Enteric Chromosomal Islands: DNA Packaging Specificity and Role of λ-like Helper Phage Terminase.

The phage-inducible chromosomal islands (PICIs) of Gram-negative bacteria are analogous to defective prophages that have lost the ability to propagate without the aid of a helper phage. PICIs have acquired genes that alter the genetic repertoire of the bacterial host, including supplying virulence factors. Recent work by the Penadés laboratory elucidates how a helper phage infection or prophage induction induces the island to excise from the bacterial chromosome, replicate, and become packaged into functional virions.

The product of the bacteriophage lambda W gene: purification and properties.

Gene W is one of the 10 genes that control the morphogenesis of the bacteriophage lambda head. The morpho genesis of the phage lambda head proceeds through the synthesis of an intermediate assembly called the prohead. This is an empty shell into which the bacteriophage DNA is introduced--packaged--by the phage enzyme DNA terminase.

The bacteriophage lambda DNA packaging enzyme: identification of four structural domains of the gpNu1 subunit using limited proteolysis.

Lambda DNA terminase, the enzyme that cleaves virion-length chromosomes from multigenomic concatemers and packages them into the bacteriophage head, is composed of two subunits, gpNu1 and gpA. Direct determination of the structure of gpNu1, the smaller subunit, has not been possible because of its insolubility in aqueous solutions. Therefore, to identify smaller and potentially water-soluble domains of gpNu1, we analyzed the nature of the products obtained by limited digestion of the protein with several proteases.

Thermodynamic and functional characterization of protein W from bacteriophage lambda. The three C-terminal residues are critical for activity.

Gene product W (gpW), the head-tail joining protein from bacteriophage lambda, provides a fascinating model for studying protein interactions. Composed of only 68 residues, it must interact with at least two other proteins in the phage, and probably with DNA. To study the structural and functional properties of gpW, plasmids were constructed expressing gpW with hexahistidine tag sequences at either the N or C terminus.

Mutations in the terminase genes of bacteriophage lambda that bypass the necessity for FI.

DNA maturation in bacteriophage lambda is the process by which the concatemeric precursor DNA is cleaved at sites called cos to generate mature lambda DNA molecules. These DNA molecules are then packaged into procapsids, the empty capsid precursors. The enzyme that catalyses these events is lambda DNA terminase.

Mutations of the coat protein gene of bacteriophage lambda that overcome the necessity for the Fl gene; the EFi domain.

The functions of most of the 10 genes involved in phage lambda capsid morphogenesis are well understood. The function of the FI gene is one of the exceptions. Mutants in FI fail to mature and package DNA.

Structural transitions during maturation of bacteriophage lambda capsids.

The three-dimensional structures of the procapsid and of the mature capsid of bacteriophage lambda were determined to a resolution of approximately 3.4 nm by cryo-electron microscopy and image processing. The mature lambda capsid contains two major proteins, gpE and gpD, arranged on a T = 7 lattice, with gpE arranged as hexamers and pentamers and gpD arranged as trimers.

Identification of USF as the ubiquitous murine factor that binds to and stimulates transcription from the immunoglobulin lambda 2-chain promoter.

To study the specificity and identity of NF-lambda 2, a ubiquitous murine nuclear factor that interacts specifically with the promoter of the lambda 2-chain gene and stimulates its transcription, competition experiments were carried out using DNA fragments from various immunoglobulin regulatory elements. The results showed that a fragment containing the H-chain enhancer competed efficiently for the binding of NF-lambda 2. Dissection of the H-chain enhancer revealed that the microE3 motif contributed the competing ability.

The purification and properties of the scaffolding protein of bacteriophage lambda.

The Nu3 gene of bacteriophage lambda resides within a cluster of genes that specify structural components of the bacteriophage head. Previous experiments indicate that the Nu3 gene product (gpNu3) is associated with immature proheads but is not detectable in mature proheads or bacteriophage particles, hence its classification as a scaffolding protein. The Nu3 gene has been cloned and overexpressed, and its protein product has been purified.

Isolation and characterization of mutations in the bacteriophage lambda terminase genes.

The terminase enzyme of bacteriophage lambda is a hetero-oligomeric protein which catalyzes the site-specific endonucleolytic cleavage of lambda DNA and its packaging into phage proheads; it is composed of the products of the lambda Nul and A genes. We have developed a simple method to select mutations in the terminase genes carried on a high-copy-number plasmid, based on the ability of wild-type terminase to kill recA strains of Escherichia coli. Sixty-three different spontaneous mutations and 13 linker insertion mutations were isolated by this method and analyzed.

Production of lambda-phi 29 phage chimeras.

Proheads of bacteriophage lambda which carry the connector of phage phi 29 instead of that of lambda have been produced in vitro. These hybrid proheads have a structure similar to that of normal lambda proheads. Furthermore, the chimeric proheads can package both lambda and phi 29 DNA.

Interaction of a nuclear protein with a palindromic sequence of the mouse immunoglobulin lambda 2-chain gene promoter is important for its transcription.

By using a gel mobility retardation assay, we detected the formation of three major complexes from the binding of nuclear proteins to the promoter of the immunoglobulin lambda 2-chain gene. Two of the complexes were generated by the presence of an unidentified nuclear factor(s) called herein NF-lambda 2. Although the sequences between lambda 2- and lambda 1-chain gene promoters are very similar, the lambda 1-chain promoter did not compete for the binding of NF-lambda 2 efficiently.

Analysis of the expression of murine lambda genes transfected into immunocompetent cell lines.

Hybridoma cell lines were transfected with plasmids containing either a rearranged lambda 1 or a rearranged lambda 2 mouse gene. The levels of lambda-chains synthesized by these transfectants were very low or undetectable. Activation of the expression of the lambda 2 gene was achieved artificially by deleting a portion of the region upstream of the promoter.

The interaction of E. coli integration host factor and lambda cos DNA: multiple complex formation and protein-induced bending.

The interaction of E. coli's integration Host Factor (IHF) with fragments of lambda DNA containing the cos site has been studied by gel-mobility retardation and electron microscopy. The cos fragment used in the mobility assays is 398 bp and spans a region from 48,298 to 194 on the lambda chromosome.

Expression of an immunoglobulin kappa light-chain gene in lymphoid cells using a bovine papillomavirus-1 (BPV-1) vector.

Bovine papillomavirus-1 (BPV-1) replicates extrachromosomally in certain murine cell lines, suggesting that vectors based on the BPV-1 replicon might provide a means of obtaining more uniform gene expression among independent transformants. We have tested such a vector for the expression in hybridoma cells of the immunoglobulin kappa light-chain gene, but found that the level of expression varies greatly among transformants. Our results also indicate that in these transformants the vector has probably been incorporated into chromosomal DNA.

Lethal effect of lambda DNA terminase in recombination deficient Escherichia coli.

lambda DNA terminase is the enzyme that catalyses the cleavage of lambda DNA concatemers into genome-size molecules and packages them into the capsid. The cleavage (DNA maturation) takes place in a specific site in the phage DNA called cos. Either one of two Escherichia coli proteins, integration host factor (IHF) and terminase host factor (THF), is required, in addition to terminase, for maturation of wild-type lambda DNA in vitro.

Bacteriophage lambda DNA packaging. The product of the FI gene promotes the incorporation of the prohead to the DNA-terminase complex.

Lambda DNA packaging in vitro can be examined in stages. In a first step, lambda DNA interacts with terminase to form a DNA-enzyme complex, called complex I. Upon addition of proheads, in a second step, a ternary complex, complex II, containing DNA, terminase and the prohead is formed.

The control of lambda DNA terminase synthesis.

Nu1 and A, the genes coding for bacteriophage lambda DNA terminase, rank among the most poorly translated genes expressed in E. coli. To understand the reason for this low level of translation the genes were cloned into plasmids and their expression measured.

The overproduction of DNA terminase of coliphage lambda.

An artificial operon containing the genes coding for the two subunits of lambda DNA terminase, Nul and A, has been constructed. Derivatives of plasmid pBR322 served as the cloning vehicles. The transcription is driven by the pL promoter of phage lambda, and translation of the terminase genes was made efficient by the replacement of the wild-type ribosome-binding sites for those of lambda genes cII and/or D.

Synthesis of a trans-acting inhibitor of DNA maturation by prohead mutants of phage lambda.

Bacteriophage lambda with mutations in genes that control prohead assembly and other head precursors cannot mature their DNA. In this paper we present evidence that the failure of these phage mutants to mature DNA is a reflection of a mechanism that modulates terminase nicking activity during normal phage development. We have constructed plasmids that contain the lambda-cohesive end site (cos) and the genes that code for DNA terminase, the enzyme that matures DNA by cutting at cos.

A region of the immunoglobulin-mu heavy chain necessary for forming pentameric IgM.

In order to define the molecular requirements for IgM pentamer formation, we have isolated several mutant hybridomas which produce predominantly monomeric IgM. For one such mutant, 102, we synthesized a cDNA clone of its mu-mRNA, and found an in-frame 39-bp deletion, which thus encodes a mu-chain lacking amino acids 550-562, a region spanning the fourth constant domain and the tail of the mu-chain. To prove that this deletion is sufficient to block pentamer formation, we used site-directed mutagenesis to construct a mu-gene lacking these 39 bp, and have shown that the expression of this altered mu-gene results in the production of monomeric IgM.

Analysis of hybridoma mutants defective in synthesis of immunoglobulin M.

Hybridoma mutants defective in the expression of IgM have been analyzed by molecular and somatic cell hybridization techniques. The frequency of kappa light-chain mutants in the hybridoma PC7 was much higher than for other cell lines. In contrast to the mutations which we observed previously, the kappa mutants examined here resulted from complete or partial deletion of the kappa gene.

Site-directed cleavage of immunoglobulin gene segments by lymphoid cell extracts.

To study the enzyme(s) involved in the site-specific recombination of immunoglobulin (Ig) gene segments, we designed an assay to detect V-J joining in vitro. The DNA from a hybrid phage (lambda VJCK) containing the VK41 gene segment separated by a 6-kilobase spacer region from the entire J-CK sequence was incubated with lymphoid cell extracts and packaged in vitro. Phages carrying genomic deletions were selected by screening for ethylenediaminetetraacetic acid resistance.