The mammalian alphaD-globin gene lineage and a new model for the molecular evolution of alpha-globin gene clusters at the stem of the mammalian radiation

We have explored the evolution of the alpha-globin gene family by comparative sequence and phylogenetic analyses of mammalian alpha-globin genes. Our analyses reveal the existence of a new alpha-globin gene lineage in mammals that is related to the alpha(D)-globin genes of birds, squamates and turtles. The gene is located in the middle of the alpha-globin gene cluster of a marsupial, Sminthopsis macroura and of humans. It exists in a wide variety of additional mammals, including pigs, cows, cats, and dogs, but is a pseudogene in American marsupials. Evolutionary analyses suggest that the gene has generally evolved under purifying selection, indicative of a functional gene. The presence of mRNA products in humans, pigs, and cows also suggest that the gene is expressed and likely to be functional. The analyses support the hypothesis that the alpha(D)-globin gene lineage has an ancient evolutionary origin that predates the divergence of amniotes. The structural similarity of alpha-globin gene clusters of marsupials and humans suggest that an eight gene cluster (5'-zeta2-zeta1-alpha(D)-alpha3-alpha2-alpha1-theta-omega-3'), including seven alpha-like genes and one beta-like globin gene (omega-globin) existed in the common ancestor of all marsupial and eutherian mammals. This basic structure has remained relatively stable in marsupials and in the lineage leading to humans, although omega-globin has been lost from the alpha-globin gene cluster of humans.     

The site of the action of the angora-Y gene and its interaction with the fuzzy-Y gene in the mouse

The site of action of the goY mutant gene was determined in the aggregation chimaeras C57BL-goY/goY----DBA (+/+). Chimerism was detected by mosaicism of coat pigmentation and electrophoretic pattern of glucose phosphate isomerase. In 28-day-old chimaeras the regions of light-brown coat alternated black coat, stripes of short hairs alternated those of long hairs. These stripes of different length and width extended from spine in lateral-ventral direction. The hairs plucked from long hairs stripes had a similar length that those of goY/goY mice of same age, but the hairs plucked from short hair stripes corresponded to the hair length of +/+ mice. These data show that the goY gene acts in epidermal cells of hair follicles and its expression is autonomous. It has been established that in double homozygotes goY/goYfzY/fzY both mutant genes are expressed: the considerable increase of hair length as compared to norm--the effect of the goY gene and curly coat--the effect of the fzY gene. In goY/goYfzY/fzY mice during the formation of G1 guard hairs the incomplete expression of the goY gene is observed that is due to the suppression of hair growth by the fzY mutant gene. The fzY gene does not suppress the growth of G2 hairs and therefore the full expression of the goY gene occurs in goY/goYfzY/fzY adult mice.     

霍乱毒素A基因内部翻译调控元件具有翻译起始功能

通过大肠杆菌体外转录－体外翻译系统,证明霍乱毒素Ａ基因内部的翻译调控元件具有翻译起始功能,且其翻译起始效率较ｃｔｘＡ基因高得多,当ｃｔｘＡ的起始密码突变时,从该元件起始的翻译效率下降,说明基因内翻译起以ｃｔｘＡ翻译起始的调控。结果进一步证实了霍乱毒素Ａ、Ｂ亚工比例表达调控的翻译弱化－翻译偶联机理。     

Transcriptional regulation of the Drosophila catalase gene by the DRE/DREF system

Reactive oxygen species (ROS) cause oxidative stress and aging. The catalase gene is a key component of the cellular antioxidant defense network. However, the molecular mechanisms that regulate catalase gene expression are poorly understood. In this study, we have identified a DNA replication-related element (DRE; 5'-TATCGATA) in the 5'-flanking region of the Drosophila catalase gene. Gel mobility shift assays revealed that a previously identified factor called DREF (DRE- binding factor) binds to the DRE sequence in the Drosophila catalase gene. We used site-directed mutagenesis and in vitro transient transfection assays to establish that expression of the catalase gene is regulated by DREF through the DRE site. To explore the role of DRE/DREF in vivo, we established transgenic flies carrying a catalase-lacZ fusion gene with or without mutation in the DRE. The beta-galactosidase expression patterns of these reporter transgenic lines demonstrated that the catalase gene is upregulated by DREF through the DRE sequence. In addition, we observed suppression of the ectopic DREF-induced rough eye phenotype by a catalase amorphic Cat(n1) allele, indicating that DREF activity is modulated by the intracellular redox state. These results indicate that the DRE/DREF system is a key regulator of catalase gene expression and provide evidence of cross-talk between the DRE/DREF system and the antioxidant defense system.     

Molecular cloning and nucleotide sequence of the gene for the ribosomal protein S11 from the archaebacterium Halobacterium marismortui

The gene encoding ribosomal protein S11 (Escherichia coli S15 homologue) from Halobacterium marismortui was cloned employing two synthetic oligonucleotide mixtures, 23 and 32 bases in length, as hybridization probes. The nucleotide sequence of the gene and the adjacent 5'- and 3'-flanking regions (1300 base pairs) were then determined by the dideoxy chain termination method. Comparison of the nucleotide sequence of the H. marismortui S11 gene with that of the E. coli S15 gene (rpsO) showed that the 3'-end of the S11 gene can be aligned with the entire E. coli S15 gene, sharing 44% identical nucleotides. It has been found that the S11 gene has a higher G + C content (G + C = 65%) than that of the E. coli S15 gene (G + C = 53%). This increase in G + C content specifically shows up as a preference for G + C in the 3rd position of the codon. Upstream of the S11 gene, an archaebacterial promoter sequence (GGACTTTCA) and a putative ribosomal binding site (GCGGT) have been found, 88 and 15 (or 24) base pairs from the initiation codon of the gene. In addition, an open reading frame could be identified immediately after the stop codon for the S11 gene. Northern blotting analysis using the S11 coding region as probe has shown that the S11 gene is located on a 2.4-kilobase mRNA, suggesting that it is cotranscribed with other downstream gene(s).     

The problem of the gene

During the early 20th century the diverse practices of genetics were unified by the concept of the gene. This classical gene was simultaneously a unit of structure, function, mutation, and recombination. Starting in the 1940s, however, the classical gene began to fragment. Today when we speak of a gene for some malady, a regulatory gene, a structural gene, or a gene frequency, it is entirely possible that we are deploying different gene concepts even though we are using the same term. The problem of the gene addresses the fragmentation of the classical gene concept by asking to what extent a comprehensive and unifying gene concept is possible or desirable. Fully comprehensive gene concepts seem untenable today, but, within different disciplinary domains, unifying, but non-comprehensive, gene concepts can be epistemically worthwhile. The problem of the gene persists, however, not because of its epistemic value, but because of its political value. Using both the arguments for newly proposed gene concepts and the historical dispute over the classical gene, I argue that the desirability of gene concepts rests in part on the political ramifications of their deployment and contestation.     

Retroviral long terminal repeat is the promoter of the gene encoding the tumor-associated calcium-binding protein oncomodulin in the rat

Oncomodulin is a small calcium-binding protein normally found only in extra-embryonic tissues such as the placenta, but whose presence in a variety of tumors has been documented. We have isolated the oncomodulin gene from a Buffalo rat genomic library. The rat gene is approximately 9000 bases in length and consists of five exons and four introns. The introns interrupt the coding sequence of oncomodulin in positions identical with those previously reported for the parvalbumin gene, indicating that the two genes are derived from a common ancestor. Analysis of the promoter sequence of the oncomodulin gene revealed that the gene is under the control of a solo long terminal repeat element related to intracisternal-A particles, a family of endogenous retroviral elements. This represents a unique example of a mammalian gene transcribed in normal and tumor cells, from a promoter of viral origin.     

Intragenic Sequences Affect the Expression of the Gene Encoding Glial Fibrillary Acidic Protein

We show that the expression of the gene encoding glial fibrillary acidic protein (GFAP) gene is affected by at least three cis-acting elements. A positive regulatory element that is located between nucleotides -1,631 and -1,479 can confer cell type-specific expression on a heterologous gene. A second regulatory element is located between nucleotides -97 and -80. The third is a negative regulatory element that is located within the first intron of the gene. Deletion of this element activates GFAP expression in HeLa cells, and affects promoter function in glioma cells.     

Two copies of the human apolipoprotein C-I gene are linked closely to the apolipoprotein E gene

The gene for human apolipoprotein (apo) C-I was selected from human genomic cosmid and lambda libraries. Restriction endonuclease analysis showed that the gene for apoC-I is located 5.5 kilobases downstream of the gene for apoE. A copy of the apoC-I gene, apoC-I', is located 7.5 kilobases downstream of the apoC-I gene. Both genes contain four exons and three introns; the apoC-I gene is 4653 base pairs long, the apoC-I' gene 4387 base pairs. In each gene, the first intron is located 20 nucleotides upstream from the translation start signal; the second intron, within the codon of Gly-7 of the signal peptide region; and the third intron, within the codon for Arg39 of the mature plasma protein coding region. The upstream apoC-I gene encodes the known apoC-I plasma protein and differs from the downstream apoC-I' gene in about 9% of the exon nucleotide positions. The most important difference between the exons results in a change in the codon for Gln-2 of the signal peptide region, which introduces a translation stop signal in the downstream gene. Major sequence differences are found in the second and third introns of the apoC-I and apoC-I' genes, which contain 9 and 7.5 copies, respectively, of Alu family sequences. The apoC-I gene is expressed primarily in the liver, and it is activated when monocytes differentiate into macrophages. In contrast, no mRNA product of the apoC-I' gene can be detected in any tissue, suggesting that it may be a pseudogene. The similar structures and the proximity of the apoE and apoC-I genes suggest that they are derived from a common ancestor. Furthermore, they may be considered to be constituents of a family of seven apolipoprotein genes (apoE, -C-I, -C-II, -C-III, -A-I, -A-II, and -A-IV) that have a common evolutionary origin.     

Solving the preserving reversal median problem

Genomic rearrangement operations can be very useful to infer the phylogenetic relationship of gene orders representing species. We study the problem of finding potential ancestral gene orders for the gene orders of given taxa, such that the corresponding rearrangement scenario has a minimal number of reversals, and where each of the reversals has to preserve the common intervals of the given input gene orders. Common intervals identify sets of genes that occur consecutively in all input gene orders. The problem of finding such an ancestral gene order is called the preserving reversal median problem (pRMP). A tree-based data structure for the representation of the common intervals of all input gene orders is used in our exact algorithm TCIP for solving the pRMP. It is known that the minimum number of reversals to transform one gene order into another can be computed in polynomial time, whereas the corresponding problem with the restriction that common intervals should not be destroyed is already NP-hard. It is shown theoretically that TCIP can solve a large class of pRMP instances in polynomial time. Empirically we show the good performance of TCIP on biological and artificial data.     

The evolution of the novel Sdic gene cluster in Drosophila melanogaster

The origin of new genes and of new functions for existing genes are fundamental processes in molecular evolution. Sdic is a newly evolved gene that arose recently in the D. melanogaster lineage. The gene encodes a novel sperm motility protein. It is a chimeric gene formed by duplication of two other genes followed by multiple deletions and other sequence rearrangements. The Sdic gene exists in several copies in the X chromosome, and is presumed to have undergone several duplications to form a tandemly arrayed gene cluster. Given the very recent origin of the gene and the gene cluster, the analysis of the composition of this gene cluster represents an excellent opportunity to study the origin and evolution of new gene functions and the fate of gene duplications. We have analyzed the nucleotide sequence of this region and reconstructed the evolutionary history of this gene cluster. We found that the cluster is composed by four tandem copies of Sdic; these duplicates are very similar but can be distinguished by the unique pattern of insertions, deletions, and point mutations in each copy. The oldest gene copy in the array has a 3' exon that has undergone accelerated diversification, and also shows divergent regulatory sequences. Moreover, there is evidence that this might be the only gene copy in the tandem array that is transcribed at a significant level, expressing a novel sperm-specific protein. There is also a retrotransposon located at the 3' end of each Sdic gene copy. We argue that this gene cluster was formed in the last two million years by at least three tandem duplications and one retrotransposition event.     

Identifying the rooted species tree from the distribution of unrooted gene trees under the coalescent

Gene trees are evolutionary trees representing the ancestry of genes sampled from multiple populations. Species trees represent populations of individuals—each with many genes—splitting into new populations or species. The coalescent process, which models ancestry of gene copies within populations, is often used to model the probability distribution of gene trees given a fixed species tree. This multispecies coalescent model provides a framework for phylogeneticists to infer species trees from gene trees using maximum likelihood or Bayesian approaches. Because the coalescent models a branching process over time, all trees are typically assumed to be rooted in this setting. Often, however, gene trees inferred by traditional phylogenetic methods are unrooted. We investigate probabilities of unrooted gene trees under the multispecies coalescent model. We show that when there are four species with one gene sampled per species, the distribution of unrooted gene tree topologies identifies the unrooted species tree topology and some, but not all, information in the species tree edges (branch lengths). The location of the root on the species tree is not identifiable in this situation. However, for 5 or more species with one gene sampled per species, we show that the distribution of unrooted gene tree topologies identifies the rooted species tree topology and all its internal branch lengths. The length of any pendant branch leading to a leaf of the species tree is also identifiable for any species from which more than one gene is sampled.