A new suppressor of a lamB signal sequence mutation, prlZ1, maps to 69 minutes on the Escherichia coli chromosome.

Reversion analysis has been employed to isolate suppressors that restore export of a unique LamB signal sequence mutant. The mutation results in a substitution of Arg for Met at position 19, which prevents LamB export to the outer membrane and leads to a Dex- phenotype. Unlike other LamB signal sequence mutants utilized for reversion analysis, LamB19R becomes stably associated with the inner membrane in an export-specific manner. In this study, Dex+ revertants were selected and various suppressors were isolated. One of the extragenic suppressors, designated prlZ1, was chosen for further study. prlZ1 maps to 69 min on the Escherichia coli chromosome. The suppressor is dominant and SecB dependent. In addition to its effect on lamB19R, prlZ1 suppresses the export defect of signal sequence point mutations at positions 12, 15, and 16, as well as several point mutations in the maltose-binding protein signal sequence. prlZ1 does not suppress deletion mutations in either signal sequence. This pattern of suppression can be explained by interaction of a helical LamB signal sequence with the suppressor.

Export and trimerization pathways of maltoporin overlap in the inner membrane of Escherichia coli.

The production of functional porins involves multiple steps including: export of precursor polypeptides from the cytoplasm, assembly of monomers into trimers, and stabilization of trimers by association with lipopolysaccharide. In this report, a late export/assembly intermediate of the maltoporin (LamB) is found in the inner membrane of Escherichia coli using cell fractionation studies. This processed intermediate is transiently associated with a unique Triton X-100-insoluble subfraction of the inner membrane. The kinetics of appearance and solubility characteristics of this intermediate correspond to those of the metastable trimer form of LamB, suggesting that the export and assembly pathways overlap in the inner membrane prior to final localization in the bulk outer membrane.

Two distinct regions of the LamB signal sequence function in different steps in export.

The hydrophobic core of the Escherichia coli LamB signal sequence contains two structurally distinct regions. One region forms a helix in nonpolar environments, and the other is less structured. These regions seem to be of special importance for export, as judged by the magnitude of the defect caused by their mutational inactivation. To gain insight into the mechanistic importance of these two regions, we examined the ability of precursors to pass partially through the export pathway when each region is mutated. The results demonstrate that mutations in the helical and unstructured regions of the signal sequence block different steps in the export pathway.

New suppressors of signal-sequence mutations, prlG, are linked tightly to the secE gene of Escherichia coli.

Analysis of more than 100 extragenic suppressors of the lamB14D signal-sequence mutation (changes Val in the hydrophobic core region at position 14 to Asp) has revealed alterations that appear to lie at prlA (secY) and secA (prlD), two loci known to be mutable to suppressor alleles, and a new suppressor termed prlG. One allele of the new suppressor class, prlG1, has been characterized in some detail. This suppressor counteracts, to some degree, the export defect conferred by a variety of signal-sequence mutations in two different genes, lamB and malE. Genetic analysis shows that the dominant suppressor mutations are linked tightly to, and probably allelic with, the gene secE. This result, coupled with data obtained with conditional-lethal alleles of secE, argues strongly that SecE is an important component of the cellular protein export machinery in Escherichia coli.

Two cellular components, PrlA and SecB, that recognize different sequence determinants are required for efficient protein export.

We exploited the conditional-lethal phenotype of secB null mutations to demonstrate that SecB function was required for PrlA-mediated suppression of signal sequence mutations. The results of these experiments provide information about the functions performed and the sequence determinants recognized by each of these components of the protein export machinery of Escherichia coli.

A progenitor of the outer membrane LamB trimer.

During its localization to the outer membrane, LamB possesses distinctive biochemical properties as it passes through the cytoplasmic membrane. Because LamB entered this dynamic state with an attached signal sequence and leaves after cleavage, we call this export-related form of LamB the early-translocation form (et-LamB).

Kinetic analysis of lamB mutants suggests the signal sequence plays multiple roles in protein export.

We have developed a quantitative assay to measure the rate of processing of precursor LamB into mature protein and have used this assay to characterize 10 previously isolated and 3 new lamB signal sequence mutants. The data suggest that the LamB signal sequence serves a complex function. Our assay has revealed five types of signal sequence defect: 1) a strong kinetic defect resulting from alteration of the secondary structure in the putative alpha-helical region in the hydrophobic core, 2) a strong, or 3) a weak kinetic defect due to placement of a charged residue in the hydrophobic core, 4) decreased synthesis of LamB, and 5) both a decrease in synthesis and a strong kinetic defect. The effect of an extragenic suppressor, prlA4 on the rate of processing pLamB containing signal sequence mutations was also examined and compared to the rates in wild-type strains. It was found that prlA4 increases the rate of processing in some, but not all, mutants having a kinetic defect while having no effect on the decreased synthesis seen in mutants of types 4 and 5.

Nucleotide sequence of the Escherichia coli motB gene and site-limited incorporation of its product into the cytoplasmic membrane.

The motB gene product of Escherichia coli is an integral membrane protein required for rotation of the flagellar motor. We have determined the nucleotide sequence of the motB region and find that it contains an open reading frame of 924 nucleotides which we ascribe to the motB gene. The predicted amino acid sequence of the gene product is 308 residues long and indicates an amphipathic protein with one major hydrophobic region, about 22 residues long, near the N terminus. There is no consensus signal sequence. We postulate that the protein has a short N-terminal region in the cytoplasm, an anchoring region in the membrane consisting of two spanning segments, and a large cytoplasmic C-terminal domain. By placing motB under control of the tryptophan operon promoter of Serratia marcescens, we have succeeded in overproducing the MotB protein. Under these conditions, the majority of MotB was found in the cytoplasm, indicating that the membrane has a limited capacity to incorporate the protein. We conclude that insertion of MotB into the membrane requires the presence of other more hydrophobic components, possibly including the MotA protein or other components of the flagellar motor. The results further reinforce the concept that the total flagellar motor consists of more than just the basal body.

Gene sequence and predicted amino acid sequence of the motA protein, a membrane-associated protein required for flagellar rotation in Escherichia coli.

The motA and motB gene products of Escherichia coli are integral membrane proteins necessary for flagellar rotation. We determined the DNA sequence of the region containing the motA gene and its promoter. Within this sequence, there is an open reading frame of 885 nucleotides, which with high probability (98% confidence level) meets criteria for a coding sequence. The 295-residue amino acid translation product had a molecular weight of 31,974, in good agreement with the value determined experimentally by gel electrophoresis. The amino acid sequence, which was quite hydrophobic, was subjected to a theoretical analysis designed to predict membrane-spanning alpha-helical segments of integral membrane proteins; four such hydrophobic helices were predicted by this treatment. Additional amphipathic helices may also be present. A remarkable feature of the sequence is the existence of two segments of high uncompensated charge density, one positive and the other negative. Possible organization of the protein in the membrane is discussed. Asymmetry in the amino acid composition of translated DNA sequences was used to distinguish between two possible initiation codons. The use of this method as a criterion for authentication of coding regions is described briefly in an Appendix.