Lineage-specific biology revealed by a finished genome assembly of the mouse. PLoS Biol. 2009;7:e1000112. [PMID: 19468303 PMCID: PMC2680341 DOI: 10.1371/journal.pbio.1000112]

The origins and impact of primate segmental duplications

Duplicated sequences are substrates for the emergence of new genes and are an important source of genetic instability associated with rare and common diseases. Analyses of primate genomes have shown an increase in the proportion of interspersed segmental duplications (SDs) within the genomes of humans and great apes. This contrasts with other mammalian genomes that seem to have their recently duplicated sequences organized in a tandem configuration. In this review, we focus on the mechanistic origin and impact of this difference with respect to evolution, genetic diversity and primate phenotype. Although many genomes will be sequenced in the future, resolution of this aspect of genomic architecture still requires high quality sequences and detailed analyses.

Separating derived from ancestral features of mouse and human genomes

To take full advantage of the mouse as a model organism, it is essential to distinguish lineage-specific biology from what is shared between human and mouse. Investigations into shared genetic elements common to both have been well served by the draft human and mouse genome sequences. More recently, the virtually complete euchromatic sequences of the two reference genomes have been finished. These reveal a high ( approximately 5%) level of sequence duplications that had previously been recalcitrant to sequencing and assembly. Within these duplications lie large numbers of rodent- or primate-specific genes. In the present paper, we review the sequence properties of the two genomes, dwelling most on the duplications, deletions and insertions that separate each of them from their most recent common ancestor, approx. 90 million years ago. We consider the differences in gene numbers and repertoires between the two species, and speculate on their contributions to lineage-specific biology. Loss of ancient single-copy genes are rare, as are gains of new functional genes through retrotransposition. Instead, most changes to the gene repertoire have occurred in large multicopy families. It has been proposed that numbers of such 'environmental genes' rise and fall, and their sequences change, as adaptive responses to infection and other environmental pressures, including conspecific competition. Nevertheless, many such genes may be under little or no selection.

The evolution of human segmental duplications and the core duplicon hypothesis

Duplicated sequences are important sources of genetic instability and in the evolution of new gene function within species. Hominids have a preponderance of intrachromosomal duplications organized in an interspersed fashion, as opposed to tandem duplications, which are common in other mammalian genomes such as mouse, dog, and cow. Multiple lines of evidence, including sequence divergence, comparative primate genomes, and fluorescence in situ hybridization (FISH) analyses, point to an excess of segmental duplications in the common ancestor of humans and African great apes. We find that much of the interspersed human duplication architecture within chromosomes is focused around common sequence elements referred to as "core duplicons." These cores correspond to the expansion of gene families, some of which show signatures of positive selection and lack orthologs present in other mammalian species. This genomic architecture predisposes apes and humans not only to extensive genetic diversity, but also to large-scale structural diversity mediated by nonallelic homologous recombination. In humans, many de novo large-scale genomic changes mediated by these duplications are associated with neuropsychiatric and neurodevelopmental disease. We propose that the disadvantage of a high rate of new mutations is offset by the selective advantage of newly minted genes within the cores.

Two novel phosphatidylinositol-4-phosphate 5-kinase type Igamma splice variants expressed in human cells display distinctive cellular targeting

The generation of various phosphoinositide messenger molecules at distinct locations within the cell is mediated via the specific targeting of different isoforms and splice variants of phosphoinositide kinases. The lipid messenger PtdIns(4,5)P₂ is generated by several of these enzymes when targeted to distinct cellular compartments. Several splice variants of the type Iγ isoform of PIPK (PtdIns4P 5-kinase), which generate PtdIns(4,5)P₂, have been identified, and each splice variant is thought to serve a unique functional role within cells. Here, we have identified two novel C-terminal splice variants of PIPKIγ in human cells consisting of 700 and 707 amino acids. These two splice variants are expressed in multiple tissue types and display PIPK activity in vitro. Interestingly, both of these novel splice variants display distinct subcellular targeting. With the addition of these two new splice isoforms, there are minimally five PIPKIγ splice variants that have been identified in mammals. Therefore, we propose the use of the HUGO (Human Genome Organization) nomenclature in the naming of the splice isoforms. PIPKIγ_i4 (700 amino acids) is present in the nucleus, a targeting pattern that has not been previously observed in any PIPKIγ splice variant. PIPKIγ_i5 (707 amino acids) is targeted to intracellular vesicle-like structures, where it co-localizes with markers of several types of endosomal compartments. As occurs with other PIPKIγ splice variants, the distinctive C-terminal sequences of PIPKIγ_i4 and PIPKIγ_i5 may facilitate association with unique protein targeting factors, thereby localizing the kinases to their appropriate cellular subdomains for the site-specific generation of PtdIns(4,5)P₂.

Unearthing the roles of imprinted genes in the placenta

Mammalian fetal survival and growth are dependent on a well-established and functional placenta. Although transient, the placenta is the first organ to be formed during pregnancy and is responsible for important functions during development, such as the control of metabolism and fetal nutrition, gas and metabolite exchange, and endocrine control. Epigenetic marks and gene expression patterns in early development play an essential role in embryo and fetal development. Specifically, the epigenetic phenomenon known as genomic imprinting, represented by the non-equivalence of the paternal and maternal genome, may be one of the most important regulatory pathways involved in the development and function of the placenta in eutherian mammals. A lack of pattern or an imprecise pattern of genomic imprinting can lead to either embryonic losses or a disruption in fetal and placental development. Genetically modified animals present a powerful approach for revealing the interplay between gene expression and placental function in vivo and allow a single gene disruption to be analyzed, particularly focusing on its role in placenta function. In this paper, we review the recent transgenic strategies that have been successfully created in order to provide a better understanding of the epigenetic patterns of the placenta, with a special focus on imprinted genes. We summarize a number of phenotypes derived from the genetic manipulation of imprinted genes and other epigenetic modulators in an attempt to demonstrate that gene-targeting studies have contributed considerably to the knowledge of placentation and conceptus development.