Genomic structure and sequence variation of a 3.3-kb repeat DNA element of the kangaroo rat, Dipodomys ordii

The genomic structure and sequence variation of a 3.3-kb repeat DNA element, representing 5% of the genome of the kangaroo rat Dipodomys ordii, has been investigated. Most of the repeats are arranged in tandem arrays of 50 kb or more. Thirteen randomly selected genomic clones have been mapped with twelve restriction enzymes. The frequency of sequence divergence in the genomic clones is 0.5%. The clone maps and the genomic structure studies have permitted the characterization of a number of variant members of the 3.3-kb repeat family. The genomic organization of the repeat resembles that for repeated DNAs found in large tandem arrays or satellites.     

Recent amplification of the kangaroo endogenous retrovirus, KERV, limited to the centromere

Mammalian retrotransposons, transposable elements that are processed through an RNA intermediate, are categorized as short interspersed elements (SINEs), long interspersed elements (LINEs), and long terminal repeat (LTR) retroelements, which include endogenous retroviruses. The ability of transposable elements to autonomously amplify led to their initial characterization as selfish or junk DNA; however, it is now known that they may acquire specific cellular functions in a genome and are implicated in host defense mechanisms as well as in genome evolution. Interactions between classes of transposable elements may exert a markedly different and potentially more significant effect on a genome than interactions between members of a single class of transposable elements. We examined the genomic structure and evolution of the kangaroo endogenous retrovirus (KERV) in the marsupial genus Macropus. The complete proviral structure of the kangaroo endogenous retrovirus, phylogenetic relationship among relative retroviruses, and expression of this virus in both Macropus rufogriseus and M. eugenii are presented for the first time. In addition, we show the relative copy number and distribution of the kangaroo endogenous retrovirus in the Macropus genus. Our data indicate that amplification of the kangaroo endogenous retrovirus occurred in a lineage-specific fashion, is restricted to the centromeres, and is not correlated with LINE depletion. Finally, analysis of KERV long terminal repeat sequences using massively parallel sequencing indicates that the recent amplification in M. rufogriseus is likely due to duplications and concerted evolution rather than a high number of independent insertion events.     

Isolation of a potentially functional HPRT processed pseudogene from the hill kangaroo Macropus robustus

A highly conserved hypoxanthine phosphoribosyltransferase processed pseudogene (KPH) has been isolated from a female kangaroo (Macropus robustus) λEMBL3 genomic library. The pseudogene contains only transcribed material with all of the introns precisely removed and has possible direct repeats at either end of the message. It has a 654-nucleotide open reading frame (ORF) from the Met start codon to the stop codon that contains no additions, deletions or premature stops relative to expressed HPRT genes and, therefore, the possibility exists that it is expressed in vivo. Possible CAAT and GC boxes are present in the region 5' to the ORF and a polyadenylation signal is present in the region 3' to the ORF. If not expressed, the age of the pseudogene is estimated to be 10.7 million years. We propose that integration into the genome occurred specifically in a homocopolymeric region within a highly repeated region unique to the kangaroo genome.     

The Motilin Gene Evolved a New Function in Kangaroo Rats and Kangaroo Mice (Dipodomyinae)

The motilin receptor gene was lost in the ancestral lineage of rodents. Subsequently, the gene encoding its ligand, motilin, has experienced different evolutionary fates. Previous genomic analyses had shown that the motilin gene (MLN) became a pseudogene independently in the lineages leading to the guinea pig and the common ancestor of the mouse and rat, yet an intact, and thus potentially functional, open reading frame for the MLN was preserved in the Dipodomys ordii genome. As only a single MLN haplotype from D. ordii was available, and this sequence is from a low coverage draft genome, it is possible that the intact MLN found in the draft kangaroo rat genome is an artifact, or represents an intermediate in the process of becoming a pseudogene. In order to establish whether an intact MLN is retained in kangaroo rats despite the loss of its specific receptor, and to investigate the evolutionary mechanisms underlying the retention of this gene sequence, we isolated MLN sequences from species that represent the diversity of the Dipodomyinae [the monophyletic Dipodomyinae subfamily consists of two genera: Dipodomys (kangaroo rats) and Microdipodops (kangaroo mice)]. The results demonstrate that the MLN sequence is well conserved in Dipodomyinae, and it codes for a predicted motilin peptide sequence possessing a conserved N-terminal pharmacophore and the potential to be processed and secreted as a hormone. The observations that the MLN evolved as a functional gene during the radiation of the Dipodomyinae, species that have lost their original motilin receptor, suggest that the MLN has undergone a lineage-specific physiological adaptation to a new function.     

Genomic contributions in livestock gene introgression programmes

The composition of the genome after introgression of a marker gene from a donor to a recipient breed was studied using analytical and simulation methods. Theoretical predictions of proportional genomic contributions, including donor linkage drag, from ancestors used at each generation of crossing after an introgression programme agreed closely with simulated results. The obligate drag, the donor genome surrounding the target locus that cannot be removed by subsequent selection, was also studied. It was shown that the number of backcross generations and the length of the chromosome affected proportional genomic contributions to the carrier chromosomes. Population structure had no significant effect on ancestral contributions and linkage drag but it did have an effect on the obligate drag whereby larger offspring groups resulted in smaller obligate drag. The implications for an introgression programme of the number of backcross generations, the population structure and the carrier chromosome length are discussed. The equations derived describing contributions to the genome from individuals from a given generation provide a framework to predict the genomic composition of a population after the introgression of a favourable donor allele. These ancestral contributions can be assigned a value and therefore allow the prediction of genetic lag.     

Genome size of man and animals relative to the plant Allium cepa

A direct Feulgen-cytophotometric comparison of the genomic DNA content (C value) was performed between the liliaceous plant species Allium cepa and a number of animal species to reassess the genome size ratios between plants and animals. These appeared unduly ambiguous as a consequence of divergent picogram estimates in several animal reference species. Taking 1C = 16.75 pg for Allium cepa, the estimates were (1C value in picograms): man, 3.11; Indian muntjak CCL 157 cell line, 2.68; domestic pig, 2.79; Chinese hamster, 2.66; CHO cell line, 2.73; laboratory rat, 2.65; mouse, 3.04; rat kangaroo Pt-K2 cell line, 4.21; fowl, 1.16; and the green toad, 4.30. These values are consistent with a number of independent absolute and relative DNA content determinations reported for animals, and therefore define a coherent set of animal and plant reference values for genome size determinations.     

kangaroo,a mobile element from Volvox carteri,is a member of a newly recognized third class of retrotransposons

Retrotransposons play an important role in the evolution of genomic structure and function. Here we report on the characterization of a novel retrotransposon called kangaroo from the multicellular green alga, Volvox carteri. kangaroo elements are highly mobile and their expression is developmentally regulated. They probably integrate via double-stranded, closed-circle DNA intermediates through the action of an encoded recombinase related to the lambda-site-specific integrase. Phylogenetic analysis indicates that kangaroo elements are closely related to other unorthodox retrotransposons including PAT (from a nematode), DIRS-1 (from Dictyostelium), and DrDIRS1 (from zebrafish). PAT and kangaroo both contain split direct repeat (SDR) termini, and here we show that DIRS-1 and DrDIRS1 elements contain terminal features structurally related to SDRs. Thus, these mobile elements appear to define a third class of retrotransposons (the DIRS1 group) that are unified by common structural features, genes, and integration mechanisms, all of which differ from those of LTR and conventional non-LTR retrotransposons.     

The sequence of the 3.3-kilobase repetitive element fromDipodomys ordii suggests a mechanism for its amplification and interspersion

Summary DNA from the kangaroo rat,Dipodomys ordii, contains a 3.3-kb, highly repeated sequence that is interspersed throughout the genome in small tandem clusters. One 3.3-kb unit has been cloned into pBR322 and the nucleotide sequence determined. The clone used was shown to be representative of the bulk of such sequences found in the genomic DNA. The sequence contains 10 homologous subunits each ca. 260 bp in length. Comparison of these to one another yielded a 258-bp consensus sequence containing a 35-bp terminal inverted repeat. Two unique stretches also occur. One of these contains a region that could serve as a promoter for RNA polymerase III; the other contains a sequence related to the ARS sequences of yeast. It is proposed that an ancestral sequence similar to the consensus sequence was amplified to 10 or more units, and that, subsequently, two other sequences were inserted. The properties of these insertions may have led to the dispersal of the sequence throughout the genome.     

Phylogenetic relationships of the Banded Hare wallaby (Lagostrophus fasciatus) and a map of the kangaroo mitochondrial control region

The complete mitochondrial genome of the endangered Banded Hare wallaby ( Lagostrophus fasciatus ) was sequenced and used for phylogenetic analysis. The data set consisted of 10 377 nucleotides (3459 amino acids) from three kangaroo species. The phylogenetic analyses strongly supported the hypothesis that the Banded Hare wallaby is the sister-group of the wallaroo (subfamily Macropodidae). In addition to the phylogenetic reconstruction, the mt control region, or d -loop, from Australian marsupials has been mapped for the first time. The results show that the organization of the kangaroo control region is similar to that of placental mammals. The presence of a duplicated CSB-1 block found in all three kangaroo species is an uncommon feature of mammalian mt DNA. The CSB domain was found to be the most variable region in the control region, followed by a less variable ETAS domain.     

Spatial organization of the mouse genome and its role in recurrent chromosomal translocations

The extent to which the three-dimensional organization of the genome contributes to chromosomal translocations is an important question in cancer genomics. We generated a high-resolution Hi-C spatial organization map of the G1-arrested mouse pro-B cell genome and used high-throughput genome-wide translocation sequencing to map translocations from target DNA double-strand breaks (DSBs) within it. RAG endonuclease-cleaved antigen-receptor loci are dominant translocation partners for target DSBs regardless of genomic position, reflecting high-frequency DSBs at these loci and their colocalization in a fraction of cells. To directly assess spatial proximity contributions, we normalized genomic DSBs via ionizing radiation. Under these conditions, translocations were highly enriched in cis along single chromosomes containing target DSBs and within other chromosomes and subchromosomal domains in a manner directly related to pre-existing spatial proximity. By combining two high-throughput genomic methods in a genetically tractable system, we provide a new lens for viewing cancer genomes.     

Evolution of the cancer genome

Human tumors result from an evolutionary process operating on somatic cells within tissues, whereby natural selection operates on the phenotypic variability generated by the accumulation of genetic, genomic and epigenetic alterations. This somatic evolution leads to adaptations such as increased proliferative, angiogenic, and invasive phenotypes. In this review we outline how cancer genomes are beginning to be investigated from an evolutionary perspective. We describe recent progress in the cataloging of somatic genetic and genomic alterations, and investigate the contributions of germline as well as epigenetic factors to cancer genome evolution. Finally, we outline the challenges facing researchers who investigate the processes driving the evolution of the cancer genome.     

Impact of genome-wide functional analyses on cell biology research

The availability of complete genome sequences for a variety of organisms, coupled with novel approaches that allow evaluation of the functions of thousands of genes in parallel, have the potential to greatly impact on cell biology research. Functional genomic approaches in Saccharomyces cerevisiae are beginning to make significant contributions to the understanding of complex biological systems.     

The evolution of host specialization in the vertebrate gut symbiont Lactobacillus reuteri

Recent research has provided mechanistic insight into the important contributions of the gut microbiota to vertebrate biology, but questions remain about the evolutionary processes that have shaped this symbiosis. In the present study, we showed in experiments with gnotobiotic mice that the evolution of Lactobacillus reuteri with rodents resulted in the emergence of host specialization. To identify genomic events marking adaptations to the murine host, we compared the genome of the rodent isolate L. reuteri 100-23 with that of the human isolate L. reuteri F275, and we identified hundreds of genes that were specific to each strain. In order to differentiate true host-specific genome content from strain-level differences, comparative genome hybridizations were performed to query 57 L. reuteri strains originating from six different vertebrate hosts in combination with genome sequence comparisons of nine strains encompassing five phylogenetic lineages of the species. This approach revealed that rodent strains, although showing a high degree of genomic plasticity, possessed a specific genome inventory that was rare or absent in strains from other vertebrate hosts. The distinct genome content of L. reuteri lineages reflected the niche characteristics in the gastrointestinal tracts of their respective hosts, and inactivation of seven out of eight representative rodent-specific genes in L. reuteri 100-23 resulted in impaired ecological performance in the gut of mice. The comparative genomic analyses suggested fundamentally different trends of genome evolution in rodent and human L. reuteri populations, with the former possessing a large and adaptable pan-genome while the latter being subjected to a process of reductive evolution. In conclusion, this study provided experimental evidence and a molecular basis for the evolution of host specificity in a vertebrate gut symbiont, and it identified genomic events that have shaped this process.     

How do we compare hundreds of bacterial genomes?

The genomic revolution is fully upon us in 2006 and the pace of discovery is set to accelerate with the emergence of ultra-high-throughput sequencing technologies. Our complete genome collection of bacteria and archaea continues to grow in number and diversity, as genome sequencing is applied to an array of new problems, from the characterization of the pan-genome to the detection of mutation after experimentation and the exploration of microbial communities in unprecedented detail. The benefits of large-scale comparative genomic analyses are driving the community to think about how to manage our public collections of genomes in novel ways.     

SNP genotyping and population genomics from expressed sequences – current advances and future possibilities

With the rapid increase in production of genetic data from new sequencing technologies, a myriad of new ways to study genomic patterns in nonmodel organisms are currently possible. Because genome assembly still remains a complicated procedure, and because the functional role of much of the genome is unclear, focusing on SNP genotyping from expressed sequences provides a cost‐effective way to reduce complexity while still retaining functionally relevant information. This review summarizes current methods, identifies ways that using expressed sequence data benefits population genomic inference and explores how current practitioners evaluate and overcome challenges that are commonly encountered. We focus particularly on the additional power of functional analysis provided by expressed sequence data and how these analyses push beyond allele pattern data available from nonfunction genomic approaches. The massive data sets generated by these approaches create opportunities and problems as well – especially false positives. We discuss methods available to validate results from expressed SNP genotyping assays, new approaches that sidestep use of mRNA and review follow‐up experiments that can focus on evolutionary mechanisms acting across the genome.     

植物多倍体中的基因组印记

植物多倍体在自然界中广泛存在,这说明拥有多套遗传物质使得多倍体的适应进化具有优势。新多倍体形成后,一些基因组范围的变化较迅速地发生在多倍体形成开端,另一些在长期进化中发生。由于受到遗传、表观等因素的影响,亲本对于新形成多倍体基因组的贡献不均衡。这种偏向于某个亲本基因组的显性优势,称为基因组印记。植物多倍体中的基因组印记表现为基因组偏向性的序列消除、不均衡基因表达、基因沉默,这些受到基因组合并及DNA甲基化、核仁显性等表观因素影响。本文旨在为多倍体基因组进化及育种的相关研究提供参考。     

The canine era: the rise of a biomedical model

Since the annotation of its genome a decade ago, the dog has proven to be an excellent model for the study of inherited diseases. A large variety of spontaneous simple and complex phenotypes occur in dogs, providing physiologically relevant models to corresponding human conditions. In addition, gene discovery is facilitated in clinically less heterogeneous purebred dogs with closed population structures because smaller study cohorts and fewer markers are often sufficient to expose causal variants. Here, we review the development of genomic resources from microsatellites to whole‐genome sequencing and give examples of successful findings that have followed the technological progress. The increasing amount of whole‐genome sequence data warrants better functional annotation of the canine genome to more effectively utilise this unique model to understand genetic contributions in morphological, behavioural and other complex traits.     

Ecological perspectives on the sequenced genome collection

Our complete genome collection is one of our most valuable biological resources. A key challenge for the future is the interpretation of these genomes from an ecological perspective. In this review, we discuss current work at this increasingly important interface. In particular, we review ongoing work aimed at developing high quality data sets that combine ecological, environmental, evolutionary and genomic information. Such data will help to identify biases in the sequence collection and facilitate future discoveries about the nature of ecological adaptation at the genome level. These efforts will be greatly enhanced by the contributions of ecologists.     

Quantifying the relative contributions of the X chromosome,autosomes, and mitochondrial genome to local adaptation*

During local adaptation with gene flow, some regions of the genome are inherently more responsive to selection than others. Recent theory predicts that X‐linked genes should disproportionately contribute to local adaptation relative to other genomic regions, yet this prediction remains to be tested. We carried out a multigeneration crossing scheme, using two cline‐end populations of Drosophila melanogaster, to estimate the relative contributions of the X chromosome, autosomes, and mitochondrial genome to divergence in four traits involved in local adaptation (wing size, resistance to heat, desiccation, and starvation stresses). We found that the mitochondrial genome and autosomes contributed significantly to clinal divergence in three of the four traits. In contrast, the X made no significant contribution to divergence in these traits. Given the small size of the mitochondrial genome, our results indicate that it plays a surprisingly large role in clinal adaptation. In contrast, the X, which represents roughly 20% of the Drosophila genome, contributes negligibly—a pattern that conflicts with theoretical predictions. These patterns reinforce recent work implying a central role of mitochondria in climatic adaptation, and suggest that different genomic regions may play fundamentally different roles in processes of divergence with gene flow.