Nucleotide sequence of bacteriophage T4 gene 23 and the amino acid sequence of its product

Phylogenetic diversity of T4-like bacteriophages in Lake Baikal, East Siberia

Among the tailed phages, the myoviruses, those with contractile tails, are widespread and diverse. An important component of the Myoviridae family is the genus 'T4-like viruses'. The present study was aimed at elucidating the molecular diversity of T4-type bacteriophages in Lake Baikal by partial sequencing of g23 genes of T4-type bacteriophages. Our study revealed that the g23 gene sequences investigated were highly diverse and different from those of T4-like bacteriophages and from g23 clones obtained from different environments. Phylogenetic analysis showed that all g23 fragments from Lake Baikal, except for the one sequence, were more closely related to marine T4 cyanophages and to previously described subgroups of uncultured T4 phages from marine and rice field environments.

Molecular architecture of bacteriophage T4

In studying bacteriophage T4--one of the basic models of molecular biology for several decades--there has come a Renaissance, and this virus is now actively used as object of structural biology. The structures of six proteins of the phage particle have recently been determined at atomic resolution by X-ray crystallography. Three-dimensional reconstruction of the infection device--one of the most complex multiprotein components--has been developed on the basis of cryo-electron microscopy images. The further study of bacteriophage T4 structure will allow a better understanding of the regulation of protein folding, assembly of biological structures, and also mechanisms of functioning of the complex biological molecular machines.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Understanding viral partitioning in two-phase aqueous nonionic micellar systems: 1. Role of attractive interactions between viruses and micelles

The partitioning behavior of viruses in the two-phase aqueous nonionic n-decyl tetra(ethylene oxide) (C10E4) micellar system cannot be fully explained by considering solely the repulsive, steric, excluded-volume interactions that operate between the viruses and the nonionic C10E4 micelles. Specifically, an excluded-volume theory developed recently by our group is not able to quantitatively predict the observed viral partition coefficients, even though this theory is capable of providing reasonable quantitative predictions of protein partition coefficients. To shed light on the discrepancy between the theoretically predicted and the experimentally measured viral partition coefficients, a central assumption underlying the excluded-volume theory that the viruses and the C10E4 micelles interact solely through repulsive, excluded-volume interactions was challenged in this study. In particular, utilizing bacteriophage P22 as a model virus, a competitive inhibition test and a partitioning study of the capsids of bacteriophage P22 were conducted. Based on the results of these two experimental studies, it was concluded that any attractive interactions between the tailspikes of bacteriophage P22 and the C10E4 micelles are negligible. Another experimental study was carried out wherein the partition coefficients of the model viruses, bacteriophages P22 and T4, were measured at various temperatures, and compared with those previously obtained for bacteriophage phiX174. This comparison also indicated that possible attractive, electromagnetic-induced interactions between the bacteriophage particles and the C10E4 micelles cannot be invoked to rationalize the observed discrepancy between the theoretically predicted and the experimentally measured viral partition coefficients.

Correlation of topographic surface and volume data from three-dimensional electron microscopy

Three-dimensional(3D) reconstructions from tilt series in an electron microscope show in general an anisotropic resolution due to an instrumentally limited tilt angle. As a consequence, the information in the z direction is blurred, thus making it difficult to detect the boundary of the reconstructed structures. In contrast, high-resolution topography data from microscopic surface techniques provide exactly complementary information. The combination of topographic surface and volume data leads to a better understanding of the 3D structure. The new correlation procedure presented determines both the height scaling of the topographic surface and the relative position of surface and volume data, thus allowing information to be combined. Experimental data for crystalline T4 bacteriophage polyheads were used to test the new method. Three-dimensional volume data were reconstructed from a negatively stained tilt series. Topographic data for both surfaces were obtained by surface relief reconstruction of electron micrographs of freeze-dried and unidirectionally metal-shadowed polyheads. The combined visualization of volume data with the scaled and aligned surface data shows that the correlation technique yields meaningful results. The reported correlation method may be applied to surface data obtained by any microscopic technique yielding topographic data.

Phylogeny of the major head and tail genes of the wide-ranging T4-type bacteriophages

We examined a number of bacteriophages with T4-type morphology that propagate in different genera of enterobacteria, Aeromonas, Burkholderia, and Vibrio. Most of these phages had a prolate icosahedral head, a contractile tail, and a genome size that was similar to that of T4. A few of them had more elongated heads and larger genomes. All these phages are phylogenetically related, since they each had sequences homologous to the capsid gene (gene 23), tail sheath gene (gene 18), and tail tube gene (gene 19) of T4. On the basis of the sequence comparison of their virion genes, the T4-type phages can be classified into three subgroups with increasing divergence from T4: the T-evens, pseudoT-evens, and schizoT-evens. In general, the phages that infect closely related host species have virion genes that are phylogenetically closer to each other than those of phages that infect distantly related hosts. However, some of the phages appear to be chimeras, indicating that, at least occasionally, some genetic shuffling has occurred between the different T4-type subgroups. The compilation of a number of gene 23 sequences reveals a pattern of conserved motifs separated by sequences that differ in the T4-type subgroups. Such variable patches in the gene 23 sequences may determine the size of the virion head and consequently the viral genome length. This sequence analysis provides molecular evidence that phages related to T4 are widespread in the biosphere and diverged from a common ancestor in acquiring the ability to infect different host bacteria and to occupy new ecological niches.

Capsid expansion follows the initiation of DNA packaging in bacteriophage T4

Most bacteriophages undergo a dramatic expansion of their capsids during morphogenesis. In phages lambda, T3, T7 and P22, it has been shown that expansion occurs during the packaging of DNA into the capsid. The terminase-DNA complex docks with the portal vertex of an unexpanded prohead and begins packaging. After some of the DNA has entered, the major head protein undergoes a conformational change that increases both the volume and stability of the capsid. In phage T4, the link between packaging and expansion has not been established. We explored the possibility of such a connection using a pulse-chase protocol and high resolution sucrose gradient analysis of capsid intermediates isolated from wild-type T4-infected cells. We show that the first particle appearing after the pulse is an unexpanded prohead, which can be isolated in vitro as the ESP (empty small particle). The next intermediate to appear is also unexpanded, but contains DNA. This new intermediate, the ISP (initiated small particle), can also be isolated on agarose gels, permitting confirmation of both its expansion state and DNA content ( approximately 10 kbp). It appears, therefore, that >/=8% of the T4 genome enters the head shell prior to expansion. Following packaging of an undetermined amount of DNA, the capsid expands, producing the ILP (initiated large particle), which is finally converted to a full head upon the completion of packaging. An expanded, empty prohead, the ELP (empty large particle), was also observed during 37 degrees C infections, but failed to mature to phage during the chase. Thus the ELP is unlikely to be an intermediate in normal head assembly. We conclude by suggesting that studies on assembly benefit from an emphasis on the processes involved, rather than on the structural intermediates which accumulate if these processes are interrupted.

The bacteriophage T4 DNA packaging apparatus targets the unexpanded prohead

During the morphogenesis of the bacteriophage T4 capsid, a conformational change of the major head shell protein, gene product (gp) 23, causes a 50% increase in capsid volume. This expansion is required to accept the full length chromosome and, therefore, must precede the completion of packaging. The expanded shell is thinner and more stable than its precursor, and can bind accessory proteins which further stabilize it. In phages lambda, T3, T7 and P22, expansion occurs during DNA packaging. However, in T4, expanded capsids can package DNA in vitro and expansion occurs in cells infected with packaging-defective mutants, raising the possibility that expansion and packaging are not coupled. Proteolytically mature gp23 (gp23*) in unexpanded proheads is sensitive to chymotrypsin cleavage at Phe154-Ser155, creating a 38 kDa peptide, while gp23* in expanded capsids is refractory to the protease. We used an expansion assay based on this protease sensitivity to determine the expansion status of capsids isolated from various packaging-defective mutants with the goal of determining whether packaging and expansion are normally linked. In infections at 20 degrees C, mutants in the packaging enzymes gp16 and gp17 fail to expand. However, in gene 49(-) mutants, which initiate packaging but fail to complete it, expansion is complete. Thus, packaging drives expansion, and the unexpanded prohead is the substrate for the packaging reaction. We also show that expansion observed in 16(-) and 17(-) infections at 37 degrees C is linked to aberrant packaging. Capsids produced at 15 minutes, when no packaging can be detected, never expand. However, by 35 minutes when aberrant packaging begins, so does expansion of freshly made capsids. Thus in all cases now examined, expansion is only observed in vivo when DNA packaging is also occurring, indicating that these two processes are coupled.

Cloning and sequencing of major capsid protein (mcp) gene of a vibriophage, KVP20, possibly related to T-even coliphages

A large, tailed, prolate-headed vibriophage designated KVP20 was isolated from seawater. KVP20 was morphologically very similar to the previously described vibriophage, KVP40 (Matsuzaki, S., Inoue, T., Tanaka, S., 1998. Virology, 242, 314-318). However, they showed entirely different host specificities and could easily be differentiated from each other by their patterns of DNA restriction fragments. The major capsid protein (mcp) gene of KVP20 encoding the precursor of major capsid protein (pro-Mcp) was cloned and sequenced. The deduced amino-acid (aa) sequence of KVP20 pro-Mcp was compared with the reported aa sequences of KVP40 pro-Mcp, as well as of the equivalent proteins (gp23s) of coliphages T4 and RB49. There was 96.7, 57.5, and 55.2% homology to the corresponding proteins of KVP40, T4, and RB49, respectively. These data strongly suggest that the two vibriophages are closely related to each other and that they are both distantly, but definitely, related to coliphages T4 and RB49.

A vibriophage, KVP40, with major capsid protein homologous to gp23* of coliphage T4

The mcp gene encoding the major capsid protein (Mcp) of vibriophage KVP40, a large-tailed DNA phage, was cloned and sequenced. The nucleotide sequence of the mcp gene was 64.4% similar to that of gene 23 of coliphage T4. Analysis of the N-terminal amino acid sequence of purified native Mcp revealed that the mcp gene actually coded for a precursor, pro-Mcp, whose 62 N-terminal amino acids must be removed upon maturation to Mcp. Thus, mature Mcp would consist of 452 amino acid residues and have a calculated molecular mass of 47,561 Da. Comparison of amino acid sequences of Mcp and gp23*, the major capsid protein of T4, demonstrated 61.8% identity and 89.7% similarity between them. In addition, a sequence, TATAAATA, identical to a typical T4 late promoter sequence was seen in the region upstream of the mcp gene. These findings, together with their morphological similarity, suggest that KVP40 and T4 are phylogenetically related.

The genome of the pseudo T-even bacteriophages, a diverse group that resembles T4

Polymerase chain reaction analysis of a large collection of bacteriophages with T-even morphology revealed four phages that are distantly related to all the others. The genomes of these pseudo T-even phages hybridized under stringent conditions to only a limited portion of the T4 genome that encodes virus head, head-to-tail joining and contractile tail genes. Except for this region, no extensive hybridization was detected between most pairs of the different pseudo T-even genomes. Sequencing of this conserved region of the pseudo T-even phage RB49 revealed substantial nucleotide sequence divergence from T4 (approximately 30% to 40%), and random genomic sequencing of this phage indicated that more than a third of its sequences had no detectable homology to T4. Among those sequences related to the T-even genes were virion structural components including the constituents of the phage base plate. Only a few sequences had homology to T4 early functions; these included ribonucleotide diphosphatase reductase, DNA ligase and the large subunit of DNA topoisomerase. The genomes of the pseudo T-even phage were digested by restriction enzymes that are unable to digest the T-even DNAs which contain glucosylated hydroxymethyl-cytosine residues. This suggests that only limited nucleotide modifications must be present in the pseudo T-even genomes. Conservation of much of the morphogenetic region of these diverse phage genomes may reflect particularly strong sequence constraints on these gene products. However, other explanations are considered, including the possibility that the various morphogenetic segments were acquired by the pseudo T-even genomes by modular evolution. These results support the notion that phage evolution may proceed within a network of both closely and distantly related genomes.

The asiA gene product of bacteriophage T4 is required for middle mode RNA synthesis

The asiA gene of bacteriophage T4 encodes a 10-kDa peptide which binds strongly in vitro to the sigma 70 subunit of Escherichia coli RNA polymerase, thereby weakening sigma 70-core interactions and inhibiting sigma 70-dependent transcription. To assess the physiological role of this protein, we have introduced an amber mutation into the proximal portion of the asiA gene. On suppressor-deficient hosts, this mutant phage (amS22) produces minute plaques and exhibits a pronounced delay in phage production. During these mutant infections, T4 DNA synthesis is strongly delayed, suggesting that the AsiA protein plays an important role during the prereplicative period of phage T4 development. The kinetics of protein synthesis show clearly that while T4 early proteins are synthesized normally, those expressed primarily via the middle mode exhibit a marked inhibition. In fact, the pattern of protein synthesis after amS22 infection resembles greatly that seen after infection by amG1, an amber mutant in motA, a T4 gene whose product is known to control middle mode RNA synthesis. The amber mutations in the motA and asiA genes complement, both for phage growth and for normal kinetics of middle mode protein synthesis. Furthermore, primer extension analyses show that three different MotA-dependent T4 middle promoters are not recognized after infection by the asiA mutant phage. Thus, in conjunction with the MotA protein, the AsiA protein is required for transcription activation at T4 middle mode promoters.

Conformational changes of a viral capsid protein. Thermodynamic rationale for proteolytic regulation of bacteriophage T4 capsid expansion, co-operativity, and super-stabilization by soc binding

We have used differential scanning calorimetry in conjunction with cryo-electron microscopy to investigate the conformational transitions undergone by the maturing capsid of phage T4. Its precursor shell is composed primarily of gp23 (521 residues): cleavage of gp23 to gp23* (residues 66 to 521) facilitates a concerted conformational change in which the particle expands substantially, and is greatly stabilized. We have now characterized the intermediate states of capsid maturation; namely, the cleaved/unexpanded, state, which denatures at tm = 60 degrees C, and the uncleaved/expanded state, for which tm = 70 degrees C. When compared with the precursor uncleaved/unexpanded state (tm = 65 degrees C), and the mature cleaved/expanded state (tm = 83 degrees C, if complete cleavage precedes expansion), it follows that expansion of the cleaved precursor (delta tm approximately +23 degrees C) is the major stabilizing event in capsid maturation. These observations also suggest an advantage conferred by capsid protein cleavage (some other phage capsids expand without cleavage): if the gp23-delta domains (residues 1 to 65) are not removed by proteolysis, they impede formation of the stablest possible bonding arrangement when expansion occurs, most likely by becoming trapped at the interface between neighboring subunits or capsomers. Icosahedral capsids denature at essentially the same temperatures as tubular polymorphic variants (polyheads) for the same state of the surface lattice. However, the thermal transitions of capsids are considerably sharper, i.e. more co-operative, than those of polyheads, which we attribute to capsids being closed, not open-ended. In both cases, binding of the accessory protein soc around the threefold sites on the outer surface of the expanded surface lattice results in a substantial further stabilization (delta tm = +5 degrees C). The interfaces between capsomers appear to be relatively weak points that are reinforced by clamp-like binding of soc. These results imply that the "triplex" proteins of other viruses (their structural counterparts of soc) are likely also to be involved in capsid stabilization. Cryo-electron microscopy was used to make conclusive interpretations of endotherms in terms of denaturation events. These data also revealed that the cleaved/unexpanded capsid has an angular polyhedral morphology and has a pronounced relief on its outer surface. Moreover, it is 14% smaller in linear dimensions than the cleaved/expanded capsid, and its shell is commensurately thicker.

Mutations that eliminate the requirement for the vertex protein in bacteriophage T4 capsid assembly

The capsid of bacteriophage T4 is composed of two essential structural proteins, gp23, the major constituent of the capsid, and gp24, a less prevalent protein that is located in the pentameric vertices of the capsid. gp24 is required both to stabilize the capsid and to allow it to be further matured. This requirement can be eliminated by bypass-24 (byp24) mutations within g23. We have isolated, cloned and sequenced several new byp24 mutations. These mutations are cold-sensitive in the absence of gp24, and are located in regions of g23 not known to contain any other mutations affecting capsid assembly. The cold-sensitivity of the byp24 mutations can be reduced by further mutations within g23 (trb mutations). Cloning and sequencing of these trb mutations has revealed that they lie in regions of g23 that contain clusters of mutations that cause the production of high levels of petite and giant phage (ptg mutations). Despite the proximity of the trb mutations to the ptg mutations, none of the ptg mutations has a Trb phenotype. The mutation ptE920g, which is also located near one of the ptg clusters, and which produces only petite and wild-type phage, has been shown to confer a Trb but not a Byp24 phenotype. The relevance of these observations to our understanding of capsid assembly is discussed.

Nucleotide sequence of the bacteriophage P22 genes required for DNA packaging

The mechanism of DNA packaging by dsDNA viruses is not well understood in any system. In bacteriophage P22 only five genes are required for successful condensation of DNA within the capsid. The products of three of these genes, the portal, scaffolding, and coat proteins, are structural components of the precursor particle, and two, the products of genes 2 and 3, are not. The scaffolding protein is lost from the structure during packaging, and only the portal and coat proteins are present in the mature virus particle. These five genes map in a contiguous cluster at the left end of the P22 genetic map. Three additional genes, 4, 10, and 26, are required for stabilizing of the condensed DNA within the capsid. In this report we present the nucleotide sequence of 7461 bp of P22 DNA that contains the five genes required for DNA condensation, as well as a nonessential open reading frame (ORF109), gene 4, and a portion of gene 10. N-terminal amino acid sequencing of the encoded proteins accurately located the translation starts of six genes in the sequence. Despite the fact that most of these proteins have striking analogs in the other dsDNA bacteriophage groups, which perform highly analogous functions, no amino acid sequence similarity between these analogous proteins has been found, indicating either that they diverged a very long time ago or that they are the products of spectacular convergent evolution.

Role of the major capsid protein of phage T4 in DNA packaging from structure-function and site-directed mutagenesis studies

Heat cleavage of asp-pro peptide bonds was used to probe the primary structures of the Phage T4 major capsid protein precursor, gp23, its mature capsid form gp23*, and a DNA-dependent ATPase, called capsizyme. This analysis suggests that capsizyme is a gp23** resulting from the N-terminal processing found in gp23* as well as shortening at the C-terminus. Photoaffinity labeling with Azido-ATP and BrU-DNA, followed by heat cleavage, suggests binding sites for these compounds toward the C-terminus of gp23**, suggesting localization of functions within the gp23 primary sequence. Site-directed mutagenesis experiments were targeted therefore to the C-terminal end of g23 as well as to its processing sites. N-terminal processing site modification supports the consensus gp21 proteinase cleavage rule, whereas mutagenesis at the C-terminus suggests that the C-terminal alteration is unlikely to result from a gp21-morphogenesis proteinase cleavage. Amino acid replacements in gp23 at newly introduced amber sites reveal a new g23 mutant phenotype, defective partially DNA-filled heads, in support of the hypothesis that gp23 and its products function directly in the DNA packaging mechanism.

A proposed structure of bacteriophage T4 gene product 22--a major prohead scaffolding core protein

Gene 22 of bacteriophage T4 encodes a major prohead scaffolding core protein of 269 amino acid residues. From its nucleotide sequence the gene product (gp) 22 has a predicted Mr of 29.9 and a pI of 4.3. The protein is rich in charged residues (glutamic acid and lysine) and contains low amounts of proline and glycine and no cysteine residues. We suggest that gp22 undergoes limited proteolytic processing which eliminates the short C-terminal piece from the molecule during the early steps of prohead assembly. Most amino acid residues of the gp22 polypeptide chain (80%) have an alpha-helical conformation and form seven peculiar alpha-helices. A model suggesting the spatial organization of gp22 is presented. Three long alpha-helices numbered 1 (1A and 1B), 3, and 5 (5A and 5B) are packed in an antiparallel fashion along the major axis of the road-shaped molecule. Two rather short alpha-helices (2 and 4) are located at the distal and proximal ends of the protein molecule, respectively. Helix number 2, which is a proteolytic fragment of gp22 found in mature T4 heads, is packed with helices 1A and 3, similar to a novel element of supersecondary structure, the alpha alpha-corner. Helix number 4 probably interacts with the gp20 connector of the prohead. The implications of the structure of the gp22 molecule for the assembly of the prohead core are discussed.

Nonsense mutants defining seven new genes of the lipid-containing bacteriophage PR4

Thirty-eight new nonsense mutants of the lipid-containing bacteriophage PR4 were isolated. These mutants define seven new viral genes, including the gene encoding the terminal genome protein and an accessory lytic factor. The defective gene products produced in uv-irradiated cells infected with representative mutants from each of the new genetic groups were identified using sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Extracts of uv-irradiated cells infected with nonsense mutants that produce a defective major capsid protein, P2, also lacked two lower molecular weight proteins. The synthesis of all three protein species was recovered in cells infected with one-step revertants of two independent major capsid protein mutants, suggesting the possibility of post-translational processing or overlapping genes. The time course of protein synthesis in wild-type PR4-infected cells was examined using SDS-PAGE. These analyses revealed at least 34 proteins produced following phage PR4 infection that were not present in uninfected control cultures.

The maturation-dependent conformational change of the major capsid protein of bacteriophage T4 involves a substantial change in secondary structure

We have investigated the conformational basis of the expansion transformation that occurs upon maturation of the bacteriophage T4 prohead, by using laser Raman spectroscopy to determine the secondary structure of the major capsid protein in both the precursor and the mature states of the surface lattice. This transformation involves major changes in the physical, chemical, and immunological properties of the capsid and is preceded in vivo by processing of its major protein, gp23 (56 kDa), to gp23* (49 kDa), by proteolysis of its N-terminal gp23-delta domain. The respective secondary structures of gp23 in the unexpanded state, and of gp23* in the expanded state, were determined from the laser Raman spectra of polyheads, tubular polymorphic variants of the capsid. Similar measurements were also made on uncleaved polyheads that had been expanded in vitro and, for reference, on thermally denatured polyheads. We find that, with or without cleavage of gp23, expansion is accompanied by substantial changes in secondary structure, involving a major reduction in alpha-helix content and an increase in beta-sheet. The beta-sheet contents of gp23* or gp23 in the expanded state of the surface lattice, and even of gp23 in the unexpanded state, are sufficient for a domain with the "jellyroll" fold of antiparallel beta-sheets, previously detected in the capsid proteins of other icosahedral viruses.(ABSTRACT TRUNCATED AT 250 WORDS)

A site in the T4 bacteriophage major head protein gene that can promote the inhibition of all translation in Escherichia coli

The cryptic DNA element, e14, synthesizes a protein, Lit, which can inhibit gene expression late in T4 bacteriophage development. This inhibition is due to the interaction between the Lit protein and a short region, the gol region, within gene 23, the major head protein gene of phage T4. We have constructed plasmids in which the gol region is transcribed from the lac promoter and fused translationally and transcriptionally to lacZ and cat (chloramphenicol acetyltransferase). These fusion plasmids were used to demonstrate that, in the presence of Lit protein, the gol region inhibits the expression of genes downstream in the same transcription unit. This local inhibition does not require the gene 23 polypeptide from the gol region. In addition, inducing the transcription and translation of the gol region in the presence of Lit protein causes an immediate global inhibition of all translation in Escherichia coli. This global inhibition does require the gene 23 polypeptide. No more than 75 base-pairs of DNA from the gol region are required for both the local and global inhibitions. The gol region sequence contains a short dyad symmetry. However, it is the sequence of bases in the region of dyad symmetry and not the ability to form a hairpin in the RNA that is required for gol region activity.

Escherichia coli RNase E has a role in the decay of bacteriophage T4 mRNA

Bacteriophage T4 mRNAs are markedly stabilized, both chemically and functionally, in an Escherichia coli strain deficient in the RNA-processing endonuclease RNase E. The functional stability of total T4 messages increased 6-fold; we were unable to detect a T4 message whose functional stability was not increased. There was a 4-fold increase in the chemical stability of total T4 RNA. The degree of chemical stabilization of six specific T4 mRNAs examined varied from a maximum of 28-fold to a minimum of 1.5-fold. In the RNase E-deficient strain, several minutes delay and a slower rate of progeny production led to a reduction in final phage yield of approximately 50%. Although the effect of the rne temperature-sensitive mutation could be indirect, the simplest interpretation of our results is that RNase E acts directly in the degradation of many T4 mRNAs.

Heat cleavage of bacteriophage T4 gene 23 product produces two peptides previously identified as head proteins

During studies on the intracellular protein pools of bacteriophage T4, we found that amber mutants in gene 23 blocked the synthesis of a 20-kilodalton (kDa) protein. Radiolabeled amino acid pulses showed that the protein appears at 8 min postinfection with kinetics similar to those of other major late species. Pulse-chase experiments demonstrated that the 20-kDa protein behaves like a primary product and also revealed a 29-kDa protein which, like other proteins cleaved during head assembly, appeared only after a long chase. Both species have been identified as constituents of the T4 head and have resisted previous efforts to identify their genetic origin. The dependence of the 20- and 29-kDa head proteins on the presence of gene 23 protein (gp23) and the observation that the sum of their masses equalled that of mature cleaved gp23 suggested that these two proteins were derived from this major capsid species. Evidence is presented demonstrating that heating samples before electrophoresis causes peptide bond cleavages in gp23, leading to the formation of the two peptides. As predicted by the results of Rittenhouse and Marcus (Anal. Biochem. 138:442-448, 1984), the cleavage occurs at Asp-336-Pro-337 and at two other Asp-Pro sites. Limited heat-induced proteolysis followed by two-dimensional gel analysis provided a peptide map of gp23 useful in the characterization of its assembly-related cleavages.

The structure of three bacteriophage T4 genes required for tail-tube assembly

Three different protein molecules copurify with T4 tail tubes after the tubes are released from the baseplate by guanidine hydrochloride treatment. These tube-associated proteins (TAPs) are the products of genes 29, 48, and 54. To further investigate the structural roles that these proteins may play in T4 tail assembly we have cloned and sequenced the genes coding for these proteins and have deduced their predicted amino acid sequences. The sequence data reveal a region of amino acid sequence similarity between gp54 and the T4 tail-tube structural protein, gp19. We believe that this region of similarity is significant and consistent with the role gp54 may play in initiating T4 tail-tube polymerization.

Induction of the heat shock regulon of Escherichia coli markedly increases production of bacterial viruses at high temperatures

Production of bacteriophages T2, T4, and T6 at 42.8 to 44 degrees C was increased from 8- to 260-fold by adapting the Escherichia coli host (grown at 30 degrees C) to growth at the high temperature for 8 min before infection; this increase was abolished if the host htpR (rpoH) gene was inactive. Others have shown that the htpR protein increases or activates the synthesis of at least 17 E. coli heat shock proteins upon raising the growth temperature above a certain level. At 43.8 to 44 degrees C in T4-infected, unadapted cells, the rates of RNA, DNA, and protein synthesis were about 100, 70, and 70%, respectively, of those in T4-infected, adapted cells. Production of the major processed capsid protein, gp23, was reduced significantly more than that of most other T4 proteins in unadapted cells relative to adapted cells. Only 4.6% of the T4 DNA made in unadapted cells was resistant to micrococcal nuclease, versus 50% in adapted cells. Thus, defective maturation of T4 heads appears to explain the failure of phage production in unadapted cells. Overproduction of the heat shock protein GroEL from plasmids restored T4 production in unadapted cells to about 50% of that seen in adapted cells. T4-infected, adapted E. coli B at around 44 degrees C exhibited a partial tryptophan deficiency; this correlated with reduced uptake of uracil that is probably caused by partial induction of stringency. Production of bacteriophage T7 at 44 degrees C was increased two- to fourfold by adapting the host to 44 degrees C before infection; evidence against involvement of the htpR (rpoH) gene is presented. This work and recent work with bacteriophage lambda (C. Waghorne and C.R. Fuerst, Virology 141:51-64, 1985) appear to represent the first demonstrations for any virus that expression of the heat shock regulon of a host is necessary for virus production at high temperature.

Genetic control of capsid length in bacteriophage T4: clustering of ptg mutations in gene 23

Fifty-two new bacteriophage T4 ptg mutations have been isolated by selecting for the giant-capsid phenotype they display. Genetic mapping placed all of them at eight sites, all located in gene 23. These sites were clustered in three locations, one near amber B17 (gene 23 nucleotide [NT] 268), another centrally placed between amE506 (NT 706) and amE1270 (NT 925), and the third between amC208 (NT 1297) and amE1236 (NT 1489). The lack of a selective system for identifying recombinant genotypes when dealing with the very close linkages found within these clusters opens the possibility that more than eight sites are represented in this set of mutations. Since one site was represented by only one mutation, it seems likely that further searching might uncover additional sites. It is suggested that the clustering of mutations observed here identifies regions of the gene 23 product that play a role in regulating the capsid length of T4.

Genetic control of capsid length in bacteriophage T4: DNA sequence analysis of petite and petite/giant mutants

The T4 gene 23 product (gp23) encodes the major structural protein of the mature capsid. Mutations in this gene have been described which disrupt the normal length-determining mechanism (A.H. Doermann, F.A. Eiserling, and L. Boehner, J. Virol. 12:374-385, 1973). Mutants which produce high levels of petite and giant phage (ptg) are restricted to three tight clusters in gene 23 (A.H. Doermann, A. Pao, and P. Jackson, J. Virol. 61:2823-2827, 1987). Twenty-six of these ptg mutations were cloned, and their DNA sequence alterations were determined. Each member of this set of ptg mutants arose from a single mutation, and the set defined 10 different sites at which ptg mutations can occur in gene 23. Two petite (pt) mutations in gene 23 (pt21-34 and ptE920g), which produce high frequencies of petite particles but no giants, were also sequenced. Both pt21-34 and ptE920g were shown to include multiple mutations. The phenotypes attributed to both pt and ptg mutations are discussed relative to the mechanism of capsid morphogenesis. A site-directed mutation (SD-1E) was created at the ptgNg191 site, and its phenotypic consequences were examined. Plaque morphology revertants arising from a gene 23 mutant derivative of pt21-34 and from SD-1E were isolated. A preliminary mapping of the mutation(s) responsible for their revertant phenotypes suggested that both intra- and extragenic suppressors of the petite phenotype can be isolated by this method.

Nonsense suppression context effects in Escherichia coli bacteriophage T4

Nonsense suppression by supE44 has been examined in a collection of 14 T4 gene 22 and gene 23 UAG mutants, for which the precise gene location is known. In concordance with previous studies, UAG followed by a pyrimidine was inefficiently suppressed. However, among positions with similar 3' nucleotides, there was considerable variation in suppression efficiency. The competition between supE44 and Release Factor 1 (RF 1) was also investigated following the introduction of a multicopy RF 1 plasmid. An inverse relationship between the efficiency of suppression and RF 1 competition was observed.

T-even type phages can change their host range by recombination with gene 34 (tail fibre) or gene 23 (head)

T-even type phages recognize their cellular receptors with the tip of their long tail fibres. The gene products involved in receptor recognition are proteins 37 and 38. While screening libraries of phage K3 with a probe of gene 38 from phage T2, a class of weakly hybridizing clones was found in addition to the expected clones of gene 38 of K3. One of these clones was identified as being from gene 23 of the phage which codes for the major head subunit; another clone originated from gene 34, which codes for the proximal half of the long tail fibres. Neither gene product 23 nor 34 is involved in receptor recognition. Phages can recombine with the DNA of the gene 23 and gene 34 clones and change the host range.

Assembly and disassembly of bacteriophage T4 polyheads

The assembly of the product of bacteriophage T4 gene 23 (gp23), the uncleaved form of the main shell protein, has been studied. Assembly and disassembly follow the predictions for entropy-driven processes; assembly is strongly favored by conditions of high salt concentrations and high temperatures, whereas low salt and low temperatures promote disassembly. In the absence of the scaffolding core proteins in vitro, only polyheads, the tubular variant of the prohead, are produced. Kinetic studies show that the rate of polyhead dissociation depends on the concentration of associated protein, not on the number and length of the particles. Comparable to crystal formation, assembly of gp23 occurs above a critical concentration, which is dependent on salt concentration, pH and temperature. These characteristics are common to most self-assembling systems. The oligomeric states of gp23 have been investigated by analytical ultracentrifugation, which indicated the existence, at very low salt concentration and low temperature, of an equilibrium between monomers and higher oligomers, culminating in the hexamer. At pH 9.0 polyheads are completely dissociated into their monomeric gp23 subunits. Our data suggest that the hexamer is a true intermediate of polyhead assembly.

Terminators of transcription with RNA polymerase from Escherichia coli: what they look like and how to find them

We present here a compilation of prokaryotic transcription terminator sequences (ref. 1-152). The compilation includes 49 independent terminators, 52 speculated independent terminators, 27 sites shown to function in vivo, and some 20 proven or speculated rho-dependent terminators. In addition to the well-known features of independent terminators (dyad symmetry and T-run), two consensus are found: CGGG(C/G) upstream and TCTG downstream of the termination point. A subset of the collection of sequence has been used to construct a computer algorithm to locate independent terminators by sequence analysis.

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.

Deletion analysis of a bacteriophage T4 late promoter

We have conducted a BAL 31 unidirectional deletion analysis to determine whether the conserved consensus sequence found upstream of all sequenced phage T4 late genes represents the late T4 promoter or is only part of the promoter. The results confirm those of Elliott and Geiduschek [Cell 36 (1984) 211-219] that no sequences upstream from the consensus sequence are necessary for late transcription activity. In addition, they provide evidence that sequences downstream from the consensus sequence are important. We have also constructed a sequence that differs in several positions from the consensus but which still shows the properties of a late T4 promoter. Finally, we have noticed a remarkable homology between the consensus sequence for late T4 promoters and mitochondrial promoters from Saccharomyces cerevisiae and Kluyveromyces lactis.

Intracellular morphogenesis of bacteriophage T4. II. Head morphogenesis

The relative phage yields of cells of Escherichia coli infected with both wild-type and amber mutant phages deficient in head morphogenesis were determined. The decrease in burst size as a function of the ratio of mutant:wild-type-infecting phage was linear and proportional for mutants in genes 20, 22, and 23, while for mutants in genes 21, 31, and 24 the results suggest an excess of intracellular gene product. The initiation of assembly of phage particles was not delayed at reduced gene product levels; only a reduction in the rate of phage assembly was observed. The effects on burst size of pairs of mutations in genes 20 and 23, 22 and 23, and 22 and 24, in both cis and trans arrangements, were identical. Experiments using the mutant E920g in gene 23 show that varying the kind and intracellular amounts of the major capsid protein (gp23) with respect to the major core or scaffold protein (gp22) had a profound effect on the length of the T4 head. Head length determination must therefore depend on the proper intracellular balance between these two proteins.