Gene content and organization of an 85-kb DNA segment from the genome of the phytopathogenic mollicute Spiroplasma kunkelii

Spiroplasma kunkelii, the causative agent of corn stunt disease in maize ( Zea mays L.), is a helical, cell wall-less prokaryote assigned to the class Mollicutes. As part of a project to sequence the entire S. kunkelii genome, we analyzed an 85-kb DNA segment from the pathogenic strain CR2-3x. This genome segment contains 101 ORFs and two tRNA genes. The majority of the ORFs code for predicted proteins that can be assigned to respective clusters of orthologous groups (COGs). These COGs cover diverse functional categories including genetic information storage and processing, cellular processes, and metabolism. The most notable gene cluster in this genome segment is a super-operon capable of encoding 24 ribosomal proteins. The organization of genes in this operon reflects the unique evolutionary position of the spiroplasma. Gene duplications, domain rearrangements, and frameshift mutations in the segment are interpreted as indicators of phase variation in the spiroplasma. To our knowledge, this is the first analysis of a large genome segment from a plant pathogenic spiroplasma.Communicated by W. Goebel     

Cosmid cloning and sample sequencing of the genome of the uncultivable mollicute,Western X-disease phytoplasma,using DNA purified by pulsed-field gel electrophoresis

Western X-disease (WX) phytoplasma is an uncultivable, intracellular pathogen of plants and insects with an AT-rich genome of 670 kb. As part of the genome sequencing project of WX phytoplasma, we have cloned approximately 50% of its genome into the pcosRW2 cosmid vector using DNA purified from pulsed-field gels. One of the cosmid clones with an insert of 24.6 kb was sequenced, which along with the cosmid end sequences, represents 60 kb of unique sequence from the WX phytoplasma genome. The putative genes identified in this sequence represent a wide variety of functions and many had not been previously identified in a phytoplasma.     

Predicted ATP-binding cassette systems in the phytopathogenic mollicute <Emphasis Type="Italic">Spiroplasma kunkelii</Emphasis>

Spiroplasma kunkelii is a cell wall-free, helical, and motile mycoplasma-like organism that causes corn stunt disease in maize. The bacterium has a compact genome with a gene set approaching the minimal complement necessary for cellular life and pathogenesis. A set of 21 ATP-binding cassette (ABC) domains was identified during the annotation of a draft S. kunkelii genome sequence. These 21 ABC domains are present in 18 predicted proteins, and are components of 16 functional systems, which account for 5% of the protein coding capacity of the S. kunkelii genome. Of the 16 systems, 11 are membrane-bound transporters, and two are cytosolic systems involved in DNA repair and the oxidative stress response; the genes for the remaining three hypothetical systems harbor nonsense and/or frameshift mutations, so their functional status is doubtful. Assembly of the 11 multicomponent transporters, and comparisons with other known systems permitted functional predictions for the S. kunkelii ABC transporter systems. These transporters convey a wide variety of substrates, and are critical for nutrient uptake, multidrug resistance, and perhaps virulence. Our findings provide a framework for functional characterization of the ABC systems in S. kunkelii.Communicated by W. Goebel     

Infection and replication sites of Spiroplasma kunkelii (Class: Mollicutes) in midgut and Malpighian tubules of the leafhopper Dalbulus maidis

Spiroplasma kunkelii distribution and infection mechanisms in the intestines and Malpighian tubules of Dalbulus maidis were investigated by transmission electron microscopy. Spiroplasmas were found between microvilli and in endocytic vesicles of the midgut epithelium. At the basal part, cytoplasmic vesicles contained multiple spiroplasmas with tube-like extensions and spiroplasmas accumulated between the laminae rara and densa of the basal lamina. Tip structures of flask-shaped spiroplasmas pierced the lamina densa that was discontinuous in close proximity to spiroplasmas. Spiroplasmas were found in hemolymph, crossed the basal lamina of Malpighian tubule epithelium and accumulated at high numbers in muscle cells that had cytopathogenic changes. S. kunkelii had perithrochous approximately 8nm diameter structures determined to be fimbriae protruding from the cell surface, and similar structures were adhering to the basal lamina of midgut epithelium and to external lamina of muscle cells. Further, spiroplasmas had pili-like appendages at one or both cell poles and appeared to conjugate. This is the first time that fimbriae and pili have been observed in a mollicutes.     

Characterization and high-quality draft genome sequence of Herbivorax saccincola A7, an anaerobic,alkaliphilic, thermophilic,cellulolytic, and xylanolytic bacterium

An anaerobic, cellulolytic-xylanolytic bacterium, designated strain A7, was isolated from a cellulose-degrading bacterial community inhabiting bovine manure compost on Ishigaki Island, Japan, by enrichment culture using unpretreated corn stover as the sole carbon source. The strain was Gram-positive, non-endospore forming, non-motile, and formed orange colonies on solid medium. Strain A7 was identified as Herbivorax saccincola by DNA-DNA hybridization, and phylogenetic analysis based on 16S rRNA gene sequences showed that it was closely related to H. saccincola GGR1 (= DSM 101079^T). H. saccincola A7 (= JCM 31827 = DSM 104321) had quite similar phenotypic characteristics to those of strain GGR1. However, the optimum growth of A7 was at alkaline pH (9.0) and 55 °C, compared to pH 7.0 at 60 °C for GGR1, and the fatty acid profile of A7 contained 1.7-times more C_17:0 iso than GGR1. The draft genome sequence revealed that H. saccincola A7 possessed a cellulosome-like extracellular macromolecular complex, which has also been found for Clostridium thermocellum and C. clariflavum. H. saccincola A7 contained more glycoside hydrolases (GHs) belonging to GH families-11 and -2, and more diversity of xylanolytic enzymes, than C. thermocellum and C. clariflavum. H. saccincola A7 could grow on xylan because it encoded essential genes for xylose metabolism, such as a xylose transporter, xylose isomerase, xylulokinase, and ribulose-phosphate 3-epimerase, which are absent from C. thermocellum. These results indicated that H. saccincola A7 has great potential as a microorganism that can effectively degrade lignocellulosic biomass.     

Detection of a Concanavalin A binding protein in the mollicute Spiroplasma citri and purification from the plasma membrane

A protein that binds Concanavalin A (Con A) was detected on Western blots of Spiroplasma citri proteins. Its apparent molecular weight was 84000. It was localized in the plasma membrane. Affinity chromatography on Con A-agarose was used to isolate this protein. The glycosylation inhibitor, tunicamycin, inhibits S. citri growth and seems to block the glycosylation of the Con A-binding protein.     

Gene and genome duplications in vertebrates: the one-to-four (-to-eight in fish) rule and the evolution of novel gene functions

One important mechanism for functional innovation during evolution is the duplication of genes and entire genomes. Evidence is accumulating that during the evolution of vertebrates from early deuterostome ancestors entire genomes were duplicated through two rounds of duplications (the 'one-to-two-to-four' rule). The first genome duplication in chordate evolution might predate the Cambrian explosion. The second genome duplication possibly dates back to the early Devonian. Recent data suggest that later in the Devonian, the fish genome was duplicated for a third time to produce up to eight copies of the original deuterostome genome. This last duplication took place after the two major radiations of jawed vertebrate life, the ray-finned fish (Actinopterygia) and the sarcopterygian lineage, diverged. Therefore the sarcopterygian fish, which includes the coelacanth, lungfish and all land vertebrates such as amphibians, reptiles, birds and mammals, tend to have only half the number of genes compared with actinopterygian fish. Although many duplicated genes turned into pseudogenes, or even 'junk' DNA, many others evolved new functions particularly during development. The increased genetic complexity of fish might reflect their evolutionary success and diversity.     

DNA sequence organization and transcription of the chicken genome

A new approach has been used to examine DNA sequence organization in the chicken genome. The interspersion pattern was determined by studying the fraction of labelled DNA fragments of different lengths that hybridized to an excess of short chicken repeated DNA sequences. The results indicate that chicken DNA has a pattern of sequence organization quite different than the standard ‘Xenopus’ or ‘Drosophila’ patterns. Two classes of unique sequences are found. One, 34% of the genome, consists of unique sequences approx. 4 kb long interspersed with repeated sequences. The second, non-interspersed fraction, 38% of the genome, consists of unique sequences found in long tracts, a minimum of approx. 22 kb in length. In an attempt to determine whether a relationship exists between DNA sequence organization and the distribution of structural genes we have isolated chicken DNA sequences belonging to different interspersion classes and tested each for the presence of structural genes by hybridization to excess poly(A)⁺ mRNA. Sequences complementary to poly(A)⁺ mRNA can be found with approximately the same frequency in both the non-interspersed fraction of the genome and a repeat-contiguous fraction enriched for interspersed sequences.     

A multilocus sequence analysis of the genus Xanthomonas

A multilocus sequence analysis (MLSA) of strains representing all validly published Xanthomonas spp. (119 strains) was conducted using four genes; dnaK, fyuA, gyrB and rpoD, a total of 440 sequences. Xanthomonas spp. were divided into two groups similar to those indicated in earlier 16S rDNA comparative analyses, and they possibly represent distinct genera. The analysis clearly differentiated most species that have been established by DNA-DNA reassociation. A similarity matrix of the data indicated clear numerical differences that could form the basis for species differentiation in the future, as an alternative to DNA-DNA reassociation. Some species, X. cynarae, X. gardneri and X. hortorum, formed a single heterogeneous group that is in need of further investigation. X. gardneri appeared to be a synonym of X. cynarae. Recently proposed new species, X. alfalfae, X. citri, X. euvesicatoria, X. fuscans and X. perforans, were not clearly differentiated as species from X. axonopodis, and X. euvesicatoria and X. perforans are very probably synonyms. MLSA offers a powerful tool for further investigation of the classification of Xanthomonas. Based on the dataset produced, the method also offers a relatively simple way of identifying strains as members of known species, or of indicating their status as members of new species.     

Draft genome sequence of the termite,Coptotermes formosanus: Genetic insights into the pyruvate dehydrogenase complex of the termite

Termites are generally deficient in pyruvate dehydrogenase (PDH), which links glycolysis to the Krebs cycle; however, one termite species, Coptotermes formosanus, has some PDH activity, though it is not enough to maintain the respiration of the termite by itself. We obtained a high quality annotated draft genome of C. formosanus. We found that all genes constituting the PDH complex and controlling PDH activity are present in the genome of C. formosanus, except for the PDH protein X component that is essential for a functional PDH complex. Additionally, we found that C. formosanus has three endo-ß-1,4-glucanases (EGs), for which the amino acid sequences differ from those of previously reported EGs. Despite the ability of termites to convert cellulose to glucose and the resulting glucose to pyruvate, PDH is likely to function poorly due to a missing X component of the PDH complex.     

A survey of single nucleotide polymorphisms identified from whole‐genome sequencing and their functional effect in the porcine genome,

Genetic variants detected from sequence have been used to successfully identify causal variants and map complex traits in several organisms. High and moderate impact variants, those expected to alter or disrupt the protein coded by a gene and those that regulate protein production, likely have a more significant effect on phenotypic variation than do other types of genetic variants. Hence, a comprehensive list of these functional variants would be of considerable interest in swine genomic studies, particularly those targeting fertility and production traits. Whole‐genome sequence was obtained from 72 of the founders of an intensely phenotyped experimental swine herd at the U.S. Meat Animal Research Center (USMARC). These animals included all 24 of the founding boars (12 Duroc and 12 Landrace) and 48 Yorkshire–Landrace composite sows. Sequence reads were mapped to the Sscrofa10.2 genome build, resulting in a mean of 6.1 fold (×) coverage per genome. A total of 22 342 915 high confidence SNPs were identified from the sequenced genomes. These included 21 million previously reported SNPs and 79% of the 62 163 SNPs on the PorcineSNP60 BeadChip assay. Variation was detected in the coding sequence or untranslated regions (UTRs) of 87.8% of the genes in the porcine genome: loss‐of‐function variants were predicted in 504 genes, 10 202 genes contained nonsynonymous variants, 10 773 had variation in UTRs and 13 010 genes contained synonymous variants. Approximately 139 000 SNPs were classified as loss‐of‐function, nonsynonymous or regulatory, which suggests that over 99% of the variation detected in our pigs could potentially be ignored, allowing us to focus on a much smaller number of functional SNPs during future analyses.     

Complete genome sequence of the kirromycin producer Streptomyces collinus Tü 365 consisting of a linear chromosome and two linear plasmids

Streptomyces collinus Tü 365 (DSMZ 40733), isolated from Kouroussa (Guinea), is the producer of the elfamycin family antibiotic kirromycin, which inhibits bacterial protein biosynthesis by interfering with elongation factor EF-Tu. Here, we report on the Streptomyces collinus Tü 365 complete genome sequence of the 8.27 MB chromosome and the two plasmids SCO1 and SCO2.     

Genomic sequence of the aflatoxigenic filamentous fungus Aspergillus nomius

Background

Aspergillus nomius is an opportunistic pathogen and one of the three most important producers of aflatoxins in section Flavi. This fungus has been reported to contaminate agricultural commodities, but it has also been sampled in non-agricultural areas so the host range is not well known. Having a similar mycotoxin profile as A. parasiticus, isolates of A. nomius are capable of secreting B- and G- aflatoxins.

Results

In this study we discovered that the A. nomius type strain (NRRL 13137) has a genome size of approximately 36 Mb which is comparable to other Aspergilli whose genomes have been sequenced. Its genome encompasses 11,918 predicted genes, 72 % of which were assigned GO terms using BLAST2GO. More than 1,200 of those predicted genes were identified as unique to A. nomius, and the most significantly enriched GO category among the unique genes was oxidoreducatase activity. Phylogenomic inference shows NRRL 13137 as ancestral to the other aflatoxigenic species examined from section Flavi. This strain contains a single mating-type idiomorph designated as MAT1-1.

Conclusions

This study provides a preliminary analysis of the A. nomius genome. Given the recently discovered potential for A. nomius to undergo sexual recombination, and based on our findings, this genome sequence provides an additional evolutionary reference point for studying the genetics and biology of aflatoxin production.     

A search for patterns in the nucleotide sequence of the MS2 genome

Summary The nucleotide sequence of the RNA of the bacteriophage MS2 was examined by computer for internal patterns. We used a technique which analyzes a nucleotide sequence as a Markov chain. This led us to discover patterns within the translated and untranslated regions of the RNA in addition to those patterns formed by the codons. One of the more surprising results of this analysis was the discovery that the non-coding sequences in the genome are as highly ordered, although in a different sense, as the genes themselves. Also of interest was the discovery that the codon frequency distributions for the three genes are similar.     

A transposon-like sequence with short terminal inverted repeats in the nuclear genome of Chlamydomonas reinhardtii

A 1.2 kb DNA sequence, flanked by a potential seven base target-site duplication, was found inserted into a TOC1 transposable element from Chlamydomonas reinhardtii. The insertion sequence, named TOC2, is a member of a family of repeated DNA sequences that is present in all the C. reinhardtii strains tested. It resembles class II transposable elements: it possesses short 14 bp imperfect terminal repeats that begin AGGAGGGT, and sub-terminal direct repeats located within 250 bp of the termini. No large open reading frames were found. The terminal bases and length of target-site duplication are important in classifying transposable elements. On this basis TOC2 does not fall readily into existing families of class II transposable elements found in plants.     

A draft genome sequence of the pulse crop chickpea (Cicer arietinum L.)

Cicer arietinum L. (chickpea) is the third most important food legume crop. We have generated the draft sequence of a desi‐type chickpea genome using next‐generation sequencing platforms, bacterial artificial chromosome end sequences and a genetic map. The 520‐Mb assembly covers 70% of the predicted 740‐Mb genome length, and more than 80% of the gene space. Genome analysis predicts the presence of 27 571 genes and 210 Mb as repeat elements. The gene expression analysis performed using 274 million RNA‐Seq reads identified several tissue‐specific and stress‐responsive genes. Although segmental duplicated blocks are observed, the chickpea genome does not exhibit any indication of recent whole‐genome duplication. Nucleotide diversity analysis provides an assessment of a narrow genetic base within the chickpea cultivars. We have developed a resource for genetic markers by comparing the genome sequences of one wild and three cultivated chickpea genotypes. The draft genome sequence is expected to facilitate genetic enhancement and breeding to develop improved chickpea varieties.