Molecular cloning of the Harvey sarcoma virus closed circular DNA intermediates: initial structural and biological characterization.

Supercoiled Harvey sarcoma virus (Ha-SV) DNA was extracted from newly infected cells by the Hirt procedure, enriched by preparative agarose gel electrophoresis, and digested with EcoRI, which cleaved the viral DNA at a unique site. The linearized Ha-SV DNA was then inserted into lambda gtWESlambda B at the EcoRI site and cloned in an approved EK2 host. Ha-SV DNA inserts from six independently derived recombinant clones have been analyzed by restriction endonuclease digestion, molecular hybridization, electron microscopy, and infectivity. Four of the Ha-SV DNA inserts were identical, contained about 6.0 kilobase pairs (kbp), and comigrated in agarose gels with the infectious, unintegrated, linear Ha-SV DNA. One insert was approximately 0.65 kbp smaller (5.35 kbp) and one was approximately 0.65 kpb larger (6.65 kpb) than the 6.0 kpb inserts. R-looping with Ha-SV RNA revealed that the small (5.35 kbp) insert contained one copy of the Ha-SV RNA. Preliminary restriction endonuclease digestion of the recombinant DNAs suggested that the middle-size inserts contained a 0.65-kbp tandem duplication of sequences present only one in the small-size insert; this duplication corresponded to the 0.65-kpb terminal duplication of the unintegrated linear Ha-SV DNA. The large-size insert apparently contained a tandem triplication of these terminally located sequences. DNA of all three sized inserts induced foci in NIH 3T3 cells, and focus-forming activity could be rescued from the transformed cells by superinfection with helper virus. Infectivity followed single-hit kinetics, suggesting that the foci were induced by a single molecule.     

Generation of a 50,000-member human DNA library with an average DNA insert size of 75-100 kbp in a bacteriophage P1 cloning vector

A bacteriophage P1 cloning system that permits the isolation and amplification of cloned DNA fragments as large as 100 kbp was described previously. We have now utilized a similar system to generate a 50,000-member human DNA library with DNA inserts ranging in size from 75 to 100 kbp. Two major obstacles were overcome in constructing the library. The first concerned the mcrAB restriction system of Escherichia coli, which degrades DNA containing MeC and interferes with the recovery of cloned human DNA inserts. In the P1 cloning system, the effect of the Mcr restriction activity is to decrease recovery of cloned inserts by about 35-fold when the activity is in the host cell line and by about 3-fold when the activity is in the cells used to prepare the packaging extract. To circumvent this problem we inactivated, by mutation, the McrAB proteins in both components of the cloning system. The second obstacle concerned the preferential cloning of small DNA fragments from a population of fragments ranging in size from 20 to 100 kbp. To deal with this problem we first modified the P1 lysogen used to prepare the in vitro head-tail packaging extract so that it would produce 12 times as many large P1 heads (head capacity about 110 kbp) as small P1 heads (head capacity about 45 kbp). We then restructured the P1 cloning vector so that it could be used to produce vector "arm" fragments that could be ligated to insert DNA at only one end. This prevented the formation of long concatamers consisting of alternating units of vector and insert DNA and prohibited the packaging of small inserts in large phage heads. Using the insert-biased large head extract, the arms vector, and size-selected human DNA fragments, we showed that as much as 90% of recovered transformants contained inserts in the desired high molecular weight range.     

Characterization of the feline c-abl proto-oncogene

Analysis of total feline DNA by genomic blot hybridization, using the viral oncogene of Abelson murine leukemia virus as a specific probe, has led to the identification of multiple v-abl homologous genetic sequences in the cat genome. Upon restriction endonuclease BamHI digestion, the combined size of the v-abl homologous DNA fragments was about 31 kbp. To characterize these sequences further, four independent v-abl homologous cosmid clones with overlapping cellular inserts have been isolated from a gene library of cat lung genomic DNA. These inserts represent a contiguous region of cellular DNA sequences of 56 kbp in length. Within this region of the feline genome, the v-abl homologous sequences are discontinuously dispersed over a region of about 34 kbp. They represent the complete feline v-abl cellular homolog and are colinear with the viral v-abl oncogene. Nine regions of highly repetitive DNA sequences have been mapped in close proximity to v-abl homologous sequences. These results establish the presence of only a single c-abl proto-oncogene in the cat genome and present its genetic organization.     

Cloning of peptidase genes from Lactobacillus helveticus CNRZ 32

Lactic acid bacteria express a complex proteolytic enzyme system that is capable of hydrolyzing casein to amino acids. We have begun to examine the number and specificity of exopeptidases from Lactobacillus helveticus CNRZ 32. A genomic library of L. helveticus CNRZ 32 DNA fragments from a Sau3A partial digestion was constructed in Escherichia coli DH5 utilizing pJDC9. This library was screened for the presence of aminopeptidase, X-prolyl dipeptidyl aminopeptidase (X-PDAP), and dipeptidase activities by two methods. The first screening identified an aminopeptidase II (APII) and X-PDAP. The X-PDAP was determined to be present on four independent DNA inserts ranging in size from 3.5 to 7.7 kilobase pairs (kbp). EcoRI/EcoRV digests of these plasmids suggested that all inserts had 1.0 and 1.8 kbp fragments in common. The gene for APII was determined to be present on three independent DNA inserts ranging in size from 8.2 to 11.3 kbp. EcoRI digestion of these plasmids indicated that 1.2 and 1.8 kbp fragments were in common. The second screening identified an additional aminopeptidase (API), a di/tripeptidase (DTP) with prolinase activity, a broad-specificity dipeptidase (DPI), and a narrow-specificity dipeptidase (DPII). The insert size of clones expressing API, DTP, DPI, DPII were 4.8, 9.5, 5.8, and 6.3 kbp, respectively. Histochemical staining of native polyacrylamide gels from recombinant E. coli cultures demonstrated that the cloned peptidase co-migrated with native L. helveticus CNRZ 32 enzymes. Correspondence to: J. L. Steele     

Construction, analysis, and beta-glucanase screening of a bacterial artificial chromosome library from the large-bowel microbiota of mice

A metagenomic (community genomic) library consisting of 5,760 bacterial artificial chromosome clones was prepared in Escherichia coli DH10B from DNA extracted from the large-bowel microbiota of BALB/c mice. DNA inserts detected in 61 randomly chosen clones averaged 55 kbp (range, 8 to 150 kbp) in size. A functional screen of the library for beta-glucanase activity was conducted using lichenin agar plates and Congo red solution. Three clones with beta-glucanase activity were detected. The inserts of these three clones were sequenced and annotated. Open reading frames (ORF) that encoded putative proteins with identity to glucanolytic enzymes (lichenases and laminarinases) were detected by reference to databases. Other putative genes were detected, some of which might have a role in environmental sensing, nutrient acquisition, or coaggregation. The insert DNA from two clones probably originated from uncultivated bacteria because the ORF had low sequence identity with database entries, but the genes associated with the remaining clone resembled sequences reported in Bacteroides species.     

Construction, Analysis, and β-Glucanase Screening of a Bacterial Artificial Chromosome Library from the Large-Bowel Microbiota of Mice

A metagenomic (community genomic) library consisting of 5,760 bacterial artificial chromosome clones was prepared in Escherichia coli DH10B from DNA extracted from the large-bowel microbiota of BALB/c mice. DNA inserts detected in 61 randomly chosen clones averaged 55 kbp (range, 8 to 150 kbp) in size. A functional screen of the library for β-glucanase activity was conducted using lichenin agar plates and Congo red solution. Three clones with β-glucanase activity were detected. The inserts of these three clones were sequenced and annotated. Open reading frames (ORF) that encoded putative proteins with identity to glucanolytic enzymes (lichenases and laminarinases) were detected by reference to databases. Other putative genes were detected, some of which might have a role in environmental sensing, nutrient acquisition, or coaggregation. The insert DNA from two clones probably originated from uncultivated bacteria because the ORF had low sequence identity with database entries, but the genes associated with the remaining clone resembled sequences reported in Bacteroides species.     

Expression of Mycoplasma pulmonis antigens in Escherichia coli

The expression of Mycoplasma pulmonis antigen in Escherichia coli was investigated by cloning genomic DNA derived from M. pulmonis m 53, and the DNA fragment participating in antigen expression was identified. When the DNA library of M. pulmonis was screened by colony immunoassay using anti-M. pulmonis serum, 10 recombinant clones expressing seroreactive antigens were obtained. The recombinant plasmids isolated from these clones included 3.7-6.5 kilobase pair (kbp) DNA inserts, while all clones contained a common 2.3-kbp DNA fragment. Subcloning of initial DNA inserts showed that the common 2.3-kbp fragment is essential for antigen expression. Moreover, antiserum against the recombinant antigen generated from the 2.3-kbp DNA fragment recognized a native M. pulmonis antigen. The reactivity of this antiserum was absorbed specifically with M. pulmonis. These results suggest that the cloned 2.3-kbp DNA fragment codes an antigen specific to M. pulmonis.     

Cloning and expression of pca genes from Pseudomonas putida in Escherichia coli

Beta-Ketoadipate elicits expression of five structural pca genes encoding enzymes that catalyse consecutive reactions in the utilization of protocatechuate by Pseudomonas putida. Three derivatives of P. putida PRS2000 were obtained, each carrying a single copy of Tn5 DNA inserted into a separate region of the genome and preventing expression of different sets of pca genes. Selection of Tn5 in or near the pca genes in these derivatives was used to clone four structural pca genes and to enable their expression as inserts in pUC19 carried in Escherichia coli. Three of the genes were clustered as components of an apparent operon in the order pcaBDC. This observation indicates that rearrangement of the closely linked genes accompanied divergence of their evolutionary homologues, which are known to appear in the order pcaDBC in the Acinetobacter calcoaceticus pcaEFDBCA gene cluster. Additional evidence for genetic reorganization during evolutionary divergence emerged from the demonstration that the P. putida pcaE gene lies more than 15 kilobase pairs (kbp) away from the pcaBDC operon. An additional P. putida gene, pcaR, was shown to be required for expression of the pca structural genes in response to beta-ketoadipate. The regulatory pcaR gene is located about 15 kbp upstream from the pcaBDC operon.     

Conversion of bacteriophage fd into an efficient single-stranded DNA vector system

Summary Single-stranded DNA vectors were constructed in vitro by insertion of various DNA fragments into the Intergenic Region of the single-stranded DNA phage fd. These inserts introduce into the phage genome unique cleavage sites for restriction nucleases which are suited for sticky joining in cloning experiments. Since these sites are usually located within genes coding for antibiotic resistance, inactivation of a resistance gene by insertion can be used as a marker for the successful cloning of a DNA fragment. Resistance genes also allow to select for recombinant DNA phages and to minimize the loss of DNA inserts which otherwise becomes significant above an insert size of about one kb. Cloning of several DNA fragments is described and strand separation of double-stranded DNA fragments by means of cloning into fd DNA is given as an example for application of single-stranded DNA vectors.Abbreviations Ap ampicillin - Cm chloramphenicol - Km kanamycin - Sm streptomycin - kb, kbp a unit length equivalent to 1000 bases, respectively 1000 base pairs - wt wild type     

Recombinant human immunodeficiency virus type 1 integrase exhibits a capacity for full-site integration in vitro that is comparable to that of purified preintegration complexes from virus-infected cells

Retrovirus preintegration complexes (PIC) in virus-infected cells contain the linear viral DNA genome (approximately 10 kbp), viral proteins including integrase (IN), and cellular proteins. After transport of the PIC into the nucleus, IN catalyzes the concerted insertion of the two viral DNA ends into the host chromosome. This successful insertion process is termed "full-site integration." Reconstitution of nucleoprotein complexes using recombinant human immunodeficiency virus type 1 (HIV-1) IN and model viral DNA donor substrates (approximately 0.30 to 0.48 kbp in length) that are capable of catalyzing efficient full-site integration has proven difficult. Many of the products are half-site integration reactions where either IN inserts only one end of the viral donor substrate into a circular DNA target or into other donors. In this report, we have purified recombinant HIV-1 IN at pH 6.8 in the presence of MgSO4 that performed full-site integration nearly as efficiently as HIV-1 PIC. The size of the viral DNA substrate was significantly increased to 4.1 kbp, thus allowing for the number of viral DNA ends and the concentrations of IN in the reaction mixtures to be decreased by a factor of approximately 10. In a typical reaction at 37 degrees C, recombinant HIV-1 IN at 5 to 10 nM incorporated 30 to 40% of the input DNA donor into full-site integration products. The synthesis of full-site products continued up to approximately 2 h, comparable to incubation times used with HIV-1 PIC. Approximately 5% of the input donor was incorporated into the circular target producing half-site products with no significant quantities of other integration products produced. DNA sequence analysis of the viral DNA-target junctions derived from wild-type U3 and U5 coupled reactions showed an approximately 70% fidelity for the HIV-1 5-bp host site duplications. Recombinant HIV-1 IN successfully utilized a mutant U5 end containing additional nucleotide extensions for full-site integration demonstrating that IN worked properly under nonideal active substrate conditions. The fidelity of the 5-bp host site duplications was also high with these coupled mutant U5 and wild-type U3 donor ends. These studies suggest that recombinant HIV-1 IN is at least as capable as native IN in virus particles and approaching that observed with HIV-1 PIC for catalyzing full-site integration.     

Cloning and restriction analysis of the hexokinase PII gene of the yeast Saccharomyces cerevisiae

Summary Carbon catabolite repression in yeast depends on catalytic active hexokinase isoenzyme PII (Entian 1980a). A yeast strain lacking hexokinase isoenzymes PI and PII was transformed, using a recombinant pool with inserts of yeast nuclear DNA up to 10 kbp in length. One hundred transformants for hexokinase were obtained. All selected plasmids coded for hexokinase isoenzyme PII, none for hexokinase isoenzyme PI, and carbon catabolite repression was restored in the transformants. Thirty-five independently isolated stable plasmids were investigated further. Analysis with the restriction enzyme EcoRI showed that these plasmids fell into two classes with different restriction behaviour. One representative of each class was amplified in Escherichia coli and transferred back into the yeast hexokinase-deficient strain with concomitant complementation of the nuclear mutation. The two types of insert were analysed in detail with 16 restriction enzymes, having 0–3 cleavage sites on transformant vector YRp7. The plasmids differed from each other by the orientation of the yeast insert in the vector. After yeast transformation with fragments of one plasmid the hexokinase PII gene was localised within a region of 1.65 kbp.     

Construction and characterization of a soybean bacterial artificial chromosome library and use of multiple complementary libraries for genome physical mapping

Two plant-transformation-competent large-insert binary clone bacterial artificial chromosome (hereafter BIBAC) libraries were previously constructed for soybean cv. Forrest, using BamHI or HindIII. However, they are not well suited for clone-based genomic sequencing due to their larger ratio of vector to insert size (27.6 kbp:125 kbp). Therefore, we developed a larger-insert bacterial artificial chromosome (BAC) library for the genotype in a smaller vector (pECBAC1), using EcoRI. The BAC library contains 38,400 clones; about 99.1% of the clones have inserts; the average insert size is 157 kbp; and the ratio of vector to insert size is much smaller (7.5 kbp:157 kbp). Colony hybridization with probes derived from several chloroplast and mitochondrial genes showed that 0.89% and 0.45% of the clones were derived from the chloroplast and mitochondrial genomes, respectively. Considering these data, the library represents 5.4 haploid genomes of soybean. The library was hybridized with six RFLP marker probes, 5S rDNA and 18S-5.8S-25S rDNA, respectively. Each RFLP marker hybridized to about six clones, and the 5S and 18S-5.8S-25S rDNA probes collectively hybridized to 402 BACs—about 1.05% of the clones in the library. The BAC library complements the existing soybean Forrest BIBAC libraries by using different restriction enzymes and vector systems. Together, the BAC and BIBAC libraries encompass 13.2 haploid genomes, providing the most comprehensive clone resource for a single soybean genotype for public genome research. We show that the BAC library has enhanced the development of the soybean whole-genome physical map and use of three complementary BAC libraries improves genome physical mapping by fingerprint analysis of most of the clones of the library. The rDNA-containing clones were also fingerprinted to evaluate the feasibility of constructing contig maps of the rDNA regions. It was found that physical maps for the rDNA regions could not be readily constructed by fingerprint analysis, using one or two restriction enzymes. Additional data to fingerprints and/or different fingerprinting methods are needed to build contig maps for such highly tandem repetitive regions and thus, the physical map of the entire soybean genome.     

Cloning of a DNA fragment from Streptomyces griseus which directs streptomycin phosphotransferase activity

DNA from Streptomyces griseus ATCC 12475 was partially digested with Sau3A and fragments were ligated into BglII-cleaved pIJ702. When the ligation mixture was used to transform protoplasts of Streptomyces lividans TK54, two transformants resistant to both thiostrepton and streptomycin were isolated. The hybrid plasmids pBV3 and pBV4 which they contained, carrying inserts of sizes 4.45 and 11.55 kbp respectively, each retransformed S. lividans to streptomycin resistance at high efficiency. Both plasmids hybridized to restriction digests of S. griseus chromosomal DNA in Southern blot experiments. In vitro deletion and sub-cloning experiments showed the sequence conferring streptomycin resistance to lie within a segment of 1.95 kbp. Extracts of TK54(pBV3) and TK54(pBV4) contained a streptomycin phosphotransferase similar to that in extracts of S. griseus. Streptomycin phosphotransferase activity appeared in extracts of S. griseus, TK54(pBV3) and TK54(pBV4) within 2 d of inoculation. When pBV3 and pBV4 were retransformed into S. griseus with selection for thiostrepton resistance, plasmid DNA of sizes corresponding to the incoming plasmids was found in the transformants. In these transformants the phosphotransferase appeared at 1.5 rather than 2 d, and reached a level over twice that of the original S. griseus strain.     

A new vector for cloning of genes and replicons in yeasts

A novel Escherichia coli-Saccharomyces cerevisiae shuttle vector lambda MAN78 has been constructed. The vector contains phage lambda 47.1 DNA, Sacch. cerevisiae chromosomal segment with TRP1 gene and the yeast ARS1 replicator. This vector may be propagated as a phage and, similar to parental lambda 47.1, allows direct selection of large DNA inserts (15-24 kbp) in E. coli. lambda MAN78 can efficiently transform LiCl-treated yeast cells (3-5 X 10(3) transformants per 1 microgram DNA). Replication of hybrid molecules in E. coli cells does not influence the ability of the molecules to transform yeast cells and replicate in the cells.     

Isolation of cDNA for Pea Phytochrome Using an Expression Vector

Partially purified phytochrome mRNA was obtained from etiolatedpea epicotyls by polyribosome immunoprecipitation or by sizefractionation of total poly(A)⁺RNA, and used for the synthesisof double-stranded complementary DNA (cDNA). cDNA librarieswere constructed using an Escherichia coli expression vector,pUC9, and screened for phytochrome cDNA by colony immunologicalassay. Nine colonies were found to produce a 27 kDa polypeptidethat was reactive to both polyclonal and monoclonal antipeaphytochrome antibodies. The plasmids from these colonies containedcDNA inserts of 1.2 or 2.0 kbp. Hybridization-arrest translationassay verified that the cDNA clones contained a sequence codingfor phytochrome polypeptide. RNA blot hybridization analysisindicated that the cDNA hybridized to a 4.1 kb poly(A)⁺RNA indark-grown pea. (Received March 22, 1986; Accepted June 13, 1986)     

Cytoplasmic Leucyl-Trna Synthetase of Neurospora Crassa Is Not Specified by the Leu-5 Locus

We generated a lambda gt11 Neurospora crassa cDNA library and screened the library for the cytoplasmic leucyl-tRNA synthetase (cyto LeuRS) clones using cyto LeuRS specific antibody. Two clones, lambda NCLRSC1 and lambda NCLRSC2, were obtained which have inserts of approximately 2 kbp and approximately 1.3 kbp, and which overlap by about 0.6 kbp. The following lines of evidence indicate that lambda NCLRSC1 and lambda NCLRSC2 encode parts of cyto LeuRS. (1) Antibodies affinity purified using either of the fusion proteins encoded by lambda NCLRSC1 or lambda NCLRSC2 inhibit cyto LeuRS activity. Thus, the fusion protein and cyto LeuRS share immunological determinants. (2) The same antibodies also react with an approximately 115-kDa protein, which comigrates with purified cyto LeuRS, in immunoblots of total N. crassa proteins. We used the cDNA clones to probe a N. crassa genomic DNA library and isolated two genomic DNA clones. Partial sequence analysis of cDNA and genomic DNA clones shows a methionine initiated open reading frame, which includes a stretch of amino acid residues that are highly conserved and that are at the ATP binding site in aminoacyl-tRNA synthetases. Using the cloned DNA as probe, we show that the cyto LeuRS mRNA is approximately 3900 nucleotides long. Finally, we have used restriction fragment length polymorphism mapping to show that the cyto LeuRS gene resides on the far right of linkage group II and not on linkage group V where the leu-5 mutation, which was previously reported to specify cyto LeuRS, is located.     

Large-scale purification of plasmid insert DNA sequences using low-percentage agarose exclusion chromatography

Linear double-stranded DNA fragments ranging from 0.14 to 8.4 kbp have been fractionated on low-percentage agarose exclusion gels. Both Ultragel A2 (2% agarose) and Bio-Gel A150m (1% agarose) exclude DNA fragments greater than 900 bp, while the exclusion limit of Bio-Gel A50m (2% agarose) is about 350 bp. All gels result in moderate resolution of DNA fragments smaller than the exclusion limits; we generally observe nearly complete one-step separation of fragments that differ in size by a factor of 2. On the basis of these results, we have used these exclusion gels to routinely purify greater than 0.4 mg of plasmid insert DNA sequences in one step and over 2.5 mg with a single column, demonstrating that these gel matrices can be ideally suited for repeated rapid large-scale purification of plasmid inserts. In addition, this knowledge allows for a more rational design of plasmids in those cases where large-scale use of the insert DNA is required.