Expansions and contractions of the genetic map relative to the physical map of yeast chromosome III.

To examine the relationship between genetic and physical chromosome maps, we constructed a diploid strain of the yeast Saccharomyces cerevisiae heterozygous for 12 restriction site mutations within a 23-kilobase (5-centimorgan) interval of chromosome III. Crossovers were not uniformly distributed along the chromosome, one interval containing significantly more and one interval significantly fewer crossovers than expected. One-third of these crossovers occurred within 6 kilobases of the centromere. Approximately half of the exchanges were associated with gene conversion events. The minimum length of gene conversion tracts varied from 4 base pairs to more than 12 kilobases, and these tracts were nonuniformly distributed along the chromosome. We conclude that the chromosomal sequence or structure has a dramatic effect on meiotic recombination.     

Juxtaposition of the genes encoding Mycoplasma pneumoniae cytadherence-accessory proteins HMW1 and HMW3.

The loss and reacquisition of high-Mr (HMW) proteins, HMW1, 2, 3, 4 and 5, by Mycoplasma pneumoniae correlates with cytadherence phase variation. We are cloning and characterizing the genes encoding HMW1-5 to understand the mechanism regulating their coordinate expression. HMW1 was purified by polyacrylamide-gel electrophoresis. Amino acid (aa) sequence data were obtained from enzymatically generated peptide fragments from HMW1. A degenerate 17-mer probe synthesized based upon the aa sequence of one peptide clearly identified a single 4.75-kb BamHI fragment of M. pneumoniae DNA under stringent hybridization conditions. This fragment was cloned into pUC19 to generate pKV16. Restriction mapping of the 4.75-kb BamHI fragment in pKV16 revealed a possible overlap with the 9.4-kb EcoRI fragment containing the gene encoding protein HMW3. Southern blotting and reciprocal hybridization studies confirmed this overlap, establishing the juxtaposition of the genes encoding HMW1 and HMW3. Finally, physical mapping analysis by probing restriction fragments of M. pneumoniae DNA resolved by pulsed-field gel electrophoresis with the cloned genes encoding HMW1 and HMW3 revealed definitively that the hmw locus maps to a 106.8-kb ApaI fragment, rather than a 117.5-kb ApaI fragment, as had been reported previously for hmw3 [Krause and Mawn, J. Bacteriol. 172 (1990) 4790-4797].     

Cloning and regulation of Schizosaccharomyces pombe thi2, a gene involved in thiamine biosynthesis.

Biosyntheses of the pyrimidine and thiazole moieties of the thiamine molecule occur by separate pathways. In Schizosaccharomyces pombe, a gene, thi2, is responsible for thiazole synthesis [Schweingruber et al., Curr. Genet. 19 (1991) 249-254]. We have cloned a 3.1-kb genomic S. pombe fragment which can functionally complement a thi2 mutant. The fragment maps genetically at the thi2 site, indicating that it carries thi2. As shown by Northern hybridization analysis, the appearance of thi2 mRNA levels is repressed when cells are grown in the presence of thiamine and 5-(2-hydroxyethyl)-4-methylthiazole. The thi3 gene involved in the biosynthesis of the pyrimidine moiety, is also regulated by thiamine [Maundrell, J. Biol. Chem. 265 (1990) 10857-10864; Schweingruber et al., Curr. Genet. 19 (1991) 249-254]. We previously identified and analyzed four regulatory genes (tnr1, tnr2, tnr3, and thi1) that are responsible for the regulation of thi3 [Schweingruber et al., Genetics (1992) in press]. Mutants defective in these regulatory genes affect expression of thi2 in a similar way to thi3. This indicates that biosynthesis of the pyrimidine and thiazole moieties are under common genetic control in S. pombe.     

RPC19, the gene for a subunit common to yeast RNA polymerases A (I) and C (III)

Yeast RNA polymerases A (I) and C (III) share a subunit called AC19. The gene encoding AC19 has been isolated from yeast genomic DNA using oligonucleotide probes deduced from peptide sequences of the isolated subunit. This gene (RPC19) contains an intron-free open reading frame of 143 amino acid residues. RPC19 is a single copy gene that maps on chromosome II and is essential for cell viability. The amino acid sequence contains a sequence motif common to the Escherichia coli RNA polymerase alpha subunit, the Saccharomyces cerevisiae AC40 and B44.5 subunits, the human hRPB33 product, and the CnjC conjugation-specific gene product of Tetrahymena. The 5'-upstream region contains a sequence element, the PAC box, that has been conserved in at least 10 genes encoding subunits of RNA polymerases A and C.     

Peaks of linkage are localized by a BAC/PAC contig of the 6p reading disability locus.

A gene for reading disability has been localized by nonparametric linkage to 6p21.3-p22 in several published reports. However, the lack of an uninterrupted genomic clone contig has made it difficult to determine accurate intermarker distances, precise marker order, and genetic boundaries and hinders direct comparisons of linkage. The search and discovery of the hemochromatosis gene (HFE) led to the creation of a bacterial artificial chromosome (BAC) and P-1 derived artificial chromosome (PAC) contig that extended physical maps 4 Mb from the MHC toward pter and localized new markers in that region [10-12]. Using this contig, we localized 124 sequence tagged sites, expressed sequence tags, and short tandem repeats including most of the markers in linkage with reading disability phenotypes, succinic semialdehyde dehydrogenase, GPLD1, prolactin, and 18 uncharacterized genes. This new contig joins and extends previously published physical maps to span the entire chromosome 6 reading disability genetic locus. Physical mapping data from the complete contig show overlap of the published linkage peaks for reading disability, provide accurate intermarker distances and order, and offer resources for generating additional markers and candidate genes for high resolution genetic studies in this region.     

Amplified expression and large-scale purification of protein G'.

PCR was used to isolate the gene fragment coding for Protein G' (SpG'), a truncated bacterial cell surface protein from Streptococcus G148 which binds to the Fc region of IgG and expressed in E. coli [Goward et al. (1990) Biochem. J. 267: 171-177]. The PCR primer was designed to change the TTG initiation triplet to ATG and to incorporate it into an NdeI restriction site (CATATG), allowing the gene to be cloned in frame into an NdeI restriction site immediately downstream of a trp promoter. Expression of SpG' was estimated as about 30% total soluble cell protein which compares very favourably to the less than 1% total soluble cell protein obtained from the original system [Goward, et al. (1990) Biochem. J. 267: 171-177]. Homogeneous SpG' was recovered by a single anion-exchange chromatography step on Q-Sepharose FF in a process which avoided use of an affinity adsorbent. Even though SpG' consists of almost identical repetitive domains from amino acid sequence analysis, different proteolytic sensitivity of each domain was observed indicating their structural dissimilarity.     

Molecular structure of a yeast gene, PDI1, encoding protein disulfide isomerase that is essential for cell growth.

A genomic DNA clone for protein disulfide isomerase (PDI) of Saccharomyces cerevisiae was isolated by hybridization with synthesized oligonucleotide probes based on a partial amino acid sequence of yeast PDI. The introduction of a multiple copy plasmid carrying this fragment into yeast caused a tenfold increase in PDI specific activity and in the amount of PDI antigen in the extract. The gene on this fragment was named PDI1. The nucleotide sequence of the gene predicts a polypeptide of 522 amino acids with about 30% identity to mammalian PDIs. The predicted amino acid sequence contains an N-terminal signal peptide-like sequence, the C-terminal putative endoplasmic reticulum retention signal of yeast (HDEL), and two putative active site sequences of PDI (WCGHCK). The predicted polypeptide is acidic and contains five putative glycosylation sites, consistent with the molecular properties of the purified yeast PDI [T. Mizunaga et al. (1990) J. Biochem. 108, 846-851]. The PDI1 gene was mapped on chromosome III. A gene disruption experiment revealed that the PDI1 gene is essential for cell growth.     

A class III myosin expressed in the retina is a potential candidate for Bardet-Biedl syndrome

Class III myosins are actin-based motors with amino-terminal kinase domains. Expression of these motors is highly enhanced in retinal photoreceptors. As mutations in the gene encoding NINAC, a Drosophila melanogaster class III myosin, cause retinal degeneration, human homologs of this gene are potential candidates for human retinal disease. We have recently reported the cloning of MYO3A, a human myosin III expressed predominantly in the retina and retinal pigmented epithelium [1]. The map locus of MYO3A is close to, but does not overlap, that of human Usher's 1F [2]. Here we introduce a shorter class III myosin isoform, MYO3B, which is expressed in the retina, kidney, and testis. We describe the cDNA sequence, genomic organization, and splice variants of MYO3B expressed in the human retina. A product of 36 exons, MYO3B has several splice variants containing either one or two calmodulin binding (IQ) motifs in the neck domain and one of three predominant tail variations: a short tail ending just past the second IQ motif, or two alternatively spliced longer tails. MYO3B maps to 2q31.1-q31.2, a region that overlaps the locus for a Bardet-Biedl syndrome (BBS5) linked to markers at 2q31 [3].     

Preservation of the Y transcriptome in a 10-million-year-old plant sex chromosome system

Classical genetic studies discovered loss of genes from the ancient sex chromosome systems of several animals (genetic degeneration), and complete genome sequencing confirms that the heterogametic sex is hemizygous for most sex-linked genes. Genetic degeneration is thought to result from the absence of recombination between the sex chromosome pair (reviewed by [1]) and is very rapid after sex chromosome-autosome fusions in Drosophila [2-4]. Plant sex chromosome systems allow study of the time course of degeneration, because they evolved from a state wholly without sex chromosomes (rather than after a large genome region fused to a preexisting sex chromosome), and, in several taxa, recombination stopped very recently. However, despite increasing genetic and physical mapping of plant nonrecombining sex-determining regions [5-8], it remains very difficult to discover sex-linked genes, and it is unclear whether Y-linked genes are losing full function. We therefore developed a high-throughput method using RNA-Seq to identify sex linkage in Silene latifolia. Recombination suppression between this plant's XY sex chromosome pair started only about 10 million years ago [9]. Our approach identifies several hundred new sex-linked genes, and we show that this young Y chromosome retains many genes, yet these already have slightly reduced gene expression and are accumulating changes likely to reduce protein functions.     

Assignment of human teratocarcinoma derived growth factor (TDGF) sequences to chromosomes 2q37, 3q22, 6p25 and 19q13.1.

The human teratocarcinoma derived growth factor 1 (TDGF1) gene maps on chromosome (Chr) 3p21.3. One pseudogene (TDGF3) maps on Chr Xq21-->q22. We now report the nucleotide sequence and chromosome location of three additional TDGF pseudogenes. The three new sequences (TDGF2, TDGF4 and TDGF5) are truncated at the 5' end and have accumulated several point mutations, deletions and insertions. TDGF2, TDGF4 and TDGF6 map on Chrs 2q37, 6p25 and 3q22, respectively. Finally, Southern blot analysis of DNA from normal individuals shows a highly variable restriction pattern of the TDGF sequences.     

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.     

KNL1/Spc105 recruits PP1 to silence the spindle assembly checkpoint

The spindle assembly checkpoint (SAC) delays anaphase onset until kinetochores accomplish bioriented microtubule attachments [1]. Although several centromeric and kinetochore kinases, including Aurora B, regulate kinetochore-microtubule attachment and/or SAC activation [2-4], the molecular mechanism that translates bioriented attachment into SAC silencing remains unclear [5]. Employing a method to rapidly induce exact gene replacement in budding yeast [6], we show here that the binding of protein phosphatase 1?(PP1/Glc7) to the evolutionarily conserved RVSF motif of the kinetochore protein Spc105 (KNL1/Blinkin/CASC5) is essential for viability by silencing the SAC, while it plays an auxiliary nonessential role for physical chromosome segregation. Although Aurora B may inhibit this binding, persistent PP1-Spc105 interaction does not affect chromosome segregation and is insufficient to silence the SAC in the absence of microtubules, indicating that dynamic regulation of this?interaction is dispensable. However, the amount of PP1 targeted to kinetochores must be finely tuned, because recruitment of either no or one extra copy of PP1 to Spc105 is detrimental, illustrating the vital impact of targeting an exiguous fraction of PP1 to the kinetochore. We propose that the PP1-Spc105 interaction enables local regulation of dynamic phosphorylation and dephosphorylation at the kinetochore to couple microtubule attachment and SAC silencing.     

Chromosomal mapping of the mouse IL-4 and human IL-5 genes

We mapped the mouse interleukin (IL)-4 gene on chromosome 11 by restriction fragment length polymorphism using recombinant inbred mouse strains. The human IL-5 gene was mapped on chromosome 5q 23.3-31.1 by in situ hybridization. Because the granulocyte macrophage colony-stimulating factor (GM-CSF) and IL-3 genes were previously mapped on mouse chromosome 11 (within a 230-kb region) and human chromosome 5, the IL-4 and IL-5 genes are likely to cluster on the same chromosomes with the GM-CSF and IL-3 genes in both species.     

Characterization and chromosomal mapping of a human steroid 5 alpha-reductase gene and pseudogene and mapping of the mouse homologue.

The enzyme steroid 5 alpha-reductase catalyzes the conversion of testosterone into the more powerful androgen, dihydrotestosterone. We previously described the cloning of rat and human cDNAs that encode steroid 5 alpha-reductase and their expression in oocytes and cultured cells. Here, we report the isolation, characterization, and chromosomal mapping of two human steroid 5 alpha-reductase genes. One gene (symbol SRD5A1) is functional, contains five exons separated by four introns, and maps to the distal short arm of chromosome 5. Two informative restriction fragment length polymorphisms are present in exons 1 and 2 of this gene. A second gene (symbol SRD5AP1) has all of the hallmarks of a processed pseudogene and was mapped to the q24-qter region of the X chromosome. In the mouse, a single steroid 5 alpha-reductase gene (Srd5 alpha-1) is linked to Xmv-13 on chromosome 13.     

Molecular Mapping of Wheat: Major Genes and Rearrangements in Homoeologous Groups 4, 5, and 7

A molecular-marker linkage map of hexaploid wheat (Triticum aestivum L. em. Thell) provides a framework for integration with the classical genetic map and a record of the chromosomal rearrangements involved in the evolution of this crop species. We have constructed restriction fragment length polymorphism (RFLP) maps of the A-, B-, and D-genome chromosomes of homoeologous groups 4, 5, and 7 of wheat using 114 F(7) lines from a synthetic X cultivated wheat cross and clones from 10 DNA libraries. Chromosomal breakpoints for known ancestral reciprocal translocations involving these chromosomes and for a known pericentric inversion on chromosome 4A were localized by linkage and aneuploid analysis. Known genes mapped include the major vernalization genes Vrn1 and Vrn3 on chromosome arms 5AL and 5DL, the red-coleoptile gene Rc1 on 7AS, and presumptively the leaf-rust (Puccinia recondita f.sp. tritici) resistance gene Lr34 on 7DS and the kernel-hardness gene Ha on 5DS. RFLP markers previously obtained for powdery-mildew (Blumeria graminis f.sp. tritici) resistance genes Pm2 and Pm1 were localized on chromosome arms 5DS and 7AL.     

Polymorphism of genes coding for nuclear 18S rRNA indicates genetic distinctiveness of anastomosis group 10 from other groups in the Rhizoctonia solani species complex.

DNA polymorphism in the 18S nuclear rRNA gene region was investigated by using 11 restriction endonucleases for 161 isolates of 25 intraspecific groups (ISGs) representing 11 reported anastomosis groups (AGs) of Rhizoctonia solani. A PCR-based restriction mapping method in which enzymatically amplified DNA fragments and subfragments were digested with one or two restriction enzymes was employed. Four types of DNA restriction maps of this region were constructed for these 25 ISGs. Map type I of the 18S rDNA region was represented by isolates of a majority of R. solani ISGs. Map types II and III, represented by ISG 2E and 9 isolates and 5C isolates, respectively, differed from map I by the absence of one (map type II) or two (map type III) restriction sites. Map type IV, represented by ISG 10A and B (or AG 10) isolates, showed significant restriction site variations, with five enzymes in this region compared with those of the remaining ISGs or AGs. Ten of the 25 restriction sites in the 18S rRNA gene region were informative and selected for analysis. Previously reported restriction maps of the 5.8S rRNA gene region, including the internal transcribed spacers, were aligned with each other, and 12 informative restriction sites were identified. These data were used alone and in combination to evaluate group relationships. Analyses derived from these data sets by maximum parsimony and likelihood methods showed that AG 10 isolates were distinct and distantly related to the majority isolates of the other AGs of this species complex.     

Regional mapping of the parathyroid hormone gene (PTH) by cytogenetic and molecular studies.

The locus for the human parathyroid hormone gene (PTH) was assigned to a region proximal to 11p15.4 using restriction fragment length polymorphisms and gene dose studies performed on a patient with the Beckwith-Wiedemann syndrome accompanied with a chromosome abnormality [46,XX,-14,+der(14),t(14;11)(q32.3;p15.3)pat]. Our data suggest that PTH is localized in 11p15.3----p15.1, most likely near the border of the bands 11p15.4 and 11p15.3.