Isolation of deletion and substitution mutants of adenovirus type 5

The infectivity of adenovirus type 5 DNA can be increased to about 5 x 10³ plaque-forming units per μg DNA if the DNA is isolated as a DNA-protein complex. Utilizing this improved infectivity, a method was developed for the selection of mutants lacking restriction endonuclease cleavage sites. The procedure involves three steps. First, the DNA-protein complex is cleaved with a restriction endonuclease. The Eco RI restriction endonuclease was used here. It cleaves adenovirus type 5 DNA to produce three fragments: fragment A (1–76 map units), fragment C (76–83 map units) and fragment B (10–83 map units). Second, the mixture of fragments is rejoined by incubating with DNA ligase, and, third, the modified DNA is used to infect cells in a DNA plaque assay. Mutants were obtained which lacked the endonuclease cleavage site at 0.83 map units. Such mutant DNAs were selected by this procedure because they were cleaved by the Eco RI endonuclease to produce only two fragments: a normal A fragment and a fused B/C fragment. These two fragments could be rejoined to produce a viable DNA molecule as a result of a bimolecular reaction with one ligation event; this exerted a strong selection for such molecules since a trimolecular reaction (keeping the C fragment in its proper orientation) and two ligation events were required to regenerate a wild-type molecule. The alterations resulting in the loss of the Eco RI endonuclease cleavage site at 0.83 map units include both deletion and substitution mutations. The inserted sequences in the substitution mutations are cellular in origin.     

Sites in simian virus 40 chromatin which are preferentially cleaved by endonucleases.

Simian virus 40 (SV40) chromatin isolated from infected BSC-1 cell nuclei was incubated with deoxyribonuclease I, staphylococcal nuclease or an endonuclease endogenous to BSC-1 cells under conditions selected to introduce one doublestrand break into the viral DNA. Full-length linear DNA was isolated, and the distribution of sites of initial cleavage by each endonuclease was determined by restriction enzyme mapping. Initial cleavage of SV40 chromatin by deoxyribonuclease I or by endogenous nuclease reduced the recovery of Hind III fragment C by comparison with the other Hind III fragments. Similarly, Hpa I fragment B recovery was reduced by comparison with the other Hpa I fragments. When isolated SV40 DNA rather than SV40 chromatin was the substrate for an initial cut by deoxyribonuclease I or endogenous nuclease, the recovery of all Hind III or Hpa I fragments was approximately that expected for random cleavage. Initial cleavage by staphylococcal nuclease of either SV40 DNA or SV40 chromatin occurred randomly as judged by recovery of Hind III or Hpa I fragments. These results suggest that, in at least a portion of the SV40 chromatin population, a region located in Hind III fragment C and Hpa I fragment B is preferentially cleaved by deoxyribonuclease I or by endogenous nuclease but not by staphylococcal nuclease.Complementary information about this nuclease-sensitive region was provided by the appearance of clusters of new DNA fragments after restriction enzyme digestion of DNA from viral chromatin initially cleaved by endogenous nuclease. From the sizes of new fragments produced by different restriction enzymes, preferential endonucleolytic cleavage of SV40 chromatin has been located between map positions 0.67 and 0.73 on the viral genome.     

Size and physical map of the chromosome of Haemophilus influenzae.

A variation of pulse-field electrophoresis, field-inversion gel electrophoresis, was used to determine the size and physical map of the chromosome of Haemophilus influenzae. The DNA of H. influenzae had a low G + C content (39%) and no restriction sites for the enzymes NotI or SfiI. However, a number of restriction enzymes (SmaI, ApaI, NaeI, and SacII) that recognized 6-base-pair sequences containing only G and C nucleotides were found to generate a reasonable number of DNA fragments that were separable in agarose gels by field-inversion gel electrophoresis. The sizes of the DNA fragments were calibrated with a lambda DNA ladder and lambda DNA restriction fragments. The sum of fragment sizes obtained with restriction digests yielded a value for the chromosome of 1,980 kilobase pairs. Hybridization of a labeled fragment with two or more fragments from a digest with a different restriction enzyme provided the information needed to construct a circular map of the H. influenzae chromosome.     

Preferential uptake of restriction fragments from a gonococcal cryptic plasmid by competent Neisseria gonorrhoeae

Factors involved in the specificity of DNA uptake by competent Neisseria gonorrhoeae were examined. Host-controlled modification did not affect uptake. Certain restriction fragments of the 4.2 kb gonococcal cryptic plasmid pFA1 and of the replicative form of the bacteriophage M13 were taken up in preference to others, independent of differences in fragment size. A 600 bp fragment from the 4.2 kb plasmid was cloned into pLES2, a gonococcal-Escherichia coli shuttle vector; the 600 bp fragment was taken up into a DNAase-I-resistant state in preference to the vector fragment. A second 370 bp fragment in pFA1 was also taken up preferentially. The 600 bp and 370 bp fragments share a 10 bp sequence, which is found in pFA1 only on fragments that were taken up readily. However, a fragment from M13 which was efficiently taken up did not contain this 10 bp sequence. In addition, this sequence was not sufficient to direct preferential DNA uptake by gonococci, since a recombinant plasmid containing this 10 bp sequence was not taken up appreciably better than the vector plasmid or another recombinant plasmid containing an unrelated 10 bp sequence. Sequence comparisons of the three restriction fragments which were preferentially taken up did not yield any consensus sequences greater than 7 bp. Although it is likely that efficient uptake of DNA by gonococci is determined by DNA structure, a single short sequence could not be found that accounted for specific uptake.     

A technique for radiolabeling DNA restriction endonuclease fragments to high specific activity

A technique for conveniently radiolabeling DNA restriction endonuclease fragments to high specific activity is described. DNA fragments are purified from agarose gels directly by ethanol precipitation and are then denatured and labeled with the large fragment of DNA polymerase I, using random oligonucleotides as primers. Over 70% of the precursor triphosphate is routinely incorporated into complementary DNA, and specific activities of over 10(9) dpm/microgram of DNA can be obtained using relatively small amounts of precursor. These "oligolabeled" DNA fragments serve as efficient probes in filter hybridization experiments.     

Direct and indirect gene replacements in Aspergillus nidulans.

We performed three sets of experiments to determine whether cloned DNA fragments can be substituted for homologous regions of the Aspergillus nidulans genome by DNA-mediated transformation. A linear DNA fragment containing a heteromorphic trpC+ allele was used to transform a trpC- strain to trpC+. Blot analysis of DNA from the transformants showed that the heteromorphic allele had replaced the trpC- allele in a minority of the strains. An A. nidulans trpC+ gene was inserted into the argB+ gene, and a linear DNA fragment containing the resultant null argB allele was used to transform a trpC- argB+ strain to trpC+. Approximately 30% of the transformants were simultaneously argB-. The null argB allele had replaced the wild-type allele in a majority of these strains. The A. nidulans SpoC1 C1-C gene was modified by removal of an internal restriction fragment and introduced into a trpC- strain by transformation with a circular plasmid. A transformant containing a tandem duplication of the C1-C region separated by plasmid DNA was self-fertilized, and trpC- progeny were selected. All of these had lost the introduced plasmid DNA sequences, whereas about half had retained the modified C1-C gene and lost the wild-type copy. Thus, it is possible with A. nidulans to replace chromosomal DNA sequences with DNA fragments that have been cloned and modified in vitro by using either one- or two-step procedures similar to those developed for Saccharomyces cerevisiae.     

Restriction endonucleases and their applications

Restriction endonucleases are deoxyribonucleases which cleave double-stranded DNA into fragments. With only one exception, all restriction endonucleases recognize short, non-methylated DNA sequences. Restriction endonucleases can be divided into two groups based on the position of the cleavage site relative to the recognition sequence. Class I restriction endonucleases cleave double-stranded DNA at positions outside the recognition sequence and generate fragments of random size. The cleavage sites of Class II restriction endonucleases are located, in most cases, within the recognition sequence. Most of the Class II restriction endonucleases recognize 4, 5, or 6 base pair palindromes and generate fragments with either flush ends or staggered ends. DNA fragments with staggered ends contain 3, 4, or 5 nucleotide single-stranded tails called ‘sticky ends’. DNA fragments produced by Class II restriction endonuclease cleavage can be separated on gels according to their molecular weight. The fragments can be isolated from the gel and used for sequence analysis to elucidate genetic information stored in DNA. Further, an isolated fragment can be inserted into a small extrachromosomal DNA, e.g. plasmid, phage or viral DNA, and its replication and expression can be studied in clones of prokaryotic or eukaryotic cells. Restriction endonucleases and cloning technology are powerful modern tools for attacking genetic problems in medicine, agriculture and industrial microbiology.     

Detection of mutations and DNA polymorphisms using whole genome Southern Cross hybridization.

We report a general method for the detection of restriction fragment length alterations associated with mutations or polymorphisms using whole genomic DNA rather than specific cloned DNA probes. We utilized a modified Southern Cross hybridization to display the hybridization pattern of all size-separated restriction fragments from wild-type Caenorhabditis elegans to all the corresponding fragments in a particular mutant strain and in a distinct C. elegans variety. In this analysis, almost all homologous restriction fragments are the same size in both strains and result in an intense diagonal of hybridization, whereas homologous fragments that differ in size between the two strains generate an off-diagonal spot. To attenuate the contribution of repeated sequences in the genome to spurious off-diagonal spots, restriction fragments from each genome were partially resected with a 3' or 5' exonuclease and not denatured, so that only the DNA sequences at the ends of these fragments could hybridize. Off-diagonal hybridization spots were detected at the expected locations when genomic DNA from wild-type was compared to an unc-54 mutant strain containing a 1.5 kb deletion or to a C. elegans variety that contains dispersed transposon insertions. We suggest that this modified Southern Cross hybridization technique could be used to identify restriction fragment length alterations associated with mutations or genome rearrangements in organisms with DNA complexities as large as 10(8) base pairs and, using rare-cutting enzymes and pulse-field gel electrophoresis, perhaps as large as mammalian genomes. This information could be used to clone fragments associated with such DNA alterations.     

A novel method for producing partial restriction digestion of DNA fragments by PCR with 5-methyl-CTP.

Partial digestion of DNA fragments is a standard procedure for subcloning analysis and for generating restriction maps. We have developed a novel method to generate a partial digestion for any DNA fragment that can be amplified by PCR. The method involves the incorporation of 5-methyl-dCTP into the PCR product to protect most of the restriction sites. As a result, complete digestion of the modified PCR products with a 5-methyl-dCTP-sensitive enzyme will produce an array of restriction fragments equivalent to a partial restriction enzyme digestion reaction done on unmethylated PCR products. This method reduces the time and material needed to produce partially-digested DNA fragments by traditional methods. Furthermore, using fluorescein-labeled primers in the reaction, we were able to detect the fluorescein-labeled end fragments resulting from the enzyme digestion using a fluorimager or anti-fluorescein-AP antibody and thus determine the restriction maps.     

Deoxyribonucleic acid modifications and restriction endonuclease production in Neisseria gonorrhoeae.

Modification of gonococcal deoxyribonucleic acid (DNA) was investigated, and the relationship with endonuclease production was explored. Both chromosomal and plasmid DNA from different gonococcal strains, irrespective of their plasmid content, was poorly cleaved by the restriction endonucleases HaeII, HaeIII, SacII, and BamHI. The fragment pattern of the Tn3 segment present on the 7.2-kilobase gonococcal resistance plasmid, when compared to its known DNA sequence, allowed us to conclude that the HaeIII and BamHI resistance was due to modification of these sites. A comparison of the fragment pattern of the resistance plasmid, when isolated from Escherichia coli or Neisseria gonorrhoeae, revealed that the resistance of HaeII must also be due to modification of its recognition sequence. Isoschizomers of HaeII and HaeIII can be found in isolates of N. gonorrhoeae (NgoI and NgoII, respectively). A new restriction endonuclease in gonococci, NgoIII, with a specificity similar to SacII, is reported here. High-pressure liquid chromatography of gonococcal DNA showed the presence of 5-methylcytosine. It is suggested that the methylation of cytosine residues in the HaeII (NgoI), HaeIII (NgoII), and SacII (NgoIII) recognition sites is the basis for the resistance of gonococcal DNA to cleavage by these enzymes. This methylation may be part of a host restriction modification system. In two out of five gonococcal strains the sequence -GATC- was modified. One strain unable to modify this sequence was a spontaneous mutant of a strain carrying such a modifying function.     

Analysis of the Vicia faba genome by use of restriction endonucleases.

DNA of the broad bean, Vicia faba, was cleaved by the restriction endonucleases endoR . EcoRI, endoR . HindIII, endoR . HincII, endoR . BamI, and endoR . BspRI. Separation in agarose gels of the resulting fragments revealed, in addition to the bulk DNA, an enzyme-specific pattern of bands composed of restriction fragments of 300 to more than 30,000 base pairs in length. Bulk DNA was characterized by an unusual size distribution which significantly deviated from that expected according to the random fragmentation theory. It is argued that the observed distribution is due to the high proportion of repetitive DNA within this species (approximately equal to 75%). In all digests, a class of high-molecular-weight restriction fragments of more than 30,000 base pairs in length was observed which comprised 5-8% of the genome. It showed hybridization with highly repetitive DNA (c0t less than or equal to 2 x 10(-2) M . s) and included a fraction (2-3% of the genome) highly resistant to the activity of all the enzymes tested. The buoyant density in CsCl of this resistant DNA was not different from that of the total DNA (36% dG + dC). In endoR . EcoRI digests, the high-molecular-weight fragment class contained, in addition to the resistant DNA, a fraction of relatively high buoyant density (calculated dG + dC content: 61%) containing cleavage sites for the other enzymes used.     

DNA Fingerprinting and Analysis of Population Structure in the Chestnut Blight Fungus, Cryphonectria Parasitica

We analyzed DNA fingerprints in the chestnut blight fungus, Cryphonectria parasitica, for stability, inheritance, linkage and variability in a natural population. DNA fingerprints resulting from hybridization with a dispersed moderately repetitive DNA sequence of C. parasitica in plasmid pMS5.1 hybridized to 6-17 restriction fragments per individual isolate. In a laboratory cross and from progeny from a single perithecium collected from a field population, the presence/absence of 11 fragments in the laboratory cross and 12 fragments in the field progeny set segregated in 1:1 ratios. Two fragments in each progeny set cosegregated; no other linkage was detected among the segregating fragments. Mutations, identified by missing bands, were detected for only one fragment in which 4 of 43 progeny lacked a band present in both parents; no novel fragments were detected in any progeny. All other fragments appeared to be stably inherited. Hybridization patterns did not change during vegetative growth or sporulation. However, fingerprint patterns of single conidial isolates of strains EP155 and EP67 were found to be heterogenous due to mutations that occurred during culturing in the laboratory since these strains were first isolated in 1976-1977. In a population sample of 39 C. parasitica isolates, we found 33 different fingerprint patterns with pMS5.1. Most isolates differed from all other isolates by the presence or absence of several fragments. Six fingerprint patterns each occurred twice. Isolates with identical fingerprints occurred in cankers on the same chestnut stems three times; isolates within the other three pairs were isolated from cankers more than 5 m apart. The null hypothesis of random mating in this population could not be rejected if the six putative clones were removed from the analysis. Thus, a rough estimate of the clonal fraction of this population is 6 in 39 isolates (15.4%).     

Sequence analysis of two yeast mitochondrial DNA fragments containing the genes for tRNA Ser UCR and tRNA Phe UUY.

Two restriction enzyme fragments containing yeast mitochondrial tRNA genes have been characterized by DNA sequence analysis. One of these fragments is 320 base pairs long and contains a tRNA Ser gene. The corresponding tRNA SER was isolated from yeast mitochondria and its nucleotide sequence also was determined. This mitochondrial tRNA is 90 nucleotides in length, has a G + C content of 38%, and has UGA as the anticodon. A portion of a 680-base-pair DNA fragment containing a tRNA Phe gene was also sequenced. The portion of this gene which codes for the mature tRNA is 75 base pairs in length, has a G + C content of 33%, and contains the anticodon GAA. Neither gene contains an intervening sequence or codes for the 3' CCA terminus. Both are surrounded by regions of more than 90% A + T. The significance of these sequences is discussed.     

Restriction site insertion-PCR (RSI-PCR) for rapid discrimination and typing of closely related microbial strains

Taking advantage of point mutations between DNA sequences of closely related microbial strains, PCR primers modified with respect to the target sequence at positions 2-5 near the 3' end were designed to obtain a fragment harbouring an artificial restriction site specific for a given strain. The modified forward primer coupled with a specific reverse primer allows for the amplification of DNA fragments which can be digested with the specific endonuclease only in those strains where the restriction site is inserted by the DNA polymerase. The effectiveness of the method, named restriction site insertion-PCR (RSI-PCR), was tested on isolates of the 'Bacillus cereus group' for the rapid typing and discrimination of these closely related strains.     

PCR fragmentation of DNA

A method has been developed to prepare random DNA fragments using PCR. First, two cycles are carried out at 16 degrees C with the Klenow's fragment and oligonucleotides (random primers) with random 3'-sequences and the 5'-constant part containing the site for cloning with the site-specific endonuclease. The random primers can link to any DNA site, and random DNA fragments are formed during DNA synthesis. During the second cycle, after denaturation of the DNA and addition of the Klenow's fragment, the random primers can link to newly synthesized DNA strands, and after DNA synthesis single-stranded DNA fragments are produced which have a constant primer sequence at the 5'-end and a complementary to it sequence at the 3'-end. During the third cycle, the constant primer is added and double-stranded fragments with the constant primer sequences at both ends are formed during DNA synthesis. Incubation for 1 h at 37 degrees C degrades the oligonucleotides used at the first stage due to endonuclease activity of the Klenow's fragment. Then routine PCR amplification is carried out using the constant primer. This method is more advantageous than hydrodynamic methods of DNA fragmentation widely used for "shotgun" cloning.     

The linkage mapping of cloned restriction fragment length differences in Caenorabditis elegans

Summary The genomic DNA of two closely related strains of the nematode, Caenorhabditis elegans, Bristol (N2), and Bergerac (Bo), has different restriction endonuclease sites (Emmons et al. 1979). Since these two strains interbreed, it is possible to regard the restriction fragment length differences (RFLDs) as mutant variants. The N2 and Bo pattern can be segregated and mapped using clasical genetic techniques.Utilizing a number of genetic markers existing in the N2 strain, we have constructed hybrid populations homozygous for either Bristol or Bergerac over a given chromosomal region with random Bristol-Bergerac composition for the remainder of the genome. Genomic restriction digests from these hybrid populations were probed with random cloned fragments of Bristol DNA. In this way, fragments were mapped to genetically well characterized regions of the C. elegans genome. 27 probes which hybridize to a total of 310 Kb of DNA were found to exhibit six restriction fragment differences. Four of these differences have been mapped, providing probes for four different genomic regions. We have combined classical genetics and recombinant DNA technology to construct linkage maps of cloned DNA fragments using restriction fragment length differences. We are pursuing this approach in order to advance the knowledge of the genetic organization of C. elegans and to provide a means of cloning genes in an organism which provides an experimental model for the study of many biological systems. It is hoped that this approach will also provide a practical solution to some difficult problems in nematode strain identification. Furthermore, the characterization of the families of transposable elements responsible for generating many of the RFLDs will undoubtedly contribute to the understanding of the biological significance of these elements.     

A new pair of M13 vectors for selecting either DNA strand of double-digest restriction fragments

The strategy of shotgun cloning with M13 is based on obtaining random fragments used for the rapid accumulation of sequence data. A strategy, however, is sometimes needed for obtaining subcloned sequences preferentially out of a mixture of fragments. Shotgun sequencing experiments have shown that not all DNA fragments are obtained with the same frequency and that the redundant information increases during the last third of a sequencing project. In addition, experiments have shown that particular fragments are obtained more frequently in one orientation, allowing the use of only one of the two DNA strands as a template for M13 shotgun sequencing. Two new M13 vectors, M13mp8 and M13mp9, have been constructed that permit the cloning of the same restriction fragment in both possible orientations. Consequently, each of the two strands becomes a (+) strand in a pair of vectors. The fragments to be cloned are cleaved with two restriction enzymes to produce a fragment with two different ends. The insertion of such a fragment into the vector can occur only in one orientation. Since M13mp8 and M13mp9 have their array of cloning sites in an antiparallel order, either orientation for inserting a double-digest fragment can be selected by the choice of the vector.     

Nonrandom DNA sequencing of exonuclease III-deleted complementary DNA

The nonrandom DNA sequence analysis procedure of Poncz et al. [Proc. Natl. Acad. Sci. USA 79, 4298-4302 (1982)] was extensively modified to permit the determination of complementary DNA (cDNA) sequences containing G-C homopolymer regions. The recombinant cDNA plasmid was cleaved at a unique restriction enzyme site close to the cDNA and treated with Exonuclease III under controlled conditions to generate a set of overlapping fragments having deletions 50-1500 bases in length at the free 3' termini. After removal of single-stranded DNA regions by Bal31 and DNA polymerase I large fragment, the unique restriction enzyme site was recreated by blunt end ligation of synthetic oligonucleotides to the deleted DNA fragments and restriction enzyme digestion. The cDNA fragment was excised from the cloning vector using a second different restriction enzyme having a unique site that flanks the cDNA fragment and subsequently force-cloned into either M13 mp10 or mp11. This method should also be particularly useful for the sequencing of other types of DNA molecules with lengths 1500 bp or smaller.