Detection of nonintegrated plasmid deoxyribonucleic acid in the folded chromosome of Escherichia coli: physiochemical approach to studying the unit of segregation.

Physiocochemical evidence presented indicates plasmid deoxyribonucleic acid (DNA) can associate with host chromosome without linear insertion of the former into the latter. This conclusion is based on the observation that covalently closed circular (CCC) plasmid DNA can cosediment with undegraded host chromosome in a neutral sucrose gradient. When F plus bacteria are lysed under conditions that preserve chromosome, approximately 90% of CCC F sex factor plasmid (about 1% of the total DNA) is found in folded chromosomes sedimenting at rates between 1,500 and 4,000s. The remaining 10% of the CCC F DNA sediments at the rate (80S) indicative of the free CCC plasmid form. Reconstruction experiments in which 80S, CCC F DNA is added to F plus or F minus bacteria before cell lysis show that exogenous F DNA does not associate with folded chromosomes. In F plus bacteria, F plasmid is harbored at a level of one or two copies per chromosomal equivalent. In bacteria producing colicin E1, the genetic determinant of this colicin, the Col E1 plasmid, is harbored at levels of 10 to 13 copies per chromosomal equivalent; yet, greater than 90% of these plasmids do not cosediment with the 1,800S species of folded chromosome. However, preliminary evidence suggests one or two Col E1 plasmids may associate with the 1,800S folded chromosome. Based on evidence presented in this and other papers, we postulate F plasmid can link to folded chromosome because the physicochemical structure of the plasmid resembles a supercoiled region of the chromosome and, therefore, is able to interact with the ribonucleic acid that stabilizes the folded chromosome structure. Implications of this model for F plasmid replication and segregation are discussed.     

Association of R6K plasmid replicative intermediates with the folded chromosome of Escherichiacoli

When $\text{Escherichia}\text{coli}$ strain CSH50(R6K) is lysed so as to preserve the folded chromosome structure approximately 9 of the 11 R6K molecules maintained per chromosomal equivalent cosediment with the host nucleoid on a neutral sucrose gradient; the remaining 2 plasmids sediment at their normal rate. When cells are briefly labeled with [³H]thymidine, the majority of plasmid replicative intermediates and nascent mature plasmids are found in the plasmid subpopulation that cosediments with host folded chromosomes. This finding suggests that plasmid replication occurs in a restricted cellular locus, perhaps even while in association with its host's folded chromosome.     

Nonintegrated plasmid-folded chromosome complexes: genetic studies on formation and possible relationship to plasmid replication.

When folded chromosomes are purified from plasmid-containing bacteria, a reproducible fraction of the host's covalently closed, circular (CCC) plasmid DNA copurifies with the chromosomes. From this copurification, we infer the existence of nonintegrative plasmid-chromosome (NPC) complexes. Previously, we noted that plasmids dependent on DNA polymerase III and with stringent control of replication complex to a greater extent than plasmids dependent on DNA polymerase I and with relaxed control of replication. We have examined this subject in more depth and find that: (i) The composite plasmids formed by in vitro recombination of a “stringent” with a “relaxed” replicon complex to chromosomes at the frequency of the component replicon which directs replication; (ii) all of the detectable replicative intermediates, but only 25% of the CCC forms, of plasmid ColE1 complex to chromosome; and (iii) when a mini-F plasmid is deleted for the DNA sequences which include the primary origin of replication, the complexing frequency decreases 30 to 40%. We conclude from these findings that NPC complexes either indirectly or directly relate to plasmid replication. Further, we find that the EcoRI kan⁺ fragments of pML31 and the ampicillin resistance transposon, Tn3, promote complexing of both ColE1 and mini-F plasmids to host chromosomes. The biological significance of this latter complexing is unknown. However, we conclude from these studies and from point (iii) that complexing is determined in part by unique plasmid sequences.     

A novel type of E. coli mutants with increased chromosomal copy number

We have isolated E. coli mutants which can grow at 30 degrees C but not at 42 degrees C and are able to harbor the oriC plasmid (minichromosome) at a higher copy number than the parental wild-type strain at the permissive temperature. The mutants were found to contain higher amounts of chromosomal DNA per mg protein than the wild-type, whether or not they harbor the plasmid. Experimental results suggest that the higher amount of chromosomal DNA is due to a higher copy number of chromosomes and not to a larger amount of DNA per chromosome. These properties in each of the mutants are caused by a single mutation at the rpoB or rpoC gene that code for the beta or beta' subunit of RNA polymerase, respectively. The mutations are thought to affect the regulation of replication of oriC-bearing replicons, that is, the E. coli chromosome and oriC plasmids, but not the miniF plasmid.     

Isolation and characterization of Pseudomonas putida R-prime plasmids

A number of enhanced chromosome mobilizing (ECM) plasmids derived from the wide host range plasmid R68 have been used to construct R-prime plasmids carrying a maximum of two map minutes of the Pseudomonas putida PPN chromosome, using Pseudomonas aeruginosa PAO as the recipient. For one ECM plasmid, pMO61, the ability to form R-primes did not correlate with the ability to mobilize chromosomes in intrastrain crosses, suggesting that different mechanisms are involved. Physical analysis of one R-prime showed that 3.5 kb of chromosomal DNA had been inserted between the tandem IS21 sequences carried by the parent ECM plasmid.     

Method for obtaining more-accurate covalently closed circular plasmid-to-chromosome ratios from bacterial lysates by dye-buoyant density centrifugation.

A method that gives high recovery of deoxyribonucleic acid (DNA) from crude bacterial lysates using ethidium bromide-cesium chloride density gradient centrifugation is presented. After Pronase digestion and shearing of the lysate, essentially 100% recovery of chromosomal DNA and a reproducible recovery of covalently closed circular (CCC) plasmid DNA is obtained for a specific plasmid in a given strain. This method should be useful for comparing the CCC plasmid/chromosome ratio of various plasmid-host combinations.     

Isolation and characterization of Escherichia coli chromosomal mutants affecting plasmid copy number.

We have isolated chromosomal mutants of an Escherchia coli K-12 strain that maintain higher levels of an F' plasmid. The mutants are designated as plasmid copy number (pcn) mutants. They were detected by selecting for increased lactose fermentation in bacteria deleted for the lac operon but harboring an F'lacI,P pro+ plasmid. When examined for the amount of F' plasmid deoxyribonucleic acid (DNA) by the dye-CsCl isopycnic technique, the mutants show two to seven times as much covalently closed, circular (CCC) DNA as does the parental strain. The increased plasmid level in one mutant strain (pcn-24) was confirmed by DNA-DNA hybridization; however, this latter technique indicated about a twofold lower increase when compared with the increase measured for pcn-24 by the dye-CsCl technique. In mutant pcn-24 the increased amount of F' DNA reflects a proportional increase in monomeric-size plasmid molecules because oligomeric forms are not found. Also, in mutant pcn-24 the extra CCC plasmid copies do not seem to be randomly distributed throughout the cell's cytoplasm but appear complexed in situ with their host's folded chromosome. In all pcn mutants examined to date, the classical sex factor F is maintained at normal levels, whereas the viral plasmid Pl CM is maintained at two to three times the normal level. In all 17 pcn mutants isolated, the pcn mutation maps on the chromosome and not on the plasmid. Finally, the absolute amount of CCC F' DNA detectable in lysates of the six different pcn mutants examined decreased 50 to 90% upon incubation of the lysate at 37 C. In contrast, no loss of CCC DNA occurs when lysates of the parental F' strain are incubated at 37 C.     

Construction of plasmids integrating into the Bacillus subtilis chromosome through homologous recombination and their use as integration vectors

We constructed a number of plasmids which integrate into the chromosome of Bacillus subtilis through homology recombination. Plasmids consist of pBR322 replicon, different fragments of Bac. subtilis chromosomal DNA, Cm resistance marker from pBD64 plasmid. Frequency of transformation was 10(-4) per bacterial cell. Foreign DNA (genes for tryptophan metabolism of Bac. mesentericus) was introduced into the chromosome of Bac. subtilis with the help of these plasmids.     

Plasmid transfer from Streptomyces to Mycobacterium smegmatis by spontaneous transformation

Hybrids of the Streptomyces coelicolor conjugative plasmid SCP2* and the Mycobacterium plasmid pAL5000 were transferred from Streptomyces coelicolor or Streptomyces lividans to Mycobacterium smegmatis mc2155 in plate crosses. Inactivation of the SCP2* transfer function did not prevent or reduce plasmid transfer. This transfer was DNase I sensitive and thus involved release of DNA from Streptomyces, followed by transformation of M. smegmatis. M. smegmatis growing on specific solid media was also transformed by pure CCC and linear plasmid DNA. Small plasmids were taken up intact but large plasmids suffered deletions. Competence developed within 24 h of incubation at 30 degrees C or 37 degrees C, and up to 400 transformants were obtained per microg of CCC plasmid DNA. Transformation frequencies were higher when M. smegmatis was co-cultivated with plasmid-free Streptomyces, but unaffected by resident homologous sequences or inactivation of recA in M. smegmatis. Spontaneous transformation was also observed with a circular Streptomyces transposable element which inserted into chromosomal sites. Transformative plasmid transfer was also shown to occur between M. smegmatis strains. This is the first report of non-artificially induced, spontaneous plasmid transformation in Mycobacterium.     

Biochemical Studies of Two Bacillus pumilus Plasmids

Bacillus pumilus NRS 576 harbored an estimated two copies per chromosome of a covalently closed, circular (CCC) deoxyribonucleic acid (DNA) molecule, the 576 plasmid. The 576 plasmid has a buoyant density of 1.698 g/cm(3) and a molecular weight of about 28 x 10(6). Plasmid copy number remained about the same in both exponentially growing and stationary-phase cells. Spontaneous variants of NRS 576 that formed spores at an elevated frequency were designated as W mutants. W mutants appeared to have lost the 576 plasmid on the basis of the following: W mutants (38 tested) lacked detectable CCC DNA, and the majority of the plasmid homologous sequences in bulk NRS 576 DNA were absent from bulk W mutant DNA. B. pumilus ATCC 7065 harbored at least 10 copies per chromosome of a CCC DNA element, the 7065 plasmid. The 7065 plasmid has a buoyant density of 1.696 g/cm(3) and a molecular weight of about 6 x 10(6). Although the copy number of the plasmid appeared to remain the same in exponentially growing and stationary-phase cells, an additional CCC form of higher molecular weight was detected in stationary-phase cells.     

Plasmid profiles and restriction fragment length polymorphism of Rhizobium leguminosarum bv. viciae in field populations

Abstract 56 isolates of Rhizobium leguminosarum biovar viciae from one field were characterized by analysis of plasmid profile, total DNA restriction pattern and restriction fragment length polymorphism (RFLP) of 2 chromosomal regions and of symbiotic (Sym) plasmid. Different levels of similarity exist in patterns generated by the different techniques. At the level of partial similarity these techniques give comparable results for more than 80% of the isolates, with the exception of RFLP profiling with the Sym probe. Analysis at this level allows the grouping of the isolates that have most of their non-Sym genome similarly organized. At the level of total similarity, the techniques are no more equivalent and provide complementary information on possible evolution of the different elements of the genome identified by each specific technique. The non-Sym plasmids defining classes were strongly associated with specific chromosomal backgrounds. In contrast, variations in Sym plasmids were not related with variations in the remaining genome. Host range towards chromosomes was variable among the Sym plasmids, which may reflect plasmid transfer between strains.     

Plasmid vector for cloning in Streptococcus pneumoniae and strategies for enrichment for recombinant plasmids

A new plasmid, pLS101, was constructed for use as a vector for cloning in Streptococcus pneumoniae. This plasmid carries two selectable genes, tet and malM, each of which contains two or more restriction sites for cloning. Insertional inactivation of the malM gene allowed direct selection of TcRMal- clones containing recombinant plasmids. Other means of enriching a recipient population for cells containing recombinant plasmids were examined. The effect of removing vector terminal phosphate in attempts to clone heterogeneous DNA fragments, such as those from chromosomal DNA, was to abolish recombinant plasmid establishment altogether, presumably because donor DNA processing during entry into the cell prevented establishment of the hemiligated molecule. However, with homogeneous DNA fragments, such as those from plasmid or viral DNA, vector phosphate removal allowed enrichment for recombinant plasmids. In the cloning of heterogeneous DNA that was homologous to the recipient chromosome (i.e. chromosomal DNA from S. pneumoniae), recovery of recombinant plasmids could be enriched tenfold (relative to the regenerated vector) by the process of chromosomal facilitation of plasmid establishment. This involved an additional passage of the mixed plasmids in which interaction with the chromosome of plasmids containing chromosomal DNA inserts (i.e. recombinant plasmids) increased their frequency of establishment relative to the vector plasmid. An overall strategy for cloning in S. pneumoniae, depending on the nature of the fragment to be cloned, is proposed.     

The fibrous structure of human chromosomes in relation to rearrangements and aberrations; a theoretical consideration.

Human chromosomes as a type-sample for mammalian chromosomes consist of 200-A fibers, folded to chromomeres, which are interconnected by about a dozen longitudinal fibers. The average fiber at both interphase and metaphase contains 28.3 lengths of one double helix of DNA per length of fiber. The orientation of DNA imparts polarity to the fiber and thus to the chromosome and is an important constraint in concepts of chromosomal aberrations and rearrangements, some of which are being interpreted on the basis of fiber-fiber exchanges. Chromosomal rearrangements discernible by light microscopy are not likely to be fully synonymous with change in gene sequence. Chromosomes are considered to possess a plane of symmetry originating from semiconservative replication. Implications for chromosomal structure, centromeric function, and chromatid cohesion are discussed. Fibers connecting one chromosome to others are discussed in light of the proposal that fiber regions of repeated nucleotide sequences exist that facilitate fiber-fiber exchanges. No free fiber or DNA ends are thought to occur at any time in the nucleus.     

Plasmid and chromosomal DNA replication and partitioning during the Caulobacter crescentus cell cycle

Cell division in Caulobacter crescentus yields a swarmer and a stalked cell. Only the stalked cell progeny is able to replicate its chromosome, and the swarmer cell progeny must differentiate into a stalked cell before it too can replicate its chromosome. In an effort to understand the mechanisms that limit chromosomal replication to the stalked cell, plasmid DNA synthesis was analyzed during the developmental cell cycle of C. crescentus, and the partitioning of both the plasmids and the chromosomes to the progeny cells was examined. Unlike the chromosome, plasmids from the incompatibility groups Q and P replicated in all C. crescentus cell types. However, all plasmids tested showed a ten- to 20-fold higher replication rate in the stalked cells than the swarmer cells. We observed that all plasmids replicated during the C. crescentus cell cycle with comparable kinetics of DNA synthesis, even though we tested plasmids that encode very different known (and putative) replication proteins. We determined the plasmid copy number in both progeny cell types, and determined that plasmids partitioned equally to the stalked and swarmer cells. We also reexamined chromosome partitioning in a recombination-deficient strain of C. crescentus, and confirmed an earlier report that chromosomes partition to the progeny stalked and swarmer cells in a random manner that does not discriminate between old and new DNA strands.     

Saccharomyces cerevisiae centromere CEN11 does not induce chromosome instability when integrated into the Aspergillus nidulans genome.

We constructed Aspergillus nidulans transformation plasmids containing the A. nidulans argB+ gene and either containing or lacking centromeric DNA from Saccharomyces cerevisiae chromosome XI (CEN11). The plasmids transformed an argB Aspergillus strain to arginine independence at indistinguishable frequencies. Stable haploid transformants were obtained with both plasmids, and strains were identified in which the plasmids had integrated into chromosome III by homologous recombination at the argB locus. Plasmid DNA was recovered from a transformant containing CEN11, and the sequence of the essential portion of CEN11 was determined to be unaltered. The transformants were further characterized by using them to construct heterozygous diploids and then testing the diploids for preferential loss of the plasmid-containing chromosomes. The CEN11 sequence had little or no effect on chromosome stability. Thus, CEN11 does not prevent chromosomal integration of plasmid DNA and probably lacks centromere activity in Aspergillus spp.     

Linear- and circular-plasmid copy numbers in Borrelia burgdorferi.

Borrelia burgdorferi, the Lyme disease agent, and other members of the spirochetal genus Borrelia have double-stranded linear plasmids in addition to supercoiled circular plasmids. The copy number relative to the chromosome was determined for 49- and 16-kb linear plasmids and a 27-kb circular plasmid of the type strain, B31, of B. burgdorferi. All three plasmids were present in low copy number, about one per chromosome equivalent, as determined by relative hybridizations of replicon-specific DNA probes. The low copy number of Borrelia plasmids suggests that initiation of DNA replication and partitioning are carefully controlled during the cell division cycle. The copy numbers of these three plasmids of strain B31 were unchanged after approximately 7,000 generations in continuous in vitro culture. A clone of B. burgdorferi B31 that did not contain the 16-kb linear plasmid was obtained after exposure of a culture to novobiocin, a DNA gyrase inhibitor. The plasmid-cured strain contains only one linear plasmid, the 49-kb plasmid, and thus has the smallest genome reported to date for B. burgdorferi.     

Properties and transforming activities of two plasmids in Streptococcus pneumoniae

Summary Two plasmids from group B streptococcus were introduced into pneumococcus (Streptococcus pneumoniae) and examined for copy number, stability, and some features of the process by which they transform pneumococcal recipients. The 3.6 Mdal pMV158 (tet) was present at a minimum of 12 to 16 copies per chromosome and was never observed to be cured. The 20 Mdal pIP501 (cat erm) had a minimum copy number of 3 to 4 per chromosome and was lost spontaneously at a frequency near 0.03 per division. The presence of novobiocin increased this frequency 2 to 3-fold. Competence for chromosomal transformation and the membrane endonuclease needed for normal DNA entry were required for plasmid transformation. Plasmid transformants segregated transformed cells one generation ahead of chromosomal transformants. Both single and multiple hit components of the transformation reaction kinetics were observed, but the latter could not be seen in the presence of competing chromosomal DNA. The majority of the transforming activity behaved as covalently closed circular DNA in dye-buoyancy gradients. Although most of the activity for both plasmids sedimented in sucrose gradients more rapidly than did monomeric closed circular DNA, a significant fraction was found at a position suggesting that it may have been due to monomeric plasmids.     

Relationship of R6K replicating forms to the folded chromosome of Escherichia coli.

An examination of the relationship of both nonreplicating and replicating forms of R6K plasmid DNA to the Escherichia coli folded chromosome showed that both forms cosediment with the chromosome in neutral sucrose gradients. Approximately 20% of the nonreplicatin molecules was found as freely sedimenting forms when the folded-configuration of the chromosomes was preserved. However, under the same conditions negligible amounts of the replicating forms were found as freely sedimenting molecules. Thus, it is concluded that the replicating forms, when compared with nonreplicating molecules, are preferentially associated with the folded chromosomal structure. Exposure of the folded chromosomal structure to RNase resulted in an unfolding of the chromosome and a concomitant increase in the amount of freely sedimenting replicating and nonreplicating forms of R6K DNA. Analyses of the single-stranded length of RNase-released nascent molecules suggest that they replicate in continuous association with the folded chromsome complex. Nonenzymatic unfolding of the chromosomes by progressively lowering the sodium ion concentration during lysis resulted in a progressive increase in the release of nonreplicating molecules. Replicating molecules wer not released by unfolding the chromosome in this fashion.     

DNA packaging by the Bacillus subtilis defective bacteriophage PBSX.

Defective bacteriophage PBSX, a resident of all Bacillus subtilis 168 chromosomes, packages fragments of DNA from all portions of the host chromosome when induced by mitomycin C. In this study, the physical process for DNA packaging of both chromosomal and plasmid DNAs was examined. Discrete 13-kilobase (kb) lengths of DNA were packaged by wild-type phage, and the process was DNase I resistant and probably occurred by a head-filling mechanism. Genetically engineered isogenic host strains having a chloramphenicol resistance determinant integrated as a genetic flag at two different regions of the chromosome were used to monitor the packaging of specific chromosomal regions. No dramatic selectivity for these regions could be documented. If the wild-type strain 168 contains autonomously replicating plasmids, especially pC194, the mitomycin C induces an increase in size of resident plasmid DNA, which is then packaged as 13-kb pieces into phage heads. In strain RB1144, which lacks substantial portions of the PBSX resident phage region, mitomycin C treatment did not affect the structure of resident plasmids. Induction of PBSX started rolling circle replication on plasmids, which then became packaged as 13-kb fragments. This alteration or cannibalization of plasmid replication resulting from mitomycin C treatment requires for its function some DNA within the prophage deletion of strain RB1144.