PrlC, a suppressor of signal sequence mutations in Escherichia coli, can direct the insertion of the signal sequence into the membrane

The prlC gene product of Escherichia coli can be altered by mutation so that it restores export of proteins with defective signal sequences. The strongest suppressor, prlC8, restores processing of a mutant signal sequence to a rate indistinguishable from the wild-type. Data obtained by changing gene dosage of the dominant suppressor and its specificity for different signal sequence mutations suggest that PrlC8 interacts directly with the hydrophobic core of the signal sequence. Despite the fact that signal sequence processing appears to be mediated by leader peptidase, the processed mature protein is not translocated efficiently from the cytoplasm. Results obtained with various double mutants indicate that PrlC8-mediated processing of mutant signal sequences does not require components of the cellular export machinery such as SecA, SecB or PrlA (SecY) and that the block in translocation from the cytoplasm occurs because PrlA (SecY) fails to recognize the defective signal sequence. We suggest that PrlC8 directs insertion of the mutant signal sequence into the membrane bilayer to an extent that processing by leader peptidase can occur. This reaction is novel in that it has not been observed previously in vivo.     

Secretion-defective mutations in the signal sequence for Saccharomyces cerevisiae invertase.

Nine mutations in the signal sequence region of the gene specifying the secreted Saccharomyces cerevisiae enzyme invertase were constructed in vitro. The consequences of these mutations were studied after returning the mutated genes to yeast cells. Short deletions and two extensive substitution mutations allowed normal expression and secretion of invertase. Other substitution mutations and longer deletions blocked the formation of extracellular invertase. Yeast cells carrying this second class of mutant gene expressed novel active internal forms of invertase that exhibited the following properties. The new internal proteins had the mobilities in denaturing gels expected of invertase polypeptides that had retained a defective signal sequence and were otherwise unmodified. The large increase in molecular weight characteristic of glycosylation was not seen. On nondenaturing gels the mutant enzymes were found as heterodimers with a normal form of invertase that is known to be cytoplasmic, showing that the mutant forms of the enzyme are assembled in the same compartment as the cytoplasmic enzyme. All of the mutant enzymes were soluble and not associated with the membrane components after fractionation of crude cell extracts on sucrose gradients. Therefore, these signal sequence mutations result in the production of active internal invertase that has lost the ability to enter the secretory pathway. This demonstrates that the signal sequence is required for the earliest steps in membrane translocation.     

Two nuclear export signals of Cdc6 are differentially associated with CDK-mediated phosphorylation residues for cytoplasmic translocation

Cdc6 is cleaved at residues 442 and 290 by caspase-3 during apoptosis producing p49-tCdc6 and p32-tCdc6, respectively. While p32-tCdc6 is unable to translocate into the cytoplasm, p49-tCdc6 retains cytoplasmic translocation activity, but it has a lower efficiency than wild-type Cdc6. We hypothesized that a novel nuclear export signal (NES) sequence exists between amino acids 290 and 442. Cdc6 contains a novel NES in the region of amino acids 300–315 (NES2) that shares sequence similarity with NES1 at residues 462–476. In mutant versions of Cdc6, we replaced leucine with alanine in NES1 and NES2 and co-expressed the mutant constructs with cyclin A. We observed that the cytoplasmic translocation of these mutants was reduced in comparison to wild-type Cdc6. Moreover, the cytoplasmic translocation of a mutant in which all four leucine residues were mutated to alanine was significantly inhibited in comparison to the translocation of wild-type Cdc6. The Crm1 binding activities of Cdc6 NES mutants were consistent with the efficiency of its cytoplasmic translocation. Further studies have revealed that L468 and L470 of NES1 are required for cytoplasmic translocation of Cdc6 phosphorylated at S74, while L311 and L313 of NES2 accelerate the cytoplasmic translocation of Cdc6 phosphorylated at S54. These results suggest that the two NESs of Cdc6 work cooperatively and distinctly for the cytoplasmic translocation of Cdc6 phosphorylated at S74 and S54 by cyclin A/Cdk2.     

Genes Affecting the Regulation of SUC2 Gene Expression by Glucose Repression in SACCHAROMYCES CEREVISIAE

Mutants of Saccharomyces cerevisiae with defects in sucrose or raffinose fermentation were isolated. In addition to mutations in the SUC2 structural gene for invertase, we recovered 18 recessive mutations that affected the regulation of invertase synthesis by glucose repression. These mutations included five new snf1 (sucrose nonfermenting) alleles and also defined five new complementation groups, designated snf2, snf3, snf4, snf5, and snf6. The snf2, snf4, and snf5 mutants produced little or no secreted invertase under derepressing conditions and were pleiotropically defective in galactose and glycerol utilization, which are both regulated by glucose repression. The snf6 mutant produced low levels of secreted invertase under derepressing conditions, and no pleiotropy was detected. The snf3 mutants derepressed secreted invertase to 10-35% the wild-type level but grew less well on sucrose than expected from their invertase activity; in addition, snf3 mutants synthesized some invertase under glucose-repressing conditions.--We examined the interactions between the different snf mutations and ssn6, a mutation causing constitutive (glucose-insensitive) high-level invertase synthesis that was previously isolated as a suppressor of snf1. The ssn6 mutation completely suppressed the defects in derepression of invertase conferred by snf1, snf3, snf4 and snf6, and each double mutant showed the constitutivity for invertase typical of ssn6 single mutants. In contrast, snf2 ssn6 and snf5 ssn6 strains produced only moderate levels of invertase under derepressing conditions and very low levels under repressing conditions. These findings suggest roles for the SNF1 through SNF6 and SSN6 genes in the regulation of SUC2 gene expression by glucose repression.     

Sorting of soluble ER proteins in yeast.

In animal cells, luminal endoplasmic reticulum (ER) proteins are prevented from being secreted by a sorting system that recognizes the C-terminal sequence KDEL. We show that yeast has a similar sorting system, but it recognizes HDEL, rather than KDEL: derivatives of the enzyme invertase that bear the HDEL signal fail to be secreted. An invertase fusion protein that is retained in the cells is partially modified by outer-chain mannosyl transferases, which reside in the Golgi element. This supports the view, based on studies in animal cells, that ER targeting is achieved by continuous retrieval of proteins from the Golgi. We have used an invertase fusion gene to screen for mutants that are defective in this sorting system. Over 60 mutants were obtained; eight of these are alleles of a single gene, erd1. The mutant strains grow normally at 30 degrees C, but instead of retaining the fusion protein in the cells, they secrete it.     

Escherichia coli SecB stimulates export without maintaining export competence of ribose-binding protein signal sequence mutants.

Ribose-binding protein (RBP) is exported to the periplasm of Escherichia coli via the general export pathway. An rbsB-lacZ gene fusion was constructed and used to select mutants defective in RBP export. The spontaneous Lac+ mutants isolated in this selection contained either single-amino-acid substitutions or a deletion of the RBP signal sequence. Intact rbsB genes containing eight different point mutations in the signal sequence were reconstructed, and the effects of the mutations on RBP export were examined. Most of the mutations caused severe defects in RBP export. In addition, different suppressor mutations in SecY/PrlA protein were analyzed for their effects on the export of RBP signal sequence mutants in the presence or absence of SecB. Several RBP signal sequence mutants were efficiently suppressed, but others were not suppressed. Export of an RBP signal sequence mutant in prlA mutant strains was partially dependent on SecB, which is in contrast to the SecB independence of wild-type RBP export. However, the kinetics of export of an RBP signal sequence mutant point to a rapid loss of pre-RBP export competence, which occurs in strains containing or lacking SecB. These results suggest that SecB does not stabilize the export-competent conformation of RBP and may affect translocation by stabilizing the binding of pre-RBP at the translocation site.     

A new genetic selection identifies essential residues in SecG, a component of the Escherichia coli protein export machinery.

The signal sequence of the murine serine protease inhibitor PAI-2 promotes alkaline phosphatase export to the E. coli periplasm. However, high level expression of this chimeric protein interferes with cell growth. Since most suppressors of this toxic phenotype map to secA and secY, growth arrest results from a defective interaction of the chimeric protein with the export machinery. We have characterized suppressors which map in secG, a newly defined gene of the export machinery. All single amino acid substitutions map to three adjacent codons. These secG mutants have a weak Sec phenotype, as determined by their effect on export mediated by wild-type and mutant signal sequences. Whilst a secG disruption allele also confers a weak Sec phenotype, it does not suppress the toxicity of the chimeric protein. This difference results from a selective effect of the secG suppressors on the kinetics of export mediated by the PAI-2 signal sequence. Using a malE signal sequence mutant, which has a Mal-phenotype in secG mutant strains, we have isolated extragenic Mal+ suppressors. Most suppressors map to secY, and several are allele-specific. Finally, SecG overexpression accelerates the kinetics of protein export, suggesting that there are two types of functional translocation complexes: with or without SecG.     

Intragenic revertants of yeast invertase variants with secretion-defective leader sequences.

Several secretion-defective variants of invertase from Saccharomyces cerevisiae were generated by replacement of the wild-type signal sequence codons with DNA fragments with random sequences. Strains encoding these proteins failed to grow on medium containing sucrose as the sole source of carbon. The invertase that was made in these strains was found to fractionate with soluble, cytoplasmic proteins, and indirect immunofluorescence confirmed that the mutant invertase was located throughout the cytoplasm. To define the defects in the secretion-defective leader sequences, we selected revertants by requiring growth on sucrose. Surprisingly, most of the reversion events consisted of point changes and duplications in the upstream noncoding portion of the gene. Each of these changes introduced several hydrophobic residues into the nonfunctional leader sequences, suggesting that the defective random leader peptides might simply lack adequate hydrophobicity to be effective signal peptides.     

Isolation, complementation and partial characterization of mutants of the methanol autotroph Xanthobacter H4-14 defective in methanol dissimilation

Seven mutants of Xanthobacter H4-14, unable to grow on methanol but capable of growth on formate, were isolated and complemented with a chromosomal clone bank constructed in the broad-host-range cosmid pVK100. One mutant could not be complemented but the others fell into four distinct complementation groups that involved three different recombinant clones. All of the complementing regions were separated by at least 10 kbp. The five complementation classes had different phenotypic characteristics and were defective in different aspects of methanol and formaldehyde oxidation. Class I mutants were defective in methanol oxidation, class II mutants were impaired in formaldehyde oxidation, class III mutants appeared to be defective in a regulatory element involving the methanol oxidation system, and class IV mutants appeared to be defective in a regulatory element involving formaldehyde oxidation. Class V mutants exhibited a methanol-sensitive phenotype, which was correlated with an imbalance between methanol and formaldehyde dehydrogenase activities. Analysis of this class suggested it was defective in a repressor that regulated methanol dissimilation functions.     

N-terminal basic amino acids are not required for translocation and processing of preproparathyroid hormone

An N-terminal deletion mutant of preproparathyroid hormone that contains a single basic amino acid, lysine, in the N-terminal domain of the signal peptide is translocated across the endoplasmic reticulum membrane similarly to intact preproparathyroid hormone. To examine the function of charged residues preceeding the hydrophobic core, the lysine was replaced by an uncharged (methionine) or negatively charged (glutamic acid) amino acid. The translocational activity of the mutant signal peptides was assayed in a reticulocyte lysate system containing chicken oviduct microsomal membranes. Altering the net charge of the N-terminal domain did not abolish signal sequence activity, although the efficiency of translocation was decreased for the mutant with a glutamic acid substitution. Posttranslational, ribosome independent, translocation was observed for all the mutants tested, with the same dependence on N-terminal charge but with much lower efficiency than cotranslational translocation. These studies show that the presence of basic amino acids in the N-terminal domain of a eukaryotic signal sequence is not required for its activity.     

Neither lipid modification nor processing of prolipoprotein is essential for the formation of murein-bound lipoprotein in Escherichia coli.

The relationship between the modification and processing of prolipoprotein and the formation of murein-bound lipoprotein has been investigated using Escherichia coli mutants altered in the signal sequence of prolipoprotein and an E. coli strain producing OmpF-Lpp hybrid protein. The glyceride-modified prolipoprotein in mutant lppT20 and in globomycin-treated wild-type strain were covalently attached to the peptidoglycan. Likewise, the unmodified prolipoproteins in mutants lppL20, lppV20, and lppG21 were attached to the peptidoglycan. The OmpF-Lpp hybrid protein that is processed but not modified with lipid due to the absence of the cysteine-containing modification site in the hybrid protein was also covalently linked to the peptidoglycan. These results indicate that neither lipid modification nor the processing of prolipoprotein is essential for the formation of murein-bound lipoprotein in E. coli. In contrast, introduction of a charged amino acid residue such as Asp or Arg at the 14th position of prolipoprotein affected not only the lipid modification and processing of the mutant prolipoprotein but also the formation of murein-bound lipoprotein. Replacement of the Gly14 with Glu or Lys partially affected the lipid modification and processing of prolipoprotein; the peptidoglycan of the lppE14 and lppK14 mutants contained a reduced amount of mature lipoprotein but no mutant prolipoprotein. In addition, lpp mutants A20I23I24 and A20I23K24 were found to be defective in both lipid modification/processing of prolipoprotein and the formation of murein-bound lipoprotein. The defective formation of murein-bound lipoprotein in the latter mutants may be related to an alteration in the secondary structure at the modification/processing site of the mutant prolipoproteins.     

Relationship of siderophore-mediated iron assimilation to virulence in crown gall disease

Three classes of mutants defective in the biosynthesis of the siderophore agrobactin were isolated from Agrobacterium tumefaciens A217 after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. Class I mutants produced uniquely the catechol 2,3-dihydroxybenzoic acid, whereas classes II and III produced no detectable catechol. Class II differed from class III mutants in that exogenous 2,3-dihydroxybenzoic acid was utilized only by the former to synthesize agrobactin. Growth of strains B6 and A217, under iron starvation, led to enhanced production of several envelope proteins migrating in the 80,000-dalton range upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. One mutant, defective in agrobactin iron utilization, lacked one of these proteins. This protein may represent a siderophore receptor or fragment or subunit thereof. With a single exception, all of the mutants obtained in this work were capable of initiating tumorous growth in sunflower plants and on carrot root disks, provided pTiB6806 was present. Comparison of the catechols produced by strain B6806 and its nononcogenic, Ti-plasmid-deficient derivative A217, indicated that the genes encoding agrobactin synthesis are not associated with the virulence plasmid of A. tumefaciens B6806. Analysis of gall tissue for agrobactin did not reveal the presence of this siderophore. Finally, citrate, an iron-carrier in plants, enhanced significantly the growth of the agrobactin-deficient mutants in a low-iron medium. These results suggest that the production of agrobactin in planta is not requisite to infection and that citrate may serve as an alternative carrier of iron for A. tumefaciens within the host.     

Isolation and characterization of mutants of Rhizobium leguminosarum bv. viciae 248 with altered lipopolysaccharides: possible role of surface charge or hydrophobicity in bacterial release from the infection thread

Effects of alterations in lipopolysaccharide (LPS) structure of Rhizobium leguminosarum bv. viciae on effective symbiosis and on a number of cell surface characteristics were studied. Tn5 mutants with altered LPSs were screened for their inability to bind monoclonal antibody 3, one of three monoclonal antibodies to the tentative O-antigenic part of the wild-type LPS of strain 248. Ten class I LPS mutants completely lacked the O-antigen-containing LPS species. The class II LPS mutant had a severely diminished amount of an antigenically altered O-antigen-containing LPS. The class III LPS mutant had normal amounts of an altered, O-antigen-containing LPS. Class I and II mutants, but not the class III mutant, showed abnormal nodule development (i.e., blocked in the stage of bacterial release from the infection thread) resulting in nodules in which very few, at the most, plant cells contained bacteroids and which were unable to fix nitrogen. Class I and II mutants were nonmotile and were more sensitive to hydrophobic compounds than the parent strain. The most striking difference between the symbiotically defective class I and II LPS mutants on one hand and the wild-type strain and the class III mutant on the other hand was that the class I and II mutants have a more hydrophobic cell surface and a higher electrophoretic mobility. A role for an O-antigen-containing LPS in bacterial release from the infection thread, through its effects on general physicochemical cell surface characteristics, is proposed.     

A domain of the hepadnavirus capsid protein is specifically required for DNA maturation and virus assembly

Mutations introduced into the capsid gene of duck hepatitis B virus (DHBV) were tested for their effects on viral DNA synthesis and assembly of enveloped viruses. Four classes of mutant phenotypes were observed among a series of deletions of covering the 3' end of the capsid open reading frame. Class I mutant capsids were able to support normal single-stranded and relaxed circular viral DNA synthesis; class II mutant capsids supported normal single-stranded DNA synthesis but not relaxed circular DNA synthesis; class III mutant capsids resembled class II capsids, but viral DNA synthesis was inhibited 5- to 10-fold; and class IV capsids were severely restricted in their ability to support viral DNA synthesis. Class I capsids were assembled into enveloped virions, but class II, III, and IV capsids were not. Viral DNA synthesized inside class II capsids was normal with respect to minus-strand DNA initiation, plus-strand DNA initiation, and circularization of the DNA, but plus strands failed to be elongated to mature 3-kb DNA. The results suggest that a function of the capsid protein specifically required for viral DNA maturation is also required for assembly of nucleocapsids into envelopes. Thus, class II mutants appear to be defective in the appearance of the "packaging signal" for virus assembly (J. Summers and W. Mason, Cell 29:403-415, 1982).     

Isolation and properties of Bacillus brevis mutants unable to produce tyrocidine.

Mutants of Bacillus brevis ATCC 10068 were isolated which produced less than 1/100 of the amount of tyrocidine produced by the parent strain. These mutants produced spores at the same frequency and which were as resistant to heating at 80 degrees C for up to 3 h as were those produced by the parent strain. A partially purified tyrocidine synthetase from strain ATCC 10068 catalyzed [32P]PPi-ATP exchange reactions dependent on added tyrocidine-constituent amino acids. These activities were separated into three groups (I, II, and III) by fractionation on an Ultrogel AcA34 column. Each group was similar to one of the three components (heavy, intermediate, and light, respectively) found previously for strain ATCC 8185 except that glutamate-dependent activity was not detected in the group I activities and some amino acyl-tRNA synthetase activities were associated with the group III activities. Some of the mutants were shown to have defective tyrocidine synthetase enzymes. Mutant BH30 was defective in two of the group II amino acid-dependent [32P]PPi-ATP exchange reactions, mutant BH16 was defective in one of the group I and one of the group II reactions, and mutant BH34 had alterations to activities in all of the groups. It is unlikely that any of these mutants could synthesise tyrocidine. We conclude that tyrocidine is not involved in either the sporulation process or the resistance of spores of B. brevis ATCC 10068 to heating at 80 degrees C for up to 3 h.     

Mutations that alter the signal sequence of alkaline phosphatase in Escherichia coli.

A phoA-lacZ gene fusion was used to isolate mutants altered in the alkaline phosphatase signal sequence. This was done by selecting Lac+ mutants from a phoA-lacZ fusion strain that produces a membrane-bound hybrid protein and is unable to grow on lactose. Two such mutant derivatives were characterized. The mutations lie within the phoA portion of the fused gene and cause internalization of the hybrid protein. When the mutations were genetically recombined into an otherwise wild-type phoA gene, they interfered with export of alkaline phosphatase to the periplasm. The mutant alkaline phosphatase protein was found instead in the cytoplasm in precursor form. DNA sequence analysis demonstrated that both mutations lead to amino acid alterations in the signal sequence of alkaline phosphatase.     

Mutational analysis of simian virus 40 T antigen: isolation and characterization of mutants with deletions in the T-antigen gene.

A series of mutants of simian virus 40 has been constructed with deletions in the coding sequence for large T antigen. Nucleotide sequence analysis indicates that 4 mutants have in-phase and 11 have out-of-phase deletions. Mutant DNAs were assayed for the following activities: the ability to form plaques, the ability to produce T antigen as scored by indirect immunofluorescence, viral DNA replication, and morphological transformation of rat cells. Two viable mutants were found, and these had deletions confined to the carboxyl terminus of T antigen. Only those mutants coding for polypeptides greater than 40% of the length of wildtype T antigen produced detectable nuclear fluorescence. The two viable mutants with deletions in the carboxyl terminus of the protein retained the ability both to replicate their DNA, although at a reduced level, and to transform nonpermissive cells. Mutants with sequence changes that result in the loss of more than 117 amino acids from the carboxyl terminus were not viable and were also defective in the DNA replication and transformation functions of T antigen, although several produced detectable nuclear fluorescence. These functions were also sensitive to the removal of amino acids near the amino terminus and in the middle of the protein.     

Pleiotropic hydrogenase mutants of Escherichia coli K12: growth in the presence of nickel can restore hydrogenase activity

Anaerobic growth in the presence of 0.6 mM NiCl2 was able to restore hydrogenase and benzyl-viologen-linked formate dehydrogenase activities to a mutant (FD12), which is normally defective in these activities. This mutant carries a mutation located near minute 58 in the genome. Hydrogenase isoenzyme I and II activities were restored along with the hydrogenase activity that forms part of the formate hydrogen lyase system. A plasmid (pRW1) was constructed, containing a 4.8 kb chromosomal DNA insert, which was able to complement the lesion in mutant FD12. Further mutants with mutations near 58 minutes on the chromosome, and which lacked hydrogenase and formate dehydrogenase activities were isolated. These mutants were divided into three groups. Class I mutants were restored to the wild-type phenotype either by growth with 0.6 mM NiCl2 or following transformation with pRW1. Class II mutants were also complemented by pRW1 but were unaffected by growth with NiCl2. Class III mutants were unaffected by both pRW1 and growth with NiCl2. The cloned 4.8 kb fragment of chromosomal DNA therefore encodes two genes essential for hydrogenase activity. Restriction analysis indicates that the cloned DNA is the same as a fragment that has previously been cloned and which complements the hydB locus (Sankar et al. (1985) J. Bacteriol., 162, 353-360). None of the three classes of mutants possess mutations in hydrogenase structural genes.     

Redundancy of signal and anchor functions in the NH2-terminal uncharged region of influenza virus neuraminidase, a class II membrane glycoprotein

Class II membrane glycoproteins share a common topology of the NH2 terminus inside and the COOH terminus outside the cell. Their transport to the cell surface is initiated by the function of a single hydrophobic domain near the NH2 terminus. This functional domain serves both as an uncleaved signal sequence and as a transmembrane anchor. We examined the signal and anchor functions of influenza virus neuraminidase, a prototype class II membrane glycoprotein, by deletion analysis of its long, uncharged amino-terminal region. The results presented here show that the entire stretch of 29 uncharged amino acids (7 to 35) is not required for either a signal sequence or an anchor sequence function. On the basis of translocation and membrane stability data for different mutants, we suggest that the first 20 amino acid residues (7 to 27) are likely to provide the hydrophobic core for these functions and that within this putative subdomain some sequences are more efficient than the other sequences in providing a translocation function. Finally, it appears that neuraminidase and its mutant proteins are translocated with the proper orientation, regardless of the characteristics of the flanking sequences.