Isolation of bovine Y-derived sequence: potential use in embryo sexing.

To obtain bovine Y-derived probes, we have constructed a bovine plasmid library enriched for Y-specific DNA sequences by the deletion enrichment method. The resulting clones were analyzed by hybridization to Southern blots of male and female genomic DNA. From 200 clones tested, two (BC1.2 and BC1.34) were entirely male specific, six gave a male-female differential hybridization pattern, and the remaining reacted similarly with male and female DNA. Interspecies somatic cell hybrid studies and chromosomal in situ hybridization confirmed that the BC1.2 sequence was derived from the Y chromosome. This 54-bp fragment is present at about 2000-2500 copies in the bovine male genome. No polymorphism was revealed with any of the restriction enzymes used, suggesting enzyme site conservation within blocks of repeats. Evolutionary study has shown that the BC1.2 sequence is conserved within Bos and Bison genera and remains male specific. The male specificity and repeated nature of the BC1.2 sequence have enabled us to use it as a molecular probe for sex determination on small numbers of cells by in situ hybridization.     

Association of transformation of xenosomes from nonkiller to killer with extrachromosomal DNA.

Extrachromosomal DNA in the form of covalently closed circular DNA molecules was isolated from killer and nonkiller xenosomes, bacterial endosymbionts of the marine protozoan Parauronema acutum. Restriction endonuclease digests of these molecules derived from 12 isolates revealed consistent, readily identifiable, differences in the pattern of fragments of the killer as compared with those present in the nonkiller. Transformation of the nonkiller to killer by infection is also accompanied by a change from the nonkiller to killer pattern. Based on analysis of fragments resulting from restriction endonuclease digests, two circular duplex DNA molecules, each 63 kilobase pairs (kbp) in length, were identified in the 263-20 nonkiller stock and mapped. The maps revealed that each possesses a single BamHI site and multiple BglI, BstIIE, PstI, and SalI sites. A distinguishing feature of these maps is that the two molecules share a region about 17 kbp in length in which multiple restriction sites are in register with each other. Allowing for a 0.5-kbp insertion or deletion and the introduction or removal of only a few restriction sites, an additional stretch extending approximately 31 kbp beyond this sequence could also be considered to be homologous. The structure of the killer plasmid appears to be more complex, and we have been unable, as yet, to construct physical maps for this DNA. We postulate that the killer plasmid DNA is composed of three, perhaps four, circular 63-kbp duplexes, at least one which contains a single BamHI site and another which contains two BamHI sites. The remaining molecules may represent copies of either or both of the other two, modified to contain additional restriction sites. Transformation from the nonkiller to the killer is visualized as the insertion of restriction sites at various points along parent nonkiller plasmid DNA molecules. The mechanism by which these sites are introduced is unknown.     

The chloroplast genome of Carthamus tinctorius

Summary A physical map of safflower (Carthamus tinctorius L.) chloroplast DNA has been generated using Sall, Pstl, Kpnl and HindIII restriction endonucleases. Southern blots to single and double digests by these enzymes were hybridized with ³²P-dCTP nick-translated Kpnl probes, which were individually isolated from agarose gels. The plastid genome was found to be circular (151 kbp), to contain a repeated sequence of about 25 kbp, and to have small and large single copy regions of approximately 20 and 81 kbp, respectively. Heterologous probes from spinach and Euglena containing psbA, rbcL, atpA or rrnA structural genes were also hybridized with such single and double restriction enzyme digests and mapped on this circular chlorpolast genome. The genetic map was found to be co-linear with that of spinach and many other higher plants.     

Bacterial artificial chromosome-based physical map of Gibberella zeae (Fusarium graminearum).

Fusarium graminearum is the primary causal pathogen of Fusarium head blight of wheat and barley. To accelerate genomic analysis of F. graminearum, we developed a bacterial artificial chromosome (BAC)-based physical map and integrated it with the genome sequence and genetic map. One BAC library, developed in the HindIII restriction enzyme site, consists of 4608 clones with an insert size of approximately 107 kb and covers about 13.5 genome equivalents. The other library, developed in the BamHI restriction enzyme site, consists of 3072 clones with an insert size of approximately 95 kb and covers about 8.0 genome equivalents. We fingerprinted 2688 clones from the HindIII library and 1536 clones from the BamHI library and developed a physical map of F. graminearum consisting of 26 contigs covering 39.2 Mb. Comparison of our map with the F. graminearum genome sequence showed that the size of our physical map is equivalent to the 36.1 Mb of the genome sequence. We used 31 sequence-based genetic markers, randomly spaced throughout the genome, to integrate the physical map with the genetic map. We also end-sequenced 17 BamHI BAC clones and identified 4 clones that spanned gaps in the genome sequence. Our new integrated map is highly reliable and useful for a variety of genomics studies.     

Localization of replication origins in pea chloroplast DNA.

The locations of the two replication origins in pea chloroplast DNA (ctDNA) have been mapped by electron microscopic analysis of restriction digests of supercoiled ctDNA cross-linked with trioxalen. Both origins of replication, identified as displacement loops (D-loops), were present in the 44-kilobase-pair (kbp) SalI A fragment. The first D-loop was located at 9.0 kbp from the closest SalI restriction site. The average size of this D-loop was about 0.7 kbp. The second D-loop started 14.2 kbp in from the same restriction site and ended at about 15.5 kbp, giving it a size of about 1.3 kbp. The orientation of these two D-loops on the restriction map of pea ctDNA was determined by analyzing SmaI, PstI, and SalI-SmaI restriction digests of pea ctDNA. One D-loop has been mapped in the spacer region between the 16S and 23S rRNA genes. The second D-loop was located downstream of the 23S rRNA gene. Denaturation mapping of recombinants pCP 12-7 and pCB 1-12, which contain both D-loops, confirmed the location of the D-loops in the restriction map of pea ctDNA. Denaturation-mapping studies also showed that the two D-loops had different base compositions; the one closest to a SalI restriction site denatured readily compared with the other D-loop. The recombinants pCP 12-7 and pCB 1-12 were found to be highly active in DNA synthesis when used as templates in a partially purified replication system from pea chloroplasts. Analysis of in vitro-synthesized DNA with either of these recombinants showed that full-length template DNA was synthesized. Recombinants from other regions of the pea chloroplast genome showed no significant DNA synthesis activity in vitro.     

Characterization of bacteriophage P1 library containing inserts of Drosophila DNA of 75–100 kilobase pairs

A multiple-hit bacteriophage P1 library containing DNA fragments from Drosophila melanogaster in the size range 75–100 kb was created and subjected to a preliminary evaluation for completeness, randomness, fidelity, and clone stability. This P1 library presently contains 3840 individual clones, or approximately two genome equivalents. The library was screened with a small set of unique-sequence test probes, and clones containing the sequences have been recovered. In situ hybridization with salivary gland chromosomes indicates that the clones originate from the site of the probe sequences in the genome, and filter hybridization of restriction digests suggests that the clones are not rearranged in comparison with the genomic sequences. Approximately 1.7% of the clones contain sequences that hybridize with ribosomal DNA. A small subset of these clones was tested for stability by examination of restriction fragments produced after repeated subculturing, and no evidence for instability was found. The P1 cloning system has general utility in molecular genetics and may provide an important intermediate level of resolution in physical mapping of the Drosophila genome.by W. Hennig     

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.     

Study on rRNA genes in Mycobacterium smegmatis

The number of rRNA genes in Mycobacterium smegmatis was examined by hybridization of BamHI and SalI digests of chromosomal DNA with 3'-end-labeled 5S, 16S, 23S rRNA and tRNA. Each RNA probe gave two hybridization bands. The PstI fragments of 6.6 kilobases were cloned to pBR322. The cloned DNA was characterized by restriction endonuclease mapping, DNA-RNA hybridization, and the R-loop technique.     

Chloroplast genome organization of bromegrass,Bromus inermis Leyss

Summary A physical map of the Bromus inermis chloroplast genome was constructed using heterologous probes of barley and wheat chloroplast DNA (cpDNA) to locate restriction sites. The map was aligned from data obtained from filter hybridization experiments on single and double enzyme digests. Cleavage sites for the enzymes PstI, SalI, KpnI, XhoI and PvuII were mapped. The chloroplast genome of B. inermis is similar in physical organization to that of other grasses. The circular cpDNA molecule of B. inermis has the typical small (12.8 kbp) and large (81.3 kbp) single-copy regions separated by a pair of inverted repeat (21 kbp) regions. The cpDNA molecule of B. inermis is collinear in sequence to that of wheat, rye, barley and oats. No structural rearrangements or major deletions were observed, indicating that the cpDNA of Bromus is a useful tool in phylogenetic studies.     

Physical mapping of a 330 X 10(3)-base-pair region of the Myxococcus xanthus chromosome that is preferentially labeled during spore germination.

Myxococcus xanthus was pulse-labeled with [3H]thymidine immediately after germination of dimethyl sulfoxide-induced spores. The restriction enzyme digests of the total chromosomal DNA from the pulse-labeled cells were analyzed by one-dimensional as well as two-dimensional agarose gel electrophoresis. Four PstI fragments preferentially labeled at a very early stage of germination were cloned into the unique PstI site of pBR322. By using these clones as probes, a restriction enzyme map was established covering approximately 6% of the total M. xanthus genome (330 X 10(3) base pairs). The distribution of the specific activities of the restriction fragments pulse-labeled after germination suggests a bidirectional mode of DNA replication from a fixed origin.     

Isolation of A/D and C genome specific dispersed and clustered repetitive DNA sequences from Avena sativa.

DNA gel-blot and in situ hybridization with genome-specific repeated sequences have proven to be valuable tools in analyzing genome structure and relationships in species with complex allopolyploid genomes such as hexaploid oat (Avena sativa L., 2n = 6x = 42; AACCDD genome). In this report, we describe a systematic approach for isolating genome-, chromosome-, and region-specific repeated and low-copy DNA sequences from oat that can presumably be applied to any complex genome species. Genome-specific DNA sequences were first identified in a random set of A. sativa genomic DNA cosmid clones by gel-blot hybridization using labeled genomic DNA from different Avena species. Because no repetitive sequences were identified that could distinguish between the A and D gneomes, sequences specific to these two genomes are refereed to as A/D genome specific. A/D or C genome specific DNA subfragments were used as screening probes to identify additional genome-specific cosmid clones in the A. sativa genomic library. We identified clustered and dispersed repetitive DNA elements for the A/D and C genomes that could be used as cytogenetic markers for discrimination of the various oat chromosomes. Some analyzed cosmids appeared to be composed entirely of genome-specific elements, whereas others represented regions with genome- and non-specific repeated sequences with interspersed low-copy DNA sequences. Thus, genome-specific hybridization analysis of restriction digests of random and selected A. sativa cosmids also provides insight into the sequence organization of the oat genome.     

Molecular cloning of avian sarcoma virus closed circular DNA: structural and biological characterization of three recombinant clones.

Unintegrated, circular viral DNA, isolated from Prague A avian sarcoma virus (PrA-ASV)-infected quail cells (QT6), was cloned in the lambda vector lambda gtWES x lambda B. Three independent lambda-ASV recombinants were identified, and each contained a complete copy of the PrA-ASV genome. The arrangement of the ASV sequences within the recombinants was determined by restriction enzyme analysis and hybridization with labeled ASV-specific complementary DNA. One of the recombinants (lambda RPA101) resulted from cloning at the EcoRI site located within the terminally repeated sequence and therefore was virtually co-linear with PrA-ASV virion RNA. The other two recombinants (lambda RPA102 and 103) resulted from cloning at the EcoRI site located within the viral env gene. By restriction enzyme analysis and by measurement of R-loops formed between lambda RPA101 and PrA-ASV virion 35S RNA, the viral genome was estimated to be 9,100 bases in length. Genome length viral DNA purified from clones lambda RPA102 and 103 was biologically active. Transfection of chicken embryo cells with viral DNA, in the form of either circles or linear dimers, produced foci of transformed cells within 8 to 10 days. Linear DNA was much less efficient at inducing transformation. Viral DNA from the clone lambda RPA101 was unable to cause transformation; the basis for this defect is unknown.     

Chloroplast DNA variation in pearl millet and related species

The evolution of specific regions of the chloroplast genome was studied in five grass species in the genus Pennisetum, including pearl millet, and one species from a related genus (Cenchrus). Three different regions of the chloroplast DNA were investigated. The first region included a 12-kilobase pair (kbp) EcoRI fragment containing the 23S, 16S and 5S ribosomal RNA genes, which is part of a larger duplicated region of reverse orientation. The second region was contained in a 21-kbp Sa/I fragment, which spans the short single-copy sequence separating the two reverse repeat structures and which overlaps the duplicated copies of the 12-kbp Eco RI fragment. The third region was a 6-kbp EcoRI fragment located in the large single-copy region of the chloroplast genome. Together these regions account for slightly less than 25% of the chloroplast genome. Each of these DNA fragments was cloned and used as hybridization probes to determine the distribution of homologous DNA fragments generated by various restriction endonuclease digests.—A survey of 12 geographically diverse collections of pearl millet showed no indication of chloroplast DNA sequence polymorphism, despite moderate levels of nuclear-encoded enzyme polymorphism. Interspecific and intergeneric differences were found for restriction endonuclease sites in both the small and the large single-copy regions of the chloroplast genome. The reverse repeat structure showed identical restriction site distributions in all materials surveyed. These results suggest that the reverse repeat region is differentially conserved during the evolution of the chloroplast genome.     

A family of repeated sequences dispersed through the genome of Lilium henryi

A family of dispersed repeats longer than 7 kilobase pairs (kbp) has been identified in the very large genome of Lilium henryi, and two subregions cloned. Initially a rapidly reannealing probe (C₀t<1 M s) was prepared by hydroxyapatite chromatography. Half the copies of all sequences repeated 15000 times per genome are expected to reanneal by this C₀t value. The probe hydridized to abundant fragments of 2, 5, and 7 kbp released from genomic DNA by Bam HI digestion. Twelve 2-kb fragments and ten 5-kb sequences were cloned into pBR322. Restriction mapping of the two sets of clones showed individual members to be quite similar. Length variation was no more than 200 base pairs (bp) between repeats, and consensus sites were present on 80%–90% of occasions. In situ hybridization using representative 2-kbp and 5-kbp clones showed each sequence to be dispersed throughout all chromosomal regions. Studies on the genomic organization suggested that the 2-kbp and 5-kbp sequences are usually adjacent, and that occasional absence of the internal Bam HI site results in the release of the 7-kbP fragment. There are at least 13000 copies of the full repeat per L. henryi genome, thus accounting for approximately 0.3% of the total of 32 million kbp.     

Molecular evidence on maize specific DNA fragment transferred into wheat through sexual hybridization

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Restriction endonuclease mapping of the hepatitis B viral genome isolated from Taiwan

The Eco RI fragment of hepatitis B virus (HBV) DNA isolated from human blood plasma Dane particles were inserted into plasmid pUC8 Eco RI site and transformed into E. coli JM103 host. Two recombinants pTWL1 and pTWL2 were found to carry 3.2 kbp fragment and proved to have HBV genome by Southern hybridization method. The 1.4 kbp Bam HI fragment which carried the hepatitis B viral surface antigen (HBsAg) gene, obtained via Bam HI digestion of Dane particles DNA which was made fully double stranded by endogenous DNA polymerase reaction, was also inserted into plasmid pUC8 Bam HI site. Four recombinant clones, pTWS1, pTWS2, pTWS3, and pTWS4 were found. Only one of the clones pTWS1 carried the HBsAg gene in a correct orientation with respect to the lac promoter sequence. The physical mapping of HBV DNA was performed with several restriction endonucleases. Our results indicated that the HBV DNA insert contains unique XbaI and HpaI cleavage sites and lacks the cleavage sites for the HindIII, SmaI, KpnI, SalI, and SstI endonucleases. The locations of Bam HI, BglII, and HincII endonucleases cleavage sites within the cloned HBV DNA of the pTWL1 plasmid were similar to that HBV DNA of adw and adw2 subtypes.     

SERIAL PASSAGE OF TRICHOPLUSIA NI SINGLE EMBEDDED BACULOVIRUS IN HOMOLOGOUS CELL LINE*

Abstract Trichoplusia ni single embedded nuclear polyhedrosis virus (TnSNPV) is highly pathogenic for cell line but there were some problems with producing a few polyhedra and decrease of efficiency during serial passages. Sixty serial passages of TnSNPV were conducted in Tn 5B1–4 cell. Replication of the viral DNA and comparison of the viral character between the wild virus and clones from serial passages were performed. The TnSNPV DNA molecular weight, 115.8 kbp, was estimated by restriction enzyme analysis. Replication of the viral DNA which was analyzed by slot blot hybridization started at 8 h postinfection (p.i) and the DNA increased fast after 28 h p. i. The DNA synthesis reached a maximal number at 40 h p. i. The result from serial passage of the virus demanstrated that the relative BV titer was maitained at approximately 5 log TCIDSO/mL. The polyhedra of viral clones from early passages were almost normal but the majority of clones from late passages produced polyhedra without virions by examination with electron microscopy. Although there were some alterations with viral DNA from different clones, yet all of clones were from a homologous genome of wild virus by examination of restriction enzyme analysis and DNA:DNA hybridization.     

Restriction fragment pattern analysis of HPRT mutations induced in rat-liver epithelial cells by alkylating and arylating agents.

Structural alterations in the hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene in genomic DNA of adult rat-liver (ARL) epithelial cells that were mutated by alkylating and arylating mutagens were studied by restriction enzyme fragment pattern (RFP) analysis. ARL cells were mutated with the direct-acting alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) or the activation-dependent arylating agents 7,12-dimethylbenz[a]anthracene (DMBA) and N-2-acetylaminofluorene (AAF). Alterations in the HPRT gene of at least 10 independent 6-thioguanine-resistant (TGr) clones mutated by each chemical were analyzed using 8 different restriction endonucleases; Hind III, EcoRI, BamHI, XbaI, Hae III, XhoI, MspI and PstI, and a full-length HPRT cDNA as a probe in molecular hybridization. Among the 10 MNNG-induced mutants, the RFPs obtained with most endonucleases displayed no changes, while an altered RFP was found in only one mutant using XbaI. None of the 10 DMBA-induced mutants displayed altered RFPs. Restriction analysis of the 10 AAF-induced mutants showed no abnormality in HPRT gene structure in most restriction digests, while altered RFPs were detected in one mutant using MspI and in two mutants with XbaI digestion. Overall, the studies reveal an absence of major DNA sequence changes in 26 of 30 induced mutants although the mutant phenotype of 4 of the TGr clones can be attributed to gross chromosomal changes or a point mutation at the restriction site. The absence of detectable alterations in the RFPs of the majority of the mutants is strongly suggestive of base substitution as the major molecular alteration underlying the mutant phenotype. The HPRT activity of 14 of 30 mutants was at least 5% of the wild-type level, which is consistent with a structural alteration in the gene product expressed as partial activity of the enzyme. Therefore, the data are interpreted as indicating that in the ARL cells, all 3 mutagens induced primarily localized alterations in base sequences in the HPRT gene together with a few mutations involving large sequence changes.     

Insertions of palindromic DNA sequences into the J-F intercistronic region of bacteriophage phi X174 interfere with normal phage growth

The effect of hairpin (cruciform) size on the regulation of gene expression was investigated by cloning a series of palindromic sequences into the non-essential J-F intercistronic region of the bacteriophage phi X174 ins6 genome. Genetic stability of the insert sequence and its effect on the growth efficiency of the phage was used as an initial measure of the biological consequence of hairpin insertions. Multimers of increasing size of the BamHI linker sequence C-C-G-G-A-T-C-C-G-G were inserted into the PvuII site of the parental strain ins6. The largest hairpin that could be constructed and maintained in the phi X174 genome had a stem length of 22 base-pairs and a loop size of four nucleotides (linker tetramer). However, this structure proved to be disadvantageous to the phage and was rapidly deleted from its genome. Trimer inserts were more stable, but were eventually deleted also. Monomer and dimer inserts, though genetically stable, decreased the growth efficiency of the phage as judged by competitive growth experiments and measurements of burst size. The physical formation of these hairpins was shown by restriction digests of single-stranded DNA with BamHI and HpaII. We argue that these secondary structures form in vivo, at least in the single-stranded genome and the polycistronic mRNAs, and were responsible for the observed growth defects.