Structure of the human hemopexin gene and evidence for intron-mediated evolution

Summary The human hemopexin gene was isolated and its structure determined. The gene spans approximately 12 kb and is interrupted by nine introns. When the intron/exon pattern was examined with respect to the polypeptide segments they encode, a direct correspondence between exons and the 10 repeating units in the protein was observed. The introns are not randomly placed; they fall in the middle of the region of amino acid sequence homology in strikingly similar locations in 6 of the 10 units and in a symmetrical position in the two halves of the coding sequence. These features strongly support the hypothesis that the gene evolved through intron-mediated duplications of a primordial sequence to a five-exon cluster. A more recent gene duplication led to the present-day gene organization.     

A novel human glycosyltransferase: primary structure and characterization of the gene and transcripts

We report the identification and primary structure of a novel human glycosyltransferase, B3GTL (beta3-glycosyltransferase-like). The 498 residue protein consists of a short cytoplasmic N-terminal "tail" (residues 1-4), a single transmembrane domain with type II topology (residues 5-28), a "stem" region (residues 29-260), and a catalytic domain (residues 261-498). The genomes of Anopheles gambiae, Drosophila melanogaster, and Caenorhabditis elegans encode potential orthologs which share 31-39% sequence identity with B3GTL, as well as the following features: a conserved catalytic domain containing a triple aspartate motif (DDD) at its core, a conserved pattern of cysteine residues, a C-terminal KDEL-like motif, and conserved residues and motifs that affiliate this novel group with a family of beta3-glycosyltransferases (GT31 in the CAZY classification). The B3GTL gene lacks canonical TATA and CAAT boxes and contains three functional polyadenylation sites. It is transcribed in a wide range of tissues and in TGF-beta-treated T84 epithelial cells.     

Increased complexity of gene structure and base composition in vertebrates

How the structure and base composition of genes changed with the evolution of vertebrates remains a puzzling question. Here we analyzed 895 orthologous protein-coding genes in six multicellular animals: human, chicken, zebrafish, sea squirt, fruit fly, and worm. Our analyses reveal that many gene regions, particularly intron and 3' UTR, gradually expanded throughout the evolution of vertebrates from their invertebrate ancestors, and that the number of exons per gene increased. Studies based on all protein-coding genes in each genome provide consistent results.We also find that GC-content increased in many gene regions (especially 5' UTR) in the evolution of endotherms, except in coding-exons.Analysis of individual genomes shows that 3′ UTR demonstrated stronger length and CC-content correlation with intron than 5' UTR, and gene with large intron in all six species demonstrated relatively similar GC-content. Our data indicates a great increase in complexity in vertebrate genes and we propose that the requirement for morphological and functional changes is probably the driving force behind the evolution of structure and base composition complexity in multicellular animal genes.     

Structure of the human serotonin 5-HT4 receptor gene and cloning of a novel 5-HT4 splice variant

Several variants of the serotonin 5-HT4 receptor are known to be produced by alternative splicing. To survey the existence and usage of exons in humans, we cloned the human 5-HT4 gene. Based on sequence analysis seven C-terminal variants (a-g) and one internal splice variant (h) were found. We concentrated in this study on the functional characterization of the novel splice variant h, which leads to the insertion of 14 amino acids into the second extracellular loop of the receptor. The h variant was cloned as a splice combination with the C-terminal b variant; therefore, we call this receptor 5-HT4(hb). This novel receptor variant was expressed transiently in COS-7 cells, and its pharmacological profile was compared with those of the previously cloned 5-HT4(a) and 5-HT4(b) isoforms, with the latter being the primary reference for the h variant. In competition binding experiments using reference 5-HT4 ligands, no significant differences were detected. However, the broadly used 5-HT4 antagonist GR113808 discriminated functionally among the receptor variants investigated. As expected, it was an antagonist on the 5-HT4(a) and 5-HT4(b) variant but showed partial agonistic activity on the 5-HT4(hb) variant. These data emphasize the importance of variations introduced by splicing for receptor pharmacology and may help in the understanding of conflicting results seen with 5-HT4 ligands in different model systems.     

Repeated structure and possible gene duplications in high potential iron protein and rubredoxin

Summary The three-dimensional structures of bacterial high potential iron protein (HIPIP) and rubredoxin have been searched for repeats to test whether these molecules evolved by independent tandem gene duplications. HIPIP has no structural repeats in spite of the observed repeated pattern in the amino acid sequence fromRhodopseudomonas gelatinosa. Rubredoxin fromClostridium pasteurianum has repeated hairpin loops of ten alpha-carbon atoms on both sides of the active centre iron-sulphur complex, which can be superposed within a root mean square deviation of 0.84 Å by rotating about a local pseudo-dyad axis. The structural repeat matches a weak repeat in the amino acid sequence. It is concluded that the sequence repeats in HIPIP are probably a coincidence but that rubredoxin may have evolved by gene duplication from a dimer of two primitive hairpin loops.     

Genetics of the peroxidase isoenzymes in Petunia

Summary As detected by starch gel electrophoresis, the fast moving anodal group of peroxidase isoenzymes, the PRXa complex, of a Petunia homozygous for the encoding gene can be made up of one to four bands, depending on the tissue sampled, the age of the tissue and of the plant, and the genetic background. Additional evidence is presented showing that the PRXa complex is encoded by one structural gene, prxA, rather than by tandem duplicated genes. On the basis of electrophoretic variation in Petunia hybrida and related species, five prxA alleles were found. A prxA internal site mutation was found recognized by the absence of recombination between the mutation that affected the temporal programme of the gene and the mutation that altered the mobility of the enzyme. By a three-point test, the gene prxA was located on chromosome III and found to be linked to the genes Mf1 and Ht1 in the order prxA-Mf1-Ht1. The construction of a trisomic III triply heterozygous for prxA confirmed the location of prxA.     

Behavioral influences on gene structure and other new ideas concerning sex change in fishes

Synopsis The interpretation of experiments, designed to reveal whether sex change is induced behaviorally, can influence the type of physiological mechanism we propose to underlie sex change. Mechanisms involving stimulation differ from mechanisms of disinhibition and each is inferred from different ways of conceptualizing behavioral experiments. Both types of mechanism are likely to involve CNS, hypothalamus, pituitary, and gonad. Recent work, however, also implicates H-Y antigen and Bkm satellite DNA in the sex-change process. These studies raise the exciting possibility that the changes in behavioral relationships between the sexes that induce sex change also produce changes in certain aspects of DNA. The nature of the proximate causes of sex change plays a surprisingly important role in influencing evolutionary models of sex change. Such models can be evaluated by first examining their applicability to real populations and, if they are applicable, then testing their validity by comparing their predictions with observed data. The size advantage model, in spite of its proven ability to stimulate and direct research, does not fare well in either of these stages of evaluation. The basic weakness of the model is its failure to incorporate individual adaptability into the life history of sex-changing fishes.     

Density-dependent migration and human population structure in historical Massachusetts

Studies of population structure often focus on the effects of population size and migration rates on genetic variation. Few studies, however, have investigated the relationship between these two factors. The purpose of this paper is to determine the extent to which migration (and gene flow) is density-dependent (that is, affected by population size) for populations in historical Massachusetts. Data from 4,859 marriage records were analyzed from four populations in north-central Massachusetts during the time period 1741 to 1849. These data were placed into 29 samples defined in terms of population and time cohort. Within each cohort the overall exogamy rate was computed along with three estimates of gene flow based on marital migration: local migration (k), long-distance migration (m), and effective migration rate (me). Three samples show unusually low rates that reflect the history of settlement. Regression analyses were used with the remaining samples, and they show nonlinear density-dependent migration that is unrelated to temporal trends. Migration is highest in samples with small population sizes (less than 800) and large population sizes (greater than 1,600). Migration is lowest in medium-sized populations. Two processes are suggested to explain this curvilinear relationship of migration and population size. In small populations, the lack of suitable potential mates and/or availability of settled land leads to an increase in migration into the population. As population size increases, this migration decreases. After populations reach a certain size, migration increases again, most likely reflecting the economic pull of larger populations. These patterns could act to enhance, or counter, genetic drift, depending on the direction of density dependence.