Relationships among genes and gene products of bacteriophage BF23

Twenty-five gene products of bacteriophage BF23 were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their functions were studied in relation to type I and II genes classified by means of genetic complementation tests. All the type I mutants were defective in the synthesis of a tail protein, L3. In addition, 4 type I gene products, L5 (gp21), L7 (gp20), L8 (gp29), and L9 (gp25), were identified as constituents of tails (gp21 denotes that a protein is a product of gene 21). Three type IIb mutants in genes 10, 14, and 19 diminished substantially the production of late proteins, including tail and head proteins, and the two other type IIb mutants in genes 1 and 2 were defective in the synthesis of both early and late proteins. Of 14 type IIa mutants, at least 6 were defective in phage DNA synthesis and 2 were defective in the synthesis of head proteins. The defect in the head donor activities of type IIa mutants in extract complementation tests was due to the failure of the formation of mature heads containing DNA. The above results support directly the results of the genetic characterization of BF23 genes.     

Evidence that a phage T4 DNA packaging enzyme is a processed form of the major capsid gene product

A phage T4 DNA packaging enzyme appears to arise as a processed form of the major T4 capsid structural protein gp23. The enzyme activity and antigen are missing from all head gene mutants that block the morphogenetic proteolytic processing reactions of the head proteins in vivo. The enzyme antigen can be formed in vitro by T4 (gp21) specific processing of gp23 containing extracts. Enzyme antigen is found in active processed proheads but not in full heads. The enzyme and the major capsid protein show immunological cross-reactivity, produce common peptides upon proteolysis, and share an assembly-conformation-dependent ATP binding site. The packaging enzyme and the mature capsid protein (gp23*) both appear to arise from processing of gp23, the former as a minor product of a specific gp23 structure in the prohead, acting in DNA packaging as a DNA-dependent ATPase, and a headful-dependent terminase.     

Studies on the structure, protein composition and aseembly of the neck of bacteriophage T4

We have developed an osmotic shock procedure which disconnects the tail from the head of intact bacteriophage T4, leaving the neck region attached to the tail. Purification of these necked tails permitted detailed structural observations of the neck and the collar/whisker complex attached to it, as well as comparison by gel electrophoresis with tails lacking the neck. Five or six neck proteins were found: N1 (M_r = 52,000; 39 copies/phage) is the product of the wac³ gene (Pwac), forms both the collar and six whiskers as a multimeric fibrous protein, and probably assembles onto phage after head to tail joining; N2 (M_r= 35,000; 5 to 6 copies/phage), N3 (M_r= 33,000; 17 copies/phage) identified here as P13, and N6 (M_r= 28,000; 10 to 11 copies/phage) are all assembled in heads prior to tail joining; N4 (M_r= 32,000; 6 to 9 copies/phage) is unusual in that it is present in wac or wac⁺ phage and necked tails but is absent from purified heads; N5 (M_r =29,000) is probably P14 and like N4 is not found in heads. However, while we find one to two copies of N5 per necked tail, we have not observed it in phage.An aberrant neck structure called the extension assembles on the distal end of the tail connector late (after 33 min, 30 °C) in head-defective, mutant-infected cells. The extension contains five of the six neck proteins (N2 is absent), and blocks head to tail joining in vitro. Mutations in genes 13 and 14, and the double mutant 49:Wac block extension assembly.Other results show that the wac mutant E727J is an amber lesion, and that Pwac can assemble on collarless, wac phage in vitro.     

The lambda head-tail joining reaction: purification, properties and structure of biologically active heads and tails

Procedures were developed to obtain biologically active lambda heads and tails at high purity with 20 to 40% recovery. Free heads, free tails and phage particles differ markedly in stability. Phage are stable in solutions containing Mg²⁺ but tails are not. The protein subunits which form the shaft of the tail dissociate in the presence of Mg²⁺ and form multisubunit spherical structures. EDTA protects free tails against inactivation but disrupts heads and phage particles. The four carbon diamine, putrescine, stabilizes heads against inactivation; the three and five carbon diamines are less effective. Electron micrographs reveal a new “knob” structure at the distal end of the tail fiber of phage and of free tails. Tails released from EDTA-disrupted phage possess a “head-tail connector”, a structure not present on the tail before its joining with a head.     

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).     

Transmission of amber mutants of bacteriophage T4. IV. The frequency of the phenomenon of temperature sensitivity of replication in non-permissive cells of amber mutants for the head genes

Dependence of multiplication of 42 single and double amber mutants in 16 phage head genes on the incubation temperature was studied in the cells of non-permissive host. For amber mutants in 6 head genes the birst size decreases by several orders, with the increase of the incubation temperature. Among amber mutants of the above mentioned genes, mutants in genes 4 and 65 can be distinguished as those with considerably large burst size at low temperature. Phage head genes form the groups, according to temperature sensitivity of multiplication of amber mutants. These groups, together with corresponding groups of phage tail genes, constitute common temperature-sensitive and non-sensitive gene groups on the phage genomic map.     

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 touch of glue to complete bacteriophage assembly: the tail‐to‐head joining protein (THJP) family

Bacteriophage SPP1 is a nanomachine built to infect the bacterium Bacillus subtilis. The phage particle is composed of an icosahedric capsid, which contains the viral DNA, and a long non‐contractile tail. Capsids and tails are produced in infected cells by two distinct morphogenetic pathways. Characterization of the suppressor‐sensitive mutant SPP1sus82 showed that it produces DNA‐filled capsids and tails but is unable to assemble complete virions. Its purified tails have a normal length but lack a narrow ring that tapers the tail end found at the tail‐to‐head interface. The mutant is defective in production of gp17. The gp17 ring is exposed in free tails competent for viral assembly but becomes shielded in the final virion structure. Recombinant gp17 is active in an in vitro assay to stick together capsids and tails present in extracts of SPP1sus82‐infected cells, leading to formation of infectious particles. Gp17 thus plays a fundamental role in the tail‐to‐head joining reaction, the ultimate step of virus particle assembly. This is the conserved function of gp17 and its structurally related proteins like lambda gpU. This family of proteins can also provide fidelity to termination of the tail tube elongation reaction in a subset of phages including coliphage lambda.     

Influence of the growth rate on the macromolecular composition of Acinetobacter calcoaceticus in carbon-limited chemostat culture

Abstract Infectious phage particles can be formed in vitro when extracts of T1-infected cells are incubated with T1 DNA. The DNA packaging system is based on mixtures of complementing extracts from Escherichia coli sup⁰ cells infected with the amber mutants am 4 (gene 16) or am 10 (gene 13). Gene 16 mutants are defective in the formation of DNA-filled heads but make proheads; gene 13 mutants are defective in prohead formation. Three forms of DNA have been packaged: (1) endogenous concatemeric DNA present in mixtures of am 4 and am 10 mutant extracts; (2) concatemeric DNA; (3) virion DNA both when supplied exogenously to mixtures of am 4 · am 20 and am 10 · am 20 double mutant extracts ( am 20 inhibits T1 DNA synthesis). The reaction requires added ATP, Mg²⁺ and spermidine for optimum efficiency and produces about 1.5 × 10³ pfu/ μ g and about 1 × 10⁴ pfu/ μ g for exogenous concatemeric and virion DNA, respectively.     

The receptor specificity of bacteriophages can be determined by a tail fiber modifying protein.

T-Even type bacteriophages recognize their cellular receptors with the distal ends of their long tail fibers. The distal part of these fibers consists of a dimer of gene product (gp) 37. The assembly of this gp to a functional dimer requires the action of two other proteins, gp57 and gp38. Genes (g) 38 have been cloned from five T-even type phages which use the Escherichia coli outer membrane protein OmpA as a receptor. The phages used differ in their ability to infect a series of ompA mutants producing altered OmpA proteins, i.e., each phage has a specific host range for these mutants. The cloned genes 38 complemented g38 amber mutants of phage T2, which uses the outer membrane protein OmpF as a receptor. The complemented phages had become phenotypically OmpA-dependent and, with one exception, OmpF-independent, but regained the host range of T2 upon growth in a host lacking the cloned g38. The host range of the complemented phages, as determined on the ompA mutants, was identical to, similar to, or different from that of the phage, from which the cloned g38 originated. The results presented show that gp38 from one phage can phenotypically 'imprint', in a finely-tuned manner, a host range onto gp37 of another phage with a different host specificity. In view of the extreme diversity of host ranges observed, it is suggested that gp38 of T2 and of the OmpA-specific phages may remain attached to gp37 in the phage particle and in cooperation with gp37 determine the host range.     

Amber mutants in gene 67 of phage T4. Effects on formation and shape determination of the head

Two amber mutations in gene 67 of bacteriophage T4 were constructed by oligonucleotide-directed mutagenesis and the resulting mutated genes were recombined back into the phage genome and their phenotype was studied. The 67amK1 mutation is close to the amino terminus of the gene, and phage carrying this mutation are unable to form plaques on suppressor-negative hosts. A second mutation, 67amK2, which lies in the middle of the gene, three codons N-terminal to a proteolytic cleavage site, produces a small number of viable phage particles. In suppressor-negative hosts, both mutants produce polyheads and proheads. 67amK1 assembles only few proheads that have a disorganized core structure, as judged from thin sections of infected cells. The proheads and the mature phages of both mutants are mainly isometric rather than having the usual prolate shape. Depending on the 67 mutant and the host, between 20% and 73% of the particles that are produced are isometric, and 1 to 10% are two-tailed biprolate particles. 67amK2 phages grown on a supD suppressor strain that inserts serine in place of the wild-type leucine do not contain gp67* derived from gene product 67 (gp67) by proteolytic cleavage. This demonstrates the importance of the correct amino acid at this position in the protein. Other abnormalities in these 67amK2 phages are the presence of uncleaved scaffolding core proteins (IPIII and gp68), indicating a structural alteration in the prohead scaffold, resulting in only partial cleavage. In wild-type phages these proteins are found in the head only in the cleaved form. With double-mutants of 67 with mutations in the major shell protein gp23 no naked scaffolding cores were found, confirming the necessity of gp67 for the assembly or persistence of a "normal" core.     

Studies on the In Vitro Assembly of Bacteriophage φ80 and φ80-Lambda Hybrids

Suppressor-sensitive (sus) mutants of bacteriophage 80 defective in late functions were classified, by means of in vitro assembly tests, into two complementation groups: head donors and tail donors. Each group of mutants was subdivided, by means of two-factor crosses, into six cistrons. Deletion mapping revealed clustering of tail and also of head cistrons. The two clusters were located in the left arm of vegetative 80 (the tail specifying cluster being distal). In vitro cross complementation between 80 and lambda sus mutants revealed that whereas lambda heads could quite efficiently bind 80 tails to form viable phage, the union of 80 heads and lambda tails was very much less efficient. Deletion mapping of the 80 sus mutants, using both 80 and i⁸⁰h^λ deletion lysogens indicated congruent gross gene arrangement in the two related bacteriophages.     

The bacteriophage P4 alpha gene is the structural gene for bacteriophage P4-induced RNA polymerase

Two temperature-sensitive mutants of satellite phage P4 which do not synthesize P4 DNA at the nonpermissive temperature have been isolated. One of these phage is mutated in the P4 alpha gene. It complements a P4 delta mutant, but not a P4 alpha amber mutant; both mutants are phenotypically identical to alpha amber mutants in all properties studied. They synthesize P4 early proteins 1 and 2 as well as two additional P4-induced early proteins, 5 and 6, which are described here. P4 late proteins are not synthesized by these mutants and cannot be transactivated by helper phage P2. The mutants are unable to transactivate P2 late proteins from a P2 AB mutant. The P4 RNA polymerase activity which has been suggested to be involved in P4 DNA synthesis is not detected at the nonpermissive temperature. The P4 polymerase activity in partially purified extracts prepared from cells infected with the mutant at the permissive temperature is temperature sensitive. Reduced activity is found in vitro when these extracts are preincubated at 41 degrees C or assayed at temperatures higher than 37 degrees C. Thus, the P4 RNA polymerase is the product of the alpha gene. Temperature shift experiments show that the alpha gene product is required until late in the P4 cycle.     

Structural aberrations in T-even bacteriophage. IX. Effect of mixed infection on the production of giant bacteriophage.

To date, the production of T-even bacteriophage with giant heads has been achieved in two ways: (i) by use of canavanine-arginine treatment of Escherichia coli B cultures infected by wild-type bacteriophage (Cummings and Bolin, Bacteriol. Rev. 40:314-359, 1976; Cummings et al., Virology 54:245-261, 1973), which give a size distribution of giants that is phage specific (Cummings et al., Virology 54:245-261, 1973); and (ii) by infection with certain missense mutants of T4D gene 23 (Doermann et al., J. Virol. 12:374-385, 1973; ICN-UCLA Symposium on Molecular Biology, p. 243-285, 1973) or temperature-sensitive mutants of gene 24 (Aebi et al., J. Supramol. Struct. 2:253-275, 1974; Biljenga et al., J. Mol. Biol. 103:469-498, 1976). We now report the effect of mixed infection with several mutants of T4D on both the production and the size of giant bacteriophage. We found that gene 24 mutant is a critical partner for the production of giants. Infection using T4.24 mutants together with either T4.23 mutants, T4B+ or T6+ led to the formation of giants with heads 10- to 14-fold longer than normal-length heads. Infection with amber 24-bypass 24 double mutants of T4D led to the production of giants when gene 23 mutant was used to co-infect. Addition of canavanine to the co-infected cultures could alter the size distribution of giants, depending on which phage were used to coinfect. Gene 22 mutants had a modifying effect on these results. In the absence of canavanine co-infection with gene 22 mutants prevented the production of giants, and in the presence of canavanine giants of 1.5 to 5 head lengths were found. We have interpreted these results to mean that critical concentrations of gene products 22, 23, and 24 interact to control head length in T-even bacteriophage.     

Mutations in coliphage p1 affecting host cell lysis

A total of 103 amber mutants of coliphage P1 were tested for lysis of nonpermissive cells. Of these, 83 caused cell lysis at the normal lysis time and have defects in particle morphogenesis. Five amber mutants, with mutations in the same gene (gene 2), caused premature lysis and may have a defect in a lysis regulator. Fifteen amber mutants were unable to cause cell lysis. Artificially lysed cells infected with five of these mutants produced viable phage particles, and phage particles were seen in thin sections of unlysed, infected cells. However, phage production by these mutants was not continued after the normal lysis time. We conclude that the defect of these five mutants is in a lysis function. The five mutations were found to be in the same gene (designated gene 17). The remaining 10 amber mutants, whose mutations were found to be in the same gene (gene 10), were also unable to cause cell lysis. They differed from those in gene 17 in that no viable phage particles were produced from artificially lysed cells, and no phage particles were seen in thin sections of unlysed, infected cells. We conclude that the gene 10 mutants cannot synthesize late proteins, and it is possible that gene 10 may code for a regulator of late gene expression for P1.     

Suppression of Amber and Ochre Mutants in Salmonella typhimurium by a Mutant F′-1-gal Factor Carrying an Ochre Suppressor Gene

A Salmonella typhimurium strain was given the amber mutation hisC527 by transduction, made galactose-negative by mutation, then infected with the F'-1-gal factor. Of 107 spontaneous and mutagen-induced histidine-independent mutants tested, 3 proved to result from suppressor mutations within the F' factor. The mutant F' factors, when transferred to S. typhimurium and E. coli auxotrophs, suppressed amber and ochre but not UGA or missense mutants, and are inferred to carry ochre suppressor genes. Attempts to isolate an F' amber suppressor mutant were unsuccessful. A suppressor F' factor was transferred to 14 rough mutants which had been isolated from LT2 hisC527 (amber) by selection for resistance to phage P22.c2. One rough mutant was partly suppressed, as shown by its acquisition of O agglutinability and by alterations in its phage resistance pattern. Phage P22h grown on the suppressed mutant contransduced its rf. gene with cysE(+) and with pyrE(+), and the affected locus is inferred to be rfaL. Both the original and the mutant F' factors conferred resistance to the rough-specific phage Br60, which is therefore "female-specific."     

Morphogenesis of bacteriophage lambda deletion mutants. I. Abnormal head-related structures produced in normal Escherichia coli.

Late in the morphogenesis of bacteriophage lambda, DNA condenses into the nascent head and is cut from a concatemeric replicative intermediate by a nucleolytic function, Ter, acting at specific sites, called cos. As a result of this process, heads of lambda deletion mutants contain less DNA than those of the wild-type phage. It has been reported that phage with very large deletions (22% of the genome or more) grow poorly but that normal growth can be restored by the non-specific addition of DNA to the genome. This finding implies that DNA content may exert a physical effect on some stage of head assembly.We have investigated the effects of two long deletions, b221 and tdel33, on head assembly. Bacteria infected with the mutants were lysed with non-ionic detergent under conditions favoring stabilization of labile structures containing condensed DNA. It has proved possible to isolate two aberrant head-related structures produced by the deletion mutants. One of these (“overfilled heads”) contains DNA which is longer than the deletion mutant genome and is about the same size as that found in wild-type heads. These structures appear to be unable to attach tails. The second type of structure (“incompletely filled heads”) contains a short piece of DNA, 40% of the length of the mutant genome. The incompletely filled heads are found both with and without attached tails. Both of these abnormal structures are initially attached to the replicating DNA but are released by treatment with DNAase. The nature of these abnormal structures indicates that very small genomes affect a late stage of head morphogenesis, after the DNA is complexed with a capsid of normal size. The results presented suggest that underfilling of the capsid interferes with the ability of the Ter function to properly cleave cos.     

Bacteriophage T4 tail assembly: structural proteins and their genetic identification

We have identified the structural proteins of phage T4 precursor tails. Complete tails, labeled with ¹⁴C-labeled amino acids, were isolated from cells infected with mutants blocked in head assembly. The proteins were characterized by sodium dodecyl sulfate-acrylamide gel electrophoresis and subsequent autoradiography. The complete tails are made up of at least fifteen different species of phage proteins.To identify the genes specifying these proteins we prepared ¹⁴C-labeled amino acid lysates made with amber mutants defective in each of the twenty-one genes involved in tail assembly. Comparison of the gel pattern of the amber mutant lysates with wild type lysates enabled us to identify the following gene products, with molecular weights in parentheses: P6 (85,000); P7 (140,000); P8 (46,000); P9 (34,000); P10 (88,000); P11 (26,000); P12 (55,000); P15 (35,000); P18 (80,000); P19 (21,000); P29 (77,000). These eleven species are all structural proteins of the tail. The genetically unidentified tail proteins have molecular weights of 42,000, 41,000, 40,000 and 35,000. They are likely to be the products of known phage genes which were not resolved in the crowded middle region of the whole lysate gel patterns. The major tail proteins are all synthesized during the late part of the phage growth cycle.The mobilities of the proteins derived from tails did not differ from the mobilities of the proteins when derived from the unassembled pools of subunits accumulating in mutant infected cells, or when derived from complete phage particles.The genes for at least seven of the structural proteins are contiguous on the genetic map. Genes for proteins needed in many copies seem to be clustered separ- ately from genes whose products are needed in only a few copies. Consideration of protein sizes and published mapping data on phage T4 also suggest that the phage structural proteins are, on the average, much larger than the non-structural proteins.The requirement that at least fifteen different species of proteins must come together in forming a phage tail emphasizes the complexity of this morphogenetic process.     

Genetic control of capsid length in bacteriophage T4 VII. A model of length regulation based on DNA size

Four models for head length regulation in bacteriophage T4 are described and discussed. Several length mutants in the major capsid protein gene (23) were studied by sucrose gradient analysis, rotating gel analysis of DNA length, and by mixed infection gene dosage experiments with T4 amber mutants in gene 24. The results show that head length variation is quantized and highly specific, in that certain amino acid changes in gp23 results in reproducible and well-defined head length phenotypes. These data are presented as being most consistent with a vernier-type of head length control mechanism.     

Proteolysis of the major capsid protein T4 bacteriophage polyheads limited by quaternary structure.

Bacteriophage T4 carrying an amber mutation in gene 22 plus an amber mutation in gene 21 form aberrant, tubular structures termed rough polyheads, instead of complete phage when they infect Escherichia coli B. These rough polyheads consist almost entirely of the major capsid protein in its uncleaved form (gp23). When rough polyheads are treated under mild conditions with any of the five proteases, trypsin, chymotrypsin, thermolysin, pronase, or the protease from Staphylococcus aureus V8, the gp23 is rapidly hydrolyzed at a limited number of peptide bonds. In contrast, cleaved capsid protein (gp23) in mature phage capsids is completely resistant to proteolysis under the same conditions. A major project in this laboratory requires determining the primary structure of gp23, a large protein (Mr = 58,000) quite rich in those amino acids at which cleavages are achieved by conventional means. Recovery of peptides from the complex mixtures resulting from such cleavages proved to be extremely difficult. The limited proteolysis of gp23 in rough polyheads had yielded a set of large, easily purified fragments which are greatly simplifying the task of determining the primary structure of this protein.