENV-
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infected), even though those proteins were observed in both conditions in the sample
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containing proteins above 10 kDa [3], as represented in Figure 4, suggesting a differential proteolysis between infected and uninfected cells during secretion
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processes. Another evidence that differential proteolysis occur is demonstrated in Figure 5, which shows that distinct peptides from fibrinogen were detected in samples
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from mock-infected or DENV-infected cells.
Taken together, the observation of peptides originated from secreted proteins
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with high molecular mass, some of them identified in the previous analysis of the secretome [3], the identification of proteases and proteases inhibitors differentially secreted by DENV-infected cells throughout the same study, and the presence of
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fragments from proteins described as inserted in the membrane of extracellular vesicles [35] in this study, support the hypothesis of the differential proteolytic processing during
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DENV infection. However, it is important to mention that since the viability tests revealed negligible values for cell death and/or lysis, the presence of these molecules in
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the extracellular medium would be a result of either a differential extracellular proteolysis or an intracellular proteolysis followed by secretion of the resulting peptides
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by unconventional mechanisms. Thus, in order to verify whether the identified polypeptides were classified as secreted molecules, we compared our data with those obtained in other secretome studies [3, 36-45], and also searched for their subcellular location using the Uniprot database. These analyses revealed that 62% of the molecules identified in our study were classified as secreted. While the remaining molecules were described as present in the membrane of extracellular vesicles (11%) [32] or as intracellular proteins (components of intracellular organelles as well as cytosolic or nuclear proteins – 27%). This data confirms that most of identified peptides came from secreted proteins. To predict differences in the cleavage site by distinct proteases in the intact samples, we conducted an analysis using the PeptideCutter program considering the sequences exclusive to each condition. This analysis predicts possible sites of
ACCEPTED MANUSCRIPT cleavages after simulation of the digestion process using different types of enzymes, and allowed us to find out differences between the samples (Figure 6). In the mockinfected condition, we noticed a higher chance of protein cleavage by enzymes with
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actions similar to thermolysin (which cleaves between aliphatic amino acids with
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hydrophobic side chain, such as isoleucine, leucine, valine and alanine) and trypsin (which cleaves between basic amino acids, such as arginine and lysine). Conversely, in
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the DENV-infected condition, the peptides presented a higher chance to have been cleaved by enzymes with actions similar to chymotrypsin (which cleaved between
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aromatic amino acids with hydrophobic side chains, such as tyrosine, and phenylalanine - with high specificity -, or leucine, methionine and histidine – with low specificity). This
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variation would occur due to differential proteolytic processing, explaining the differences among the sequences and the number of peptides obtained from the mockinfected condition (37 exclusive sequences) and the DENV-infected condition (23
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exclusive sequences). It is worth mentioning that the action of more than one enzyme upon the same protein could generate very small peptides, which would explain the
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reduced number of identifications, since the length of the sequence can hinder the reliability to identify these molecules.
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Protein degradation may be triggered by different stimuli, such as oxidative stress, aging, pathogens and alterations in environment conditions [46-48]. It is possible
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that the DENV infection promotes alterations in cellular proteolytic processes modifying the activity or the expression of some enzymes and/or inhibitors. In our earlier work, we detected different molecules potentially involved in proteolytic processes, such as proteasome alpha-4, cathepsins (D, L and X), PCSK9 and TIMP-1 both in mock and infected conditions; carboxypeptidase A3, LON peptidase (N-terminal and ring finger 3) and serine protease (Htra isoform 1) only in mock condition; and serine (or cysteine) proteinase inhibitor clade I (neuroserpin) member 1 and TIMP-2 only in DENV-infected condition [3]. Furthermore, we observed that the concentration of TIMP-1 (a metalloproteinase inhibitor) was lower in the secretome of DENV-infected cells compared to that of mock-infected cells [3]. In the present work, we identified other proteases and protease inhibitors, such as inter-alpha-trypsin inhibitor (heavy chain H2)
ACCEPTED MANUSCRIPT and ADAM10 only in mock condition; and TFPI, neurotrypsin and trypsin only in DENVinfected condition. Inter-alpha trypsin inhibitor is a serine protease inhibitor; the peptide identified in
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the UF is located in its propeptide region [49-50] (Figure 7a). The sequence identified in ADAM10, the disintegrin and metalloproteinase domain-containing protein 10, is located in the extracellular region of the protein [51-52] (Figure 7b). TFPI (tissue factor pathway
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inhibitor) is a protease inhibitor formed by three domains (K1, K2 and K3), where K1 and K2 inhibit the complex coagulator factor VIIa-tissue factor and coagulator factor Xa,
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respectively, preventing the extrinsic pathway activation in the coagulation process, and K3 domain, from which the peptide identified belongs, had no protease inhibition
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function [53] (Figure 7c). Neurotrypsin is a serine protease and the sequence identified is located in the zymogen activation region [54] (Figure 7d). Finally, a peptide from human trypsin was also identified. However, it was not possible to determine from which
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protein species of trypsin it came from since it is a conservative sequence [55]. The fact that all these proteases and protease inhibitors have theoretical molecular masses
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higher than 10 kDa, but were only identified in the UF, indicates that these molecules underwent a proteolytic processing where only the peptides generated after this event
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were identified. This processing would hinder the original function of these molecules or help the conversion of zymogens to the active form, leading to changes in the panel of
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peptides produced by the cell. An explanation for the absence of detection of these molecules in our previous study could be related to the lower sensitivity of the experimental procedures used, which would have underestimated the amount and variety of the identified proteases and protease inhibitors. Although data collected during this work allowed us to observe a proteolytic processing upon molecules presented in the secretome, complementary studies are necessary for a better understanding of the pathophysiological relevance of this phenomenon. It is noteworthy that the identification of these proteases and protease inhibitors complements our previous work, and taken together, the results of both studies indicate alterations in the variety and amount of these molecules. For instance, among the molecules only identified in the mock intact samples, we found a peptide originated from proSAAS, also known as proprotein convertase subtilisin/kexin type 1
ACCEPTED MANUSCRIPT inhibitor. This peptide corresponds to the KEP segment that is normally generated during processing of proSAAS by protein convertases 1/3 (PC1/3) and PC2 followed by carboxypeptidase E [56] (Figure 8), indicating that these proteases were active in mock-
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infected cells but not in the DENV-infected cells.
Through the analysis using the PeptideCutter program, we observed in the mockinfected sample a higher number of peptides probably resulting from cleavage by an
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enzyme similar to thermolysin (Figure 6), which acts between aliphatic amino acids with hydrophobic side chain. When we analyzed the proteases only present in the secretome
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from mock-infected cells, we found two enzymes, LON peptidase and Htra [3], both described in other organisms as acting at hydrophobic residues [57-58]. Conversely, in
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the DENV-infected sample, we observed a reduction on the number of peptides resulted from the cleavage by an enzyme similar to trypsin (Figure 6). This phenomenon could be explained by the presence of serine protease inhibitors, such as neuroserpin and
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inter-alpha trypsin inhibitor, only observed in the sample from DENV-infected cells. We could also hypothesize the existence of a chymase-like enzyme in the secretome of the
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DENV-infected cells, since we noticed a higher number of peptides cleaved by an enzyme similar to chymotrypsin (cleaves of aromatic amino acids with hydrophobic
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lateral chains) [59]. Consequently, the infection would modulate the action of certain enzymes on secreted proteins, leading to different proteolytic processing and the
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generation of a peptide panel distinct from the non-infected condition.
4. Conclusion The compilation of the results obtained in this study, including mass spectrometry analyses combined with in silico studies for prediction of cleavage sites for proteolytic activity, together with the results from our previous secretome study [3] allowed us to identify alterations in the proteolytic processing of the secreted proteins. This could be explained by infection-induced differences in the expression of proteases or protease inhibitors, as well as the activation of different enzyme families triggered by specific stimuli or by differential regulation of their inhibitors.
ACCEPTED MANUSCRIPT Conflict of interest statement
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The authors declare that they have no conflicts of interest.
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Acknowledgements
This work was supported by Fundação Carlos Chagas Filho de Amparo à Pesquisa do
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Estado do Rio de Janeiro (FAPERJ 103.163/2011, FAPERJ E-26/110.092/2013, FAPERJ E-26/201.167/2014), Conselho Nacional de Desenvolvimento Científico e
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Tecnológico (MCT/CNPq 476448/2008-5, (MCT/CNPq 550114/2010-6 and MCT/CNPq 306669/2013-7) and Plataformas Tecnologicas, Fiocruz. MBC was a recipient of a
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Ph.D. fellowship from CAPES and MROT was a recipient of a post-doctoral fellowship from CAPES/Faperj. The authors thanks the professor Igor C. Almeida, from Department of Biological Sciences, Border Biomedical Research Center, University of
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Texas at El Paso, and the PhD Paulo C. Carvalho, from Laboratory for Proteomics and Protein Engineering, Carlos Chagas Institute, Fiocruz, Paraná, for the fruitful
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discussions and help, and also the designer Pedro Bigler, from Centro de Desenvolvimento Tecnológico em Saúde (CDTS), for preparing high resolution figures
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References
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for publication, and for creating the graphical abstract.
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Figure legends
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Figure 1: A schematic overview of the strategies and methodologies applied to perform the mass spectrometry analysis of the samples obtained from the ultrafiltrate of the mock-infected and DENVinfected conditions.
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Figure 2: The Venn diagrams constructed from the molecules identified in the mock-infected condition (A) and DENV-infected condition (B) after distinct enzymatic treatments (applying the bottom-up strategy) using the EASY-nLC-II System (Thermo Scientific, USA) coupled to Orbitrap Velos mass spectrometers. Endoproteinases: Lys-C, Tryp (trypsin) and Lys-C+Tryp (digestion by Lys-C followed by trypsin). The raw data was run using Comet program against the Uniprot (dengue virus) and NextProt (Homo sapiens) databases. Figure 3: The Venn diagrams constructed after molecule identification. The molecules only found in the mock infected condition (M) are shown in blue. The molecules only found in the DENV-infected condition (DENV) are shown in red, and the shadowed area represents the molecules common to both conditions. (A) The bottom-up strategy, (B) the top-down strategy and (C) a compilation of the molecules identified by both strategies using mass spectrometers (nESI LTQ Orbitrap XL and Orbitrap Velos). The raw data was run using Comet program against the Uniprot (dengue virus) and NextProt (Homo sapiens) databases. Figure 4: Molecules identified in both conditions during the secretome [3] analysis but only in one condition during the ultrafiltrate analysis. Figure 5: Alignment of sequences on Uniprot tool. Identified sequences on carboxy-terminal region from human fibrinogen (P02671-2 = Isoform 2 of Fibrinogen alpha chain, residues 601 to 644) among the conditions, indicating differential proteolysis. Sequences presents only in DENV-infected condition (red), mock-infected condition (blue), and common to both conditions (black). Figure 6: The analysis of the exclusive sequences presents in the mock-infected condition (blue) and the DENV-infected condition (red) by the PeptideCutter program. The tool was used to predict possible sites of cleavage after in silico digestion. All enzymes were considered in the analysis.
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Figure 8: Schematic diagram of the proSAAS processing with emphasis in the generation of a proSAASderived peptide (KEP molecule). The region that corresponds to the localization of the identified peptide is highlighted in red.
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ACCEPTED MANUSCRIPT Biological Significance Since the liver, one of the targets of DENV infection, is responsible for producing molecules involved in distinct biological processes, the identification of proteins and
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peptides secreted by hepatocytes after infection would help to a better understanding of the physiopathology of dengue. Proteomic analyses of molecules with less than 10 kDa secreted by HepG2 cells after infection with DENV revealed differential proteolytic
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processing as an effect of DENV infection.
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Graphical abstract
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Small molecules from the secretome of DENV-infected HepG2 cells were identified. Bottom-up
and
top-down
approaches allowed
on
protein
Differential proteolytic processing of the secreted molecules due to infection was
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observed.
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identification
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S1874-3919(16)30307-4 doi: 10.1016/j.jprot.2016.07.011 JPROT 2624
To appear in:
Journal of Proteomics
Received date: Revised date: Accepted date:
25 January 2016 27 June 2016 13 July 2016
Please cite this article as: Caruso Marjolly B., Trugilho Monique R.O., Teixeira-Ferreira Andr´e S., Perales Jonas, Da Poian Andrea T., Zingali Russolina B., Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus, Journal of Proteomics (2016), doi: 10.1016/j.jprot.2016.07.011
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ACCEPTED MANUSCRIPT Proteomic analysis of the secretome of HepG2 cells indicates differential proteolytic processing after infection with dengue virus.
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Marjolly B. Carusoa, b, Monique R.O. Trugilhoa, c, d, Luiza M. Higaa, b, ¤, André S. TeixeiraFerreiraa, c, Jonas Peralesa, c, Andrea T. Da Poiana, b, and Russolina B. Zingalia, b, * a
Rede Proteômica do Rio de Janeiro, Brazil Programa de Biologia Estrutural, Instituto de Bioquímica Médica Leopoldo de Meis, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ 21941-902, Brazil c Laboratório de Toxinologia, Departamento de Fisiologia e Farmacodinâmica, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, RJ 21045-900, Brazil
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b
d
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Current address: Centro de Desenvolvimento Tecnológico em Saúde (CDTS), Fundação Oswaldo Cruz, Rio de Janeiro, RJ 21045-900, Brazil ¤ Current address: Laboratório de Virologia Molecular, Departamento de Genética, Instituto de Biologia, Universidade Federal do Rio de Janeiro
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* Corresponding author at: Unidade de Espectrometria de Massas e Proteômica (UEMP), Instituto de Bioquímica Médica Leopoldo de Meis, Universidade Federal do Rio de Janeiro - UFRJ, Rio de Janeiro, Brazil. Tel/Fax.: +55 21 39386782. E-mail addresses: [email protected] (R.B. Zingali)
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ABSTRACT
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Secretome analysis can be described as a subset of proteomics studies consisting in the analysis of the molecules secreted by cells or tissues. Dengue virus (DENV)
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infection can lead to a broad spectrum of clinical manifestations, with the severe forms of the disease characterized by hemostasis abnormalities and liver injury. The hepatocytes are a relevant site of viral replication and a major source of plasma proteins. Until now, we had limited information on the small molecules secreted by hepatic cells after infection by DENV. In the present study, we analysed a fraction of the secretome of mock- and DENV-infected hepatic cells (HepG2 cells) containing molecules with less than 10 kDa, using different proteomic approaches. We identified 175 proteins, with 57 detected only in the samples from mock-infected cells, 59 only in samples from DENV-infected cells, and 59 in both conditions. Most of the peptides identified were derived from proteins larger than 10 kDa, suggesting a proteolytic processing of the secreted molecules. Using in silico analysis, we predicted consistent differences between the proteolytic processing occurring in mock and DENV-infected
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molecules would be involved in the pathogenesis of dengue.
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Key words: dengue virus, hepatic cells, proteome, low molecular mass proteins,
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prediction of proteolytic enzymes, secretome.
Biological Significance
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Since the liver, one of the targets of DENV infection, is responsible for producing molecules involved in distinct biological processes, the identification of proteins and
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peptides secreted by hepatocytes after infection would help to a better understanding of the physiopathology of dengue. Proteomic analyses of molecules with less than 10 kDa secreted by HepG2 cells after infection with DENV revealed differential proteolytic
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processing as an effect of DENV infection.
1. Introduction
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Following the genomic revolution, proteomics rose as a promising approach to give a much wider comprehension of an unlimited number of biological phenomena [1].
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However, as time went by in the early 2000s, proteomics began to be used mostly for hypothesis-free exploratory studies, making many proteomic studies to become reports of lists of proteins expressed in a cell, tissue or organism without introducing the novelty that has been expected [2]. But even in this scenario, with the hypothesis-driven studies generating results of much higher impact, sometimes the exploratory studies reveal completely unexpected findings. This is the case of the work described here. In a previous work, we used an exploratory proteomic approach to analyze the proteins secreted by hepatic cells infected with dengue virus (DENV) [3]. Dengue is endemic in over 100 countries and is considered the most important arthropod-borne disease nowadays, with almost 4 billion people living at risk areas for infection [4-6]. Brazil is one of the most affected countries in Latin America, reporting more than 1,500,000 cases in 2015 with almost 900 deaths [7]. Although the majority of dengue
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cytokines involved in the control of vascular permeability, the evaluation of the panel of
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proteins and peptides secreted by the hepatocytes is of great interest. Additionally, the liver is recognized as a major site of DENV replication [14-17].
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Analyzing the secretome fraction of DENV-infected hepatocytes containing the proteins with molecular masses higher than 10 kDa, we observed the presence of
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several differentially secreted proteins, such as peptidyl-prolyl isomerases A and B, tissue inhibitor of metalloproteinases 1 and 2 and superoxide dismutase, macrophage
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inhibitory factor migration and α-enolase, all of them are potentially involved in the dengue pathogenesis [3]. This study also revealed a surprising finding: the presence of α-enolase, a classic cytoplasmic glycolytic enzyme, among the most abundant secreted
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proteins by infected cells. This finding allowed us to show enolase as a molecule with unconventional secretion pathway that, being a plasminogen activator when secreted,
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may contribute to hemostatic disorders observed in dengue pathogenesis [18].
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Considering that approximately 50% of all human proteins have molecular masses lower than 26.5 kDa [19] or are small proteins or peptides produced by proteolytic processing of larger proteins [20], in the present study we investigated the small
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molecules (< 10 kDa) present on the secretome of hepatic cells after DENV infection. Again, the findings were surprising. Instead of identifying biologically active peptides that could be involved in the disease progression, the results revealed the presence of several fragments from proteins with known high molecular masses. This unexpected observation led us to formulate a new hypothesis: the occurrence of changes in the proteolytic processing of the secreted molecules. More interestingly, in silico analyses revealed that while in mock-infected sample a higher number of peptides result from cleavage by an enzyme similar to thermolysin, in DENV-infected samples we found a higher number of peptides cleaved by an enzyme similar to chymotrypsin and a decrease in the number of peptides resulted from the cleavage by an enzyme similar to trypsin, which could be explained by the presence of serine protease inhibitors, such as neuroserpin and inter-alpha trypsin inhibitor, only observed in the sample from DENV-
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pathophysiological alterations that occurring in dengue.
2. Materials and methods
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2.1 Separation steps to obtain the low molecular mass samples HepG2 cells were grown in DMEM (Invitrogen Corporation, USA) supplemented
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with 10% fetal bovine serum (FBS). DENV serotype 2 (strain 16681) was propagated in the Aedes albopitcus C6/36 cell line (DENV MOI = 0.1 – 9dpi) [21]. HepG2 cells were
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mock-infected or infected with DENV at MOI 1. After 32 h, cells were extensively washed with PBS and incubated for further 16 h with serum-free DMEM (Invitrogen Corporation, USA). At 48 h post-infection, the conditioned medium containing secreted
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proteins was collected as described elsewhere [3]. In order to ensure that the experimental conditions used to prepare the samples did not cause cell death and
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disruption, MTT, Trypan Blue and LDH assays were performed [3]. Viability assays (MTT and Trypan Blue exclusion) showed less than 3% death cells, both for infected
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and mock-infected cells. Additionally, absence of cell disruption was confirmed by the negligible LDH activity in the conditioned media (1.35% and 1.23% of the total LDH
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activity, for mock-infected and infected cells, respectively). Four independent experiments were conducted to obtain suitable biological replicates (n = 4) for each condition. The conditioned media of the cells were concentrated and fractioned using a 10 kDa cutoff membrane [3]. The fractions containing proteins with molecular masses below 10 kDa were called ultrafiltrate (UF), as shown in figure 1. The UF from mock (M) and DENV-infected (DENV) cells were concentrated by lyophilization and submitted to a desalting step using a Sep-Pak Vac C18 cartridge (Water Corporation Sep-Pak – 1 cc/100 mg), according to the manufacturer’s recommendations, prior to analysis by MS.
2.2 Analysis of the digested molecules from the ultrafiltrate secretome of infected hepatic cells
ACCEPTED MANUSCRIPT 2.2.1 Separation and concentration of the ultrafiltrate samples prior to distinct enzymatic treatments The UF from the M and DENV conditions were filtered as describes in the item
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separation steps (2.1) and concentrated using an Amicon® Ultra-4 Centrifugal Filter Unit (3 kDa), according to the manufacturer´s instructions (Merck Millipore). This step was necessary in order to remove contaminants observed in the standardization stage
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that interfered on the ionization steps of mass spectrometry analysis (data not shown). The samples above 3 kDa were quantified by a bicinchoninic acid assay [22] using BSA
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(Sigma) as a standard. Aliquots containing 10 µg of proteins from each condition were treated with 1 M urea and 10 mM DTT at 56C for 1 hour and 55 mM iodoacetamide at
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room temperature for 45 minutes. At the end of the carbamidomethylation step, each aliquot was submitted to a distinct enzymatic treatment, where the endoproteinases were prepared to a final concentration of 1 µg/µl: trypsin (1 µg), or Lys-C (0.5 µg), or
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trypsin (1 µg) followed by Lys-C (0.5 µg) overnight at 37C. The reactions were
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terminated upon the addition of 0.1% formic acid.
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2.2.2 Mass spectrometry analysis using an Orbitrap Velos The peptides obtained after the enzymatic treatments were desalted and
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solubilized in 20 µl of 0.1% formic acid, and 4 µl of the 5x diluted samples were loaded on a C18 trap column (20 mm x 100 μm, 200 Å, Magic, AQ matrix, 5 µm – Michrom Bioresources, USA), followed by the separation of the samples in a C18 column (100 mm x 75 μm, 200 Å, Magic, AQ matrix, 5 µm - Michrom Bioresources, USA) onto an EASY-nLC-II System (Thermo Scientific, USA) coupled to an Orbitrap Velos. The samples were eluted (0.2 μL/min) using a linear gradient (0 to 60%) of 100% acetonitrile containing 0.1% formic acid for 58 min. The nESI voltage was set at 1.9 kV without the influence of any gas, and the source temperature was 200 °C. The instrument control and data acquisition for the MS and MS/MS were conducted using Xcalibur software (2.0.7 version). The data acquisition was performed using alternating MS for an Orbitrap with a resolution of 60,000 (FWHM @ m/z 400) and using MS2 for a linear trap. A maximum of 10 ions was selected for MS fragmentation using CID. The fragmentation
ACCEPTED MANUSCRIPT had normalized collision energy of 35, and only precursors with a charge state of 2 were selected for MS/MS acquisitions using the CID mode. Precursors with a charge state of
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1 and/or an intensity lower than 10.000 were excluded.
2.3 Analysis of the intact molecules from the ultrafiltrated secretome of infected
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hepatic cells 2.3.1 Desalting step in POROS R2
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The UF (50 µg) from the M and DENV conditions were completely dried using a speed vacuum concentrator system (Thermo Scientific Savant SDP111V) and
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solubilized in 1% trifluoroacetic acid. These samples were subjected to a desalting step using an in-house made column using POROS R2 C8-C18 resin (Applied Biosystems) at 10 mg/ml. The columns were packaged in 10 µl tips (Axygen) using pieces of C8 disc
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(3M Empore) as blockades. The activation solution used was 100% acetonitrile (10 µl), and the equilibration solution was 1% trifluoroacetic acid (two aliquots of 10 µl). The
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elution was performed using sequential solutions, where the first solution contained 20 µl of 0.1% trifluoroacetic acid /70% acetonitrile and the last solution contained 20 µl of
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100% acetonitrile. The eluted molecules were completely dried by a speed vacuum
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concentrator system prior to a strong cationic exchange separation step.
2.3.2 Strong cationic exchange separation The dried samples were solubilized in 100 µl of a solution containing 5 mM KH2PO4/ 25% acetonitrile (pH 3), and the molecules were fractionated using strong cationic exchange Ultra-Micro SpinColumns (Harvard Apparatus). The columns were hydrated in the same solution and centrifuged at 110 g for 2 min. The elution was performed using 150 µl of KCl at increasing concentrations (75, 150 and 300 mM) followed by a centrifugation step at 110 g for 2 min. The eluted fractions were dried by a speed vacuum concentrator system and submitted to a new desalination step using POROS R2 columns. Then, the samples were subjected to mass spectrometry analysis by an LTQ Orbitrap XL.
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2.3.3 Mass spectrometry analysis using the LTQ Orbitrap XL
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The intact samples were desalted and loaded onto an EASY-nLC-II System as
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previously described for the Orbitrap Velos, but in this case coupled to LTQ Orbitrap XL. The nESI voltage was set to 1.9 kV without the influence of any gas, and the source temperature was 200 °C. The instrument control and data acquisition for the MS and
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MS/MS were conducted using Xcalibur software (2.0.7 version). The data acquisition was performed using alternating MS for an Orbitrap with a resolution of 60,000 (FWHM
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@ m/z 400) and using MS2 for a linear trap. A maximum of 10 ions was selected for MS fragmentation using collision-induced dissociation (CID), and a maximum of 3 ions with
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a higher intensity was fragmented using electron transfer dissociation (ETD). Both fragmentations had normalized collision energy of 35. Only precursors with a charge
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state of 2 were selected for MS/MS acquisitions using the CID mode, and only precursors with charge states of 3, 4 and 5 were selected for MS/MS acquisitions in the ETD mode. Precursors with a charge state of 1 and/or an intensity lower than 10.000
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were excluded.
2.4 Computational analysis
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2.4.1 Protein identification and quantification The spectra obtained from the Orbitrap Velos (experimental duplicates) and from LTQ Orbitrap XL analyses (experimental duplicates) were compared with the theoretical spectra using the “PatternLab for Proteomics” software v 3.2 [23] for protein identification. All mass spectrometry data generated for this study is made available at http://max.ioc.fiocruz.br/mtrugilho/CarusoMB2016/. Peptide sequence matching (PSM) was performed using the Comet algorithm [24] against the protein-centric human, from Homo sapiens database (NeXtProt - 20,126 proteins entries) with proteins entries downloaded on January 2015 plus a FASTA file containing Dengue virus dengue virus database (Uniprot - GeneBank taxon number 14). A target-reverse decoy strategy was employed. The search parameters used for the UF samples prior distinct enzymatic
ACCEPTED MANUSCRIPT treatments were as follows: digestion with the endoproteinases trypsin and LysC, spectra fixed modification of cysteine carbamidomethylation and as a variable
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modification the oxidation of methionine. Alternatively, for the analysis of the UF intact
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molecules, the search parameters were: no enzyme, spectra fixed modification of cysteine carbamidomethylation and as a variable modification the oxidation of methionine. The Comet search engine considered a precursor mass tolerance of 10
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ppm for MS spectra and 500 ppm for MS/MS. All identification results are reported with the maximum parsimony principle [25], which is the minimal number of proteins or
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peptides that can be explained when the same peptide sequence is shared by all identified peptides, and less than 1% FDR, both peptide and protein level, by
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PatternLab’s Search Engine Processor (SEPro) module. Spectral counting (SC) for estimation of protein copy number was accomplished using the normalized spectral
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abundance factor (NSAF) [26]. Differentially abundant molecules were pinpointed using PatternLab’s TFold module with a Benjamini–Hochberg q-value of 0.05 [27]. Proteins
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uniquely identified in one condition (mock or DENV-infected HepG2 cells) were
module.
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pinpointed according to PatternLabs Approximate Area Proportional Venn Diagram
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2.4.2 Prediction analysis of proteolytic process Since the results showed the presence of proteolytic fragments of proteins with a molecular mass higher than 10 kDa, we decided to evaluate intrinsic proteolysis in the samples. In order to predict possible differences in the cleavage sites of the molecules present in the ultrafiltrates, we conducted an in silico analysis using the PeptideCutterExPASy program. The program predicts possible sites of cleavage after a simulation of digestion with different types of enzymes. We use the FASTA sequences from the proteins mapped of the identified peptides on intact sample. The sequences of the peptides obtained from the analysis and the FASTA sequence of the equivalent protein were manually compared. The N-terminal sites where the sequence of intact peptides
ACCEPTED MANUSCRIPT and the FASTA sequence for each protein were aligned were manually compared and
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grouped according to the type of enzyme that would be able to act on that site.
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3. Results and discussion
The pathophysiological alterations that occur during severe dengue cases seem
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to involve directly or indirectly vascular, hemostatic and hepatic disturbances. Several reports have described hepatic cells as one of the sites for virus replication during
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dengue infection [28-30]. Since the liver is responsible for the synthesis of numerous molecules, such as plasma proteins and coagulation factors, as cited earlier, the study of the proteins secreted by hepatic cells is important to better understand dengue
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pathogenesis. Previously, our group performed a study of the secretome of DENVinfected HepG2 cells with a focus on the molecules with masses higher than 10 kDa [3].
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However, until now we had limited information on the small molecules secreted during infection, which would contain biologically active peptides involved in disease
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progression. Therefore, we decide to analyze the fraction containing molecules with less than 10 kDa present in that secretome, which we named as ultrafiltrate (UF), as
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depicted in the diagram shown in Figure 1. To confirm the presence of only small molecules in our samples, we initially performed a MS analysis (data not shown), which
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indicates that the majority of molecules from mock-infected and DENV-infected samples have molecular masses below the cutoff used in the separation step, with the exception of one protein with a molecular mass of approximately 24.7 kDa, found in both samples. This initial analysis also revealed similar populations of ions in both samples (data not shown), but no natural peptide was identified. One important limitation of the analysis of intact molecules by mass spectrometry is the difficulty in equally ionizing all the molecules contained in the mixture for further identification. Therefore, the identification of the molecules present in the UF fraction was performed using two complementary mass spectrometry approaches known as bottom-up and top-down analyses. To ensure that the majority of the polypeptides contained in the UFs were identified, we characterized these molecules after enzymatic digestion, the bottom-up
ACCEPTED MANUSCRIPT strategy. Several studies have reported that the diversification of enzymatic treatments improves the amount and diversity of peptides obtained and identified [31]. Therefore, these UFs were subjected to three distinct enzymatic treatments with the
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endoproteinases trypsin, Lys-C and Lys-C followed by trypsin. The peptides generated
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from each digestion were analyzed by LTQ mass spectrometer using an EASY-nLC-II System (Thermo Scientific, USA) coupled to an Orbitrap Velos. The results obtained
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reinforced the relevance of enzymatic diversification since some molecules only had their sequences identified after a specific enzymatic treatment. The number of
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molecules identified after each enzymatic treatment is shown as a Venn diagram for the samples from mock-infected (Figure 2A) and DENV-infected (Figure 2B) cells. The
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combined result of all enzymatic treatments allowed the identification of 135 proteins. Of these molecules, 39 were detected only in the mock condition, 58 only in the DENVinfected condition, and 38 were identified in both conditions (Figure 3A).
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To complement the information regarding the complexity of the polypeptides present in the UFs, we conducted a complementary study of the samples using the top-
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down mass spectrometry strategy. In this approach, the molecules were directly analyzed by mass spectrometry without previous digestion. Before the analysis, the
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intact samples were desalinated, and the eluted fraction was applied to a nESI LTQ Orbitrap XL mass spectrometer (Thermo Scientific, USA). Since the intact molecules
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have intrinsic charge, are larger than peptides produced by enzymatic digestion, and have some limitations regarding the ionization process, we use two complementary fragmentation methodologies, CID (selecting precursors with charge state of +2) and ETD (selecting precursors with multiples charge state such as +3, +4 and +5). This analysis resulted in the identification of 53 molecules. Among them, 18 were detected only in the mock condition, 8 in the DENV-infected condition and 26 were common to both conditions (Figure 3B). By combining all the data obtained by the top-down and bottom-up strategies, we were able to identify a total of 175 proteins, with 57 molecules detected in the mockinfected condition, 59 in the DENV-infected condition and 59 observed in both conditions (Figure 3C). Also, a label free quantification analysis based on the spectral counting (SC) was used to estimate the protein copy number in the PatternLabs
ACCEPTED MANUSCRIPT software. The results were plotted as an Approximate Area Proportional Venn Diagrams in Figure 3 revealing that only 12 molecules were differentially expressed between the studied conditions (considering a q-value of 0.05 using PatternLab’s TFold module with
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a Benjamini–Hochberg). Among these molecules, 4 were observed after enzymatic
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treatment analyses and 8 in the intact samples (Table S2a and S2b). It is interesting to mention that among the 175 identified polypeptides, 33 were only detected during the
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analysis of intact molecules on LTQ Orbitrap XL mass spectrometer. Twelve of them were detected only in the mock condition, 5 only in the DENV-infected condition and 16
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were common to both samples. These data reinforce the relevance of applying complementary strategies to obtain a more complete panel of information about the
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molecules present in the UFs of the studied conditions. A compilation of all the identified molecules, disregarding the strategy adopted, can be found in the Supplementary Data (Table S1b).
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According to the literature, the most challenging event in the study of the secretome is avoiding the action of proteases on secreted proteins because of the
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difficulty in distinguishing natural peptides from those originating from protein degradation as a result of artifactual proteolysis [32]. Most natural bioactive peptides
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present in body fluids are found at reduced concentrations; thus, fragments originating from more abundant proteins would hamper the identification of these natural peptides
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[33-34]. Therefore, the use of protease inhibitors is imperative to lessen the unspecific proteolytic action and to allow the identification of real natural peptides. However, the characterization of the molecules present on the UF showed that even after adding protease inhibitors during sample preparation, the majority of polypeptides (49 out of 52 molecules) found in the intact samples had theoretical molecular masses higher than 10 kDa. Surprisingly, instead of active peptides, the results revealed the presence of several fragments from proteins with known high molecular masses. This unexpected observation led us to formulate the hypothesis of proteolytic processing upon the secreted molecules. As mentioned before, previous data obtained from MS analysis (data not shown) revealed the presence of only one protein with molecular mass higher than 10 kDa in the samples, therefore suggesting that most of the peptides identified correspond to
ACCEPTED MANUSCRIPT fragments of proteolytically processed proteins. Importantly, UF analyses also revealed that some of the peptides derived from proteins with theoretical masses higher than 10 kDa were present in only one of the conditions studied (mock-infected or DENV-
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infected), even though those proteins were observed in both conditions in the sample
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containing proteins above 10 kDa [3], as represented in Figure 4, suggesting a differential proteolysis between infected and uninfected cells during secretion
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processes. Another evidence that differential proteolysis occur is demonstrated in Figure 5, which shows that distinct peptides from fibrinogen were detected in samples
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from mock-infected or DENV-infected cells.
Taken together, the observation of peptides originated from secreted proteins
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with high molecular mass, some of them identified in the previous analysis of the secretome [3], the identification of proteases and proteases inhibitors differentially secreted by DENV-infected cells throughout the same study, and the presence of
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fragments from proteins described as inserted in the membrane of extracellular vesicles [35] in this study, support the hypothesis of the differential proteolytic processing during
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DENV infection. However, it is important to mention that since the viability tests revealed negligible values for cell death and/or lysis, the presence of these molecules in
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the extracellular medium would be a result of either a differential extracellular proteolysis or an intracellular proteolysis followed by secretion of the resulting peptides
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by unconventional mechanisms. Thus, in order to verify whether the identified polypeptides were classified as secreted molecules, we compared our data with those obtained in other secretome studies [3, 36-45], and also searched for their subcellular location using the Uniprot database. These analyses revealed that 62% of the molecules identified in our study were classified as secreted. While the remaining molecules were described as present in the membrane of extracellular vesicles (11%) [32] or as intracellular proteins (components of intracellular organelles as well as cytosolic or nuclear proteins – 27%). This data confirms that most of identified peptides came from secreted proteins. To predict differences in the cleavage site by distinct proteases in the intact samples, we conducted an analysis using the PeptideCutter program considering the sequences exclusive to each condition. This analysis predicts possible sites of
ACCEPTED MANUSCRIPT cleavages after simulation of the digestion process using different types of enzymes, and allowed us to find out differences between the samples (Figure 6). In the mockinfected condition, we noticed a higher chance of protein cleavage by enzymes with
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actions similar to thermolysin (which cleaves between aliphatic amino acids with
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hydrophobic side chain, such as isoleucine, leucine, valine and alanine) and trypsin (which cleaves between basic amino acids, such as arginine and lysine). Conversely, in
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the DENV-infected condition, the peptides presented a higher chance to have been cleaved by enzymes with actions similar to chymotrypsin (which cleaved between
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aromatic amino acids with hydrophobic side chains, such as tyrosine, and phenylalanine - with high specificity -, or leucine, methionine and histidine – with low specificity). This
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variation would occur due to differential proteolytic processing, explaining the differences among the sequences and the number of peptides obtained from the mockinfected condition (37 exclusive sequences) and the DENV-infected condition (23
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exclusive sequences). It is worth mentioning that the action of more than one enzyme upon the same protein could generate very small peptides, which would explain the
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reduced number of identifications, since the length of the sequence can hinder the reliability to identify these molecules.
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Protein degradation may be triggered by different stimuli, such as oxidative stress, aging, pathogens and alterations in environment conditions [46-48]. It is possible
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that the DENV infection promotes alterations in cellular proteolytic processes modifying the activity or the expression of some enzymes and/or inhibitors. In our earlier work, we detected different molecules potentially involved in proteolytic processes, such as proteasome alpha-4, cathepsins (D, L and X), PCSK9 and TIMP-1 both in mock and infected conditions; carboxypeptidase A3, LON peptidase (N-terminal and ring finger 3) and serine protease (Htra isoform 1) only in mock condition; and serine (or cysteine) proteinase inhibitor clade I (neuroserpin) member 1 and TIMP-2 only in DENV-infected condition [3]. Furthermore, we observed that the concentration of TIMP-1 (a metalloproteinase inhibitor) was lower in the secretome of DENV-infected cells compared to that of mock-infected cells [3]. In the present work, we identified other proteases and protease inhibitors, such as inter-alpha-trypsin inhibitor (heavy chain H2)
ACCEPTED MANUSCRIPT and ADAM10 only in mock condition; and TFPI, neurotrypsin and trypsin only in DENVinfected condition. Inter-alpha trypsin inhibitor is a serine protease inhibitor; the peptide identified in
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the UF is located in its propeptide region [49-50] (Figure 7a). The sequence identified in ADAM10, the disintegrin and metalloproteinase domain-containing protein 10, is located in the extracellular region of the protein [51-52] (Figure 7b). TFPI (tissue factor pathway
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inhibitor) is a protease inhibitor formed by three domains (K1, K2 and K3), where K1 and K2 inhibit the complex coagulator factor VIIa-tissue factor and coagulator factor Xa,
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respectively, preventing the extrinsic pathway activation in the coagulation process, and K3 domain, from which the peptide identified belongs, had no protease inhibition
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function [53] (Figure 7c). Neurotrypsin is a serine protease and the sequence identified is located in the zymogen activation region [54] (Figure 7d). Finally, a peptide from human trypsin was also identified. However, it was not possible to determine from which
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protein species of trypsin it came from since it is a conservative sequence [55]. The fact that all these proteases and protease inhibitors have theoretical molecular masses
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higher than 10 kDa, but were only identified in the UF, indicates that these molecules underwent a proteolytic processing where only the peptides generated after this event
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were identified. This processing would hinder the original function of these molecules or help the conversion of zymogens to the active form, leading to changes in the panel of
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peptides produced by the cell. An explanation for the absence of detection of these molecules in our previous study could be related to the lower sensitivity of the experimental procedures used, which would have underestimated the amount and variety of the identified proteases and protease inhibitors. Although data collected during this work allowed us to observe a proteolytic processing upon molecules presented in the secretome, complementary studies are necessary for a better understanding of the pathophysiological relevance of this phenomenon. It is noteworthy that the identification of these proteases and protease inhibitors complements our previous work, and taken together, the results of both studies indicate alterations in the variety and amount of these molecules. For instance, among the molecules only identified in the mock intact samples, we found a peptide originated from proSAAS, also known as proprotein convertase subtilisin/kexin type 1
ACCEPTED MANUSCRIPT inhibitor. This peptide corresponds to the KEP segment that is normally generated during processing of proSAAS by protein convertases 1/3 (PC1/3) and PC2 followed by carboxypeptidase E [56] (Figure 8), indicating that these proteases were active in mock-
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infected cells but not in the DENV-infected cells.
Through the analysis using the PeptideCutter program, we observed in the mockinfected sample a higher number of peptides probably resulting from cleavage by an
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enzyme similar to thermolysin (Figure 6), which acts between aliphatic amino acids with hydrophobic side chain. When we analyzed the proteases only present in the secretome
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from mock-infected cells, we found two enzymes, LON peptidase and Htra [3], both described in other organisms as acting at hydrophobic residues [57-58]. Conversely, in
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the DENV-infected sample, we observed a reduction on the number of peptides resulted from the cleavage by an enzyme similar to trypsin (Figure 6). This phenomenon could be explained by the presence of serine protease inhibitors, such as neuroserpin and
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inter-alpha trypsin inhibitor, only observed in the sample from DENV-infected cells. We could also hypothesize the existence of a chymase-like enzyme in the secretome of the
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DENV-infected cells, since we noticed a higher number of peptides cleaved by an enzyme similar to chymotrypsin (cleaves of aromatic amino acids with hydrophobic
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lateral chains) [59]. Consequently, the infection would modulate the action of certain enzymes on secreted proteins, leading to different proteolytic processing and the
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generation of a peptide panel distinct from the non-infected condition.
4. Conclusion The compilation of the results obtained in this study, including mass spectrometry analyses combined with in silico studies for prediction of cleavage sites for proteolytic activity, together with the results from our previous secretome study [3] allowed us to identify alterations in the proteolytic processing of the secreted proteins. This could be explained by infection-induced differences in the expression of proteases or protease inhibitors, as well as the activation of different enzyme families triggered by specific stimuli or by differential regulation of their inhibitors.
ACCEPTED MANUSCRIPT Conflict of interest statement
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The authors declare that they have no conflicts of interest.
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Acknowledgements
This work was supported by Fundação Carlos Chagas Filho de Amparo à Pesquisa do
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Estado do Rio de Janeiro (FAPERJ 103.163/2011, FAPERJ E-26/110.092/2013, FAPERJ E-26/201.167/2014), Conselho Nacional de Desenvolvimento Científico e
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Tecnológico (MCT/CNPq 476448/2008-5, (MCT/CNPq 550114/2010-6 and MCT/CNPq 306669/2013-7) and Plataformas Tecnologicas, Fiocruz. MBC was a recipient of a
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Ph.D. fellowship from CAPES and MROT was a recipient of a post-doctoral fellowship from CAPES/Faperj. The authors thanks the professor Igor C. Almeida, from Department of Biological Sciences, Border Biomedical Research Center, University of
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Texas at El Paso, and the PhD Paulo C. Carvalho, from Laboratory for Proteomics and Protein Engineering, Carlos Chagas Institute, Fiocruz, Paraná, for the fruitful
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discussions and help, and also the designer Pedro Bigler, from Centro de Desenvolvimento Tecnológico em Saúde (CDTS), for preparing high resolution figures
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for publication, and for creating the graphical abstract.
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Figure 1: A schematic overview of the strategies and methodologies applied to perform the mass spectrometry analysis of the samples obtained from the ultrafiltrate of the mock-infected and DENVinfected conditions.
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Figure 2: The Venn diagrams constructed from the molecules identified in the mock-infected condition (A) and DENV-infected condition (B) after distinct enzymatic treatments (applying the bottom-up strategy) using the EASY-nLC-II System (Thermo Scientific, USA) coupled to Orbitrap Velos mass spectrometers. Endoproteinases: Lys-C, Tryp (trypsin) and Lys-C+Tryp (digestion by Lys-C followed by trypsin). The raw data was run using Comet program against the Uniprot (dengue virus) and NextProt (Homo sapiens) databases. Figure 3: The Venn diagrams constructed after molecule identification. The molecules only found in the mock infected condition (M) are shown in blue. The molecules only found in the DENV-infected condition (DENV) are shown in red, and the shadowed area represents the molecules common to both conditions. (A) The bottom-up strategy, (B) the top-down strategy and (C) a compilation of the molecules identified by both strategies using mass spectrometers (nESI LTQ Orbitrap XL and Orbitrap Velos). The raw data was run using Comet program against the Uniprot (dengue virus) and NextProt (Homo sapiens) databases. Figure 4: Molecules identified in both conditions during the secretome [3] analysis but only in one condition during the ultrafiltrate analysis. Figure 5: Alignment of sequences on Uniprot tool. Identified sequences on carboxy-terminal region from human fibrinogen (P02671-2 = Isoform 2 of Fibrinogen alpha chain, residues 601 to 644) among the conditions, indicating differential proteolysis. Sequences presents only in DENV-infected condition (red), mock-infected condition (blue), and common to both conditions (black). Figure 6: The analysis of the exclusive sequences presents in the mock-infected condition (blue) and the DENV-infected condition (red) by the PeptideCutter program. The tool was used to predict possible sites of cleavage after in silico digestion. All enzymes were considered in the analysis.
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Figure 8: Schematic diagram of the proSAAS processing with emphasis in the generation of a proSAASderived peptide (KEP molecule). The region that corresponds to the localization of the identified peptide is highlighted in red.
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ACCEPTED MANUSCRIPT Biological Significance Since the liver, one of the targets of DENV infection, is responsible for producing molecules involved in distinct biological processes, the identification of proteins and
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peptides secreted by hepatocytes after infection would help to a better understanding of the physiopathology of dengue. Proteomic analyses of molecules with less than 10 kDa secreted by HepG2 cells after infection with DENV revealed differential proteolytic
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Graphical abstract
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Small molecules from the secretome of DENV-infected HepG2 cells were identified. Bottom-up
and
top-down
approaches allowed
on
protein
Differential proteolytic processing of the secreted molecules due to infection was
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observed.
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identification
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