Evolutionary genomics of pathogenic bacteria

Complete genome sequences are now available for multiple strains of several bacterial pathogens and comparative analysis of these sequences is providing important insights into the evolution of bacterial virulence. Recently, DNA microarray analysis of many strains of several pathogenic species has contributed to our understanding of bacterial diversity, evolution and pathogenesis. Comparative genomics has shown that pathogens such as Escherichia coli, Helicobacter pylori and Staphylococcus aureus contain extensive variation in gene content whereas Mycobacterium tuberculosis nucleotide divergence is very limited. Overall, these approaches are proving to be a powerful means of exploring bacterial diversity, and are providing an important framework for the analysis of the evolution of pathogenesis and the development of novel antimicrobial agents.     

Genome of Helicobacter pylori strain 908

Helicobacter pylori is a genetically diverse and coevolved pathogen inhabiting human gastric niches and leading to a spectrum of gastric diseases in susceptible populations. We describe the genome sequence of H. pylori 908, which was originally isolated from an African patient living in France who suffered with recrudescent duodenal ulcer disease. The strain was found to be phylogenetically related to H. pylori J99, and its comparative analysis revealed several specific genome features and novel insertion-deletion and substitution events. The genome sequence revealed several strain-specific deletions and/or gain of genes exclusively present in HP908 compared with different sequenced genomes already available in the public domain. Comparative and functional genomics of HP908 and its subclones will be important in understanding genomic plasticity and the capacity to colonize and persist in a changing host environment.     

Draft genome sequences of the biocontrol bacterium Mitsuaria sp. strain H24L5A

Mitsuaria sp. strain H24L5A is a plant-associated bacterium with proven capacities to suppress plant pathogens. Here, we report the draft genome sequences and automatic annotation of H24L5A. Comparative genomic analysis indicates H24L5A's similarity to the Leptothrix and Methylibium species, as well as several genes potentially contributing to its biocontrol activities.     

Complete mitochondrial genome sequence of the phytopathogenic fungus Penicillium digitatum and comparative analysis of closely related species

The complete mitochondrial genome of Penicillium digitatum (Pers.:Fr) Sacc is reported, the first time in a phytopathogenic Penicillium species. Comparative analysis revealed its close relationship to mitochondrial genomes of other Penicillium and Aspergillus species, both in gene content and in arrangement. The intron content of protein coding genes revealed several differences. The different exon-intron organization of Cytochrome Oxidase Subunit 1 genes indicated their common origin before the divergence of Penicillium and Aspergillus, and that, largely, their introns were transmitted vertically.     

Genomics of the evolutionary process

Comparative analysis of genome sequences has become the primary means by which functional elements are first identified, often preceding even the identification of their function. Although this approach capitalizes on the conservation of homologous functions, it has also been successful in identifying evolutionary novelties, including new genes and pathways. As I discuss here, the analysis of multiple alignments of sequences from species on a known phylogeny has provided rich detail about the heterogeneities in the process of genome changes. Inferences of positive selection acting on protein-encoding genes have provided clues about the role of adaptive evolution in the past. These methods also identify negatively selected genes, providing some clue to genes that are most likely to be mutable to a disease-causing state.     

Multi-Platform Next-Generation Sequencing of the Domestic Turkey (Meleagris gallopavo): Genome Assembly and Analysis

A synergistic combination of two next-generation sequencing platforms with a detailed comparative BAC physical contig map provided a cost-effective assembly of the genome sequence of the domestic turkey (Meleagris gallopavo). Heterozygosity of the sequenced source genome allowed discovery of more than 600,000 high quality single nucleotide variants. Despite this heterozygosity, the current genome assembly (∼1.1 Gb) includes 917 Mb of sequence assigned to specific turkey chromosomes. Annotation identified nearly 16,000 genes, with 15,093 recognized as protein coding and 611 as non-coding RNA genes. Comparative analysis of the turkey, chicken, and zebra finch genomes, and comparing avian to mammalian species, supports the characteristic stability of avian genomes and identifies genes unique to the avian lineage. Clear differences are seen in number and variety of genes of the avian immune system where expansions and novel genes are less frequent than examples of gene loss. The turkey genome sequence provides resources to further understand the evolution of vertebrate genomes and genetic variation underlying economically important quantitative traits in poultry. This integrated approach may be a model for providing both gene and chromosome level assemblies of other species with agricultural, ecological, and evolutionary interest.     

Microevolutionary genomics of bacteria

The availability of multiple complete genome sequences from the same species can facilitate attempts to systematically address basic questions in genome evolution. We refer to such efforts as "microevolutionary genomics". We report the results of comparative analyses of complete intraspecific genome (and proteome) sequences from four bacterial species--Chlamydophila pneumoniae, Escherichia coli, Helicobacter pylori and Neisseria meningitidis. Comparisons of average synonymous (K(s)) and nonsynonymous (K(a)) substitution rates were used to assess the influence of various biological factors on the rate of protein evolution. For example, E. coli experiences the most intense purifying selection of the species analyzed, and this may be due to the relatively larger population size of this species. In addition, essential genes were shown to be more evolutionarily conserved than nonessential genes in E. coli and duplicated genes have higher rates of evolution than unique genes for all species studied except C. pneumoniae. Different functional categories of genes were shown to evolve at significantly different rates emphasizing the role of category-specific functional constraints in determining evolutionary rates. Finally, functionally characterized genes tend to be conserved between strains, while uncharacterized genes are over-represented among the unique, strain-specific genes. This suggests the possibility that nonessential genes are responsible for driving the evolutionary diversification between strains.     

Comparative DNA sequence analysis of mapped wheat ESTs reveals the complexity of genome relationships between rice and wheat

The use of DNA sequence-based comparative genomics for evolutionary studies and for transferring information from model species to related large-genome species has revolutionized molecular genetics and breeding strategies for improving those crops. Comparative sequence analysis methods can be used to cross-reference genes between species maps, enhance the resolution of comparative maps, study patterns of gene evolution, identify conserved regions of the genomes, and facilitate interspecies gene cloning. In this study, 5,780 Triticeae ESTs that have been physically mapped using wheat (Triticum aestivum L.) deletion lines and segregating populations were compared using NCBI BLASTN to the first draft of the public rice (Oryza sativa L.) genome sequence data from 3,280 ordered BAC/PAC clones. A rice genome view of the homoeologous wheat genome locations based on sequence analysis shows general similarity to the previously published comparative maps based on Southern analysis of RFLP. For most rice chromosomes there is a preponderance of wheat genes from one or two wheat chromosomes. The physical locations of non-conserved regions were not consistent across rice chromosomes. Some wheat ESTs with multiple wheat genome locations are associated with the non-conserved regions of similarity between rice and wheat. The inverse view, showing the relationship between the wheat deletion map and rice genomic sequence, revealed the breakdown of gene content and order at the resolution conferred by the physical chromosome deletions in the wheat genome. An average of 35% of the putative single copy genes that were mapped to the most conserved bins matched rice chromosomes other than the one that was most similar. This suggests that there has been an abundance of rearrangements, insertions, deletions, and duplications eroding the wheat-rice genome relationship that may complicate the use of rice as a model for cross-species transfer of information in non-conserved regions.     

Review: Other Helicobacter species

This article is a review of the most important, accessible, and relevant literature published between April 2018 and April 2019 in the field of Helicobacter species other than Helicobacter pylori. The initial part of the review covers new insights regarding the presence of gastric and enterohepatic non‐H. pylori Helicobacter species (NHPH) in humans and animals, while the subsequent section focuses on the progress in our understanding of the pathogenicity and evolution of these species. Over the last year, relatively few cases of gastric NHPH infections in humans were published, with most NHPH infections being attributed to enterohepatic Helicobacters. A novel species, designated “Helicobacter caesarodunensis,” was isolated from the blood of a febrile patient and numerous cases of human Helicobacter cinaedi infections underlined this species as a true emerging pathogen. With regard to NHPH in animals, canine/feline gastric NHPH cause little or no harm in their natural host; however they can become opportunistic when translocated to the hepatobiliary tract. The role of enterohepatic Helicobacter species in colorectal tumors in pets has also been highlighted. Several studies in rodent models have further elucidated the mechanisms underlying the development of NHPH‐related disease, and the extra‐gastric effects of a Helicobacter suis infection on brain homeostasis was also studied. Comparative genomics facilitated a breakthrough in the evolutionary history of Helicobacter in general and NHPH in particular. Investigation of the genome of Helicobacter apodemus revealed particular traits with regard to its virulence factors. A range of compounds including mulberries, dietary fiber, ginseng, and avian eggs which target the gut microbiota have also been shown to affect Helicobacter growth, with a potential therapeutic utilization and increase in survival.     

Strain-specific genes of Helicobacter pylori: distribution, function and dynamics

Whole-genome clustering of the two available genome sequences of Helicobacter pylori strains 26695 and J99 allows the detection of 110 and 52 strain-specific genes, respectively. This set of strain-specific genes was compared with the sets obtained with other computational approaches of direct genome comparison as well as experimental data from microarray analysis. A considerable number of novel function assignments is possible using database-driven sequence annotation, although the function of the majority of the identified genes remains unknown. Using whole-genome clustering, it is also possible to detect species-specific genes by comparing the two H.pylori strains against the genome sequence of Campylobacter jejuni. It is interesting that the majority of strain-specific genes appear to be species specific. Finally, we introduce a novel approach to gene position analysis by employing measures from directional statistics. We show that although the two strains exhibit differences with respect to strain-specific gene distributions, this is due to the extensive genome rearrangements. If these are taken into account, a common pattern for the genome dynamics of the two Helicobacter strains emerges, suggestive of certain spatial constraints that may act as control mechanisms of gene flux.     

稻属植物的基因组进化

水稻所在的稻属(Oryza)共有24个左右的物种。由于野生稻含有大量的优良农艺性状基因, 在水稻遗传学研究中日益受到重视。随着国际稻属基因组计划的开展, 越来越多的稻属基因组序列被测定, 稻属成为进行比较、功能和进化基因组学研究的模式系统。近期开展的一系列研究对稻属不同基因组区段以及全基因组序列的比较分析, 揭示了稻属在基因组大小、基因移动、多倍体进化、常染色质到异染色质的转化以及着丝粒区域的进化等方面的分子机制。转座子的活性以及转座子因非均等重组或非法重组而造成的删除, 对稻属基因组的扩增和收缩具有重要作用。DNA双链断裂修复介导的基因移动, 特别是非同源末端连接, 是稻属基因组非共线性基因形成的主要来源。稻属基因组从常染色质到异染色质的转换过程, 伴随着转座子的大量扩增、基因片段的区段性和串联重复以及从基因组其他位置不断捕获异染色质基因。对稻属不同物种间基因拷贝数、特异基因和重要农艺性状基因的进化等研究, 可揭示稻属不同物种间表型和适应性差异的分子基础, 将加速水稻的育种和改良。     

High quality reference genome of drumstick tree(Moringa oleifera Lam.), a potential perennial crop

The drumstick tree(Moringa oleifera Lam.) is a perennial crop that has gained popularity in certain developing countries for its high-nutrition content and adaptability to arid and semi-arid environments. Here we report a high-quality draft genome sequence of M. oleifera. This assembly represents 91.78% of the estimated genome size and contains 19,465 protein-coding genes. Comparative genomic analysis between M. oleifera and related woody plant genomes helps clarify the general evolution of this species, while the identification of several species-specific gene families and positively selected genes in M. oleifera may help identify genes related to M. oleifera's high protein content, fast-growth, heat and stress tolerance. This reference genome greatly extends the basic research on M. oleifera, and may further promote applying genomics to enhanced breeding and improvement of M. oleifera.     

Analysis of a Leptospira interrogans locus containing DNA replication genes and a new IS,IS1502

Comparative bacterial genomics shows that even different isolates of the same bacterial species can vary significantly in gene content. An effective means to survey differences across whole genomes would be highly advantageous for understanding this variation. Here we show that suppression subtractive hybridization (SSH) provides high, representative coverage of regions that differ between similar genomes. Using Helicobacter pylori strains 26695 and J99 as a model, SSH identified approximately 95% of the unique open reading frames in each strain, showing that the approach is effective. Furthermore, combining data from parallel SSH experiments using different restriction enzymes significantly increased coverage compared to using a single enzyme. These results suggest a powerful approach for assessing genome differences among closely related strains when one member of the group has been completely sequenced.     

Recent genome duplications facilitate the phenotypic diversity of Hb repertoire in the Cyprinidae

Whole-genome duplications(WGDs) are an important contributor to phenotypic innovations in evolutionary history. The diversity of blood oxygen transport traits is the perfect reflection of physiological versatility for evolutionary success among vertebrates. In this study, the evolutionary changes of hemoglobin(Hb) repertoire driven by the recent genome duplications were detected in representative Cyprinidae fish, including eight diploid and four tetraploid species. Comparative genomic analysis revealed a substantial variation in both membership composition and intragenomic organization of Hb genes in these species.Phylogenetic reconstruction analyses were conducted to characterize the evolutionary history of these genes. Data were integrated with the expression profiles of the genes during ontogeny. Our results indicated that genome duplications facilitated the phenotypic diversity of the Hb gene family; each was associated with species-specific changes in gene content via gene loss and fusion after genome duplications. This led to repeated evolutionary transitions in the ontogenic regulation of Hb gene expression.Our results revealed that genome duplications helped to generate phenotypic changes in Cyprinidae Hb systems.     

Comparative Whole-Genome Analysis of Clinical Isolates Reveals Characteristic Architecture of Mycobacterium tuberculosis Pangenome

The tubercle complex consists of closely related mycobacterium species which appear to be variants of a single species. Comparative genome analysis of different strains could provide useful clues and insights into the genetic diversity of the species. We integrated genome assemblies of 96 strains from Mycobacterium tuberculosis complex (MTBC), which included 8 Indian clinical isolates sequenced and assembled in this study, to understand its pangenome architecture. We predicted genes for all the 96 strains and clustered their respective CDSs into homologous gene clusters (HGCs) to reveal a hard-core, soft-core and accessory genome component of MTBC. The hard-core (HGCs shared amongst 100% of the strains) was comprised of 2,066 gene clusters whereas the soft-core (HGCs shared amongst at least 95% of the strains) comprised of 3,374 gene clusters. The change in the core and accessory genome components when observed as a function of their size revealed that MTBC has an open pangenome. We identified 74 HGCs that were absent from reference strains H37Rv and H37Ra but were present in most of clinical isolates. We report PCR validation on 9 candidate genes depicting 7 genes completely absent from H37Rv and H37Ra whereas 2 genes shared partial homology with them accounting to probable insertion and deletion events. The pangenome approach is a promising tool for studying strain specific genetic differences occurring within species. We also suggest that since selecting appropriate target genes for typing purposes requires the expected target gene be present in all isolates being typed, therefore estimating the core-component of the species becomes a subject of prime importance.     

The chicken gene nomenclature committee report

Comparative genomics is an essential component of the post-genomic era. The chicken genome is the first avian genome to be sequenced and it will serve as a model for other avian species. Moreover, due to its unique evolutionary niche, the chicken genome can be used to understand evolution of functional elements and gene regulation in mammalian species. However comparative biology both within avian species and within amniotes is hampered due to the difficulty of recognising functional orthologs. This problem is compounded as different databases and sequence repositories proliferate and the names they assign to functional elements proliferate along with them. Currently, genes can be published under more than one name and one name sometimes refers to unrelated genes. Standardized gene nomenclature is necessary to facilitate communication between scientists and genomic resources. Moreover, it is important that this nomenclature be based on existing nomenclature efforts where possible to truly facilitate studies between different species. We report here the formation of the Chicken Gene Nomenclature Committee (CGNC), an international and centralized effort to provide standardized nomenclature for chicken genes. The CGNC works in conjunction with public resources such as NCBI and Ensembl and in consultation with existing nomenclature committees for human and mouse. The CGNC will develop standardized nomenclature in consultation with the research community and relies on the support of the research community to ensure that the nomenclature facilitates comparative and genomic studies.     

Genome structure analysis of molluscs revealed whole genome duplication and lineage specific repeat variation

Comparative genome structure analysis allows us to identify novel genes, repetitive sequences and gene duplications. To explore lineage-specific genomic changes of the molluscs that is good model for development of nervous system in invertebrate, we conducted comparative genome structure analyses of three molluscs, pygmy squid, nautilus and scallops using partial genome shotgun sequencing. Most effective elements on the genome structural changes are repetitive elements (REs) causing expansion of genome size and whole genome duplication producing large amount of novel functional genes. Therefore, we investigated variation and proportion of REs and whole genome duplication. We, first, identified variations of REs in the three molluscan genomes by homology-based and de novo RE detection. Proportion of REs were 9.2%, 4.0%, and 3.8% in the pygmy squid, nautilus and scallop, respectively. We, then, estimated genome size of the species as 2.1, 4.2 and 1.8 Gb, respectively, with 2× coverage frequency and DNA sequencing theory. We also performed a gene duplication assay based on coding genes, and found that large-scale duplication events occurred after divergence from the limpet Lottia, an out-group of the three molluscan species. Comparison of all the results suggested that RE expansion did not relate to the increase in genome size of nautilus. Despite close relationships to nautilus, the squid has the largest portion of REs and smaller genome size than nautilus. We also identified lineage-specific RE and gene-family expansions, possibly relate to acquisition of the most complicated eye and brain systems in the three species.     

Comparative mapping between<Emphasis Type="Italic"> Medicago sativa</Emphasis> and<Emphasis Type="Italic"> Pisum sativum</Emphasis>

Comparative genome analysis has been performed between alfalfa ( Medicago sativa) and pea ( Pisum sativum), species which represent two closely related tribes of the subfamily Papilionoideae with different basic chromosome numbers. The positions of genes on the most recent linkage map of diploid alfalfa were compared to those of homologous loci on the combined genetic map of pea to analyze the degree of co-linearity between their linkage groups. In addition to using unique genes, analysis of the map positions of multicopy (homologous) genes identified syntenic homologs (characterized by similar positions on the maps) and pinpointed the positions of non-syntenic homologs. The comparison revealed extensive conservation of gene order between alfalfa and pea. However, genetic rearrangements (due to breakage and reunion) were localized which can account for the difference in chromosome number (8 for alfalfa and 7 for pea). Based on these genetic events and our increasing knowledge of the genomic structure of pea, it was concluded that the difference in genome size between the two species (the pea genome is 5- to 10-fold larger than that of alfalfa) is not a consequence of genome duplication in pea. The high degree of synteny observed between pea and Medicago loci makes further map-based cloning of pea genes based on the genome resources now available for M. truncatula a promising strategy.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by W. R. McCombie