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Significance Wood decay fungi have historically been characterized as either white rot, which degrade all components of plant cell walls, including lignin, or brown rot, which leave lignin largely intact. Genomic analyses have shown that white-rot species possess multiple lignin-degrading peroxidases (PODs) and expanded suites of enzymes attacking crystalline cellulose. To test the adequacy of the white/brown-rot categories, we analyzed 33 fungal genomes. Some species lack PODs, and thus resemble brown-rot fungi, but possess the cellulose-degrading apparatus typical of white-rot fungi. Moreover, they appear to degrade lignin, based on decay analyses on wood wafers. Our results indicate that the prevailing paradigm of white rot vs. brown rot does not capture the diversity of fungal wood decay mechanisms.
Brown-rot fungi such as Postia placenta are common inhabitants of forest ecosystems and are also largely responsible for the destructive decay of wooden structures. Rapid depolymerization of cellulose is a distinguishing feature of brown-rot, but the biochemical mechanisms and underlying genetics are poorly understood. Systematic examination of the P. placenta genome, transcriptome, and secretome revealed unique extracellular enzyme systems, including an unusual repertoire of extracellular glycoside hydrolases. Genes encoding exocellobiohydrolases and cellulose-binding domains, typical of cellulolytic microbes, are absent in this efficient cellulose-degrading fungus. When P. placenta was grown in medium containing cellulose as sole carbon source, transcripts corresponding to many hemicellulases and to a single putative -1-4 endoglucanase were expressed at high levels relative to glucose-grown cultures. These transcript profiles were confirmed by direct identification of peptides by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Also upregulated during growth on cellulose medium were putative iron reductases, quinone reductase, and structurally divergent oxidases potentially involved in extracellular generation of Fe(II) and H2O2. These observations are consistent with a biodegradative role for Fenton chemistry in which Fe(II) and H2O2 react to form hydroxyl radicals, highly reactive oxidants capable of depolymerizing cellulose. The P. placenta genome resources provide unparalleled opportunities for investigating such unusual mechanisms of cellulose conversion. More broadly, the genome offers insight into the diversification of lignocellulose degrading mechanisms in fungi. Comparisons with the closely related white-rot fungus Phanerochaete chrysosporium support an evolutionary shift from white-rot to brown-rot during which the capacity for efficient depolymerization of lignin was lost.cellulose ͉ fenton ͉ lignin ͉ cellulase ͉ brown-rot
TTh he e p pl la an nt t c ce el ll l w wa al ll l d de ec co om mp po os si in ng g m ma ac ch hi in ne er ry y u un nd de er rl li ie es s t th he e f fu un nc ct ti io on na al l d di iv ve er rs si it ty y o of f f fo or re es st t f fu un ng gi i T Th he e p pl la an nt t c ce el ll l w wa al ll l d de ec co om mp po os si in ng g m ma ac ch hi in ne er ry y u un nd de er rl li ie es s t th he e f fu un nc ct ti io on na al l d di iv ve er rs si it ty y o of f f fo or re es st t f fu un ng gi i
Efficient lignin depolymerization is unique to the wood decay basidiomycetes, collectively referred to as white rot fungi. Phanerochaete chrysosporium simultaneously degrades lignin and cellulose, whereas the closely related species, Ceriporiopsis subvermispora, also depolymerizes lignin but may do so with relatively little cellulose degradation. To investigate the basis for selective ligninolysis, we conducted comparative genome analysis of C. subvermispora and P. chrysosporium . Genes encoding manganese peroxidase numbered 13 and five in C. subvermispora and P. chrysosporium , respectively. In addition, the C. subvermispora genome contains at least seven genes predicted to encode laccases, whereas the P. chrysosporium genome contains none. We also observed expansion of the number of C. subvermispora desaturase-encoding genes putatively involved in lipid metabolism. Microarray-based transcriptome analysis showed substantial up-regulation of several desaturase and MnP genes in wood-containing medium. MS identified MnP proteins in C. subvermispora culture filtrates, but none in P. chrysosporium cultures. These results support the importance of MnP and a lignin degradation mechanism whereby cleavage of the dominant nonphenolic structures is mediated by lipid peroxidation products. Two C. subvermispora genes were predicted to encode peroxidases structurally similar to P. chrysosporium lignin peroxidase and, following heterologous expression in Escherichia coli , the enzymes were shown to oxidize high redox potential substrates, but not Mn 2+ . Apart from oxidative lignin degradation, we also examined cellulolytic and hemicellulolytic systems in both fungi. In summary, the C. subvermispora genetic inventory and expression patterns exhibit increased oxidoreductase potential and diminished cellulolytic capability relative to P. chrysosporium .
Transposable elements (TEs) are exceptional contributors to eukaryotic genome diversity. Their ubiquitous presence impacts the genomes of nearly all species and mediates genome evolution by causing mutations and chromosomal rearrangements and by modulating gene expression. We performed an exhaustive analysis of the TE content in 18 fungal genomes, including strains of the same species and species of the same genera. Our results depicted a scenario of exceptional variability, with species having 0.02 to 29.8% of their genome consisting of transposable elements. A detailed analysis performed on two strains of Pleurotus ostreatus uncovered a genome that is populated mainly by Class I elements, especially LTR-retrotransposons amplified in recent bursts from 0 to 2 million years (My) ago. The preferential accumulation of TEs in clusters led to the presence of genomic regions that lacked intra- and inter-specific conservation. In addition, we investigated the effect of TE insertions on the expression of their nearby upstream and downstream genes. Our results showed that an important number of genes under TE influence are significantly repressed, with stronger repression when genes are localized within transposon clusters. Our transcriptional analysis performed in four additional fungal models revealed that this TE-mediated silencing was present only in species with active cytosine methylation machinery. We hypothesize that this phenomenon is related to epigenetic defense mechanisms that are aimed to suppress TE expression and control their proliferation.
Growth of Escherichia coli in the presence of certain D-amino acids, such as D-methionine, results in the incorporation of the D-amino acid into macromolecular peptidoglycan and can be lethal at high concentrations.Previous studies suggested that incorporation was independent of the normal biosynthetic pathway. An enzymatic reaction between the D-amino acid and macromolecular peptidoglycan was proposed as the mechanism of incorporation. The application of more advanced analytical techniques, notably high-pressure Biosynthesis of the peptidoglycan sacculus, the stressbearing structure of the cell wall, is one of the most complex metabolic processes in the bacterial cell, in particular from the physiological point of view. Cell growth is strictly dependent on the enlargement of the sacculus, and cell division is concomitant with the formation of a transverse wall, the septum, in the sacculus (11, 21). Therefore, a strict coordination among growth rate, cell division, and peptidoglycan synthesis is required to ensure viability. Furthermore, as the sacculus supports the turgor pressure of the cell, it must grow without the formation of discontinuities. Otherwise, cell lysis will follow, as often happens when peptidoglycan synthesis is disturbed (12,13,17,27). As a further complication of this scheme, the sacculus itself is not a static structure but rather is a macromolecule subject to highly dynamic metabolic activity comprising maturation, turnover, and growth-phase-dependent structural changes (4,5,(8)(9)(10)22).A breakthrough in the investigation of peptidoglycan structure was the introduction by Glauner et al. of highpressure liquid chromatography (HPLC)-based analytical methods for the determination of the muropeptide composition (6, 7). These techniques permitted routine analyses of unprecedented accuracy and resolution. More than 30 types of muropeptide were demonstrated as constitutive elements of Escherichia coli peptidoglycan. The structures of many of them were either known or understandable on the basis of identified enzymatic reactions. However, a new family of relatively abundant (3 to 5%) cross-linked muropeptides was discovered. The distinctive feature of these muropeptides is that cross-linking occurs by a direct meso-diaminopimelyl-* Corresponding author. meso-diaminopimelic acid peptide bridge (dap-dap bridge) of LD configuration instead of by the classical D-alanyl-mesodiaminopimelic acid bridge (Ala-dap bridge) of DD configuration. At present, the genesis and physiological role of this family of muropeptides are unknown. Nevertheless, synthesis via penicillin-binding proteins (PBPs) seems improbable, suggesting the existence in the cell envelope of specific enzymes to catalyze the formation and cleavage of LD-dapdap bridges (5-7, 12, 22).A large number of enzymes specifically involved in peptidoglycan metabolism have been identified (11,12). However, the enzymes involved in such important processes as the binding of lipoprotein and the formation of the dap-dap bridges mentioned above remain unk...
Summary Plants and fungi use light and other signals to regulate development, growth, and metabolism. The fruiting bodies of the fungus Phycomyces blakesleeanus are single cells that react to environmental cues, including light, but the mechanisms are largely unknown [1]. The related fungus Mucor circinelloides is an opportunistic human pathogen that changes its mode of growth upon receipt of signals from the environment to facilitate pathogenesis [2]. Understanding how these organisms respond to environmental cues should provide insights into the mechanisms of sensory perception and signal transduction by a single eukaryotic cell, and their role in pathogenesis. We sequenced the genomes of P. blakesleeanus and M. circinelloides, and show that they have been shaped by an extensive genome duplication or, most likely, a whole genome duplication (WGD), which is rarely observed in fungi [3-6]. We show that the genome duplication has expanded gene families, including those involved in signal transduction, and that duplicated genes have specialized, as evidenced by differences in their regulation by light. The transcriptional response to light varies with the developmental stage and is still observed in a photoreceptor mutant of P. blakesleeanus. A phototropic mutant of P. blakesleeanus with a heterozygous mutation in the photoreceptor gene madA demonstrates that photosensor dosage is important for the magnitude of signal transduction. We conclude that the genome duplication provided the means to improve signal transduction for enhanced perception of environmental signals. Our results will help to understand the role of genome dynamics in the evolution of sensory perception in eukaryotes.
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