Organization of the human cholesteryl ester transfer protein gene

The plasma cholesteryl ester transfer protein (CETP) catalyzes the transfer of phospholipids and neutral lipids between the lipoproteins. Thus, this protein may be important in modulating lipoprotein levels in the plasma. We have determined the primary structure and organization of the human CETP gene. Southern blotting of cellular DNA indicated a single copy of the CETP gene exists per haploid genome. Analysis of three overlapping genomic clones showed that the gene spans approximately 25 kbp and contains 16 exons (size range 32-250 bp). Overall, the sequence and organization of the CETP gene do not resemble those of other lipid-metabolizing enzymes or apolipoproteins. However, comparison of the CETP sequence, one exon at a time, with the sequences in the sequence databases revealed a striking identity of a pentapeptide sequence (ValLeuThrLeuAla) within the hydrophobic core of the signal sequences of human CETP, apolipoproteins A-IV and A-I, and lipoprotein lipase. This pentapeptide sequence was not found in the signal sequences of other proteins, suggesting that it may mediate a specialized function related to lipid metabolism or transport.     

Gene functional similarity search tool (GFSST)

Background  

With the completion of the genome sequences of human, mouse, and other species and the advent of high throughput functional genomic research technologies such as biomicroarray chips, more and more genes and their products have been discovered and their functions have begun to be understood. Increasing amounts of data about genes, gene products and their functions have been stored in databases. To facilitate selection of candidate genes for gene-disease research, genetic association studies, biomarker and drug target selection, and animal models of human diseases, it is essential to have search engines that can retrieve genes by their functions from proteome databases. In recent years, the development of Gene Ontology (GO) has established structured, controlled vocabularies describing gene functions, which makes it possible to develop novel tools to search genes by functional similarity.     

PGMapper: a web-based tool linking phenotype to genes

SUMMARY: With the availability of whole genome sequence in many species, linkage analysis, positional cloning and microarray are gradually becoming powerful tools for investigating the links between phenotype and genotype or genes. However, in these methods, causative genes underlying a quantitative trait locus, or a disease, are usually located within a large genomic region or a large set of genes. Examining the function of every gene is very time consuming and needs to retrieve and integrate the information from multiple databases or genome resources. PGMapper is a software tool for automatically matching phenotype to genes from a defined genome region or a group of given genes by combining the mapping information from the Ensembl database and gene function information from the OMIM and PubMed databases. PGMapper is currently available for candidate gene search of human, mouse, rat, zebrafish and 12 other species. AVAILABILITY: Available online at http://www.genediscovery.org/pgmapper/index.jsp.     

Isolation and characterization of the mouse ubiquitin-specific protease Usp15

We have characterized the mouse ortholog of the human ubiquitin-specific protease USP15. Mouse Usp15 consists of 981 amino acids with a predicted molecular mass of 112 kDa, contains the highly conserved Cys and His boxes present in all members of the UBP family of deubiquitinating enzymes, and is 98% identical/99% similar to human USP15. Usp15 shares 59.5% identity/75.5% sequence similarity with the mouse Unp(Usp4) oncoprotein. Recombinant Usp15 demonstrated ubiquitin-specific protease activity against engineered linear fusions of ubiquitin to glutathione S-transferase. Usp15 can also cleave the ubiquitin-proline bond, as can USP15 and Usp4. Alignment of mouse and human Usp15 and Usp4 protein sequences suggested that Usp15/USP15 may be alternately spliced in a manner analogous to Usp4. Sequence analysis of RT-PCR products from several human and mouse cell lines and tissues revealed alternate splicing in all cells studied. Northern blot analysis of both mouse and human Usp15 revealed two differently sized mRNAs in all tissues examined, owing to alternate polyadenylation sites spaced by 1.5 kb. Chromosomal mapping by interspecific backcross analysis localized the Usp15 gene to the distal region of mouse Chromosome (Chr) 10. This region is syntenic with human Chr 12q24, the location of human USP15, and a different location to Unp(Usp4) (Chr 9). Identification of the mouse Usp15 gene (>69.5 kb) and human USP15 gene (145 kb) sequences in genome databases reveals that both are composed of 22 exons with identical splice sites, and both have an exon/intron structure identical to the mouse Usp4 gene, including the alternately spliced exon. Phylogenetic studies suggest that a sequence currently identified as a chicken Usp4 ortholog is in fact a USP15 ortholog, while bona-fide chicken, cow, and rat Usp4 orthologs can be identified in EST databases.     

The Burkholderia Genome Database: facilitating flexible queries and comparative analyses

As the genome sequences of multiple strains of a given bacterial species are obtained, more generalized bacterial genome databases may be complemented by databases that are focused on providing more information geared for a distinct bacterial phylogenetic group and its associated research community. The Burkholderia Genome Database represents a model for such a database, providing a powerful, user-friendly search and comparative analysis interface that contains features not found in other genome databases. It contains continually updated, curated and tracked information about Burkholderia cepacia complex genome annotations, plus other Burkholderia species genomes for comparison, providing a high-quality resource for its targeted cystic fibrosis research community. AVAILABILITY: http://www.burkholderia.com. Source code: GNU GPL.     

Immunoglobulin heavy-chain joining genes in the rat: comparison with mouse and human

We have cloned by the polymerase chain reaction a 2.1-kb fragment carrying heavy-chain joining (JH) gene segments and a part of the JH-C mu intron of the rat. Sequencing showed that the rat genome has four functional JH segments and that only a slight divergence has occurred after the separation of rat and mouse. A systematic sequence comparison between the two species and human revealed an additional JH pseudogene in rat and mouse 5' of JH1 which has not been described so far. The implications in evolutionary terms are discussed. In addition, we give an assessment of the misincorporation rate of the Taq polymerase.     

Multi-species comparative mapping in silico using the COMPASS strategy

MOTIVATION: The completion of human and mouse genome sequences provides a valuable resource for decoding other mammalian genomes. The comparative mapping by annotation and sequence similarity (COMPASS) strategy takes advantage of the resource and has been used in several genome-mapping projects. It uses existing comparative genome maps based on conserved regions to predict map locations of a sequence. An automated multiple-species COMPASS tool can facilitate in the genome sequencing effort and comparative genomics study of other mammalian species. RESULTS: The prerequisite of COMPASS is a comparative map table between the reference genome and the predicting genome. We have built and collected comparative maps among five species including human, cattle, pig, mouse and rat. Cattle-human and pig-human comparative maps were built based on the positions of orthologous markers and the conserved synteny groups between human and cattle and human and pig genomes, respectively. Mouse-human and rat-human comparative maps were based on the conserved sequence segments between the two genomes. With a match to human genome sequences, the approximate location of a query sequence can be predicted in cattle, pig, mouse and rat genomes based on the position of the match relatively to the orthologous markers or the conserved segments. AVAILABILITY: The COMPASS-tool and databases are available at http://titan.biotec.uiuc.edu/COMPASS/     

Comparative human-mouse-rat sequence analysis of the ICAM gene cluster on HSA 19p13.2 and a 185-kb porcine region from SSC 2q

The human intercellular adhesion molecule gene (ICAM) cluster is located in a GC-rich and gene-rich region on HSA 19p13.2. We determined the complete DNA sequence of a 185-kb porcine bacterial artificial chromosome (BAC) clone containing parts of the ICAM gene cluster. We used the porcine sequence for a detailed comparative analysis between human, pig, mouse and rat. The 185 kb of porcine sequence covered 220 kb of homologous sequence in the human genome, which adds to the growing evidence that the porcine genome is somewhat smaller than the human genome. The genomic sequences of the four species showed a high level of conserved synteny and no rearrangements in gene order were observed. During evolution, the ICAM3 gene was inactivated by mutation in the mouse and rat genome, whereas it is still present in the human and pig genome. The loss of Icam3 in rodent genomes might be relevant for rodent-specific properties of the T-cell-mediated immune response. All the other investigated genes are conserved across all four investigated sequences.     

A comparative analysis of regulatory regions of the transthyretin gene in the mouse, human, and chimpanzee genomes

A full genome analysis of differences between the gene expression in the human and chimpanzee brains revealed that the gene for transthyretin, the carrier of thyroid hormones, is differently transcribed in the cerebella of these species. A 7-kbp DNA fragment of chimpanzee was sequenced to identify possible regulatory sequences responsible for the differences in expression. One hundred and thirteen substitutions were found in the chimpanzee sequence in comparison with the human sequence. About 40% of the substitutions were revealed within the repeating elements of the genome; their location and sizes did not differ from those in the corresponding fragments of the human genome, and the nucleotide sequences had a high degree of identity. A comparison of nucleotide sequences of the transthyretin region of human, chimpanzee, and mouse genes revealed substantial differences in the distribution of G + C content along the examined fragment in the human (chimpanzee) and mouse genes and allowed us to localize three sequence tracts with a higher degree of identity in the three species. One of these tracts is located in the promoter region of the gene, and the other two probably determine the specificity of transthyretin gene expression in the liver and brain. One of the conserved tracts of the chimpanzee genome was found to have a single and a triple nucleotide substitution. The triple substitution distinguishes chimpanzees from humans and mice, which have identical sequences of this site. It is likely that these substitutions are responsible for the differences in the expression levels of the transthyretin gene in the human and chimpanzee brains.     

A Comparative Analysis of Regulatory Regions of the Transthyretin Gene in the Mouse, Human, and Chimpanzee Genomes

A full genome analysis of differences between the gene expression in the human and chimpanzee brains revealed that the gene for transthyretin, the carrier of thyroid hormones, is differently transcribed in the cerebella of these species. A 7-kbp DNA fragment of chimpanzee was sequenced to identify possible regulatory sequences responsible for the differences in expression. One hundred and thirteen substitutions were found in the chimpanzee sequence in comparison with the human sequence. About 40% of the substitutions were revealed within the repeating elements of the genome; their location and sizes did not differ from those in the corresponding fragments of the human genome, and the nucleotide sequences had a high degree of identity. A comparison of nucleotide sequences of the transthyretin region of human, chimpanzee, and mouse genes revealed substantial differences in the distribution of G + C content along the examined fragment in the human (chimpanzee) and mouse genes and allowed us to localize three sequence tracts with a higher degree of identity in the three species. One of these tracts was located in the promoter region of the gene, and the other two probably determine the specificity of transthyretin gene expression in the liver and brain. One of the conserved tracts of the chimpanzee genome was found to have a single and a triple nucleotide substitution. The triple substitution distinguishes chimpanzees from humans and mice, which have identical sequences of this site. It is likely that these substitutions are responsible for the differences in the expression levels of the transthyretin gene in the human and chimpanzee brains.     

Species-specific regulation of alternative splicing in the C-terminal region of the p53 tumor suppressor gene

Alternative splicing occurs in the C-terminal region of the p53 tumor suppressor gene between two alternative 3′ splice sites in intron 10. This alternative splicing event has been detected in murine cells, but not in rat or human tissues. In this paper, we have characterized the pattern of p53 alternative splicing in cell lines from five different species. Our results confirm that p53 alternative splicing is species-specific, being detected only in cell lines of rodent origin. Using transient transfection assays, we have established that the rat p53 gene undergoes efficient alternative splicing in both mouse and rat cell lines, thus demonstrating that it has all the necessary cis-acting sequences to be alternatively spliced. In contrast, we were unable to detect any usage of the human alternative 3′ splice site under the same experimental conditions. Thus, the low levels or absence of alternatively spliced p53 mRNA in rat and human cell lines seems to be the result of different mechanisms. Our results support the hypothesis that there are species-specific mechanisms implicated in the regulation of p53 activity.     

An automated algorithm for extracting functional immunologic V-genes from genomes in jawed vertebrates

Variable (V) domains of immunoglobulins (Ig) and T cell receptors (TCR) are generated from genomic V gene segments (V-genes). At present, such V-genes have been annotated only within the genome of a few species. We have developed a bioinformatics tool that accelerates the task of identifying functional V-genes from genome datasets. Automated recognition is accomplished by recognizing key V-gene signatures, such as recombination signal sequences, size of the exon region, and position of amino acid motifs within the translated exon. This algorithm also classifies extracted V-genes into either TCR or Ig loci. We describe the implementation of the algorithm and validate its accuracy by comparing V-genes identified from the human and mouse genomes with known V-gene annotations documented and available in public repositories. The advantages and utility of the algorithm are illustrated by using it to identify functional V-genes in the rat genome, where V-gene annotation is still incomplete. This allowed us to perform a comparative human–rodent phylogenetic analysis based on V-genes that supports the hypothesis that distinct evolutionary pressures shape the TCRs and Igs V-gene repertoires. Our program, together with a user graphical interface, is available as open-source software, downloadable at http://code.google.com/p/vgenextract/.     

Reduced high density lipoprotein cholesterol in human cholesteryl ester transfer protein transgenic mice

The human cholesteryl ester transfer protein (CETP) facilitates the exchange of neutral lipids among lipoproteins. In order to evaluate the effects of increased plasma CETP on lipoprotein levels, a human CETP minigene was placed under the control of the mouse metallothionein-I promoter and used to develop transgenic mice. Integration of the human CETP transgene into the mouse genome resulted in the production of active plasma CETP. Zinc induction of CETP transgene expression caused depression of serum cholesterol due to a significant reduction of high density lipoprotein cholesterol. There was no change in total cholesterol content in very low and low density lipoproteins. However, there was a decrease in the free cholesterol/cholesteryl ester ratio in plasma and in all lipoprotein fractions of transgenic mouse plasma, suggesting stimulation of plasma cholesterol esterification. The results suggest that high levels of plasma CETP activity may be a cause of reduced high density lipoproteins in humans.