A mitochondrial genome with a reversed transmission route in the Mediterranean mussel Mytilus galloprovincialis

Species of the marine mussel genus Mytilus are known to contain two mitochondrial genomes, one transmitted maternally (the F genome) and the other paternally (the M genome). The two genomes have diverged by more than 20% in DNA sequence. Here we present the complete sequence of a third genome, genome C, which we found in the sperm of a Mytilus galloprovincialis male. The coding part of the new genome resembles in sequence the F genome, from which it differs by about 2% on average, but differs from the M genome by as much as the F from the M. Its major control region (CR) is more than three times larger than that of the F or the M genome and consists of repeated sequence domains of the CR of the M genome flanked by domains of the CR of the F genome. We present a sequence of events that reconstruct most parsimoniously the derivation of the C genome from the F and M genomes. The sequence consists of a duplication of CR elements of the M genome and subsequent insertion of these tandemly repeated elements in the F genome by recombination. The fact that the C genome was found as the only mitochondrial genome in the sperm of the male from which it was extracted suggests that it is transmitted paternally.     

Mutational equilibrium model of genome size evolution

The paper describes a mutational equilibrium model of genome size evolution. This model is different from both adaptive and junk DNA models of genome size evolution in that it does not assume that genome size is maintained either by positive or stabilizing selection for the optimum genome size (as in adaptive theories) or by purifying selection against too much junk DNA (as in junk DNA theories). Instead the genome size is suggested to evolve until the loss of DNA through more frequent small deletions is equal to the rate of DNA gain through more frequent long insertions. The empirical basis for this theory is the finding of a strong correlation and of a clear power-function relationship between the rate of mutational DNA loss (per bp) through small deletions and genome size in animals. Genome size scales as a negative 1.3 power function of the deletion rate per nucleotide. Such a relationship is not predicted by either adaptive or junk DNA theories. However, if genome size is maintained at equilibrium by the balance of mutational forces, this empirilical relationship can be readily accommodated. Within this framework, this finding would imply that the rate of DNA gain through large insertions scales up a quarter-power function of genome size. On this view, as genome size grows, the rate of growth through large insertions is increasing as a quarter power function of genome size and the rate of DNA loss through small deletions increases linearly, until eventually, at the stable equilibrium genome size value, rates of growth and loss equal each other. The current data also suggest that the long-term variation is genome size in animals is brought about to a significant extent by changes in the intrinsic rates of DNA loss through small deletions. Both the origin of mutational biases and the adaptive consequences of such a mode of evolution of genome size are discussed.     

Genome size of 14 species of fireflies (Insecta,Coleoptera, Lampyridae)

Eukaryotic genome size data are important both as the basis for comparative research into genome evolution and as estimators of the cost and difficulty of genome sequencing programs for non-model organisms.In this study,the genome size of 14 species of fireflies (Lampyridae) (two genera in Lampyrinae,three genera in Luciolinae,and one genus in subfamily incertae sedis) were estimated by propidium iodide (PI)-based flow cytometry.The haploid genome sizes of Lampyridae ranged from 0.42 to 1.31 pg,a 3.1-fold span.Genome sizes of the fireflies varied within the tested subfamilies and genera.Lamprigera and Pyrocoelia species had large and small genome sizes,respectively.No correlation was found between genome size and morphological traits such as body length,body width,eye width,and antennal length.Our data provide additional information on genome size estimation of the firefly family Lampyridae.Furthermore,this study will help clarify the cost and difficulty of genome sequencing programs for non-model organisms and will help promote studies on firefly genome evolution.     

Old can be new again: HAPPY whole genome sequencing, mapping and assembly

During the last three decades, both genome mapping and sequencing methods have advanced significantly to provide a foundation for scientists to understand genome structures and functions in many species. Generally speaking, genome mapping relies on genome sequencing to provide basic materials, such as DNA probes and markers for their localizations, thus constructing the maps. On the other hand, genome sequencing often requires a high-resolution map as a skeleton for whole genome assembly. However, both genome mapping and sequencing have never come together in one pipeline. After reviewing mapping and next-generation sequencing methods, we would like to share our thoughts with the genome community on how to combine the HAPPY mapping technique with the new-generation sequencing, thus integrating two systems into one pipeline, called HAPPY pipeline. The pipeline starts with preparation of a HAPPY panel, followed by multiple displacement amplification for producing a relatively large quantity of DNA. Instead of conventional marker genotyping, the amplified panel DNA samples are subject to new-generation sequencing with barcode method, which allows us to determine the presence/absence of a sequence contig as a traditional marker in the HAPPY panel. Statistical analysis will then be performed to infer how close or how far away from each other these contigs are within a genome and order the whole genome sequence assembly as well. We believe that such a universal approach will play an important role in genome sequencing, mapping, and assembly of many species; thus advancing genome science and its applications in biomedicine and agriculture.     

E value cutoff and eukaryotic genome content phylogenetics

Genome content analysis has been used as a source of phylogenetic information in large prokaryotic tree of life studies. Recently the sequencing of many eukaryotic genomes has allowed for the similar use of genome content analysis for these organisms too. In this communication we examine the utility of genome content analysis for recovering phylogenetic patterns in several eukaryotic groups. By constructing multiple matrices using different e value cutoffs we examine the dynamics of altering the e value cutoff on five eukaryotic genome data sets. Our analysis indicates that the e value cutoff that is used as a criterion in the construction of the genome content matrix is a critical factor in both the accuracy and information content of the analysis. Strikingly, genome content by itself is not a reliable or accurate source of characters for phylogenetic analysis of the taxa in the five data sets we analyzed. We discuss two problems--small genome attraction and genome duplications as being involved in the rather poor performance of genome content data in recovering eukaryotic phylogeny.     

Repetitive DNA variation and pivotal-differential evolution of wild wheats.

Several polyploid species in the genus Triticum contain a U genome derived from the diploid T. umbellulatum. In these species, the U genome is considered to be unmodified from the diploid based on chromosome pairing analysis, and it is referred to as pivotal. The additional genome(s) are considered to be modified, and they are thus referred to as differential genomes. The M genome derived from the diploid T. comosum is found in many U genome polyploids. In this study, we cloned three repetitive DNA sequences found primarily in the U genome and two repetitive DNA sequences found primarily in the M genome. We used these to monitor variation for these sequences in a large set of species containing U and M genomes. Investigation of sympatric and allopatric accessions of polyploid species did not show repetitive DNA similarities among sympatric species. This result does not support the idea that the polyploid species are continually exchanging genetic information through introgression. However, it is also possible that repetitive DNA is not a suitable means of addressing the question of introgression. The U genomes of both diploid and polyploid U genome species were similar regarding hybridization patterns observed with U genome probes. Much more variation was found both among diploid T. comosum accessions and polyploids containing M genomes. The observed variation supports the cytogenetic evidence that the M genome is more variable than the U genome. It also raises the possibility that the differential nature of the M genome may be due to variation within the diploid T. comosum, as well as among polyploid M genome species and accessions.     

GENOMICS IN THE LIGHT OF EVOLUTIONARY TRANSITIONS

Molecular biology has entrenched the gene as the basic hereditary unit and genomes are often considered little more than collections of genes. However, new concepts and genomic data have emerged, which suggest that the genome has a unique place in the hierarchy of life. Despite this, a framework for the genome as a major evolutionary transition has not been fully developed. Instead, genome origin and evolution are frequently considered as a series of neutral or nonadaptive events. In this article, we argue for a Darwinian multilevel selection interpretation for the origin of the genome. We base our arguments on the multilevel selection theory of hypercycles of cooperative interacting genes and predictions that gene‐level trade‐offs in viability and reproduction can help drive evolutionary transitions. We consider genomic data involving mobile genetic elements as a test case of our view. A new concept of the genome as a discrete evolutionary unit emerges and the gene–genome juncture is positioned as a major evolutionary transition in individuality. This framework offers a fresh perspective on the origin of macromolecular life and sets the scene for a new, emerging line of inquiry—the evolutionary ecology of the genome.     

鸡基因组研究新进展

鸡基因组测序草图的完成标志着禽类功能基因组时代的到来。鸡不仅是全世界广泛饲养且有重要经济价值的禽类,而且是极具生命科学研究价值的模式动物。因此,鸡基因组测序草图的完成将对遗传育种和生物学研究有重要的影响。本文综述了近年来鸡基因组研究的最新进展,主要内容包括鸡基因组的有关数据、物理图谱、遗传连锁图谱、比较基因组学、序列表达标签、生物信息学等方面所取得的成绩,同时对鸡基因组研究结果的应用前景进行了展望。     

Genome phylogenetic analysis based on extended gene contents

With the rapid growth of entire genome data, whole-genome approaches such as gene content become popular for genome phylogeny inference, including the tree of life. However, the underlying model for genome evolution is unclear, and the proposed (ad hoc) genome distance measure may violate the additivity. In this article, we formulate a stochastic framework for genome evolution, which provides a basis for defining an additive genome distance. However, we show that it is difficult to utilize the typical gene content data-i.e., the presence or absence of gene families across genomes-to estimate the genome distance. We solve this problem by introducing the concept of extended gene content; that is, the status of a gene family in a given genome could be absence, presence as single copy, or presence as duplicates, any of which can be used to estimate the genome distance and phylogenetic inference. Computer simulation shows that the new tree-making method is efficient, consistent, and fairly robust. The example of 35 microbial complete genomes demonstrates that it is useful not only to study the universal tree of life but also to explore the evolutionary pattern of genomes.     

Whole genome sequencing and its applications in medical genetics

Fundamental improvement was made for genome sequencing since the next-generation sequencing (NGS) came out in the 2000s. The newer technologies make use of the power of massively-parallel short-read DNA sequencing, genome alignment and assembly methods to digitally and rapidly search the genomes on a revolutionary scale, which enable large-scale whole genome sequencing (WGS) accessible and practical for researchers. Nowadays, whole genome sequencing is more and more prevalent in detecting the genetics of diseases, studying causative relations with cancers, making genome-level comparative analysis, reconstruction of human population history, and giving clinical implications and instructions. In this review, we first give a typical pipeline of whole genome sequencing, including the lab template preparation, sequencing, genome assembling and quality control, variants calling and annotations. We compare the difference between whole genome and whole exome sequencing (WES), and explore a wide range of applications of whole genome sequencing for both mendelian diseases and complex diseases in medical genetics. We highlight the impact of whole genome sequencing in cancer studies, regulatory variant analysis, predictive medicine and precision medicine, as well as discuss the challenges of the whole genome sequencing.      

trans-dominant inhibition of human hepatitis delta virus genome replication.

Infection with hepatitis delta virus (HDV) is an important cause of acute and chronic liver disease and can be rapidly fatal. Sequencing of the HDV RNA genome has revealed variability at the C-terminal end of the delta antigen reading frame. One genome type (termed the S genome) synthesizes a 24-kDa protein thought to be required for genome replication. Another genome type (termed the L genome) extends the reading frame by 19 amino acids as a result of a single base change. Replication of the S and L genomes was studied in cultured fibroblasts. While the S genome efficiently initiated genome replication, the L genome did not. Moreover, in a codelivery experiment, L genome RNA inhibited replication of the S genome. Potent trans inhibition was also observed following cotransfection of the S genome and a plasmid encoding the larger delta antigen. Mutational analysis indicated that the inhibitory activity was not a simple function of the large delta antigen reading frame's extra length. Implications for the viral life cycle, clinical infection, and potential treatment are discussed.     

Whole-genome sequencing of eukaryotes: From sequencing of DNA fragments to a genome assembly

Rapid advances in sequencing technologies of second- and even third-generation made the whole genome sequencing a routine procedure. However, the methods for assembling of the obtained sequences and its results require special consideration. Modern assemblers are based on heuristic algorithms, which lead to fragmented genome assembly composed of scaffolds and contigs of different lengths, the order of which along the chromosome and belonging to a particular chromosome often remain unknown. In this regard, the resulting genome sequence can only be considered as a draft assembly. The principal improvement in the quality and reliability of a draft assembly can be achieved by targeted sequencing of the genome elements of different size, e.g., chromosomes, chromosomal regions, and DNA fragments cloned in different vectors, as well as using reference genome, optical mapping, and Hi-C technology. This approach, in addition to simplifying the assembly of the genome draft, will more accurately identify numerical and structural chromosomal variations and abnormalities of the genomes of the studied species. In this review, we discuss the key technologies for the genome sequencing and the de novo assembly, as well as different approaches to improve the quality of existing drafts of genome sequences.     

Random distribution pattern and non-adaptivity of genome size in a highly variable population of Festuca pallens

BACKGROUND AND AIMS: The spatial and statistical distribution of genome sizes and the adaptivity of genome size to some types of habitat, vegetation or microclimatic conditions were investigated in a tetraploid population of Festuca pallens. The population was previously documented to vary highly in genome size and is assumed as a model for the study of the initial stages of genome size differentiation. METHODS: Using DAPI flow cytometry, samples were measured repeatedly with diploid Festuca pallens as the internal standard. Altogether 172 plants from 57 plots (2.25 m(2)), distributed in contrasting habitats over the whole locality in South Moravia, Czech Republic, were sampled. The differences in DNA content were confirmed by the double peaks of simultaneously measured samples. KEY RESULTS: At maximum, a 1.115-fold difference in genome size was observed. The statistical distribution of genome sizes was found to be continuous and best fits the extreme (Gumbel) distribution with rare occurrences of extremely large genomes (positive-skewed), as it is similar for the log-normal distribution of the whole Angiosperms. Even plants from the same plot frequently varied considerably in genome size and the spatial distribution of genome sizes was generally random and unautocorrelated (P > 0.05). The observed spatial pattern and the overall lack of correlations of genome size with recognized vegetation types or microclimatic conditions indicate the absence of ecological adaptivity of genome size in the studied population. CONCLUSIONS: These experimental data on intraspecific genome size variability in Festuca pallens argue for the absence of natural selection and the selective non-significance of genome size in the initial stages of genome size differentiation, and corroborate the current hypothetical model of genome size evolution in Angiosperms (Bennetzen et al., 2005, Annals of Botany 95: 127-132).     

水稻和其他禾本科植物基因组多倍体起源的证据

基因加倍(Gene duplication)被认为是进化的加速器。古老的基因组加倍事件已经在多个物种中被确定,包括酵母、脊椎动物以及拟南芥等。本研究发现水稻基因组同样存在全基因组加倍事件,大概发生在禾谷类作物分化之前,距今约7000万年。在水稻基因组中,共找到117个加倍区段(Duplicated block),分布在水稻的全部12条染色体,覆盖约60％的水稻基因组。在加倍区段,大约有20％的基因保留了加倍后的姊妹基因对(Duplicated pairs)。与此形成鲜明对照的是加倍区段的转录因子保留了60％的姊妹基因。禾本科植物全基因组加倍事件的确定对研究禾本科植物基因组的进化具有重要影响,暗示了多倍体化及随后的基因丢失、染色体重排等在禾谷类物种分化中扮演了重要角色。     

Toward sequencing the Tetrahymena genome: exploiting the gift of nuclear dimorphism

Important scientific discoveries have utilized the unique advantages of Tetrahymena thermophila as a research organism. Recently developed molecular genetic manipulations allow full exploitation of the many scientific dividends that would result from having its genome sequenced. As a typical ciliated protozoan, Tetrahymena exhibits "nuclear dimorphism". It possesses two differentiated forms of its nuclear genome: a globally repressed, diploid germline or micronuclear genome, and a polyploid, site-specifically fragmented somatic or macronuclear genome. The macronuclear genome is, in effect, a natural, large-insert library of the micronuclear genome. This presentation describes how the gifts of nuclear dimorphism are being exploited in the experimental analysis of molecular and cell biology. Mechanisms present in humans that are either absent in other eukaryotic microbial model systems, or not as readily accessible in them as in Tetrahymena, are especially relevant. This presentation also reviews unique tools generated by nuclear dimorphism that are being used for genetically and physically mapping the Tetrahymena genome.     

Comparison of rice and Arabidopsis annotation

Several versions of the rice genome were published in 2002, providing a first overview of the genome content of this model monocot. At the same time, the genome of the model dicot, Arabidopsis thaliana, reached a new level of annotation as thousands of full-length cDNA sequences were integrated with the genome sequence.     

Diagnosis of rotavirus infection with cloned cDNA copies of viral genome segments.

The diagnostic potential of cloned cDNA copies of human rotavirus (strain WA) genome segments for the detection of rotavirus in clinical specimens has been determined. A hybridization assay in which a mixture of 32P-labeled cDNAs representing the 11 rotavirus segments was used as a probe compared favorably with three frequently used diagnostic tests for rotavirus in terms of both specificity and sensitivity. Significantly, clinical isolates could be readily distinguished when cloned cDNA copies of individual genome segments were used independently as a probe. In assays in which genome RNA from rotaviruses of known subgroups and serotypes were tested, cloned probes that encode nonstructural viral proteins hybridized efficiently to genome RNAs of all strains, whereas cloned probes corresponding to genome segments 6 and 9 exhibited the potential for differentiating strains of different subgroups and serotypes. Cloned cDNA copies of rotavirus genome segments therefore offer considerable potential for improved general diagnosis of rotavirus in clinical specimens, as well as for epidemiological studies in which virus isolates can be distinguished on the basis of nucleotide sequence homology of individual genome segments.     

Genomic organization of selected genes in the small monogonont rotifer, Brachionus koreanus

Information of genome structure with its size variation may provide important clues for evolutionary processes at lower taxon level in eukaryotes. Here, we analyzed the compact genome structure of the monogonont rotifer, Brachionus koreanus in the light of transphyletic genome comparison and economic genome usage. To confirm the genome compactness of B. koreanus, we compared the genomic structure of several selected genes with those of human and pufferfish. For example, one of the large genes, DNA-dependent protein kinase (DNA-PK) with dimeric protein Ku70 and Ku80, showed high similarity, even though genomic DNA lengths were quite different. The replication protein As (RPAs) as a heterotrimeric protein also showed a compact genomic structure including all the essential domains and motifs in B. koreanus. Regarding transmembrane protein-containing genes, the B. koreanus P-glycoprotein (P-gp) showed exactly the same topology of the TM domain compared to those of human and pufferfish, even though it had a compact genome structure. In addition, the gene structure of an inducible repair enzyme O(6)-methylguanine DNA methyltransferase (O(6)-MGMT) of B. koreanus showed the highest compactness among the genes tested. The objective of this report is to evaluate the potential for whole genome sequencing and functional genomic research using the monogonont rotifer B. koreanus as a non-model organism that plays important roles in aquatic food-webs. Subsequently, we discussed possible reasons for compact genome structures as well as small and fewer introns from several perspectives. We conclude that the small size genome of B. koreanus would make this species potentially useful for comparative genome structure analysis of non-model species through whole genome sequencing and genetic mapping.     

Use of low-coverage, large-insert, short-read data for rapid and accurate generation of enhanced-quality draft Pseudomonas genome sequences

Next-generation genomic technology has both greatly accelerated the pace of genome research as well as increased our reliance on draft genome sequences. While groups such as the Genomics Standards Consortium have made strong efforts to promote genome standards there is a still a general lack of uniformity among published draft genomes, leading to challenges for downstream comparative analyses. This lack of uniformity is a particular problem when using standard draft genomes that frequently have large numbers of low-quality sequencing tracts. Here we present a proposal for an "enhanced-quality draft" genome that identifies at least 95% of the coding sequences, thereby effectively providing a full accounting of the genic component of the genome. Enhanced-quality draft genomes are easily attainable through a combination of small- and large-insert next-generation, paired-end sequencing. We illustrate the generation of an enhanced-quality draft genome by re-sequencing the plant pathogenic bacterium Pseudomonas syringae pv. phaseolicola 1448A (Pph 1448A), which has a published, closed genome sequence of 5.93 Mbp. We use a combination of Illumina paired-end and mate-pair sequencing, and surprisingly find that de novo assemblies with 100x paired-end coverage and mate-pair sequencing with as low as low as 2-5x coverage are substantially better than assemblies based on higher coverage. The rapid and low-cost generation of large numbers of enhanced-quality draft genome sequences will be of particular value for microbial diagnostics and biosecurity, which rely on precise discrimination of potentially dangerous clones from closely related benign strains.