A bacteriophage T4 gene which functions to inhibit Escherichia coli Lon protease

Inhibitors of bacterial immune systems: discovery, mechanisms and applications

To contend with the diversity and ubiquity of bacteriophages and other mobile genetic elements, bacteria have developed an arsenal of immune defence mechanisms. Bacterial defences include CRISPR-Cas, restriction-modification and a growing list of mechanistically diverse systems, which constitute the bacterial 'immune system'. As a response, bacteriophages and mobile genetic elements have evolved direct and indirect mechanisms to circumvent or block bacterial defence pathways and ensure successful infection. Recent advances in methodological and computational approaches, as well as the increasing availability of genome sequences, have boosted the discovery of direct inhibitors of bacterial defence systems. In this Review, we discuss methods for the discovery of direct inhibitors, their diverse mechanisms of action and perspectives on their emerging applications in biotechnology and beyond.

Integrated Omics Reveal Time-Resolved Insights into T4 Phage Infection of E. coli on Proteome and Transcriptome Levels

Bacteriophages are highly abundant viruses of bacteria. The major role of phages in shaping bacterial communities and their emerging medical potential as antibacterial agents has triggered a rebirth of phage research. To understand the molecular mechanisms by which phages hijack their host, omics technologies can provide novel insights into the organization of transcriptional and translational events occurring during the infection process. In this study, we apply transcriptomics and proteomics to characterize the temporal patterns of transcription and protein synthesis during the T4 phage infection of E. coli. We investigated the stability of E. coli-originated transcripts and proteins in the course of infection, identifying the degradation of E. coli transcripts and the preservation of the host proteome. Moreover, the correlation between the phage transcriptome and proteome reveals specific T4 phage mRNAs and proteins that are temporally decoupled, suggesting post-transcriptional and translational regulation mechanisms. This study provides the first comprehensive insights into the molecular takeover of E. coli by bacteriophage T4. This data set represents a valuable resource for future studies seeking to study molecular and regulatory events during infection. We created a user-friendly online tool, POTATO4, which is available to the scientific community and allows access to gene expression patterns for E. coli and T4 genes.

Cryo-EM structure of the full-length Lon protease from Thermus thermophilus

In bacteria, Lon is a large hexameric ATP‐dependent protease that targets misfolded and also folded substrates, some of which are involved in cell division and survival of cellular stress. The N‐terminal domain of Lon facilitates substrate recognition, but how the domains confer such activity has remained unclear. Here, we report the full‐length structure of Lon protease from Thermus thermophilus at 3.9 Å resolution in a substrate‐engaged state. The six N‐terminal domains are arranged in three pairs, stabilized by coiled‐coil segments and forming an additional channel for substrate sensing and entry into the AAA+ ring. Sequence conservation analysis and proteolysis assays confirm that this architecture is required for the degradation of both folded and unfolded substrates in bacteria.

Systemic Expression, Purification, and Initial Structural Characterization of Bacteriophage T4 Proteins Without Known Structure Homologs

Bacteriophage T4 of Escherichia coli is one of the most studied phages. Research into it has led to numerous contributions to phage biology and biochemistry. Coding about 300 gene products, this double-stranded DNA virus is the best-understood model in phage study and modern genomics and proteomics. Ranging from viral RNA polymerase, commonly found in phages, to thymidylate synthase, whose mRNA requires eukaryotic-like self-splicing, its gene products provide a pool of fine examples for phage research. However, there are still up to 130 gene products that remain poorly characterized despite being one of the most-studied model phages. With the recent advancement of cryo-electron microscopy, we have a glimpse of the virion and the structural proteins that present in the final assembly. Unfortunately, proteins participating in other stages of phage development are absent. Here, we report our systemic analysis on 22 of these structurally uncharacterized proteins, of which none has a known homologous structure due to the low sequence homology to published structures and does not belong to the category of viral structural protein. Using NMR spectroscopy and cryo-EM, we provided a set of preliminary structural information for some of these proteins including NMR backbone assignment for Cef. Our findings pave the way for structural determination for the phage proteins, whose sequences are mainly conserved among phages. While this work provides the foundation for structural determinations of proteins like Gp57B, Cef, Y04L, and Mrh, other in vitro studies would also benefit from the high yield expression of these proteins.

Polyphosphate, cyclic AMP, guanosine tetraphosphate, and c-di-GMP reduce in vitro Lon activity

Lon protease is conserved from bacteria to humans and regulates cellular processes by degrading different classes of proteins including antitoxins, transcriptional activators, unfolded proteins, and free ribosomal proteins. Since we found that Lon has several putative cyclic diguanylate (c-di-GMP) binding sites and since Lon binds polyphosphate (polyP) and lipid polysaccharide, we hypothesized that Lon has an affinity for phosphate-based molecules that might regulate its activity. Hence we tested the effect of polyP, cyclic adenosine monophosphate (cAMP), cyclic guanosine monophosphate (cGMP), guanosine tetraphosphate (ppGpp), c-di-GMP, and GMP on the ability of Lon to degrade α-casein. Inhibition of in vitro Lon activity occurred for polyP, cAMP, ppGpp, and c-di-GMP. We also demonstrated by HPLC that Lon is able to bind c-di-GMP. Therefore, four cell signals were found to regulate the activity of Lon protease.

The first structure in a family of peptidase inhibitors reveals an unusual Ig-like fold

We report the crystal structure solution of the Intracellular Protease Inhibitor (IPI) protein from Bacillus subtilis, which has been reported to be an inhibitor of the intracellular subtilisin Isp1 from the same organism. The structure of IPI is a variant of the all-beta, immunoglobulin (Ig) fold. It is possible that IPI is important for protein-protein interactions, of which inhibition of Isp1 is one. The intracellular nature of ISP is questioned, because an alternative ATG codon in the ipi gene would produce a protein with an N-terminal extension containing a signal peptide. It is possible that alternative initiation exists, producing either an intracellular inhibitor or a secreted form that may be associated with the cell surface.  Homologues of the IPI protein from other species are multi-domain proteins, containing signal peptides and domains also associated with the bacterial cell-surface. The cysteine peptidase inhibitors chagasin and amoebiasin also have Ig-like folds, but their topology differs significantly from that of IPI, and they share no recent common ancestor. A model of IPI docked to Isp1 shows similarities to other subtilisin:inhibitor complexes, particularly where the inhibitor interacts with the peptidase active site.

Discovery of functional toxin/antitoxin systems in bacteria by shotgun cloning

Toxin-antitoxin (TA) modules, composed of a toxic protein and a counteracting antitoxin, play important roles in bacterial physiology. We examined the experimental insertion of 1.5 million genes from 388 microbial genomes into an Escherichia coli host using more than 8.5 million random clones. This revealed hundreds of genes (toxins) that could only be cloned when the neighboring gene (antitoxin) was present on the same clone. Clustering of these genes revealed TA families widespread in bacterial genomes, some of which deviate from the classical characteristics previously described for such modules. Introduction of these genes into E. coli validated that the toxin toxicity is mitigated by the antitoxin. Infection experiments with T7 phage showed that two of the new modules can provide resistance against phage. Moreover, our experiments revealed an "antidefense" protein in phage T7 that neutralizes phage resistance. Our results expose active fronts in the arms race between bacteria and phage.

The Lon AAA+ protease

As the first ATP-dependent protease to be identified, Lon holds a special place in the history of cellular biology. In fact, the concept of ATP-dependent protein degradation was established through the findings that led to the discovery of Lon. Therefore, this chapter begins with a historical perspective, describing the milestones that led to the discovery of Lon and ATP-dependent proteolysis, starting from the early findings in the 1960s until the demonstration of Lon's ATP-dependent proteolytic activity in vitro, in 1981. Most of our knowledge on Lon derives from studies of the Escherichia coli Lon ortholog, and, therefore, most of this chapter relates to this particular enzyme. Nonetheless, Lon is not only found in most bacterial species, it is also found in Archaea and in the mitochondrion and chloroplast of eukaryotic cells. Therefore many of the conclusions gained from studies on the E. coli enzyme are relevant to Lon proteases in other organisms. Lon, more than any other bacterial or organellar protease, is associated with the degradation of misfolded proteins and protein quality control. In addition, Lon also degrades many regulatory proteins that are natively folded, thus it also plays a prominent role in regulation of physiological processes. Throughout the years, many Lon substrates have been identified, confirming its role in the regulation of diverse cellular processes, including cell division, DNA replication, differentiation, and adaptation to stress conditions. Some examples of these functions are described and discussed here, as is the role of Lon in the degradation of misfolded proteins and in protein quality control. Finally, this chapter deals with the exquisite sensitivity of protein degradation inside a cell. How can a protease distinguish so many substrates from cellular proteins that should not be degraded? Can the specificity of a protease be regulated according to the physiological needs of a cell? This chapter thus broadly discusses the substrate specificity of Lon and its allosteric regulation.

Classification of Myoviridae bacteriophages using protein sequence similarity

Background

We advocate unifying classical and genomic classification of bacteriophages by integration of proteomic data and physicochemical parameters. Our previous application of this approach to the entirely sequenced members of the Podoviridae fully supported the current phage classification of the International Committee on Taxonomy of Viruses (ICTV). It appears that horizontal gene transfer generally does not totally obliterate evolutionary relationships between phages.

Results

CoreGenes/CoreExtractor proteome comparison techniques applied to 102 Myoviridae suggest the establishment of three subfamilies (Peduovirinae, Teequatrovirinae, the Spounavirinae) and eight new independent genera (Bcep781, BcepMu, FelixO1, HAP1, Bzx1, PB1, phiCD119, and phiKZ-like viruses). The Peduovirinae subfamily, derived from the P2-related phages, is composed of two distinct genera: the "P2-like viruses", and the "HP1-like viruses". At present, the more complex Teequatrovirinae subfamily has two genera, the "T4-like" and "KVP40-like viruses". In the genus "T4-like viruses" proper, four groups sharing >70% proteins are distinguished: T4-type, 44RR-type, RB43-type, and RB49-type viruses. The Spounavirinae contain the "SPO1-"and "Twort-like viruses."

Conclusion

The hierarchical clustering of these groupings provide biologically significant subdivisions, which are consistent with our previous analysis of the Podoviridae.

The role of interactions between phage and bacterial proteins within the infected cell: a diverse and puzzling interactome

Interactions between bacteriophage proteins and bacterial proteins are important for efficient infection of the host cell. The phage proteins involved in these bacteriophage-host interactions are often produced immediately after infection. A survey of the available set of published bacteriophage-host interactions reveals the targeted host proteins are inhibited, activated or functionally redirected by the phage protein. These interactions protect the bacteriophage from bacterial defence mechanisms or adapt the host-cell metabolism to establish an efficient infection cycle. Regrettably, a large majority of bacteriophage early proteins lack any identified function. Recent research into the antibacterial potential of bacteriophage-host interactions indicates that phage early proteins seem to target a wide variety of processes in the host cell - many of them non-essential. Since a clear understanding of such interactions may become important for regulations involving phage therapy and in biotechnological applications, increased scientific emphasis on the biological elucidation of such proteins is warranted.

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.

A conserved domain in Escherichia coli Lon protease is involved in substrate discriminator activity

Lon protease of Escherichia coli regulates a diverse set of physiological responses including cell division, capsule production, plasmid stability, and phage replication. Little is known about the mechanism of substrate recognition by Lon. To examine the interaction of Lon with two of its substrates, RcsA and SulA, we generated point mutations in lon which affected its substrate specificity. The most informative lon mutant overproduced capsular polysaccharide (RcsA stabilized) yet was resistant to DNA-damaging agents (SulA degraded). Immunoblots revealed that RcsA protein persisted in this mutant whereas SulA protein was rapidly degraded. The mutant contains a single-base change within lon leading to a single amino acid change of glutamate 240 to lysine. E240 is conserved among all Lon isolates and resides in a charged domain that has a high probability of adopting a coiled-coil conformation. This conformation, implicated in mediating protein-protein interactions, appears to confer substrate discriminator activity on Lon. We propose a model suggesting that this coiled-coil domain represents the discriminator site of Lon.

Functional role of the N-terminal region of the Lon protease from Mycobacterium smegmatis

Lon protease homologues contain a poorly conserved N-terminal region of variable length. To better understand the role of the N-terminal region of Lon in the complicated reaction cycle of ATP-dependent protein degradation, we expressed and characterized mutants of the Lon protease from Mycobacterium smegmatis (Ms-Lon) lacking 90, 225, and 277 N-terminal residues (N-G91, N-E226, and N-I278, respectively). N-I278 displayed neither peptidase nor ATPase activity despite the fact that it was stable and soluble in vivo, had a near-wild-type CD spectrum, and the deleted residues included neither the catalytic nucleophile for peptide bond hydrolysis (S675) nor the ATP binding regions. N-G91 and N-E226 retained peptidase activities against small unstructured peptides that were stimulated, to near-wild-type levels, by the Ms-Lon substrate protein alpha-casein. By contrast, N-G91 and N-E226 retained basal ATPase activities, but these activities were only stimulated weakly by alpha-casein. Ms-Lon, N-E226, and N-G91 all exhibited low-level peptidase activity in assays containing nonhydrolyzed nucleotide analogues. However, these peptidase activities were stimulated strongly by alpha-casein in the case of Ms-Lon but weakly by alpha-casein in the cases of N-G91 and N-E226. Strikingly, despite the near-wild-type peptidase activities of N-G91 and N-E226, both were severely impaired in their degradation of the Ms-Lon protein substrates alpha-casein in vitro and RcsA in vivo. Overall, N-G91 and N-E226 displayed catalytic properties similar to Escherichia coli Lon (Ec-Lon) in the presence of the PinA inhibitor, suggesting that PinA inhibits Ec-Lon protease by inhibiting the function of Ec-Lon's N-terminal region. In vivo protease assays further revealed that, in contrast to the inactive Ms-Lon point mutant S675A, N-G91 and N-E226 did not reduce the cellular activity of RcsA. This same defect was observed previously for Ms-Lons with multiple mutations in their peptidase active sites. We conclude that proteolytically inactive mutants of Ms-Lon retain the ability to reduce the cellular activity of RcsA but that both the N-terminal region and the peptidase active site region of Ms-Lon are required for this activity of wild-type Ms-Lon. The inabilities of N-G91 and N-E226 to degrade larger protein substrates and to reduce the cellular activity of RcsA were not the result of drastic alterations in their quaternary structures. Gel filtration profiles of N-G91 and N-E226 revealed that each was primarily tetrameric, with an increased percentage of dimeric species and a decreased percentage of trimeric species relative to Ms-Lon. The observed shifts in the dimer/trimer ratios of the N-terminal truncation mutants suggest that the Ms-Lon tetramer contains two types of subunit-subunit interactions.

Regulation of proteolysis of the stationary-phase sigma factor RpoS

RpoS, the stationary-phase sigma factor of Escherichia coli, is responsible for increased transcription of an array of genes when cells enter stationary phase and under certain stress conditions. RpoS is rapidly degraded during exponential phase and much more slowly during stationary phase; the resulting changes in RpoS accumulation play an important role in providing differential expression of RpoS-dependent gene expression. It has previously been shown that rapid degradation of RpoS during exponential growth depends on RssB (also called SprE and MviA), a protein with homology to the family of response regulators, and on the ClpXP protease. We find that RssB regulation of proteolysis does not extend to another ClpXP substrate, bacteriophage lambda O protein, suggesting that RssB acts on the specific substrate RpoS rather than on the protease. In addition, the activity of RpoS is down-regulated by RssB when degradation is blocked. In cells blocked for RpoS degradation by a mutation in clpP, cells devoid of RssB show a four- to fivefold-higher activity of an RpoS-dependent reporter fusion than cells overproducing RssB. Therefore, RssB allows specific environmental regulation of RpoS accumulation and may also modulate activity. The regulation of degradation provides an irreversible switch, while the regulation of activity may provide a second, presumably reversible level of control.

Isolation and characterization of the phage T4 PinA protein, an inhibitor of the ATP-dependent lon protease of Escherichia coli

The bacteriophage T4 PinA protein, expression of which leads to inhibition of protein degradation in Escherichia coli cells, has been purified from cells carrying multiple copies of the pinA gene. PinA is a heat-stable protein with a subunit Mr of 18,800 and an isoelectric point of 4.6. Under nondenaturing conditions on a gel filtration column, PinA migrated in two peaks corresponding to a dimer and a tetramer. Purified PinA inhibited ATP-dependent protein degradation by Lon protease in vitro; it did not inhibit the activity of other E. coli ATP-dependent proteases, ClpAP or ClpYQ. Furthermore, PinA did not inhibit ATP-independent proteolysis in E. coli cell extracts. PinA binds with high affinity to Lon protease (Kd approximately 10 nM for dimer binding), and a complex with approximately 1 dimer of PinA per tetramer of Lon protease could be isolated by gel filtration. Lon activity was partially restored upon dilution of the PinA-Lon complex to subnanomolar concentrations, indicating that inhibition was reversible and that PinA did not covalently modify Lon protease. PinA was not cleaved by Lon protease, and heating the Lon-PinA complex at 65 degrees C denatured Lon protease and released active PinA. The properties of PinA in vitro suggest that PinA inhibits protein degradation in vivo by forming a tight, reversible complex with Lon protease.

PinA inhibits ATP hydrolysis and energy-dependent protein degradation by Lon protease

The bacteriophage T4 PinA protein inhibited degradation of [3H]alpha-methyl casein by purified Lon protease from Escherichia coli, but inhibition was noncompetitive with respect to casein. PinA did not inhibit cleavage of the fluorogenic peptide, N-glutaryl-alanylalanylphenylalanyl-3-methoxynaphthylamide and, moreover, did not block the ability of protein substrates, such as casein, to activate cleavage of fluorogenic peptides by Lon. Thus, PinA does not block the proteolytic active site or the allosteric protein-binding site on Lon. Inhibition of basal ATPase activity was variable (50-90%), whereas inhibition of protein-activated ATPase activity was usually 80-95%. Inhibition was noncompetitive with respect to ATP. PinA did not block activation of peptide cleavage by nonhydrolyzable analogs of ATP. These data suggest that PinA does not bind at the ATPase active site of Lon and does not interfere with nucleotide binding to the enzyme. PinA inhibited cleavage of the 72-amino acid protein, CcdA, degradation of which requires ATP hydrolysis, but did not inhibit cleavage of the carboxyl-terminal 41-amino acid fragment of CcdA, degradation of which does not require ATP hydrolysis. PinA thus appears to interact at a novel regulatory or enzymatic site involved in the coupling between ATP hydrolysis and proteolysis, possibly blocking the protein unfolding or remodeling step essential for degradation of high molecular weight protein substrates by Lon.

Effects on mRNA degradation by Escherichia coli transcription termination factor Rho and pBR322 copy number control protein Rop

Mutants in Escherichia coli transcription termination factor Rho, termed rho(nusD), were previously isolated based on their ability to block the growth of bacteriophage T4. Here we show that rho(nusD) strains have decreased average half-lives for bulk cellular mRNA. Decreased E. coli message lifetimes could be because of increased ribonuclease activity in the rho mutant cells: if a Rho-dependent terminator precedes a ribonuclease gene, weaker termination in the rho mutants could lead to nuclease overexpression. However, inactivation of ribonuclease genes in rho026 cells did not relieve the defective phage growth. Unexpectedly, expression of the pBR322 Rop protein, a structure-specific, sequence-independent RNA-binding protein, in rho(nusD) cells restored the ability of T4 to grow and prolonged cellular message half-life in both the wild-type and the rho026 mutant. These results suggest that it is the RNA-binding ability of Rho rather than its transcription termination function that is important for the inhibition of bacteriophage growth and the shorter bulk mRNA lifetime. We propose that altered interaction of the mutant Rho with mRNA could make the RNA more susceptible to degradation. The inability of the RNA-binding proteins SrmB and DeaD to reverse the rho mutant phenotype when each is overexpressed implies that the required RNA interactions are specific. The results show novel roles for Rho and Rop in mRNA stability.

The HflB protease of Escherichia coli degrades its inhibitor lambda cIII

The cIII protein of bacteriophage lambda is known to protect two regulatory proteins from degradation by the essential Escherichia coli protease HflB (also known as FtsH), viz., the lambda cII protein and the host heat shock sigma factor sigma32. lambda cIII, itself an unstable protein, is partially stabilized when the HflB concentration is decreased, and its half-life is decreased when HflB is overproduced, strongly suggesting that it is degraded by HflB in vivo. The in vivo degradation of lambda cIII (unlike that of sigma32) does not require the molecular chaperone DnaK. Furthermore, the half-life of lambda cIII is not affected by depletion of the endogenous ATP pool, suggesting that lambda cIII degradation is ATP independent (unlike that of lambda cII and sigma32). The lambda cIII protein, which is predicted to contain a 22-amino-acid amphipathic helix, is associated with the membrane, and nonlethal overproduction of lambda cIII makes cells hypersensitive to the detergent sodium dodecyl sulfate. This could reflect a direct lambda cIII-membrane interaction or an indirect association via the membrane-bound HflB protein, which is known to be involved in the assembly of certain periplasmic and outer membrane proteins.

Proteases and their targets in Escherichia coli

Proteolysis in Escherichia coli serves to rid the cell of abnormal and misfolded proteins and to limit the time and amounts of availability of critical regulatory proteins. Most intracellular proteolysis is initiated by energy-dependent proteases, including Lon, ClpXP, and HflB; HflB is the only essential E. coli protease. The ATPase domains of these proteases mediate substrate recognition. Recognition elements in target are not well defined, but are probably not specific amino acid sequences. Naturally unstable protein substrates include the regulatory sigma factors for heat shock and stationary phase gene expression, sigma 32 and RpoS. Other cellular proteins serve as environmental sensors that modulate the availability of the unstable proteins to the proteases, resulting in rapid changes in sigma factor levels and therefore in gene transcription. Many of the specific proteases found in E. coli are well-conserved in both prokaryotes and eukaryotes, and serve critical functions in developmental systems.

Proteases and protein degradation in Escherichia coli

In E. coli, protein degradation plays important roles in regulating the levels of specific proteins and in eliminating damaged or abnormal proteins. E. coli possess a very large number of proteolytic enzymes distributed in the cytoplasm, the inner membrane, and the periplasm, but, with few exceptions, the physiological functions of these proteases are not known. More than 90% of the protein degradation occurring in the cytoplasm is energy-dependent, but the activities of most E. coli proteases in vitro are not energy-dependent. Two ATP-dependent proteases, Lon and Clp, are responsible for 70-80% of the energy-dependent degradation of proteins in vivo. In vitro studies with Lon and Clp indicate that both proteases directly interact with substrates for degradation. ATP functions as an allosteric effector promoting an active conformation of the proteases, and ATP hydrolysis is required for rapid catalytic turnover of peptide bond cleavage in proteins. Lon and Clp show virtually no homology at the amino acid level, and thus it appears that at least two families of ATP-dependent proteases have evolved independently.

Regulation of two nested proteins from gene 49 (recombination endonuclease VII) and of a lambda RexA-like protein of bacteriophage T4

Phage T4 gene 49, encoding recombination endonuclease VII, specifies, by initiation from an AUG and an internal GUG codon, two in-frame overlapping peptides (of 18 and 12 kD). The gene is transcribed early and late, albeit from different promoters. The sequence predicts that in long early transcripts, initiated far upstream of the coding sequence, the Shine-Dalgarno sequence of the first ribosome binding site can be sequestered in a hairpin and/or cleaved. These processes might reduce initiation from the first AUG and facilitate initiation of the 12-kD peptide from the internal GUG. The potential of this hairpin to participate in Y structures or cruciforms suggests possible autoregulation. Shorter, more stable late transcripts initiated from a late promoter immediately upstream of the first ribosome binding site cannot form this hairpin. More efficient translation of the longer 18-kD gene 49 peptide from these late transcripts accounts for the strong dependence of endonuclease VII activity on late gene expression. An ORF downstream from gene 49 can be translated from a motA-dependent transcript that starts inside gene 49 as well as from the gene 49 transcripts. Its initiation codon overlaps the stop codon of gene 49, suggesting some coupling of translation. The deduced protein resembles, among others, the RexA protein of phage lambda. Possible implications for T4 recombination and for the interference of lambda lysogens with T4 gene 49 and rII mutants are discussed.