R Factor Deoxyribonucleic Acid in Chromosomeless Progeny of Escherichia coli

The deoxyribonucleic acid (DNA) of resistance (R) factor 222 carried by Escherichia coli strain P678-54 was found in the normally chromosomeless progeny (minicells) of that strain. The entry of the R222 DNA into minicells appears to be via segregation at the time of their formation from normal cells. The R222 DNA can replicate in minicells although the extent of its replication appears to be limited. An analysis of the R222 DNA structure indicates that it exists in minicells as double-stranded linear, open circular, and twisted circular monomers (molecular weight, about 6.2 x 10(7) daltons). The monomers visualized by electron microscopy are 31.0 +/- 0.5 mum in length. An examination of the effect of acridine orange on the replication of R222 and colicin E1 DNA indicates the dye intereferes with plasmid DNA replication.     

Repressor for the sn-glycerol-3-phosphate regulon of Escherichia coli K-12: cloning of the glpR gene and identification of its product

The glpR gene encoding the repressor for the glp regulon of Escherichia coli was cloned from a library of HindIII DNA fragments established in bacteriophage lambda. Phages harboring glpR were isolated by selection for sn-glycerol-3-phosphate dehydrogenase function encoded by glpD, which is adjacent to glpR on the E. coli linkage map. Restriction endonuclease analysis and recloning of DNA fragments localized glpR to a 3-kilobase-pair EcoRI-SalI segment of DNA. Strains exhibiting constitutive expression of the glp operons were strongly repressed after introduction of multicopy plasmids containing the glpR gene. Analysis of proteins labeled in minicells harboring either glpR+ recombinant plasmids or a glpR::Tn5 derivative showed that the glpR gene product is a protein with an apparent molecular weight of 33,000.     

Cloning and expression of the beta-D-phosphogalactoside galactohydrolase gene of Lactobacillus casei in Escherichia coli K-12.

Lactose metabolism in Lactobacillus casei 64H is associated with the presence of plasmid pLZ64. This plasmid determines both phosphoenolpyruvate-dependent phosphotransferase uptake of lactose and beta-D-phosphogalactoside galactohydrolase. A shotgun clone bank of chimeric plasmids containing restriction enzyme digest fragments of pLZ64 DNA was constructed in Escherichia coli K-12. One clone contained the gene coding for beta-D-phosphogalactoside galactohydrolase on a 7.9-kilobase PstI fragment cloned into the vector pBR322 in E. coli strain chi 1849. The beta-D-phosphogalactoside galactohydrolase enzyme isolated from E. coli showed no difference from that isolated from L. casei, and specific activity of beta-D-phosphogalactoside galactohydrolase was stimulated 1.8-fold in E. coli by growth in media containing beta-galactosides. A restriction map of the recombinant plasmid was compiled, and with that information, a series of subclones was constructed. From an analysis of the proteins produced by minicells prepared from transformant E. coli cells containing each of the recombinant subclone plasmids, it was found that the gene for the 56-kilodalton beta-D-phosphogalactoside galactohydrolase was transcribed from an L. casei-derived promoter. The gene for a second protein product (43 kilodaltons) was transcribed in the opposite direction, presumably under the control of a promoter in pBR322. The relationship of this second product to the lactose metabolism genes of L. casei is at present unknown.     

Construction and analysis of recombinant lambda phages containing mitochondrial DNA fragments.

Rat mtDNA has a molecular length of about 16 kilobase (kb) pairs and is cleaved into seven fragments by restriction endonuclease EcoRI. These fragments were cloned in Escherichia coli K-12 host using lambda gtWES.lambda B' (lambda gtWES.lambda B, for short, in this paper) as a vector. Recombinant DNAs containing one or a few fragments of the mtDNA were transfected to CaCl2-treated E. coli, and the plaques containing specific recombinant phages were selected. DNA amplified in the recombinanat phage lambda gt.mt was shown to contain the same restriction endonuclease cleavage sites as those found in the mtDNA. Present results permitted the DNA sequencing of any portion of the mitochondrial genome.     

Expression of cloned mitochondrial DNA from the petite negative yeast Schizosaccharomyces pombe in E. coli minicells

The minicell producing Escherichia coli strain D24 (lysogenic for phage lambda cI857) was transformed with the recombinant plasmid pDG3 containing the entire mitochondrial (mt) genome of the fission yeast Schizosaccharomyces pombe (S. pombe) cloned in the single BamHI-site of the E. coli plasmid pBR322 (Del Giudice 1981). By DNA-RNA hybridization it could be shown that the total mtDNA sequence of the plasmid pDG3 was transcribed in the E. coli minicells. The cloned mtDNA also directed the synthesis of at least five novel polypeptides with molecular weights between 7,200 and 34,000. When the minicell producing E. coli strain P678-54 was transformed with the hybrid plasmid pDG3, considerable portions of the inserted mtDNA sequences were deleted. One of the resulting plasmids (pDG4), lacking about two-thirds of the mtDNA sequence, directed the synthesis of new polypeptides in the range of 7,000 to 17,500 daltons. Another derivative of pDG3, the plasmid pDG5, containing one-sixth of the mtDNA sequence, directed the synthesis of at least three novel polypeptides. The mt origin of novel polypeptides coded by the hybrid plasmid pDG3 was demonstrated by use of antisera raised against total mitochondrial proteins from S. pombe and antisera against subunits II and III of cytochrome c oxidase from Saccharomyces cerevisiae (S. cer.).     

Hybrid plasmids containing the araBAD genes of Escherichia coli B/r.

The DNA fragments generated by restriction endonuclease BamI which contain the araCBAD genes from E.coli B/r have been cloned. The DNA fragments containing ara genes were idenified by a compairson of the BamI fragments of lambdah80dara phages containing different ara deletion mutations. The ara genes were cloned into the plasmid pBR317, a derivative of ColE1. The cloned DNA fragments were analyzed by digestion with pairs of restriction endonucleases to determine the molecular weight of the chimeras and to identify the cloned ara DNA fragments. The cloned ara fragments were also identified by genetic complementation and recombination tests.     

Cloning and expression of Thiobacillus versutus aspartate-semialdehyde dehydrogenase gene in Escherichia coli

The Thiobacillus versutus asd gene coding for aspartate-semialdehyde dehydrogenase was cloned in Escherichia coli cells using pBR322 as a vector. The gene was expressed independently of its orientation, suggesting that E. coli RNA polymerase recognized T. versutus promoter sequence. The T. versutus DNA coded protein, of the molecular weight 44,000, was identified by the analysis of the proteins produced by minicells.     

Protein expression in Escherichia coli minicells containing recombinant plasmids specifying trimethoprim-resistant dihydrofolate reductases.

Deoxyribonucleic acid fragments containing the structural genes for several trimethoprim-resistant dihydrofolate reductases from naturally occurring plasmids were inserted into small cloning vehicles. The genetic expression of these hybrid plasmids was studied in purified Escherichia coli minicells. The type I dihydrofolate reductase, encoded by plasmid R483 and residing within transposon 7 (Tn7), had a subunit molecular weight of 18,000. The type II dihydrofolate reductase, specified by plasmid R67, had a subunit molecular weight of 9,000. These two enzymes were antigenically distinct in that anti-type II dihydrofolate reductase (R67) antibody did not cross-react with the type I (R483) protein. The trimethoprim-resistant reductase specified by plasmid R388 had a subunit molecular weight of about 10,500 and was immunologically related to the type II (R67) enzyme. A 9,000 subunit of the dihydrofolate encoded by the transposition element Tn402 was also antigenically related to the R67 reductase.     

Mapping and cloning of Eco RI-fragments of bacteriophage T5+ DNA.

The Eco RI-fragments of bacteriophage T5 DNA were mapped using a technique which involves primarily length measurements of molecules observed in the electron microscope. Since Eco RI cleavage generates termini with 4-nucleotide long cohesive ends, fragments of complete and partial Eco RI digests were covalently circularized with DNA ligase at dilute DNA concentrations before measuring relative to internal length standards. This established the order of the internal Eco RI fragments. The two external Eco RI fragments, which had only one Eco RI terminus, were positioned relative to the internal fragments by identifying the location of some of the naturally-occurring nicks in partially denatured linear Eco RI fragments. An attempt was made to clone each of the internal Eco RI-fragments of T5 DNA via transformation into E. coli after ligation in vitro with the plasmid pMB 9. Only one fragment could be cloned and this fragment did not specify any new polypeptides in minicells of either the E. coli EK1 host, X1411, or the EK 2 host, X1776.     

Protein expression in E. coli minicells by recombinant plasmids.

The polypeptides synthesized in E. coli minicells from recombinant plasmids containing DNA fragments from cauliflower mosaic virus, Drosophila melanogaster, and mouse mitochondria were examined. Molecularly cloned fragments of cauliflower mosaic virus DNA directed the synthesis of high levels of three polypeptides, which were synthesized entirely from within the cloned virus DNA fragments independent of their insertion into the plasmid vehicles. Several fragments of D. melanogaster DNA were capable of initiating polypeptide synthesis; however, termination of these polypeptides was dependent upon the insertion into the plasmid vehicle. The majority of D. melanogaster DNA fragments examined did not direct the detectable synthesis of any polypeptides. Insertion of DNA into the Eco RI site of ColE1 and pSC101 plasmids resulted in the altered expression of plasmid-encoded polypeptides. In the case of ColE1, this site of insertion lies within the colicin E1 structural gene, and insertion of foreign DNA into the site results in the synthesis of an inactive truncated colicin E1 molecule. It is probable that the Eco RI site in pSC101 lies within the structural gene for a polypeptide involved in tetracycline resistance, and insertion of DNA into this site may also result in the synthesis of a truncated or elongated polypeptide.     

A deoxyribonuclease of Diplococcus pneumoniae specific for methylated DNA.

A deoxyribonuclease specific for methylated DNA was isolated from Diplococcus pneumoniae. The enzyme, an endonuclease, degrades DNA for Escherichia coli to fragments of average molecular weight about half a million; it forms discrete fragments from phage lambda DNA. Methyl-deficient E. coli DNA is not attacked, neither is DNA from Micrococcus radiodurans, which contains no methylated adenine or cytosine. Nor is DNA from D. pneumoniae or phage T7 attacked. However, DNA from M. radiodurans, D. pneumoniae, and T7 is attacked after methylation with and E. coli extract. Methylated T7 DNA is degraded to discrete fragments. Although the genetic transforming activity of normal DNA from D. pneumoniae is not affected by the enzyme, transforming activity of methylated DNA is destroyed. The enzyme is designated endonuclease R Dpn I. Under certain conditions another enzyme of complementary specificity can be isolated. This enzyme, designated endonuclease R Dpn II, produces a similar pattern of fragments from the DNA of T7 without prior methylation of the DNA. It also degrades normal DNA for D. pneumoniae. It is suggested that this pair of enzymes plays a role in some unknown control process, which would involve a large fraction of the specific base sequences that are methylated in E. coli DNA and are present but not methylated in DNA from other sources.     

Cloning and expression of bacterial ice nucleation genes in Escherichia coli.

Epiphytic populations of Pseudomonas syringae and Erwinia herbicola are important sources of ice nuclei that incite frost damage in agricultural crop plants. We have cloned and characterized DNA segments carrying the genes (ice) responsible for the ice-nucleating ability of these bacteria. The ice region spanned 3.5 to 4.0 kilobases and was continuous over this region in P. syringae Cit7R1. The cloned fragments imparted ice-nucleating activity in Escherichia coli. Substantial increases in the nucleating activity of both E. coli and P. syringae were obtained by subcloning the DNA fragments on multicopy plasmid vectors. Southern blot analysis showed substantial homology between the ice regions of P. syringae and E. herbicola, although individual restriction sites within the ice regions differed between the two species.     

Cloning and characterization of the genes encoding the malolactic enzyme and the malate permease of Leuconostoc oenos.

Using degenerated primers from conserved regions of the protein sequences of malic enzymes, we amplified a 324-bp DNA fragment by PCR from Leuconostoc oenos and used this fragment as a probe for screening a Leuconostoc oenos genomic bank. Of the 2,990 clones in the genomic bank examined, 7 with overlapping fragments were isolated by performing colony hybridization experiments. Sequencing 3,453 bp from overlapping fragments revealed two open reading frames that were 1,623 and 942 nucleotides long and were followed by a putative terminator structure. The first deduced protein (molecular weight, 59,118) is very similar (level of similarity, 66%) to the malolactic enzyme of Lactococcus lactis; as in several malic enzymes, highly conserved protein regions are present. The synthesis of a protein with an apparent molecular mass of 60 kDa was highlighted by the results of labelling experiments performed with Escherichia coli minicells. The gene was expressed in E. coli and Saccharomyces cerevisiae and conferred "malolactic activity" to these species. The second open reading frame encodes a putative 34,190-Da protein which has the characteristics of a carrier protein and may have 10 membrane-spanning segments organized around a central hydrophilic core. Energy-dependent L-[14C]malate transport was observed with E. coli dicarboxylic acid transport-deficient mutants carrying the malate permease-expressing vector. Our results suggest that in Leuconostoc oenos the genes that encode the malolactic enzyme and a malate carrier protein are organized in a cluster.