Improving trehalose synthase activity by adding the C-terminal domain of trehalose synthase from Thermus thermophilus

Accepted Manuscript Improving trehalose synthase activity by adding the C-terminal domain of trehalose synthase from Thermus thermophilus Yan Li, Ziwei Wang, Yue Feng, Qipeng Yuan PII: DOI: Reference:

S0960-8524(17)30857-X http://dx.doi.org/10.1016/j.biortech.2017.05.189 BITE 18215

To appear in:

Bioresource Technology

Received Date: Revised Date: Accepted Date:

9 March 2017 27 May 2017 29 May 2017

Please cite this article as: Li, Y., Wang, Z., Feng, Y., Yuan, Q., Improving trehalose synthase activity by adding the C-terminal domain of trehalose synthase from Thermus thermophilus, Bioresource Technology (2017), doi: http:// dx.doi.org/10.1016/j.biortech.2017.05.189

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1

Improving trehalose synthase activity by adding the C-terminal domain of

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trehalose synthase from Thermus thermophilus

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Yan Li, Ziwei Wang, Yue Feng, Qipeng Yuan⃰

4

State Key Laboratory of Chemical Resource Engineering, Beijing University of

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Chemical Technology, No. 15 East Road of North Third Ring, Chao Yang District,

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Beijing 100029, China

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Abstract

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The conversion of maltose into trehalose by trehalose synthase (TreS) is a simple, fast,

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high substrate specificity and low-cost approach to produce trehalose. TreS from

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Thermus thermophilus (TtTreS) is a thermostable enzyme, whose C-terminal domain

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(TtTreS-C) was previously shown to improve the thermostability of a TreS enzyme

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through direct linking. The aim of this work was to study In this study, we studied the

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activities of four other TreS enzymes from different sources linked with or without

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TtTreS-C. The results showed that a flexible linker peptide between TreS enzymes

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and TtTreS-C is essential for their activity enhancement. Moreover, the specific

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activities of the four enzymes were also improved by linking to the TtTreS-C

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fragment. Together, our study provides novel insights into the functions of the

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C-terminal domain of TtTreS, and would facilitate its future application in enzyme

21

engineering.

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1. Introduction

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Trehalose (R-D-glucopyranosyl-1, 1-R-D-glucopyranoside) is a non-reducing 1

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disaccharide found in various organisms including bacteria, algae, fungi, yeasts and

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plants (Elbein et al., 2003; Richards et al., 2002; Zhang et al., 2010). It serves as a

26

source of energy, protects proteins and cellular membranes from a variety of

27

environmental stresses, including desiccation, dehydration, high temperature, freezing,

28

et al (Asker et al., 2009; Elbein et al., 2003; Li et al., 2012; Ryu et al., 2010; Wei et al.,

29

2013; Xiuli et al., 2009). Some bacteria and yeasts such as Kluyveromyces marxianus

30

were sensitive to alcohol, osmotic and oxidative stress, which correlated with the

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increases in the cell trehalose concentrations (Erdei et al., 2011). Chang-Joon Kim’s

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group overexpressed trehalose biosynthetic genes (otsBA), which could help the cells

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tolerate the toxicity of crude glycerol for direct use (Nguyen et al., 2013). Due to

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these properties, trehalose is widely applied as additives, stabilizers, and sweeteners in

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food, cosmetics and pharmaceutical industries (Guo et al., 2000).

36

Among different approaches to synthesize trehalose, enzymatic synthesis has

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been most widely used, which has been recently reviewed (Schiraldi et al., 2002). A

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putative UDP-glucose 4-epimerase in Pyrococcus horikoshiii was cloned, expressed

39

and purified from Escherichia coli in Lee’s group’s study. It could be coupled with

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trehalose sytnase (TreT) to regenerate UDP-Gal from UDP (Chung et al., 2012). The

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conversion of maltose into trehalose, catalyzed by trehalose synthase (TreS), is a

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simple, fast, high substrate specificity and low-cost approach (Liang et al., 2013; Wu

43

et al., 2011), much better than starch bioprocessing which involves two steps. The

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TreS pathway has been revealed in several organisms, such as Pseudomonas putida,

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Corynebacterium glutamicum, Streptomyces coelicolor, Thermus thermophilus and 2

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Thermotoga maritime.

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Trehalose synthase from Thermus thermophilus (TtTreS) is a thermostable

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enzyme from the Thermus strain. The enzyme contains a unique C-terminal domain

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apart from the active domain (Silva et al., 2003). Wang et al have identified that this

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extra C-terminal domain plays a key role in maintaining the thermophilicity and

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thermostability of TtTreS (Wang et al., 2007). This previous report showed that the C

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terminus of TtTreS (designated as TtTreS-C here after) also modulates the side

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reaction to reduce glucose production under high temperature conditions. When added

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with the C-terminal domain of TtTreS, the thermostability of a cold-active TreS from

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Deinococcus radiodurans (DrTreS) was greatly improved. However, they did not test

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the impact on the specific activity of a TreS enzyme by adding the TtTreS-C, although

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they detected less byproduct during the reaction catalyzed by DrTreS with the

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TtTreS-C than DrTreS itself.

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Previously, we have optimized the activity of trehalose synthases from different

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species have been optimized and determined the optimal temperature has been

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determined, pH value, reaction time and substrate concentration for TtTreS (Li et al.,

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2015). In the beginning of this study, The whole C-terminal domain of TtTreS has

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been deleted as in the study of Wang et al. Surprisingly, the truncated forms of TtTreS

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(containing 1-552, 1-566, 1-666, 1-766 or 1-866 amino acids) all showed decreased

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activities compared with the full-length TtTreS enzyme (data not shown). We also

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tested The enzyme reactions of all the truncated forms of TtTreS enzymes also have

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been tested under different temperatures, however, none of the truncated forms of 3

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enzymes showed normal activities in these situations (data not shown). Thus, it

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suggested that the TtTreS-C might not only play a role in thermophilicity and

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thermostability of TtTreS, but also function in the activity of TtTreS possibly through

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stabilizing the active domain, which was not studied in Wang’s study. In this study,

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trehalose synthase genes with only the active domains from four different sources

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have been expressed in Escherichia coli (Fig.1). Our results showed that linking

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TtTreS-C to the C-termini of the four TreS enzymes could all increase the enzymatic

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activities of them. In addition, a linker peptide between TreS and TtTreS-C is essential

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for the activity enhancement, suggesting that spatial organization of the two domains

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is important for the impact of TtTreS-C on the activity of the active domains of TreSs

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(Fig.1). Together, our study provides novel insights into the functions of the

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C-terminal domain of TtTreS and would facilitate its future application in enzyme

80

engineering.

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2. Materials and methods

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2.1. Bacterial strains and media

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E. coli DH5α (from Strata gene) was used for plasmid construction. E. coli

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Rosetta (DE3) (from the E. Coli Genetic Stock Center) was used for protein

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expression and enzyme assays. Strains used in this study are summarized in Table 1.

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The trehalose synthase genes were obtained from Pseudomonas putida

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NBRC14164, Corynebacterium glutamicum ATCC 13032, Streptomyces coelicolor

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ATCC 23899, Thermus thermophilus HB27 and Thermotoga maritime MSB8.

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LB medium contains 10 g/liter tryptone, 5 g/liter yeast extract, and 10 g/liter NaCl. 4

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The TB minimal medium contains 12 g/liter tryptone, 24 g/liter yeast extract, 4

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ml/liter glycerol, 2.31 g/liter KH2PO4, and 16.43 g/liter K2HPO4·3H2O. When needed,

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ampicillin, was added to the medium at 100 µg/ml, respectively.

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2.2. Amplification of the trehalose synthase genes by PCR and plasmid construction

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The genomic DNA of Pseudomonas putida NBRC 14164, Corynebacterium

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glutamicum ATCC 13032, Streptomyces coelicolor ATCC 23899, Thermus

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thermophilus HB27 and Thermotoga maritime MSB8 were obtained from the

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University of Georgia, Athens, GA. The nucleotide sequences of the trehalose

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synthase (TreS) were originally retrieved from GenBank with the BLAST program

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(Fig. 2). These trehalose synthases have different N-terminal domains and also low

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identity amino acid sequences. Trehalose synthases from two thermophilic bacteria

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and two normal bacteria have been tried to meature the impact of the C-terminal

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domain of trehalose synthase from Thermus thermophilus. All the genes were

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amplified with PCR using PrimeSTAR DNA polymerase (TaKaRa) and the genomic

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DNAs as templates.

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PCR amplification consisted of an initial denaturation step at 98 °C for 2 min,

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followed by 30 cycles of denaturation at 98 °C for 10 s, annealing at 55 °C for 5 s,

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and extension at 72 °C for a specific time, which is decided by the target gene length.

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Plasmids and primers used in this study are listed in Table 1 and Table 2,

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respectively. The plasmids pET-22b was utilized for gene cloning and protein

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expression. The PpTreS, PpTreS565, CgTreS, ScTreS and TmTreS were short for

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TreS from Pseudomonas putida NBRC 14164 genomic DNA, Corynebacterium 5

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glutamicum ATCC 13032 genomic DNA, Streptomyces coelicolor ATCC 23899

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genomic DNA and Thermotoga maritime MSB8 genomic DNA, respectively. The

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TtTreS-C was short for C-terminal of TreS from Thermus thermophilus HB27

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genomic DNA.

116

The amplified DNA fusion fragments from four sources were subsequently

117

digested and thereafter ligated into expression vector pET-22b respectively, to

118

construct twelve recombinant plasmids (Table 1), which were then transformed into

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the competent E. coli DH5α. The restriction enzymes and ligase were purchased from

120

Thermo Scientific. The competent E. coli DH5α and E. coli Rosetta (DE3) were

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purchased from TransGen.

122

2.3. Protein expression and purification

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E. coli Rosetta (DE3) was transformed with the corresponding expression

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plasmids. The obtained transformants were inoculated in 4 ml LB medium containing

125

100 µg/ml of ampicillin and grown aerobically at 37 °C overnight. 500 µl overnight

126

cultures were inoculated into 50 ml fresh TB medium, left to grow at 37 °C until the

127

optical density at 600 nm (OD600) reached 0.6, and then the E. coli Rosetta (DE3)

128

transformants were induced with 0.5 mM isopropyl-β-D-thiogalactopyranoside (IPTG)

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and shaken at 16 °C overnight. The cells were harvested 30 h after induction and

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broken using ultrasonic cell disruptor. After centrifugation, the supernatants were used

131

as crude enzyme for enzymatic assays. The crude extracts of the recombinant

132

enzymes were further purified by using the following steps: The protein was first

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purified with affinity chromatography using a Ni-NTA column (Qiagen) 6

134

pre-equilibrated with the lysis buffer and eluted with the lysis buffer supplemented

135

with 300 mM imidazole, which was followed by purification with gel filtration using

136

a Superdex-200 (GE Healthcare) column equilibrated with a buffer containing 10 mM

137

Tris–HCl pH 8.0, 200 mM NaCl, and 5 mM DTT. The purified protein was analyzed

138

by SDS–PAGE. The fractions containing the target protein were pooled and

139

concentrated to 20 mg/ml.

140

2.4. Enzymatic assays

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The reaction was carried out in a 21 ml system containing 20 ml 20% maltose and

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1 ml crude or purified enzymes in 1×PBS buffer (pH 7.4). Four different sources of

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trehalose synthases have been reacted at the optimal temperature which has been

144

obtained in the previous study (Li et al., 2015). When four sources of recombinant

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TreS-TreS-C activity was meatured, different temperatures were attempted to obtain

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the optimal temperature. After 10 min, the trehalose production was measured by

147

High Performance Liquid Chromatography analysis (HPLC). Trehalose synthase

148

enzyme activity was defined under the condition of the optimal reaction temperature,

149

with excessive maltose solution as the substrate. The activity consuming 1 µmol

150

maltose or generating 1 µmol trehalose in 1 min was defined as one unit of enzyme

151

activity. The protein amount was determined by software Image J grayscale scanning.

152

2.5. HPLC analysis

153

Trehalose (SIGMA), was used as the standard. Both standard and samples were

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analyzed and quantified by HPLC (HITACHI) with a reverse-phase Venusil PS NH

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column (Agela) and a differential refraction detector. Solvent A was water with 87% 7

156

acetonitrile. The column temperature was set to 25 °C. The flow rate was 1 ml/min.

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Quantification of trehalose was based on the peak areas.

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2.6. Optimization of the reaction conditions

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For the recombinant E. coli harboring pET-22b-PpTreS, pET-22b-CgTreS,

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pET-22b-ScTreS,

pET-22b-TmTreS,

pET-22b-PpTreS565-linker-TtTreS-C,

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pET-22b-CgTreS-linker-TtTreS-C,

162

pET-22b-TmTreS-linker-TtTreS-C, respectively, the enzymatic reaction conditions

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were optimized as follows. The reaction was carried out under the temperature of

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20 °C, 30 °C, 40 °C or 50 °C, respectively. To define the optimal temperature, the

165

enzyme was incubated in various temperatures for 10 h with 10% maltose, and

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trehalose amount was measured under the condition described above.

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3. Results and discussion

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3.1. Effect of TtTreS-C on enzymatic activity of TreS enzymes

pET-22b-ScTreS-linker-TtTreS-C

and

169

TreS enzymes from four different sources were adopted in this research. In order

170

to test whether linking the TtTreS-C would increase the activity of the single-domain

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TreSs, we linked tThe active domains of four TreS enzymes from different sources to

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TtTreS-C have been linked, with or without a flexible linker peptide. The sequence of

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the flexible linker peptide was GGGSGS, modified from the review article of

174

J.Sivaraman (Li et al., 2015). These chimera proteins have been expressed in E.coli,

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and their crude enzymatic activities were compared with the four native enzymes.

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First, different enzyme reaction temperatures (containing 20, 30, 40, 50 °C) have been

177

tested in this study, and the reactions were subsequently carried out under the optimal 8

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temperature of 20 °C, 20 °C, 20 °C or 30 °C, respectively for the four enzymes from

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different sources. After a reaction of 10 min, the trehalose production was measured

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by High Performance Liquid Chromatography analysis (HPLC) and the results

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showed that although linking the four enzymes directly to TtTreS-C did not increase

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the enzymatic activity of TreSs, the chimera proteins with linker peptides between the

183

enzymes and TtTreS-C all showed increased activities compared to the native

184

enzymes (Fig. 3).

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This suggested that the linker peptide between TreS and TtTreS-C has an

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important role in the activity enhancement. In order to maintain steric configuration

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and catalytic ability of trehalose synthase, medium-sized flexible linker peptide was

188

adopted in this study. On the other hand, the results also showed that the TtTreS-C not

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only plays a role in thermophilicity and thermostability of TtTreS, but also function in

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the activity of TtTreS. Taken together, these results suggested that TtTreS-C did affect

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the enzymatic activities of TreSs, and the spatial organization of the active domain

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and TtTreS-C is important for the impact of TtTreS-C on the activity of the active

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domains of TreSs. Thus, in the following studies, only chimera proteins with linker

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peptides were used in the comparison with native enzymes.

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3.2. TtTreS-C increases the specific activities of TreSs

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By transforming the eight recombinant plasmids (four native enzyme plasmids

197

and four chimera protein plasmids with linkers) into E.coli, we first determined tThe

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optimal temperature of the enzyme reaction for each construct has been determined

199

firstly. Under the optimal temperatures, the specific activities of each transformants 9

200

have been obtained (Fig. 4). The results showed that linking the four enzymes to

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TtTreS-C with peptide linkers could also increase the specific activities of TreS

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enzymes. The specific activities of trehalose synthases from Pseudomonas putida,

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Corynebacterium glutamicum, Streptomyces coelicolor and Thermotoga maritime

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were increased 1.91-fold, 1.38-fold, 1.94-fold and 1.64-fold by fusion with TtTreS-C,

205

respectively. This suggested that the enzyme properties of the four enzymes were

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modified by the TtTreS-C linked.

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3.3. Reaction temperature optimization of trehalose biosynthesis

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Furthermore, the enzymatic reaction conditions for trehalose synthase production

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were optimized with the recombinant E. coli harboring the four native enzyme

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plasmids and four chimera protein plasmids, respectively. When the crude enzyme

211

was added with 10% maltose solution, we noticed the results show that the conversion

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efficiency began to decrease when the temperature was raised up. No additional

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trehalose accumulation was observed up to high temperature in the above described

214

experiments (Fig. 5). Therefore, the optimal temperatures of the four chimera

215

enzymes were determined to be 20 °C, 20 °C, 20 °C and 30 °C, respectively (Fig. 5).

216

In the study of Wang et al, the recombinant DrTS-TtTS∆N enzyme had a higher

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thermostability than DrTS in their reactions. However, in our this study, the optimal

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temperatures of the four chimera enzymes were not increased under our reaction

219

conditions. We suggest that it This phenomenon might result from the different

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reaction conditions used in our and their studies. Moreover, it also indicated that the

10

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TtTreS-C might exhibit different effects on different proteins, either increasing the

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thermostability or the specific activities of target enzymes.

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4. Conclusions

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In the current study, we first tested the heterologous expression of TreS genes

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from four different sources with or without TtTreS-C has been tested firstly. The

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enzymatic reaction temperature for the trehalose bioconversion was optimized

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respectively. The results showed that both the conversion and the specific activities of

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TreS enzymes were increased after linking to the TtTreS-C. The present study could

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shed light on the further investigation of the efficient expression of TreS genes and

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optimization of enzymatic reactions. In addition, linker-based connection between the

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active domains of trehalose synthases and TtTreS-C has an important impact on the

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enzymatic activity, suggesting that spatial organization of the two domains is

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important for the impact of TtTreS-C on the activity of the active domains of TreSs.

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Future more linker types could be tested to get better improvement of the activity of

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TreS enzymes.

236 237

Acknowledgments

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The authors would like to acknowledge the financial support of the National

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Natural Science Foundation of China (Nos. 21636001 and 31670766) and the

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Fundamental Research Funds for the Central Universities (buctrc201613, ZY1629).

241 242

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302 303

14

304 305

Fig.1.

306

CgTreS-linker-TtTreS-C, ScTreS-linker-TtTreS-C and TmTreS-linker-TtTreS-C. And

307

then they were subsequently digested and thereafter ligated into expression vector

308

pET-22b respectively, to construct eight recombinant plasmids and were transformed

309

into E.coli Rosetta (DE3).

Expression

of

enzymes

310

15

about

PpTreS565-linker-TtTreS-C,

PpTreS CgTreS ScTreS TmTreS

...................................MAKRSRPA.AFIDDPL......WYKDAVIYQLHIKSF MTDTSPLNSQPSADHHPDHAARPVLDAHGLIVEHESEEFPVPAPAPGEQPWEKKNREWYKDAVFYEVLVRAF ..................................MTVNEPVPD.TFEDTPAGDRHPDWFKRAVFYEVLVRSF ...........................................................VDVVLRERSIEEY

30 72 37 13

PpTreS CgTreS ScTreS TmTreS

FDANNDGIGDFAGLISKLDYIAELGVNTLWLLPFYPSPRRDDGYDIAEYKAVHPDYGSLADARRFIAEAHKR YDPEGNGVGSLKGLTEKLDYIQWLGVDCIWIPPFYDSPLRDGGYDIRNFREILPEFGTVDDFVELVDHAHRR QDSNGDGIGDLKGLTAKLDYLQWLGVDCLWLPPFFKSPLRDGGYDVSDYTAVLPEFGDLADFVEFVDAAHQR RTIIGNEVDEIKKLAEPLKGKKVLHVNATAYGGGVAEILHN.LVPLMRSVGLDARWRVIEAPDEFFNVTKKF

102 144 109 84

PpTreS CgTreS ScTreS TmTreS

GLRVITELVINHTSDQHPWFQRARHAKRGSKARDFYVWSDDEQKYDGTRIIFLDTEKSNWTWDPVAGQYFWH GLRVITDLVMNHTSDQHAWFQESRRDPTGPYG.DFYVWSDDPTLYNEARIIFVDTEESNWTYDPVRGQYFWH GMRVIIDFVMNHTSDQHPWFQESRKNPDGPYG.DYYVWADDDTRYADARIIFVDTEASNWTHDPVRGQYYWH HNTLQGADIEISEEEWNLYEEVCRKNAELIQDEELFVIHDSQP...AAVRKFVDLNDRKWIWRCHIDLSTPN

174 215 180 153

PpTreS CgTreS ScTreS TmTreS

RFYSHQPDLNFDNPQVLNAVIKVMRFWLDLGVDGLRLDAIPYLIERDGTNNENLPETHTVLKAIRAEIDANY RFFSHQPDLNYDNPAVQEAMLDVLRFWLDLGLDGFRLDAVPYLFEREGTNGENLKETHDFLKLCRSVIEKEY RFFSHQPDLNYENPAVQEEMLAALKFWLDLGVDGYRLDAVPYLYAEEGTNCENLPASHAFLKRVRREIDAQY MKVWQKFSQYLEG...YNRLVFHLEEYFPQGWK.ERSIAFPPSIDPLSEKNRDLDEDTIRKTLERLEIDPER

246 287 252 221

PpTreS CgTreS ScTreS TmTreS

PDRMLLAEANQWPEDTRPYFGE.GEG.DECHMAFHFPLMPRMYMALAMEDRFPITDILRQTPEIPANCQWAI PGRILLAEANQWPQDVVEYFGEKDKG.DECHMAFHFPLMPRIFMGVRQGSRTPISEILANTPEIPKTAQWGI PDTVLLAEANQWPEDVVDYFGDYSTGGDECHMAFHFPVMPRIFMAVRRESRYPVSEILAKTPAIPSGCQWGI PLITVVARFDPWKD....................LFSAIDVYRLVKKEIPEVQLAVVSAMAADDPE..GWFF

316 358 324 271

PpTreS CgTreS ScTreS TmTreS

FLRNHDELTLEMVTDRERDYLWNYYAEDRRARINLGIRRRLAPLLQRDRRRIELLTSLLLSMPGTPTLYYGD FLRNHDELTLEMVSDEERSYMYSQFASEPRMRANVGIRRRLSPLLEGDRNQLELLHGLLLSLPGSPVLYYGD FLRNHDELTLEMVTDEERDYMYAEYAKDPRMRANIGIRRRLATLLDNDRDQIELFTALLLALPGSPILYYGD FEK.....VLRYAGTDEDIKFCTNLKGVGNKEVNAIQRATTVALHTATREGFGLVISEALYKR...VPVVAR

388 430 396 335

PpTreS CgTreS ScTreS TmTreS

ELGMGDNIYLGDRDGVRTPMQWSPDRNGGFSRADPQRLVLPPIMDPLYGYQTVNVEAQSHDPHSLLNWTRRM EIGMGDNIWLHDRDGVRTPMQWSNDRNGGFSKADPERLYLPAIQNDQYGYAQVNVESQLNRENSLLRWLRNQ EIGMGDNIWLGDRDAVRTPMQWTPDRNAGFSTCDPGRLYLPAIMDPVYGYQVTNVEASMASPSSLLHWTRRM PVGG...VKIQVKHGENGYLAWEREDLAGYVVKLIKDEELRRKMGE...KGRQTVVENFIITVHLKNYLKLF

460 502 468 401

PpTreS CgTreS ScTreS TmTreS

LAVRKQQKAFGRGTLRTLTPSNRRILAYIREYTDADGHTEVILCVANVSRAAQAAELELSQYADKVPVEMLG ILIRKQYRAFGAGTYREVSSTNESVLTFLREHKG.....QTILCVNNMSKYPQAVSLDLREFAGHTPREMSG IEIRKQNPAFGLGTYTELPSSNPAVLAFLREYED.....DLVLCVNNFARFAQPTELDLREFAGRHPVELFG LDLLR...................................................................

532 569 535 406

PpTreS CgTreS ScTreS TmTreS

GSAFPPIGQLPFLLTLPPYAFYWFLLA.AHDRMPSWHIQATEGLPELTTLVLRKRMEELLEAPARDTLQTTI GQLFPTIAEREWIVTLAPHGFFWFDLT..ADEKDDME................................... GVRFPAIGELPYLLTLGGHGFYWFRLTRVASRIGRRA................................... ........................................................................

603 604 572 406

311 312

Fig.2. The amino acid sequence of CgTreS, ScTreS, TmTreS and the front partial

313

amino acid sequence of PpTreS. By comparing, their sequence were different. Lane 1:

314

The partial sequence of trehalose synthase gene from Pseudomonas putida NBRC

315

14164; Lane 2: The partial sequence of trehalose synthase gene from

316

Corynebacterium glutamicum ATCC 13032; Lane 3: The partial sequence of 16

317

trehalose synthase gene from Streptomyces coelicolor ATCC 23899; Lane 4: The

318

partial sequence of trehalose synthase gene from Thermotoga maritime MSB8.

319

17

320

321 322

Fig. 3. Crude trehalose synthase activity in recombinant E.coli Rosetta (DE3)

323

harboring pET-22b-PpTreS, pET-22b-PpTreS565-TtTreS-C,

324

pET-22b-PpTreS565-linker-TtTreS-C, pET-22b-CgTreS, pET-22b-CgTreS-TtTreS-C,

325

pET-22b-CgTreS-linker-TtTreS-C, pET-22b-ScTreS, pET-22b-ScTreS-TtTreS-C,

326

pET-22b-ScTreS-linker-TtTreS-C, pET-22b-TmTreS, pET-22b-TmTreS-TtTreS-C and

327

pET-22b-TmTreS-linker-TtTreS-C respectively by measuring at the same reaction

328

conditions. The amount of trehalose were measured by high performance liquid

329

chromatography.

330

18

331 332

Fig. 4. The activities of TreS, which from different sources, with or without

333

C-terminal of trehalose synthase from Thermus thermophilus were showed. The data

334

were generated from three independent experiments.

335

19

336 337

Fig. 5. Trehalose production in recombinant E.coli Rosetta (DE3) harboring

338

pET-22b-PpTreS, pET-22b-PpTreS565-linker-TtTreS-C (a), pET-22b-CgTreS,

339

pET-22b-CgTreS-linker-TtTreS-C (b), pET-22b-ScTreS,

340

pET-22b-ScTreS-linker-TtTreS-C (c), pET-22b-TmTreS, and

341

pET-22b-TmTreS-linker–TtTreS-C (d) respectively by varying reaction temperatures.

342

The amount of trehalose under different temperatures were measured by high

343

performance liquid chromatography.

344

20

345

Table 1

346

The details of strains and plasmids. Plasmid or strain Strains E coli DH5α

E coli Rosetta (DE3)

E coli Rosetta (DE3) -1 E coli Rosetta (DE3) -2 E coli Rosetta (DE3) -3 E coli Rosetta (DE3) -4 E coli Rosetta (DE3) -5 E coli Rosetta (DE3) -6 E coli Rosetta (DE3) -7 E coli Rosetta (DE3) -8 E coli Rosetta (DE3) -9

E coli Rosetta (DE3) -10 E coli Rosetta (DE3) -11 E coli Rosetta (DE3) -12 Plasmids pET-22b pET-22b-PpTreS

Descriptiona

Reference or sources

F-ψ80dlacZ△ (lacZYA-argF) U169 endA1 recA1 hsdR17 (rk-, mk+) supE44λ-thi-1 gyrA96 relA1 phoA F-ompT hsdSB(rB-, mB-) galdcmlacY1 (DE3) pRARE (argU, argW, ilex, glyT, leuW, proL) (Cmr) E coli Rosetta (DE3) harboring pET-22b-PpTreS E coli Rosetta (DE3) harboring pET-22b-CgTreS E coli Rosetta (DE3) harboring pET-22b-ScTreS E coli Rosetta (DE3) harboring pET-22b-TmTreS E coli Rosetta (DE3) harboring pET-22b-PpTreS565-TtTtreS-C E coli Rosetta (DE3) harboring pET-22b-CgTreS-TtTreS-C E coli Rosetta (DE3) harboring pET-22b-ScTreS-TtTreS-C E coli Rosetta (DE3) harboring pET-22b-TmTreS-TtTreS-C E coli Rosetta (DE3) harboring pET-22b-PpTreS565-linker-TtTtre S-C E coli Rosetta (DE3) harboring pET-22b-CgTreS-linker-TtTreS-C E coli Rosetta (DE3) harboring pET-22b-ScTreS-linker-TtTreS-C E coli Rosetta (DE3) harboring pET-22b-TmTreS-linker-TtTreS-C

TransGen

TransGen

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pT7 expression vector, Novagen PBR322origin, Ampr pET-22b vector containing PpTreS This study 21

from pseudomonas putida pET-22b-CgTreS pET-22b vector containing CgTreS from Corynebacterium glutamicum pET-22b-ScTreS pET-22b vector containing ScTreS from Streptomyces coelicolor pET-22b-TmTreS pET-22b vector containing TmTreS from Thermotoga maritime pET-22b-PpTreS565-TtTre pET-22b vector containing PpTreS S-C from pseudomonas putida and TtTreS-C from Thermus thermophilus pET-22b-CgTreS-TtTreS-C pET-22b vector containing CgTreS from Corynebacterium glutamicum and TtTreS-C from Thermus thermophilus pET-22b-ScTreS-TtTreS-C pET-22b vector containing ScTreS from Streptomyces coelicolor and TtTreS-C from Thermus thermophilus pET-22b-TmTreS-TtTreS-C pET-22b vector containing TmTreS from Thermotoga maritime and TtTreS-C from Thermus thermophilus pET-22b-PpTreS565-linker- pET-22b vector containing PpTreS TtTreS-C from pseudomonas putida and TtTreS-C from Thermus thermophilus with linker pET-22b-CgTreS-linker-TtT pET-22b vector containing CgTreS reS-C from Corynebacterium glutamicum and TtTreS-C from Thermus thermophilus with linker pET-22b-ScTreS-linker-TtT pET-22b vector containing ScTreS reS-C from Streptomyces coelicolor and TtTreS-C from Thermus thermophilus with linker pET-22b-TmTreS-linker-Tt pET-22b vector containing TmTreS TreS-C from Thermotoga maritime and TtTreS-C from Thermus thermophilus with linker 347

a

Amp r, ampicillin resistant.

348

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349

Table 2

350

The details of primer sequences. Name of Primers

Primer sequences

PpTreS-f PpTreS-r CgTreS-f

5’-GGGAAAGGATCCGGCCAAGCGTTCCCGCC-3’ 5’-GGGAAACTCGAGTGACTCTCCCCAGGTACTGATC-3’ 5’-GGGAAACCATGGGCACTGATACCTCTCCGTTGAATTCTCA3’ 5’-GGGAAAAAGCTTTTCCATATCGTCCTTTTCATCGGC-3’ 5’-GGGAAAGGATCCGCACCGTCAACGAGCCCGTAC-3’ 5’-GGGAAAAAGCTTAGCGCGGCGGCCG-3’ 5’-GGGAAAGAATTCGGATGTTGTGTTGAGAGAGCGAAGC-3’ 5’-GGGAAAGTCGACCCTCAACAGATCTAAGAAGAGTTTCAG ATAGTT-3’ 5’-GGGAAAGAATTCGGCCAAGCGTTCCCGCCCGGC-3’

CgTreS-r ScTreS-f ScTreS-r TmTreS-f TmTreS-r PpTreS565(TtTreSC)-f PpTreS565(TtTreSC)-r TtTreS-C(PpTreS56 5)-f TtTreS-C(PpTreS56 5)-r CgTreS(TtTreS-C)-f CgTreS(TtTreS-C)-r TtTreS-C(CgTreS)-f TtTreS-C(CgTreS)-r ScTreS(TtTreS-C)-f ScTreS(TtTreS-C)-r TtTreS-C(ScTreS)-f TtTreS-C(ScTreS)-r TmTreS(TtTreS-C)-f TmTreS(TtTreS-C)-r TtTreS-C(TmTreS)-f TtTreS-C(TmTreS)-r PpTreS565L(TtTreS -C)-f PpTreS565L(TtTreS -C)-r LTtTreS-C(PpTreS5

5’-CGGGGGCGGGCTCCTCGGCGGGCATGCGGTCATGGGCG-3 ’ 5’-CGCCCATGACCGCATGCCCGCCGAGGAGCCCGCCCCCG-3’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCT-3’ 5’-GGGAAAGTCGACGACTGATACCTCTCCGTTGAA-3’ 5’-CGGGGGCGGGCTCCTCGGCTTCCATATCGTCCTTTTCA-3’ 5’-TGAAAAGGACGATATGGAAGCCGAGGAGCCCGCCCCCG-3 ’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCT-3’ 5’-GGGAAAGAATTCGACCGTCAACGAGCCCGTACC-3’ 5’-CGGGGGCGGGCTCCTCGGCGGATGCGACTCGGGTGAGC-3 ’ 5’-GCTCACCCGAGTCGCATCCGCCGAGGAGCCCGCCCCCG-3 ’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCT-3’ 5’-GGGAAAGAATTCGGATGTTGTGTTGAGAGAGCG-3’ 5’-CGGGGGCGGGCTCCTCGGCCCTCAACAGATCTAAGAAG-3 ’ 5’-CTTCTTAGATCTGTTGAGGGCCGAGGAGCCCGCCCCCG-3’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCT-3’ 5’-GGGAAAGGATCCGGCCAAGCGTTCCCGCCCGGCAGCC-3’ 5’-GGCGGCGGCTCCGGCTCCGGGCATGCGGTCATGG-3’ 5’-GGAGCCGGAGCCGCCGCCTGGGCCGAGGAGCCCG-3’ 23

65)-f LTtTreS-C(PpTreS5 65)-r CgTreSL(TtTreS-C)f CgTreSL(TtTreS-C)r LTtTreS-C(CgTreS)f LTtTreS-C(CgTreS)r ScTreSL(TtTreS-C)f ScTreSL(TtTreS-C)r LTtTreS-C(ScTreS)f LTtTreS-C(ScTreS)r TmTreSL(TtTreS-C) -f TmTreSL(TtTreS-C) -r LTtTreS-C(TmTreS) -f LTtTreS-C(TmTreS) -r

5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCTGCCAGCG CTCGT-3’ 5’-GGGAAACCATGGGACTGATACCTCTCCGTTGAATTCTCAG CCG-3’ 5’-GGCGGCGGCTCCGGCTCCTTCCATATCGTCCTTT-3’ 5’-GGAGCCGGAGCCGCCGCCTGGGCCGAGGAGCCCG-3’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCTGCCAGCG CTCGT-3’ 5’-GGGAAAGGATCCGACCGTCAACGAGCCCGTACCTGACAC CTTCGAG-3’ 5’-GGCGGCGGCTCCGGCTCCAGCGCGGCGGCCGATG-3’ 5’-GGAGCCGGAGCCGCCGCCTGGGCCGAGGAGCCCG-3’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCTGCCAGCG CTCGT-3’ 5’-GGGAAAGGATCCGGATGTTGTGTTGAGAGAGCGAAGCAT AGAGG-3’ 5’-GGCGGCGGCTCCGGCTCCCCTCAACAGATCTAAG-3’ 5’-GGAGCCGGAGCCGCCGCCTGGGCCGAGGAGCCCGCCCCC GAG-3’ 5’-GGGAAAAAGCTTGGCTTTTCCGGCCTTGGCCTGCCAGCG CTCGT-3’

351 352

24

353

Highlights

354 355 356 357 358 359 360 361


We tested the heterologous expression of TreS genes with or without TtTreS-C in Escherichia coli.
Linking TtTreS-C to the C-termini of TreS enzymes could all increase the enzymatic activities.
A linker peptide between TreS and TtTreS-C is essential for the activity enhancement.
The specific activities of TreS enzymes were also improved by TtTreS-C.

362

25