Comparative chromosome mapping of a conserved homoeo box region in mouse and human

Specific genes are assumed to regulate pattern formation in the mammalian embryo, but as yet none has been identified unequivocally. It is possible that such genes in mammals may be identified by virtue of a conserved coding sequence, because many of the Drosophila melanogaster homoeotic and segmentation genes, which have crucial roles in the regulation of segmental pattern formation during embryonic development, contain a 180-base pair (bp) DNA sequence, the homoeo box, and that sequences homologous to the Drosophila homoeo box are also present in 6-10 copies in higher animals, including mammals. Although the assumption that the homoeo box identifies genes responsible for pattern formation in mammals remains to be validated, it is a particularly attractive hypothesis given the strong conservation of homoeo boxes over vast evolutionary distances. Here we report the localization of a human homoeo box region, previously cloned and shown to contain two homoeo boxes within a sequence of 5-kilobases (kb), to the long arm of chromosome 17. We show that two single-copy homoeo box-flanking probes derived from this region strongly hybridize to single-copy restriction fragments in mouse genomic DNA and that these conserved homoeo box-flanking sequences map to mouse chromosome 11. This may be significant as several genes that map to chromosome 17 in human also map to chromosome 11 in the mouse, implying that a segment of mouse chromosome 11 is homologous to a region of human chromosome 17. Taken together, these data suggest that the homoeo box region detected with our probes is highly conserved in human and mouse.     

An unusual translocation of immunoglobulin gene segments in variants of the mouse myeloma MPC11

Immunoglobulin light chain genes of the mouse are composed in germ-line DNA of four separate segments, the leader, V (variable), J (joining) and C (constant) segments. In immunocompetent cells a V and J gene segment are joined by a site-specific recombination event. In variants of the mouse myeloma MPC11 a so-called kappa (k) light chain fragment is expressed which consists of the MOPC321 leader peptide, joined to the kappa constant region peptide. Using the Southern blotting technique we found that the gene coding for the light chain fragment has apkparently been generated by an aberrant translocation of a V gene segment identical or very similar to the MOPC321 V gene segment into the large intervening sequence between the J and the C gene segments. The resulting deletion of the splice signals of the J segments could be the reason for the observed splicing between leader and C region sequences, a phenomenon which may be of general interest for the understanding of the splicing mechanism.     

Sequences at the somatic recombination sites of immunoglobulin light-chain genes.

The entire nucleotide sequence of a 1.7-kilobase embryonic DNA fragment containing five joining (J) DNA segments for mouse immunoglobulin kappa chain gene has been determined. Each J DNA segment can encode amino acid residues 96--108. Comparison of one of the five J DNA sequences with those of an embryonic variable (V) gene and a complete kappa chain gene permitted localisation of a precise recombination site. The 5'-flanking regions of J DNA segments could form an inverted stem structure with the 3'-non-coding region of embryonic V genes. This hypothetical structure and gel-blotting analysis of total embryo and myeloma DNA suggest that the somatic recombination may be accompanied by excision of an entire DNA segment between a V gene and a J DNA segment. Antibody diversity may in part be generated by modulation of the precise recombination sites.     

Comparative analyses of multi-species sequences from targeted genomic regions

The systematic comparison of genomic sequences from different organisms represents a central focus of contemporary genome analysis. Comparative analyses of vertebrate sequences can identify coding and conserved non-coding regions, including regulatory elements, and provide insight into the forces that have rendered modern-day genomes. As a complement to whole-genome sequencing efforts, we are sequencing and comparing targeted genomic regions in multiple, evolutionarily diverse vertebrates. Here we report the generation and analysis of over 12 megabases (Mb) of sequence from 12 species, all derived from the genomic region orthologous to a segment of about 1.8 Mb on human chromosome 7 containing ten genes, including the gene mutated in cystic fibrosis. These sequences show conservation reflecting both functional constraints and the neutral mutational events that shaped this genomic region. In particular, we identify substantial numbers of conserved non-coding segments beyond those previously identified experimentally, most of which are not detectable by pair-wise sequence comparisons alone. Analysis of transposable element insertions highlights the variation in genome dynamics among these species and confirms the placement of rodents as a sister group to the primates.     

A uniform deleting element mediates the loss of kappa genes in human B cells

Human immunoglobulin light-chain genes become rearranged in an ordered fashion during pre-B-cell development such that rearrangement generally occurs in kappa genes before lambda genes (refs 1,2). This ordered process includes an unanticipated deletion of the constant kappa (C kappa) gene and kappa enhancer sequence which precedes lambda rearrangement, and the site of this deletional recombination was located 3' to the joining (J kappa) segments in 75% of cases studied. We have now characterized the recombinational element responsible for this event on three separate alleles and found them to be identical. This kappa-deleting element recombined site-specifically with a palindromic signal (CACAGTG) located in the J kappa-C kappa intron. All losses of C kappa genes in other human B cells were mediated by this determinant, including the 25% of instances when this element recombined with sequences 5' to J kappa. In contrast, the kappa-deleting element remained in its germline form on all successful kappa-producing alleles. Moreover, kappa loss is an evolutionarily conserved event, as the kappa-deleting element appears to be the human homologue of the murine RS sequence. Our results suggest that this element may help ensure isotypic and allelic exclusion of light chains and may be involved in the ordered use of human light-chain genes.     

A novel type of aberrant recombination in immunoglobulin genes and its implications for V-J joining mechanism

Functional kappa light chain genes are formed during B-lymphocyte differentiation by the joining of initially separate V and J gene segments. It has been suggested that the intervening DNA is deleted, however the recent reports of what appear to be the reciprocal products of V and J recombination (back-to-back conserved V and J flanking sequences, called f-fragments) in DNA from mature lymphocytes make a simple deletion model unlikely. An alternative scheme involving unequal sister chromatid exchange has been proposed, supported by the evidence that the f-fragments seem to have segregated from the chromosome carrying the reciprocal complete kappa light chain gene (this and other schemes are briefly reviewed in ref. 8). We report here the analysis of a mouse myeloma (MOPC 41), in which a productive (kappa+) and a non-productive (kappa-) rearrangement has occured, which may help to clarify the mechanism of V-J joining. The aberrant rearrangement has led to the joining of a J1 gene segment to a sequence unrelated to any V gene (L10), and which in the germ line is flanked by a sequence resembling a V region recombination signal sequence. In this case no segregation of the reciprocal recombination products (kappa-41 and f41), which is a required step in sister chromatid exchange models, has taken place. An inversion model provides the simplest explanation of this J rearrangement.     

Organization and sequence studies of the 17-piece chicken conalbumin gene

The conalbumin gene has been cloned and shown to consist of at least 17 exons approximately 60-200 base pairs long. The DNA sequence upstream from the region coding for the 5' end of the mRNA shows similarities with sequences present in homologous positions in other genes. High and low frequency repetitive sequences are found both upstream from the conalbumin gene and within one intron.     

The joining of V and J gene segments creates antibody diversity

The variable regions of mouse kappa (kappa) chains are coded for by multiple variable (V) gene segments and multiple joining (J) gene segments. The V kappa gene segments code for residues 1 to 95; the J kappa gene segments code for residues 96 to 108 (refs 1-3). This gene organisation is similar to that encoding the V lambda regions. Diversity in V kappa regions arises from several sources: (1) there are multiple germ-line V kappa gene segments and J kappa gene segments; (2) combinatorial joining of V kappa gene segments with different germline J kappa gene segments; and possibly, (3) somatic point mutation, as postulated for V lambda gene segments. Also, from a comparison of the number of germ-line J kappa gene segments and amino acid sequences, it has been suggested that J kappa region sequences may be determined by the way V kappa and J kappa gene segments are joined. This report supports this model by directly associating various J kappa sequences with given J kappa gene segments.     

Comparison of cloned rabbit and mouse beta-globin genes showing strong evolutionary divergence of two homologous pairs of introns.

Cloned beta-globin genes of both mouse and rabbit each contain a large and a small intervening sequence (intron) of about equal length at precisely the same positions relative to the coding sequence. The homologous introns show some sequence similarity, particularly at the junctions with the coding sequence. They most probably arose from a common ancestral sequence and diverged substantially during evolution.     

DNase I hypersensitive sites in the chromatin of human mu immunoglobulin heavy-chain genes

An immunoglobulin polypeptide chain is encoded by multiple gene segments that lie far apart in germ-line DNA and must be brought together to allow expression of an immunoglobulin gene active in B lymphocytes. For the immunoglobulin heavy chain genes, one of many variable (V) region genes becomes joined to one of several diversity (D) segments which are fused to one of several joining (J) segments lying 5' of the constant region (C) genes. Here we show that the rearranged mu genes of an IgM-producing human B-lymphocyte cell line exhibit pancreatic deoxyribonuclease (DNase I) hypersensitive sites in the JH-C mu intron that are absent in naked DNA or the chromatin of other differentiated cell types. DNA sequence analysis reveals that the major hypersensitive site maps to a conserved region of the JH-C mu intron recently shown to function as a tissue-specific enhancer of heavy-chain gene expression. A similar association of an enhancer-like element with a DNase I hypersensitive site has been reported for the mouse immunoglobulin light-chain J kappa-C kappa intron. These results implicate disruption of local chromatin structure in the mechanism of immunoglobulin enhancer function.     

Mouse Cmu heavy chain immunoglobulin gene segment contains three intervening sequences separating domains

The IgM molecule is composed of subunits made up of two light chain and two heavy chain (mu) polypeptides. The mu chain is encoded by several gene segments--variable (V), joining (J) and constant (Cmu). The Cmu gene segment is of particular interest for several reasons. First, the mu chain must exist in two very different environments--as an integral membrane protein in receptor IgM molecules (micrometer) and as soluble serum protein in IgM molecules into the blood (mus). Second, the Cmu region in mus is composed of four homology units or domains (Cmu1, Cmu2, Cmu3 and Cmu4) of approximately 110 amino acid residues plus a C-terminal tail of 19 residues. We asked two questions concerning the organisation of the Cmu gene segment. (1) Are the homology units separated by intervening DNA sequences as has been reported for alpha (ref. 5), gamma 1 (ref. 6) and gamma 2b (ref. 7) heavy chain genes? (2) Is the C-terminal tail separated from the Cmu4 domain by an intervening DNA sequence? If so, DNA rearrangements or RNA splicing could generate hydrophilic and hydrophobic C-terminal tails for the mus and micrometer polypeptides, respectively. We demonstrate here that intervening DNA sequences separate each of the four coding regions for Cmu domains, and that the coding regions for the Cmu4 domains and the C-terminal tail are directly contiguous.     

Numerous potentially functional but non-genic conserved sequences on human chromosome 21

The use of comparative genomics to infer genome function relies on the understanding of how different components of the genome change over evolutionary time. The aim of such comparative analysis is to identify conserved, functionally transcribed sequences such as protein-coding genes and non-coding RNA genes, and other functional sequences such as regulatory regions, as well as other genomic features. Here, we have compared the entire human chromosome 21 with syntenic regions of the mouse genome, and have identified a large number of conserved blocks of unknown function. Although previous studies have made similar observations, it is unknown whether these conserved sequences are genes or not. Here we present an extensive experimental and computational analysis of human chromosome 21 in an effort to assign function to sequences conserved between human chromosome 21 (ref. 8) and the syntenic mouse regions. Our data support the presence of a large number of potentially functional non-genic sequences, probably regulatory and structural. The integration of the properties of the conserved components of human chromosome 21 to the rapidly accumulating functional data for this chromosome will improve considerably our understanding of the role of sequence conservation in mammalian genomes.     

蒙古鮊ob基因的克隆与组织表达特异性的初步研究

根据已知的人和鼠ob基因序列设计引物,通过运用RT-PCR技术首次从蒙古鮊脂肪组织的RNA中扩增获得ob基因片段,并经序列分析证实为ob基因编码区438 bp的序列.不同物种同源性比较表明ob基因序列具有很高的保守性:蒙古鮊与人、猪和鼠的ob基因核苷酸编码序列的同源性分别为82.9%、84.0%和99.1%;蒙古鮊ob基因编码的蛋白leptin氨基酸序列与人、猪和鼠氨基酸同源性分别为80.8%、78.8%和95.9%.用RT-PCR技术分析组织ob基因的表达特异性,结果表明:ob基因在脂肪和肝脏组织中的表达量最大,在心脏、脾脏、肌肉、脑、卵巢中的表达量次之,在肾脏中仅微量表达,而在精巢和肠道组织中则不表达.     

Independent evolution of structural and coding regions in a Neurospora mitochondrial intron

The discovery of intervening sequences (introns) in eukaryotic genes has raised questions about the origin and evolution of these sequences. Hypotheses concerning these topics usually consider the intron as a unit that could be lost or gained over time, or as a region within which recombination can occur to facilitate the production of new proteins by exon shuffling. Additional complexities are observed in introns of mitochondrial and chloroplast genes which contain secondary structures required for messenger RNA splicing and open-reading frames encoding proteins. Here we describe differences in the organization of protein-coding sequences in the intron of the mitochondrial ND1 gene in two closely related species of Neurospora. These differences show that intron sequences involved in secondary structure formation and in protein coding can evolve as physically distinct elements. Indeed, the secondary structure elements of the ND1 intron can contain two different coding sequences located at two different positions within the intron.