Comparative Genome Structure,Secondary Metabolite,and Effector Coding Capacity across Cochliobolus Pathogens

The genomes of five Cochliobolus heterostrophus strains, two Cochliobolus sativus strains, three additional Cochliobolus species (Cochliobolus victoriae, Cochliobolus carbonum, Cochliobolus miyabeanus), and closely related Setosphaeria turcica were sequenced at the Joint Genome Institute (JGI). The datasets were used to identify SNPs between strains and species, unique genomic regions, core secondary metabolism genes, and small secreted protein (SSP) candidate effector encoding genes with a view towards pinpointing structural elements and gene content associated with specificity of these closely related fungi to different cereal hosts. Whole-genome alignment shows that three to five percent of each genome differs between strains of the same species, while a quarter of each genome differs between species. On average, SNP counts among field isolates of the same C. heterostrophus species are more than 25× higher than those between inbred lines and 50× lower than SNPs between Cochliobolus species. The suites of nonribosomal peptide synthetase (NRPS), polyketide synthase (PKS), and SSP–encoding genes are astoundingly diverse among species but remarkably conserved among isolates of the same species, whether inbred or field strains, except for defining examples that map to unique genomic regions. Functional analysis of several strain-unique PKSs and NRPSs reveal a strong correlation with a role in virulence.     

The rice/maize pathogen Cochliobolus spp. infect and reproduce on Arabidopsis revealing differences in defensive phytohormone function between monocots and dicots

The fungal genus Cochliobolus describes necrotrophic pathogens that give rise to significant losses on rice, wheat, and maize. Revealing plant mechanisms of non‐host resistance (NHR) against Cochliobolus will help to uncover strategies that can be exploited in engineered cereals. Therefore, we developed a heterogeneous pathosystem and studied the ability of Cochliobolus to infect dicotyledons. We report here that C. miyabeanus and C. heterostrophus infect Arabidopsis accessions and produce functional conidia, thereby demonstrating the ability to accept Brassica spp. as host plants. Some ecotypes exhibited a high susceptibility, whereas others hindered the necrotrophic disease progression of the Cochliobolus strains. Natural variation in NHR among the tested Arabidopsis accessions can advance the identification of genetic loci that prime the plant’s defence repertoire. We found that applied phytotoxin‐containing conidial fluid extracts of C. miyabeanus caused necrotic lesions on rice leaves but provoked only minor irritations on Arabidopsis. This result implies that C. miyabeanus phytotoxins are insufficiently adapted to promote dicot colonization, which corresponds to a retarded infection progression. Previous studies on rice demonstrated that ethylene (ET) promotes C. miyabeanus infection, whereas salicylic acid (SA) and jasmonic acid (JA) exert a minor function. However, in Arabidopsis, we revealed that the genetic disruption of the ET and JA signalling pathways compromises basal resistance against Cochliobolus, whereas SA biosynthesis mutants showed a reduced susceptibility. Our results refer to the synergistic action of ET/JA and indicate distinct defence systems between Arabidopsis and rice to confine Cochliobolus propagation. Moreover, this heterogeneous pathosystem may help to reveal mechanisms of NHR and associated defensive genes against Cochliobolus infection.     

Cloning,expression and characterization of a novel acidic xylanase,XYL11B,from the acidophilic fungus Bispora sp. MEY-1

A xylanase gene (xyl11B) was cloned from Bispora sp. MEY-1 and expressed in Pichia pastoris. xyl11B, with a 66-bp intron, encodes a mature protein of 219 residues with highest identity (57.1%) to the Trichoderma reesei xylanase of glycoside hydrolase family 11. The purified recombinant XYL11B was acidophilic, exhibiting maximum activity at pH 2.6 and 65 °C. The enzyme was also thermostable, pH stable, and was highly resistant to both pepsin and trypsin, suggesting good performance in the digestive tract as a feed supplement to improve animal nutrition. The activity of XYL11B was enhanced by most metal ions but was inhibited weakly by Hg²⁺, Pb²⁺and Cu²⁺, which strongly inhibit many other xylanases. The specific activity of XYL11B for oat spelt xylan substrate was 2049 U mg^?1. The main hydrolysis products of xylan were xylose and xylobiose.     

Cloning, disruption, and expression of two endo-beta 1, 4-xylanase genes, XYL2 and XYL3, from Cochliobolus carbonum.

In culture, the filamentous fungus Cochliobolus carbonum, a pathogen of maize, makes three cationic xylanases, XYL1, which encodes the major endoxylanase (Xyl1), was earlier cloned and shown by gene disruption to encode the first and second peaks of xylanase activity (P. C. Apel, D. G. Panaccione, F. R. Holden, and J. D. Walton, Mol. Plant-Microbe Interact. 6:467-473, 1993). Two additional xylanase genes, XYL2 and XYL3, have now been cloned from C. carbonum. XYL2 and XYL3 are predicted to encode 22-kDa family G xylanases similar to Xyl1. Xyl2 and Xyl3 are 60% and 42% identical, respectively, to Xyl1, and Xyl2 and Xyl3 are 39% identical. XYL1 and XYL2 but not XYL3 mRNAs are present in C. carbonum grown in culture, and XYL1 and XYL3 but not XYL2 mRNAs are present in infected plants. Transformation-mediated gene disruption was used to construct strains mutated in XYL1, XYL2, and XYL3. Xyl1 accounts for most of the total xylanase activity in culture, and disruption of XYL2 or XYL3 does not result in the further loss of any xylanase activity. In particular, the third peak of cationic xylanase activity is still present in a xyl1 xyl2 xyl3 triple mutant, and therefore this xylanase must be encoded by yet a fourth xylanase gene. A minor protein of 22 kDa that can be detected immunologically in the xyl1 mutant disappears in the xyl2 mutant and is therefore proposed to be the product of XYL2. The single xylanase mutants were crossed with each other to obtain multiple xylanase disruptions within the same strain. Strains disrupted in combinations of two and in all three xylanases were obtained. The triple mutant grows at the same rate as the wild type on xylan and on maize cell walls. The triple mutant is still fully pathogenic on maize with regard to lesion size, morphology, and rate of lesion development.     

C4 genes of the chimpanzee,gorilla, and orang-utan: evidence for extensive homogenization

The human complement component 4 is encoded in two genes, C4A and C4B, residing between the class I and class II genes of the major histocompatibility complex. The C4A and C4B molecules differ in their biological activity, the former binding more efficiently to proteins than to carbohydrates while for the latter, the opposite holds true. To shed light on the origin of the C4 genes we isolated cosmid clones bearing the C4 genes of a chimpanzee, a gorilla, and an orang-utan. From the clones, we isolated the fragments coding for the C4d part of the gene (exons and introns) and sequenced them. Altogether we sequenced eight gene fragments: three chimpanzee (Patr-C4-1 ^*01, Patr-C4-1 ^*02, Patr-C4-2 ^*01), two gorilla (Gogo-C4-1 ^*01, Gogo-C4-2 ^*01), and three orang-utan (Popy-C4-1 ^*01, Popy-C4-2 ^*01, Popy-C4-3 ^*01). Comparison of the sequences with each other and with human C4 sequences revealed that in the region believed to be responsible for the functional difference between the C4A and C4B proteins the C4A genes of the different species fell into one group and the C4B genes fell into another. In the rest of the sequence, however, the C4A and C4B genes of each species resembled each other more than they did C4 genes of other species. These results are interpreted as suggesting extensive homogenization (concerted evolution) of the C4 genes in each species, most likely by repeated unequal, homologous, intragenic crossing-over. Address correspondence and offprint requests to: J. Klein.     

Production in <Emphasis Type="Italic">Trichoderma reesei</Emphasis> of three xylanases from <Emphasis Type="Italic">Chaetomium thermophilum</Emphasis>: a recombinant thermoxylanase for biobleaching of kraft pulp

Three endoxylanase genes were cloned from the thermophilic fungus Chaetomium thermophilum CBS 730.95. All genes contained the typical consensus sequence of family 11 glycoside hydrolases. Genomic copies of Ct xyn11A, Ct xyn11B, and Ct xyn11C were expressed in the filamentous fungus T. reesei under the control of the strong T. reesei cel7A (cellobiohydrolase 1, cbh1) promoter. The molecular masses of the Ct Xyn11A, Ct Xyn11B, and Ct Xyn11C proteins on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) were 27, 23, and 22 kDa, respectively. Ct Xyn11A was produced almost as efficiently as the homologous xylanase II from a corresponding single-copy transformant strain. Ct Xyn11B production level was approximately half of that of Ct Xyn11A. The amount of Ct Xyn11C was remarkably lower. Ct Xyn11A had the highest temperature optimum and stability of the recombinant xylanases and the highest activity at acid-neutral pH (pH 5–7). It was the most suitable for industrial bleaching of kraft pulp at high temperature.     

Family 10 and 11 xylanase genes from Caldicellulosiruptor sp. strain Rt69B.1

Three family 10 xylanase genes (xynA, xynB, and xynC) and a single family 11 xylanase gene (xynD) were identified from the extreme thermophile Caldicellulosiruptor strain Rt69B.1 through the use of consensus PCR in conjunction with sequencing and polyacrylamide gel electrophoresis. These genes appear to comprise the complete endoxylanase system of Rt69B.1. The xynA gene was found to be homologous to the xynA gene of the closely related Caldicellulosiruptor strain Rt8B.4, and primers designed previously to amplify the Rt8B.4 xynA gene could amplify homologous full-length xynA gene fragments from Rt69B.1. The complete nucleotide sequences of the Rt69B.1 xynB, xynC, and xynD genes were obtained using genomic walking PCR. The full-length xynB and xynC genes are more than 5 kb in length and encode highly modular enzymes that are the largest xylanases reported to date. XynB has an architecture similar to the family 10 xylanases from Thermoanaerobacterium saccharolyticum (XynA) and Clostridium thermocellum (XynX) and may be cell wall associated, while XynC is a bifunctional enzyme with an architecture similar to the bifunctional β-glycanases from Caldicellulosiruptor saccharolyticus. The xynD gene encodes a two-domain family 11 xylanase that is identical in architecture to the XynB family 11 xylanase from the unrelated extreme thermophile Dictyoglomus thermophilum strain Rt46B.1. The sequence similarities between the Rt69B.1 xylanases with respect to their evolution are discussed. Received: May 13, 1998 / Accepted: October 22, 1998     

A new acidophilic endo-β-1,4-xylanase from Penicillium oxalicum: cloning,purification, and insights into the influence of metal ions on xylanase activity

A new acidophilic xylanase (XYN11A) from Penicillium oxalicum GZ-2 has been purified, identified and characterized. Synchronized fluorescence spectroscopy was used for the first time to evaluate the influence of metal ions on xylanase activity. The purified enzyme was identified by MALDI TOF/TOF mass spectrometry, and its gene (xyn11A) was identified as an open reading frame of 706 bp with a 68 bp intron. This gene encodes a mature protein of 196 residues with a predicted molecular weight of 21.3 kDa that has the 100 % identity with the putative xylanase from the P. oxalicum 114-2. The enzyme shows a structure comprising a catalytic module family 10 (GH10) and no carbohydrate-binding module family. The specific activities were 150.2, 60.2, and 72.6 U/mg for beechwood xylan, birchwood xylan, and oat spelt xylan, respectively. XYN11A exhibited optimal activity at pH 4.0 and remarkable pH stability under extremely acidic condition (pH 3). The specific activity, K _m and V _max values were 150.2 U/mg, 30.7 mg/mL, and 403.9 μmol/min/mg for beechwood xylan, respectively. XYN11A is a endo-β-1,4-xylanase since it release xylobiose and xylotriose as the main products by hydrolyzing xylans. The activity of XYN11A was enhanced 155 % by 1 mM Fe²⁺ ions, but was inhibited strongly by Fe³⁺. The reason of enhancing the xylanase activity of XYN11A with 1 mM Fe²⁺ treatment may be responsible for the change of microenvironment of tryptophan residues studied by synchronous fluorescence spectrophotometry. Inhibition of the xylanase activity by Fe³⁺ was first time demonstrated to associate tryptophan fluorescence quenching.     

A new xylanase from a Trichoderma harzianum strain

A new xylanase (XYL2) was purified from solid-state cultures of Trichoderma harzianum strain C by ultrafiltration and gel filtration. SDS-PAGE of the xylanase showed an apparent homogeneity and molecular weight of 18 kDa. It had the highest activity at pH 5.0 and 45°C and was stable at 50°C and pH 5.0 up to 4 h xylanase. XYL2 had a low K _m with insoluble oat spelt xylan as substrate. Compared to the amino acid composition of xylanases from Trichoderma spp, xylanase XYL2 presented a high content of glutamate/glutamine, phenylalanine and cysteine, and a low content of serine. Xylanase XYL2 improved the delignification and selectivity of unbleached hardwood kraft pulp. Received 02 February 1999/ Accepted in revised form 17 April 1999     

Identification of new GH 10 and GH 11 xylanase genes from Aspergillus versicolor MKU3 by genome-walking PCR

Xylanases randomly clear the backbone of xylans, which are hemicelluloses representing a considerable source of fixed carbon in nature. Consequently, these enzymes have important industrial applications. To characterize the genes responsible for producing these enzymes, we cloned xylanase genes belonging to the GH11 and GH10 families from Aspergillus versicolor MKU3 using a 2-step polymerase chain reaction (PCR) protocol involving degenerate PCR and genome-walking PCR (GWPCR). We amplified a family 10 xylanase consensus fragment using degenerate PCR primers exhibiting specificity for conserved motifs within fungal family 10 xylanase genes. We identified a single family 10 xylanase gene (xynv10) and determined its entire gene sequence during the second step of GWPCR, which was used to amplify genomic DNA fragments upstream and downstream of xynv10. The xynv10 sequence contains a 1,378-bp open reading frame separated by 8 introns with an average size of 49 bp. We also amplified a partial GH11 xylanase gene sequence (xynv11) using degenerate PCR and genome-walking methods. Amplification of the C-terminal region of xynv11 using a degenerate primer designed from sequences revealed strong homology with the partial GH11 xylanase gene of A. versicolor MKU3. The structural region in xynv11 was approximately 680 bp and has one intron that is approximately 64 bp in length. Further expression and characterization of these genes will give better understanding of the role of these genes in xylan degradation by A. versicolor.     

Characterization of abiotic stress-responsive <Emphasis Type="Italic">Arabidopsis thaliana RD29A</Emphasis> and <Emphasis Type="Italic">RD29B</Emphasis> genes and evaluation of transgenes

Abiotic stresses have adverse effects on plant growth and productivity. The homologous RD29A and RD29B genes are exquisitely sensitive to various abiotic stressors. Therefore, RD29A and RD29B gene sequences have potential to confer abiotic stress resistance in crop species grown in arid and semi-arid regions. To our knowledge, no information on the physiological roles of the proteins encoded by RD29A and RD29B are available in the literature. To understand how these proteins function, we used reverse genetic approaches, including identifying rd29a and rd29b T-DNA knockout mutants, and examining the effects of complementing transgenes with the genes under control of their native promoters and chimeric genes with the native promoters swapped. Four binary vectors with the RD29A and RD29B promoters upstream of the cognate RD29A and RD29B cDNAs and as chimeric genes with noncognate promoters were used to transform rd29a and rd29b plants. Cold, drought, and salt induced both genes; the promoter of RD29A was found to be more responsive to drought and cold stresses, whereas the promoter of RD29B was highly responsive to salt stress. Morphological and physiological responses of rd29a and rd29b plants to salt stress were further investigated. Root growth, and photosynthetic properties declined significantly, while solute concentration (Ψπ), water use efficiency (WUE) and δ¹³C ratio increased under salt stress. Unexpectedly, the rd29a and rd29b knockout mutant lines maintained greater root growth, photosynthesis, and WUE under salt stress relative to control. We conclude that the RD29A and RD29B proteins are unlikely to serve directly as protective molecules.     

An acid and highly thermostable xylanase from <Emphasis Type="Italic">Phialophora</Emphasis> sp. G5

An endo-β-1,4-xylanase gene, designated xyn10G5, was cloned from Phialophora sp. G5 and expressed in Pichia pastoris. The 1,197-bp full-length gene encodes a polypeptide of 399 amino acids consisting of a putative signal peptide at residues 1–20, a family 10 glycoside hydrolase domain, a short Gly/Thr-rich linker and a family 1 carbohydrate-binding module (CBM). The deduced amino acid sequence of XYN10G5 shares the highest identity (53.4%) with a putative xylanase precursor from Aspergillus terreus NIH2624. The purified recombinant XYN10G5 exhibited the optimal activity at pH 4.0 and 70 °C, remained stable at pH 3.0–9.0 (>70% of the maximal activity), and was highly thermostable at 70 °C (retaining ~90% of the initial activity for 1 h). Substrate specificity studies have shown that XYN10G5 had the highest activity on soluble wheat arabinoxylan (350.6 U mg⁻¹), and moderate activity to various heteroxylans, and low activity on different types of cellulosic substrates. Under simulated gastric conditions, XYN10G5 was stable and released more reducing sugars from soluble wheat arabinoxylan; when combined with a glucanase (CelA4), the viscosity of barley–soybean feed was significantly reduced. These favorable enzymatic properties make XYN10G5 a good candidate for application in the animal feed industry.     

ChMCO1 of Cochliobolus heterostrophus is a new class of metallo-oxidase, playing an important role in DHN-melanization

A metallo-oxidase gene from a phytopathogenic filamentous fungus, Cochliobolus heterostrophus was cloned. Structural prediction of ChMco1 indicated that this protein lacks a transmembrane helix and is soluble, whereas other known fungal metallo-oxidases including Saccharomyces cerevisiae FET3 are localized to the cell membrane. The results of searches in fungal genomic databases and phylogenetic analysis of fungal metallo-oxidases revealed that ChMco1 and its allies are distinct homologues of Fet3 and unique to filamentous ascomycetous species including C. heterostrophus. We performed a functional analysis of ChMCO1 by generating null mutants for the ChMco1 gene. The ChMco1 null (∆ChMco1) mutants clearly had reduced melanization, although they showed normal growth and conidiation. Results also show that ∆ChMco1 mutants lost laccase activity. These results suggest that ChMCO1 is a novel class of metallo-oxidase that is necessary for laccase activity and melanization.     

Detection of Cochliobolus heterostrophus races in South China

Cochliobolus heterostrophus is the causal pathogen of the southern corn leaf blight (SCLB). There are three known races: race O, race C and race T. To determine which C. heterostrophus races comprise the field population in southern China and to assess diversity of these strains in terms of virulence, 200 isolates from diseased plants were collected in nine provinces/municipalities. All were race O, that is, no race T or race C isolates were found. Sixty race O isolates that sporulated well were chosen for further analysis. Virulence was measured using the integral optical density (IOD) of leaf lesions on four maize inbred lines. UPGMA cluster analysis of AFLP markers was applied to the 60 race O isolates plus control race O, T and C strains. Phylogenetic distribution, geographic location and virulence were not correlated. These results can provide valuable information for guidance in early warning and disease control.     

Integrative taxonomy of the stunt nematodes of the genera Bitylenchus and Tylenchorhynchus (Nematoda,Telotylenchidae) with description of two new species and a molecular phylogeny

Stunt nematodes are characterized by phenotypic plasticity, with overlapping morphology and morphometry leading to potential misidentification. Consequently, the application of integrative taxonomic approaches is useful to species delimitation based on a combination of different perspectives, e.g. morphology and DNA sequences. We conducted nematode surveys in cultivated and natural environments in Spain and the USA, from which we identified 18 known species of the family Telotylenchidae and two new taxa within the studied samples. These species were morphologically, morphometrically, and molecularly characterized. The results of light and scanning electron microscopic observations, and molecular and phylogenetic analysis also allowed two new species to be distinguished, described herein as B itylenchus hispaniensis sp. nov. and T ylenchorhynchus mediterraneus sp. nov. The phylogenetic analysis was carried out using molecular data from nuclear ribosomal DNA genes [D2–D3 expansion segments of the large ribosomal subunit (28S), internal transcribed spacer (ITS), and partial small ribosomal subunit (18S)]. We also provide here a test of alternative hypotheses that confirms the monophyly of both Tylenchorhynchus and Bitylenchus sensu Siddiqi's classification but does not support Fortuner & Luc's conceptual view of Tylenchorhynchus as a large genus. Ancestral state reconstructions of several diagnostic morphological characters using a maximum parsimony approach showed congruence in morphological and molecular evolution for stylet knob inclination and tail tip annulation. Our analysis emphasizes some of the problems related to the taxonomy and phylogeny of nematodes of Telotylenchinae. © 2014 The Linnean Society of London     

Engineering a high-performance,metagenomic-derived novel xylanase with improved soluble protein yield and thermostability

The novel termite gut metagenomic-derived GH11 xylanase gene xyl7 was expressed in Escherichia coli BL21, and the purified XYL7 enzyme exhibited high specific activity (6340 U/mg) and broad pH active range of 5.5–10.0. Directed evolution was employed to enhance the thermostability of XYL7; two mutants (XYL7-TC and XYL7-TS) showed a 250-fold increase in half-life at 55 °C, with a 10 °C increase in optimal temperature compared to that of wild-type XYL7. A truncated enzyme (XYL7-Tr3) acquired by protein engineering showed similar catalytic properties as the wild-type, with a tenfold increase in soluble protein yield by the mutant. The reducing sugar produced by XYL7-TC was about fourfold greater than that produced by their parents when incubated with xylan at 60 °C for 4 h. The engineered novel xylanase exhibited superior enzymatic performance and showed promise as an excellent candidate for industrial application due to its high specific activity, stability and soluble protein yield.