Restriction maps and restriction fragment length polymorphisms of the human 21-hydroxylase genes

Restriction maps were constructed for the two human 21-hydroxylase genes (21-OHA and 21-OHB) by using DNA from subjects homozygous for a deletion of each gene. Comparing the patterns of these two genes, a KpnI restriction site occurred in the 21-OHA gene in place of a TaqI site in the 21-OHB gene about 1-kb from the 5' end of the gene, and an extra EcoRI site was located 500 bp 5' to the common EcoRI site. The DNA of fourteen unrelated normal subjects was digested with nine restriction endonucleases (AccI, BamHI, BgIII, EcoRI, HindIII, KpnI, MspI, SacI and TaqI). Restriction fragment length polymorphisms were found with EcoRI, HindIII and AccI that resulted from polymorphic endonuclease sites outside the genes.     

The rabbit alpha-like globin gene cluster is polymorphic both in the sizes of BamHI fragments and in the numbers of duplicated sets of genes

The alpha-like globin gene cluster in rabbits contains embryonic zeta- globin genes, an adult alpha-globin gene, and theta-globin genes of undetermined function. The basic arrangement of genes, deduced from analysis of cloned DNA fragments, is 5'-zeta 0-zeta 1-alpha 1-theta 1- zeta 2-zeta 3-theta 2-3'. However, the pattern of restriction fragments containing zeta- and theta-globin genes varies among individual rabbits. Analysis of BamHI fragments of genomic DNA from 24 New Zealand white rabbits revealed eight different patterns of fragments containing zeta-globin genes. The large BamHI fragments containing genes zeta 0 and zeta 1 are polymorphic in length, whereas a 1.9-kb fragment containing the zeta 2 gene and the 3.5-kb fragment containing the zeta 3 gene do not vary in size. In contrast to this constancy in the size of the restriction fragments, the copy number of the zeta 2 and zeta 3 genes does vary among different rabbits. No length polymorphism was detected in the BamHI fragments containing the theta-globin genes, but again the copy number varies for restriction fragments containing the theta 2 gene. The alpha 1- and theta 1-globin genes are located in a nonpolymorphic 7.2-kb BamHI fragment. The combined data from hybridization with both zeta and theta probes shows that the BamHI cleavage pattern does not vary within the region 5'-alpha 1-theta 1- zeta 2-zeta 3-theta 2-3', but the pattern genomic blot-hybridization patterns for the progeny of parental rabbits with different zeta-globin gene patterns shows that the polymorphic patterns are inherited in a Mendelian fashion. Two different haplotypes have been mapped based on the genomic blot-hybridization data. The variation in the alpha-like globin gene cluster in the rabbit population results both from differences in the copy number of the duplication block containing the zeta-zeta-theta gene set and from the presence or absence of polymorphic BamHI sites.      

Analysis of the N-acetyltransferase 2 gene polymorphism in the patients with chronic obstructive pulmonary disease and in populations of the Volga-Ural region

Restriction fragment-length polymorphism of the gene coding for N-acetyltransferase 2 (NAT2) was typed in populations of the Volga-Ural region (Bashkirs, Tatars, Chuvashes, Udmurts, and Russians) as well as in patients with chronic obstructive pulmonary disease (COPD) and in healthy individuals. Rapid and slow acetylator phenotypes were determined based on the presence or absence of the KpnI, TaqI, and BamHI restriction endonuclease recognition sites. The proportion of slow acetylators in the populations examined varied from 40.00% in Bashkirs to 64.15% in Chuvashes with statistically significant difference between these two ethnic groups (chi 2 = 5.7; p = 0.02). Overall, in the Volga-Ural populations slow acetylators represented 56.25% of the subjects examined. This value was similar to those presented in other studies of Caucasoid populations. In the COPD patients a statistically significant decrease of the slow acetylator frequency to 48.28% compared to healthy individuals (62.18%) was observed (chi 2 = 4.60; p = 0.036). The data obtained suggest a possible association between the drug resistance in the COPD patients with the rapid acetylator phenotype, which can lead to the development of the chronic form of the disease.     

Physical map of the Rhodobacter sphaeroides bacteriophage phi RsG1 genome and location of the prophage on the host chromosome.

We constructed a physical map of the 50-kilobase-pair (kb) DNA of the temperate Rhodobacter sphaeroides bacteriophage phi RsG1, with the relative positions of the cleavage sites for the nine restriction endonucleases KpnI, HindIII, XbaI, ClaI, BclI, EcoRV, EcoRI, BglII, and BamHI indicated. Using biotinylated phi RsG1 DNA as a probe in hybridization studies, we detected homologies with virus DNA and fragments of restriction endonuclease-digested host chromosomal DNA but not with plasmid DNA. This indicates that the prophage is integrated into the host chromosome. In addition, the use of specific probes such as the 10.4-kb BglII A fragment and the 2.65-kb BamHI H fragment allowed the determination of the position of phage attachment site (attP).     

Construction of plasmid vectors that facilitate subcloning and recovery of yeast and Escherichia coli DNA fragments

We have constructed a plasmid vector (pNF2) which is a derivative of the multicopy yeast cloning vehicle YEp24. This derivative contains a single BamHI site flanked immediately on each side by SalI sites. The latter site was selected because it appears to be infrequent in yeast nuclear DNA. Thus, DNA fragments produced by partial digestion with enzymes (such as Sau3A) that cut at frequent intervals and leave single-stranded ends that have sequence homology with BamHI sites, can be conveniently subcloned into this site. Such fragments can then be excised intact by digestion with SalI enzyme. Plasmid pNF2 also contains the kanamycin-resistance (kanR) gene derived from Tn903 and confers resistance in yeast to the antibiotic G418. pNF2 was converted into an integrating vector (pNF3) by deleting a 2.2-kb EcoRI fragment containing a sequence that determines autonomous replication in yeast. Further deletion of a HindIII fragment containing the yeast URA3 gene converts the plasmid into one containing only pBR322 sequences plus the kanR gene (pNF4).     

Structure and restriction fragment length polymorphism of genes for human liver arylamine N-acetyltransferases.

Genomic DNA clones coding for polymorphic and monomorphic arylamine N-acetyltransferases (NAT) of human liver were isolated from a genomic DNA library, and their restriction maps and partial nucleotide sequences were determined. Messenger RNA for monomorphic NAT was coded in one exon, while mRNA for polymorphic NAT was coded in two exons; the 5'-noncoding region was located in one exon 8 kb upstream from another exon containing the coding and 3'-noncoding regions. Recently, we have shown that there are three types of polymorphic NAT gene; one of the genes corresponds to a high NAT activity, while the other two genes give rise to a low NAT activity. The restriction fragment length polymorphism (RFLP) was analyzed by Southern blot hybridization of genomic DNAs from homozygotes of the three polymorphic NAT genes using various fragments of the cloned NAT gene. RFLPs of polymorphic NAT gene were observed in coding and 3'-flanking region upon digestion with BamHI and KpnI.     

The minimal replicon of a Streptomycete plasmid produces an ultrahigh level of plasmid DNA

A functional map of Streptomyces coelicolor plasmid SCP2* was deduced from derivatives constructed by in vitro deletions. Functions were analyzed on bifunctional shuttle plasmids that contained pBR322 for selection and replication in Escherichia coli and fragments of SCP2* for replication in Streptomyces griseofuscus C581 and strains of Streptomyces lividans. The aph gene for neomycin resistance from Streptomyces fradiae and the tsr gene for thiostrepton resistance from Streptomyces azureus were incorporated as selectable antibiotic resistance markers in streptomycetes. An 11.8-kb sequence bounded by EcoRI and KpnI restriction sites contains the information for self-transfer and normal replication of the plasmid. A 5.9-kb EcoRI-SalI fragment contains all of the information for normal replication. Partial digestion generated a 2.2-kb Sau3A fragment that is sufficient for replication but it produces ten times higher plasmid copy number than the basic replicon. pHJL400 and PHJL401 are useful shuttle vectors containing the moderate-copy-number streptomycete plasmid combined with the E. coli plasmid pUC19. A 1.4-kb BclI-Sau3A fragment with an additional internal BclI site contains the minimal replicon but it produces 1000 times higher plasmid copy number than the basic replicon. pHJL302 is a useful shuttle vector containing the ultrahigh-copy-number streptomycete plasmid combined with the E. coli plasmid pUC19.     

Insertion of a long KpnI family member within a mitochondrial-DNA-like sequence present in the human nuclear genome

Structural analysis of a phage lambda Charon 4A clone carrying one of the human nuclear mitochondrial(mut)-DNA-like sequences revealed that a KpnI-family member (KpnI 5.5-kb DNA) is inserted within this sequence. The inserted KpnI 5.5-kb DNA contains several possible polyadenylation signal sequences followed by an A-rich sequence at its 3' end and is flanked by perfect 13-bp direct repeats of the duplicated mtDNA-like sequences. These structures strongly suggest that the KpnI 5.5-kb DNA is a mobile element. Comparison of the 5' terminal sequences of the KpnI 5.5-kb DNA and four other long KpnI-family DNAs so far examined, using the predicted general promoter sequence for eukaryotic tRNAs, indicates that they contain the consensus sequences for the split internal RNA polymerase III control region.     

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 characterization of styrene catabolism genes from Pseudomonas fluorescens ST.

A gene bank from Pseudomonas fluorescens ST was constructed in the broad-host-range cosmid pLAFR3 and mobilized into Pseudomonas putida PaW340. Identification of recombinant cosmids containing the styrene catabolism genes was performed by screening transconjugants for growth on styrene and epoxystyrene. Transposon mutagenesis and subcloning of one of the selected genome fragments have led to the identification of three enzymatic activities: a monooxygenase activity encoded by a 3-kb PstI-EcoRI fragment and an epoxystyrene isomerase activity and an epoxystyrene reductase activity encoded by a 2.3-kb BamHI fragment. Escherichia coli clones containing the 3-kb PstI-EcoRI fragment were able to transform styrene into epoxystyrene, and those containing the 2.3-kb BamHI fragment converted epoxystyrene into phenylacetaldehyde or, only in the presence of glucose, into 2-phenylethanol. The three genes appear to be clustered and are probably encoded by the same DNA strand. In E. coli, expression of the epoxystyrene reductase gene was under the control of its own promoter, whereas the expression of the other two genes was dependent on the presence of an external vector promoter.     

Restriction map of the 125-kilobase plasmid of Bacillus thuringiensis subsp. israelensis carrying the genes that encode delta-endotoxins active against mosquito larvae.

A large plasmid containing all delta-endotoxin genes was isolated from Bacillus thuringiensis subsp. israelensis; restricted by BamHI, EcoRI, HindIII, KpnI, PstI, SacI, and SalI; and cloned as appropriate libraries in Escherichia coli. The libraries were screened for inserts containing recognition sites for BamHI, SacI, and SalI. Each was labeled with 32P and hybridized to Southern blots of gels with fragments generated by cleaving the plasmid with several restriction endonucleases, to align at least two fragments of the relevant enzymes. All nine BamHI fragments and all eight SacI fragments were mapped in two overlapping linkage groups (with total sizes of about 76 and 56 kb, respectively). The homology observed between some fragments is apparently a consequence of the presence of transposons and repeated insertion sequences. Four delta-endotoxin genes (cryIVB-D and cytA) and two genes for regulatory polypeptides (of 19 and 20 kDa) were localized on a 21-kb stretch of the plasmid; without cytA, they are placed on a single BamHI fragment. This convergence enables subcloning of delta-endotoxin genes (excluding cryIVA, localized on the other linkage group) as an intact natural fragment.     

Cloning of the ColE3-CA38 colicin and immunity genes and identification of a plasmid region which enhances colicin production

The colicin and immunity genes of plasmid ColE3-CA38 have been localized by characterization of bacteria carrying its cloned restriction fragments. They are within a 3.14-kb EcoRI segment, such that the immunity gene contains the KpnI site, and the colicin gene is adjacent to it within a 2.1-kb KpnI-HincII segment. The immunity gene and one end of the colicin gene are in the region of ColE3-CA38 which is not homologous to the closely related plasmid ColE2-P9. A 0.64-kb PvuI-EcoRI segment of the plasmid adjacent to that containing the colicin and immunity genes was found to augment colicin production on solid media, and also affected the morphology of clearing zones produced by the cells when used as indicators in overlays of stabs of colicin E2 or E7 producers. The 0.64-kb segment was required in its native orientation relative to the 3.14-kb EcoRI segment to cause its effects.     

High-level expression vectors to synthesize unfused proteins in Escherichia coli

A new class of plasmid vectors (pANK-12, pANH-1, and pPL2) for synthesizing unfused proteins was constructed by inserting synthetic linkers at the NdeI site (CATATG) of plasmid pJL6, which contains the lambda cII gene initiator codon. These expression vectors contain the lambda pL promoter, the cII ribosome-binding site, cII start codon and unique restriction sites (KpnI, Asp718, HpaI, BamHI) downstream from the initiator ATG for expression of unfused proteins. The main advantage of these vectors is that any DNA fragment with an open reading frame that does not possess a start and/or a stop codon can be directed to overproduce protein in an unfused form.     

Molecular and genetic analyses of arylamine N-acetyltransferase polymorphism of rabbit liver

A cDNA clone encoding the full coding region of polymorphic arylamine N-acetyltransferase was isolated from rabbit liver and expressed in Chinese hamster ovary cells. The expressed enzyme acetylated 2-aminofluorene, procainamide, sulfamethazine, and p-aminobenzoic acid at equivalent rates. N-Acetyltransferase activity was measured in 17 rabbits from an inbred colony which were classified into rapid, intermediate, and slow acetylators. The livers of the rapid and intermediate acetylators efficiently acetylated all four substrates, while the liver from the slow acetylator showed a low but significant activity with p-aminobenzoic acid. Immunoblot and Northern blot analyses of rabbit livers indicated that the differences in N-acetyltransferase activity were due to differences in N-acetyltransferase protein and mRNA content. Genomic clones of N-acetyltransferase were isolated from the rapid and slow acetylator rabbits. The nucleotide sequence of the gene from rapid acetylator rabbit was identical to that of the cDNA, while the sequence of the gene from slow acetylator rabbit was homologous, but not identical, to the cDNA sequence. Genomic Southern blot and polymerase chain reaction analyses of the genomic DNAs and cDNAs from the three types of acetylator indicated that the gene for polymorphic arylamine N-acetyltransferase is totally deleted in the slow acetylator rabbit, while the gene from slow acetylator rabbit is expressed in all rabbits and might encode another N-acetyltransferase. Thus the genetic mechanism of N-acetyltransferase polymorphism in rabbit liver is essentially different from that of human liver as demonstrated in this laboratory (Ohsako, S., and Deguchi, T. (1990) J. Biol. Chem. 265, 4630-4634; Deguchi, T., Mashimo, M., and Suzuki, T. (1990) J. Biol. Chem. 265, 12757-12760).     

The EcoDXX1 restriction and modification system: cloning the genes and homology to type I restriction and modification systems

The Escherichia coli plasmid pDXX1 codes for a type I restriction and modification system, EcoDXX1. A 15.5-kb BamHI fragment from pDXX1 has been cloned and contains the hsdR, hsdM, and hsdS genes that encode the EcoDXX1 system. The EcoDXX1 hsd genes can complement the gene products of the EcoR124 and EcoR124/3 hsd systems, but not those of EcoK and EcoB. Hybridization experiments using EcoDXX1 hsd genes as a probe demonstrate homology between EcoDXX1 and EcoR124 and EcoR124/3 restriction-modification systems, but weak or no homology between EcoDXX1 and EcoK or EcoB systems.     

Sequences and expression of alleles of polymorphic arylamine N-acetyltransferase of human liver.

Fifty human livers obtained at autopsy were analyzed for N-acetyltransferase and classified into six genotypes. Determination of N-acetyltransferase activity and proteins from supernatants of liver homogenates indicate that genotype I corresponds to rapid acetylator, genotypes II and III to intermediate acetylator, and genotypes IV, V, and VI to slow acetylator phenotypes. Northern blot analysis shows that levels of mRNA for N-acetyltransferase in the livers do not markedly differ among the six genotypes. Three alleles of the N-acetyltransferase gene were cloned and sequenced. mRNA is coded in two exons. Comparison of alleles 2 and 3, which correspond to low N-acetyltransferase activity, with allele 1, which corresponds to high N-acetyltransferase activity, revealed several polymorphisms. Two gene sequence differences occur in the coding exons of alleles 2 and 3, one of which would produce different amino acids in the proteins. Those sequence differences that lead to amino acid substitutions result in a loss of BamHI and TaqI sites for alleles 2 and 3, respectively. Expression studies of the alleles in Chinese hamster ovary cells show that allele 1 expresses high levels of N-acetyltransferase activity and enzyme protein, while alleles 2 and 3 express low levels of both protein and activity.