Morphogenesis of the tail of bacteriophage lambda. III. Morphogenetic pathway.

Precursors of the tail of bacteriophage λ have been detected by measurements of in vitro complementation activities and serum blocking activity in sucrose gradients of lysates defective in tail genes.On the basis of these measurements, a pathway for the assembly of the λ tail is proposed:The morphogenesis of the λ tail starts from the tail fiber (product of gene J) located at the distal end of the tail, and proceeds to the proximal end. Gene J by itself produces a 15 S structure with serum blocking activity but without any detectable in vitro complementation activity, which may be the least advanced precursor of the λ tail or an abortive product. Functions of genes J, I, K, L are required for the formation of a 15 S precursor that has in vitro complementation activities with J⁻, I⁻, K⁻ and L⁻ lysates and serum blocking activity. If the products of genes G and H act on the latter 15 S precursor, a 25 S precursor is made, but this precursor seems either to be in equilibrium with the 15 S precursor or to degrade easily into the 15 S precursor. Gene M has a function of stabilizing the 25 S precursor. After the action of gene M product, the 25 S precursor is ready to serve as a nucleus on which the product of gene V (the major tail protein) assembles. However, gene U product is also necessary at this step for the correct assembly of the major tail protein on the 25 S precursor. Without gene U product the assembly of the major tail protein does not stop at the correct length and a polytail is formed instead of a morphologically normal tail. Finally, gene Z product acts on the morphologically normal tail and makes it a biologically active tail. Without the action of gene Z product, the defective tail binds to a head and forms a phage-like particle which is only very weakly infectious. (The position of gene T in the pathway is not determined, because no sus mutant is available in gene T.)Two abnormal, less efficient pathways are also present in vitro. (1) If gene U product acts on a polytail in an U⁻ lysate, the polytail finally binds to a head and forms a phage particle with an extra long tail which is infectious to a small extent. (2) The function of gene K seems to be bypassed to some extent: K⁻ lysates accumulate particles which sediment as fast as normal phage and which are complemented by other tail⁻ lysates.     

Orientation of the DNA in the filamentous bacteriophage f1

The filamentous bacteriophage f1 consists of a molecule of circular single-stranded DNA coated along its length by about 2700 molecules of the B protein. Five molecules of the A protein and five molecules of the D protein are located near or at one end of the virion, while ten molecules of the C protein are located near or at the opposite end. The two ends of the phage can be separated by reacting phage fragments, which have been generated by passage of intact phage through a French press, with antibody directed against the A protein (Grant et al., 1981a). By hybridizing the DNA isolated from either end of ³²P-labeled phage to specific restriction fragments of fl replicative form I DNA, we have determined that the single-stranded DNA of the filamentous bacteriophage f1 is oriented within the virion. For wild-type phage, the DNA that codes for the gene III protein is located at the A and D protein end and that which corresponds to the intergenic region is located close to the C protein end of the particle. The intergenic region codes for no protein but contains the origins for both viral and complementary strand DNA synthesis. Analysis of the DNA orientation in phage in which the plasmid pBR322 has been inserted into different positions within the intergenic region of fl shows that the C protein end of all sizes of filamentous phage particles appears to contain a common sequence of phage DNA. This sequence is located near the junction of gene IV and the intergenic region, and probably is important for normal packaging of phage DNA into infectious particles. There appears to be no specific requirement for the origins of viral and complementary strand DNA synthesis to be at the end of a phage particle.     

Genetic control of whisker antigen of bacteriophage T4D

An antigenic component of T4 whiskers (short fibrils located in the region of the head—tail junction) has been reported to be under the control of gene 49 (Yanagida & Ahmad-Zadeh, 1970; Yanagida, 1972). This was based on immunological evidence using antiserum to particles of T4D adsorbed with gene 49-defective extract made with the mutant amE727. The latter phage, however, is shown here to be a double mutant bearing amber mutations in gene 49 and another gene, herein referred to as wac (whisker antigen control gene). Gene wac maps in the general region of gene 16. Evidence is presented indicating that the whisker antigen is under the control of wac and not gene 49. In wac-defective infections phage are produced that lack a protein. This protein appears by electrophoretic analysis in sodium dodecyl sulfate-polyacrylamide gels to be the major component of the antigen.The tail fibers of wac-defective bacteriophage are in an open configuration under conditions in which those of wild-type phage are folded alongside the tail. Thus, the wac gene may have a role in the regulation of tail-fiber configuration.     

Head length determination in bacteriophage T4: The role of the core protein P22

We have found that two different temperature-sensitive mutations in gene 22, tsA74 and ts22-2, produce high frequencies (up to 85%) of petite phage particles when grown at a permissive or intermediate temperature. Moreover, the ratio of petite to normal particles in a lysate depends upon the temperature at which the phage are grown. These petite phage particles appear to have approximately isometric heads when viewed in the electron microscope, and can be distinguished from normal particles by their sedimentation coefficient and by their buoyant density in CsCl. They are biologically active as detected by their ability to complement a co-infecting amber helper phage. Lysates of both mutants grown at a permissive temperature reveal not only a significant number of petite phage particles in the electron microscope, but also sizeable classes of wider-than-normal particles, particles having abnormally attached tails, and others having more than one tail.Striking protein differences exist between the purified phage particles of tsA74 or ts22-2 and wild-type T4. B1¹, a 61,000 molecular weight head protein, is completely absent from the phage particles of both mutants, and the internal protein IPIII¹ is present in reduced amounts as compared to wild type. The precursor to B1¹ is present in the lysates, but these mutations appear to prevent its incorporation into heads, so it does not become cleaved.The product of gene 22 (P22) is known to be the major protein of the morphogenetic core of the T4 head. Besides the mutations reported here, several mutations which affect head length have been found in gene 23, which codes for the major capsid protein (Doermann et al., 1973b). We suggest a model in which head length is determined by an interaction between the core (P22 and IPIII) and the outer shell (P23).     

Cleavage of head and tail proteins during bacteriophage T5 assembly: selective host involvement in the cleavage of a tail protein

Electrophoresis studies showed that at least three phage-specified proteins undergo proteolytic cleavage during the development of bacteriophage T5. One of these proteins has a molecular weight of about 135,000 and the product of this cleavage reaction is a minor component of the T5 tail, having a molecular weight of about 128,000. All of the tail-defective T5 mutants studied in this report failed to induce this cleavage reaction under restrictive conditions. This reaction also failed to occur in Escherichia coli groEA639 and groEA36 infected with wild type T5. Examination of lysates of infected groE cells in the electron microscope revealed the presence of filled and empty heads as well as tubular head structures, but no tails were detected. The filled heads were able to combine with separately prepared T5 tails in vitro to form infectious phage particles. Therefore, propagation of T5 in these groE mutants is prevented primarily by a specific block in tail assembly. A T5 mutant, T5?6, was isolated, which has the capacity to propagate in these groE hosts. The gene locus in T5?6 was mapped.The second T5 protein which is cleaved has a molecular weight of 50,000 and is related to head morphogenesis. Treatment of infected cells with l-canavanine (50 μg/ml) inhibited cleavage of this polypeptide. Only small quantities of the major head protein (32,000 mol. wt) were produced in these treated cells. Treatment with canavanine lead to production of tubular heads. The major protein component of partially purified tubular heads has a molecular weight of 50,000. Cells infected with T5 amber H30b, a mutant defective in head gene D20, does not produce the 50,000 and 32,000 molecular weight proteins. These findings suggest that the 50,000 molecular weight protein undergoes cleavage to form the major head polypeptide. A third T5 protein is cleaved to form a minor head component with a molecular weight of 43,000 and its cleavage is linked to that involving the major head protein.     

A component of the side tail fiber of Escherichia coli bacteriophage lambda can functionally replace the receptor-recognizing part of a long tail fiber protein of the unrelated bacteriophage T4.

The distal part of the long tail fiber of Escherichia coli bacteriophage T4 consists of a dimer of protein 37. Dimerization requires the catalytic action of protein 38, which is encoded by T4 and is not present in the virion. It had previously been shown that gene tfa of the otherwise entirely unrelated phage lambda can functionally replace gene 38. Open reading frame (ORF) 314, which encodes a protein that exhibits homology to a COOH-terminal area of protein 37, is located immediately upstream of tfa. The gene was cloned and expressed in E. coli. An antiserum against the corresponding polypeptide showed that it was present in phage lambda. The serum also reacted with the long tail fibers of phage T4 near their free ends. An area of the gene encoding a COOH-terminal region of ORF 314 was recombined, together with tfa, into the genome of T4, thus replacing gene 38 and a part of gene 37 that codes for a COOH-terminal part of protein 37. Such T4-lambda hybrids, unlike T4, required the presence of outer membrane protein OmpC for infection of E. coli B. An ompC missense mutant of E. coli K-12, which was still sensitive to T4, was resistant to these hybrids. We conclude that the ORF 314 protein represents a subunit of the side tail fibers of phage lambda which probably recognize the OmpC protein. ORF 314 was designated stf (side tail fiber). The results also offer an explanation for the very unusual fact that, despite identical genomic organizations, T4 and T2 produce totally different proteins 38. An ancestor of T4 from the T2 lineage may have picked up tfa and stf from a lambdoid phase, thus possibly demonstrating horizontal gene transfer between unrelated phage species.     

Attachment of tail fibers in bacteriophage T4 assembly: role of the phage whiskers.

The collar and whiskers of bacteriophage T4 extend outward from the top of the tail and play a role in regulating retraction of the tail fibers (Conley &; Wood, 1975). The collar and whiskers also are required for efficient tail fiber attachment during phage assembly. The structural gene for the collar/whisker protein is called wac. In vitro, infected-cell extracts that contain tail fibers activate whiskerless (wac) tail fiberless particles and ordinary (wac⁺) tail fiberless particles at equal rates if the extracts contain the wac⁺ gene product. However, extracts that contain tail fibers but no wac⁺ gene product activate wac particles about ten times more slowly. In vivo, whiskers are not essential for plaque formation, but a wac mutation causes a delay in the appearance of intracellular phage and a fivefold decrease in the burst size of infectious particles.The effect of the whiskers on tail fiber attachment is due to an interaction between the whisker and the distal half of the tail fiber, similar if not identical to the interaction that controls tail fiber retraction in complete phage. The following observations support this view: a slow rate of in vitro tail fiber attachment similar to that described above is seen with wac⁺ particles when they are pretreated with anti-whisker serum, or when the tail fibers carry a mutational alteration in gp36, a structural protein in the distal half fiber near the central kink. Lack of whiskers does not affect the slow rate of attachment of proximal half fibers to the baseplate of fiberless particles, but lack of whiskers greatly decreases the rate at which particles with attached proximal half fibers are activated by addition of distal half fibers. Since whiskers normally are attached to the phage only after head—tail union (Coombs &; Eiserling, 1977; Terzaghi et al., 1978), these findings explain why tail fibers do not attach efficiently to the baseplates of free tails.     

Mechanism of length determination in bacteriophage lambda tails

The mechanism of length determination in bacteriophage λ tails is discussed as a model for regulation in protein assembly systems.The λ tail is a long flexible tube ending in a conical part and a single tail fiber. Its length is exactly determined in the sense that the number of major tail protein (gpV) molecules, which comprise more than 80% of the mass of the tail, is exactly the same in all tails. Assembly of gpV is regulated by the initiator complex, which contains the tail fiber and the conical part,and by the terminator protein gpU. There are two key points in the assembly of gpV with respect to length determination. (1) Assembly of gpV on the initiator pauses at the correct tail length. Binding of gpU to the tail only fixes the pause firmly. (2) When the tail length is too short, binding of gpU to tails is inhibited.Deletions and a duplication (both in frame) in gene H, which codes for one of the proteins in the initiator, result in production of phage particles with altered tail length. Moreover, the tail length is roughly proportional to the length of the mutated versions of gene H. This shows that the tail length is measured by the length of gene H protein (gpH), which seems to be approximately as long as the tail tube, if extended like a thread, according to secondary structure prediction (α-helices connected by other structures). Various pieces of evidence show that about six molecules of gpH are attached to the remaining portion of the initiator by the C-terminal part and folded into a somewhat compact form, while they are elongated as they are enclosed in the tail tube during assembly of gpV. Unlike interaction between the length-measuring genome RNA and the coat protein of tobacco mosaic virus, the major tail protein gpV does not bind specifically to the ruler protein gpH. Rather, gpH determines the tail length by inhibiting the binding of gpU to short tails and by signalling the pause when the correct tail length is attained.     

A minor pathway leading to plaque-forming particles in bacteriophage lambda. Studies on the function of gene D

Lysates of bacteriophage λ, mutant in the head gene D, contain a minor amount of defective particles which can be isolated and complemented to infective particles by adding purified gene D product. The defective particles contain DNA with a specific infectivity in the helper assay of about 10% of phage DNA. This DNA is firmly held in the capsid and a tail is attached. Although the particles adsorb to sensitive bacteria, the DNA is not injected. The complemented, infectious particles differ from normal phage by having a lower density. After growing in a permissive host, phage particles of normal density are produced. The implications of the ability of gene D protein to bind to otherwise complete particles as a last step are discussed.     

Mapping of recognition sites for the restriction endonuclease from Escherichia coli K12 on bacteriophage PM2 DNA.

Several mutations in gene B of phage S13 appear to shorten the B protein by elimination of an N-terminal fragment, without destroying the B protein function. The shortened B protein resulting from each of these mutations can block the unique DNA-nicking properties of the S13 gene A protein. Because of the block in gene A function, normal gene B protein may have a function in phage DNA synthesis in addition to its known role in catalyzing capsid assembly.From gel electrophoresis the mutant B protein is estimated to be shorter than the normal S13 B protein by 1720 ± 70 daltons and is therefore believed to be an internal reinitiation fragment. The reinitiated fragments are functional and are made in about twice the amount of the normal B protein.The phage mutants which yield the reinitiation fragments are double mutants, each phage containing the same gene B nonsense mutation and each appearing to contain a different compensating gene B mutation. Various data support the assumption that the compensating mutations are frame-shifts, including the fact that suppression does not restore the normal-sized B protein. The reinitiation is assumed to occur at a pre-existing out-of-phase initiator codon, near the nonsense triplet; the correct reading frame would then be restored by each of the several different compensating mutations.The position of the normal S13 B protein in the gel electrophoresis pattern has been located both by elimination and shifting of the B peak, using appropriate amber mutants. The molecular weight of the S13 B protein is about 17,200, and is 2100 daltons less than the B protein of phage φX174; the S13 B protein can nevertheless substitute for the φX 174 B protein. Thus substantial portions of the B protein can be deleted without destroying its function.     

Smooth specific phage adsorption: endorhamnosidase activity of tail parts of P22

The tail parts of phage P22 as well as the phage particles cleave the O-antigen of its host bacterium, $\text{Salmonella typhimurium}$. The cleavage is caused by specific breakage of α-rhamnosyl 1–3 galactose linkages. Thus the tail parts of this phage consist of an enzyme, endorhamnosidase. The enzyme was not detected in nonpermissible strain infected with an amber gene 9 mutant of P22. Head without tail parts gains infectivity only after incubation with the tail parts which carry this enzymatic activity.     

Gene encoding a hybrid OmpF-PhoE pore protein in the outer membrane of Escherichia coli K12

Summary To study the structure-function relationship of outer membrane pore proteins of E. coli K12, a hybrid gene was constructed in which the DNA encoding amino acid residues 2–73 of the mature PhoE protein is replaced by the homologous part of the related ompF gene. The product of this gene is incorporated normally into the outer membrane. It was characterized with respect to its pore activity and its phage receptor and colicin receptor properties. It is concluded (i) that the preference of the PhoE protein pore for negatively charged solutes is partly determined by the amino terminal 73 amino acids, (ii) that part of the receptor site of PhoE protein for phage TC45 is located in this part of the protein, (iii) that colicin N uses OmpF protein as (part of) its receptor, (iv) that the specificity of OmpF protein as a colicin N receptor is completely located within the 80 amino terminal amino acid residues, whereas the specificity of this protein as a colicin A receptor is completely located within the 260 carboxy terminal amino acid residues, and (v) that the amino terminal 73 amino acid residues of PhoE protein span the membrane at least once.     

Dual Functions of Bacteriophage T4D Gene 28 Product: Structural Component of the Viral Tail Baseplate Central Plug and Cleavage Enzyme for Folyl Polyglutamates I. Identification of T4D Gene 28 Product in the Tail Plug

The T4D bacteriophage gene 28 product is a component of the central plug of the tail baseplate, as shown by the following two independent lines of evidence. (i) A highly sensitive method for radioactive labeling of only tail baseplate plug components was developed. These labeled plug components were incorporated by a complementation procedure into new phage particles and were analyzed by radioautography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three new structural proteins were found in addition to the three known tail plug proteins (i.e., gP29, gP27, and gP5). One of the three newly identified components had a molecular weight of 24,000 to 25,000 and appeared to be a product of T4D gene 28. (ii) Characterization of mutants of Escherichia coli bacteriophage T4D which produced altered gene 28 products also indicated that the gene 28 product was a viral tail component. T4D 28^ts phage particles produced at the permissive temperature had altered heat labilities compared with parent T4D particles. We isolated a single-step temperature revertant of T4D 28^ts and found that it produced phage particles which phenotypically resembled the original T4D particles. Since the properties of the phage baseplate components usually determine heat lability, these two changes in physical stability after two sequential single mutations in gene 28 supported the other evidence that the gene 28 product was a viral baseplate component. Also, compared with parent T4D particles, T4D 28^ts and T4D 28am viral particles adsorbed at different rates to various types of host cells. In addition, T4D 28^ts particles exhibited a different host range than parent T4D particles. This T4D mutant formed plaques with an extremely low efficiency on all E. coli K-12 strains tested. We found that although T4D 28^ts particles adsorbed rapidly and irreversibly to the E. coli K-12 strains, as judged by gene rescue experiments, these particles were not able to inject their DNA into the E. coli K-12 strains. On the other hand, the T4D 28^ts revertant had a plating efficiency on E. coli K-12 strains that was quite similar to the plating efficiency of the original parent, T4D. These properties of phage particles containing an altered gene 28 product supported the analytical finding that the gene 28 product is a structural component of the central plug of the T4D tail baseplate. They also indicated that this component plays a role in both host cell recognition and viral DNA injection.     

Maturation of the head of bacteriophage T4. II. Head-related, aberrant tau-particles

Three somewhat different types of particle accumulate in cells infected with a phage carrying a mutation in gene 21 (in addition to the tubular variant (polyhead) of the head). The major type is the so-called τ-particle. These particles are very fragile, associated with the cell membrane, and have a sedimentation coefficient of about 420 S. They possess no DNA if isolated, and contain predominantly the precursor proteins P23, P24, P22 and the internal protein IP III, in addition to protein P20 and several proteins of unknown genetic origin.The remainder of the particles are partially or completely filled with DNA. The ratio of τ-particles to these partially or completely filled particles depends upon the particular mutant (in gene 21) phage used. In cells infected with a phage carrying the amber mutation (N90) in gene 21, about 10% of the precursor head protein P23 is cleaved to P231, and correspondingly about 10% of the particles are partially or completely filled with DNA. In cells infected with the temperature-sensitive mutant (N8) in gene 21, about 1% of the particles are fully or partially filled, and correspondingly about 1% of the P23 is cleaved to P231. In either case, the DNA-associated particles contain predominantly the cleaved proteins P231 and IP III1, and have none of the P22 and IP III found in τ-particles. This observation, and the correlation of the amount of partially or completely filled particles with the extent of the cleavage of P23 in the lysates, strongly suggest that cleavage of the head proteins is required for DNA packaging to occur.The τ-particles have properties similar to the so-called prohead I particles which we have isolated as intermediates in wild-type head assembly (preceding paper). However, temperature shift-down experiments, using several different phage carrying temperature-sensitive mutations in gene 21, indicate that the bulk of the τ-particles cannot be used for normal phage production.     

Altered arrangement of the DNA in injection-defective lambda bacteriophage.

We have characterized two variant bacteriophage λ particles, λZ^? and λdocL, that have low infectivity but normal morphology. The low infectivity is due, at least in part, to a defect in DNA injection. This defect is probably the result of an altered location of the right end of the chromosome with respect to the phage tail: the right end of λZ^? and λdocL DNA, in contrast to that of wild-type λ, cannot be cross-linked to the tail. The cross-linking experiments were greatly facilitated by a new technique that allows routine spreading of DNA for electron microscopy without the use of a protein film.We propose that the Z gene product, a tail protein, acts by recognizing a specific feature near the right terminus of the DNA and promoting its insertion into the tail. This feature is presumably missing in most λdocL particles.     

Structural and Functional Studies of gpX of Escherichia coli Phage P2 Reveal a Widespread Role for LysM Domains in the Baseplates of Contractile-Tailed Phages

A variety of bacterial pathogenicity determinants, including the type VI secretion system and the virulence cassettes from Photorhabdus and Serratia, share an evolutionary origin with contractile-tailed myophages. The well-characterized Escherichia coli phage P2 provides an excellent system for studies related to these systems, as its protein composition appears to represent the “minimal” myophage tail. In this study, we used nuclear magnetic resonance (NMR) spectroscopy to determine the solution structure of gpX, a 68-residue tail baseplate protein. Although the sequence and structure of gpX are similar to those of LysM domains, which are a large family associated with peptidoglycan binding, we did not detect a peptidoglycan-binding activity for gpX. However, bioinformatic analysis revealed that half of all myophages, including all that possess phage T4-like baseplates, encode a tail protein with a LysM-like domain, emphasizing a widespread role for this domain in baseplate function. While phage P2 gpX comprises only a single LysM domain, many myophages display LysM domain fusions with other tail proteins, such as the DNA circulation protein found in Mu-like phages and gp53 of T4-like phages. Electron microscopy of P2 phage particles with an incorporated gpX-maltose binding protein fusion revealed that gpX is located at the top of the baseplate, near the junction of the baseplate and tail tube. gpW, the orthologue of phage T4 gp25, was also found to localize to this region. A general colocalization of LysM-like domains and gpW homologues in diverse phages is supported by our bioinformatic analysis.     

Rodent phylogeny revised: analysis of six nuclear genes from all major rodent clades

Background

Bacterial biofilm is ubiquitous in nature. However, it is not clear how this crowded habitat would impact the evolution of bacteriophage (phage) life history traits. In this study, we constructed isogenic λ phage strains that only differed in their adsorption rates, because of the presence/absence of extra side tail fibers or improved tail fiber J, and maker states. The high cell density and viscosity of the biofilm environment was approximated by the standard double-layer agar plate. The phage infection cycle in the biofilm environment was decomposed into three stages: settlement on to the biofilm surface, production of phage progeny inside the biofilm, and emigration of phage progeny out of the current focus of infection.

Results

We found that in all cases high adsorption rate is beneficial for phage settlement, but detrimental to phage production (in terms of plaque size and productivity) and emigration out of the current plaque. Overall, the advantage of high adsorption accrued during settlement is more than offset by the disadvantages experienced during the production and emigration stages. The advantage of low adsorption rate was further demonstrated by the rapid emergence of low-adsorption mutant from a high-adsorption phage strain with the side tail fibers. DNA sequencing showed that 19 out of the 21 independent mutant clones have mutations in the stf gene, with the majority of them being single-nucleotide insertion/deletion mutations occurring in regions with homonucleotide runs.

Conclusion

We conclude that high mutation rate of the stf gene would ensure the existence of side tail fiber polymorphism, thus contributing to rapid adaptation of the phage population between diametrically different habitats of benthic biofilm and planktonic liquid culture. Such adaptability would also help to explain the maintenance of the stf gene in phage λ's genome.     

Physical characterization of bacteriophage MX4, a generalized transducing phage for Myxococcus xanthus.

A generalized transducing bacteriophage of Myxococcus xanthus has been examined. The phage particle consists of an isometric head and a contractile tail. The genome of the phage is a linear DNA molecule of molecular weight 39 ± 2.1 × 10⁶, which contains the normal DNA bases 70% of which are guanosine + cytosine. No overall heterogeneity of base composition is present. The DNA does not carry easily detectable cohesive ends nor is it cyclically permuted. It does contain a large and somewhat variable terminal redundancy. Heating phage particles in the presence of EDTA causes tail sheath contraction and ejection of DNA, some of which remains attached to the tail. Digestion of tail-bound DNA with restriction enzymes shows that the phage tail can be attached to either end of the DNA. Thus the DNA probably contains recognition sites for the packaging of its DNA at both ends. These results suggest possible mechanisms for the genesis of transducing particles by phage MX4.     

Packaging of coliphage lambda DNA. I. The role of the cohesive end site and the gene A protein

The cohesive ends of the DNA of bacteriophage λ particles are normally formed by the action of a nuclease on the cohesive end sites (cos) of concatemeric λ DNA (reviewed by Hohn et al., 1977). The nuclease also cuts the cos site of an integrated prophage, and DNA located to the right is preferentially packaged into phage particles. This process occurs with approximately the same efficiency and rate in a single lysogen as in a tandem polylysogen. Thus, the rate of cos cutting does not increase when the number of cos sites per molecule increases, an hypothesis that has been proposed to explain why cohesive ends are not formed in circular monomers of λ DNA. We propose instead that the interaction of Ter with cos is influenced by the configuration of the DNA outside of cos during packaging, and that this configuration is different for circular monomers than for other forms of λ DNA. A model that gives rise to such a difference is described.We also found that missense mutations in the λ A gene changed the efficiency of packaging of phage relative to host DNA. This was not the case for missense mutations in several phage genes required for capsid formation. Thus, the product of gene A plays a role in determining packaging specificity, as expected if it is or is part of the nuclease that cuts λ DNA at cos.