Presence of one linear and one circular chromosome in the Agrobacterium tumefaciens C58 genome.

Analysis of the entire Agrobacterium tumefaciens C58 genome by pulsed-field gel electrophoresis (PFGE) reveals four replicons: two large molecules of 3,000 and 2,100 kb, the 450-kb cryptic plasmid, and the 200-kb Ti plasmid. Digestion by PacI or SwaI generated 12 or 14 fragments, respectively. The two megabase-sized replicons, used as probes, hybridize with different restriction fragments, showing that these replicons are two independent genetic entities. A 16S rRNA probe and genes encoding functions essential to the metabolism of the organism were found to hybridize with both replicons, suggesting their chromosomal nature. In PFGE, megabase-sized circular DNA does not enter the gel. The 2.1-Mb chromosome always generated an intense band, while the 3-Mb band was barely visible. After linearization of the DNA by X-irradiation, the intensity of the 3-Mb band increased while that of the 2.1-Mb remained constant. This suggests that the 3-Mb chromosome is circular and that the 2.1-Mb chromosome is linear. To confirm this hypothesis, genomic DNA, trapped in an agarose plug, was first submitted to PFGE to remove any linear DNA present. The plug was then recovered, and the remaining DNA was digested with either PacI or SwaI and then separated by PFGE. The fragments corresponding to the small chromosome were found to be absent, while those corresponding to the circular replicon remained, further proof of the linear nature of the 2.1-Mb chromosome.     

Multiple replicons constituting the genome of Pseudomonas cepacia 17616.

Macrorestriction fragment analysis of DNA from Pseudomonas cepacia 17616, in conjunction with Southern hybridization experiments using junction fragments containing rare restriction enzyme sites as probes, indicated that this bacterium contains three large circular replicons of 3.4, 2.5, and 0.9 megabases (Mb). Inclusion of the 170-kb cryptic plasmid present in this strain gave an overall estimate of genome size of 7 Mb. Other Southern hybridization experiments indicated that the three large replicons contained rRNA genes as well as insertion sequence elements identified previously in this strain. The distribution of SwaI, PacI, and PmeI sites on the three replicons was determined. A derivative of Tn5-751 carrying a SwaI site was used to inactivate and map genes on the 2.5- and 3.4-Mb replicons. Mutants were isolated in which the 2.5- and 0.9-Mb replicons had been reduced in size to 1.8 and 0.65 Mb, respectively. The loss of DNA from the 2.5-Mb replicon was associated with lysine auxotrophy, beta-lactamase deficiency, and failure to utilize ribitol and trehalose as carbon and energy sources. DNA fragments corresponding in size to randomly linearized forms of the different replicons were detected in unrestricted DNA by pulsed-field gel electrophoresis. The results provide a framework for further genetic analysis of strain 17616 and for evaluation of the genomic complexities of other P. cepacia isolates.     

Vectors with restriction-site banks. III. Escherichia coli-Saccharomyces cerevisiae shuttle vectors

The bank of unique restriction sites present in plasmid pJRD158 has been incorporated into new vectors carrying selective markers and replicons derived from commonly used Escherichia coli-Saccharomyces cerevisiae shuttle vectors pJDB207 and YRp7. The new vectors pMH158 and pJO158 have 21 and 23 unique restriction sites, respectively, and their complete DNA sequences are known.     

The restriction mapping of c gene deletions in Streptomyces bacteriophage phi C31 and their use in cloning vector development

In addition to 20 previously mapped restriction sites in the DNA of phi C31, we have determined eight sites for SphI, four for EcoRV, and two for SstII; there are none for BglII or SstI. Nine sites were in a 12-kb segment of DNA containing no previously mapped sites. Deletions causing clear-plaque morphology were located in this part of the DNA, in a 3-kb interval between an EcoRV and an SphI site at the centre of the DNA molecule. One of the deletions (delta C3) was obtained in a previously described phi C31c+::vph (viomycin phosphotransferase) derivative containing two PstI sites separated by 3.9-kb of inessential DNA. After in vitro PstI treatment, plaque-forming phages lacking the 3.9-kb fragment were obtained from the c+ phage but not from its delta C3 derivative. Thus a 36.2-kb genome, but not one of 34.4 kb, was able to give infectious virions. PstI-generated DNA fragments of up to 8 kb can be inserted in vitro into the delta C3 derivative with retention of the vph selective marker. With the insertion of a 6.03-kb PstI fragment of plasmid SCP2, the latter phage became a potential vector (with loss of vph) for BamHI-generated DNA fragments of up to 9 kb. In the course of this work, several ClaI sites in phi C31::pBR322 bifunctional replicons were shown to be lost when the DNA was propagated in a dam+ Escherichia coli strain. This will allow the use of such replicons for the cloning of ClaI-generated DNA fragments of up to 6.7 kb.     

DNA replication in Physarum polycephalum: bidirectional replication of DNA within replicons.

The direction of replication of DNA within replicons of Physarum polycephalum was studied by pulse-labelling with 5-bromouracil-deoxyriboside (BrdUrd) and 3H-adenosine deoxyriboside (dAdo), followed by ultraviolet- (UV) -photolysis and analysis of molecular weights of single strand DNA fragments on alkaline sucrose gradients. Newly made DNA within replicons at all stages of completion is split in two equal halves upon UV irradiation when BrdUrd was given at the time of initiation of DNA synthesis. This shows that replication within replicons of Physarum polycephalum starts at an origin located in the center of each unit, proceeding bidirectionally from this origin.     

Cloning of the complete Mycoplasma pneumoniae genome.

The complete genome of Mycoplasma pneumoniae was cloned in an ordered library consisting of 34 overlapping or adjacent cosmids, one plasmid and two lambda phages. The genome size was determined by adding up the sizes of either the individual unique EcoRI restriction fragments of the gene bank or of the XhoI fragments of genomic M. pneumoniae DNA. The values from these calculations, 835 and 849 kbp, are in good agreement. An XhoI restriction map was constructed by identifying adjacent DNA fragments by probing with selected cosmid clones.     

Isolation and complementation of mutants of Anabaena sp. strain PCC 7120 unable to grow aerobically on dinitrogen.

Mutants of Anabaena sp. strain PCC 7120 unable to grow aerobically on dinitrogen were isolated by mutagenesis with UV irradiation, followed by a period of incubation in yellow light and then by penicillin enrichment. A cosmid vector, pRL25C, containing replicons functional in Escherichia coli and in Anabaena species was constructed. DNA from wild-type Anabaena sp. strain PCC 7120 was partially digested with Sau3AI, and size-fractionated fragments about 40 kilobases (kb) in length were ligated into the phosphatase-treated unique BamHI site of pRL25C. A library of 1,054 cosmid clones was generated in E. coli DH1 bearing helper plasmid pDS4101. A derivative of conjugative plasmid RP-4 was transferred to this library by conjugation, and the library was replicated to lawns of mutant Anabaena strains with defects in the polysaccharide layer of the envelopes of the heterocysts. Mutant EF116 was complemented by five cosmids, three of which were subjected to detailed restriction mapping; a 2.8-kb fragment of DNA derived from one of the cosmids was found to complement EF116. Mutant EF113 was complemented by a single cosmid, which was also restriction mapped, and was shown to be complemented by a 4.8-kb fragment of DNA derived from this cosmid.     

The value of electrophoretic fingerprinting and karyotyping in wine yeast breeding programmes

Electrophoretic banding pattens of total soluble cell proteins, DNA restriction fragments and chromosomal DNA were used to characterise ten strains ofSaccharomyces cerevisiae used for commercial production of wine. These fingerprinting procedures provided unique profiles for all the different yeast strains and can therefore be used to identify and control industrial strains. Furthermore, the protein profiles, restriction fragments banding patterns and electrophoretic karyotyping by contour clamped homogeneous electric field electrophoresis (CHEF), were valuable to differentiate hybrid and parental strains in yeast breeding programmes. Hybrid strains, with desirable oenological properties, were obtained by mass spore-cell mating between a heterothallic killer yeast and two homothallic sensitive strains and all were shown to have unique DNA fingerprints and electrophoretic karyotypes.     

Molecular cloning and functional analysis of DNA regions of plasmid RP4 determining the incompatibility properties

Sau3A-generated DNA fragments determining incompatibility functions of the plasmid RP4 were cloned on the vectors pTK16 and pBR322. Inc+ recombinant plasmids were divided into two types: 1) expressing incompatibility only towards the homologous RP4 replicon, 2) expressing incompatibility - both towards the homologous RP4 replicon and towards the heterologous replicons of plasmids R906 and R751. For one member of the first type plasmids it was shown that the cloned Inc+-specific insertion derived from the region of location of the EcoRI restriction site. The majority of the Inc+ recombinant plasmids showed asymmetric expression of incompatibility, predominantly eliminating the resident IncP plasmid.     

Physical and genetic map of the genome of Vibrio parahaemolyticus: presence of two chromosomes in Vibrio species

We constructed a physical map of the genomic DNA (5.1 Mb) for Vibrio parahaemolyticus strain AQ4673 by combining 17 adjacent NotI fragments. This map shows two circular replicons of 3.2 and 1.9 Mb. Pulsed-field gel electrophoresis (PFGE) of undigested genomic DNA revealed two bands of corresponding sizes. Analysis both by NotI digestion and by Southern blot of the two isolated bands confirmed the existence of two replicons. The presence of genes for 16S rRNA on both the replicons indicates that the replicons are chromosomes rather than megaplasmids. The two bands were also seen after PFGE of undigested genomic DNA of V. parahaemolyticus strains other than AQ4673, and of strains belonging to other Vibrio species, such as V. vulnificus, V. fluvialis and various serovars and biovars of V. cholerae. It is noteworthy that V. cholerae O1 strain 569B, a classical biovar, was also shown to have two replicons of 2.9 and 1.2 Mb, which does not agree with a physical map proposed in a previous study. Our results suggest that a two-replicon structure is common throughout Vibrio species.     

Single-stranded replication intermediates of ribosomal DNA replicons of pea.

Replication of ribosomal DNA replicons in cells of Pisum sativum (cv. Alaska) occurs bidirectionally by displacement loops. Replication is initiated on opposite parental strands and nascent chains are elongated moving 5'----3' along each parental template. Replicative intermediates were analyzed by 2-dimensional agarose gel electrophoresis under neutral--neutral and neutral--alkaline conditions. Southern blots of ribosomal DNA fragments separated in the second dimension under neutral conditions show slowly migrating replicative fragments that hybridize with specific probes in a manner consistent with bidirectional replication. The replicative fragments are present in root meristems with cells in S phase; they are absent or few in number in meristems with cells in G2 phase. The following observations indicate that the replicative fragments are single stranded. The apparent length of the replicative fragments is not the same when separated under neutral and alkaline conditions. They contain rDNA without breaks and they do not exhibit the smaller nascent chains expected from replication bubbles and forks. They are not cleaved by restriction enzymes that require duplex DNA as substrate and they are digestible by S1 nuclease.     

Sticky PCR: A PCR-based protocol for targeted protein engineering

This article describes a simple but powerful PCR-based protocol for the generation of cohesive ends on linear DNA fragments, permitting the precise engineering of DNA constructs for a variety of applications. These include the introduction of deletion mutations, domain swapping, creating hybrid DNA fusions, or targeted protein engineering. This novel method can also facilitate the cloning of large or complex DNA fragments into a relevant cloning vector independent of the use of internal restriction endonuclease sites. The protocol involves the amplification of the required fragments by polymerase chain reaction through the use of two sets of overlapping desalted oligonucleotide primers. The subsequent mixing, denaturation and re-annealing of these products present correct cohesive terminal ends for ligation. There is no requirement for special vectors, enzymes or bases, suggesting that this protocol provides a unique way of engineering constructs in a rapid and cost-effective way for specific applications, such as precise deletion or swapping of various domains of the epidermal growth factor receptor to determine their role in membrane localization.     

Construction of a micro-library enriched with genomic replication origins of carrot somatic embryos by laser microdissection.

In this paper, we describe an effective method for constructing a micro-library enriched with chromosomal DNA replication origins. Carrot (Daucus carota L.) somatic embryos at early globular stage were incubated for 15 min in the presence of bromodeoxyuridine (BrdU) to pulse label newly synthesized DNA strands. Nuclei were isolated from the cells, and the DNA was extracted on microscopic slides. DNA fibers spread on slides were visualized using anti-BrdU and FITC-conjugated secondary antibodies. DNA regions where BrdU was incorporated were clearly visualized under a fluorescent microscope as dots on DNA fibers. Regions of DNA fiber containing many fluorescent dots should contain replicons in them. DNA fibers showing many fluorescence dots, or replicons were easily cut and collected using a laser microdissection system equipped with a pulse laser beam. DNA fragments containing many replicons were able to be collected with an efficiency of 20-30 DNA fragments per 1 h. Using degenerate oligonucleotide primed PCR, fragments were randomly amplified from the microdissected fragments, and subcloned to construct a micro-library. This is the first report of the application of a laser microdissection technique for constructing a micro-library enriched with replication origins of chromosomal DNA, although there were some reports on laser microdissection of chromosomes. The simple procedure established here should open up a new application of laser optics.     

A method for the generation of small pre-determined deletions in plasmid DNA: deletion analysis of the tetR region of vector pBR322

A general method is described that allows precise deletion of a chosen restriction fragment(s) from a plasmid having many cleavage sites for that restriction enzyme. The DNA to be deleted is first separated from the rest of the plasmid on a larger DNA fragment contained between two different unique restriction sites. This fragment is then subdigested by the restriction endonuclease of interest, which recognises two or more tetranucleotide (cohesive end or blunt end) sequences on the fragment, and is recloned between the two original unique restriction sites. The method is rapid, efficient, and the results are predictable. Examples are given in which predetermined HpaII (9 bp, 147 bp), TaqI (141 bp) and AluI (15 bp, 403 bp) fragments have been selectively removed from the tetR region of plasmid pBR322.     

Isolation and characterization of genomic clones for two chicken phenobarbital-inducible cytochrome P-450 genes

A cDNA clone specific for a chicken phenobarbital-inducible cytochrome P-450 was used to screen a chicken genomic library. Twenty-nine clones were isolated, restriction mapped, and divided into two non-overlapping groups. The cDNA clone hybridized to 12 kilobases of DNA from both groups. Both groups contained restriction fragments which hybridized to both 5' and 3' fragments of the cDNA clone, and it was concluded that the two groups were derived from two separate genes. Southern transfer analysis of individual chicken DNAs and quantitative hybridization analysis indicated that these two genes are independent and are present as single copies/haploid genome. Comparison of restriction digests of the cloned DNAs and total genomic DNA discounted the possibility that other closely related P-450 genes are present in the chicken genome.     

Organization of the yeast ribosomal RNA gene cluster via cloning and restriction analysis.

The restriction endonuclease EcoR1 cleaves Saccharomyces cerevisiae DNA, which codes for ribosomal RNA (rRNA), into seven fragments, A second restriction endonuclease, HindIII, cleaves the same yeast ribosomal DNA into two fragments. These two restriction enzymes each yield DNA segments that total about 5.9 megadaltons. The "repeat unit" of the yeast genes coding for rRNA is thus about 5.9 megadaltons or about 9000 base pairs long. The two HindIII-cleaved DNA fragments as well as one of the EcoR1-cleaved DNA fragments were purified and amplified by cloning in Escherichia coli. Three of the seven EcoR1-generated DNA fragments could then be ordered by treating the two cloned HindIII DNA fragments with EcoR1. This led the assignment of the two HindIII restriction sites. The various restriction DNA fragments were hybridized directly from the gel utilizing 32P-labeled 5 S, 5.8 S, 18 S, and 25 S rRNA. Identification of the various DNA restriction segments then led to the final ordering of the DNA fragments. The gene coding for the 5 S RNA is adjacent to the gene coding for the 35 S precursor rRNA. These two groups of genes thus occur as a cluster in the following sequence: [5 S-spacer]-[spacer-18 S-5.8 S-25 S-spacer]-[spacer-5 S]. The actual map of the DNA restriction fragments is presented.     

A simple method for sequencing small DNAs by introducing precise overlapping ends into restriction digestion fragments.

A method has been devised whereby certain complete restriction digestions can have short overlaps of unique sequence incorporated into the fragments during cloning. Thus one can identify when the DNA fragments are contiguous. Here, this technique is used to produce a contig for a 2.5 kb fragment of genomic DNA. This is a simple approach to ordering digestion fragments without necessarily performing restriction mapping. It is envisaged that this technique will be useful for sequencing cDNAs and small genomic fragments.     

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.     

Genomic typing of Escherichia coli O157:H7 by semi-automated fluorescent AFLP analysis

Escherichia coli serotype O157:H7 isolates were analyzed using a relatively new DNA fingerprinting method, amplified fragment length polymorphism (AFLP). Total genomic DNA was digested with two restriction endonucleases (EcoRI and MseI), and compatible oligonucleotide adapters were ligated to the ends of the resulting DNA fragments. Subsets of fragments from the total pool of cleaved DNA were then amplified by the polymerase chain reaction (PCR) using selective primers that extended beyond the adapter and restriction site sequences. One of the primers from each set was labeled with a fluorescent dye, which enabled amplified fragments to be detected and sized automatically on an automated DNA sequencer. Three AFLP primer sets generated a total of thirty-seven unique genotypes among the 48 E. coli O157:H7 isolates tested. Prior fingerprinting analysis of large restriction fragments from these same isolates by pulsed-field gel electrophoresis (PFGE) resulted in only 21 unique DNA profiles. Also, AFLP fingerprinting was successful for one DNA sample that was not typable by PFGE, presumably because of template degradation. AFLP analysis, therefore, provided greater genetic resolution and was less sensitive to DNA quality than PFGE. Consequently, this DNA typing technology should be very useful for genetic subtyping of bacterial pathogens in epidemiologic studies.     

Total synthesis of multi-kilobase DNA sequences from oligonucleotides

A method for synthesizing DNA from 40-mer oligonucleotides, which we used to generate a 32-kb DNA fragment, is explained. DNA sequences are synthesized as approximately 500 bp fragments (synthons) in a two-step PCR reaction and cloned using ligation-independent cloning (LIC). Synthons are then assembled into longer full-length sequences in a stepwise manner. By initially synthesizing smaller fragments (synthons), the number of clones sequenced is low compared with synthesizing complete multi-kilobase DNA sequences in a single step. LIC eliminates the need for purification of fragments before cloning, making the process amenable to high-throughput operation and automation. Type IIs restriction enzymes allow seamless assembly of synthons without placing restrictions on the sequence being synthesized. Synthetic fragments are assembled in pairs to generate the final construct using vectors that allow selection of desired clones with two unique antibiotic resistance markers, and this eliminates the need for purification of fragments after digestion with restriction endonucleases.