Synthetic ColE1 plasmids carrying genes for cell division in Escherichia coli.

Clarke and Carbon's collection of 2000 E. coli strains, which harbor ColE1 plasmids carrying small random segments of the E. coli chromosome, was screened for the correction of thermosensitive defects in the processes of cell division and in the synthesis of murein-lipoprotein. The genetic defects examined in this screening were those in partition of daughter nuclei (par), cleavage of cells (fts), determination of a cell shape (rod), and synthesis of murein-lipoprotein (lpo). We found plasmids carrying E. coli chromosomal segments containing ftsB⁺, ftsE⁺,ftsI⁺,ftsM⁺, and parA⁺. However, none was found to transfer ftsA⁺, ftsC⁺, ftsF⁺, ftsG⁺, ftsJ⁺, ftsK⁺, ftsL⁺, parB⁺, rod⁺, and lpo⁺. One of the donor strains transferring a gene that corrected thermosensitive cell cleavage in the ftsI^? mutant overproduced the penicillin-binding protein 3 by ca. 10-fold.     

Molecular breeding of the basidiomycete Coprinus cinereus strains with high lignin-decolorization and -degradation activities using novel heterologous protein expression vectors

Two chromosome-integrating vectors, pLC1 and pLC2, were used. The former is the pUC19-based vector carrying the Lentinus edodes ras gene promoter and priA gene terminator, and the latter is the pBR322-based vector carrying the promoter and terminator of the priA gene. The manganese (II) peroxidase (MnP) cDNA (mnpc) derived from Pleurotus ostreatus was fused between the promoter and terminator of pLC1 and pLC2, yielding the recombinant plasmids pLC1-mnp and pLC2-mnp. These plasmids were introduced into protoplasts of the Coprinus cinereus trp1 strain with the C. cinereus TRP1-containing plasmid pCc1001 by co-transformation. Two Trp⁺ transformants for each plasmid, showing clearly higher lignin-decolorization activities, were obtained through introduction of pLC1-mnp and pLC2-mnp. Southern-blot analysis revealed that the four transformants all possess the mnpc sequence on their chromosomes. One Trp⁺ MnP⁺ transformant (named TF2-7), which was derived from the introduction of pLC2-mnp and carried the highest number of copies (approx. 10) of mnpc, showed remarkably high lignin-decolorization and -degradation activities; at the time of cultivation when only 35%–40% of the lignin was decolored and degraded by the control Trp⁺ transformant obtained by the introduction of pCc1001 alone, almost all of the lignin was decolored and degraded by TF2-7. Received: 20 October 1997 / Accepted: 31 October 1997     

Selection and timing of replication of plasmids R1drd-19 and F'lac in Escherichia coli.

The selection and timing of plasmid replication was studied in exponentially growing cultures of Escherichia coli K-12 carrying the plasmid R1drd-19 and E. coli strains B/r A and B/r F carrying the plasmid F′lac. In all cases plasmid replication was studied by analysis of covalently closed circular (CCC) DNA. The turnover time of replicating plasmid DNA into CCC-DNA was found to be less than 4 min. Density shift experiments (from ¹⁵NH₄⁺, D₂O to ¹⁴NH₄⁺, H₂O) showed that plasmids R1drd-19 and F′lac are selected randomly for replication. This means that one of the plasmid copies in a cell is selected and replicated. There is no further plasmid replication in the cell until all plasmid copies, including the newly formed ones, have the same probability of being selected for replication. The early kinetics of the appearance of light plasmid DNA after the density shift showed that the time interval between successive replications of plasmids R1drd-19 and F′lac is $\text{τ}\text{n}$, where τ is the generation time and n is the average number of plasmid replications per cell and cell cycle. In a second type of experiment, exponentially growing cells were separated into a series of size classes by low-speed centrifugation in sucrose step gradients. Replication of plasmids R1drd-19 and F′lac was equally frequent in all size classes. This result is in accordance with the results of the density shift experiment. It can therefore be concluded that replication of plasmids R1drd-19 and F′lac is evenly spread over the whole cell cycle, which means that one plasmid replication occurs every time the cell volume has increased by one initiation mass.     

On the process of cellular division in Escherichia coli: nucleotide sequence of the gene for penicillin-binding protein 3

We determined the nucleotide sequence of a DNA fragment containing the ftsI gene coding for the penicillin-binding protein 3 (PBP-3), an indispensable enzyme for cell division of Escherichia coli. The entire ftsI gene was within the 2.8 kilobase PvuII fragment derived from the chromosomal segment on pLC26-6 (Nishimura et al. 1977). The coding region for PBP-3 was identified by comparison with the N-terminal amino acid sequence of in vitro synthesized PBP-3. The structural gene for ftsI consisted of 1,764 base-pairs coding for a 588 amino acid residue-polypeptide with a molecular weight of 63,850. PBP-3 synthesized in vitro showed a lower mobility in SDS-gel electrophoresis than that of the authentic PBP-3, suggesting that the primary translation product of the ftsI gene may be processed to yield mature PBP-3.     

Chromosome morphology of the czechoslovak species of the genusScorzonera

Karyotypic formulae of theScorzonera L. species are as follows:S. purpurea L.: K (2n)=14=8 A^m+6 B^sm and K (2n)=14+1=9 A^m+6 B^sm;S. austriaca Willd.: K (2n)=14=6 A^m+6 B^sm+2 C^st;S. humilis L.: K (2n)=14=12 A^m+2 B^sm;S. parviflora Jacq.: K (2n)=14=10 A^m+4 B^sm;S. hispanica L.: K (2n)=12 A^m+2 B^sm. The results of the study of the karyotypes of the generaScorzonera L.,Tragopogon L. andPodospermum DC. are summarized.     

Studies of the morphology of chromosomes of some selected species

Karyotypes of twelve species from twenty-four localities in southern Moravia and one locality in Slovakia were investigated. Their counts or karyotypic formulae are as follows:Chenopodium foliosum (Moench) Ascherson: K (2n)=18=16 A^m+2 B^sm;Astragalus austriacus Jacq.: K (2n)=16=8 A^m+8 B^sm;Astragalus exscapus L.: K (2n)=16=10 A^m+4 B^sm+2 C^st;Astragalus cicer L.: K (2n)=64;Astragalus onobrychis L.: K (2n=64 and K (2n)=64+1;Vicia dumetorum L.: K (2n=14=10 A^m+4 B^sm;Vicia sylvatica L.: K (2n)=14=2 A^m+10 B^sm+2 C^st;Vicia pisiformis L.: K (2n)=12=8 A^m+4 B^sm;Vicia cassubica L.: K (2n)=12=4 A^m+6 B^sm+2 C^st;Vicia cracca L. (from five localities in southern Moravia): K (2n)=28=4 A^m+12 B^sm+12 C^st and K (2n)=28+1=5 A^m+12 B^sm+12 C^st;Vicia cracca L. (from one locality in Slovakia): K (2n)=14=2 A^m+6 B^sm+6 C^st;Vicia tenuifolia Roth: K (2n)=24=4 A^m+16 B^sm+4 C^st;Serratula lycopifolia (Vill.) Kern.: K (2n)=60.     

Physical map of the nrdA-nrdB-ftsB-glpT region of the chromosomal DNA of Escherichia coli

Seven pLC plasmids (pLC 3-46, 8-12, 8-24, 8-29, 14-12, 19-24 and 42-17) which complemented nrdA, nrdB, ftsB and/or glpT mutations of Escherichia coli were analyzed. A restriction map of each plasmid was constructed and restriction fragments were subcloned into pBR322. A physical map of approx. a 15 X 10(6) Mr segment of the chromosomal DNA was deduced from the overlapping region of the pLC plasmids. The pLC plasmids and newly constructed plasmids were examined for the ability to rescue the mutations. The complementation tests defined the location of the genes in the 15 X 10(6) Mr segment in the following order: nrdA-nrdB-ftsB-glpT. Functional nrdAB and ftsB genes were located in the 3.1 X 10(6) Mr EcoRI-PstI fragment.     

ColE1 hybrid plasmids containing Escherichia coli genes involved in the biosynthesis of glutamate and glutamine

The Clarke-Carbon bank of Escherichia coli strains carrying ColE1 hybrid plasmids was screened for complementation of gdh, gltB, and glnA mutations affecting nitrogen metabolism in E. coli. Plasmids which complemented each one of these mutations were isolated. In every case, the plasmids conferred to otherwise mutant cells the capacity to synthesize the corresponding wild-type enzymes: glutamate dehydrogenase, glutamate synthase, and glutamine synthetase (GS), respectively. For three representative plasmids, endonuclease restriction maps were constructed. One of the plasmids, pACR1, which complemented glnA mutations, including the glnA21::Tn5 insertion, was deemed to carry the glnA⁺ allele. GS synthesis by pACR1 $\text{glnA}{}^{\mathrm{+}}\text{glnA20}$ heterozygous merodiploids was subjected to repression by growth on 15 mm NH₄⁺ and had a twofold high derepressed level than wild-type (glnA⁺) haploid cells when grown on 0.5 mm NH₄⁺ or on glutamate as only nitrogen sources. The presence of glutamine as sole nitrogen source promoted repressed GS synthesis in the $\text{glnA}{}^{\mathrm{+}}\text{glnA20}$ merodiploids. By contrast, glutamine allowed almost fully derepressed synthesis of GS in glnA⁺ haploid cells.     

Incompatibility between Flac, R386, and F:pSC101 recombinant plasmids: the specificity of F incompatibility genes.

The specificity of F incompatibility genes (inc⁺) has been studied with the Flac and R386 plasmids, members of the IncFI incompatibility group. Recently, two inc⁺ regions, incA (46.4–49.3F) and incB (43.1–46.4F) were identified by cloning these F sequences onto pSC101 and subsequently demonstrating incompatibility of the recombinants with Flac. It is shown here that the FincA⁺ recombinant is incompatible with both Flac and R386 while the FincB⁺ recombinant is incompatible only with Flac. Also, a plasmid mutant is described that has reduced incompatibility against Flac and R386. The mutation is located on the BamHI restriction fragment that contains the FincA region. These genetic findings are consistent with the deduction of Palchaudhuri and Maas, based on heteroduplex analysis of IncFI plasmids, that placed the IncFI determinant in the 46.4–48.6F region. The findings also indicate that the FincB⁺ gene product, which has been implicated in negative control of F copy number, is specific for the F replicon.     

Isolation of recombinant plasmids and phage carrying the lexA gene of Escherichia coli K-12

The lexA gene of Escherichia coli K-12 was cloned from the plasmid pLC44-14 into pBR322. Plasmids carrying lexA+ were selected by their ability to complement a recessive tsl mutation, which is believed to be a mutation in lexA. The smallest lexA+ recombinant plasmid, pJL21, contained an EcoRI-PstI fragment 2.9 kilobases (kb) in length; two larger plasmids also contained this fragment, and genetic material to one or both sides of the EcoRI-PstI fragment. Plasmids homologous to pJL21, but carrying a dominant mutation, lexA3, or one of three recessive amber mutations in lexA, termed spr, were also isolated. To clone the EcoRI-PstI fragment onto a lambda vector, the PstI end was first converted to an EcoRI end by attachment of a 100-base pair PstI-EcoRI fragment isolated from the plasmid ColE1; the resultant EcoRI fragment was then cloned into the lambda vector lambda gt4. A restriction map of pLC44-14 was obtained for nine restriction enzymes. The orientation of this map was determined relative to the E. coli genetic map by complementation of the gene ubiA+ and by comparison with restriction enzyme digests of another plasmid, pLC11-9, which carries dnaB, a gene closely linked to lexA, but does not carry lexA.     

Detection of hepatitis C virus (HCV) negative strand RNA and NS3 protein in peripheral blood mononuclear cells (PBMC): CD3<Superscript>+</Superscript>, CD14<Superscript>+</Superscript> and CD19<Superscript>+</Superscript>

Background

Although hepatitis C virus (HCV) is primarily hepatotropic, markers of HCV replication were detected in peripheral blood mononuclear cells (PBMC) as well as in ex vivo collected tissues and organs. Specific strains of HCV were found to be capable to infect cells of the immune system: T and B cells and monocytes/macrophages as well as cell lines in vitro. The direct invasion of cells of the immune system by the virus may be responsible for extrahepatic consequences of HCV infection: cryoglobulinemia and non-Hodgkin’s lymphoma.The aim of the present study was to determine the prevalence of markers of HCV infection: negative strand HCV RNA and non-structural NS3 protein in PBMC subpopulations: CD3⁺, CD14⁺ and CD19⁺. The presence of virus and the proportion of affected cells within a particular PBMC fraction could indicate a principal target cell susceptible for HCV.

Methods

PBMC samples were collected from 26 treatment-free patients chronically infected with HCV. PBMC subpopulations: CD3⁺, CD14⁺, CD19⁺ were obtained using positive magnetic separation. The presence of negative strand RNA HCV and viral NS3 protein were analyzed by strand-specific RT-PCR and NS3 immunocytochemistry staining.

Results

Negative strand HCV RNA was detectable in 7/26 (27%), whereas NS3 protein in 15/26 (57.6%) of PBMC samples. At least one replication marker was found in 13/26 (50%) of CD3⁺ cells then in 8/26 (30.8%) of CD14⁺ and CD19⁺ cells. The highest percentage of cells harboring viral markers in single specimen was also observed in CD3⁺ (2.4%), then in CD19⁺ (1.2%), and much lower in CD14⁺ (0.4%) cells.

Conclusions

Our results indicate that CD3⁺ cells are a dominant site for extrahepatic HCV replication, although other PBMC subpopulations may also support virus replication.

     

Contrasting effects of Elg1-RFC and Ctf18-RFC inactivation in the absence of fully functional RFC in fission yeast

Proliferating cell nuclear antigen loading onto DNA by replication factor C (RFC) is a key step in eukaryotic DNA replication and repair processes. In this study, the C-terminal domain (CTD) of the large subunit of fission yeast RFC is shown to be essential for its function in vivo. Cells carrying a temperature-sensitive mutation in the CTD, rfc1-44, arrest with incompletely replicated chromosomes, are sensitive to DNA damaging agents, are synthetically lethal with other DNA replication mutants, and can be suppressed by mutations in rfc5. To assess the contribution of the RFC-like complexes Elg1–RFC and Ctf18–RFC to the viability of rfc1-44, genes encoding the large subunits of these complexes have been deleted and overexpressed. Inactivation of Ctf18–RFC by the deletion of ctf18⁺, dcc1⁺ or ctf8⁺ is lethal in an rfc1-44 background showing that full Ctf18–RFC function is required in the absence of fully functional RFC. In contrast, rfc1-44 elg1Δ cells are viable and overproduction of Elg1 in rfc1-44 is lethal, suggesting that Elg1–RFC plays a negative role when RFC function is inhibited. Consistent with this, the deletion of elg1⁺ is shown to restore viability to rfc1-44 ctf18Δ cells.     

Influence of plasmids carrying the lexA gene on DNA repair and related processes in Escherichia coli K-12

Summary Plasmid pLC44-14 from the Clarke and Carbon collection has been shown to carry the lexA gene. The presence of lexA was demonstrated by complementation of tsl mutants which lie close to lexA on the E. coli K-12 linkage map and are probably in the lexA gene, and by crossing the dominant lexA mutation on to pLC44-14 to produce a recombinant plasmid, pSEl, which gave the host cell the properties of a lexA mutant. The lexA gene has been cloned on to pBR322 (Little, 1980). pJL21, which carries the lexA ⁺ gene, rendered the host cell moderately sensitive to UV light, greatly reduced the extent of Weigle reactivation and mutagenesis of UV-irradiated phage , and inhibited induction of protein X by either UV light or nalidixic acid. A similar plasmid carrying a mutant lexA3 allele produced extreme sensitivity to UV light, reduced recombinant production 10 to 50-fold following Hfr x F^– conjugation crosses, and otherwise mimicked the effects of pJL21. Introduction of an amber mutation into the lexA gene carried by the plasmid greatly reduced the UV-sensitivity of the host, thereby indicating that the extreme sensitivity was due to the mutant lexA gene product. These properties of strains with lexA plasmids are thought to originate from high levels of the lexA protein in the cell due to a large plasmid copy number. This protein, which appears from other studies to regulate negatively the recA gene, may inhibit expression of recA or other DNA repair genes when present in excess amounts in the cell.     

Immune Response of Calves Vaccinated with Brucella abortus S19 or RB51 and Revaccinated with RB51

Brucella abortus S19 and RB51 strains have been successfully used to control bovine brucellosis worldwide; however, currently, most of our understanding of the protective immune response induced by vaccination comes from studies in mice. The aim of this study was to characterize and compare the immune responses induced in cattle prime-immunized with B. abortus S19 or RB51 and revaccinated with RB51. Female calves, aged 4 to 8 months, were vaccinated with either vaccine S19 (0.6–1.2 x 10¹¹ CFU) or RB51 (1.3 x 10¹⁰ CFU) on day 0, and revaccinated with RB51 (1.3 x 10¹⁰ CFU) on day 365 of the experiment. Characterization of the immune response was performed using serum and peripheral blood mononuclear cells. Blood samples were collected on days 0, 28, 210, 365, 393 and 575 post-immunization. Results showed that S19 and RB51 vaccination induced an immune response characterized by proliferation of CD4⁺ and CD8⁺ T-cells; IFN-ɣ and IL-17A production by CD4⁺ T-cells; cytotoxic CD8⁺ T-cells; IL-6 secretion; CD4⁺ and CD8⁺ memory cells; antibodies of IgG1 class; and expression of the phenotypes of activation in T-cells. However, the immune response stimulated by S19 compared to RB51 showed higher persistency of IFN-ɣ and CD4⁺ memory cells, induction of CD21⁺ memory cells and higher secretion of IL-6. After RB51 revaccination, the immune response was chiefly characterized by increase in IFN-ɣ expression, proliferation of antigen-specific CD4⁺ and CD8⁺ T-cells, cytotoxic CD8⁺ T-cells and decrease of IL-6 production in both groups. Nevertheless, a different polarization of the immune response, CD4⁺- or CD8⁺-dominant, was observed after the booster with RB51 for S19 and RB51 prime-vaccinated animals, respectively. Our results indicate that after prime vaccination both vaccine strains induce a strong and complex Th1 immune response, although after RB51 revaccination the differences between immune profiles induced by prime-vaccination become accentuated.     

New mutations in cloned Escherichia coli umuDC genes: Novel phenotypes of strains carrying a umuC125 plasmid

The umuDC locus of Escherichia coli is required for most mutagenesis by UV and many chemicals. Mutations in E. coli umuDC genes cloned on pBR322-derived plasmids wer e isolated by two methods. First, spontaneously-arising mutant umuDC plasmids that failed to confe cold-sensitive growth on a lexA51(Def) strain were isolated by selection. Second, mutant umuDC plasmids that affected apparent mutant yield after UV-irradiation in a strain carrying umuD⁺C⁺ in the chromosome were isolated by screening hydroxylamine-mutagenized umuD⁺C⁺ plasmids. pBR322-derived umuD⁺C⁺ plasmids inhibited the induction of the SOS response of lexA⁺ strains as measured by expression of din::Mu dl(lac) Ap) fusionsbut most mutant plasmids did not. Mutant plasmids defective in complementation of chromosomal umuD44, umuC36, or both were found among those selected for failure to confer cold-sensitivity, whereas those identified by the screening procedure yielded mostly mutant plasmids with more complex phenotypes. We studied in greater detail a plasmid pLM109, carrying the umuC125 mutation. This plasmid increased the sensitivity of lexA⁺ strainsto killing by UV-irradiation but was able to complement the deficiencies of umuC mutants in UV mutagenesis. pLM109 failed to confer cold-sensitive growth on lexA(Def) strains but inhibited SOS induction in lexA⁺ strains. The effect of pLM109 on the UV sensitivity of lexA(Def)strains was similar to that of the parental umuD⁺C⁺ plasmid. The mutation responsible for the phenotypes of pLM109 was localized to a 615-bp fragment. DNA sequencing revealed that the umuC125mutation was a G:C → A:T transition that changed codon 39 of umuC from GCC → GTC thus changing Ala39 to Val39. The implications of the umuC125 mutation for umuDC-dependent effects on UV-mutagenesis and cell survival after UV damage are discussed.     

Tumor-Targeted Human T Cells Expressing CD28-Based Chimeric Antigen Receptors Circumvent CTLA-4 Inhibition

Adoptive T cell therapy represents a promising treatment for cancer. Human T cells engineered to express a chimeric antigen receptor (CAR) recognize and kill tumor cells in a MHC-unrestricted manner and persist in vivo when the CAR includes a CD28 costimulatory domain. However, the intensity of the CAR-mediated CD28 activation signal and its regulation by the CTLA-4 checkpoint are unknown. We investigated whether T cells expressing an anti-CD19, CD3 zeta and CD28-based CAR (19-28z) displayed the same proliferation and anti-tumor abilities than T cells expressing a CD3 zeta-based CAR (19z1) costimulated through the CD80/CD28, ligand/receptor pathway. Repeated in vitro antigen-specific stimulations indicated that 19-28z⁺ T cells secreted higher levels of Th1 cytokines and showed enhanced proliferation compared to those of 19z1⁺ or 19z1-CD80⁺ T cells. In an aggressive pre-B cell leukemia model, mice treated with 19-28z⁺ T cells had 10-fold reduced tumor progression compared to those treated with 19z1⁺ or 19z1-CD80⁺ T cells. shRNA-mediated CTLA-4 down-regulation in 19z1-CD80⁺ T cells significantly increased their in vivo expansion and anti-tumor properties, but had no effect in 19-28z⁺ T cells. Our results establish that CTLA-4 down-regulation may benefit human adoptive T cell therapy and demonstrate that CAR design can elude negative checkpoints to better sustain T cell function.     

Squamous Tissue Lymphocytes in the Esophagus of Controls and Patients with Reflux Esophagitis and Barrett’s Esophagus Are Characterized by a Non-Inflammatory Phenotype

Background and Objective

Reflux esophagitis (RE) is characterized by inflammation of the squamous epithelium (SQ) of the esophagus and may progress to Barrett’s esophagus (BE) characterized by intestinal metaplasia. The role of inflammation in this transition has been postulated but lacks experimental evidence. Here, the inflammatory responses in the esophagus of these patients were investigated.

Patients and Methods

Fifty-one esophageal biopsies from with patients BE (n = 19), RE (n = 8) and controls (n = 23) were analyzed. T-cells were analyzed before and after ex vivo expansion (14 days) by multicolor flow cytometric analysis. The following markers were studied: CD3, CD4, CD8 (T-cell markers), Granzyme B (marker of cytotoxicity), CD103 (αE/epithelial integrin) and NKg2a (inhibitory receptor on T-cells and NK-cells).

Results

Analysis of ex vivo cultures from normal looking SQ from controls, RE patients, and BE patients revealed no significant differences in the number and phenotypes of T-cells. In contrast, tissue from RE was different to normal SQ in four aspects: 1) higher percentages of CD3⁺CD4⁺-cells (72±7% vs 48±6%, p = 0.01) and 2) CD8⁺GranzymeB⁺ -cells (53±11% vs 26±4%, p<0.05), while 3) lower percentages of CD4⁺CD103⁺-cells (45±19% vs 80±3%, p = 0.02) and 4) CD8⁺NKg2a⁺- cells (31±12% vs 44±5%).

Conclusion

Despite the fact that both tissues are exposed to the same reflux associated inflammatory triggers, the immune response observed in RE is clearly distinct from that in SQ of BE. The differences in immune responses in BE tissue might contribute to its susceptibility for transformation into intestinal metaplasia.