HU and integration host factor function as auxiliary proteins in cleavage of phage lambda cohesive ends by terminase

Viral genome packaging machines: Structure and enzymology

Although the process of genome encapsidation is highly conserved in tailed bacteriophages and eukaryotic double-stranded DNA viruses, there are two distinct packaging pathways that these viruses use to catalyze ATP-driven translocation of the viral genome into a preassembled procapsid shell. One pathway is used by ϕ29-like phages and adenoviruses, which replicate and subsequently package a monomeric, unit-length genome covalently attached to a virus/phage-encoded protein at each 5'-end of the dsDNA genome. In a second, more ubiquitous packaging pathway characterized by phage lambda and the herpesviruses, the viral DNA is replicated as multigenome concatemers linked in a head-to-tail fashion. Genome packaging in these viruses thus requires excision of individual genomes from the concatemer that are then translocated into a preassembled procapsid. Hence, the ATPases that power packaging in these viruses also possess nuclease activities that cut the genome from the concatemer at the beginning and end of packaging. This review focuses on proposed mechanisms of genome packaging in the dsDNA viruses using unit-length ϕ29 and concatemeric λ genome packaging motors as representative model systems.

ATP serves as a nucleotide switch coupling the genome maturation and packaging motor complexes of a virus assembly machine

The assembly of double-stranded DNA viruses, from phages to herpesviruses, is strongly conserved. Terminase enzymes processively excise and package monomeric genomes from a concatemeric DNA substrate. The enzymes cycle between a stable maturation complex that introduces site-specific nicks into the duplex and a dynamic motor complex that rapidly translocates DNA into a procapsid shell, fueled by ATP hydrolysis. These tightly coupled reactions are catalyzed by terminase assembled into two functionally distinct nucleoprotein complexes; the maturation complex and the packaging motor complex, respectively. We describe the effects of nucleotides on the assembly of a catalytically competent maturation complex on viral DNA, their effect on maturation complex stability and their requirement for the transition to active packaging motor complex. ATP plays a major role in regulating all of these activities and may serve as a 'nucleotide switch' that mediates transitions between the two complexes during processive genome packaging. These biological processes are recapitulated in all of the dsDNA viruses that package monomeric genomes from concatemeric DNA substrates and the nucleotide switch mechanism may have broad biological implications with respect to virus assembly mechanisms.

Endogenous and Foreign Nucleoid-Associated Proteins of Bacteria: Occurrence, Interactions and Effects on Mobile Genetic Elements and Host's Biology

Mobile Genetic Elements (MGEs) are mosaics of functional gene modules of diverse evolutionary origin and are generally divergent from the hosts´ genetic background. Existing biases in base composition and codon usage of these elements` genes impose transcription and translation limitations that may affect the physical and regulatory integration of MGEs in new hosts. Stable appropriation of the foreign DNA depends on a number of host factors among which are the Nucleoid-Associated Proteins (NAPs). These small, basic, highly abundant proteins bind and bend DNA, altering its topology and folding, thereby affecting all known essential DNA metabolism related processes. Both chromosomally- (endogenous) and MGE- (foreign) encoded NAPs have been shown to exist in bacteria. While the role of host-encoded NAPs in xenogeneic silencing of both episomal (plasmids) and integrative MGEs (pathogenicity islands and prophages) is well acknowledged, less is known about the role of MGE-encoded NAPs in the foreign elements biology or their influence on the host's chromosome expression dynamics. Here we review existing literature on the topic, present examples on the positive and negative effects that endogenous and foreign NAPs exert on global transcriptional gene expression, MGE integrative and excisive recombination dynamics, persistence and transfer to suitable hosts and discuss the nature and relevance of synergistic and antagonizing higher order interactions between diverse types of NAPs.

Physical and Functional Characterization of a Viral Genome Maturation Complex

Genome packaging is strongly conserved in the complex double-stranded DNA viruses, including the herpesviruses and many bacteriophages. In these cases, viral DNA is packaged into a procapsid shell by a terminase enzyme. The packaging substrate is typically a concatemer composed of multiple genomes linked in a head-to-tail fashion, and terminase enzymes perform two essential functions: 1) excision of a unit length genome from the concatemer (genome maturation) and 2) translocation of the duplex into a procapsid (genome packaging). While the packaging motors have been described in some detail, the maturation complexes remain ill characterized. Here we describe the assembly, physical characteristics, and catalytic activity of the λ-genome maturation complex. The λ-terminase protomer is composed of one large catalytic subunit tightly associated with two DNA recognition subunits. The isolated protomer binds DNA weakly and does not discriminate between nonspecific DNA and duplexes that contain the packaging initiation sequence, cos. The Escherichia coli integration host factor protein (IHF) is required for efficient λ-development in vivo and a specific IHF recognition sequence is found within cos. We show that IHF and the terminase protomer cooperatively assemble at the cos site and that the small terminase subunit plays the dominant role in complex assembly. Analytical ultracentrifugation analysis reveals that the maturation complex is composed of four protomers and one IHF heterodimer bound at the cos site. Tetramer assembly activates the cos-cleavage nuclease activity of the enzyme, which matures the genome end in preparation for packaging. The stoichiometry and catalytic activity of the complex is reminiscent of the type IIE and IIF restriction endonucleases and the two systems may share mechanistic features. This study, to our knowledge, provides our first detailed glimpse into the structural and functional features of a viral genome maturation complex, an essential intermediate in the development of complex dsDNA viruses.

The Nucleoid: an Overview

This review provides a brief review of the current understanding of the structure-function relationship of the Escherichia coli nucleoid developed after the overview by Pettijohn focusing on the physical properties of nucleoids. Isolation of nucleoids requires suppression of DNA expansion by various procedures. The ability to control the expansion of nucleoids in vitro has led to purification of nucleoids for chemical and physical analyses and for high-resolution imaging. Isolated E. coli genomes display a number of individually intertwined supercoiled loops emanating from a central core. Metabolic processes of the DNA double helix lead to three types of topological constraints that all cells must resolve to survive: linking number, catenates, and knots. The major species of nucleoid core protein share functional properties with eukaryotic histones forming chromatin; even the structures are different from histones. Eukaryotic histones play dynamic roles in the remodeling of eukaryotic chromatin, thereby controlling the access of RNA polymerase and transcription factors to promoters. The E. coli genome is tightly packed into the nucleoid, but, at each cell division, the genome must be faithfully replicated, divided, and segregated. Nucleoid activities such as transcription, replication, recombination, and repair are all affected by the structural properties and the special conformations of nucleoid. While it is apparent that much has been learned about the nucleoid, it is also evident that the fundamental interactions organizing the structure of DNA in the nucleoid still need to be clearly defined.

Integration host factor assembly at the cohesive end site of the bacteriophage lambda genome: implications for viral DNA packaging and bacterial gene regulation

Integration host factor (IHF) is an Escherichia coli protein involved in (i) condensation of the bacterial nucleoid and (ii) regulation of a variety of cellular functions. In its regulatory role, IHF binds to a specific sequence to introduce a strong bend into the DNA; this provides a duplex architecture conducive to the assembly of site-specific nucleoprotein complexes. Alternatively, the protein can bind in a sequence-independent manner that weakly bends and wraps the duplex to promote nucleoid formation. IHF is also required for the development of several viruses, including bacteriophage lambda, where it promotes site-specific assembly of a genome packaging motor required for lytic development. Multiple IHF consensus sequences have been identified within the packaging initiation site (cos), and we here interrogate IHF–cos binding interactions using complementary electrophoretic mobility shift (EMS) and analytical ultracentrifugation (AUC) approaches. IHF recognizes a single consensus sequence within cos (I1) to afford a strongly bent nucleoprotein complex. In contrast, IHF binds weakly but with positive cooperativity to nonspecific DNA to afford an ensemble of complexes with increasing masses and levels of condensation. Global analysis of the EMS and AUC data provides constrained thermodynamic binding constants and nearest neighbor cooperativity factors for binding of IHF to I1 and to nonspecific DNA substrates. At elevated IHF concentrations, the nucleoprotein complexes undergo a transition from a condensed to an extended rodlike conformation; specific binding of IHF to I1 imparts a significant energy barrier to the transition. The results provide insight into how IHF can assemble specific regulatory complexes in the background of extensive nonspecific DNA condensation.

AT-rich region and repeated sequences - the essential elements of replication origins of bacterial replicons

Repeated sequences are commonly present in the sites for DNA replication initiation in bacterial, archaeal, and eukaryotic replicons. Those motifs are usually the binding places for replication initiation proteins or replication regulatory factors. In prokaryotic replication origins, the most abundant repeated sequences are DnaA boxes which are the binding sites for chromosomal replication initiation protein DnaA, iterons which bind plasmid or phage DNA replication initiators, defined motifs for site-specific DNA methylation, and 13-nucleotide-long motifs of a not too well-characterized function, which are present within a specific region of replication origin containing higher than average content of adenine and thymine residues. In this review, we specify methods allowing identification of a replication origin, basing on the localization of an AT-rich region and the arrangement of the origin's structural elements. We describe the regularity of the position and structure of the AT-rich regions in bacterial chromosomes and plasmids. The importance of 13-nucleotide-long repeats present at the AT-rich region, as well as other motifs overlapping them, was pointed out to be essential for DNA replication initiation including origin opening, helicase loading and replication complex assembly. We also summarize the role of AT-rich region repeated sequences for DNA replication regulation.

The bacteriophage DNA packaging motor

An ATP-powered DNA translocation machine encapsidates the viral genome in the large dsDNA bacteriophages. The essential components include the empty shell, prohead, and the packaging enzyme, terminase. During translocation, terminase is docked on the prohead's portal protein. The translocation ATPase and the concatemer-cutting endonuclease reside in terminase. Remarkably, terminases, portal proteins, and shells of tailed bacteriophages and herpes viruses show conserved features. These DNA viruses may have descended from a common ancestor. Terminase's ATPase consists of a classic nucleotide binding fold, most closely resembling that of monomeric helicases. Intriguing models have been proposed for the mechanism of dsDNA translocation, invoking ATP hydrolysis-driven conformational changes of portal or terminase powering DNA motion. Single-molecule studies show that the packaging motor is fast and powerful. Recent advances permit experiments that can critically test the packaging models. The viral genome translocation mechanism is of general interest, given the parallels between terminases, helicases, and other motor proteins.

Building a virus from scratch: assembly of an infectious virus using purified components in a rigorously defined biochemical assay system

The assembly of double-stranded DNA (dsDNA) viruses such as poxvirus, the herpesviruses and many bacteriophages is a complex process that requires the coordinated activities of numerous proteins of both viral and host origin. Here, we report the assembly of an infectious wild-type lambda virus using purified proteins and commercially available DNA, and optimization of the assembly reaction in a rigorously defined biochemical system. Seven proteins, purified procapsids and tails, and mature lambda DNA are necessary and sufficient for efficient virus assembly in vitro. Analysis of the reaction suggests that (i) virus assembly in vitro is optimal under conditions that faithfully mimic the intracellular environment within an Escherichia coli cell, (ii) concatemeric DNA is required for the successful completion of virus assembly, (iii) several of the protein components oligomerize concomitant with their step-wise addition to the nascent virus particle and (iv) tail addition is the rate-limiting step in virus assembly. Importantly, the assembled virus may enter either of the developmental pathways (lytic or lysogenic) expected of a lambda virion. Thus, we demonstrate for the first time that a wild-type, complex DNA virus may be assembled from purified components under defined biochemical conditions. This system provides a powerful tool to characterize, at the molecular level, the step-by-step processes required to assemble an infectious virus particle. Given the remarkable similarities between dsDNA bacteriophage and eukaryotic dsDNA viruses, characterization of the lambda system has broad biological implications in our understanding of virus development at a global level.

A bipartite bacteriophage T4 SOC and HOC randomized peptide display library: detection and analysis of phage T4 terminase (gp17) and late sigma factor (gp55) interaction

HOC and SOC are dispensable T4 capsid proteins that can be used for phage display of multiple copies of peptides and proteins. A bipartite phage T4 peptide library was created by displaying on tetra-alanine linker peptides five randomized amino acids from the carboxyl-terminus of SOC and five randomized amino acids from the amino terminus of HOC. The bipartite library was biopanned against the phage T4 terminase large subunit gp17 to identify T4 gene products that may interact with the terminase. The sequences of selected phages displayed matches to those T4 gene products previously known by genetic and biochemical criteria to interact with gp17: gp20 (portal protein), gp32 (single-stranded DNA binding protein), gp16 (terminase small subunit), and gp17 (self). In addition, matches were found to gp55 (T4 late sigma factor), gp45 (sliding clamp), gp44 (clamp loader), gp2 (DNA end protein), and gp23 (major capsid protein). Abundant amino acid sequence matches were found to aa region 118-134 of gp55. Immunoprecipitation and affinity column chromatography demonstrated direct binding of gp17 and gp55; moreover, gp17 bound specifically to a column-coupled peptide corresponding to gp55 residues 111-136. Measurements of gene 17 and other mRNA levels in mutant-infected bacteria did not support a role of gp17-gp55 interaction in regulation of terminase or other late gene transcription. However, whereas DNA concatemers that accumulate in prohead and terminase defective phage T4 infections could be packaged in vitro to approximately 10% wild-type efficiency, 55am33am defective concatemeric DNA was packaged at least 100-fold less efficiently. Moreover, gp55 residues 111-136 peptide specifically blocked DNA packaging in vitro. These results suggest that the T4 terminase interaction with T4 late sigma factor gp55 plays a role in DNA packaging in vivo. The gp55 interaction may function to load the terminase onto DNA for packaging.

Alterations of the portal protein, gpB, of bacteriophage lambda suppress mutations in cosQ, the site required for termination of DNA packaging

The cosQ site of bacteriophage lambda is required for DNA packaging termination. Previous studies have shown that cosQ mutations can be suppressed in three ways: by a local suppressor within cosQ, an increase in the length of the lambda chromosome, and missense mutations affecting the prohead's portal protein, gpB. In the present work, revertants of a set of lethal cosQ mutants were screened for suppressors. Seven new cosQ suppressors affected gene B, which encodes the portal protein of the prohead. All seven were allele-nonspecific suppressors of cosQ mutations. Experiments with several phages having two cosQ suppressors showed that the suppression effects were additive. Furthermore, these double suppressors had minimal effects on the growth of cosQ(+) phages. These trans-acting suppressors affecting the portal protein are proposed to allow the mutant cosQ site to be more efficiently recognized, due to the slowing of the rate of translocation.

Bacteriophage lambda DNA packaging: DNA site requirements for termination and processivity

Bacteriophage lambda chromosomes are processively packaged into preformed shells, using end-to-end multimers of intracellular viral DNA as the packaging substate. A 200 bp long DNA segment, cos, contains all the sequences needed for DNA packaging. The work reported here shows that efficient DNA packaging termination requires cos's I2 segment, in addition to the required termination subsite, cosQ, and the nicking site, cosN. Efficient processivity requires cosB, in addition to cosQ and cosN. An initiation-defective mutant form of cosB sponsored efficient processivity, indicating that the terminase-cosB interactions required for termination are less stringent than those required at initiation. The finding that an initiation-defective form of cosB is functional for processivity allows a re-interpretation of a similar finding, obtained previously, that the initiation-defective cosB of phage 21 is functional for processivity by the lambda packaging machinery. The cosBphi21 result can now be interpreted as indicating that interactions between cosBphi21 and lambda terminase, while insufficient for initiation, function for processivity.

The essential HupB and HupN proteins of Pseudomonas putida provide redundant and nonspecific DNA-bending functions

A protein mixture containing two major components able to catalyze a beta-recombination reaction requiring nonspecific DNA bending was obtained by fractionation of a Pseudomonas putida extract. N-terminal sequence analysis and genomic data base searches identified the major component as an analogue of HupB of Pseudomonas aeruginosa and Escherichia coli, encoding one HU protein variant. The minor component of the fraction, termed HupN, was divergent enough from HupB to predict a separate DNA-bending competence. The determinants of the two proteins were cloned and hyperexpressed, and the gene products were purified. Their activities were examined in vitro in beta-recombination assays and in vivo by complementation of the Hbsu function of Bacillus subtilis. HupB and HupN were equally efficient in all tests, suggesting that they are independent and functionally redundant DNA bending proteins. This was reflected in the maintenance of in vivo activity of the final sigma54 Ps promoter of the toluene degradation plasmid, TOL, which requires facilitated DNA bending, in DeltahupB or DeltahupN strains. However, hupB/hupN double mutants were not viable. It is suggested that the requirement for protein-facilitated DNA bending is met in P. putida by two independent proteins that ensure an adequate supply of an essential cellular activity.

Transcriptional organization and dynamic expression of the hbpCAD genes, which encode the first three enzymes for 2-hydroxybiphenyl degradation in Pseudomonas azelaica HBP1

Pseudomonas azelaica HBP1 degrades the toxic substance 2-hydroxybiphenyl (2-HBP) by means of three enzymes that are encoded by structural genes hbpC, hbpA, and hbpD. These three genes form a small noncontiguous cluster. Their expression is activated by the product of regulatory gene hbpR, which is located directly upstream of the hbpCAD genes. The HbpR protein is a transcription activator and belongs to the so-called XylR/DmpR subclass within the NtrC family of transcriptional activators. Transcriptional fusions between the different hbp intergenic regions and the luxAB genes of Vibrio harveyi in P. azelaica and in Escherichia coli revealed the existence of two HbpR-regulated promoters; one is located in front of hbpC, and the other one is located in front of hbpD. Northern analysis confirmed that the hbpC and hbpA genes are cotranscribed, whereas the hbpD gene is transcribed separately. No transcripts comprising the entire hbpCAD cluster were detected, indicating that transcription from P(hbpC) is terminated after the hbpA gene. E. coli mutant strains lacking the structural genes for the RNA polymerase sigma(54) subunit or for the integration host factor failed to express bioluminescence from P(hbpC)- and P(hbpD)-luxAB fusions when a functional hbpR gene was provided in trans. This pointed to the active role of sigma(54) and integration host factor in transcriptional activation from these promoters. Primer extension analysis revealed that both P(hbpC) and P(hbpD) contain the typical motifs at position -24 (GG) and -12 (GC) found in sigma(54)-dependent promoters. Analysis of changes in the synthesis of the hbp mRNAs, in activities of the 2-HBP pathway enzymes, and in concentrations of 2-HBP intermediates during the first 4 h after induction of continuously grown P. azelaica cells with 2-HBP demonstrated that the specific transcriptional organization of the hbp genes ensured smooth pathway expression.

Characterization in vitro and in vivo of a new HU family protein from Streptococcus thermophilus ST11

Streptococcus thermophilus is a thermophilic gram-positive bacterium belonging to the lactic acid group. We report the isolation and characterization of a new 9.6-kDa DNA-binding protein, HSth, belonging to the HU family of nucleoid-associated proteins. The hsth gene was isolated in a 2.5-kb genomic region, upstream of a gene with strong homology to Lactococcus lactis pyrD. It is transcribed from a single E. coli sigma(70)-like promoter. Based on its high level of sequence similarity to B. subtilis and E. coli HU, HSth appears to be an HU homologue. The HSth protein shows biochemical and functional properties typical of HU proteins from gram-positive bacteria, being heat-stable, acid-soluble, and homodimeric. When expressed in HU-deficient E. coli cells, HSth supported the growth of bacteriophage Mu as efficiently as E. coli HU homo- and heterodimeric proteins. It did not, however, display any IHF-specific functions. Finally, we show that HSth binds to linear DNA with no apparent specificity, forming protein-DNA complexes similar but not identical to those observed with E. coli HU proteins.

Transcription regulation by repressosome and by RNA polymerase contact

The original model of repression of transcription initiation is steric interference of RNA polymerase binding to a promoter by its repressor protein bound to a DNA site that overlaps the promoter. From the results described here, we propose two other mechanisms of repressor action, both of which involve formation of higher-order DNA-multiprotein complexes. These models also explain the problem of RNA polymerase gaining access to a promoter in the condensed nucleoid in response to an inducing signal to initiate transcription.

Differential binding of the Escherichia coli HU, homodimeric forms and heterodimeric form to linear, gapped and cruciform DNA

We have shown recently that the relative abundance of the three dimeric forms (alpha2, alphabeta and beta2) of the HU protein from Escherichia coli varies during growth and in response to environmental changes. Using gel retardation assays we have compared the DNA binding properties of the three dimers with different DNA substrates. The determination of their DNA binding parameters shows that the relative affinities of HUalphabeta and HUalpha2 are comparable. Both recognize, with a high degree of affinity under stringent conditions, cruciform structures or DNA molecules with a nick or a gap, whereas they bind to linear DNA only at low salt. DNA containing a gap of two nucleotides is in fact the substrate recognized with the highest degree of affinity by these two forms under all conditions. Conversely, HUbeta2 binds very poorly to duplex DNA and shows a much lower affinity for nicked or gapped DNAs. However, HUbeta2 binds to cruciform DNA structures almost as well as HUalphabeta and HUalpha2. This almost exclusive binding of HUbeta2 to a unique substrate is surprising in regards of the quasi identity, in the three forms, of the flexible arms considered as the DNA-binding domains of the three forms of HU. Cruciform DNA may stabilize HUbeta2 structure which could be structurally defective.

Mutations that extend the specificity of the endonuclease activity of lambda terminase

Terminase, an enzyme encoded by the Nu1 and A genes of bacteriophage lambda, is crucial for packaging concatemeric DNA into virions. cosN, a 22-bp segment, is the site on the virus chromosome where terminase introduces staggered nicks to cut the concatemer to generate unit-length virion chromosomes. Although cosN is rotationally symmetric, mutations in cosN have asymmetric effects. The cosN G2C mutation (a G-to-C change at position 2) in the left half of cosN reduces the phage yield 10-fold, whereas the symmetric mutation cosN C11G, in the right half of cosN, does not affect the burst size. The reduction in phage yield caused by cosN G2C is correlated with a defect in cos cleavage. Three suppressors of the cosN G2C mutation, A-E515G, A-N509K, and A-R504C, have been isolated that restore the yield of lambda cosN G2C to the wild-type level. The suppressors are missense mutations that alter amino acids located near an ATPase domain of gpA. lambda A-E515G, A-N509K, and A-R504C phages, which are cosN+, also had wild-type burst sizes. In vitro cos cleavage experiments on cosN G2C C11G DNA showed that the rate of cleavage for A-E515G terminase is three- to fourfold higher than for wild-type terminase. The A-E515G mutation changes residue 515 of gpA from glutamic acid to glycine. Uncharged polar and hydrophobic residues at position 515 suppressed the growth defect of lambda cosN G2C C11G. In contrast, basic (K, R) and acidic (E, D) residues at position 515 failed to suppress the growth defect of lambda cosN G2C C11G. In a lambda cosN+ background, all amino acids tested at position 515 were functional. These results suggest that A-E515G plays an indirect role in extending the specificity of the endonuclease activity of lambda terminase.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Termination of packaging of the bacteriophage lambda chromosome: cosQ is required for nicking the bottom strand of cosN

Termination of packaging of the lambda chromosome involves completion of translocation of the DNA into the head shell, and conversion of the translocation complex into a cleavage complex. The cleavage reaction introduces staggered nicks into the downstream cosN to generate the right cohesive end of the chromosome. cosQ, a site adjacent to cosN, was found to be required for nicking the bottom strand of cosN; bottom strand nicking was also sequence-specific for bps at the nick site. Nicking of the top strand of cosN (cosNL) was stimulated by cosQ, but fidelity and efficiency of cosNL nicking were largely dictated by other cos subsites (i.e. cosB and I2). Aberrant top-strand cleavage within cosQ was observed in the absence of I2, and nicking at a site 8 nt 5' to the normal cosNL nick site occurred in the absence of cosB. The presence of cosQ was found to be insufficient to arrest DNA translocation in vivo, indicating that cosQ, per se, is not a packaging stop signal. A model is presented in which the role of cosQ is to depolarize the asymmetric arrangement of terminase protomers in the translocation complex so that protomers are configured to match the 2-fold rotational symmetry of cosN.

Genetic evidence that recognition of cosQ, the signal for termination of phage lambda DNA packaging, depends on the extent of head filling

Packaging a phage lambda chromosome involves cutting the chromosome from a concatemer and translocating the DNA into a prohead. The cutting site, cos, consists of three subsites: cosN, the nicking site; cosB, a site required for packaging initiation; and cosQ a site required for termination of packaging. cosB contains three binding sites (R sequences) for gpNu1, the small subunit of terminase. Because cosQ has sequence identity to the R sequences, it has been proposed that cosQ is also recognized by gpNu1. Suppressors of cosB mutations were unable to suppress a cosQ point mutation. Suppressors of a cosQ mutation (cosQ1) were isolated and found to be of three sorts, the first affecting a base pair in cosQ. The second type of cosQ suppression involved increasing the length of the phage chromosome to a length near to the maximum capacity of the head shell. A third class of suppressors were missense mutations in gene B, which encodes the portal protein of the virion. It is speculated that increasing DNA length and altering the portal protein may reduce the rate of translocation, thereby increasing the efficiency of recognition of the mutant cosQ. None of the cosQ suppressors was able to suppress cosB mutations. Because cosQ and cosB mutations are suppressed by very different types of suppressors, it is concluded that cosQ and the R sequences of cosB are recognized by different DNA-binding determinants.

Mutations in Nu1, the gene encoding the small subunit of bacteriophage lambda terminase, suppress the postcleavage DNA packaging defect of cosB mutations

The linear double-stranded DNA molecules in lambda virions are generated by nicking of concatemeric intracellular DNA by terminase, the lambda DNA packaging enzyme. Staggered nicks are introduced at cosN to generate the cohesive ends of virion DNA. After nicking, the cohesive ends are separated by terminase; terminase bound to the left end of the DNA to be packaged then binds the empty protein shell, i.e., the prohead, and translocation of DNA into the prohead occurs. cosB, a site adjacent to cosN, is a terminase binding site. cosB facilitates the rate and fidelity of the cosN cleavage reaction by serving as an anchoring point for gpNu1, the small subunit of terminase. cosB is also crucial for the formation of a stable terminase-DNA complex, called complex I, formed after cosN cleavage. The role of complex I is to bind the prohead. Mutations in cosB affect both cosB functions, causing mild defects in cosN cleavage and severe packaging defects. The lethal cosB R3- R2- R1- mutation contains a transition mutation in each of the three gpNu1 binding sites of cosB. Pseudorevertants of lambda cosB R3- R2- R1- DNA contain suppressor mutations affecting gpNu1. Results of experiments that show that two such suppressors, Nu1ms1 and Nu1ms3, do not suppress the mild cosN cleavage defect caused by the cosB R3- R2- R1- mutation but strongly suppress the DNA packaging defect are presented. It is proposed that the suppressing terminases, unlike the wild-type enzyme, are able to assemble a stable complex I with cosB R3- R2- R1- DNA. Observations on the adenosine triphosphatase activities and protease susceptibilities of gpNu1 of the Nu1ms1 and Nu1ms3 terminases indicate that the conformation of gpNu1 is altered in the suppressing terminases.

Isolation and characterization of the integration host factor genes of Pasteurella haemolytica

Using a bacteriophage lambda complementation system in Escherichia coli, we cloned genes encoding subunits of the heterodimeric DNA binding/bending protein, integration host factor, from the bovine pathogen, Pasteurella haemolytica. Complementation of ihfA and ihfB mutations in E. coli demonstrated that the P. haemolytica gene products form functional heterologous heterodimers. The ihfA and ihfB genes encode polypeptides predicted to be 99 and 93 amino acids long, respectively, and are very similar to integration host factor subunits from other Gram-negative bacteria, although phylogenetic analysis indicated that the P. haemolytica sequences are distantly related to those from other bacteria. Most significant amino acid differences were restricted to the amino-terminal domains of the predicted peptides.

Action at a distance for negative control of transcription of the glpD gene encoding sn-glycerol 3-phosphate dehydrogenase of Escherichia coli K-12

Aerobic sn-glycerol 3-phosphate dehydrogenase is a cytoplasmic membrane-associated respiratory enzyme encoded by the glpD gene of Escherichia coli. The glpD operon is tightly controlled by cooperative binding of the glp repressor to tandem operators (O(D)1 and O(D)2) that cover the -10 promoter element and 30 bp downstream of the transcription start site. In this work, two additional operators were identified within the glpD structural gene at positions 568 to 587 (0(D)3) and 609 to 628 (0(D)4). The two internal operators bound the glp repressor in the presence or absence of the tandem operators (O(D)1 and O(D)2) in vitro, as shown by DNase I footprinting. To assess a potential regulatory role for the two internal operators in vivo, a glpD-lacZ transcriptional fusion containing all four operators was constructed. The response of this fusion to the glp repressor was compared with those of fusion constructs in which O(D)3 and O(D)4 were inactivated by either deletion or site-directed mutagenesis. It was found that the repression conferred by binding of the glp repressor to O(D)1 and O(D)2 was increased five- to sevenfold upon introduction of the internal operators. A regulatory role for HU was suggested when it was found that repressor-mediated control of glpD transcription was increased fourfold in strains containing HU compared with that of strains deficient in HU. The effect of HU was apparent only in the presence of all four glpD operators. The results suggest that glpD is controlled by formation of a repression loop between the tandem and internal operators. HU may assist repression by bending the DNA to facilitate loop formation.

Effects of integration host factor and DNA supercoiling on transcription from the ilvPG promoter of Escherichia coli

Integration host factor (IHF) activates transcription from the ilvPG promoter by severely distorting the DNA helix in an upstream region of a supercoiled DNA template in a way that alters the structure of the DNA in the downstream promoter region and facilitates open complex formation. In this report, the in vivo and in vitro influence of DNA supercoiling on transcription from this promoter is examined. In the absence of IHF, promoter activity increases with increased DNA supercoiling. In the presence of IHF, the same increases in superhelical DNA densities result in larger increases in promoter activity until a maximal activation of 5-fold is obtained. However, the relative transcriptional activities of the promoter in the presence and absence of IHF at any given DNA superhelical density remains the same. Thus, IHF and increased DNA supercoiling activate transcription by different mechanisms. Also, IHF binds with equal affinities to its target site on linear and supercoiled DNA templates. Therefore, IHF binding does not activate transcription simply by increasing the local negative supercoiling of the DNA helix in the downstream promoter region or by differential binding to relaxed and supercoiled DNA templates.

How is osmotic regulation of transcription of the Escherichia coli proU operon achieved? A review and a model

The proU operon in enterobacteria encodes a binding-protein-dependent transporter for the active uptake of glycine betaine and L-proline, and serves an adaptive role during growth of cells in hyperosmolar environments. Transcription of proU is induced 400-fold under these conditions, but the underlying signal transduction mechanisms are incompletely understood. Increased DNA supercoiling and activation by potassium glutamate have each been proposed in alternative models as mediators of proU osmoresponsivity. We review here the available experimental data on proU regulation, and in particular the roles for DNA supercoiling, potassium glutamate, histone-like proteins of the bacterial nucleoid, and alternative sigma factors of RNA polymerase in such regulation. We also propose a new unifying model, in which the pronounced osmotic regulation of proU expression is achieved through the additive effects of at least three separate mechanisms, each comprised of a cis element [two promoters P1 and P2, and negative-regulatory-element (NRE) downstream of both promoters] and distinct trans-acting factors that interact with it: stationary-phase sigma factor RpoS with P1, nucleoid proteins HU and IHF with P2, and nucleoid protein H-NS with the NRE. In this model, potassium glutamate may activate proU expression through each of the three mechanisms whereas DNA supercoiling has a very limited role, if any, in the osmotic induction of proU transcription. We also suggest that proU may be a virulence gene in the pathogenic enterobacteria.

The sigma 54-dependent promoter Ps of the TOL plasmid of Pseudomonas putida requires HU for transcriptional activation in vivo by XylR

In the presence of toluene and xylenes, the sigma 54-dependent Ps promoter of the TOL (toluene biodegradation) plasmid pWW0 of Pseudomonas putida is activated at a distance by the XylR protein, of the NtrC family of transcriptional regulators. Since contacts between XylR bound to upstream activating sites and the RNA polymerase require the looping out of the intervening DNA segment, the intrinsic curvature, the bendability of the corresponding sequence, and the spatial effects of protein-induced DNA bending have an influence on promoter activity. Unlike other sigma 54-dependent promoters, Ps does not require the structural aid of the integration host factor to assemble a specific promoter geometry required for transcriptional initiation. In vivo analysis of transcriptional activity in various genetic backgrounds suggests, instead, that the looping out of intervening DNA sequences in Ps would result from the exacerbation of a preexisting static bend within the region, assisted by the histone-like protein HU.

Virus DNA packaging: the strategy used by phage lambda

Phage lambda, like a number of other large DNA bacteriophages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is co-ordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the lambda DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric lambda DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN to complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endonuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNu1, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in lambda has aspects that differ from other lambda DNA transactions. Unlike the site-specific recombination system of lambda, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complex, and unlike the DNA replication system of lambda, the same protein machinery is used for both initiation and translocation during lambda DNA packaging.

Expression of the genes coding for the Escherichia coli integration host factor are controlled by growth phase, rpoS, ppGpp and by autoregulation

Transcriptional control of the himA and the himD/hip genes coding for the two subunits of the integration host factor (IHF) was investigated. The promoters for the two genes were identified by the use of primer extension and S1 analysis. Expression from both promoters was found to increase as the cells enter stationary phase. Mutation in rpoS, known to be induced upon entry to stationary phase, dramatically reduced the growth-phase response of the himA P4 promoter but had only a small effect on the induction of the himD/hip promoter. The increased activity of both promoters required the presence of the relA and spoT genes, suggesting that ppGpp plays a major role in the response to stationary phase. An artificial increase in ppGpp in exponentially growing cells induced a rapid increase in himA P4 and himD/hip mRNA levels. Experiments with a mutant defective in rpoS showed that the response of the himA P4 promoter to high ppGpp levels was greatly reduced while that of himD/hip was only slightly affected. Therefore, it seems that different mechanisms involving RpoS and ppGpp regulate the growth-phase response of the two promoters. We propose that the effect of ppGpp on himA P4 is mediated via RpoS whereas the himD/hip promoter is affected by ppGpp independently of RpoS. Expression of the himD/hip and himA genes was found to be subject to negative autoregulation. IHF-binding sites, implicated in autoregulation, were found to overlap both the himD/hip and himA P4 promoters. An additional IHF-binding site was found upstream of the himD/hip promoter. All three sites show low binding affinity to IHF suggesting that autoregulation can take place only after sufficiently high levels of IHF accumulate in the cell.

Evidence for involvement of proteins HU and RpoS in transcription of the osmoresponsive proU operon in Escherichia coli

Transcription of the proU operon of Escherichia coli is induced several hundred-fold upon growth at elevated osmolarity, but the underlying mechanisms are incompletely understood. Three cis elements appear to act additively to mediate proU osmoresponsivity: (i) sequences around a promoter, P1, which is situated 250 bp upstream of the first structural gene proV; (ii) sequences around another (sigma 70-dependent) promoter, P2, which is situated 60 bp upstream of proV; and (iii) a negative regulatory element present within the proV coding region. These three cis elements are designated, respectively, P1R, P2R, and NRE. trans-acting mutants with partially derepressed proU expression have been obtained earlier, and a vast majority of the mutations affect the gene encoding the nucleoid protein HNS. In this study we employed a selection for trans-acting mutants with reduced proU+ expression, and we obtained a derivative that had suffered mutations in two separate loci designated dpeA and dpeB. The dpeB mutation caused a marked reduction in promoter P1 expression and was allelic to rpoS, the structural gene for the stationary-phase-specific sigma factor of RNA polymerase. Expression from P1 was markedly induced, in an RpoS-dependent manner, in stationary-phase cultures. In contrast to the behavior of the isolated P1 promoter, transcription from a construct carrying the entire proU cis-regulatory region (P1R plus P2R plus NRE) was not significantly affected by either growth phase or RpoS. The dpeA locus was allelic to hupB, which along with hupA encodes the nucleoid protein HU. hupA hupB double mutants exhibited a pronounced reduction in proU osmotic inducibility. HU appears to affect proU regulation through the P2R mechanism, whereas the effect of HNS is mediated through the NRE.

Growth phase variation of integration host factor level in Escherichia coli

We have measured the intracellular abundance of integration host factor (IHF), a site-specific, heterodimeric DNA-binding protein, in exponential- and stationary-phase cultures of Escherichia coli K-12. Western immunoblot analysis showed that cultures that had been growing exponentially for several generations contained 0.5 to 1.0 ng of IHF subunits per microgram of total protein and that this increased to 5 to 6 ng/microgram in late-stationary-phase cultures. IHF is about one-third to one-half as abundant in exponentially growing cells as HU, a structurally related protein that binds DNA with little or no site specificity. Wild-type IHF is metabolically stable, but deletion mutations that eliminated one subunit reduced the abundance of the other when cells enter stationary phase. We attribute this reduction to the loss of stabilizing interactions between subunits. A mutation that inactivates IHF function but not subunit interaction increased IHF abundance, consistent with results of previous work showing that IHF synthesis is negatively autoregulated. We estimate that steady-state exponential-phase cultures contain about 8,500 to 17,000 IHF dimers per cell, a surprisingly large number for a site-specific DNA-binding protein with a limited number of specific sites. Nevertheless, small reductions in IHF abundance had significant effects on several IHF-dependent functions, suggesting that the wild-type exponential phase level is not in large excess of the minimum required for occupancy of physiologically important IHF-binding sites.

Genetic and biochemical analysis of IHF/HU hybrid proteins

Integration host factor (IHF) is a small heterodimeric DNA-binding protein of E coli composed of two subunits, alpha and beta, encoded by the himA and hip genes, respectively. IHF binds to DNA at a consensus sequence and bends DNA. HU protein, encoded by the hupA and hupB genes, is similar to IHF except that it does not bind to a specific DNA sequence. To investigate the protein determinants for IHF specificity we exchanged progressively longer segments from the C-terminus of Hip with those of HupA, and followed the activity in vivo and in vitro of four such IHF/HU hybrids. Replacement of 11 residues from the C-terminal alpha helix of Hip by the complementary eight residues of HupA (hybrid 1), had only minor effects on the DNA binding activity of the protein. As progressively longer segments of Hip were replaced by HupA, a precipitous decrease in IHF activity was observed. The hybrid with the longest substitution, hybrid 4, was totally inactive in vivo and could not be purified. None of the hybrid proteins could complement HU activity. Comparing the activities of hybrid 1, hybrid 2 and IHF point mutants, led us to conclude that the structural integrity of the C-terminal alpha helix and its spatial position, but not its amino acid sequence, are important for DNA binding specificity. We favor the hypothesis that alpha helices 3 of both IHF subunits interact with the body of IHF so as to anchor the arms. This interaction stabilizes the arms to permit DNA binding specificity. Thus the C-termini of IHF influence, in an indirect way, the recognition of specific sites on DNA.

Multiple molecules of integration host factor (IHF) at a single DNA binding site, the bacteriophage lambda cos I1 site

Integration host factor (IHF) is an E coli protein that binds DNA sequence-specifically and serves as a cofactor in many intracellular processes including lambda DNA packaging. In gel shift experiments, cos DNA, a DNA fragment containing the recognition signal for lambda DNA packaging, forms multiple protein-DNA complexes when combined with pure IHF. Copper(II)-1,10 orthophenanthroline footprinting of individual IHF-cos DNA complexes shows that multiple complex formation does not result from IHF binding to successive sites on the cos DNA fragment. Instead, the footprinting of DNA from two IHF-cos complexes shows protection at one site alone. DNA in the first complex is only partially protected from nucleolytic cleavage, while DNA in the second, slower-moving, complex is completely protected at the same binding site. Quantitative Western blotting experiments determined the relative stoichiometry of IHF to DNA in the two complexes. The results confirm that two molecules of IHF bind at a single site in the cos fragment. This site, cos I1, has two matches to the IHF consensus sequence, but the two matches overlap by eight of thirteen nucleotides. A search of the DNA sequence around cos, using an expanded IHF consensus sequence, has revealed additional, low-affinity consensus matches, contiguous to these. The extent of the copper(II)-1,10 orthophenanthroline footprint and the stoichiometry of the IHF-cos I1 complexes suggest that either two molecules of IHF bind to overlapping sites, or IHF binds to a site of low affinity contiguous to a strong site. Application of a thermodynamic model to the results of gel shift experiments with IHF and cos DNA suggests that multiple complex formation requires cooperative interaction between the two IHF binding sites.

Integration host factor binds to a unique class of complex repetitive extragenic DNA sequences in Escherichia coli

Interspersed repeated DNA sequences are characteristic features of both prokaryotic and eukaryotic genomes. REP sequences are defined as conserved repetitive extragenic palindromic sequences and are found in Escherichia coli, Salmonella typhimurium and other closely related enteric bacteria. These REP sequences may participate in the folding of the bacterial chromosome. In this work we describe a unique class of 28 conserved complex REP clusters, about 100bp long, in which two inverted REPs are separated by a singular integration host factor (IHF) recognition sequence. We term these sequences RIP (for repetitive IHF-binding palindromic) elements and demonstrate that IHF binds to them specifically. It is estimated that there are about 70 RIP elements in E. coli. Our analysis shows that the RIP elements are evenly distributed around the bacterial chromosome. The possible function of the RIP element is discussed.

Deformation of DNA during site-specific recombination of bacteriophage lambda: replacement of IHF protein by HU protein or sequence-directed bends

Escherichia coli IHF protein is a prominent component of bacteriophage lambda integration and excision that binds specifically to DNA. We find that the homologous protein HU, a nonspecific DNA binding protein, can substitute for IHF during excisive recombination of a plasmid containing the prophage attachment sites attL and attR but not during integrative recombination between attP and attB. We have examined whether IHF and HU function in excisive recombination is mediated through DNA bending. Our strategy has been to construct chimeric attachment sites in which IHF binding sites are replaced by an alternative source of DNA deformation. Previously, we demonstrated that properly phased bends can substitute for the binding of IHF at one site in attP. Although this result is highly suggestive of a critical role of IHF-promoted bending in lambda integration, its interpretation is obscured by the continued need for IHF binding to the remaining IHF sites of these constructs. In the present work, we engineered a population of sequence-directed bends in the vicinity of the two essential IHF sites found in attR and attL. Even in the absence of IHF or HU, pairs of these attachment sites with properly phased bends are active for both in vitro and in vivo excision. This success, although tempered by the limited efficiency of these systems, reinforces our interpretation that IHF functions primarily as an architectural element.

Genetic analysis of mutations affecting terminase, the bacteriophage lambda DNA packaging enzyme, that suppress mutations in cosB, the terminase binding site

Terminase, the DNA packaging enzyme of phage lambda, binds to lambda DNA at a site called cosB, and introduces staggered nicks at an adjacent site, cosN, to generate the cohesive ends of virion lambda DNA molecules. Terminase also is involved in separation of the cohesive ends and in binding the prohead, the empty protein shell into which lambda DNA is packaged. Terminase is a DNA-dependent ATPase, and both subunits, gpNu1 and gpA, have ATPase activity. cosB contains a series of gpNu1 binding sites, R3, R2 and R1; between R3 and R2 is a binding site, I1, for integration host factor (IHF), the Escherichia coli DNA bending protein. In this work, a series of mutations in Nu1 have been isolated as suppressors of cosB mutations. One of the Nu1 mutations is identical to the previously described Nu1ms1/ohm1 mutation predicted to cause the change L40F in the 181 amino acid-long gpNu1. Three other Nu1 missense mutations, the Nu1ms2 (L40I), ms3 (Q97K) and ms4 (A92G) mutations, have been isolated; the relative strengths of suppression of cosB mutations by the Nu1ms mutations are: ms1 > ms2 > ms3 > ms4. The Nu1 missense mutations all affect amino acid residues that lie outside of the putative helix-turn-helix DNA binding motif of gpNu1. The Nu1ms1 and Nu1ms2 mutations alter an amino acid residue (L40) that lies directly between two segments of gpNu1 proposed to be involved in ATP binding and hydrolysis; thus these mutations are likely to alter the gpNu1 ATP-binding site. The Nu1ms3 and Nu1ms4 mutations both affect amino acid residues in the central region of gpNu1 that is predicted to form a hydrophilic alpha-helix. To explain how the Nu1ms mutations suppress cosB defects, models involving alterations of the DNA binding and/or catalytic properties of terminase are considered. The results also indicate that terminase occupancy of a single gpNu1 binding site (R3) is necessary and sufficient for the efficient initiation of DNA packaging; the Nu1ms1, ms2 and ms3 mutations permit IHF-independent plaque formation by a phage lacking R2 and R1.

Genetic analysis of cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda

cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda, consists of three binding sites (called R3, R2 and R1) for gpNu1, the small subunit of terminase; and I1, a binding site for integration host factor (IHF), the DNA bending protein of Escherichia coli. cosB is located between cosN, the site where terminase introduces staggered nicks to generate cohesive ends, and the Nu1 gene; the order of sites is: cosN-R3-I1-R2-R1-Nu1. A series of lambda mutants have been constructed that have single base-pair C-to-T transition mutations in R3, R2 and R1. A single base-pair transition mutation within any one of the gpNul binding sites renders lambda dependent upon IHF for plaque formation. lambda phage with mutations in both R2 and R3 are incapable of plaque formation even in the presence of IHF. Phages that carry DNA insertions between R1 and R2, from 7 to 20 base-pairs long, are also IHF-dependent, demonstrating the requirement for a precise spacing of gpNu1 binding sites within cosB. The IHF-dependent phenotype of a lambda mutant carrying a deletion of the R1 sequence indicates that IHF obviates the need for terminase binding to the R1 site. In contrast, a lambda mutant deleted for R2 and R1 fails to form plaques on either IHF+ or IHF- cells, indicating terminase binding of R2 is involved in suppression of R mutants by IHF. A fourth R sequence, R4, is situated on the left side of cosN; a phage with a mutant R4 sequence shows a reduced burst size on both an IHF+ and an IHF- host. The inability of the R4- mutant to be suppressed by IHF, plus the fact that R4 does not bind gpNu1, suggests R4 is not part of cosB and may play a role in DNA packaging that is distinct from that of cosB.

Interaction between bacteriophage lambda and its Escherichia coli host

Bacteriophage lambda relies to a large extent on processes requiring interactions between viral- and host-encoded proteins for its lytic growth, establishment of lysogeny, and release from the prophage state. Both biochemical and genetic studies of these interactions have yielded new information about important host and lambda functions. In particular, mutations in Escherichia coli that compromise lambda DNA replication, genome packaging, transcription elongation, and site-specific recombination have led to the identification of bacterial genes whose products are chaperones, transcription factors, or DNA-binding proteins.

Genes coding for integration host factor are conserved in gram-negative bacteria

A genetic system for the selection of clones coding for integration host factor and HU homologs is described. We demonstrate that the himA and hip genes of Serratia marcescens and Aeromonas proteolytica can substitute for the Escherichia coli genes in a variety of biological assays. We find that the sequence and genetic organization of the himA and hip genes of S. marcescens are highly conserved.

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.