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 product of W (gpW) acts after DNA packaging, but before the addition of another phage product, gene product FII, and before the addition of tails. The role of gpW is unknown. The structure of N- and C-tagged gpW has been previously determined by nuclear magnetic resonance (NMR) spectroscopy. Here we report some of the properties of the native protein. The purification of gpW to homogeneity, overproduced by a plasmid derivative, is described. To obtain large amounts of the protein, the ribosome-binding site had to be modified, showing that inefficient translation of the message is the main mechanism limiting W gene expression. The molecular weight of the protein is in close agreement to the value predicted from the DNA sequence of the gene, which suggests that it is not post-transcriptionally modified. It behaves as a monomer in solution. Radioactively labeled gpW is incorporated into phage particles in in vitro complementation, showing that gpW is a structural protein. The stage at which gpW functions and other circumstantial evidence support the idea that six molecules of gpW polymerize on the connector before the incorporation of six molecules of gpFII and before the tail attaches.

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. The gpNu1 subunit was obtained from E. coli cells transfected with the plasmid pH6-Nu1 that overproduces the protein. Incubation of gpNu1 solubized in 2.5 M guanidinium chloride with chymotrypsin resulted in the formation of at least eight discrete protein bands, while treatment with endoproteinase glu-C and bromelain yielded three and one major bands, respectively. The peptides generated by digestion with the various proteases were separated by two-dimensional gel electrophoresis and transferred to Immobilon membranes. Amino acid sequencing of the peptides allowed for the precise assignment of their N-terminal amino acid, while their estimated molecular weights permitted the identification of their C-terminal ends. The results reveal that in the presence of 2.5 M guanidinium chloride, gpNu1 is partially folded in at least four distinct structural domains that correspond to functional domains as determined by previously reported genetic experiments. This information is key to design new plasmids to overproduce these domains for further structural analysis.

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. The purified wild type fusion proteins were found to be stably folded and biologically active. The protein is monomeric as judged by equilibrium ultracentrifugation, and appears to unfold by a cooperative two-state mechanism. Circular dichroism studies indicate that the protein is 47% helical, with a T(m) of 71.3 degrees C, and a DeltaG(u) of 3.01 kcal/mol at 25 degrees C. Mutagenesis of the three hydrophobic C-terminal residues of gpW showed that they are critical for activity, even though they do not contribute to the thermodynamic stability of the protein. Using secondary structure prediction as a guide, we also designed destabilized gpW mutants. The hydrophobic nature of the gpW C terminus caused these mutants to be degraded by the ClpP-containing proteases in Escherichia coli.

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. It is composed of two subunits, made of 181 and 641 amino acids, the products of genes Nu1 and A, respectively. The product of the FI gene (gpFI) stimulates the formation of an intermediate in capsid assembly called complex II, which contains a procapsid, terminase and DNA. The mechanism of stimulation remains unknown. It has been suggested that gpFI may also stimulate terminase-mediated cos cleavage, in the absence of procapsids, by increasing enzyme turnover. Mutants in FI fail to mature and package DNA but, in comparison with other capsid gene mutants, FI mutants are leaky. Second site mutants of FI phages, called 'fin' (for FI independence), bypass the necessity for gpFI. These mutants were originally localized to the region of Nu1 and A and are of two classes: finA includes those that induce the synthesis of fourfold more gene A product (gpA) than wild-type phages, and finB includes those that produce normal amounts of gpA. Whereas all finA mutants analysed map to Nu1, finB mutants have been found both in E and in Nu1. The existence of E mutants able to bypass the necessity for gpFI in vivo shows that gpE and gpFI interact, directly or indirectly. Here we have analysed and sequenced two finA mutants and one finB mutant. All of these map in Nu1. Of the two finA mutants, one corresponds to an Ala163Ser change and the other is a silent mutation. It is likely that the finA mutations alter mRNA conformation in a manner that results in an increase in the efficiency of A mRNA translation. The fourfold increase in gpA synthesis translates into a 10-fold increase in terminase activity. These results show that terminase overproduction is sufficient to bypass the necessity for gpFI and that such an overproduction can be achieved by changes in the efficiency of translation of A due to subtle changes in the sequence upstream of the gene. The finBcs103 mutation is a His-87-->Tyr change in Nu1. Therefore, an alternative way in which to bypass the requirement for gpFI involves an alteration in the structure of gpNu1. It is likely that the altered gpNu1 would increase cleavage and packaging efficiency directly or indirectly. We have determined that DNA cleavage in vivo does not occur in the absence of gpFI. Therefore it seems that gpFI somehow facilitates an otherwise latent capacity of terminase to autoactivate its nucleolytic activity.

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. The gene product (gpFI) seems to act as a catalyst for the formation of an intermediate in capsid assembly called complex II, which contains a procapsid (an empty capsid precursor), terminase (the enzyme that cleaves the DNA precursor and packages it into the procapsid) and DNA. The mechanism for this stimulation remains unknown. It has also been reported that gpFI appeared to stimulate terminase-mediated cos cleavage, in the absence of procapsids, by increasing enzyme turnover. In comparison with other head-gene mutants, FI mutants are leaky, producing approx. 0.1 phage per infected cell. Some second-site revertants of FI- phages, called 'fin', that bypass the necessity for gpFI, have been isolated and found to harbour a mutation in the genes that code for the two subunits of terminase. In the course of mapping additional fin mutants, it was discovered that some mapped outside the terminase genes. To localize the mutations, restriction fragments of fin mutant DNAs were subcloned into plasmids and their ability to contribute to fin function was determined by marker-rescue analysis. The location of the fin mutation was further delineated by deletion analysis of a plasmid that was positive for fin. This showed that some fin mutations mapped to a region comprising genes E, D and a portion of C. The sequencing of this entire region in several fin isolates showed that the fin mutations are clustered in a small region of gene E corresponding to a portion of 26 amino acid residues of the coat protein (gpE). We have called this region of the protein the EFI domain. All the mutations result in an increase in positive charge relative to the wild-type protein. These results suggest that DNA maturation and packaging are in part controlled by an interaction between gpFI and capsid gpE.

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. The hexamers and pentamers in the virion display a cartwheel-like structure, with skewed spokes (or arms) radiating out from a central hexameric hub. The thimble-shaped gpD trimers are superimposed on the trivalent interaction point of these arms. A reconstruction of a lambda D- mutant capsid to lower resolution shows no trace of these trimers, thus revealing the interactions of the underlying arms. The procapsid has elongated, irregularly shaped hexamers with gpE subunits set perpendicularly to the capsid surface.

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. Additionally, a regulatory region found in the adenovirus major late promoter, which interacts with the human general transcription factor USF, competed very efficiently for binding to NF-lambda 2. This region contains a sequence, CACGTGAC, which is identical to a region within the NF-lambda 2 motif. The pattern of complexes formation using oligonucleotide probes corresponding to the NF-lambda 2 and USF motifs were identical, and they both differed from that displayed by the E3 probes. Antisera against different domains of USF also react specifically with NF-lambda 2 showing that this factor is antigenically related, if not identical, to USF. Furthermore, the activity of the lambda 2 promoter in an in vitro transcription assay was significantly reduced when the nuclear extract used was USF-depleted. Addition of exogenous USF to this extract restored the transcription activity. Therefore, we conclude that NF-lambda 2 is the murine homologue of USF.

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. The purified protein is biologically active, as demonstrated by its ability to complement a gpNu3-deficient extract in an in vitro assembly reaction. The sequence of the amino terminus of the protein indicates that translation of Nu3 starts at nucleotide position 5,342 on the standard lambda DNA sequence, yielding a protein with a calculated Mr of 13,396. A combination of gel exclusion chromatography and velocity sedimentation gradient data indicates that gpNu3 possesses an unusually elongated shape.

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. Extracts of cells transformed by mutant plasmids displayed variable degrees of reduction in the activity of one or both terminase subunits as assayed by in vitro lambda DNA packaging. A method of genetically mapping plasmid-borne mutations in the A gene by measuring their ability to rescue various lambda Aam phages showed that the A mutations were fairly evenly distributed across the gene. Mutant A genes were also subcloned into overproducing plasmid constructs, and it was determined that more than half of them directed the synthesis of normal amounts of full-length A protein. Three of the A gene mutants displayed dramatically reduced in vitro packaging activity only when immature (uncut) lambda DNA was used as the substrate; therefore, these mutations may lie in the endonuclease domain of terminase. Interestingly, the putative endonuclease mutations mapped in two distinct locations in the A gene separated by a least 400 bp.

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. These data show that the connector domains involved in both head assembly and DNA packaging are functionally similar. The DNA-containing lambda-phi 29 proheads can be complemented in vitro with phi 29 tails to yield infective particles capable of DNA transfer.

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. The binding site of NF-lambda 2 was localized by DNase I footprinting to a 14-bp region which is about 30 bp upstream of the immunoglobulin octamer motif. This region, referred to as the NF-lambda 2 motif, is within an 18-bp region of twofold rotational symmetry. Experiments with oligomers containing either the NF-lambda 2 or the octamer motifs as competitors for binding and DNase I footprinting, showed that the third complex is the product of the simultaneous binding of an octamer-binding protein and NF-lambda 2. Changing the sequence of the NF-lambda 2 motif to that of the lambda 1-chain counterpart abolished the binding ability of NF-lambda 2. Concomitantly, the level of chloramphenicol acetyltransferase expression driven by the mutated lambda 2 promoter decreased by two- to fivefold when compared with that of the wild-type promoter. It is therefore concluded that the interaction of NF-lambda 2 with the NF-lambda 2 motif stimulates transcription of the lambda 2-chain gene.

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. Analogous deletions in the fragment containing the lambda 1 gene did not result in gene activation suggesting that the upstream sequences of lambda 1 and lambda 2 genes have diverged enough to allow differential regulation of their expression. However, both genes were activated by insertion, at a position upstream of the promoter, of a fragment containing the K-chain gene enhancer. These results suggest that the complete set of sequence elements that mediate lambda gene activation during normal B-cell differentiation are not all contained in the fragments of genomic DNA cloned so far, and thus, at least some of them must be located at a considerable distance from 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. Several different complexes of IHF with this fragment can be distinguished by their differential mobility on polyacrylamide gels. Relative band intensities indicate that the formation of a complex between IHF and this DNA fragment has an equilibrium binding constant of the same magnitude as DNA fragments containing lambda's attP site. Gel-mobility retardation and electron microscopy have been employed to show that IHF sharply bends DNA near cos and to map the bending site. The protein-induced bend is near an intrinsic bend due to DNA sequence. The position of the bend suggests that IHF's role in lambda DNA packaging may be the enhancement of terminase binding/cos cutting by manipulating DNA structure.

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. In vivo, at least some cos cleavage is known to occur in mutants that are unable to synthesize active IHF. No THF-defective mutants have yet been isolated. In order to determine if IHF, THF or any other host protein is involved in lambda DNA maturation in vivo, I devised a selection for host mutants that are unable to support cos cleavage. The selection is based on the assumption that lambda DNA terminase will kill cells by cleaving chromosomally located cos sites. I found that DNA terminase will indeed kill cells provided that they contain a chromosomal cos site and provided also that they are defective in the host recA or recB genes. These two genes are required for certain pathways of genetic recombination and repair of damaged DNA, and I suggest that they prevent terminase-induced killing by repairing broken chromosomes. Interestingly, mutation in a related host gene, recD, did not render cells susceptible to terminase killing. recD and recB both encode subunits of exonuclease V, but recD mutants, unlike recB, remain proficient in genetic recombination and repair.(ABSTRACT TRUNCATED AT 250 WORDS)

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. Finally, upon addition of the rest of the morphogenetic components, complete phages are assembled. We have investigated the effect of the FI gene product (gpFI) in these reactions and found that a stimulation in phage yield is observed when gpFI is included early in the reaction, at the time when DNA, terminase and proheads interact to form complex II. Measurements of complex II formation revealed that gpFI stimulated the rate of formation of this intermediate. gpFI was further shown to stimulate the addition of proheads to preformed complexes I to give complex II, but the protein did not stimulate complex I formation.

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. In addition, the wild type DNA sequences immediately preceding the genes were reduced and modified. It was found that the elements that control translation are contained in the 100 base pairs upstream from the initiation codon. Interchanging these upstream sequences with those of an efficiently translated gene dramatically increased the translation of terminase subunits. It seems unlikely that the rare codons present in the genes, and any feature of their mRNA secondary structure play a role in the control of their translation. The elimination of cos from plasmids containing Nu1 and A also resulted in an increase in terminase production. This result suggests a role for cos in the control of late gene expression. The terminase subunit overproducer strains are potentially very useful for the design of improved DNA packaging and cosmid mapping techniques.

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. The DNA terminase genes are under control of a thermosensitive cI repressor. These plasmids lack most of the genes involved in prohead morphogenesis and other head precursors. However, when repression is lifted by destruction of the thermosensitive repressor, the terminase synthesized is able to cut almost 100% of the plasmids. Therefore, these plasmids can mature in the absence of proheads and other head gene products. The plasmids are also able to complement mutants of lambda deficient in terminase and DNA maturation. However, in these complementation experiments, if the phage carry mutations in prohead genes E or B, not only is phage DNA maturation blocked, but the plasmid also fails to mature. These experiments show that, in the absence of proheads, phage lambda produces a trans-acting inhibitor of maturation. The genetic determinant of this inhibitor maps in a region extending from the middle of gene B to the end of gene C. A model is proposed in which the nicking activity of DNA-bound terminase is inhibited by the trans-acting inhibitor. Prohead (and other factors) binding to this complex would release the block to allow DNA cleavage and packaging.

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. The operon also carries the oL operator, and this enables regulation of its expression by a thermosensitive repressor. The synthesis of genes Nul and A products is extremely efficient upon derepression. Within 40 min after induction of the operon, the two subunits comprise about 20% of the total cellular protein mass. Crude extracts prepared from these overproducing strains are at least 100 times more active than extracts prepared from induced lambda lysogens in both promotion of lambda DNA packaging and cosmid cleaving. The ability to produce highly concentrated terminase would enormously facilitate the study of its structure and mechanism of action. These extracts are also extremely useful in techniques such as lambda DNA packaging, cosmid mapping and cosmid linearization to improve efficiency of integration into mouse eggs.

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.

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. Mutants defective in mu chain synthesis were of more diverse types including deletions, gross rearrangements, and more subtle changes. One mutant containing a cis-acting mutation resulting in reduced expression of the mu chain had an associated partial duplication of the mu gene, while others making low or undetectable levels of mu had no gross alterations in genetic structure. The usefulness of this approach to the study of gene structure and expression is discussed.

Amplification of the gene for histidyl-tRNA synthetase in histidinol-resistant Chinese hamster ovary cells

Histidinol-resistant (HisOHR) mutants with up to a 30-fold increase in histidyl-tRNA synthetase activity have been isolated by stepwise adaptation of wild-type Chinese hamster ovary (CHO) cells to increasing amounts of histidinol in the medium. Immunoprecipitation of [35S]methionine-labeled cell lysates with antibodies to histidyl-tRNA synthetase showed increased synthesis of the enzyme in histidinol-resistant cells. The histidinol-resistant cell lines had an increase in translatable polyadenylated mRNA for histidyl-tRNA synthetase. A cDNA for CHO histidyl-tRNA synthetase has been cloned, using these histidyl-tRNA synthetase-overproducing mutants as the source of mRNA. Southern blot analysis of wild-type and histidinol-resistant cells with this cDNA showed that the histidyl-tRNA synthetase DNA bands were amplified in the resistant cells. These HisOHR cells owed their resistance to histidinol to amplification of the gene for histidyl-tRNA synthetase.

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. Although no site-specific V-J fusion events were detected, the packaging efficiency of lambda VJCK DNA was 10(2)- to 10(3)-fold lower than that of lambda DNA. This suggested the presence in the cell extracts of an endonucleolytic activity with a specificity for the mouse DNA sequences. To detect the endonuclease cleavage products, plasmids containing VK or JK gene segments were used as a DNA substrate and the products of the in vitro reaction were visualized by autoradiography in Southern blots. Double-stranded cleavages were observed to occur near the 5' end of each one of the five JK gene segments and near the 3' end of a VK gene segment. A plasmid containing the mouse I-A beta gene was found to be resistant to cleavage, thus confirming the specificity of the endonucleolytic activity for sequences associated with the mouse Ig gene segments.

Mouse immunoglobulin gene rearrangements. The sequence of a nonexpressed lambda 3-chain gene

A functionally defective lambda 3-immunoglobulin chain gene has been cloned from plasmacytoma HOPC-1 (gamma 2b, lambda 1). The lambda 3 gene resulted from the juxtaposition of the germline V lambda 1 sequence with a J lambda 3 C lambda 3 gene segment. DNA sequencing of the rearranged V lambda 1 J lambda 3 exon showed the presence of a single base pair deletion at the site of V-J joining. The alteration in the reading frame caused by this deletion generated a stop codon at the 3' end of J lambda 3, thus rendering this gene nonfunctional for light chain production. In addition, a one-point mutation in the J lambda 3-C lambda 3 intron distinguishes the rearranged gene from the unrearranged counterpart. The implications that this rearrangement has in terms of the mechanism of somatic mutations and of selective proliferation of B cells mediated by antigen stimulation are discussed.

Mouse immunoglobulin gene rearrangements. The sequence of a nonexpressed lambda 3-chain gene

A functionally defective lambda 3-immunoglobulin chain gene has been cloned from plasmacytoma HOPC-1 (gamma 2b, lambda 1). The lambda 3 gene resulted from the juxtaposition of the germline V lambda 1 sequence with a J lambda 3 C lambda 3 gene segment. DNA sequencing of the rearranged V lambda 1 J lambda 3 exon showed the presence of a single base pair deletion at the site of V-J joining. The alteration in the reading frame caused by this deletion generated a stop codon at the 3' end of J lambda 3, thus rendering this gene nonfunctional for light chain production. In addition, a one-point mutation in the J lambda 3-C lambda 3 intron distinguishes the rearranged gene from the unrearranged counterpart. The implications that this rearrangement has in terms of the mechanism of somatic mutations and of selective proliferation of B cells mediated by antigen stimulation are discussed.

Analysis of cosmids using linearization by phage lambda terminase

A group of cosmid clones was isolated from the region of the mouse t complex and analysed by a rapid restriction mapping protocol based on linearization of circular cosmid DNA in vitro. A plasmid capable of producing high levels of phage lambda terminase was constructed and procedures for in vitro cleavage of cosmid DNAs were optimised. After linearization, the cosmids were partially digested with restriction enzymes, and either cos end was labelled by hybridization with radioactive oligos complementary to the cohesive end sequence, a step which we have described previously for clones in phage lambda (Rackwitz et al., 1984). High-resolution restriction maps derived by this method were used to identify and align the cosmids, to localise the position of repetitive sequences, and to interpret the results of electron microscopy heteroduplex experiments.

The maturation of coliphage lambda DNA in the absence of its packaging

In vivo, lambda DNA cannot be cleaved at cos (matured) if proheads are not present; in vitro, however, cos cleavage readily takes place in the absence of proheads. In order to investigate this paradox, we have constructed plasmids that synthesize lambda terminase in vivo upon induction. The plasmids also contain cos at the normal position, about 190 bp upstream of lambda gene Nul. One of the plasmids, pFM3, produces levels of terminase comparable to those found after phage induction. If cells carrying pFM3 are thermoinduced, almost 100% of the intracellular plasmid DNA has a double-strand interruption at or near cos. Since the only lambda genes that pFM3 carries are Nul, A, W and B, this in vivo cleavage is occurring in the absence of proheads. Previous failure to observe lambda maturation with phages carrying prohead mutations may be due to exonucleolytic degradation of the unprotected DNA ends, a different DNA topology or compartmentalization, or terminase inhibition in the absence of prohead by the product of another lambda gene that maps to the right of gene B.

Bacteriophage lambda preconnectors. Purification and structure

The morphogenesis of bacteriophage lambda proheads is under the control of the four phage genes B, C, Nu3 and E, and the two Escherichia coli genes groEL and groES . It has been shown previously that extracts prepared from cells infected with a lambda C-E- mutant accumulate a gpB polymer, which behaves as a biologically active intermediate in prohead assembly. This gpB activity has been called a preconnector , as it is probably a precursor to the head-tail connector. We now report the partial purification of biologically active preconnectors and the characterization of its structure. In the electron microscope, preconnectors appear as donut -like structures composed of several subunits displaying radial symmetry. Optical filtration of periodic arrays of preconnectors showed that the structure has 12-fold rotational symmetry. Side views of the preconnector reveal that it resembles an asymmetrical dumbell . This information has been used to construct a three-dimensional model of the preconnector . The implications of this structure for prohead shape and function, and for DNA packaging are discussed.

Nucleotide sequences of immunoglobulin mu heavy chain deletion mutants

Mutants of an IgM producing hybridoma cell line were isolated which produce mu heavy chain fragments. Two such mutants were found to have internal deletions in the mu gene and the nucleotide sequence of the deletion endpoints was determined. No evidence was found for a role of the heavy chain switch region in the formation of these deletions. The implications of these mutants in defining the requirements of immunoglobulin gene expression are discussed.

Early intermediates in bacteriophage lambda prohead assembly. II. Identification of biologically active intermediates

The morphogenesis of bacteriophage lambda proheads is under the control of the four phage genes B, C, Nu3, and E, as well as the E. coli genes groEL and groES. It has been previously shown that extracts prepared from cells infected with a lambda C-E- mutant accumulate biologically active gpB and gpNu3 (Murialdo, H., and Becker, A., J. Mol. Biol. 125, 57-74 (1978) ). To characterize the nature of these intermediates in prohead assembly, extracts prepared from these cells were fractionated by DEAE-cellulose chromatography as well as velocity sedimentation. Intermediates containing gpB were identified by SDS-polyacrylamide gel electrophoresis and by their ability to be assembled into biologically active proheads in vitro. The results indicate that the most abundant, biologically active intermediate (greater than 98% of the gpB activity) is a 25 S gpB-containing polymer. A second biologically active intermediate (about 1% of the total gpB activity) was identified as a gpB-gpgroEL complex.

Secretion of a lambda 2 immunoglobulin chain is prevented by a single amino acid substitution in its variable region

We have studied two derivatives of the IgA (lambda 2) secreting myeloma cell line MOPC315:MOPC315.26, which produces and secretes a lambda 2 light chain, and MOPC315.37, which produces but does not secrete the lambda 2 chain. It has been reported that the only alteration in the MOPC315-37 lambda 2 chain is located in the variable region (Mosmann and Williamson, (1980) Cell 20, 283-292). In order to determine the nature of this alteration, we cloned the fragment of the chromosome containing the rearranged lambda 2 gene from both the nonsecreting variant MOPC315-37 and the normal lambda 2-secreting parent MOPC315-26 and determined their nucleotide sequence. We found that the nucleotide sequences coding for the leader peptide and for the constant region of the lambda 2 chain were identical in the secretor and nonsecretor. The sequences of the variable region differed at a single base pair corresponding to the first nucleotide in the codon for amino acid number 15. MOPC315-26 has a G in this position creating the codon GGT which codes for glycine, and MOPC315-37 has a C in this position creating the codon CGT which codes for arginine. Thus, we have demonstrated that a single amino acid substitution of a neutral amino acid, glycine, for a positively charged amino acid, arginine, results in the failure of a protein to be secreted.

Mutant immunoglobulin genes have repetitive DNA elements inserted into their intervening sequences

The kappa light chain genes from two mutant hybridoma cell lines defective in kappa light chain synthesis were isolated and compared to the wild-type kappa light chain gene. In each case, the mutant kappa light chain genes were found to contain repetitive DNA elements in their intervening sequences that were not present in the intervening sequences of the wild-type kappa light chain gene. These elements were found to be related to the genes of intracisternal A particles. These results suggest that the decreased production of kappa light chain in the mutant cell lines is due to the presence of the intracisternal A particle-related genes.

Orientation of cohesive end site cos determines the active orientation of chi sequence in stimulating recA . recBC-mediated recombination in phage lambda lytic infections

Sequence chi, 5'G-C-T-G-G-T-G-G, locally enhances homologous recombination by recA and recBC proteins of Escherichia coli. Previous work showed that, in phage lambda, chi is more active in one orientation (leftward) than in the other (rightward). Inverting cos, the sequence for the mature DNA ends of lambda, reverses this orientation dependence: the rightward chi becomes fully active, and the leftward chi becomes relatively inactive. We surmise that chi action in phage lambda is coupled with DNA packaging or injection.

Nucleotide sequence of a chromosomal rearranged lambda 2 immunoglobulin gene of mouse

The rearranged lambda 2 gene of the mouse plasmacytoma cell line MOPC315 has been cloned and sequenced. A comparison of its sequence with the sequence of the unrearranged (germ-line) V, J and C gene segments shows that the sequences of the V gene segments differ at six positions. The sequence of the J and C gene segments remained unchanged. These results add support to the hypothesis that somatic mutations occur in immunoglobulin in genes and that these mutations do not involve the C gene segment. The degree of homology of the elements of the lambda 2 gene with those of the lambda 1 gene and C lambda 3 and C lambda 4 gene fragments suggest a pathway of evolution by gene duplication of the immunoglobulin lambda light chain locus. According to this scheme the original structure V0-J0C0 gave rise to a structure V0-J1C1-J11C11 by duplication of the J0C0 region. A second duplication encompassing the whole region resulted in the present structure: V1-J3C3-J1C1/V2-J2C2-J4C4.

Arrangement of lambda light chain genes in mutant clones of the MOPC 315 mouse myeloma cells

The synthesis of lambda light chains and the arrangement of the lambda-chain genes was examined in cells of the mouse myeloma MOPC 315, which is an alpha lambda 2 producer, and in several mutants derived from it. The mutants produce lambda 2 chains only (MOPC 315.26, MOPC 315.34, and MOPC 315.37) or fail to produce alpha and lambda 2 chains (MOPC 315.25 and MOPC 315.36). Messenger RNA from the lambda 2 chain-producing cells directed the synthesis of a lambda 2 chain precursor and a fragment of the lambda 1 chain (lambda 1 F) in a wheat embryo cellfree system, whereas mRNA from the cells that do not produce lambda 2 chains directed the synthesis of lambda 1 F only. DNA from the parental MOPC 315 cells and from the lambda 2 chain-producing cells contained discrete EcoRI restriction fragments coding for rearranged lambda 1 and lambda 23 chain genes and their respective germ-line V and J-C regions. DNA from the no-Ig-producing cells contained fragments coding for the rearranged lambda 1 chain gene and the germ-line V lambda 2 region, but it lacked the sequences coding for the rearranged lambda 2 chain gene and the germ-line V lambda 1 and J-C lambda 1 regions. These results suggest that rearrangements of the lambda 1 and lambda 2 chain genes occur on different chromosomes in MOPC 315 cells and imply that rearrangements of the lambda 1 and lambda 2 chain genes on the same chromosome may be mutually exclusive.

Arrangement of lambda light chain genes in mutant clones of the MOPC 315 mouse myeloma cells

The synthesis of lambda light chains and the arrangement of the lambda-chain genes was examined in cells of the mouse myeloma MOPC 315, which is an alpha lambda 2 producer, and in several mutants derived from it. The mutants produce lambda 2 chains only (MOPC 315.26, MOPC 315.34, and MOPC 315.37) or fail to produce alpha and lambda 2 chains (MOPC 315.25 and MOPC 315.36). Messenger RNA from the lambda 2 chain-producing cells directed the synthesis of a lambda 2 chain precursor and a fragment of the lambda 1 chain (lambda 1 F) in a wheat embryo cellfree system, whereas mRNA from the cells that do not produce lambda 2 chains directed the synthesis of lambda 1 F only. DNA from the parental MOPC 315 cells and from the lambda 2 chain-producing cells contained discrete EcoRI restriction fragments coding for rearranged lambda 1 and lambda 23 chain genes and their respective germ-line V and J-C regions. DNA from the no-Ig-producing cells contained fragments coding for the rearranged lambda 1 chain gene and the germ-line V lambda 2 region, but it lacked the sequences coding for the rearranged lambda 2 chain gene and the germ-line V lambda 1 and J-C lambda 1 regions. These results suggest that rearrangements of the lambda 1 and lambda 2 chain genes occur on different chromosomes in MOPC 315 cells and imply that rearrangements of the lambda 1 and lambda 2 chain genes on the same chromosome may be mutually exclusive.

Stimulation of groE synthesis in Escherichia coli by bacteriophage lambda infection

We found that infection of Escherichia cell by lambda results in at least a twofold stimulation in the rate of synthesis of one of the products of groE. To determine what lambda-coded factors were responsible for this stimulation, numerous phage lambda mutants carrying bio substitutions were analyzed for their ability to stimulate groE synthesis. Our results revealed that the main factor(s) which is responsible for stimulating groE synthesis is located between the endpoints of the lambda bio69 and lambda bio252 substitutions, a region of DNA coding for bet, gam, kil, and cIII.

RNA splicing mutation in an aberrantly rearranged immunoglobulin lambda I gene

The mouse cell line MOPC 315 is an IgA (lambda II)-producing myeloma. We have studied a derivative of MOPC 315 that secretes normal lambda II chains but no heavy chain. This derivative, MOPC 315-26, was found to contain a rearranged lambda I gene in addition to a rearranged lambda II gene. The rearranged lambda I gene was cloned into bacteriophage lambda DNA and its structure was studied. The lambda I gene was found to have arisen by an aberrant recombination event that resulted in a single base insertion at the site of V-J region joining. In addition, the gene contained numerous point mutations in the vicinity of the junction of the V and J regions. Two point mutations occurred in the donor splice sequence normally used for the removal of the intron between the J and C regions, suggesting that the RNA synthesized from the aberrantly rearranged lambda I gene would be unable to undergo proper RNA splicing.

Molecular cloning of an immunoglobulin kappa constant gene from NZB mouse

An EcoRI fragment carrying the immunoglobulin C kappa gene and multiple J gene segments from the DNA of the NZB strain of mouse was cloned into lambda Ch 4A DNA. Subsequent characterization of the clone by heteroduplex analysis, restriction-enzyme mapping and DNA sequencing demonstrated that the organization of the J gene segments and the C kappa gene of NZB mouse was similar, if not identical, to that of DNA from the Balb/c strain of mouse. Since the amino acid sequence of the light chain of a plasmacytoma of NZB mouse shows a J region sequence different from that of Balb/c mouse, our results indicate that the new J sequence arose by somatic mutation.

Identification of a second Escherichia coli groE gene whose product is necessary for bacteriophage morphogenesis

Previous work has uncovered the existence of an Escherichia coli locus, groE, that is essential for bacterial growth, lambda phage and T4 phage head morphogenesis, and T5 phage tail assembly. Our genetic and biochemical analyses of lambda groE+ transducing phages and their deletion and point mutant derivatives show that the groE locus consists of two closely linked genes. One groE gene, groEL, has been shown to encode the synthesis of a 65,000 Mr polypeptide, whereas the second, groES, codes for the synthesis of a 15,000 Mr polypeptide. About half of the groE- bacterial isolates fall into the groES complementation group. GroE mutations in either gene cause similar phenotypes, with respect to lambda phage head morphogenesis and bacterial growth at nonpermissive temperatures.

Morphogenetic genes C and Nu3 overlap in bacteriophage lambda

In bacteriophage lambda, genes C and Nu3, two of the four cistrons which are essential for normal prohead formation, have overlapping nucleotide sequences. These genes are translated in the same reading frame so that the Nu3 protein is identical to the COOH-terminal one-third of the C protein. This structural relationship may provide for the functional interaction of the C and Nu3 proteins through their regions of structural homology during prohead assembly. The in-phase overlapping organisation of genes may constitute a general strategy to facilitate the mutual interaction of a pair of proteins through their common structural domains.