Yeast Comparative Genetics: A New MEL15 α-Galactosidase Gene of Saccharomyces cerevisiae

To supplement the earlier identified European family of the highly homologous -galactosidase MEL1–MEL11genes and the African family of the divergent MEL12–MEL14 genes, a new MEL15gene was found in several Saccharomyces cerevisiae strains isolated from maize dough in Ghana. Southern blotting and restriction enzyme analysis assigned the MEL15 gene to the African family and mapped it to chromosomes IV/XII, which migrate together in electrophoresis. Tetrad analysis ruled out the MEL15 location in the left arm of chromosome IV or the right arm of chromosome XII, which respectively contain the known MEL5 and MEL10 genes.     

A new family of polymorphic genes in Saccharomyces cerevisiae: α-galactosidase genes MEL1-MEL7

Summary Using genetic hybridization analysis we identified seven polymorphic genes for the fermentation of melibiose in different Mel⁺ strains of Saccharomyces cerevisiae. Four laboratory strains (1453-3A, 303-49, N2, C.B.11) contained only the MEL1 gene and a wild strain (VKM Y-1830) had only the MEL2 gene. Another wild strain (CBS 4411) contained five genes: MEL3, MEL4, MEL5, MEL6 and MEL7. MEL3-MEL7 were isolated and identified by backcrosses with Mel^– parents (X2180-1A, S288C). A cloned MEL1 gene was used as a probe to investigate the physical structure and chromosomal location of the MEL gene family and to check the segregation of MEL genes from CBS 4411 in six complete tetrads. Restriction and Southern hybridization analyses showed that all seven genes are physically very similar. By electrokaryotyping we found that all seven genes are located on different chromosomes MEL1 on chromosome II as shown previously by Vollrath et al. (1988), MEL2 on VII, MEL3 on XVI, MEL4 on XI, MEL5 on IV, MEL6 on XIII, and MEL7 on VI. Molecular analysis of the segregation of MEL genes from strain CBS 4411 gave results identical to those from the genetic analyses. The homology in the physical structure of this MEL gene family suggests that the MEL loci have evolved by transposition of an ancestral gene to specific locations within the genome.     

Molecular analysis of alpha-galactosidase MEL genes from Saccharomyces sensu stricto

To infer the molecular evolution of yeast Saccharomyces sensu stricto from analysis of the alpha-galactosidase MEL gene family, two new genes were cloned and sequenced from S. bayanus var. bayanus and S. pastorianus. Nucleotide sequence homology of the MEL genes of S. bayanus var. bayanus (MELb), S. pastorianus (MELpt), S. bayanus var. uvarum (MELu), and S. carlsbergensis (MELx) was rather high (94.1-99.3%), comparable with interspecific homology (94.8-100%) of S. cerevisiae MEL1-MEL11. Homology of the MEL genes of sibling species S. cerevisiae (MEL1), S. bayanus (MELb), S. paradoxus (MELp), and S. mikatae (MELj) was 76.2-81.7%, suggesting certain species specificity. On this evidence, the alpha-galactosidase gene of hybrid yeast S. pastorianus (S. carlsbergensis) was assumed to originate from S. bayanus rather than from S. cerevisiae.     

On the structure and chromosome location of the 72- and 92-kDa human type IV collagenase genes.

The 72- and 92-kDa type IV collagenases are members of a group of secreted zinc metalloproteases. Two members of this family, collagenase and stromelysin, have previously been localized to the long arm of chromosome 11. Here we assign both of the two type IV collagenase genes to human chromosome 16. By sequencing, the 72-kDa gene is shown to consist of 13 exons, 3 more than have been reported for the other members of this gene family. The extra exons encode the amino acids of the fibronectin-like domain which has so far been found in only the 72- and 92-kDa type IV collagenase. The evolutionary relationship among the members of this gene family is discussed.     

Meiotic mapping of yeast ribosomal deoxyribonucleic acid on chromosome XII.

We have used meiotic mapping techniques to locate the position of the repeating ribosomal DNA (rDNA) genes of the yeast Saccharomyces cerevisiae. We found that the rDNA genes are located on the right arm of chromosome XII, approximately 45 map units centromere distal to the gene gal2. Together with mapping data from previous studies, this result suggests that the tandem array of rDNA genes contains at least two junctions with the non-rDNA of the yeast chromosome. In addition, we observed segregation patterns of the rDNA genes consistent with meiotic recombination within the rDNA gene tandem array in 3 of the 59 tetrads examined.     

Demonstration of Q bands on mitotic chromosomes of the amphibian urodele Pleurodeles poireti Gervais, after staining with quinacrine mustard. Comparison with Pleurodeles waltii]

Preparations of metaphase chromosomes of the amphibian urodele Pleurodeles poireti were obtained by squashing cells from tailbuds of ten days old embryos which had been in 50% acetic acid. The Q-bands karyotype is described. Frequently the induced secondary constrictions exhibit a bright fluorescence, as do the centromeres, except for that of chromosome XII. In contrast, satellites on chromosomes III, IV, and XI exhibit little fluorescence. This pattern is compared with that in Pleurodeles waltlii. Differences are observable in centromeres of chromosomes III and XII and the proximal part of the long arm of chromosome VII, differences which can be used as chromosome marker in case of hybridization.     

The human endonexin II (ENX2) gene is located at 4q28----q32

A relatively recently identified family of structurally similar Ca2(+)-dependent phospholipid binding proteins is called the annexin gene family. At least seven genes are known, although their exact functions are unclear. The endonexin II gene (ENX2), one member of the gene family, is assigned to 4q28----q32 using both Southern transfer analysis of human x rodent somatic cell hybrid DNAs and in situ chromosome hybridization. One of the lipocortin II genes, another annexin, had previously been assigned to the long arm of chromosome 4.     

Genome-wide identification and expression analysis of peach auxin response factor gene families

Plant auxin response factors (ARFs) are involved in plant growth, development and multiple other processes. In this study, the ARF gene family in the peach genome was identified by bioinformatics software and RT-PCR. In total, 18 PpARF candidate genes were found in the peach genome. The DNA-binding and ARF domains, as well as motif III and IV of the PpARF gene family were highly conserved. The phylogenetic analysis revealed that PpARF gene family was divided into five classes: Class I (three members), Class II (four members), Class III (five members), Class IV (three members) and Class V (three members). The results of an intron-exon structure analysis indicated that PpARF gene family members were composed of 2–15 exons. A chromosome mapping analysis revealed that PpARF genes were distributed with different densities over eight chromosomes, with the largest number of PpARF genes on chromosome 1 (four genes), followed by chromosome 4 and 6 (three genes each). Only one gene was located on each of chromosome 3, 7 and 8. A conserved motif analysis revealed that the DNA-binding and ARF domains were observed in all PpARF proteins (except for PpARF18). Class I contained no motifs III or IV (except for PpARF7). RT-PCR results indicated that all of the PpARF genes, with the exception of PpARF15 and PpARF17, were expressed in at least one of the tissues (roots, stems, leaves, flowers and five stages of fruit development). These results suggested that the PpARF gene family members are highly and structurally conserved, and are involved in various aspects of peach growth and development, especially in fruit development.     

The mouse alpha 1(XII) and human alpha 1(XII)-like collagen genes are localized on mouse chromosome 9 and human chromosome 6.

Type XII collagen is a member of the FACIT (fibril-associated collagens with interrupted triple helices) group of extracellular matrix proteins. Like the other members of this group, collagen types IX and XIV, type XII has alternating triple-helical and non-triple-helical domains. Because of its structure, its association with collagen fibrils, and its distribution in dense connective tissues, type XII is thought possibly to act as a cross-bridge between fibrils and resist shear forces caused by tension. A portion of the ffuse gene was isolated by screening a genomic library with a chicken alpha 1 (XII) cDNA probe, followed by subcloning and sequence analysis. Comparison of exon sequences with the sequence of a mouse cDNA clone allowed the mouse gene to be identified as the alpha 1 (XII) collagen gene. In the mouse, Col12a1 is located on chromosome 9, as determined by linkage analysis using DNA from interspecific backcrosses with Mus spretus. Screening of a human genomic library also allowed the isolation of a human alpha 1(XII)-like gene (CoL12A1). This gene was mapped to chromosome 6 by blot hybridization to DNA from human/hamster hybrid cell lines. This information should prove useful in determining the role of type XII collagen genes as candidate genes in inheritable connective tissue diseases.     

Cloning of a new FLO gene from the flocculating Saccharomyces cerevisiae IM1-8b strain

A flocculation conferring gene was cloned from a genomic library of the flocculating strain Saccharomyces cerevisiae IM1-8b as a 5 kb DNA fragment. The shortest DNA fragment (XbaI-XbaI) able to confer the flocculating phenotype was 3.1 kb. Southern analysis revealed that this gene was not homologous to the already reported FLO1 gene since strong hybridization signals were obtained when chromosomes IV and XII were probed with a digoxygenin-labelled fragment and no signal at all was detected for chromosome I. Partial sequencing data unequivocally ascribed the cloned fragment to chromosome XII. The gene was detected in a variety of S. cerevisiae strains regardless of their being phenotypically flocculating. This gene which, we propose as FLO2, is able to complement the flo1 mutation and is suppressed by suppressors (fsu3) that do not affect other FLO genes.     

Mapping human X-linked genes in the phalangerid marsupial Trichosurus vulpecula.

We mapped 15 human X-chromosome markers in the common brush-tailed possum, Trichosurus vulpecula (Kerr), which represents the Australian marsupial family Phalangeridae. In situ hybridization was used to localize highly conserved human X-linked genes to chromosomes of T. vulpecula diploid lines. Ten genes located on the long arm of the human X (human Xq genes) all mapped to the possum X chromosome. However, all five genes located on the short arm of the human X (human Xp genes) mapped to autosomes. These findings confirm our previous work, which showed that the X chromosome in macropodid and dasyurid marsupials bears all the human Xq genes but none of the human Xp genes studied. This suggests that the marsupial X is highly conserved, but its gene content reflects that of only part of the eutherian X, a result consistent with our hypothesis that an autosomal region was added to the X early in eutherian divergence.     

Nucleotide sequence comparison of a chromosome rearrangement on human chromosome 12 and the corresponding ape chromosomes

Chromosome rearrangement has been considered to be important in the evolutionary process. Here, we demonstrate the evolutionary relationship of the rearranged human chromosome 12 and the corresponding chromosome XII in apes (chimpanzee, bonobo, gorilla, orangutan, and gibbon) by examining PCR products derived from the breakpoints of inversions and by conducting shotgun sequencing of a gorilla fosmid clone containing the breakpoint and a "duplicated segment" (duplicon). We confirmed that a pair of 23-kb duplicons flank the breakpoints of inversions on the long and short arms of chimpanzee chromosome XII. Although only the 23-kb duplicon on the long arm of chimpanzee chromosome XII and its telomeric flanking sequence are found to be conserved among the hominoids (human, great apes, and gibbons), the duplicon on the short arm of chimpanzee chromosome XII is suggested to be the result of a duplication from that on the long arm. Furthermore, the shotgun sequencing of a gorilla fosmid indicated that the breakpoint on the long arm of the gorilla is located at a different position 1.9 kb from that of chimpanzee. The region is flanked by a sequence homologous to that of human chromosome 6q22. Our findings and sequence analysis suggest a close relationship between segmental duplication and chromosome rearrangement (or breakpoint of inversion) in Hominoidea. The role of the chromosome rearrangement in speciation is also discussed based on our new results.     

Genetic study of plasmid integration into yeast chromosomes. IV. Integration of the plasmid pYF91 into different yeast chromosomes

Integration of the episomic chimeric plasmid pYF91 into yeast chromosomes has been studied. Plasmid insertion into the chromosomes was observed to occur with the frequency of 4 X 10(-8). 379 integrants were selected from the highly unstable (cir0) transformants. The fact of plasmid integration into particular chromosomes was confirmed for 318 integrants. Genetic analysis showed that the plasmid can integrate into the region of LEU2 gene or into another arm of chromosome III (227 integrants), and also into other chromosomes: I, II, IV, V, VI, VII, VIII, IX, XII, XV (91 integrants). It is suggested that integration is the result of recombination between yeast chromosomes and homologous plasmid regions carrying LEU2 gene or Ty element and "delta" sequence.     

A germ cell specific gene of the ARGONAUTE family is essential for the progression of premeiotic mitosis and meiosis during sporogenesis in rice

The rice (Oryza sativa) genome contains 18 copies of genes of the ARGONAUTE (AGO) family. Although AGO members play important roles in RNA-mediated silencing during plant development, a family member that is specifically involved in sexual reproduction has not been identified in plants. We identified the rice AGO gene MEIOSIS ARRESTED AT LEPTOTENE1 (MEL1) from the analysis of seed-sterile mutants. In the mel1 mutant, chromosome condensation was arrested at early meiotic stages and irregularly sized, multinucleated, and vacuolated pollen mother cells (PMCs) frequently appeared in developing anthers. In addition, histone H3 lysine-9 dimethylation of pericentromeres was rarely reduced and modification of the nucleolar-organizing region was altered in mel1 mutant PMCs. The mutation also affected female germ cell development. These results indicate that the germ cell-specific rice MEL1 gene regulates the cell division of premeiotic germ cells, the proper modification of meiotic chromosomes, and the faithful progression of meiosis, probably via small RNA-mediated gene silencing, but not the initiation and establishment of germ cells themselves.     

Association of colony variation in Serratia marcescens with the differential expression of protease and type 1 fimbriae

Abstract Using pulsed-field gel electrophoresis of chromosomal DNA and hybridization with the MEL1 probe, we determined the chromosomal locations of polymeric α-galactosidase genes in monosporic cultures of natural strains of Saccharomyces cerevisiae . An unusual phenomenon consisting of an accumulation of the MEL genes has been found in some specific Saccharomyces cerevisiae populations. Many strains possessed a new MEL gene located on chromosome I.     

Identifying Mutations in Duplicated Functions in Saccharomyces cerevisiae: Recessive Mutations in Hmg-Coa Reductase Genes

The two yeast genes for 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase, HMG1 and HMG2, each encode a functional isozyme. Although cells bearing null mutations in both genes are inviable, cells bearing a null mutation in either gene are viable. This paper describes a method of screening for recessive mutations in the HMG1 gene, the gene encoding the majority of HMG-CoA reductase activity in the cell. This method should be applicable to the isolation of mutations in other recovered in HMG1. These mutations exhibited intragenic complementation: one allele is in one complementation group and three alleles are in a second complementation group. Assays of HMG-CoA reductase activity indicated that the point mutations destroy most if not all of the activity encoded by HMG1. Intragenic complementation occurred with partial restoration of enzymatic activity. HMG1 was mapped to the left arm of chromosome XIII near SUP79, and HMG2 was mapped to the right arm of chromosome XII near SST2. A slight deleterious effect of a null mutation in either HMG-CoA reductase gene was detected by a co-cultivation experiment involving the wild-type strain and the two single mutants.     

Molecular cloning, expression and chromosomal localization of a novel human REG family gene, REG III

Regenerating gene (Reg), first isolated from a regenerating islet cDNA library, encodes a secretory protein with a growth stimulating effect on pancreatic beta cells that ameliorates the diabetes of 90% depancreatized rats and non-obese diabetic mice. Reg and Reg-related genes have been revealed to constitute a multigene family, the Reg family, which consists of four subtypes (types I, II, III, IV) based on the primary structures of the encoded proteins of the genes [Diabetes 51(Suppl. 3) (2002) S462]. Plural type III Reg genes were found in mouse and rat. On the other hand, only one type III REG gene, HIP/PAP (gene expressed in hepatocellular carcinoma-intestine-pancreas/gene encoding pancreatitis-associated protein), was found in human. In the present study, we found a novel human type III REG gene, REG III. This gene is divided into six exons spanning about 3 kilobase pairs (kb), and encodes a 175 amino acid (aa) protein with 85% homology with HIP/PAP. REG III was expressed predominantly in pancreas and testis, but not in small intestine, whereas HIP/PAP was expressed strongly in pancreas and small intestine. IL-6 responsive elements existed in the 5'-upstream region of the human REG III gene indicating that the human REG III gene might be induced during acute pancreatitis. All the human REG family genes identified so far (REG Ialpha, REG Ibeta, HIP/PAP, REG III and REG IV) have a common gene structure with 6 exons and 5 introns, and encode homologous 158-175-aa secretory proteins. By database searching and PCR analysis using a yeast artificial chromosome clone, the human REG family genes on chromosome 2, except for REG IV on chromosome 1, were mapped to a contiguous 140 kb region of the human chromosome 2p12. The gene order from centromere to telomere was 5' HIP/PAP 3'-5' RS 3'-3' REG Ialpha 5'-5' REG Ibeta 3'-3' REG III 5'. These results suggest that the human REG gene family is constituted from an ancestor gene by gene duplication and forms a gene cluster on the region.     

Superfamily of α-galactosidase MEL genes of the Saccharomyces sensu stricto species complex

In order to study the molecular evolution of the yeasts grouped in the Saccharomyces sensu stricto species complex by analysis of the MEL gene family, we have cloned and sequenced two new species-specific MEL genes from Saccharomyces yeasts: S. paradoxus (MELp) and a Japanese Saccharomyces sp. (MELj). The clones were identified by sequence homology to the S. cerevisiae MEL1 gene. Both clones revealed an ORF of 1413 bp coding for a protein of 471 amino acids. The deduced molecular weights of the α-galactosidase enzymes were 52 767 for MELp and 52 378 for MELj. The nucleotide sequences of the MELp (EMBL accession no. X95505) and the MELj (EMBL accession no. X95506) genes showed 74.7% identity. The degree of identity of MELp to the MEL1 gene was 76.8% and to the S. pastorianus MELx gene, 75.7%. The MELj coding sequence was 75.1% identical to the MEL1 gene and 80.7% to the MELx gene. The data suggest that MEL1, MELj, MELp, and MELx genes are species-specific MEL genes. The strains studied each have only one MEL locus. The MELp gene is located on the S. paradoxus equivalent of S. cerevisiae chromosome X; the MELj gene was on the chromosome that comigrates with the S. cerevisiae chromosome VII/XV doublet and hybridizes to the S. cerevisiae chromosome XV marker HIS3.