Host/vector interactions which affect the viability of recombinant phage lambda clones

A gene encoding the tryptophan synthase beta subunit of Arabidopsis thaliana

The DNA sequence of a tryptophan synthase gene and the flanking 5' and 3' regions has been determined for Arabidopsis thaliana. The sequence encodes only the beta subunit domain, indicating that alpha and beta subunits are specified by separate genes. The gene contains four introns and encodes 470 amino acid residues. The plant amino acid sequence is highly conserved with respect to corresponding microbial sequences. The NH2-terminal amino acid sequence is characteristic of chloroplast transit peptides. Identity of the sequences of the genomic exons and a cDNA clone and the presence of cellular RNA corresponding in size and 5' sequence to the gene indicate that the gene is expressed. Analysis of Arabidopsis genomic DNA suggests the presence of a second gene for the beta subunit.

Structural analysis of proviral DNA in simian foamy virus (LK-3)-infected cells

Proviral DNA of the T-cell lymphotropic simian foamy virus strain LK-3 was characterized. In infected cells, multiple copies of unintegrated linear duplex viral DNA of about 13 kbp length are present. Nuclease S1 treatment of the DNA generated two fragments of 6.5 and 6.0 kbp length that were cloned in phage and plasmid vectors. The proviral DNA contains a single-stranded gap of 109 nucleotides. A DNA fragment spanning the gap was cloned after completing the double strand by DNA synthesis in vitro. At the 3' end, the gap contains a polypurine tract (PPT) similar to the putative initiation site of retroviral plus strand DNA synthesis, suggesting discontinuous DNA synthesis. Further analysis of the genome architecture revealed LTRs of 1.7 kbp length. An additional 1.7 kbp DNA fragment was detected after nuclease S1 digestion of proviral DNA and probably represents trimmed intermediates of "strong-stop" DNA.

Escherichia coli sbcC mutants permit stable propagation of DNA replicons containing a long palindrome

Recombinant DNA libraries generated in vitro should in theory contain all of the sequences of the genomes from which they are derived. However, the literature is dotted with reports of sequences that cannot be recovered, are under-represented, or are highly unstable. In particular, long palindromic nucleotide sequences of perfect or near-perfect symmetry are either lethal to the vector or suffer deletions or other rearrangements that remove symmetry [Collins, Cold Spring Harbor Symp. Quant. Biol. 45 (1981) 409-416; Collins et al., Gene 19 (1982) 139-146; Hagan and Warren, Gene 24 (1983) 317-326]. We report here that mutation of a single gene, namely sbcC, can overcome this inviability and allow for the stable propagation of a 571-bp nearly perfect palindrome in Escherichia coli. This has implications for the choice of strains used for the recovery and analysis of cloned nucleotide sequences.

The cyclization of linear DNA in Escherichia coli by site-specific recombination

The efficiency with which linearized plasmid DNA can transform competent Escherichia coli can be significantly increased by use of the Cre-lox site-specific recombination system of phage P1. Linear plasmid molecules containing directly repeated loxP sites (lox2 plasmids) are cyclized in Cre+ E. coli strains after introduction either by transformation or by mini-Mu transduction. Exonuclease V activity of the RecBC enzyme inhibits efficient cyclization of linearized lox2 plasmids after transformation. By use of E. coli mutants which lack exonuclease V activity, Cre-mediated cyclization results in transformation efficiencies for linearized lox2 plasmids identical to those obtained with covalently closed circular plasmid DNA. Moreover, Cre+ E. coli recBC strains allow the efficient recovery of lox2 plasmids integrated within large linear DNA molecules such as the 150-kb genome of pseudorabies virus.

Enhanced recovery and restriction mapping of DNA fragments cloned in a new lambda vector

In this paper we describe a modification to the lambda vector EMBL3 which greatly expedites the construction of restriction maps of cloned DNA sequences. In the modified vector, EMBL3cos, all the phage coding sequences are placed to the right of the cloning sites so that the left cohesive end is separated by only 200bp, rather than 20kb (as in conventional lambda vectors), from the inserted DNA fragment. We show that reliable restriction maps can be rapidly constructed from partial digests of clones made in this vector by labelling the left cohesive end with a complementary 32P-labelled oligonucleotide. In addition, we quantify the restriction of clones containing human DNA by the McrA and McrB systems of E. coli and show that the use of Mcr- plating strains can increase the yield of recombinant phage up to tenfold, to give cloning efficiencies of greater than or equal to 10(7) pfu/microgram of human DNA.

Herpes simplex virus-directed overreplication of chromosomal DNA physically linked to the simian virus 40 integration site of a transformed hamster cell line

In the simian virus 40 (SV40)-transformed hamster cell line Elona herpes simplex virus (HSV) induces amplification of SV40 DNA sequences to high-molecular-weight head-to-tail concatemers indicating an extrachromosomal rolling circle replication. In order to enable investigations concerning intrachromosomal amplification of SV40 DNA sequences and flanking cellular sequences a genomic library of Elona DNA was constructed in phage lambda. Clones harboring cellular DNA adjacent to the SV40 integration site were isolated. Plasmid subclones devoid of SV40 DNA sequences were used as hybridization probes against total DNA from HSV-infected cells. Thus the amplification of both flanking cellular sequences was demonstrated, indicating a bidirectional replication mode.

McrA and McrB restriction phenotypes of some E. coli strains and implications for gene cloning

The McrA and McrB (modified cytosine restriction) systems of E. coli interfere with incoming DNA containing methylcytosine. DNA from many organisms, including all mammalian and plant DNA, is expected to be sensitive, and this could interfere with cloning experiments. The McrA and B phenotypes of a few strains have been reported previously (1-4). The Mcr phenotypes of 94 strains, primarily derived from E. coli K12, are tabulated here. We briefly review some evidence suggesting that McrB restriction of mouse-modified DNA does occur in vivo and does in fact interfere with cloning of specific mouse sequences.

Isolation and characterization of full-length functional cDNA clones for human carcinoembryonic antigen

Carcinoembryonic antigen (CEA) expression is perhaps the most prevalent of phenotypic changes observed in human cancer cells. The molecular genetic basis of this phenomenon, however, is completely unknown. Twenty-seven CEA cDNA clones were isolated from a human colon adenocarcinoma cell line. Most of these clones are full length and consist of a number (usually three) of surprisingly similar long (534 base pairs) repeats between a 5' end of 520 base pairs and a 3' end with three different termination points. The predicted translation product of these clones consists of a processed signal sequence of 34 amino acids, an amino-terminal sequence of 107 amino acids, which includes the known terminal amino acid sequence of CEA, three repeated domains of 178 amino acids each, and a membrane-anchoring domain of 27 amino acids, giving a total of 702 amino acids and a molecular weight of 72,813 for the mature protein. The repeated domains have conserved features, including the first 67 amino acids at their N termini and the presence of four cysteine residues. Comparisons with the amino acid sequences of other proteins reveals homology of the repeats with various members of the immunoglobulin supergene family, particularly the human T-cell receptor gamma chain. CEA cDNA clones in the SP-65 vector were shown to produce transcripts in vitro which could be translated in vitro to yield a protein of molecular weight 73,000 which in turn could be precipitated with CEA-specific antibodies. CEA cDNA clones were also inserted into an animal cell expression vector and introduced by transfection into mammalian cell lines. These transfectants produced a CEA-immunoprecipitable glycoprotein which could be visualized by immunofluorescence on the cell surface.

Isolation and characterization of full-length functional cDNA clones for human carcinoembryonic antigen

Carcinoembryonic antigen (CEA) expression is perhaps the most prevalent of phenotypic changes observed in human cancer cells. The molecular genetic basis of this phenomenon, however, is completely unknown. Twenty-seven CEA cDNA clones were isolated from a human colon adenocarcinoma cell line. Most of these clones are full length and consist of a number (usually three) of surprisingly similar long (534 base pairs) repeats between a 5' end of 520 base pairs and a 3' end with three different termination points. The predicted translation product of these clones consists of a processed signal sequence of 34 amino acids, an amino-terminal sequence of 107 amino acids, which includes the known terminal amino acid sequence of CEA, three repeated domains of 178 amino acids each, and a membrane-anchoring domain of 27 amino acids, giving a total of 702 amino acids and a molecular weight of 72,813 for the mature protein. The repeated domains have conserved features, including the first 67 amino acids at their N termini and the presence of four cysteine residues. Comparisons with the amino acid sequences of other proteins reveals homology of the repeats with various members of the immunoglobulin supergene family, particularly the human T-cell receptor gamma chain. CEA cDNA clones in the SP-65 vector were shown to produce transcripts in vitro which could be translated in vitro to yield a protein of molecular weight 73,000 which in turn could be precipitated with CEA-specific antibodies. CEA cDNA clones were also inserted into an animal cell expression vector and introduced by transfection into mammalian cell lines. These transfectants produced a CEA-immunoprecipitable glycoprotein which could be visualized by immunofluorescence on the cell surface.

A new shuttle cosmid vector, pKC505, for streptomycetes: its use in the cloning of three different spiramycin-resistance genes from a Streptomyces ambofaciens library

A new shuttle cosmid vector, pKC505, was constructed for the cloning of Streptomyces DNA. This vector, which can be conjugally transferred between different streptomycetes, was used to construct a genomic library from a spiramycin-producing S. ambofaciens strain. By transformation of the spiramycin-sensitive S. griseofuscus with the library, three phenotypically different spiramycin-resistance genes were isolated. S. ambofaciens DNA in these clones was colinear with the chromosome, and the cloned DNA was stable in E. coli, S. griseofuscus and S. fradiae. These cosmids could be isolated easily from S. griseofuscus, an improvement over the previous shuttle cosmid vector, pKC462a [Stanzak et al., Bio/Technology 4 (1986) 229-232], which was somewhat difficult to isolate from S. lividans.