RITA, a novel modulator of Notch signalling, acts via nuclear export of RBP-J.

The evolutionarily conserved Notch signal transduction pathway regulates fundamental cellular processes during embryonic development and in the adult. Ligand binding induces presenilin-dependent cleavage of the receptor and a subsequent nuclear translocation of the Notch intracellular domain (NICD). In the nucleus, NICD binds to the recombination signal sequence-binding protein J (RBP-J)/CBF-1 transcription factor to induce expression of Notch target genes.

Enrichment of brain-related genes on the mammalian X chromosome is ancient and predates the divergence of synapsid and sauropsid lineages.

Previous studies have revealed an enrichment of reproduction- and brain-related genes on the human X chromosome. In the present study, we investigated the evolutionary history that underlies this functional specialization. To do so, we analyzed the orthologous building blocks of the mammalian X chromosome in the chicken genome.

Gene synteny comparisons between different vertebrates provide new insights into breakage and fusion events during mammalian karyotype evolution.

Background: Genome comparisons have made possible the reconstruction of the eutherian ancestral karyotype but also have the potential to provide new insights into the evolutionary inter-relationship of the different eutherian orders within the mammalian phylogenetic tree. Such comparisons can additionally reveal (i) the nature of the DNA sequences present within the evolutionary breakpoint regions and (ii) whether or not the evolutionary breakpoints occur randomly across the genome. Gene synteny analysis (E-painting) not only greatly reduces the complexity of comparative genome sequence analysis but also extends its evolutionary reach.

Analysis of rare APC variants at the mRNA level: six pathogenic mutations and literature review.

In monogenic disorders, the functional evaluation of rare, unclassified variants helps to assess their pathogenic relevance and can improve differential diagnosis and predictive testing. We characterized six rare APC variants in patients with familial adenomatous polyposis at the mRNA level. APC variants c.

Frequency of cancer genes on the chicken z chromosome and its human homologues: implications for sex chromosome evolution.

It has been suggested that there are special evolutionary forces that act on sex chromosomes. Hemizygosity of the X chromosome in male mammals has led to selection for male-advantage genes, and against genes posing extreme risks of tumor development. A similar bias against cancer genes should also apply to the Z chromosome that is present as a single copy in female birds.

Reconstruction of the ancestral ferungulate karyotype by electronic chromosome painting (E-painting).

By comparing high-coverage and high-quality whole genome sequence assemblies it is now possible to reconstruct putative ancestral progenitor karyotypes, here called protokaryotypes. For this study we used the recently described electronic chromosome painting technique (E-painting) to reconstruct the karyotype of the 85 million-year-old (MYA) ferungulate ancestor. This model is primarily based on dog (Canis familiaris) and cattle (Bos taurus) genome data and is highly consistent with comparative gene mapping and chromosome painting data.

Complex patterns of copy number variation at sites of segmental duplications: an important category of structural variation in the human genome.

The structural diversity of the human genome is much higher than previously assumed although its full extent remains unknown. To investigate the association between segmental duplications that display constitutive copy number differences (CNDs) between humans and the great apes and those which exhibit polymorphic copy number variations (CNVs) between humans, we analysed a BAC array enriched with segmental duplications displaying such CNDs. This study documents for the first time that in addition to human-specific gains common to all humans, these duplication clusters (DCs) also exhibit polymorphic CNVs > 40 kb.

Characterization of the human lineage-specific pericentric inversion that distinguishes human chromosome 1 from the homologous chromosomes of the great apes.

The human and chimpanzee genomes are distinguishable in terms of ten gross karyotypic differences including nine pericentric inversions and a chromosomal fusion. Seven of these large pericentric inversions are chimpanzee-specific whereas two of them, involving human chromosomes 1 and 18, were fixed in the human lineage after the divergence of humans and chimpanzees. We have performed detailed molecular and computational characterization of the breakpoint regions of the human-specific inversion of chromosome 1.

Reconstruction of a 450-My-old ancestral vertebrate protokaryotype.

From recent work the putative eutherian karyotype from 100 Mya has been derived. Here, we have applied a new in silico technique, electronic chromosome painting (E-painting), on a large data set of genes whose positions are known in human, chicken, zebrafish and pufferfish. E-painting identifies conserved syntenies in the data set, and it enables a stepwise reconstruction of the ancestral vertebrate protokaryotype comprising 11 protochromosomes.

Identification of large-scale human-specific copy number differences by inter-species array comparative genomic hybridization.

Copy number differences (CNDs), and the concomitant differences in gene number, have contributed significantly to the genomic divergence between humans and other primates. To assess its relative importance, the genomes of human, common chimpanzee, bonobo, gorilla, orangutan and macaque were compared by comparative genomic hybridization using a high-resolution human BAC array (aCGH). In an attempt to avoid potential interference from frequent intra-species polymorphism, pooled DNA samples were used from each species.

Polymorphic micro-inversions contribute to the genomic variability of humans and chimpanzees.

A combination of inter- and intra-species genome comparisons is required to identify and classify the full spectrum of genetic changes, both subtle and gross, that have accompanied the evolutionary divergence of humans and other primates. In this study, gene order comparisons of 11,518 human and chimpanzee orthologous gene pairs were performed to detect regions of inverted gene order that are potentially indicative of small-scale rearrangements such as inversions. By these means, a total of 71 potential micro-rearrangements were detected, nine of which were considered to represent micro-inversions encompassing more than three genes.

The chimpanzee-specific pericentric inversions that distinguish humans and chimpanzees have identical breakpoints in Pan troglodytes and Pan paniscus.

Seven of nine pericentric inversions that distinguish human (HSA) and chimpanzee karyotypes are chimpanzee-specific. In this study we investigated whether the two extant chimpanzee species, Pan troglodytes (common chimpanzee) and Pan paniscus (bonobo), share exactly the same pericentric inversions. The methods applied were FISH with breakpoint-spanning BAC/PAC clones and PCR analyses of the breakpoint junction sequences.

Independent intrachromosomal recombination events underlie the pericentric inversions of chimpanzee and gorilla chromosomes homologous to human chromosome 16.

Analyses of chromosomal rearrangements that have occurred during the evolution of the hominoids can reveal much about the mutational mechanisms underlying primate chromosome evolution. We characterized the breakpoints of the pericentric inversion of chimpanzee chromosome 18 (PTR XVI), which is homologous to human chromosome 16 (HSA 16). A conserved 23-kb inverted repeat composed of satellites, LINE and Alu elements was identified near the breakpoints and could have mediated the inversion by bringing the chromosomal arms into close proximity with each other, thereby facilitating intrachromosomal recombination.

An isochore transition zone in the NF1 gene region is a conserved landmark of chromosome structure and function.

The mammalian genome is organized as a mosaic of isochores, stretches of DNA with a distinct sequence composition. Isochores form the basis of the chromosomal banding pattern, which is tightly correlated with a number of structural and functional features. We have recently demonstrated that the transition from a GC-poor isochore to a GC-rich one in the NF1 gene region occurs within 5 kb and demarcates genomic regions with high and low recombination frequency.

Characterization of Pisrt1/Foxl2 in Ellobius lutescens and exclusion as sex-determining genes.

The rodent Ellobius lutescens is an exceptional mammal which determines male sex constitutively without the SRY gene and, therefore, may serve as an animal model for human 46,XX female-to-male sex reversal. It was suggested that other factors of the network of sex-determining genes determine maleness in these animals. However, some sex-determining genes like SOX9 and SF1 have already been excluded by segregation analysis as primary sex-determining factors in E.

Molecular characterisation of the pericentric inversion that distinguishes human chromosome 5 from the homologous chimpanzee chromosome.

Human and chimpanzee karyotypes differ by virtue of nine pericentric inversions that serve to distinguish human chromosomes 1, 4, 5, 9, 12, 15, 16, 17, and 18 from their chimpanzee orthologues. In this study, we have analysed the breakpoints of the pericentric inversion characteristic of chimpanzee chromosome 4, the homologue of human chromosome 5. Breakpoint-spanning BAC clones were identified from both the human and chimpanzee genomes by fluorescence in situ hybridisation, and the precise locations of the breakpoints were determined by sequence comparisons.

Molecular characterization of the pericentric inversion of chimpanzee chromosome 11 homologous to human chromosome 9.

In addition to the fusion of human chromosome 2, nine pericentric inversions are the most conspicuous karyotype differences between humans and chimpanzees. In this study we identified the breakpoint regions of the pericentric inversion of chimpanzee chromosome 11 (PTR 11) homologous to human chromosome 9 (HSA 9). The break in homology between PTR 11p and HSA 9p12 maps to pericentromeric segmental duplications, whereas the breakpoint region orthologous to 9q21.

Breakpoint analysis of the pericentric inversion distinguishing human chromosome 4 from the homologous chromosome in the chimpanzee (Pan troglodytes).

The study of breakpoints that occurred during primate evolution promises to yield valuable insights into the mechanisms underlying chromosome rearrangements in both evolution and pathology. Karyotypic differences between humans and chimpanzees include nine pericentric inversions, which may have potentiated the parapatric speciation of hominids and chimpanzees 5-6 million years ago. Detailed analysis of the respective chromosomal breakpoints is a prerequisite for any assessment of the genetic consequences of these inversions.

Wide genome comparisons reveal the origins of the human X chromosome.

The eutherian X chromosome has one of the most conserved gene arrangements in mammals. Although earlier comparisons with distantly related mammalian groups pointed towards separate origins for the short and long arms, much deeper comparisons are now possible using draft sequences of the chicken genome, in combination with genome sequences from pufferfish and zebrafish. This enables surprising new insights into the origins of the mammalian X chromosome.

Segmental duplication associated with the human-specific inversion of chromosome 18: a further example of the impact of segmental duplications on karyotype and genome evolution in primates.

The human-specific pericentric inversion of chromosome 18 was analysed using breakpoint-spanning BACs from the chimpanzee and human genome. Sequence and FISH analyses disclosed that the breakpoints map to an inverted segmental duplication of 19-kb, which most likely mediated the inversion by intrachromosomal homologous recombination. The 19-kb duplication encompasses the 3' end of the ROCK1 gene and occurred in the human lineage.

A comparative expression analysis of four MRX genes regulating intracellular signalling via small GTPases.

The X chromosomal mental retardation genes have attained high interest in the past. A rough classification distinguishes syndromal mental retardation (MRXS) and nonsyndromal mental retardation (MRX) conditions. The latter are suggested to be responsible for human specific development of cognitive abilities.

Murine pancreatic tumor cell line TD2 bears the characteristic pattern of genetic changes with two independently amplified gene loci.

TGFalpha/p53(+/-) transgenic mice represent a genetically engineered mouse model for pancreatic adenocarcinoma. The tumors develop a characteristic pattern of secondary genetic changes. From one of these tumors, the permanent cell line TD2 was established.

Pattern of secondary genomic changes in pancreatic tumors of Tgf alpha/Trp53+/- transgenic mice.

Trp53(+/-) mice overexpressing Tgfalpha in a pancreas-specific manner represent a well-established animal model for pancreatic cancer. In this study we analyzed 38 pancreatic adenocarcinomas of these mice for secondary genomic changes by comparative genomic hybridization (CGH), loss of heterozygosity (LOH) analysis, real-time PCR, and methylation-specific analysis. CGH screening of the tumors revealed a recurrent pattern of genomic changes.

Expression pattern of the Rsk2, Rsk4 and Pdk1 genes during murine embryogenesis.

The ribosomal S6 kinase family members RSK2 (RPS6KA3) and RSK4 (RPS6KA6) belong to the group of X chromosomal genes, in which defects cause unspecific mental retardation (MRX) in humans. In this study, we investigated the spatiotemporal expression pattern of these genes during mouse development with emphasis to midgestation stages. Additionally, we analyzed the expression of the phosphoinositide-dependent protein kinase-1 gene, Pdk1 (Pspk1), which is essential for the activation of Rsk family members and thus regulates their function.