Genetic characterization of an Escherichia coli mutant altered in the structure of murein lipoprotein

Phenotypic analysis of Eschericia coli mutants lacking L,D-transpeptidases

Escherichia coli has five genes encoding L,D-transpeptidases (Ldt) with varied functions. Three of these enzymes (YbiS, ErfK, YcfS) have been shown to cross-link Braun's lipoprotein to the peptidoglycan (PG), while the other two (YnhG, YcbB) form direct meso-diaminopimelate (DAP-DAP, or 3-3) cross-links within the PG. In addition, Ldt enzymes can also incorporate non-canonical D-amino acids, such as D-methionine, into the PG. To further investigate the role of these enzymes and, in particular, 3-3 linkages in cell envelope physiology we constructed and phenotypically characterized a variety of multiple Ldt deletion mutants of E. coli. We report that a triple deletion mutant lacking ybiS, erfK and ycfS is hypersusceptible to the metal-chelating agent EDTA, leaks periplasmic proteins and is resistant to the toxic effect of D-methionine. A double ynhG ycbB mutant had no discernible phenotype; however, examination of the phenotypes of various Ldt mutants bearing an additional DAP auxotrophic mutation (dapA : : Cm) showed that a quintuple mutant strain lacking all Ldt genes was severely impaired for growth on media with limited DAP. These data demonstrate that loss of the E. coli Ldt enzymes involved with coupling the PG to Braun's lipoprotein resulted in the loss of outer membrane stability while loss of the Ldt enzymes involved with DAP-DAP linkages had no observable effect on the cell envelope. Loss of all Ldt enzymes proved detrimental to growth when cells were starved for DAP, indicating a combined role for both 3-3 and Braun's lipoprotein cross-links in cell viability only under a specific PG stress.

Characterization of six lipoproteins in the sigmaE regulon

In Escherichia coli, sigma(E) regulon functions are required for envelope homeostasis during stress and are essential for viability under all growth conditions. The E. coli genome encodes approximately 100 lipoproteins, and 6 of these are regulated by sigma(E). Phenotypes associated with deletion of each of these lipoproteins are the subject of this report. One lipoprotein, YfiO, is essential for cellular viability. However, overexpression of this protein is not sufficient to alleviate the requirement of sigma(E) for viability, suggesting that the sigma(E) regulon provides more than one essential function. The remaining five lipoproteins in the sigma(E) regulon are nonessential; cells are viable even when all five are removed simultaneously. Deletion of three nonessential lipoprotein genes (nlpB, yraP, ygfL) results in the exhibition of phenotypes that suggest they are important for maintenance of the integrity of the cell envelope. deltanlpB cells are selectively sensitive to rifampin; deltayraP cells are selectively sensitive to sodium dodecyl sulfate. Such selective sensitivity has not been previously reported. Both deltayraP and deltanlpB are synthetically lethal with surA::Cm, which encodes a periplasmic chaperone and PPIase, suggesting that NlpB and YraP play roles in a periplasmic folding pathway that functions in parallel with that of SurA. Finally, the deltayfgL mutant exhibits a broad range of envelope defects, including sensitivity to several membrane-impermeable agents, an altered outer membrane protein profile, synthetic lethality with both surA::Cm and deltafkpA::Cm strains, and sensitivity to a bactericidal permeability-increasing peptide. We suggest that this lipoprotein performs a very important but as-yet-unknown function in maintaining the integrity of the cell envelope.

Genetic characterization of the Escherichia coli cyclopropane fatty acid (cfa) locus and neighboring loci

The phenotypically silent cyclopropane fatty acid synthesis (cfa) gene of Escherichia coli K-12 has been located on the genetic linkage map. This was accomplished by integrating (via homologous recombination) the selectable marker of a recombinant plasmid into the host chromosome near the cfa locus. This integration allowed the subsequent isolation of a cfa-linked transposon Tn10 insertion. Genetic mapping of the Tn10 insertion, using conventional techniques, placed the cfa locus at min 36.5 on the linkage map in the vicinity of several other non-selectable markers. We ordered cfa and these other loci by three-factor transductional analyses. Selection for excision of the Tn10 element resulted in several types of mutants which harbor mutations of cfa and of neighboring genes, presumably as a consequence of Tn10-catalyzed chromosomal rearrangements.

Assembly of outer membrane lipoprotein in an Escherichia coli mutant with a single amino acid replacement within the signal sequence of prolipoprotein

We have compared the rate of assembly of outer membrane proteins including the lipoprotein in a pair of isogenic mlpA+ (lpp+) and mlpA (lpp) strains by pulse-chase experiments. The rate of assembly of the mutant prolipoprotein into the outer membrane was slightly slower than that of the wild-type lipoprotein. The rate of assembly of protein I and protein H-2 was similar in the wild type and the mutant, whereas the rate of assembly of protein II into the outer membrane was slightly reduced in the mutant strain. The organization of outer membrane was slightly reduced in the mutant strain. The organization of outer membrane proteins in the mutant cells appeared not to be grossly altered, based on the apparent resistance (or susceptibility) of these proteins toward trypsin treatment and their resistance to solubilization by Sarkosyl. Like the wild-type lipoprotein, the mutant prolipoprotein in the outer membrane was resistant to trypsin. On the other hand, the prolipoprotein in the cytoplasmic membrane fraction of the mutant cell envelope was susceptible to trypsin digestion. We conclude from these data that proteolytic cleavage of prolipoprotein is not essential for the translocation and proper assembly of lipoprotein into outer membrane.

An Escherichia coli mutant with an amino acid alteration within the signal sequence of outer membrane prolipoprotein

Lipoprotein has been purified from an Escherichia coli strain carrying a mutation in the structural gene for murein lipoprotein (mlpA). Amino acid analysis of the purified mutant lipoprotein indicates that the mutant lipoprotein corresponds to the uncleaved prolipoprotein with a single amino acid replacement of glycine with aspartic acid. Automated Edman degradation has established the precise location of this amino acid substitution to be at the 14th residue of the prolipoprotein. This alteration in the signal sequence of prolipoprotein results in a failure of the mutated prolipoprotein to be processed. Furthermore, the structural alteration in the mutant lipoprotein appears also to have affected its topological localization in the mutant cell. Whereas lipoprotein in the wild-type strain is exclusively located in the outer membrane of the cell envelope, the membrane-bound lipoprotein in this mutant is recovered in both the inner and outer membranes of the cell envelope. The data suggest, however, that proteolytic cleavage of prolipoprotein to form mature lipoprotein is not essential for the translocation and assembly of lipoprotein into the outer membrane.

Physiological characterization of an Escherichia coli mutant altered in the structure of murein lipoprotein

Studies using isogenic transductant strains mlpA+ and mlpA as well as reversion analysis suggested that the physiological consequences of a structural gene mutation in murein lipoprotein include (i) increased sensitivity toward chelating agents ethylenediaminetetraacetic acid and ethyleneglycol-bis (beta-aminoethyl ether)-N,N-tetraacetic acid, (ii) leakage of periplasmic enzyme ribonuclease, (iii) weakened association between the outer membrane and the rigid layer accentuated by Mg2+ starvation, resulting in the formation of outer membrane blebs, and (iv) decreased growth rate in media of low ionic strength or low osmolarity. It is suggested that the bound form of lipoprotein plays an important role in the maintenance of the structural integrity of the outer membrane of the Escherichia coli cell envelope. Other outer membrane components may also contribute to the anchorage of outer membrane to the rigid layer, probably through ionic interactions with divalent cations. Using the phenotype of ribonuclease leakage as an unselected marker in a three-factor cross with P1 transduction, we were able to establish the gene order of man mlpA aroD pps on the E. coli chromosome.