Cloning bacterial genes with plasmid gammadv

Amplification of lambda plasmids in Escherichia coli relA mutants

It was previously demonstrated that, contrary to wild-type stringent (rel+) strains of Escherichia coli, in amino acid-starved relaxed (relA) mutants the replication of lambda plasmid proceeds for several hours. The replication leads to amplification of lambda plasmid DNA. Here, the conditions for this amplification have been optimized. The amplification efficiency depends on the temperature as well as on the nature of amino acid starvation, but it is only little or totally not dependent on the pH value of the medium in a range from 6.0 to 8.0. It seems that the most efficient amplification can be achieved by overnight cultivation of E. coli relA arg strain harbouring lambda plasmid at 36-39 degrees C in minimal medium containing Casamino acids. Under these conditions, the copy number of lambda plasmid increases from about 40 to about 300 per cell giving greater than 7-fold amplification.

The pCLIP plasmids: versatile cloning vectors based on the bacteriophage lambda origin of replication

A series of general-purpose plasmid vectors based on the phage lambda origin of replication (ori) has been constructed. Each vector consists of a backbone plasmid encoding chloramphenicol resistance (CmR) and containing a unique HaeII site into which the lacZ alpha-complementing multiple cloning site (MCS) region of an established vector was inserted. To increase the cloning potential of the inserted MCS, superfluous restriction sites in the backbone were removed by a variety of techniques. The vectors, designated pCLIP (for CmR lambda ori integration proficient) plasmids, are of medium copy number and are compatible with most other vectors in common use. A total of 17 unique restriction sites in pCLIP8, pCLIP9, pCLIP18, pCLIP19 and pCLIP23 are available for cloning. As well as possessing the usual properties of vectors, the pCLIP plasmids are able to integrate reversibly into lambda prophage by homologous recombination. Thus, cloned DNA can be maintained in single or multiple copy at will. By integrating recombinant plasmids into appropriate deletion prophages followed by induction, phage::plasmid hybrids are produced which can be manipulated as phage. These properties are demonstrated using a test recombinant plasmid, pCLIPLEU2. The pCLIP vectors are therefore useful for routine plasmid cloning, complementation analysis and applications where the ability to manipulate recombinants in plasmid, phage or prophage forms is advantageous.

Formation of oligomeric structures from plasmid DNA carrying cos lambda that is packaged into bacteriophage lambda heads

Plasmids that carry cos lambda, the region necessary for lambda phage packaging and that are as small as four kilobases in size can be packaged into lambda phage heads in head-to-tail tandem oligomeric structures. Multimeric oligomers as large as undecamers have been detected. Oligomer formation depends upon the products of red and gam of lambda, and the general recombination occurs between different plasmids that share homologous DNA regions. The packaging efficiency of plasmids depends on its copy number in cells and its genome size. Upon injection into a cell, the DNA establishes itself as a plasmid in a tandem structure. When such a plasmid in a high oligomeric structure is used as the source of packaging DNA, the packaging efficiency of the plasmids is elevated. The oligomers are stable in recA cells, whereas they drift toward lower oligomers in recA+ cells.

Expression of prokaryotic genes inserted into ColE1 and pVH51 plasmids

One of the DNA fragments obtained from EcoRI digests of guaA-transducing lambda phage DNA contains the intact bacterial guaA gene at its one end and the lambda phage R gene at the other end. This DNA fragment, named coslambda-guaA, does not contain promoter-operator regions of the gua operon and of the lambda phage R gene, coslambda-guaA DNA fragments were inserted in two different orientations into respective DNAs of EcoRI-cleaved ColE1 and pVH151 (= mini ColE1). Mitomycin C stimulated the guaA enzyme production in the cells harboring the hybrid plasmids with one coslambda-guaA DNA fragment insertion orientation (orientation I), but not the other (orientation II). The lambda-endolysin, product of the lambda phage R gene, was induced by mitomycin C treatment in orientation II, but it was not detected in orientation I. These results suggest that both ColE1 and pVH51 DNAs contain the mitomycin C-responsive promoter which allows transcription of the genes connected with these DNAs.

Construction and properties of hybrid plasmids carrying the E. coli gal operon

A family of hybrid plasmids carrying the entire gal operon of E. coli and designated pgal was constructed in vitro. In the case of pgal 1 (mol. wt. 16.4 Md), a fragment cut by Bam HI endonuclease from lambda gal phage DNA (lambda D-J-gal-att-int) was joined to pMB9 and cloned in the gal-strain of E. coli, which was grown on selective media with galactose as a sole source of carbon. Plasmid pgal2 was derived from pgal 1 by elimination of the 1.1 Md fragment located between the two EcoRI sites and carrying the lambda att-int region and part of pMB9. To obtain pgal3, the 10.7 Md fragment of lambda DNA located between the two SmaI sites (lambda D-J and part of pMB9) in pgal2 was cut out and the resulting flush-end fragments were sealed by the T4DNA ligase. The mol. wt. of pgal3 containing one SmaI site amounted to 4.6 Md, while several pgal3 variants that had lost their SmaI site were still smaller. Plasmid pgal1 inhibited the growth of the gal- host cells, which effect could be overcome by the accompanying helper pMB9. The presence of pgal2 and pgal3 supported the growth and multiplication of gal- cells on selective media even without the helper plasmid. The total amount of pgal plasmid DNA per cell was constant and equalled 60--70 Md (4 copies of pgal1 or 15--16 copies of pgal3, ColE1 or pMB9). This might explain why the co-presence of pMB9 helper does alleviate the "harmful" effects of the plasmid pgal1 (which carries att-int genes), by reducing the copy number of the latter from four to one.

Construction and some properties of packageable plasmid F

A derivative of plasmid F which is packageable in lambda phage coat was constructed using techniques of in vitro recombination. This plasmid is composed of three DNA fragments generated by restriction enzyme EcoRI: a miniF fragment (fragment f5 of F'lac) which is able to replicate autonomously, a DNA fragment from Staphylococcus plasmid that carries the beta-lactamase gene, and a portion of guaA (B) transducing lambda phage DNA carrying lambda cohesive ends (cos site) along with almost all the late genes but devoid of all those genes and sites that are needed for replication, regulation, and recombination. The hybrid plasmid has a molecular weight of 2.7 x 10(7) daltons, about 84% size of lambda phage genome, and can be packaged in lambda coat when helper phage replicates in the plasmid-carrier cell. The packaged plasmid and the helper lambda phage particles are separated by CsCl density gradient centrifugation. The replication characteristics of the recombinant plasmid are all those of F including the copy number, incompatibility, and curing with acidine orange. The packaged plasmid is injected into an F- cell and establishes a plasmid state with normal efficiency. In F+ or Hfr cells, the resident F factor hinders this process.

Cloning of the phr gene and amplification of photolyase in Escherichia coli

A new technique is developed for physically enriching recombinant DNA molecules in an in vitro recombination mixture. UV-irradiation of the donor DNA before recombination enables photoreactivating enzyme (PRE) (deoxyribodipyrimidine photolyase, EC 4.1.99.3) to attach to the donor segments in recombinant molecules. This attached protein causes retention of the recombinant molecules on a nitrocellulose filter, while molecules not containing donor DNA pass through. The bound DNA is repaired of its UV damage and released for insertion into cells by exposure to photoreactivating light in situ, yielding approx. 350-fold enrichment. Although applicable to any gene, this procedure has been used in cloning the Escherichia coli phr gene itself, permitting 100-fold amplification of the gene product in vivo.

Isolation and characterization of a ColE1 plasmid containing the entire bio gene cluster of Escherichia coli K12

ColE1amp plasmids carrying the entire bio gene cluster were constructed in vitro using ColE1amp as the cloning vehicle and a lambda transducing phage, lambdaatt2, as the source of bio DNA. Restriction endonuclease EcoRI digests of ColE1amp and lambdaatt2 DNA were joined by polynucleotide ligase and plasmids bearing the entire bio gene cluster were selected, after transformation, in bio deletion strains of E. coli. Recombinant DNA molecules contained one ColE1amp fragment (7.4 X 10(6) daltons) and one lambdaatt2 DNA fragment (5.4 X 10(6) daltons). Clones carrying ColE1 amp-bio plasmids produce elevated levels of biotin and biotin synthetase activity.

Isolation and characterization of a plaque-forming lambda bacteriophage carrying a ColE1 plasmid

A plaque-forming lambdaimm434 bacteriophage carrying the entire genome of colicinogenic factor E1 has been isolated and characterized. This phage, lambdaimm434ColE1, can lysogenize as a stable plasmid within a recombination-deficient Escherichia coli cell that lacks the normal attachment site for lambda phage. Furthermore, it has been found that lambdaimm434ColE1 phage carrying amber mutations in the O and P genes of the lambda genome, i.e., lambdaimm434OamPamColE1, behaves as a plaque-forming phage, and this finding suggests that the ColE1 factor DNA permits replication of the DNA of the plaque-forming phage.

Expression of the guanine operon of Escherichia coli as analyzed by bacteriophage lambda induced mutations

Studies were made on two guanine-requiring strains of Escherichia coli isolated independently as a result of insertion of prophage gamma into one of the structural genes of the guanine operon. These mutants do not exhibit any detectable guaB function but express the guaA function constitutively at a low level, presumably due to transcription from the pI promoter on the prophage. Various types of plaque-forming gua-transducing phages were generated from these lysogens. The approximate location and the mode of substitution of the gua genes in the phage genome were determined. These results clearly indicate that the gene guaB is located closer to the operator-promoter region of the gua operon than is guaA, and the gene order is "operator"-guaB-guaA.