Evolution of follistatin in teleosts revealed through phylogenetic, genomic and expression analyses

Follistatin (Fst) inhibits transforming growth factor-β (TGF-B) proteins and is a known regulator of amniote myogenesis. Here, we used phylogenetic, genomic and experimental approaches to study its evolution in teleosts. Phylogenetic analyses suggested that one fst gene (fst1) is common to euteleosts, but a second gene (fst2) is conserved specifically within the Ostariophysi. Zebrafish fst1/2 respectively appear on chromosomes 5 and 10 in two genomic regions, each with conserved synteny to a single region in tetrapods. Interestingly, other teleosts have two corresponding chromosomal regions with a similar repertoire of paralogues. Phylogenetic reconstruction clustered these gene duplicates into two sister clades branching from tetrapod sequences. We suggest that an ancestral fst-containing chromosome was duplicated during the teleost whole genome duplication, but that fst2 was lost in lineages external to the Ostariophysi. We show that Fst1 of teleosts/mammals has evolved under strong purifying selection, but the N-terminal of Fst2 may have evolved under positive selection. Furthermore, the tissue-specific expression of zebrafish fst2 was restricted to fewer tissues compared to its paralogue and the single fst1 orthologue of Atlantic salmon (Salmo salar). Zebrafish fst1/2 may have subfunctionalized relative to non-duplicated vertebrate lineages, as several regions in the fst promoter of tetrapods were conserved with one paralogue, but not both. Finally, we examined the embryonic expression of fst1 in a teleost outside the Ostariophysi (Atlantic salmon). During segmentation, fst1 was expressed in the anterior somite compartment but was excluded from muscle progenitors that strongly expressed myogenic regulatory factors (MRFs). Later, fst1 was expressed in myogenic progenitors of the pectoral fin buds and also within the pax7 ⁺ cell layer external to the myotome. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Lineage-specific evolution of the vertebrate Otopetrin gene family revealed by comparative genomic analyses

Background  

Mutations in the Otopetrin 1 gene (Otop1) in mice and fish produce an unusual bilateral vestibular pathology that involves the absence of otoconia without hearing impairment. The encoded protein, Otop1, is the only functionally characterized member of the Otopetrin Domain Protein (ODP) family; the extended sequence and structural preservation of ODP proteins in metazoans suggest a conserved functional role. Here, we use the tools of sequence- and cytogenetic-based comparative genomics to study the Otop1 and the Otop2-Otop3 genes and to establish their genomic context in 25 vertebrates. We extend our evolutionary study to include the gene mutated in Usher syndrome (USH) subtype 1G (Ush1g), both because of the head-to-tail clustering of Ush1g with Otop2 and because Otop1 and Ush1g mutations result in inner ear phenotypes.     

Yeast species recognition from gene sequence analyses and other molecular methods

This review discusses DNA-based methods used for identification of yeasts. Nuclear DNA reassociation was the first quantitative molecular method employed for recognition of yeast species and has provided a baseline for interpretation of other molecular comparisons. Among these, gene sequencing is the most definitive method, with ribosomal RNA gene sequences providing the preponderance of available data. Multigene analyses that include the sequences of protein encoding genes are being increasingly developed to provide a more definitive resolution of species. A number of rapid identification methods, such as denaturing gradient gel electrophoresis (DGGE), temperature gradient gel electrophoresis (TGGE), and flow cytometry, which are based on species-specific gene sequences, are available for use in diagnostic laboratories.     

Phylogenetic analysis of Carthamus species based on the nucleotide sequence of the nuclear SACPD gene and chloroplast trnL-trnF IGS region

To clarify the phylogenetic relationships of Carthamus species, we performed sequence analysis of the nuclear stearoyl acyl carrier protein desaturase (SACPD) gene and the chloroplast intergenic spacer region between leucine and phenylalanine tRNA genes (trnL-trnF IGS) in 13 taxa of Carthamus. The previous division of the genus into 4 taxonomic sections and allocation of particular genomes to various taxa on the basis of morphological, cytogenetic, and biosystematic analyses is not supported by the present study. Our results provide evidence of the occurrence of 5 nuclear genomes (A, B, C, X, and Y) and 3 cytoplasm types (A, B, and C) in the genus Carthamus. The cultivated safflower, C. tinctorius (2n = 24), has the B genome and type B cytoplasm. Both of these are not present in the polyploid taxa. This contradicts the earlier view that one of the genomes involved in the origin of the polyploid taxa of Carthamus is the B genome. Comparison with an outgroup species (Cirsium japonicum) indicated that C. arborescens is the most primitive species in the genus. Carthamus palaestinus is genetically closest to the cultivated safflower.     

Multiple Asian pig origins revealed through genomic analyses

Previous mitochondrial DNA (mtDNA) studies have suggested that European and Asian pig populations were derived through multiple domestication events. We investigated whether domestic pig populations were derived from distinct ancestors within their respective regions, using eight domestic breeds (five European and three Asian), and also European and Asian wild boar populations. Genomic analyses utilized 21 microsatellite markers (MS) selected for their distribution across the pig genome in addition to the mtDNA D-loop region. The number of alleles per MS loci ranged from 8 (Sw2008) to 16 (S0097 and S0218). Few significant departures from Hardy–Weinberg equilibrium were detected, suggesting the absence of heterozygote deficiencies. Analyses within populations revealed observed mean heterozygosity from 0.48 (Erhualian) to 0.68 (Dutch WB) and an expected mean heterozygosity from 0.53 (Hampshire) to 0.80 (Japanese WB) with effective alleles ranging from 2.28 (Hampshire) to 3.74 (French WB). Wild boar populations demonstrated a higher level of heterozygosity than domestic breeds. Genetic differentiation estimated by fixation indices (F_ST) ranged from 0.021 (Yorkshire and Duroc) to 0.410 (Meishan and Hampshire) and was consistent with previous mtDNA analysis. Both phylogenetic and principal component analyses revealed a distinct separation of European and Asian derived populations with tight clustering of the European domestic breeds. Conversely, the use of both MS and mtDNA clarified that the Asian populations were comprised of three groups, one represented by Erhualian and Meishan breed, the second represented by Lanyu pigs and the third represented by the Asian wild boars. The current findings support the hypothesis that Asian domestic populations were derived from multiple Asian ancestral origins whereas the European domestic populations represent a single ancestral European lineage.     

Bacterial diversity of the Inner Mongolian Baer Soda Lake as revealed by 16S rRNA gene sequence analyses

Bacterial diversity associated with Baer Soda Lake in Inner Mongolia of China was investigated using a culture-independent method. Bacterial 16S rRNA gene libraries were generated using bacterial oligonucleotide primers, and 16S rRNA gene sequences of 58 clones were analyzed phylogenetically. The library was dominated by 16S rDNAs of Gram-negative bacteria (24% -Proteobacteria, 31% -Proteobacteria, 33% -Proteobacteria, and 2% -Proteobacteria), with a lower percentage of clones corresponding to Gram-positive bacteria. Forty cloned sequences were similar to that of known bacterial isolates (>97% sequence similarity), represented by the species of the genera Brevundimonas, Comamonas, Alcaligenes, Stenotrophomonas, and Klebsiella. Eighteen cloned sequences showed less affiliation with known taxa (<97% sequence similarity) and may represent novel taxa.Communicated by K. Horikoshi     

Chitin synthase 2 gene sequence of Malassezia species.

Nucleotide sequences of the chitin synthase 2 (CHS2) gene of seven species, Malassezia furfur, M. globosa, M. obtusa, M. pachydermatis, M. restricta, M. slooffiae and M. sympodialis, were analyzed for their phylogenetic relationship. About 620-bp genomic DNA fragments of the CHS2 gene were amplified from these Malassezia species by polymerase chain reaction (PCR) and sequenced. The CHS2 nucleotide sequences of these Malassezia species showed more than 95% similarity between the species. A phylogenetic analysis of the nucleotide sequences of CHS2 gene fragments of seven Malassezia species revealed that the species were genetically distinct from each other.     

Evolution of the cyclin gene family in plants

Cyclins are key regulators of cell cycle progression. Previous studies have shown that cyclin genes in plants can be divided into 10 groups. However, because those studies only focused on genes from two well-known model plants (i.e., Arabidopsis thaliana (L.) Heynh. and Oryza sativa L.), it remains unclear whether the 10 groups are reasonably defined. In this study, by analyzing the genomes of 10 representative plants (Chlamydomonas reinhardtii P. A. Dang, Physcomitrella patens(Hedw.) Bruch & Schimp., Selaginella moellendorffii Hieron., Picea abies (L.) H. Karst., Amborella trichopoda Baill., A. thaliana, Populus trichocarpa Torr. & A. Gray ex Hook., Vitis vinifera L., O. sativa, and Sorghum bicolor (L.) Moench), we estimated the phylogenetic relationships of plant cyclins and investigated their evolutionary patterns. We confirmed that plant cyclins can be classified into 10 groups, although only eight ancestral genes may have existed in the most recent common ancestor of extant green plants. We also found that, due to the frequent occurrences of gene duplication events, several groups have expanded extensively in seed plants and, particularly, flowering plants, so that multiple genes belonging to different subgroups are present in a species. Reconciliation of the evolutionary histories of these groups and subgroups further led to the identification of evolutionarily highly conserved and rapidly duplicating gene lineages. These results will guide the classification and nomenclature of plant cyclins and help understand the conservativeness and variation in their functions.     

Evolution of the multifaceted eukaryotic akirin gene family

Background  

Akirins are nuclear proteins that form part of an innate immune response pathway conserved in Drosophila and mice. This studies aim was to characterise the evolution of akirin gene structure and protein function in the eukaryotes.     

High sequence similarity within ras exons 1 and 2 in different mammalian species and phylogenetic divergence of the ras gene family

We have determined the canine and feline N-, K-, and H-ras gene sequences from position +23 to +270 covering exons I and II which contain the mutational hot spot codons 12, 13, and 61. The results were used to assess the degree of similarity between ras gene DNA regions containing the critical domains affected in neoplastic disorders in different mammalian species. The comparative analyses performed included human, canine, feline, murine, rattine, and, whenever possible, bovine, leporine (rabbit), porcelline (guinea pig), and mesocricetine (hamster) ras gene sequences within the region of interest. Comparison of feline and canine nucleotide sequences with the corresponding regions in human DNA revealed a sequence similarity greater than 85% to the human sequence. Contemporaneous analysis of previously published ras DNA sequences from other mammalian species showed a similar degree of homology to human DNA. Most nucleotide differences observed represented synonymous changes without effect on the amino acid sequence of the respective proteins. For assessment of the phylogenetic evolution of ras gene family, a maximum parsimony dendrogram based on multiple sequence alignment of the common region of exons I and II in the N-, K-, and H-ras genes was constructed. Interestingly, a higher substitution rate among the H-ras genes became apparent, indicating accelerated sequence evolution within this particular clade. The most parsimonious tree clearly shows that the duplications giving rise to the three ras genes must have occurred before the mammalian radiation. Received: 23 July 1997 / Accepted: 30 October 1997     

Nucleotide sequence of a member of the chicken H2B histone-encoding gene family

The nucleotide sequence of a gene from the chicken H2B histone-encoding gene family has been determined. Our findings, together with those in a previous paper [Grandy and Dodgson, Nucleic Acids Res. 15 (1987) 1063-1080], show that the seven H2B genes encode three different histone variants.     

Evolution of species trait through resource competition

To understand the evolution of diverse species, theoretical studies using a Lotka–Volterra type direct competition model had shown that concentrated distributions of species in continuous trait space often occurs. However, a more mechanistic approach is preferred because the competitive interaction of species usually occurs not directly but through competition for resource. We consider a chemostat-type model where species consume resource that are constantly supplied. Continuous traits in both consumer species and resource are incorporated. Consumers utilize resource whose trait values are similar with their own. We show that, even when resource-supply has a continuous distribution in trait space, a positive continuous distribution of consumer trait is impossible. Self-organized generation of distinct species occurs. We also prove global convergence to the evolutionarily stable distribution.     

Genetic relationships among Stylosanthes species revealed by RFLP and STS analyses

Genetic relationships between 6 unclassified taxa and 24 known species of the genus Stylosanthes were investigated by RFLP and STS analyses. This allowed the diploid taxa used in this study to be classified into nine basal (genome) groups. Representative species in these groups included ’S. seabrana’/S. hamata (Group A), S. viscosa (Group B), S. humilis (Group C), S. macrocephala/S. bracteata (Group D), S. pilosa (Group E), S. leiocarpa (Group F), S. guianensis (Group G), S. tomentosa (Group H) and S. calcicola (Group I). Polyploid taxa used were grouped into five classes based on their putative genomic structures. These are AABB for S. scabra, S. aff. scabra, S. sericeiceps, S. aff. hamata and S. tuberculata; AACC for S. mexicana, S. subsericea, S. sundaica and S. sp.A; DDEE for S. capitata; AAFF for S. sympodialis; and AABBXX for S. erecta, with XX representing an unknown genome. Of the 6 unclassified taxa, three were diploids and 3 tetraploids. Of the 3 diploids, the genome of S. sp. was markedly distinct from those of all other diploids analysed in this study, with that of S. leiocarpa being the closest. The genome of S. sp.B was similar to that of S. humilis, with an average dissimilarity value of 15% between them. The genome of S. aff. viscosa was very similar to that of S. viscosa. Genetic variation between these 2 taxa was not larger than that within each of the 2 taxa. Of the 3 tetraploids, the genomic structure of S. sp.A was similar to those of S. mexicana, S. sundaica and S. subsericea, and the genomic structures of S. aff. scabra and S. aff. hamata were similar to those of S. scabra and S. sericeiceps. Received: 18 September 1998 / Accepted: 23 March 1999     

Evolution of the interleukin-1 gene family in mammals

The phylogeny of interleukin-1 family genes shows that human interleukin-1 (IL-1) is more closely related to IL-1 of the bovine than to IL-1 of the mouse, whereas human interleukin-1 (IL-1) is more closely related to IL-1 of the mouse than to IL-1 of the bovine. The IL-1 receptor antagonist (IL-1) shows homology to the C-terminal region of both IL-1 and IL-1. In the C-terminal region, the IL-1 genes of human and mouse have diverged more from each other at nonsynonymous sites than have either IL-1 or IL-1; because the same pattern is not seen at synonymous sites, it must be due not to a difference in mutation rate but rather to a greater degree of functional constraint on this region in the IL-1 and IL-1 proteins than in the IL-1 protein. But synonymous sites in IL-1 of mouse have evolved more rapidly than in IL-1 of human, indicating a higher rate of mutation in the former gene. In the N-terminal region of the protein, nonsynonymous sites have evolved at similar rates in IL-1 and IL-1. The first exon of the IL-1 gene, which encodes the leader peptide, shows evidence of homology with the first exon of IL-1, which is not translated. Thus, it seems likely that IL-1 evolved by duplication of an IL-1 gene and loss of expression of exons 2–4. Correspondence to: A.L. Hughes     

Evolution of a B2 tagged sequence from a long-range repeat family in the genus Mus

A long-range repeat family of more than 50 kb repeat size is clustered in Chromosomes (Chr) 1 of Mus musculus and M. spretus. In M. musculus this long-range repeat family shows considerable variation of copy-number frequency and contains coding regions for at least two genes. In an intron of a gene, which is part of the repeat, a B2 small interspersed repetitive element (SINE) is inserted at identical positions. The B2 element is present in all copies of the long-range repeat family; it was presumably a component of the ancestral single-copy precursor sequence that gave rise by amplification to the repeat family. Copies of the long-range repeat family vary with respect to the number of TAAA tandem repeats in the A-rich 3 end region of the B2 element. As inferred from polymerase chain reaction (PCR) data, presence and frequency of repeat number variants in the (TAAA)_n block are strain and species specific. The B2 element and its flanking regions were sequenced from two copies of the long-range repeat family. Sequence divergence between the two copies (only non-CG base substitutions and deletions/insertions) was determined to be 2.6%. Based on the drift rate in human Alu elements and a correction for the higher drift rates in rodents, and estimate for the divergence time of 1.7 million years was calculated. Since the long-range repeat family is present in M. musculus and M. spretus, it must have evolved by amplification before the separation of the two species about 1–4 million years ago.     

Evolution of the rat immunoglobulin gamma heavy-chain gene family

The sequences of the four immunoglobulin gamma heavy chains of the rat (gamma 1, gamma 2a, gamma 2b, gamma 2c) have been determined. These sequences reveal that the rat genes have evolved differently from the closely related mouse gamma genes (gamma 1, gamma 2a, gamma 2b, gamma 3): in rat two of the four genes (gamma 2a and gamma 1) are 94% homologous to each other and best resemble the single mouse gamma 1 gene. Rat gamma 2b is equivalent to the mouse gamma 2a/gamma 2b pair as regards both nucleotide sequence and antibody effector functions whilst rat gamma 2c resembles mouse gamma 3. In evolutionary terms this suggests the existence of a set of three common C gamma genes before separation of rat and mouse as individual species. In addition, two independent duplication events must have occurred after species separation affecting different constant regions; this yielded rat gamma 2a and gamma 1 as a recently evolved pair and mouse gamma 2a and gamma 2b as a different pair. Furthermore, the sequence comparisons reveal several other features of interest; rat IgG2b lacks two amino acids in CH1 which are conserved in all other sequenced gamma chains. Residues believed to be essential for monocyte interaction (FcRI) are retained only in rat gamma 2b and not in the other rat gamma genes whilst a particular motif involved in C1q interaction shows a variation in both rat IgG1 and rat IgG2a which has not been observed previously.