Structure and expression of the three MHC-linked HSP70 genes

A duplicated locus encoding the major heat shock-induced protein HSP70 is located in the major histocompatibility complex (MHC) class III region 92 kilobases (kb) telomeric to the C2 gene. Nucleotide sequence analysis of the two intronless genes, HSP70-1 and HSP70-2, has shown that they encode an identical protein product of 641 amino acids. A third intronless gene, HSP70-Hom, has also been identified 4 kb telomeric to the HSP70-1 gene. This encodes a more basic protein of 641 amino acids which has 90% sequence similarity with HSP70-1. In order to investigate the expression of the three (MHC)-linked HSP70 genes individually by northern blot analysis, we have isolated locus-specific probes from the 3 untranslated regions of the genes. The HSP70-1 and HSP70-2 genes have been shown to be expressed at high levels as a 2.4 kb mRNA in cells heat-shocked at 42°C. HSP70-1 is also expressed constitutively at very low levels. The HSP70-Hom gene, which has no heat shock consensus sequence in its 5 flanking sequence, is expressed as a 3 kb mRNA at low levels both constitutively and following heat shock.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M34267-9. Address correspondence and offprint requests to: R. D. Campbell.     

Isolation of region-specific probes from pig Chromosome 6 by coincidence cloning

Coincidence cloning is a technique that permits the isolation of sequences common to two independent sources of complex DNA, and this method has been used to isolate a set of probes from a region of porcine Chromosome (Chr) 6 containing the loci for glucosephosphate isomerase (GPI) and the skeletal muscle calcium release channel (CRC). Porcine DNA was specifically PCR-amplified from a pigxhamster hybrid cell line containing the centromere region (p1.2–q1.2) of pig Chr 6 and other pig chromosome fragments by use of a porcine SINE specific primer with an EcoRI site in the 5-end. Flow-sorted Chr 6 preparations were amplified with the same SINE primer, but with a SalI site in the 5-end. The products were digested with EcoRI and SalI respectively, combined, denatured, and reannealed. The heteroduplex molecules, containing both an EcoRI and a SalI cohensive end, were selected by cloning in SalI/EcoRI-digested pUC13. Approximately 40% of the primary clones contained a single SalI/EcoRI-insert, indicating that they are coincidence clones. The average insert size was 1.4 kb. Fluorescence in situ hybridization of a pool of 34 coincidence clones to pig chromosomes showed a preferential labeling of the centromere region and of the q2.5–q2.7 region of pig Chr 6. Nineteen coincidence clones were hybridized to SINE-PCR products from flow-sorted pig Chr 6 and to pigxrodent hybrid cell lines. Eighteen clones gave positive signals correlated with the GPI/CRC content of the source DNAs.     

Mapping of the SLA complex class III region by pulsed field gel electrophoresis

The fine order of genes in the class III region of the swine major histocompatibility complex (MHC), the SLA complex, was examined by pulsed field gel electrophoresis (PFGE) and Southern blot analysis. Four genes, C2, HSP70, TNF, and CYP21, were analyzed. The CYP21, C2, and HSP70 genes were all located within a 200-kb NotI fragment. The C2, HSP70, and TNF genes cohybridized to a 420-kb SalI fragment. The TNF gene is linked to the class I region by a 390-kb NotI fragment. Combined with a previous study from our lab, the order of genes in the SLA complex is class II-class III [(CYP21/C4)-(Bf/C2/HSP70)-TNF]-class I. The size of the class III region from CYP21 to TNF is estimated to be 500 kb. This size and the order of the genes in the swine class III region are similar to those of human, mouse, goat, and rabbit, which confirms the high conservation of class III gene organization across species.     

Sixty-nine kilobases of contiguous human genomic sequence containing the α-galactosidase A and Bruton's tyrosine kinase loci

Several disease loci have been mapped to the Xq21.3–Xq22 region of the human X Chromosome (Chr) including X-linked agammaglobulinemia (XLA), Fabry disease, Alport syndrome, and Pelizaeus Merzbacher disease. Upon cloning of the XLA gene, Bruton's tyrosine kinase (btk), both Fabry disease and XLA were mapped within the same 50- to 70-kb interval. In order to investigate the genomic organization of the region surrounding btk and the Fabry disease gene, -galactosidase A (gla), we constructed a 6-cosmid contig spanning the region from 5 of gla to 3 of btk. Two of these cosmids spanning most of the coding sequence and the upstream region of btk and gla, U237D10 and U230D1, were sequenced by a random shotgun strategy combined with automated sequencing, resulting in 69 kb of contiguous genomic sequence. Sequencing of U237D10 showed btk to be comprised of 19 exons spanning over 35 kb. Sequencing of U230D1 showed that the 3 end of gla is 9 kb from the 5 end of btk and also demonstrated the presence of two additional genes in the region immediately 5 to btk. The surprisingly high gene density is similar to that seen previously only in the human major histocompatibility locus.     

Characterization of pig-mink cell hybrids: assignment of the TK1 and UMPH2 genes to pig chromosome 12

By fusion of thymidine kinase-deficient mink cells with pig leukocytes, a new type of cell hybrid was produced. It was demonstrated that pig chromosomes segregate in pig-mink hybrids and that hybrid cells contain no cytologically visible rearrangements between the chromosomes of parental species, or chromosome fragmentation. With a set of subclones of two primary hybrid clones, the genes for thymidine kinase-1 (TK1) and uridine 5-monophosphate hydrolase-2 (UMPH2) were assigned to pig Chromosome (Chr) 12. A cell line with a single pig Chr 8 on the background of mink chromosomes was established. This clone could serve as a source of DNA for building a chromosome-specific library of pig Chr 8. The data obtained suggest that pig-mink cell hybrids can be used for mapping of pig chromosomes.     

Characterization of six new loci within the swine major histocompatibility complex class III region

A search for new potential coding sequences was conducted within two overlapping cosmid genomic DNA clusters of about 170 and 45 kb from the swine major histocompatibility complex class III region. The sequences were detected with various probes, including pools of swine cDNA, homologous and heterologous genomic sequences, and synthetic oligonucleotides. The 170 kb cluster was centered on the tumor necrosis factor genes (TNF), and the 45 kb cluster contained the heat-shock protein 70 genes (HSP70). The TNF cluster revealed the presence of five new genes: lymphotoxin , BAT1, BAT2, BAT3, and a sequence related to DNA-binding factors. No sequence homologous to B144 was found in the TNF cluster, although other unidentified coding sequences may be present in this cluster. The HSP70 cluster contained a gene identified as BAT6, that is, tRNA-valyl synthetase. These results provide new evidence that the genomic maps of these various genes in the TNF and HSP70 sub-regions are similar in swine and human.     

3-Hydroxy-3-methylglutaryl coenzyme A lyase (HL): cloning and characterization of a mouse liver HL cDNA and subchromosomal mapping of the human and mouse HL genes

3-Hydroxy-3-methylglutaryl coenzyme A lyase (HL) is a homodimeric mitochondrial matrix enzyme that catalyzes the last step of ketogenesis. Using a human HL cDNA as a probe, we isolated a 1.4-kb mouse HL cDNA (HLM) from a mouse liver library and extended the sequence in the 5 direction, using RACE PCR to include the complete coding sequence. The nucleotide sequence of the mouse HL coding region is 85.7% identical to human HL, and 52.6% to Ps. mevalonii HL. Peptide identities of 87.4% and 54.3% respectively were observed. Southern analysis of 29 strains of laboratory mice and of Mus spretus revealed a total of about 25 kb of hybridizing fragments and three polymorphic fragments in both EcoRI and HindIII digestions. The mouse HL locus (Hmgcl) was localized on Chromosome (Chr) 4: Pmv-19-12.6±3.6 cM-Hmgcl-7.3±2.3 cM-Xmv-8-1.5±1.0 cM-Gpd1. The human HL locus (HMGCL) was mapped to distal Chr 1p by analysis of a human-hamster hybrid cell panel and by in situ hybridization.     

A linkage map with microsatellites isolated from swine flow-sorted Chromosome 11

We have developed a simple and efficient method to construct partial libraries of swine Chromosome (Chr) 11, starting with only 300 flow-sorted copies. DNA is amplified by PARM-PCR with primer containing at the 5-end the sequence AGCU-. After amplification, digestion of PCR products with uracil DNA glycosylase generates cohesive ends corresponding to the SstI site. The amplified fragments can then be ligated in vector linearized with the SstI enzyme. Using five different primers, we PARM-PCR amplified and cloned swine Chr 11 DNA. These chromosome-specific libraries have been used to develop 14 different (TG)n microsatellites. Ten of these markers were assigned to Chr 11 by PCR analysis of a panel of Pig-Rodent somatic hybrids and by linkage analysis of the 171 individuals of the PiGMaP reference families. A complete linkage map of 147 cM of this chromosome was then realized by integrating existing markers.     

Molecular characterization of a wound-inducible inhibitor I gene from potato and the processing of its mRNA and protein

Genomic blotting of restriction fragments of Russet Burbank DNA indicated that at least 6 copies of Inhibitor I are present in the tetraploid potato genome. A library of potato genes in bacteriophage was screened for the presence of Inhibitor I genes using a wound-inducible tomato Inhibitor I cDNA as a hybridization probe. One phage with an insert of 13.1 kb was isolated that hybridized most strongly with the probe. A 4.2 kb Eco RI fragment containing the gene was isolated from the clone and 2.2 kb region was sequenced that included about 800 bp of both the 5 and 3 regions. The gene contained two introns of 479 and 417 bp respectively, and the splice junctions were typical of other eukaryotic genes. Putative TATAA and CAAT boxes were identified. The nucleotide sequence, when compared with a wound-inducible tomato Inhibitor I cDNA, exhibited over 90% identity. The gene codes for a prepro-Inhibitor I protein of 96 amino acids. The putative pre-sequence of 19 amino acids, differs in only one residue from that of tomato Inhibitor I. The potato pro-sequence, however, is lacking a tetrapeptide that is found in the tomato pro-sequence in the region of pro-peptide processing. This deletion, together with a substitution of a Gln for a Leu (4 residues toward the N terminus) provides an explanation for the differences at the N-termini between tomato and potato Inhibitor I natural proteins by providing different processing sites in the two pro-inhibitors. Thus, amino acid sequence differences between the N termini of tomato and potato Inhibitor I are easily explained by the mutational events. The different proposed pro-processing sites of the tomato and potato inhibitors suggest that a processing protease may be present in the vacuole with a specificity for Asn-X and Gln-X bonds.This is Scientific Paper No. 7493, Project 1791, College of Agriculture and Home Economics Research Center, Washington State UniversityThis is Scientific Paper No. 7493, Project 1791, College of Agriculture and Home Economics Research Center, Washington State University     

Occurrence of aminoglycoside phosphotransferase subclass I and II structural genes among Enterobacteriaceae spp. isolated from meat samples

Summary 3-Aminoglycoside phosphotransferase [APH(3)] enzymes are a group responsible for resistance to the antibiotics kanamycin (Km) and neomycin (Nm) in bacteria. Escherichia coli ECT24, originally isolated from a meat sample, harboured an 83-kb conjugative R-plasmid (pRPJ24) that carries transferable resistance to Km and Nm. Plasmid pRPJ24 was transferred by conjugation to Enterobacter cloacae 94R, which was used as the source of plasmid DNA in development of a probe for the Km-resistance determinant. Random cloning of BamHI and HindIII double-digest restriction fragments of pRPJ24 in the pUC18 vector plasmid produced clones resistant to both Nm and Km carrying a 1.9-kb DNA insert. Southern hybridization of pRPJ24 cloned chimeric plasmid DNA (pKPJ94) showed homology with the APH(3)II gene from transposon Tn5. A PstI digest of pKPJ94 produced a 920-bp fragment which hybridized with the APH(3)II structural gene, and was used as a DNA probe for the APH(3)II subclass gene. A 980-bp BamHI fragment from plasmid pGH54 carrying the APH(3)I gene from transposon Tn903 was used as a subclass I probe. Total DNA from 206 randomly screened Km-resistant Enterobacteriaceae isolates from raw ground beef and chicken meat samples were examined for the occurrence of APH(3) subclass I and II using non-radioactively-labelled DNA probes. Thirty-six percent and 60% of the isolates examined carried subclass I and II resistances, respectively, in the isolates from chicken meat samples. The corresponding values for bacterial strains from raw ground beef samples were 51% and 72%, respectively. Four percent of the resistant bacterial isolates from chicken samples did not display homology to either probe. This value was 28% for bacterial isolates from ground beef. Three percent of bacterial isolates from chicken samples and 44% from ground beef samples displayed homology to both APH(3) I and II DNA probes. Offprint requests to: A. H. G. P. Jayaratne     

Prothymosin α gene in humans: organization of its promoter region and localization to chromosome 2

A genomic clone encoding prothymosin (gene symbol: PTMA), a nuclear-targeted protein associated with cell proliferation, was isolated and the 5-regulatory region subcloned and sequenced. Because of previously reported discrepancies between several cDNA clones and a genomic clone for prothymosin , we determined the sequence of the first exon and of a 1.7-kb region 5 to the first exon. The sequence of the genomic clone reported here corresponds to the published cDNA sequences, suggesting that the previously noted discrepancies may be due to genetic polymorphism in this region. In addition, our sequence data extend the known 5-upstream sequence by an additional 1.5 kb allowing the identification of numerous, potential cis-acting regulatory sites. This 5-flanking cloned probe permitted us to localize the protothymosin gene to chromosome 2 in humans.     

Characterization of a swine chromosome-specific centromeric higher-order repeat

The centromeric region of swine chromosomes is comprised of tandemly repeated, divergent DNA monomer units. Here we report that these divergent DNA monomer sequences are organized into higher-order repeats, analogous to the hierarchical organization of α-satellite monomers in human centromeres. In this study, a centromeric cosmid clone was shown to be comprised entirely of a 3.3-kb higher-order repeat, with independent copies of this higher-order repeat more than 99% identical to each other. This higher-order repeat is composed of ten divergent monomer units of approximately 340 bp. The ten monomers are on average 79% identical, and all ten monomers are arranged in the same 5′ to 3′ orientation. In FISH analysis, a cloned 3.3-kb higher-order repeat hybridized to the centromere of Chromosome (Chr) 9 in metaphase spreads and detected two discrete foci in interphase nuclei, demonstrating that this swine higher-order repeat is chromosome-specific. The Chr 9 centromeric array spanned approximately 2.2 Mb as determined by pulsed-field gel electrophoresis. Moreover, the swine Chr 9 centromere is highly polymorphic, because an EcoRI restriction site polymorphism was detected. Thus, the assembly of divergent satellite sequences into chromosome-specific higher-order repeats appears to be a common organizational feature of both the human and swine centromere and suggests that the evolutionary mechanism(s) that create and maintain higher-order repeats is conserved between their genomes. Received: 6 August 1998 / Accepted: 20 January 1999     

Genes encoding light-harvesting and reaction center proteins from Chromatium vinosum

Sequencing of a 3.4 kb DNA fragment isolated from the photosynthetic purple sulfur bacterium Chromatium vinosum and of PCR products has resulted in identification of the Chr. vinosum pufL, pufM, and pufC genes, reading from the 5 to the 3 direction, and coding, respectively, for the L, M and cytochrome c subunits of the reaction center of this bacterium. Other PCR products have been used to obtain complete sequences for the pufB and pufA genes, located immediately upstream from pufL and encoding the apoproteins of two Chr. vinosum light- harvesting proteins. The 3-portion of the bchZ gene, a gene that codes for a protein involved in the biosynthesis of bacteriochlorophyll, has been located immediately upstream from pufB. A second pufB gene, pufB2, has been located downstream from pufC, as has the 5-portion of a second pufA gene, pufA2. The location of a second set of pufB and pufA genes, encoding light- harvesting proteins, downstream from pufC has not previously been reported for any photosynthetic bacterium. Translation of the gene sequences encoding these Chr. vinosum light-harvesting proteins reveals both similarities to and differences from the amino acid sequences, obtained from direct sequencing of the apoproteins, previously reported for Chr. vinosum light-harvesting proteins. Translation of these gene sequences, and of those for pufL, pufM and pufC, revealed significant homology, at the amino acid level, to the corresponding peptides of photosynthetic purple non-sulfur bacteria.     

Identification of expressed bovine class I MHC genes at two loci and demonstration of physical linkage

A cDNA library prepared from lymphocytes of a cow (E98), homozygous at major histocompatibility complex (MHC) loci (BoLA phenotype w10, KN104), was screened with a bovine MHC class I probe. Of the cDNA clones isolated, two, (2.1 and 5.1) were selected and showed divergence at both 5 and 3 termini. E98 DNA was digested with rare-cutter enzymes (Sfi I, Mlu I, Not I, and Cla I) and fragments were size-separated by field inversion gel electrophoresis (FIGE). Hybridization with an entire class I cDNA probe revealed multiple fragments generated by each enzyme. When the 3 untranslated regions (UT) of 2.1 and 5.1 were used as probes, only one fragment was revealed in each digested sample, showing locus specificity of these probes in cattle. Further, DNA of transfected mouse fibroblasts L4 (expressing KN104) and L10 (expressing w10) hybridized to the 3UT regions of clones 2.1 and 5.1, respectively, Northern blot analysis of the mRNA of the L4 and L10 transfected cells provided further evidence that the cDNA clones 2.1 and 5.1 code for the BoLA-KN104 and BoLA-w10 class I molecules respectively, and thus these represent the products of two different genes. A long range physical mapping of the BoLA-w10 and KN104 genes was performed using FIGE analysis of DNA of and homozygous and an heterozygous animal. This analysis revealed that the BoLA-w10 and KN104 genes are separated by not more than 210 kilobases (kb) and that they are components of a multigene family spanning 1550 kb. As the] w10 gene is at the BoLA-A locus we assign the KN104 gene to a B locus.     

Expression and analysis of the rat placental class I cDNA clone encoding the Pa antigen

The previously sequenced cDNA clone pARL 5 was recloned into the mammalian expression vector pcEXV3, and transient and permanent transfectants were prepared in COS7 green monkey kidney fibroblasts. The transfectants were analyzed by indirect immunofluorescence using monoclonal and polyclonal antibodies raised in specifically selected rat strain combinations. These studies showed that pARI.5 encodes the Pa antigen and that the Pa molecule is distinct from the A^a molecule. Probes were derived from the pARL5 clone and used to study the genomic DNA from Pa-positive and Pa-negative strains. Two probes derived from the 3' untranslated region (3apARI.5 and 3bpARI.5) and one probe derived from the 5' region (5pARI.5) hybridized nonspecifically in all strains under moderate stringency conditions. By contrast, anXba I restriction fragment unique to thePa gene was detected with the (5pARI.5) probe under high stringency conditions. This probe hybridized with a 1.8 kilobase (kb) fragment in the Pa-positive strains and with a 1.7 kb band in the Pa-negative strains. These studies suggest that the gene encoding the Pa antigen, or a fragment thereof, is present in both Pa-positive and Panegative strains but may not be expressed in the latter.     

5′ and 3′ SINE-PCR allows genotyping of pig families without cloning and sequencing steps

A microsatellite-containing clone, isolated from a pig Chromosome (Chr) 1-specific library was characterized by sequencing and computer analysis. The (CA)₁₇ microsatellite motif was located at the 3 end of a short interspersed element (SINE) sequence at the position normally occupied by the oligo (A) stretch. Further computer analysis indicated that 12% of published pig SINE sequences contain dinucleotide repeat motifs adjacent to their 3 ends. By performing PCR with a single SINE primer in combination with a panel of arbitrarily selected unique primers, we have demonstrated that, as in human, polymorphisms can be detected and typed in pig family DNAs. A large number of SINE primer x unique primer combinations have been screened for the ability to detect polymorphisms in pig reference family DNAs. This approach does not require prior sequence information other than that of the pig SINE. We have also found polymorphisms at the 5 ends of pig SINE sequences by similar methods, but with a primer facing out to the 5 end of the SINE.     

Application of modified differential display technique for cloning and sequencing of the 3′ region from three putative members of wheat HSP70 gene family

We have modified the differential display technique to isolate 3 regions from different members of the wheat HSP70 gene family. An HSP70 gene family-specific degenerate primer was used as a 5 primer in place of the arbitrary primer used in the original technique. We cloned and sequenced three cDNA fragments that were differentially expressed in heat stressed wheat seedlings. Based on the high similarity between predicted translation products of these three sequences and known members of the HSP70 family from plants, these cDNAs were identified as members of the HSP70 gene family. Two of these members appeared distinct in the 3 non-coding region with only 48% identity. Therefore differential display could successfully be used to isolate 3 regions of different members of a multigene family in a relatively short period, even if the members had highly similar protein-coding regions.     

Cloning and sequencing of a ligninase gene from a lignindegrading basidiomycete,Phanerochaete chrysosporium

Summary A ligninase gene has been cloned from a Phanerochaete chrysosporium genomic DNA library. Nucleotide sequencing of the gene has revealed that the ligninase structural gene contains 1116 bp of the protein-encoding sequence, of which 84 bp encode the signal peptide. The protein-encoding sequence is interrupted by eight introns which conform to the universal G-T/A-G splicing rule observed for the 3 and 5 intron boundaries. The putative eukaryotic regulatory sequences, i.e. CAAT and TATA box-like sequences, are present in the 5 flanking region.     

Lack of a BglII site at the 5′ region of the PGK 1 locus: a new variant discovered in two Chibchan Amerindian groups from Costa Rica

A new 3.8-kb allele at the 5 region of the PGK 1 locus detected by the probe pSPT/PGK is reported. This variant was discovered in the Cabecar and Guaymi, two Chibchan Amerindian groups of Costa Rica. So far, a polymorphism that consists of an EcoRI/BglI (1.3-kb) variable site within an EcoRI/BglII (1.7-kb) fragment when DNA is simultaneously digested with EcoRI, BglI and BglII is known to occur in black and Caucasian populations. These two alleles were also found in the Amerindians tested. The newly described band is due to the lack of the BglII site situated 1.7 kb downstream from the EcoRI site and to the cleavage of another BglII site 2.1 kb downstream from the lacking one. This variant might be restricted to some Amerindian groups and perhaps also to Asiatic populations. Thus, it could be a useful marker in evolutive studies and for forensic applications. Moreover, the presence of a third allele in populations with Amerindian ancestry can increase the heterozygosity of the region disclosed by the pSPT/PGK probe, thus improving its application in issues dealing with X-chromosome activation ratios in females.