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Ferric reductase-like families of Eumycetes
f u n g a l b i o l o g y 1 1 4 ( 2 0 1 0 ) 7 6 6 e7 7 7
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The Nox/Ferric reductase/Ferric reductase-like families of Eumycetes Ibtissem GRISSAa,b,c, Fre´de´rique BIDARDb,c, Pierre GROGNETa,b,c, Sandrine GROSSETETEb,c, Philippe SILARa,b,c,* a
Univ Denis Diderot, UFR Sciences du Vivant, 75013 Paris, France Univ Paris-Sud, Institut de Ge´ne´tique et Microbiologie, UMR 8621, 91405 Orsay cedex, France c CNRS, Institut de Ge´ne´tique et Microbiologie, UMR 8621, 91405 Orsay cedex, France b
article info
abstract
Article history:
Reactive Oxygen Species (ROS) are involved in plant biomass degradation by fungi and
Received 19 April 2010
development of fungal structures. While the ROS-generating NADPH oxidases from
Received in revised form
filamentous fungi are under strong scrutiny, much less is known about the related integral
5 July 2010
Membrane (or Ferric) Reductases (IMRs). Here, we present a survey of these enzymes in 29
Accepted 6 July 2010
fungal genomes covering the entire available range of fungal diversity. IMRs are present in
Available online 14 July 2010
all fungal genomes. They can be classified into at least 24 families, underscoring the high
Corresponding Editor: Michael Lorenz
diversity of these enzymes. Some are differentially regulated during colony or fruiting body development, as well as by the nature of the carbon source of the growth medium. Impor-
Keywords:
tantly, functional characterization of IMRs has been made on proteins belonging to only
Ferric reductase
two families, while nothing or very little is known about the proteins of the other 22
Fungal genomes
families.
NADPH oxidase
ª 2010 The British Mycological Society. Published by Elsevier Ltd. All rights reserved.
Reactive Oxygen Species
Introduction Reactive Oxygen Species (ROS) have been implicated in two major aspects of fungal biology. First, they participate in the degradation of the plant biomass, especially lignin lysis (ten Have & Teunissen 2001; Wesenberg et al. 2003; Martinez et al. 2005; Morel et al. 2009). Second, they are involved in signaling several developmental processes, including fruiting body maturation (Lara-Ortiz et al. 2003; Malagnac et al. 2004), spore germination (Malagnac et al. 2004; Cano-Dominguez et al. 2008; Lambou et al. 2008), mycelium growth (Leuthner et al. 2005; Semighini & Harris 2008), mutualistic symbiosis (Tanaka et al. 2006) and differentiation of appressorium and
appressorium-like structures (Egan et al. 2007; Segmuller et al. 2008; Brun et al. 2009). To date, the role of ROS in development has been mostly studied in ascomycetes, such as Aspergillus nidulans, Neurospora crassa, Epichloe festucae, Botrytis cinerea, Magnaporthe grisea and Podospora anserina. In these species, the major ROS producing enzymes evidenced as signaling development are NADPH oxidases (Nox, see Aguirre et al. 2005; Takemoto et al. 2007 for review), however a glyoxal oxidase (glo1) has also been shown to be necessary for normal hyphal morphology and filamentous growth in the basidiomycete Ustilago maydis (Leuthner et al. 2005). Plant biomass degradation is mostly studied in basidiomycetes, such as white and brown rots, which are able or not able to efficiently degrade
* Corresponding author. Institut de Ge´ne´tique et Microbiologie, UMR 8621 CNRS UPS, 91405 Orsay cedex, France. Tel.: þ33 1 69 15 46 58; fax: þ33 1 69 15 70 06. E-mail address: [email protected] 1878-6146/$ e see front matter ª 2010 The British Mycological Society. Published by Elsevier Ltd. All rights reserved. doi:10.1016/j.funbio.2010.07.002
Nox and IMR of Eumycetes
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Table 1 e Fungal CDS used in this study. Species
Lifestyle
Nox and IMR
Chytridiomycota (Chytridiomycetes)
Batrachochytrium dendrobatidis
Frog pathogen
BDEG_06864 (Nox1) BDEG_07125 (Nox2) BDEG_01882 BDEG_02345 BDEG_07017
Chytridiomycota (Chytridiomycetes)
Spizellomyces punctatus
Soil saprobe
Blastocladiomycota (Blastocladiomycetes)
Allomyces macrogynus
Pond saprobe
AMAG_13933.1 (Nox1) AMAG_15568.1 (Nox2) AMAG_11331.1 AMAG_07049.1 AMAG_NA1a AMAG_NA2a
OM
Mucoromycotina
Mucor circinelloides
Soil saprobe
Mucci1_77308 Mucci1_95952 Mucci1_85232
JGI
Mucoromycotina
Phycomyces blakesleeanus
Soil saprobe
Phybl1_77767 Phybl1_76888
JGI
Mucoromycotina
Rhizopus oryzae
Soil saprobe
RO3G_05460 RO3G_04617 RO3G_10468 RO3G_13599
FGI
Ascomycota (Schizosaccharomycetes)
Schizosaccharomyces pombe
Yeast saprobe
Sp_Frp1 CAA17033 ¼ SPBC947.05c
NCBI/Sanger
Ascomycota (Saccharomycetes)
Ashbya gossypii
Yeast-like, cotton pathogen
NM_212056 NM_208455 NM_209529 NM_211017 NM_208618
AGD
Ascomycota (Saccharomycetes)
Candida albicans SC5314
Human commensal and pathogen
orf19.1264 orf19.1263 (¼CFL1) orf19.1415 (¼CFL95) orf19.1270 orf19.5634 orf19.1930 orf19.1932 orf19.701 orf19.6138 orf19.1844 orf19.3538 orf19.2312 orf19.7077 orf19.7112 orf19.867 orf19.4843
FGI
Ascomycota (Saccharomycetes)
Saccharomyces cerevisiae
Yeast saprobe
ScFRE1 ScFRE2 ScFRE3 ScFRE4 ScFRE5 ScFRE6 ScFRE7 ScFRE8 YGL160W
SGD
BDEG_03995 SPPG_07581 (Nox1) SPPG_07607 (Nox2) SPPG_00862 SPPG_0462 SPPG_05133 SPPG_06478 SPPG_07217 SPPG_08002
URL FGI
OM
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Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Saccharomycetes)
Yarrowia lipolytica
Yeast soil saprobe
YALI0D26081g YALI0B10846g YALI0B13134g YALI0B13112g YALI0E35112g YALI0E08096g YALI0B13090g YALI0F07040g YALI0B13046g YALI0F01386g YALI0F11825g YALI0F24299g YALI0E12551g
Genolevure
Ascomycota (Eurotiomycetes)
Emericalla nidulans (Aspergillus nidulans)
Soil saprobe
ANI05457 (NoxA) AN0773 AN3208 AN4906 AN6400 AN7518 AN8683 AN7662 AN10893 AN7981 AN9023
FGI
Ascomycota (Eurotiomycetes)
Neosartorya fumigata (Aspergillus fumigatus)
Soil saprobe, human opportunistic pathogen
Afu6g13350 (NoxA) Afu1g14340 Afu3g10820 Afu6g13750 Afu8g01310 Afu1g17270 Afu3g02980 Afu6g02170 Afu6g02820 Afu7g04970 Afu1g16040 Afu5g14940 Afu4g03940 Afu2g01270 Afu8g06210 AfuNA1a AfuNA2a
AspGD
Ascomycota (Eurotiomycetes)
Coccidioides immitis
Soil saprobe, human opportunistic pathogen
CIRG_09773 (Nox1) CIRG_00499 (Nox2) CIRG_08233 CIRG_07686 CIRG_07046 CIRG_09554 CIRG_02582 CIRG_NA1a CIRG_NA2a
FGI
Ascomycota (Eurotiomycetes)
Histoplasma capsulatum
Soil saprobe, human opportunistic pathogen
HCAG_05182 (Nox1) HCAG_01252 (Nox2) HCAG_03430 HCAG_01925 HCAG_02320 HCAG_05045 HCAG_03201 HCAG_01641 HCAG_11619 HCAG_03149 HCAG_07381
FGI
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Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Dothideomycetes)
Cochliobolus heterostrophus
Maize pathogen
CocheC5_1_95484 (Nox1) CocheC5_1_95158 (Nox2) CocheC5_1_117226 (Nox3) CocheC5_1_113323 CocheC5_1_115841 CocheC5_1_18297 CocheC5_1_36266 CocheC5_1_67300 CocheC5_1_67987 CocheC5_1_79855 CocheC5_1_86222 CocheC5_1_98199 CocheC5_1_59673 CocheC5_1_105418 CocheC5_1_96373 CocheC5_1_NA1a CocheC5_1_NA2a
JGI
Ascomycota (Leotiomycetes)
Sclerotinia sclerotiorum
Broad host range plant pathogen
SS1G_05661 (Nox1) SS1G_11172 (Nox2) SS1G_10691 SS1G_03147 SS1G_11881 SS1G_11821 SS1G_14206 SS1G_06988 SS1G_05414 SS1G_06624 SS1G_08043 SS1G_09140
FGI
Ascomycota (Sordariomycetes)
Fusarium verticillioides
Soil saprobe and corn pathogen
FVEG_00444 (Nox1) FVEG_11478 (Nox2) FVEG_00030 FVEG_00787 FVEG_01564 FVEG_01784 FVEG_02200 FVEG_02265 FVEG_07148 FVEG_14005 FVEG_13485 FVEG_05576 FVEG_04694 FVEG_02748 FVEG_08464 FVEG_10346 FVEG_10064 FVEG_12507 FVEG_01628 FVEG_12454 FVEG_NA1a
FGI
Ascomycota (Sordariomycetes)
Trichoderma reesei
Soil saprobe
Trire2_79498 (Nox1) Trire2_81646 (Nox2) Trire2_106936 Trire2_110666 Trire2_111750 Trire2_111893 Trire2_22845 Trire2_23353 Trire2_54144 Trire2_6107 Trire2_61116 Trire2_81096
JGI
(continued on next page)
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Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Sordariomycetes)
Magnaporthe grisea
Rice pathogen
MGG_00750 (Nox1) MGG_06559(Nox2) MGG_08299 (Nox3) MGG_01018.6 MGG_02828.6 MGG_03667.6 MGG_07833.6 MGG_07853.6 MGG_08278.6 MGG_10760.6 MGG_12210.6 MGG_13426.6 MGG_14302.6 MGG_14647.6 MGG_14894.6
FGI
Ascomycota (Sordariomycetes)
Neurospora crassa
Soil saprobe
NCU02110 (Nox1) NCU10775 (Nox2) NCU00023 NCU00829 NCU00876 NCU02009 NCU02020 NCU02278 NCU03868 NCU08194
FGI
Ascomycota (Sordariomycetes)
Podospora anserina
Dung saprobe
Pa_1_2410 (Nox1) Pa_5_9580(Nox2) Pa_1_5020 (Nox3) Pa_5_11970 Pa_7_5660 Pa_5_10230 Pa_1_19630 Pa_1_16410 Pa_1_19550 Pa_4_2910 Pa_7_4470 Pa_1_15510 Pa_5_8960
Genoscope/IGM
Basidiomycota (Ustilaginomycetes)
Ustilago maydis
Maize pathogen
UM00382 UM00838 UM00839 UM01439 UM02395 UM05979 UM02730
FGI
Basidiomycota (Pucciniomycetes)
Puccinia graminis
Wheat pathogen
PGTG_01933 (Nox1) PGTG_04320 (Nox2) PGTG_12719 PGTG_16919 PGTG_01643 PGTG_08246 PGTG_03543 PGTG_00319
FGI
Basidiomycota (Microbotryomycetes)
Sporobolomyces roseus
Yeast, phylloplan saprobe
Sporo1_9097 (Nox1) Sporo1_31671 Sporo1_31662 Sporo1_33553 Sporo1_32130 Sporo1_27372 Sporo1_33967
JGI
Nox and IMR of Eumycetes
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Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Basidiomycota (Tremellomycetes)
Cryptococcus neoformans
Yeast, soil and dropping saprobe, human and bird opportunistic pathogen
CNAG_00876 CNAG_06821 CNAG_06524 CNAG_06976 CNAG_07604 CNAG_03498 CNAG_07770 CNAG_07334
FGI
Basidiomycota (Tremellomycetes)
Tremella mesenterica
Mycoparasite
Treme1_68048 (Nox1) Treme1_32037 (Nox2) Treme1_12876 Treme1_74287 Treme1_58976 Treme1_38393 Treme1_63255 Treme1_32173
JGI
Basidiomycota (Agaricomycetes)
Coprinopsis cinerea
Dung and soil saprobe
CC1G_10525 (Nox1) CC1G_09830 (Nox2) CC1G_00426 CC1G_03087 CC1G_03568 CC1G_08381 CC1G_14424 CC1G_06499 CC1G_15165
FGI
Basidiomycota (Agaricomycetes)
Laccaria bicolor
Mycorhiza
Lacbi1_243586 (Nox1) Lacbi1_173015 (Nox2) Lacbi1_310387 Lacbi1_184285 Lacbi1_306020 Lacbi1_304910 Lacbi1_315189
JGI
URL: AGD: http://agd.vital-it.ch/index.html; AspGD: http://www.aspergillusgenome.org/; FGI: http://www.broadinstitute.org/science/projects/ fungal-genome-initiative/fungal-genome-initiative; Genolevure: http://www.genolevures.org/; Genoscope/IGM: http://podospora.igmors. u-psud.fr; JGI: http://genome.jgi-psf.org/; NCBI: http://www.ncbi.nlm.nih.gov/sites/entrez; OM: http://www.broadinstitute.org/annotation/ genome/multicellularity_project/MultiHome.html; Sanger: http://old.genedb.org/genedb/pombe/; SGD: http://www.yeastgenome.org/ a CDS not annotated in the genome project.
lignin, respectively. In these species several ROS producing enzymes have been implicated in plant biomass degradation, including laccases, GMC oxidoreductases, galactose oxidases, copper radical oxidases (e.g. glyoxal oxidase), quinone reductases, pyranose oxidases and cellobiose dehydrogenases (ten Have & Teunissen 2001; Wesenberg et al. 2003; Martinez et al. 2005; Morel et al. 2009). From one fungus to the other the enzymology of plant biomass degradation appears different. For example, in the white rot Phanerochaete chrysosporium plant biomass degradation relies on a large set of ROS-generating oxidative enzymes that degrade lignin directly or through the activation of small weight mediators, coupled to glycoside hydrolases that break down cellulose (Martinez et al. 2004; Kersten & Cullen 2007). However, P. chrysosporium has no laccase. On the contrary, Pycnoporus cinnabarinus does rely essentially on these enzymes for lignocellulose degradation (Eggert et al. 1996). In the brown rot Postia placenta, the paucity in glycoside hydrolases genes typically found in cellulolytic microbes and the up-regulation of various oxidoreductases suggest that cellulose degradation probably relies on Fenton chemistry in which Fe2þ and oxygen peroxide react to form
hydroxyl radicals, a powerful reactant able to hydrolyze biopolymers (Martinez et al. 2009). Unlike basidiomycetes, ascomycetes, except Xylariales (Pointing et al. 2003), are not thought to be able to degrade lignin. However, the genome sequence of P. anserina, a Sordariales, shows that this species possesses many ROS-generating enzymes endowing this fungus with the ability to degrade lignin (Espagne et al. 2008). Moreover, P. anserina is able to efficiently complete its cycle with sawdust as sole nutrient source, suggesting that it is able to efficiently retrieve nutrients from wood (P.S., pers. obser.). To date, the complete array of fungal enzymes able to produce ROS for signaling development or degrading plant biomass is unknown. Similarly, the respective role of ROS and ROS-generating enzymes in development and/or biomass degradation is not understood. For example, the glo1 enzyme from U. maydis has a glyoxal oxidase activity and generates H2O2, yet it is involved in signaling (Leuthner et al. 2005). Similarly, we reported (Brun et al. 2009) that deletion of the Nox genes of P. anserina results in developmental defect associated with modification of cellulose degradation and with an apparent
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Fig 1 e Nox and IMR tree based on complete sequence alignment. CDS names have been colored according to the phylogeny using the code depicted at the bottom. Fungal Nox and IMR families have been colored arbitrarily to facilitate analysis.
augmentation of ROS production, a phenomenon also observed in M. grisea (Egan et al. 2007) and A. nidulans (Semighini & Harris 2008). The enzymes responsible for increased ROS production are unknown. Preliminary mining of the P. anserina genome suggested that integral membrane reductases (IMRs,
also known as Ferric Reductases or Metal reductases, (Kosman 2003)) could be some of the redox enzymes up-regulated in the P. anserina Nox mutants, as the genome of this species contains ten coding sequences (CDS) with similarity to IMRs (Brun et al. 2009). Like Nox, IMRs oxidize cytoplasmic
Nox and IMR of Eumycetes
NADPH and transfer the electron across the plasma membrane to reduce small molecules, dioxygen in the case of Nox (yielding thus the superoxide anion) and mostly metal (Fe3þ and Cu2þ) in the case of IMRs. However, it has been shown that the ScFRE1 Saccharomyces cerevisiae IMR may reduce other small molecules such as paraquat, albeit inefficiently (Hassett & Kosman 1995). IMRs are similar in sequence to Nox, suggesting a common origin (Dancis et al. 1992; Roman et al. 1993; Shatwell et al. 1996). If the Nox proteins of filamentous fungi have recently been under strong scrutiny, little is known about IMRs in these organisms, which have been essentially studied in the yeasts S. cerevisiae (Dancis et al. 1992; Georgatsou & Alexandraki 1994; Shatwell et al. 1996; Georgatsou & Alexandraki 1999; Yun et al. 2001; Singh et al. 2007), Candida albicans (Hammacott et al. 2000; Knight et al. 2002) and Schizosaccharomyces pombe (Roman et al. 1993). Additional studies on these enzymes have been performed on algae (Allen et al. 2007), plants (Wu et al. 2005; Feng et al. 2006; Mukherjee et al. 2006) and parasites (see Sutak et al. 2008 for a review). Because of their involvement in the generation of Fe2þ and possibly other small reduced molecules, IMRs could participate in plant biomass degradation through Fenton reactions or radical attacks. Additional roles in signaling are possible, as demonstrated for the glyoxal oxidase glo1 of U. maydis. Here, we present the results of genome analysis for the presence of Nox and IMRs in 29 fungal genomes, covering the entire known diversity of the Eumycetes. We report that the genomes of these organisms usually contain several IMR isoforms, belonging to a large array of very divergent families. The evolution of fungal Nox/IMR appears very complex. Importantly, proteins demonstrated as having a metal reductase activity in S. cerevisiae and S. pombe cluster within a restricted set of families, questioning the actual enzymatic activities of the other IMRs.
Materials and methods Fungal genomes and deduced protein sets from complete sequencing projects were searched for the presence of putative Nox and IMR genes by TBLASTN and BLASTP, respectively (Altschul et al. 1990). Because in many instances automatic annotation may not give accurate intron splicing boundaries, each putative IMR gene was manually re-annotated (Table 1). A few genes were incomplete due to gaps in the genomic sequences. Additional genes not called during the annotation were discovered (Table 1). The deduced protein sequences for complete bona fide genes were then aligned with the MAFFT algorithm (Katoh et al. 2005) using the L-INS-i parameters recommended for sequences with one conserved domain and long gaps, (Supplemental Fig 1). The alignment was then manually edited to remove poorly conserved regions (Supplemental Fig 2). Trees for the complete and edited proteins were constructed and bootstrapped (100 replicates) with PhyML with the following parameters (data type: 1, sequence format: i, number of data sets: 1, number of bootstrapped data sets: 100, substitution model: WAG, prop. invariable sites: 0.0, number categories: 4, gamma parameter: 1.0, starting tree optimized topology: BIONJ, optimized branch lengths: y and rate parameters: y) (Guindon & Gascuel 2003). Trees were visualized with the iToL server (Letunic & Bork 2007).
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Results and discussion Preliminary analysis of available fungal genome sequences by BLAST (Altschul et al. 1990) and FUNGIpath (Grossetete et al. 2010) suggested that fungi are endowed with many isoforms of Nox and IMR genes (often more than 10 per genomes). We thus focused our analysis on 29 species that would cover the whole range of fungal evolution (Table 1). These live either as yeast or mycelium and have diverse lifestyles (Table 1). As seen in Table 1, all investigated fungi are endowed with at least one IMR gene, while some lack Nox genes (Lalucque & Silar 2003). S. pombe has the simplest complement of Nox/IMR genes with only two IMR genes, including the previously characterized Frp1 IMR gene (Roman et al. 1993). At the other end of the spectrum, Fusarium verticillioides has 19 IMR and two Nox genes. There seems to be no obvious correlation between the number of Nox/IMR and the lifestyle (Table 1). Of interest is the presence in the choanoflagellate Monosiga brevicollis of one Nox (Monbr1_33523) and one IMR (Monbr1_37160). IMR are not found in animals such as Trichoplax adherens, Nematostella vectensis (a sea anemone), Drosophila melanogaster, Caenorhabiditis elegans and Human. They have thus been specifically lost in the metazoan lineage. In total, 276 fungal proteins were used for phylogenetic analysis. The 276 coding sequences (CDS) along with representative Nox and IMRs from other phyla (animals, plants and various protists) were aligned and manually edited to remove poorly aligned regions. Phylogenetic trees on complete and edited protein alignments were then constructed by maximum likelihood. Both complete and edited version yielded similar trees that permit to delimit Nox and IMR families with high statistical confidence (Fig 1 and Supplemental Fig 3). However the branching order of the different families changed between the two analyses, emphasizing the large diversity of these enzymes and precluding the elucidation of the evolution of the various Nox and IMRs. As seen in Fig 1, Nox and IMR enzymes are separated with nearly 100 % confidence, confirming that IMRs and Nox are different proteins (DeLeo et al. 1999; Kawahara et al. 2007). Presently, three Nox isoforms have been described in fungi: Nox1/NoxA, Nox2/NoxB and Nox3/NoxC (Lara-Ortiz et al. 2003). These three families are recovered in both our analyses with 100 % confidence (Fig 1). Interestingly, Spizellomyces punctatus is endowed with two CDS (SPPG_08002 and SPPG_05133) and Allomyces macrogynus one CDS (AMAG_11331.1) that cluster with the NOX enzymes and that do not clearly belong to the three previously defined families. Domain analysis of the CDS with Interproscan (Hunter et al. 2009) reveals that the three CDS possess the NAD, FAD and haem binding domains, always found in Nox. SPPG_08002 and AMAG_11331.1 contain calcium binding sites (EF-hand) in the N-terminus of the protein, as observed for the Nox3 isoforms of ascomycetes, the mammalian Nox5 isoforms and the plant enzymes. These proteins may thus be distant relatives of the other fungal Nox3 enzymes, in line with the high divergence between the Ascomycota, the Blastocladiomycota and the Chytridiomycota. On the contrary, SPPG_05133 lacks EF-hand domain and has a plasma membrane targeting signal followed by a long N-terminus extension. This N-terminus is highly
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similar to proteins from various animals (e.g. 44 % identical with BRAFLDRAFT_120072 from Branchiostoma floridae) and protozoa (e.g. 41 % identical with XP_002673156 from Naegleria gruberi). No CDS containing this domain is found in the other Eumycetes. Provided that SPPG_05133 is not a sequencing/annotation artifact, it may thus define a novel family of Nox (Nox4) resulting from the fusion of a typical Nox coding sequence with another domain of unknown activity. Supplementary Table 1 describes the complement of Nox and NoxR genes found in fungal genomes. NoxR is a regulator of Nox genes (Takemoto et al. 2006) and is surprisingly found in fungi lacking Nox genes, i.e. the Mucoromycotina and Yarrowia lipolytica (Takemoto et al. 2007). A possible explanation is that these NoxR genes activate some IMRs. Fungal IMRs are more complex than Nox as they can be classified into at least 24 families (IeXXIV; Fig 1). All these families are well separated from IMRs identified in other phylogenetic groups, i.e. plants and protozoa. Some contain a single member (families XV and XXIV), while others contain many (family V has 24 representatives). Likely, as more fungi are analyzed, the singleton will be rejoined by other members. For example, analysis of additional fungal genomes shows that F. verticillioides CDS FEVG_NA1, the single representative of family XXIV analyzed here, has orthologues in Fusarium oxysporum and Trichoderma virens; a pseudogene is also present in Trichoderma atroviride. What these IMR families reflect is not clear. Indeed, some are found in only one clade of fungi: families I and XVII are found only in Saccharomycotina, families VI, XI and XVI only in Pezizomycotina, family IV only in Ustilaginomycotina, family XIX only in Taphrinomycotina, etc. These families could thus result from the diversification in the various groups of fungi of an ancestral gene. However some families are found in both Ascomycota and Basidiomycota, such as families II, III and V. Yet, none is present in the whole diversity of fungi. From the trees of Figs 1 and 2, there is no clear evidence of horizontal gene transfer. Each fungal species has its own set of proteins belonging to particular families, even for closely related species. P. anserina, M. grisea and N. crassa are three Sordariomycetes. P. anserina has ten IMRs (two from families III, VI and VII and one from families V, VIII, IX and XI), N. crassa has eight IMRs (two from families VI and VII and one from families V, VIII, IX and XI) and M. grisea has 12 IMRs (three from family III, two from family VII, VIII and XVI, one from families V, VI and XI). Overall, the data suggest that IMR distribution is the result from a complex set of gene gains by duplication and gene losses by deletion and
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mutations (we have detected several pseudogenes during our manual gene annotation). A similar situation is not unprecedented and is found for other protein families (Espagne et al. 2008). Fungal IMRs have so far been biochemically or genetically characterized in two Saccharomycotina (S. cerevisiae, C. albicans) and one Taphrinomycotina (S. pombe) (Kosman 2003). Interestingly, the ScFre1 to ScFRE6 S. cerevisiae isoforms induced by metal deficiency and whose activities are well characterized all belong to family I (Dancis et al. 1992; Georgatsou & Alexandraki 1994; Shatwell et al. 1996; Georgatsou & Alexandraki 1999; Yun et al. 2001; Singh et al. 2007). The CFL1 (Hammacott et al. 2000) and CFL95 (Knight et al. 2002) proteins from C. albicans also belong to family I. The two S. pombe proteins define family XIX. Although a reductase activity can be predicted for the proteins of the other 22 families based on the protein domains, the actual electron acceptors for these proteins are not known. It is therefore possible that molecules other than dioxygen and metals are the true electron acceptors for some of these proteins, as it has been shown that ScFRE1 can reduce organic compounds, such as paraquat (Hassett & Kosman 1995). Additionally, these proteins could be involved in developmental processes, since the S. cerevisiae mutants lacking ScFRE8 have defective bud morphology (Watanabe et al. 2009). ScFRE8, along with other IMRs from Saccharomycotina, define IMR family XVII. To gain some insight onto the potential roles of the IMRs of the other families, we analyzed the expression profiles of the P. anserina and N. crassa proteins, as microarray data are available for these two fungi. N. crassa global transcriptome changes are available during colony development/conidiation (Kasuga & Glass 2008), and during degradation of plant cell wall (Tian et al. 2009). Data are available for all IMRs and Nox1, but lack for Nox2. As seen in Fig 2A, while Nox1 expression is not affected by the carbon source, six out of eight N. crassa IMRs are induced during growth on avicel (microcrystalline cellulose) and ground Miscanthus stem, as compared to growth on sucrose, a feature compatible with a role for IMRs in plant biomass degradation. Similarly, a developmental role in N. crassa is possible for IMRs as most are regulated during N. crassa colony development (Fig 2B). Five are up-regulated after 3 h of growth and one is down-regulated during conidiation (21 and 27 h of growth). P. anserina global transcriptome changes (Bidard et al. 2010) are available for colony development (F.B. and P.S., unpubl.), fruiting body
Fig 2 e IMR gene expression profiles in N. crassa and P. anserina. (A) Expression profile of N. crassa IMR genes at 16 h of growth on minimal medium containing sucrose as carbon source (MM 16 h), compared to growth on avicel and Miscanthus at various times (16 h, 40 h, 5 d and 10 d). Data are taken from Tian et al. (2009). (B) Expression profile of N. crassa IMR genes during colony development corresponding to 1 h, 3 h, 9 h, 15 h, 21 h and 27 h of growth. At the two last time points, N. crassa differentiates conidias. Data are taken from Kasuga & Glass (2008). Because NCU02020 has a much higher expression level than the other IMR genes, it is depicted by itself in the insert. (C) Expression profile of P. anserina IMR genes during colony development at 24 h, 48 h and 72 h of growth, during fruiting body maturation 0 h, 12 h, 24 h and 96 h after maturation and in the PaNox1 null mutant grown for 24 h. After 72 h of mycelium growth P. anserina gametes are formed and await fertilization. After 96 h of maturation, fruiting bodies are ripe and start ejecting ascospores. Because Pa_7_5660 has a much higher expression level, it is depicted in the insert. N. crassa transcriptomic data are the mean of SNR ((signal-background)/background standard deviation of the biological replicates). P. anserina transcriptomic data are mean intensity of four biological replicates.
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(perithecium) maturation (F.B. and V. Berteaux-Lecellier, unpubl.) and the Nox1 mutant (Brun et al. 2009). Nox genes are not differentially regulated in P. anserina (Brun et al. 2009), however differential expression of some IMR genes during develoment is evidenced in P. anserina. As seen in Fig 2C, four IMRs are up-regulated during P. anserina colony development. Similarly, five IMRs are down-regulated during fruiting body development, two of them (Pa_1_16410 and Pa_5_11970) having their expression increased again during the late stages of perithecium maturation. Finally, three IMRs have their expression increased in the Nox1 mutants, which have been shown to degrade cellulose more efficiently than wild type and to produce more ROS (Malagnac et al. 2004; Brun et al. 2009). The IMRs differentially regulated in N. crassa and P. anserina may or may not belong to the same family, a feature easily accounted for by the very different culture conditions used for the two fungi.
Conclusion Fungal genomes contain several IMR genes. These can be classified into at least 24 families, underscoring the high diversity of these enzymes in Eumycetes. Many are differentially regulated by the carbon source present in the growth medium and/ or during colony and fruiting body development. Those that have been genetically or biochemically investigated belong to only two of the 24 families. We therefore advocate performing targeted gene deletion and biochemical characterization of representative IMRs belonging to the other 22 families not yet investigated to gain insight into their cellular roles.
Acknowledgments This work was supported by grant ANR-05-Blan-0385. Ibtissem Grissa is the recipient of an ATER fellowship from Universite´ of Paris Diderot Paris 7.
Supplemental data Supplementary data associated with this article can be found in online version at doi:10.1016/j.funbio.2010.07.002.
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journal homepage: www.elsevier.com/locate/funbio
The Nox/Ferric reductase/Ferric reductase-like families of Eumycetes Ibtissem GRISSAa,b,c, Fre´de´rique BIDARDb,c, Pierre GROGNETa,b,c, Sandrine GROSSETETEb,c, Philippe SILARa,b,c,* a
Univ Denis Diderot, UFR Sciences du Vivant, 75013 Paris, France Univ Paris-Sud, Institut de Ge´ne´tique et Microbiologie, UMR 8621, 91405 Orsay cedex, France c CNRS, Institut de Ge´ne´tique et Microbiologie, UMR 8621, 91405 Orsay cedex, France b
article info
abstract
Article history:
Reactive Oxygen Species (ROS) are involved in plant biomass degradation by fungi and
Received 19 April 2010
development of fungal structures. While the ROS-generating NADPH oxidases from
Received in revised form
filamentous fungi are under strong scrutiny, much less is known about the related integral
5 July 2010
Membrane (or Ferric) Reductases (IMRs). Here, we present a survey of these enzymes in 29
Accepted 6 July 2010
fungal genomes covering the entire available range of fungal diversity. IMRs are present in
Available online 14 July 2010
all fungal genomes. They can be classified into at least 24 families, underscoring the high
Corresponding Editor: Michael Lorenz
diversity of these enzymes. Some are differentially regulated during colony or fruiting body development, as well as by the nature of the carbon source of the growth medium. Impor-
Keywords:
tantly, functional characterization of IMRs has been made on proteins belonging to only
Ferric reductase
two families, while nothing or very little is known about the proteins of the other 22
Fungal genomes
families.
NADPH oxidase
ª 2010 The British Mycological Society. Published by Elsevier Ltd. All rights reserved.
Reactive Oxygen Species
Introduction Reactive Oxygen Species (ROS) have been implicated in two major aspects of fungal biology. First, they participate in the degradation of the plant biomass, especially lignin lysis (ten Have & Teunissen 2001; Wesenberg et al. 2003; Martinez et al. 2005; Morel et al. 2009). Second, they are involved in signaling several developmental processes, including fruiting body maturation (Lara-Ortiz et al. 2003; Malagnac et al. 2004), spore germination (Malagnac et al. 2004; Cano-Dominguez et al. 2008; Lambou et al. 2008), mycelium growth (Leuthner et al. 2005; Semighini & Harris 2008), mutualistic symbiosis (Tanaka et al. 2006) and differentiation of appressorium and
appressorium-like structures (Egan et al. 2007; Segmuller et al. 2008; Brun et al. 2009). To date, the role of ROS in development has been mostly studied in ascomycetes, such as Aspergillus nidulans, Neurospora crassa, Epichloe festucae, Botrytis cinerea, Magnaporthe grisea and Podospora anserina. In these species, the major ROS producing enzymes evidenced as signaling development are NADPH oxidases (Nox, see Aguirre et al. 2005; Takemoto et al. 2007 for review), however a glyoxal oxidase (glo1) has also been shown to be necessary for normal hyphal morphology and filamentous growth in the basidiomycete Ustilago maydis (Leuthner et al. 2005). Plant biomass degradation is mostly studied in basidiomycetes, such as white and brown rots, which are able or not able to efficiently degrade
* Corresponding author. Institut de Ge´ne´tique et Microbiologie, UMR 8621 CNRS UPS, 91405 Orsay cedex, France. Tel.: þ33 1 69 15 46 58; fax: þ33 1 69 15 70 06. E-mail address: [email protected] 1878-6146/$ e see front matter ª 2010 The British Mycological Society. Published by Elsevier Ltd. All rights reserved. doi:10.1016/j.funbio.2010.07.002
Nox and IMR of Eumycetes
767
Table 1 e Fungal CDS used in this study. Species
Lifestyle
Nox and IMR
Chytridiomycota (Chytridiomycetes)
Batrachochytrium dendrobatidis
Frog pathogen
BDEG_06864 (Nox1) BDEG_07125 (Nox2) BDEG_01882 BDEG_02345 BDEG_07017
Chytridiomycota (Chytridiomycetes)
Spizellomyces punctatus
Soil saprobe
Blastocladiomycota (Blastocladiomycetes)
Allomyces macrogynus
Pond saprobe
AMAG_13933.1 (Nox1) AMAG_15568.1 (Nox2) AMAG_11331.1 AMAG_07049.1 AMAG_NA1a AMAG_NA2a
OM
Mucoromycotina
Mucor circinelloides
Soil saprobe
Mucci1_77308 Mucci1_95952 Mucci1_85232
JGI
Mucoromycotina
Phycomyces blakesleeanus
Soil saprobe
Phybl1_77767 Phybl1_76888
JGI
Mucoromycotina
Rhizopus oryzae
Soil saprobe
RO3G_05460 RO3G_04617 RO3G_10468 RO3G_13599
FGI
Ascomycota (Schizosaccharomycetes)
Schizosaccharomyces pombe
Yeast saprobe
Sp_Frp1 CAA17033 ¼ SPBC947.05c
NCBI/Sanger
Ascomycota (Saccharomycetes)
Ashbya gossypii
Yeast-like, cotton pathogen
NM_212056 NM_208455 NM_209529 NM_211017 NM_208618
AGD
Ascomycota (Saccharomycetes)
Candida albicans SC5314
Human commensal and pathogen
orf19.1264 orf19.1263 (¼CFL1) orf19.1415 (¼CFL95) orf19.1270 orf19.5634 orf19.1930 orf19.1932 orf19.701 orf19.6138 orf19.1844 orf19.3538 orf19.2312 orf19.7077 orf19.7112 orf19.867 orf19.4843
FGI
Ascomycota (Saccharomycetes)
Saccharomyces cerevisiae
Yeast saprobe
ScFRE1 ScFRE2 ScFRE3 ScFRE4 ScFRE5 ScFRE6 ScFRE7 ScFRE8 YGL160W
SGD
BDEG_03995 SPPG_07581 (Nox1) SPPG_07607 (Nox2) SPPG_00862 SPPG_0462 SPPG_05133 SPPG_06478 SPPG_07217 SPPG_08002
URL FGI
OM
768
I. Grissa et al.
Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Saccharomycetes)
Yarrowia lipolytica
Yeast soil saprobe
YALI0D26081g YALI0B10846g YALI0B13134g YALI0B13112g YALI0E35112g YALI0E08096g YALI0B13090g YALI0F07040g YALI0B13046g YALI0F01386g YALI0F11825g YALI0F24299g YALI0E12551g
Genolevure
Ascomycota (Eurotiomycetes)
Emericalla nidulans (Aspergillus nidulans)
Soil saprobe
ANI05457 (NoxA) AN0773 AN3208 AN4906 AN6400 AN7518 AN8683 AN7662 AN10893 AN7981 AN9023
FGI
Ascomycota (Eurotiomycetes)
Neosartorya fumigata (Aspergillus fumigatus)
Soil saprobe, human opportunistic pathogen
Afu6g13350 (NoxA) Afu1g14340 Afu3g10820 Afu6g13750 Afu8g01310 Afu1g17270 Afu3g02980 Afu6g02170 Afu6g02820 Afu7g04970 Afu1g16040 Afu5g14940 Afu4g03940 Afu2g01270 Afu8g06210 AfuNA1a AfuNA2a
AspGD
Ascomycota (Eurotiomycetes)
Coccidioides immitis
Soil saprobe, human opportunistic pathogen
CIRG_09773 (Nox1) CIRG_00499 (Nox2) CIRG_08233 CIRG_07686 CIRG_07046 CIRG_09554 CIRG_02582 CIRG_NA1a CIRG_NA2a
FGI
Ascomycota (Eurotiomycetes)
Histoplasma capsulatum
Soil saprobe, human opportunistic pathogen
HCAG_05182 (Nox1) HCAG_01252 (Nox2) HCAG_03430 HCAG_01925 HCAG_02320 HCAG_05045 HCAG_03201 HCAG_01641 HCAG_11619 HCAG_03149 HCAG_07381
FGI
(continued on next page)
Nox and IMR of Eumycetes
769
Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Dothideomycetes)
Cochliobolus heterostrophus
Maize pathogen
CocheC5_1_95484 (Nox1) CocheC5_1_95158 (Nox2) CocheC5_1_117226 (Nox3) CocheC5_1_113323 CocheC5_1_115841 CocheC5_1_18297 CocheC5_1_36266 CocheC5_1_67300 CocheC5_1_67987 CocheC5_1_79855 CocheC5_1_86222 CocheC5_1_98199 CocheC5_1_59673 CocheC5_1_105418 CocheC5_1_96373 CocheC5_1_NA1a CocheC5_1_NA2a
JGI
Ascomycota (Leotiomycetes)
Sclerotinia sclerotiorum
Broad host range plant pathogen
SS1G_05661 (Nox1) SS1G_11172 (Nox2) SS1G_10691 SS1G_03147 SS1G_11881 SS1G_11821 SS1G_14206 SS1G_06988 SS1G_05414 SS1G_06624 SS1G_08043 SS1G_09140
FGI
Ascomycota (Sordariomycetes)
Fusarium verticillioides
Soil saprobe and corn pathogen
FVEG_00444 (Nox1) FVEG_11478 (Nox2) FVEG_00030 FVEG_00787 FVEG_01564 FVEG_01784 FVEG_02200 FVEG_02265 FVEG_07148 FVEG_14005 FVEG_13485 FVEG_05576 FVEG_04694 FVEG_02748 FVEG_08464 FVEG_10346 FVEG_10064 FVEG_12507 FVEG_01628 FVEG_12454 FVEG_NA1a
FGI
Ascomycota (Sordariomycetes)
Trichoderma reesei
Soil saprobe
Trire2_79498 (Nox1) Trire2_81646 (Nox2) Trire2_106936 Trire2_110666 Trire2_111750 Trire2_111893 Trire2_22845 Trire2_23353 Trire2_54144 Trire2_6107 Trire2_61116 Trire2_81096
JGI
(continued on next page)
770
I. Grissa et al.
Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Ascomycota (Sordariomycetes)
Magnaporthe grisea
Rice pathogen
MGG_00750 (Nox1) MGG_06559(Nox2) MGG_08299 (Nox3) MGG_01018.6 MGG_02828.6 MGG_03667.6 MGG_07833.6 MGG_07853.6 MGG_08278.6 MGG_10760.6 MGG_12210.6 MGG_13426.6 MGG_14302.6 MGG_14647.6 MGG_14894.6
FGI
Ascomycota (Sordariomycetes)
Neurospora crassa
Soil saprobe
NCU02110 (Nox1) NCU10775 (Nox2) NCU00023 NCU00829 NCU00876 NCU02009 NCU02020 NCU02278 NCU03868 NCU08194
FGI
Ascomycota (Sordariomycetes)
Podospora anserina
Dung saprobe
Pa_1_2410 (Nox1) Pa_5_9580(Nox2) Pa_1_5020 (Nox3) Pa_5_11970 Pa_7_5660 Pa_5_10230 Pa_1_19630 Pa_1_16410 Pa_1_19550 Pa_4_2910 Pa_7_4470 Pa_1_15510 Pa_5_8960
Genoscope/IGM
Basidiomycota (Ustilaginomycetes)
Ustilago maydis
Maize pathogen
UM00382 UM00838 UM00839 UM01439 UM02395 UM05979 UM02730
FGI
Basidiomycota (Pucciniomycetes)
Puccinia graminis
Wheat pathogen
PGTG_01933 (Nox1) PGTG_04320 (Nox2) PGTG_12719 PGTG_16919 PGTG_01643 PGTG_08246 PGTG_03543 PGTG_00319
FGI
Basidiomycota (Microbotryomycetes)
Sporobolomyces roseus
Yeast, phylloplan saprobe
Sporo1_9097 (Nox1) Sporo1_31671 Sporo1_31662 Sporo1_33553 Sporo1_32130 Sporo1_27372 Sporo1_33967
JGI
Nox and IMR of Eumycetes
771
Table 1 e (continued) Species
Lifestyle
Nox and IMR
URL
Basidiomycota (Tremellomycetes)
Cryptococcus neoformans
Yeast, soil and dropping saprobe, human and bird opportunistic pathogen
CNAG_00876 CNAG_06821 CNAG_06524 CNAG_06976 CNAG_07604 CNAG_03498 CNAG_07770 CNAG_07334
FGI
Basidiomycota (Tremellomycetes)
Tremella mesenterica
Mycoparasite
Treme1_68048 (Nox1) Treme1_32037 (Nox2) Treme1_12876 Treme1_74287 Treme1_58976 Treme1_38393 Treme1_63255 Treme1_32173
JGI
Basidiomycota (Agaricomycetes)
Coprinopsis cinerea
Dung and soil saprobe
CC1G_10525 (Nox1) CC1G_09830 (Nox2) CC1G_00426 CC1G_03087 CC1G_03568 CC1G_08381 CC1G_14424 CC1G_06499 CC1G_15165
FGI
Basidiomycota (Agaricomycetes)
Laccaria bicolor
Mycorhiza
Lacbi1_243586 (Nox1) Lacbi1_173015 (Nox2) Lacbi1_310387 Lacbi1_184285 Lacbi1_306020 Lacbi1_304910 Lacbi1_315189
JGI
URL: AGD: http://agd.vital-it.ch/index.html; AspGD: http://www.aspergillusgenome.org/; FGI: http://www.broadinstitute.org/science/projects/ fungal-genome-initiative/fungal-genome-initiative; Genolevure: http://www.genolevures.org/; Genoscope/IGM: http://podospora.igmors. u-psud.fr; JGI: http://genome.jgi-psf.org/; NCBI: http://www.ncbi.nlm.nih.gov/sites/entrez; OM: http://www.broadinstitute.org/annotation/ genome/multicellularity_project/MultiHome.html; Sanger: http://old.genedb.org/genedb/pombe/; SGD: http://www.yeastgenome.org/ a CDS not annotated in the genome project.
lignin, respectively. In these species several ROS producing enzymes have been implicated in plant biomass degradation, including laccases, GMC oxidoreductases, galactose oxidases, copper radical oxidases (e.g. glyoxal oxidase), quinone reductases, pyranose oxidases and cellobiose dehydrogenases (ten Have & Teunissen 2001; Wesenberg et al. 2003; Martinez et al. 2005; Morel et al. 2009). From one fungus to the other the enzymology of plant biomass degradation appears different. For example, in the white rot Phanerochaete chrysosporium plant biomass degradation relies on a large set of ROS-generating oxidative enzymes that degrade lignin directly or through the activation of small weight mediators, coupled to glycoside hydrolases that break down cellulose (Martinez et al. 2004; Kersten & Cullen 2007). However, P. chrysosporium has no laccase. On the contrary, Pycnoporus cinnabarinus does rely essentially on these enzymes for lignocellulose degradation (Eggert et al. 1996). In the brown rot Postia placenta, the paucity in glycoside hydrolases genes typically found in cellulolytic microbes and the up-regulation of various oxidoreductases suggest that cellulose degradation probably relies on Fenton chemistry in which Fe2þ and oxygen peroxide react to form
hydroxyl radicals, a powerful reactant able to hydrolyze biopolymers (Martinez et al. 2009). Unlike basidiomycetes, ascomycetes, except Xylariales (Pointing et al. 2003), are not thought to be able to degrade lignin. However, the genome sequence of P. anserina, a Sordariales, shows that this species possesses many ROS-generating enzymes endowing this fungus with the ability to degrade lignin (Espagne et al. 2008). Moreover, P. anserina is able to efficiently complete its cycle with sawdust as sole nutrient source, suggesting that it is able to efficiently retrieve nutrients from wood (P.S., pers. obser.). To date, the complete array of fungal enzymes able to produce ROS for signaling development or degrading plant biomass is unknown. Similarly, the respective role of ROS and ROS-generating enzymes in development and/or biomass degradation is not understood. For example, the glo1 enzyme from U. maydis has a glyoxal oxidase activity and generates H2O2, yet it is involved in signaling (Leuthner et al. 2005). Similarly, we reported (Brun et al. 2009) that deletion of the Nox genes of P. anserina results in developmental defect associated with modification of cellulose degradation and with an apparent
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Fig 1 e Nox and IMR tree based on complete sequence alignment. CDS names have been colored according to the phylogeny using the code depicted at the bottom. Fungal Nox and IMR families have been colored arbitrarily to facilitate analysis.
augmentation of ROS production, a phenomenon also observed in M. grisea (Egan et al. 2007) and A. nidulans (Semighini & Harris 2008). The enzymes responsible for increased ROS production are unknown. Preliminary mining of the P. anserina genome suggested that integral membrane reductases (IMRs,
also known as Ferric Reductases or Metal reductases, (Kosman 2003)) could be some of the redox enzymes up-regulated in the P. anserina Nox mutants, as the genome of this species contains ten coding sequences (CDS) with similarity to IMRs (Brun et al. 2009). Like Nox, IMRs oxidize cytoplasmic
Nox and IMR of Eumycetes
NADPH and transfer the electron across the plasma membrane to reduce small molecules, dioxygen in the case of Nox (yielding thus the superoxide anion) and mostly metal (Fe3þ and Cu2þ) in the case of IMRs. However, it has been shown that the ScFRE1 Saccharomyces cerevisiae IMR may reduce other small molecules such as paraquat, albeit inefficiently (Hassett & Kosman 1995). IMRs are similar in sequence to Nox, suggesting a common origin (Dancis et al. 1992; Roman et al. 1993; Shatwell et al. 1996). If the Nox proteins of filamentous fungi have recently been under strong scrutiny, little is known about IMRs in these organisms, which have been essentially studied in the yeasts S. cerevisiae (Dancis et al. 1992; Georgatsou & Alexandraki 1994; Shatwell et al. 1996; Georgatsou & Alexandraki 1999; Yun et al. 2001; Singh et al. 2007), Candida albicans (Hammacott et al. 2000; Knight et al. 2002) and Schizosaccharomyces pombe (Roman et al. 1993). Additional studies on these enzymes have been performed on algae (Allen et al. 2007), plants (Wu et al. 2005; Feng et al. 2006; Mukherjee et al. 2006) and parasites (see Sutak et al. 2008 for a review). Because of their involvement in the generation of Fe2þ and possibly other small reduced molecules, IMRs could participate in plant biomass degradation through Fenton reactions or radical attacks. Additional roles in signaling are possible, as demonstrated for the glyoxal oxidase glo1 of U. maydis. Here, we present the results of genome analysis for the presence of Nox and IMRs in 29 fungal genomes, covering the entire known diversity of the Eumycetes. We report that the genomes of these organisms usually contain several IMR isoforms, belonging to a large array of very divergent families. The evolution of fungal Nox/IMR appears very complex. Importantly, proteins demonstrated as having a metal reductase activity in S. cerevisiae and S. pombe cluster within a restricted set of families, questioning the actual enzymatic activities of the other IMRs.
Materials and methods Fungal genomes and deduced protein sets from complete sequencing projects were searched for the presence of putative Nox and IMR genes by TBLASTN and BLASTP, respectively (Altschul et al. 1990). Because in many instances automatic annotation may not give accurate intron splicing boundaries, each putative IMR gene was manually re-annotated (Table 1). A few genes were incomplete due to gaps in the genomic sequences. Additional genes not called during the annotation were discovered (Table 1). The deduced protein sequences for complete bona fide genes were then aligned with the MAFFT algorithm (Katoh et al. 2005) using the L-INS-i parameters recommended for sequences with one conserved domain and long gaps, (Supplemental Fig 1). The alignment was then manually edited to remove poorly conserved regions (Supplemental Fig 2). Trees for the complete and edited proteins were constructed and bootstrapped (100 replicates) with PhyML with the following parameters (data type: 1, sequence format: i, number of data sets: 1, number of bootstrapped data sets: 100, substitution model: WAG, prop. invariable sites: 0.0, number categories: 4, gamma parameter: 1.0, starting tree optimized topology: BIONJ, optimized branch lengths: y and rate parameters: y) (Guindon & Gascuel 2003). Trees were visualized with the iToL server (Letunic & Bork 2007).
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Results and discussion Preliminary analysis of available fungal genome sequences by BLAST (Altschul et al. 1990) and FUNGIpath (Grossetete et al. 2010) suggested that fungi are endowed with many isoforms of Nox and IMR genes (often more than 10 per genomes). We thus focused our analysis on 29 species that would cover the whole range of fungal evolution (Table 1). These live either as yeast or mycelium and have diverse lifestyles (Table 1). As seen in Table 1, all investigated fungi are endowed with at least one IMR gene, while some lack Nox genes (Lalucque & Silar 2003). S. pombe has the simplest complement of Nox/IMR genes with only two IMR genes, including the previously characterized Frp1 IMR gene (Roman et al. 1993). At the other end of the spectrum, Fusarium verticillioides has 19 IMR and two Nox genes. There seems to be no obvious correlation between the number of Nox/IMR and the lifestyle (Table 1). Of interest is the presence in the choanoflagellate Monosiga brevicollis of one Nox (Monbr1_33523) and one IMR (Monbr1_37160). IMR are not found in animals such as Trichoplax adherens, Nematostella vectensis (a sea anemone), Drosophila melanogaster, Caenorhabiditis elegans and Human. They have thus been specifically lost in the metazoan lineage. In total, 276 fungal proteins were used for phylogenetic analysis. The 276 coding sequences (CDS) along with representative Nox and IMRs from other phyla (animals, plants and various protists) were aligned and manually edited to remove poorly aligned regions. Phylogenetic trees on complete and edited protein alignments were then constructed by maximum likelihood. Both complete and edited version yielded similar trees that permit to delimit Nox and IMR families with high statistical confidence (Fig 1 and Supplemental Fig 3). However the branching order of the different families changed between the two analyses, emphasizing the large diversity of these enzymes and precluding the elucidation of the evolution of the various Nox and IMRs. As seen in Fig 1, Nox and IMR enzymes are separated with nearly 100 % confidence, confirming that IMRs and Nox are different proteins (DeLeo et al. 1999; Kawahara et al. 2007). Presently, three Nox isoforms have been described in fungi: Nox1/NoxA, Nox2/NoxB and Nox3/NoxC (Lara-Ortiz et al. 2003). These three families are recovered in both our analyses with 100 % confidence (Fig 1). Interestingly, Spizellomyces punctatus is endowed with two CDS (SPPG_08002 and SPPG_05133) and Allomyces macrogynus one CDS (AMAG_11331.1) that cluster with the NOX enzymes and that do not clearly belong to the three previously defined families. Domain analysis of the CDS with Interproscan (Hunter et al. 2009) reveals that the three CDS possess the NAD, FAD and haem binding domains, always found in Nox. SPPG_08002 and AMAG_11331.1 contain calcium binding sites (EF-hand) in the N-terminus of the protein, as observed for the Nox3 isoforms of ascomycetes, the mammalian Nox5 isoforms and the plant enzymes. These proteins may thus be distant relatives of the other fungal Nox3 enzymes, in line with the high divergence between the Ascomycota, the Blastocladiomycota and the Chytridiomycota. On the contrary, SPPG_05133 lacks EF-hand domain and has a plasma membrane targeting signal followed by a long N-terminus extension. This N-terminus is highly
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similar to proteins from various animals (e.g. 44 % identical with BRAFLDRAFT_120072 from Branchiostoma floridae) and protozoa (e.g. 41 % identical with XP_002673156 from Naegleria gruberi). No CDS containing this domain is found in the other Eumycetes. Provided that SPPG_05133 is not a sequencing/annotation artifact, it may thus define a novel family of Nox (Nox4) resulting from the fusion of a typical Nox coding sequence with another domain of unknown activity. Supplementary Table 1 describes the complement of Nox and NoxR genes found in fungal genomes. NoxR is a regulator of Nox genes (Takemoto et al. 2006) and is surprisingly found in fungi lacking Nox genes, i.e. the Mucoromycotina and Yarrowia lipolytica (Takemoto et al. 2007). A possible explanation is that these NoxR genes activate some IMRs. Fungal IMRs are more complex than Nox as they can be classified into at least 24 families (IeXXIV; Fig 1). All these families are well separated from IMRs identified in other phylogenetic groups, i.e. plants and protozoa. Some contain a single member (families XV and XXIV), while others contain many (family V has 24 representatives). Likely, as more fungi are analyzed, the singleton will be rejoined by other members. For example, analysis of additional fungal genomes shows that F. verticillioides CDS FEVG_NA1, the single representative of family XXIV analyzed here, has orthologues in Fusarium oxysporum and Trichoderma virens; a pseudogene is also present in Trichoderma atroviride. What these IMR families reflect is not clear. Indeed, some are found in only one clade of fungi: families I and XVII are found only in Saccharomycotina, families VI, XI and XVI only in Pezizomycotina, family IV only in Ustilaginomycotina, family XIX only in Taphrinomycotina, etc. These families could thus result from the diversification in the various groups of fungi of an ancestral gene. However some families are found in both Ascomycota and Basidiomycota, such as families II, III and V. Yet, none is present in the whole diversity of fungi. From the trees of Figs 1 and 2, there is no clear evidence of horizontal gene transfer. Each fungal species has its own set of proteins belonging to particular families, even for closely related species. P. anserina, M. grisea and N. crassa are three Sordariomycetes. P. anserina has ten IMRs (two from families III, VI and VII and one from families V, VIII, IX and XI), N. crassa has eight IMRs (two from families VI and VII and one from families V, VIII, IX and XI) and M. grisea has 12 IMRs (three from family III, two from family VII, VIII and XVI, one from families V, VI and XI). Overall, the data suggest that IMR distribution is the result from a complex set of gene gains by duplication and gene losses by deletion and
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mutations (we have detected several pseudogenes during our manual gene annotation). A similar situation is not unprecedented and is found for other protein families (Espagne et al. 2008). Fungal IMRs have so far been biochemically or genetically characterized in two Saccharomycotina (S. cerevisiae, C. albicans) and one Taphrinomycotina (S. pombe) (Kosman 2003). Interestingly, the ScFre1 to ScFRE6 S. cerevisiae isoforms induced by metal deficiency and whose activities are well characterized all belong to family I (Dancis et al. 1992; Georgatsou & Alexandraki 1994; Shatwell et al. 1996; Georgatsou & Alexandraki 1999; Yun et al. 2001; Singh et al. 2007). The CFL1 (Hammacott et al. 2000) and CFL95 (Knight et al. 2002) proteins from C. albicans also belong to family I. The two S. pombe proteins define family XIX. Although a reductase activity can be predicted for the proteins of the other 22 families based on the protein domains, the actual electron acceptors for these proteins are not known. It is therefore possible that molecules other than dioxygen and metals are the true electron acceptors for some of these proteins, as it has been shown that ScFRE1 can reduce organic compounds, such as paraquat (Hassett & Kosman 1995). Additionally, these proteins could be involved in developmental processes, since the S. cerevisiae mutants lacking ScFRE8 have defective bud morphology (Watanabe et al. 2009). ScFRE8, along with other IMRs from Saccharomycotina, define IMR family XVII. To gain some insight onto the potential roles of the IMRs of the other families, we analyzed the expression profiles of the P. anserina and N. crassa proteins, as microarray data are available for these two fungi. N. crassa global transcriptome changes are available during colony development/conidiation (Kasuga & Glass 2008), and during degradation of plant cell wall (Tian et al. 2009). Data are available for all IMRs and Nox1, but lack for Nox2. As seen in Fig 2A, while Nox1 expression is not affected by the carbon source, six out of eight N. crassa IMRs are induced during growth on avicel (microcrystalline cellulose) and ground Miscanthus stem, as compared to growth on sucrose, a feature compatible with a role for IMRs in plant biomass degradation. Similarly, a developmental role in N. crassa is possible for IMRs as most are regulated during N. crassa colony development (Fig 2B). Five are up-regulated after 3 h of growth and one is down-regulated during conidiation (21 and 27 h of growth). P. anserina global transcriptome changes (Bidard et al. 2010) are available for colony development (F.B. and P.S., unpubl.), fruiting body
Fig 2 e IMR gene expression profiles in N. crassa and P. anserina. (A) Expression profile of N. crassa IMR genes at 16 h of growth on minimal medium containing sucrose as carbon source (MM 16 h), compared to growth on avicel and Miscanthus at various times (16 h, 40 h, 5 d and 10 d). Data are taken from Tian et al. (2009). (B) Expression profile of N. crassa IMR genes during colony development corresponding to 1 h, 3 h, 9 h, 15 h, 21 h and 27 h of growth. At the two last time points, N. crassa differentiates conidias. Data are taken from Kasuga & Glass (2008). Because NCU02020 has a much higher expression level than the other IMR genes, it is depicted by itself in the insert. (C) Expression profile of P. anserina IMR genes during colony development at 24 h, 48 h and 72 h of growth, during fruiting body maturation 0 h, 12 h, 24 h and 96 h after maturation and in the PaNox1 null mutant grown for 24 h. After 72 h of mycelium growth P. anserina gametes are formed and await fertilization. After 96 h of maturation, fruiting bodies are ripe and start ejecting ascospores. Because Pa_7_5660 has a much higher expression level, it is depicted in the insert. N. crassa transcriptomic data are the mean of SNR ((signal-background)/background standard deviation of the biological replicates). P. anserina transcriptomic data are mean intensity of four biological replicates.
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(perithecium) maturation (F.B. and V. Berteaux-Lecellier, unpubl.) and the Nox1 mutant (Brun et al. 2009). Nox genes are not differentially regulated in P. anserina (Brun et al. 2009), however differential expression of some IMR genes during develoment is evidenced in P. anserina. As seen in Fig 2C, four IMRs are up-regulated during P. anserina colony development. Similarly, five IMRs are down-regulated during fruiting body development, two of them (Pa_1_16410 and Pa_5_11970) having their expression increased again during the late stages of perithecium maturation. Finally, three IMRs have their expression increased in the Nox1 mutants, which have been shown to degrade cellulose more efficiently than wild type and to produce more ROS (Malagnac et al. 2004; Brun et al. 2009). The IMRs differentially regulated in N. crassa and P. anserina may or may not belong to the same family, a feature easily accounted for by the very different culture conditions used for the two fungi.
Conclusion Fungal genomes contain several IMR genes. These can be classified into at least 24 families, underscoring the high diversity of these enzymes in Eumycetes. Many are differentially regulated by the carbon source present in the growth medium and/ or during colony and fruiting body development. Those that have been genetically or biochemically investigated belong to only two of the 24 families. We therefore advocate performing targeted gene deletion and biochemical characterization of representative IMRs belonging to the other 22 families not yet investigated to gain insight into their cellular roles.
Acknowledgments This work was supported by grant ANR-05-Blan-0385. Ibtissem Grissa is the recipient of an ATER fellowship from Universite´ of Paris Diderot Paris 7.
Supplemental data Supplementary data associated with this article can be found in online version at doi:10.1016/j.funbio.2010.07.002.
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