Cloning and characterization of the Escherichia coli lit gene, which blocks bacteriophage T4 late gene expression.

Escherichia coli lit mutations inhibit gene expression late in infection by bacteriophage T4. We cloned the lit gene from wild-type E. coli and three independent lit mutants. We present evidence that lit mutations [renamed lit(Con) mutations] cause overproduction of the lit gene product and that overproduction of this product causes the inhibition of gene expression. We also present evidence that the lit gene product is nonessential for E. coli growth, although the gene is common to most E. coli K-12 strains.     

Bacteriophage T4 gol site: sequence analysis and effects of the site on plasmid transformation.

The Escherichia coli lit gene product is required for the multiplication of bacteriophage T4 at temperatures below 34 degrees C. After infection of a lit mutant host, early gene product synthesis is normal, as is T4 DNA replication; however, the late gene products never appear, and early gene product synthesis eventually ceases. Consequently, at late times, there is no protein synthesis of any kind (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979; W. Champness and L. Snyder, J. Mol. Biol. 155:395-407, 1982), and no phage are produced. We have isolated T4 mutants which can multiply in lit mutant hosts. The responsible T4 mutations (called gol mutations) completely overcome the block to T4 gene expression (Cooley et al., J. Bacteriol. 140:83-91). We have proposed that gol mutations alter a cis-acting regulatory site on T4 DNA rather than a diffusible gene product and that the wild-type form of the gol site (gol+) somehow interferes with gene expression late in infection (Champness and Snyder, J. Mol. Biol. 155:395-409). In this communication, we report the sequence of the gol region of the T4 genome from five different gol mutants. The gol mutations are all single-base-pair transitions within 40 base pairs of DNA. Therefore, the gol site is at least 40 base pairs long. The sequence data confirm that the gol phenotype is not due to an altered protein. We also report that the gol+ site in plasmids prevents transformation of Lit- but not Lit+ E. coli. Thus, the gol site is at least partially active in the absence of the T4 genome.     

Insertion of a MalE β-Galactosidase Fusion Protein into the Envelope of Escherichia coli Disrupts Biogenesis of Outer Membrane Proteins and Processing of Inner Membrane Proteins

The synthesis of a membrane-bound MalE β-galactosidase hybrid protein, when induced by growth of Escherichia coli on maltose, leads to inhibition of cell division and eventually a reduced rate of mass increase. In addition, the relative rate of synthesis of outer membrane proteins, but not that of inner membrane proteins, was reduced by about 50%. Kinetic experiments demonstrated that this reduction coincided with the period of maximum synthesis of the hybrid protein (and another maltose-inducible protein, LamB). The accumulation of this abnormal protein in the envelope therefore appeared specifically to inhibit the synthesis, the assembly of outer membrane proteins, or both, indicating that the hybrid protein blocks some export site or causes the sequestration of some limiting factor(s) involved in the export process. Since the MalE protein is normally located in the periplasm, the results also suggest that the synthesis of periplasmic and outer membrane proteins may involve some steps in common. The reduced rate of synthesis of outer membrane proteins was also accompanied by the accumulation in the envelope of at least one outer membrane protein and at least two inner membrane proteins as higher-molecular-weight forms, indicating that processing (removal of the N-terminal signal sequence) was also disrupted by the presence of the hybrid protein. These results may indicate that the assembly of these membrane proteins is blocked at a relatively late step rather than at the level of primary recognition of some site by the signal sequence. In addition, the results suggest that some step common to the biogenesis of quite different kinds of envelope protein is blocked by the presence of the hybrid protein.     

The product of the virB4 gene of Agrobacterium tumefaciens promotes accumulation of VirB3 protein.

The process of T-DNA transfer from Agrobacterium tumefaciens to plant cells is thought to involve passage of a DNA-protein complex through a specialized structure in the bacterial membrane. The virB operon of A. tumefaciens encodes 11 proteins, of which 9 are known to be located in the membranes and 10 have been shown to be essential for virulence. Sequence comparisons between proteins encoded by the virB operon and those encoded by operons from conjugative plasmids indicated that VirB proteins may form a structure similar to a conjugative pilus. Here, we examine the effects of mutations in virB4 on the accumulation and localization of other VirB proteins. VirB4 shares amino acid sequence similarity with the TraC protein of plasmid F, which is essential for pilus formation in Escherichia coli, and with the PtlC protein of Bordetella pertussis, which is required for toxin secretion. Polar and nonpolar virB4 mutants were examined, and all were shown to be unable to accumulate VirB3 protein to wild-type levels. A low level of VirB3 protein which was present in induced NT1RE cells harboring virB4 nonpolar mutant pBM1130 was found to associate with the inner membrane fraction only, whereas in wild-type cells VirB3 associated with both inner and outer membranes. The results indicate that for VirB3 to accumulate in the outer membrane, VirB4 must also be present, and it is possible that one role of VirB4 is in the correct assembly of a VirB protein membrane structure.     

Secretion and membrane integration of a filamentous phage-encoded morphogenetic protein

The filamentous phage-encoded gene IV protein is required at high levels for virus assembly, although it is not a constituent of the virion. It is an integral membrane protein that does not contain an extended hydrophobic region of the kind often required for stable integration in the inner membrane. Rather, like a number of Escherichia coli outer membrane proteins, pIV is rich in charged amino acid residues and is predicted to consist of extensive beta-sheet structures. In phage-producing cells, pIV is primarily detected in the outer membrane, while in cells that produce it from the cloned gene, pIV is found in both the inner and outer membranes. The protein is synthesized as a precursor. Following cleavage of the signal sequence and translocation into the periplasm, the mature form is initially found as a soluble species. Soluble pIV then integrates into the membrane with a half-time of one to two minutes. Neither phage assembly nor other phage proteins are needed for this membrane integration, and phage assembly does not require the presence of the soluble form. The gene IV protein may be part of the structure through which the assembling phage is extruded.     

Both a short hydrophobic domain and a carboxyl-terminal hydrophilic region are important for signal function in the Escherichia coli leader peptidase

Leader peptidase, typical of inner membrane proteins of Escherichia coli, does not have an amino-terminal leader sequence. This protein contains an internal signal peptide, residues 51-83, which is essential for assembly and remains as a membrane anchor domain. We have employed site-directed mutagenesis techniques to either delete residues within this domain or substitute a charged amino acid for one of these residues to determine the important properties of the internal signal. The deletion analysis showed that a very small apolar domain, residues 70-76, is essential for assembly, whereas residues that flank it are dispensable for its function. However, point mutations with charged amino acid residues within the polar sequence (residues 77-82) slow or abolish leader peptidase membrane assembly. Thus, a polar region, Arg-Ser-Phe-Ile-Tyr-Glu, is important for the signal peptide function of leader peptidase, unlike other signals identified thus far.     

Molecular analysis of asmA, a locus identified as the suppressor of OmpF assembly mutants of Escherichia coli K-12

We present the molecular characterization of the asmA gene, whose product is involved in the assembly of outer membrane proteins in Escherichia coli K-12. The asmA locus was initially identified as a site for suppressor mutations of an assembly defective OmpF315. Our data suggest that these suppressor mutations either completely abolish or reduce asmA expression and can be complemented in trans by piasmid clones carrying asmA sequences. The recessive nature of asmA suppressor mutations suggests that the functional AsmA protein participates in Inhibiting the assembly of OmpF315 and other mutant OmpFs. As the assembly of wild-type and parental OmpF proteins was not affected by asmA mutations, AsmA must provide an environment refractory only to the assembly of mutant OmpF proteins. However, we cannot completely rule out the possibility that AsmA plays a minor role in the assembly of wild-type and parental OmpF in wild-type cells. The presence of a putative signal sequence within the amino-terminal sequence of AsmA suggests that it is either a periplasmic or an outer membrane protein. This predicted location of AsmA is compatible with its role in the assembly of outer membrane proteins.     

Lysis and lysis inhibition in bacteriophage T4: rV mutations reside in the holin t gene.

Upon infecting populations of susceptible host cells, T-even bacteriophages maximize their yield by switching from lysis at about 25 to 35 min at 37 degrees C after infection by a single phage particle to long-delayed lysis (lysis inhibition) under conditions of sequential infection occurring when free phages outnumber host cells. The timing of lysis depends upon gene t and upon one or more rapid-lysis (r) genes whose inactivation prevents lysis inhibition. t encodes a holin that mediates the movement of the T4 endolysin though the inner cell membrane to its target, the cell wall. The rI protein has been proposed to sense superinfection. Of the five reasonably well characterized r genes, only two, rI and rV, are clearly obligatory for lysis inhibition. We show here that rV mutations are alleles of t that probably render the t protein unable to respond to the lysis inhibition signal. The tr alleles cluster in the 5' third of t and produce a strong r phenotype, whereas conditional-lethal t alleles produce the classical t phenotype (inability to lyse) and other t alleles produce additional, still poorly understood phenotypes. tr mutations are dominant to t+, a result that suggests specific ways to probe T4 holin function.     

Effects of two sec genes on protein assembly into the plasma membrane of Escherichia coli

We have examined the effects of thermosensitive mutations in secA and secY (prlA) genes on the export of proteins to the three layers of the Escherichia coli cell surface. After several hours at the nonpermissive temperature, the export of two major outer membrane proteins, lipoprotein and OmpA, is delayed, then essentially blocked, in either a secA or secY strain. These mutations also have a strong effect on the export of several proteins, such as maltose binding protein, to the periplasm, though the export of many periplasmic proteins is not affected. secA and secY block the assembly of leader peptidase, which is made without a leader sequence, into the inner membrane. However, the membrane assembly of M13 coat protein (an inner membrane protein made with an amino-terminal leader sequence) is not affected. Thus, the requirement for sec function for export does not correlate with the presence or absence of leader peptide or with a particular subcellular compartment, but rather is specific to each particular protein.     

The product of the split sunY gene of bacteriophage T4 is a processed protein.

The sunY gene of bacteriophage T4 contains a self-splicing group I intron. The ligated exons encode an open reading frame of 605 amino acids, whose inferred molecular mass is 68 kDa. However, none of the proteins made following T4 infection have been assigned to the sunY gene, and no mutations have been mapped to this locus. We show here that the primary product of the sunY gene is a protein with an apparent molecular mass of 64 kDa, which is processed to a protein approximately 4 kDa smaller. Unlike most other processed T4 proteins, cleavage occurs independently of both the T4 processing protease, the product of gene 21, and late phage protein synthesis. Insertional mutagenesis demonstrated that the sunY protein is not necessary for normal T4 growth under the conditions tested.     

The Platform Protein Is Essential for Type IV Pilus Biogenesis

A systematic genetic analysis was performed to identify the inner membrane proteins essential for type IV pilus (T4P) expression in Pseudomonas aeruginosa. By inactivating the retraction aspect of pilus function, genes essential for T4P assembly were discriminated. In contrast to previous studies in the T4P system of Neisseria spp., we found that components of the inner membrane subcomplex consisting of PilMNOP were not essential for surface pilus expression, whereas the highly conserved inner membrane protein PilC was essential. Here, we present data that PilC may coordinate the activity of cytoplasmic polymerization (PilB) and depolymerization (PilT) ATPases via their interactions with its two cytoplasmic domains. Using in vitro co-affinity purification, we show that PilB interacts with the N-terminal cytoplasmic domain of PilC. We hypothesized that PilT similarly interacts with the PilC C-terminal cytoplasmic domain. Overexpression of that domain in the wild-type protein reduced twitching motility by ∼50% compared with the vector control. Site-directed mutagenesis of conserved T4P-specific residues in the PilC C-terminal domain yielded mutant proteins that supported wild-type pilus assembly but had a reduced capacity to support twitching motility, suggesting impairment of putative PilC-PilT interactions. Taken together, our results show that PilC is an essential inner membrane component of the T4P system, controlling both pilus assembly and disassembly.     

Molecular characterization and functional analysis of a secA gene homolog in Actinobacillus actinomycetemcomitans

Results of Southern blot analyses and polymerase chain reaction revealed that the Gram-negative pathogen, Actinobacillus actinomycetemcomitans, harbored DNA homologous to the secA gene of Escherichia coli. In E. coli, the secA gene product is essential for translocation of proteins across the inner membrane via the Sec system. This A. actinomycetemcomitans secA homolog was cloned and its nucleotide sequence determined. Amino acid sequence analysis of the cloned gene revealed significant homology to the SecA proteins of Haemophilus influenzae, E. coli, Caulobacter crescentus and Bacillus subtilis. Although the cloned gene did not complement a temperature sensitive mutation in the E. coli secA gene, strains harboring the cloned gene did produce a protein that cross-reacted with anti-SecA antibody. In addition, the cloned gene did restore sensitivity to sodium azide in an E. coli azide mutant. These data support the hypothesis that A. actinomycetemcomitans may use a system similar to the Sec system of E. coli to transport proteins across the cytoplasmic membrane, but suggest that the A. actinomycetemcomitans gene product may require genera-specific Sec proteins to complement some Sec mutations in E. coli.     

The Saccharomyces cerevisiae COQ6 gene encodes a mitochondrial flavin-dependent monooxygenase required for coenzyme Q biosynthesis

Coenzyme Q (Q) is a lipid that functions as an electron carrier in the mitochondrial respiratory chain in eukaryotes. There are eight complementation groups of Q-deficient Saccharomyces cerevisiae mutants, designated coq1-coq8. Here we have isolated the COQ6 gene by functional complementation and, in contrast to a previous report, find it is not an essential gene. coq6 mutants are unable to grow on nonfermentable carbon sources and do not synthesize Q but instead accumulate the Q biosynthetic intermediate 3-hexaprenyl-4-hydroxybenzoic acid. The Coq6 polypeptide is imported into the mitochondria in a membrane potential-dependent manner. Coq6p is a peripheral membrane protein that localizes to the matrix side of the inner mitochondrial membrane. Based on sequence homology to known proteins, we suggest that COQ6 encodes a flavin-dependent monooxygenase required for one or more steps in Q biosynthesis.     

Identification of a novel signal sequence that targets transmembrane proteins to the nuclear envelope inner membrane

Herpesvirus maturation requires translocation of glycoprotein B homologue from the endoplasmic reticulum to the inner nuclear membrane. Glycoprotein B of human cytomegalovirus was used in this context as a model protein. To identify a specific signal sequence within human cytomegalovirus glycoprotein B acting in a modular fashion, coding sequences were recombined with reporter proteins. Immunofluorescence and cell fractionation demonstrated that a short sequence element within the cytoplasmic tail of human cytomegalovirus glycoprotein B was sufficient to translocate the membrane protein CD8 to the inner nuclear membrane. This carboxyl-terminal sequence had no detectable nuclear localization signal activity for soluble beta-Galactosidase and could not be substituted by the nuclear localization signal of SV40 T antigen. For glycoprotein B of herpes simplex virus, a carboxyl-terminal element with comparable properties was found. Further experiments showed that the amino acid sequence DRLRHR of human cytomegalovirus glycoprotein B (amino acids 885-890) was sufficient for nuclear envelope translocation. Single residue mutations revealed that the arginine residues in positions 4 and 6 of the DRLRHR sequence were essential for its function. These results support the view that transmembrane protein transport to the inner nuclear membrane is controlled by a mechanism different from that of soluble proteins.     

Gene 68, a new bacteriophage T4 gene which codes for the 17K prohead core protein is involved in head size determination

We have identified the gene for a major component of the prohead core of bacteriophage T4, the 17K protein. The gene, which we call gene 68, lies between genes 67 and 21 in the major cluster of T4 head genes. All of the genes in this region of the T4 genome have overlapping initiation and termination codons with the sequence T-A-A-T-G. We present the DNA sequence of the gene and show that it codes for a protein containing 141 amino acids with an acidic amino-terminal half and a basic carboxyl terminus. Antibodies prepared against the 17K protein were used to show that it is cleaved by the phage-coded gp21 protease during head maturation and that most of the protein leaves the head after cleavage. A frameshift mutation of the gene was constructed in vitro and recombined back into the phage genome. The mutated phages had a drastically reduced burst size and about half of the particles produced were morphologically abnormal, having isometric rather than prolate heads. Thus, the 17K protein is involved in head shape determination but is only semi-essential for T4 growth.     

Signal sequence processing is required for the assembly of LamB trimers in the outer membrane of Escherichia coli.

Proteins destined for either the periplasm or the outer membrane of Escherichia coli are translocated from the cytoplasm by a common mechanism. It is generally assumed that outer membrane proteins, such as LamB (maltoporin or lambda receptor), which are rich in beta-structure, contain additional targeting information that directs proper membrane insertion. During transit to the outer membrane, these proteins may pass, in soluble form, through the periplasm or remain membrane associated and reach their final destination via sites of inner membrane-outer membrane contact (zones of adhesion). We report lamB mutations that slow signal sequence cleavage, delay release of the protein from the inner membrane, and interfere with maltoporin biogenesis. This result is most easily explained by proposing a soluble, periplasmic LamB assembly intermediate. Additionally, we found that such lamB mutations confer several novel phenotypes consistent with an abortive attempt by the cell to target these tethered LamB molecules. These phenotypes may allow isolation of mutants in which the process of outer membrane protein targeting is altered.     

Misfolding of mutant adenine nucleotide translocase in yeast supports a novel mechanism of Ant1-induced muscle diseases

Approximately one-third of proteins in the cell reside in the membrane. Mutations in membrane proteins can induce conformational changes and expose nonnative polar domains/residues to the lipid environment. The molecular effect of the resulting membrane stress is poorly defined. Adenine nucleotide translocase 1 (Ant1) is a mitochondrial inner membrane protein involved in ATP/ADP exchange. Missense mutations in the Ant1 isoform cause autosomal dominant progressive external ophthalmoplegia (adPEO), cardiomyopathy, and myopathy. The mechanism of the Ant1-induced pathologies is highly debated. Here we show that equivalent mutations in the yeast Aac2 protein cause protein misfolding. Misfolded Aac2 drastically affects the assembly and stability of multiple protein complexes in the membrane, which ultimately inhibits cell growth. Despite causing similar proteostatic damages, the adPEO- but not the cardiomyopathy/myopathy-type Aac2 proteins form large aggregates. The data suggest that the Ant1-induced diseases belong to protein misfolding disorders. Protein homeostasis is subtly maintained on the mitochondrial inner membrane and can be derailed by the misfolding of one single protein with or without aggregate formation. This finding could have broad implications for understanding other dominant diseases (e.g., retinitis pigmentosa) caused by missense mutations in membrane proteins.