Three expressed sequences within the human beta-tubulin multigene family each define a distinct isotype

This paper describes the isolation and complete sequence of a novel expressed human beta-tubulin gene (beta 2). The sequence is compared with that of two other expressed human beta-tubulin genes (M40 and 5 beta). All are encoded by four exons. Though the boundaries of each exon are absolutely conserved among the three genes, the intervening sequences differ considerably in size and sequence content. Two of the genes (M40 and 5 beta) contain one (M40) or ten (5 beta) members of the middle repetitive Alu family sequences within one of their intervening sequences. Comparison of the amino acid sequences encoded by each gene reveals a high level of homology overall, though there is significant divergence between the carboxy termini of two of the genes. The pattern of expression of each beta-tubulin gene has been studied in several different human cell lines using unique non-crosshybridizing probes derived from the 3' untranslated regions. Two of the genes, M40 and beta 2, are expressed at varying levels in all of the cell lines examined, though the level of expression of one of these genes parallels the other in most cases. The third gene, 5 beta, is detectably expressed only in cells of neural origin. Thus, distinct human beta-tubulin isotypes are encoded by genes whose exon size and number has been conserved evolutionarily, but whose pattern of expression may be regulated either co-ordinately or uniquely. Of the approximately 15 sequences contained in the human beta-tubulin multigene family, nine have now been sequenced fully. The overall composition of the multigene family and the evolutionary relationships among its various members are discussed.     

Tandem Arrangement of the Human Serum Albumin Multigene Family in the Sub-centromeric Region of 4q: Evolution and Chromosomal Direction of Transcription

The albumin gene family is comprised of four genes encoding: serum albumin (ALB), α-fetoprotein (AFP), α-albumin (ALF), and vitamin D-binding protein (DBP; also known as GC). The genes are regulated developmentally, expressed in the liver, and the proteins are secreted into the bloodstream. The GC gene, and the tandemly linked ALB and AFP genes, have been previously localized to human chromosome 4q11 – 13. Using techniques of fluorescencein situhybridization to chromatin fibres, chromosome walking and DNA sequencing of genomic clones, we now report on the chromosomal location of the ALF gene and the organization of the entire gene family. The four genes are tandemly linked in the 4q sub-centromeric region: 5′ALB-5′AFP-5′ALF-5′GC3′-centromere, and hence are transcribed in the same, centromere-bound, direction. The linear arrangement of the four genes along the chromosome is not correlated with their temporal expression in the human ontogeny. It appears that GC is very close (and may be the gene proximal) to the centromere. The linear chromosomal arrangement of the four genes and the structural differences between them are congruent with the following evolutionary divergence of the gene family. Starting with the first duplication of an ancestral progenitor gene, a single evolutionary line led to the contemporary GC, leaving ALB/AFP/ALF on the other line of descent. The second duplication occurred in this ALB lineage, giving rise to ALB and the AFP/ALF progenitor, and the third, most recent one, gave rise to the AFP-ALF pair.     

Evolution of the large secreted gel-forming mucins

Mucins, the major component of mucus, contain tandemly repeated sequences that differ from one mucin to another. Considerable advances have been made in recent years in our knowledge of mucin genes. The availability of the complete genomic and cDNA sequences of MUC5B, one of the four human mucin genes clustered on chromosome 11, provides an exemplary model for studying the molecular evolution of large mucins. The emerging picture is one of expansion of mucin genes by gene duplications, followed by internal repeat expansion that strictly preserves frameshift. Computational and phylogenetic analyses have permitted the proposal of an evolutionary history of the four human mucin genes located on chromosome 11 from an ancestor gene common to the human von Willebrand factor gene and the suggestion of a model for the evolution of the repeat coding portion of the MUC5B gene from a hypothetical ancestral minigene. The characterization of MUC5B, a member of the large secreted gel-forming mucin family, offers a new model for the comparative study of the structure-function relationship within this important family.     

Selection of DNA sequences from interval 6 of the human Y chromosome with homology to a Y chromosomal fertility gene sequence of Drosophila hydei

Summary An experimental approach towards the molecular analysis of the male fertility function, located in interval 6 of the human Y chromosome, is presented. This approach is not based on the knowledge of any gene product but on the assumption that the functional DNA structure of male fertility genes, evolutionary conserved with their position on the Y chromosome, may contain an evolutionary conserved frame structure or at least conserved sequence elements. We tested this hypothesis by using dhMiF1, a fertility gene sequence of the Y chromosome of Drosophila hydei, as a screening probe on a pool of cloned human Y-DNA sequences. We were able to select 10 human Y-DNA sequences of which 7 could be mapped to Y interval 6 (the pY6H sequence family). Since the only fertility gene of the human Y chromosome is mapped to the same Y interval, our working hypothesis seems to be strongly supported. Most interesting in this respect is the isolation of the Y-specific repetitive pY6H65 sequence. The pY6H65 locus extends to a length of at least 300 kb in Y interval 6 and has a locus-specific repetitive sequence organization, reminiscent of the functional DNA structure of Y chromosomal fertility genes of Drosophila. We identified the simple sequence family (CA)_n as one sequence element conserved between the Drosophila dhMiFi fertility gene sequence and the homologous human Y-DNA sequences.     

Long terminal repeat-like elements flank a human immunoglobulin epsilon pseudogene that lacks introns

There are at least three immunoglobulin epsilon genes (C epsilon 1, C epsilon 2, and C epsilon 3) in the human genome. The nucleotide sequences of the expressed epsilon gene (C epsilon 1) and one (C epsilon 3) of the two epsilon pseudogenes were compared. The results show that the C epsilon 3 gene lacks the three intervening sequences entirely and has a 31-base A-rich sequence 16 bases 3' to the putative poly(A) addition signal, indicating that the C epsilon 3 gene is a processed gene. The C epsilon 3 gene sequence is homologous to the five separate DNA segments of the C epsilon 1 gene; namely, a segment in the 5'-flanking region (100 bases) and four exons, which are interrupted by a spacer region or intervening sequences. Long terminal repeat (LTR)-like sequences which contain TATAAA and AATAAA sequences as well as terminal inverted repeats are present in both 5'- and 3'-flanking regions. The 5' and 3' LTR-like sequences do not, however, constitute a direct repeat, unlike transposable elements of eukaryotes and retroviruses. The 3' LTR-like sequence is repetitive in the human genome, but is not homologous to the Alu family DNA. Models for the evolutionary origin of the processed gene flanked by the LTR-like sequences are discussed. The C epsilon 3 gene has a new open frame which codes potentially for an unknown protein of 292 amino acid residues.     

Complex Evolution of a Y-Chromosomal Double Homeobox 4 (DUX4)-Related Gene Family in Hominoids

The human Y chromosome carries four human Y-chromosomal euchromatin/heterochromatin transition regions, all of which are characterized by the presence of interchromosomal segmental duplications. The Yq11.1/Yq11.21 transition region harbours a peculiar segment composed of an imperfectly organized tandem-repeat structure encoding four members of the double homeobox (DUX) gene family. By comparative fluorescence in situ hybridization (FISH) analysis we have documented the primary appearance of Y-chromosomal DUX genes (DUXY) on the gibbon Y chromosome. The major amplification and dispersal of DUXY paralogs occurred after the gibbon and hominid lineages had diverged. Orthologous DUXY loci of human and chimpanzee show a highly similar structural organization. Sequence alignment survey, phylogenetic reconstruction and recombination detection analyses of human and chimpanzee DUXY genes revealed the existence of all copies in a common ancestor. Comparative analysis of the circumjacent beta-satellites indicated that DUXY genes and beta-satellites evolved in concert. However, evolutionary forces acting on DUXY genes may have induced amino acid sequence differences in the orthologous chimpanzee and human DUXY open reading frames (ORFs). The acquisition of complete ORFs in human copies might relate to evolutionary advantageous functions indicating neo-functionalization. We propose an evolutionary scenario in which an ancestral tandem array DUX gene cassette transposed to the hominoid Y chromosome followed by lineage-specific chromosomal rearrangements paved the way for a species-specific evolution of the Y-chromosomal members of a large highly diverged homeobox gene family.     

Gene structure of the human mitochondrial outer membrane receptor Tom20 and evolutionary study of its family of processed pseudogenes.

The structure of the human gene encoding the mitochondrial outer membrane receptor Tom20 has been determined from overlapping clones obtained using PCR-based techniques. The 20kb human Tom20 gene (hTom20) consists of five exons separated by four introns. The 5' flanking region presents features common with other nuclear genes encoding mitochondrial proteins. Comparison with its homologs and putative homologs in other species has revealed common features in their TPR motifs and other relevant protein domains. Aspects concerning evolutionary origins of the family of processed pseudogenes of hTom20 are also discussed.     

中华绒螯蟹Dmrt基因保守区段的克隆和序列分析

Dmrt基因家族是一个与性别决定和发育相关的基因家族,在不同进化类型的生物中具有相当的保守性。采用PCR技术,扩增了中华绒螯蟹Dmrt基因的DM结构域。经序列分析,获得了Dmrt基因家族的4个成员基因EsDmrt2a、EsDmrt2b、EsDmrt2c和EsDmrt5。结果表明,不同进化地位动物的Dmrt2和Dmrt2基因DM域编码序列存在高度的同源性,显示Dmrt基因在系统进化上高度保守,序列上的相似性可能暗示着它们在功能上的保守性。     

Phylogenetic and evolutionary analysis of the septin protein family in metazoan

Septins, a conserved family of cytoskeletal GTP-binding proteins, were presented in diverse eukaryotes. Here, a comprehensive phylogenetic and evolutionary analysis for septin proteins in metazoan was carried out. First, we demonstrated that all septin proteins in metazoan could be clustered into four subgroups, and the representative homologue of every subgroup was presented in the non-vertebrate chordate Ciona intestinalis, indicating that the emergence of the four septin subgroups should have occurred prior to divergence of vertebrates and invertebrates, and the expansion of the septin gene number in vertebrates was mainly by the duplication of pre-existing genes rather than by the appearance of new septin subgroup. Second, the direct orthologues of most human septins existed in zebrafish, which suggested that human septin gene repertoire was mainly formed by as far as before the split between fishes and land vertebrates. Third, we found that the evolutionary rate within septin family in mammalian lineage varies significantly, human SEPT1, SEPT 10, SEPT 12, and SEPT 14 displayed a relative elevated evolutionary rate compared with other septin members. Our data will provide new insights for the further function study of this protein family.     

Mouse-human orthology relationships in an olfactory receptor gene cluster

The olfactory receptor (OR) subgenome harbors the largest known gene family in mammals, disposed in clusters on numerous chromosomes. One of the best characterized OR clusters, located at human chromosome 17p13.3, has previously been studied by us in human and in other primates, revealing a conserved set of 17 OR genes. Here, we report the identification of a syntenic OR cluster in the mouse and the partial DNA sequence of many of its OR genes. A probe for the mouse M5 gene, orthologous to one of the OR genes in the human cluster (OR17-25), was used to isolate six PAC clones, all mapping by in situ hybridization to mouse chromosome 11B3-11B5, a region of shared synteny with human chromosome 17p13.3. Thirteen mouse OR sequences amplified and sequenced from these PACs allowed us to construct a putative physical map of the OR gene cluster at the mouse Olfr1 locus. Several points of evidence, including a strong similarity in subfamily composition and at least four cases of gene orthology, suggest that the mouse Olfr1 and the human 17p13.3 clusters are orthologous. A detailed comparison of the OR sequences within the two clusters helps trace their independent evolutionary history in the two species. Two types of evolutionary scenarios are discerned: cases of "true orthologous genes" in which high sequence similarity suggests a shared conserved function, as opposed to instances in which orthologous genes may have undergone independent diversification in the realm of "free reign" repertoire expansion.     

Evolutionary diversification of class II P loci in the Mhc of the mole-rat Spalax ehrenbergi

The class II region of the major histocompatibility complex (Smh) in the mole rat, Spalax ehrenbergi, consists of only two gene families, P and Q, instead of the four families (P, O, Q, and R) found in all other mammals studied to date. The Spalax P family consists of at least four beta and three alpha genes or gene fragments. In DNA-hybridization experiments, two of the beta genes behave as bona fide P-family members in that they hybridize strongly with human DP beta probes and hybridize weakly with probes specific for other class II gene families. The other two beta genes, on the other hand, hybridize weakly with human DP beta probes and nearly as well with human DQ beta probes. To determine the evolutionary relationships among these P-like genes, we have sequenced one of them. The sequence reveals, on the basis of its organization, that the gene clearly belongs to the P family, yet, on the basis of its nucleotide sequence, it is only slightly more similar to human DP than to human DQ genes. These results indicate that in the Spalax the P family of genes split into two subfamilies, PA and PB. For unknown reasons, one of these subfamilies (PB) retained more similarity to the Q gene family than did the other (PA).     

Repetitive DNA sequences in the human corticotropin-beta-lipotrophin precursor gene region: Alu family members.

Repetitive DNA sequences in the human corticotropin-beta-lipotropin precursor gene region have been studied by blot hybridization analysis and DNA sequencing. Six repetitive sequences are present in this gene region; five of them are Alu family members with an approximate length of 300 base pairs, and the other consists of a portion of an Alu family sequence. Two of these Alu family members are located in the 5'-flanking region of the gene, and the remaining four within the intervening sequences. These Alu family sequences constitute inverted repeats in the intervening sequences as well as in the 5'-flanking region of the gene.     

Organization of the human myoglobin gene.

Cross-hybridization of the grey seal myoglobin gene to human DNA detected a single human myoglobin gene plus an extensive family of sequences apparently related to the central exon of this gene. The functional human gene is 10.4 kb long and has a haemoglobin-like three exon/two intron structure with long non-coding regions similar to its seal homologue. At least 300 bp of 5'-flanking region are closely homologous between the two genes, with the exception of a divergent purine-rich region 68-114 bp upstream of the cap site. A diverged tandem repetitive sequence based on (GGAT)165 is located 1100-1750 bp upstream from the gene; internal homology units within this sequence suggest sequence homogenization by gene microconversions. A second 33-bp tandem repeat element in the first intron is flanked by a 9-bp direct repeat, shares homology with other tandem repetitive elements in the human genome and may represent a novel form of transposable element.