Characterization of monolaurin resistance in Enterococcus faecalis

There is increasing concern regarding the presence of vancomycin-resistant enterococci in domestically farmed animals, which may act as reservoirs and vehicles of transmission for drug-resistant enterococci to humans, resulting in serious infections. In order to assess the potential for the use of monolaurin as a food preservative, it is important to understand both its target and potential mechanisms of resistance. A Tn917 mutant library of Enterococcus faecalis AR01/DGVS was screened for resistance (MIC, >100 microg/ml) to monolaurin. Three mutants were identified as resistant to monolaurin and were designated DGRM2, DGRM5, and DGRM12. The gene interrupted in all three mutants was identified as traB, which encodes an E. faecalis pheromone shutdown protein and whose complementation in trans restored monolaurin sensitivity in all three mutants. DGRM2 was selected for further characterization. E. faecalis DGRM2 showed increased resistance to gentamicin and chloramphenicol (inhibitors of protein synthesis), while no difference in the MIC was observed with the cell wall-active antibiotics penicillin and vancomycin. E. faecalis AR01/DGVS and DGRM2 were shown to have similar rates (30% cell lysis after 4 h) of cell autolytic activity when activated by monolaurin. Differences in cell surface hydrophobicity were observed between the wild type and the mutant, with the cell surface of the parent strain being significantly more hydrophobic. Analysis of the cell wall structure of DGRM2 by transmission electron microscopy revealed an increase in the apparent cell wall thickness and contraction of its cytoplasm. Taken together, these results suggest that the increased resistance of DGRM2 was due to a change in cell surface hydrophobicity, consequently limiting the diffusion of monolaurin to a potential target in the cytoplasmic membrane and/or cytoplasm of E. faecalis.     

Isolation of 4-aminopyridine resistant mutants affecting alkali-insoluble glucan content of cell walls in Saccharomyces cerevisiae

Saccharomyces cerevisiae cells when grown on synthetic medium plates containing 10 mM of 4-aminopyridine (4-AP) undergo cell lysis. Using an ethylmethane sulfonate mutagenesis (EMS) screen, 4-AP resistant mutants (apr) were isolated which could grow on inhibitory concentration of 4-AP. Eighty mutants were obtained that were recessive, monogenic and formed two complementation groups. To identify genes, whose products might be interacting with the apr loci, extragenic suppressors were isolated, which reverted 4-AP resistance phenotype of apr mutants. The suppressors, when genetically characterized, were found to be recessive and represented two loci with overlapping functions. Representative alleles from apr mutants were analyzed for cell wall composition. They were found to have a higher amount of alkali-insoluble glucan signifying the role of alkali-insoluble glucan in cell wall maintenance.     

Focal accumulation of defences at sites of fungal pathogen attack

Plants resist attack by haustorium-forming biotrophic and hemi-biotrophic fungi through fortification of the cell wall to prevent penetration through the wall and the subsequent establishment of haustorial feeding structures by the fungus. While the existence of cell wall-based defences has been known for many years, only recently have the molecular components contributing to such defences been identified. Forward genetic screens identified Arabidopsis mutants impaired in penetration resistance to powdery mildew fungi that were normally halted at the cell wall. Several loci contributing to penetration resistance have been identified and a common feature is the striking focal accumulation of proteins associated with penetration resistance at sites of interaction with fungal appressoria and penetration pegs. The focal accumulation of defence-related proteins and the deposition of cell wall reinforcements at sites of attempted fungal penetration represent an example of cell polarization and raise many questions of relevance, not only to plant pathology but also to general cell biology.     

Genetic characterization of hydroxyurea-resistant mutants obtained from cell cultures of Nicotiana tabacum

Summary Genetic characterization of seven hydroxyurearesistant (HuR) mutants selected from cell cultures of Nicotiana tabacum var. Xanthi has shown that in each case resistance is inherited as a single, dominant, nuclear mutation. Four HuR mutants for which linkage analysis has been performed identify two unlinked loci.     

Isolation and characterization of Saccharomyces cerevisiae mutants resistant to Calcofluor white.

Calcofluor is a fluorochrome that exhibits antifungal activity and a high affinity for yeast cell wall chitin. We isolated Saccharomyces cerevisiae mutants resistant to Calcofluor. The resistance segregated in a Mendelian fashion and behaved as a recessive character in all the mutants analyzed. Five loci were defined by complementation analysis. The abnormally thick septa between mother and daughter cells caused by Calcofluor in wild-type cells were absent in the mutants. The Calcofluor-binding capacity, observed by fluorescence microscopy, in a S. cerevisiae wild-type cells during alpha-factor treatment was also absent in some mutants and reduced in others. Staining of cell walls with wheat germ agglutinin-fluorescein complex indicated that the chitin uniformly distributed over the whole cell wall in vegetative or in alpha-factor-treated cells was almost absent in three of the mutants and reduced in the two others. Cell wall analysis evidenced a five- to ninefold reduction in the amount of chitin in mutants compared with that in the wild-type strain. The total amounts of cell wall mannan and beta-glucan in wild-type and mutant strains were similar; however, the percentage of beta-glucan that remained insoluble after alkali extraction was considerably reduced in mutant cells. The susceptibilities of the mutants and the wild-type strains to a cell wall enzymic lytic complex were rather similar. The in vitro levels of chitin synthase 2 detected in all mutants were similar to that in the wild type. The significance of these results is discussed in connection with the mechanism of chitin synthesis and cell wall morphogenesis in S. cerevisiae.     

Molecular and physiological analysis of Arabidopsis mutants exhibiting altered sensitivities to aluminium

t Arabidopsis mutants with altered Al sensitivities have been isolated with the goal of identifying genes important for Al resistance and toxicity. By screening in a high-Al environment, seven Al-resistant mutants (alr) were isolated. The alr mutants were semi-dominant and constitute at least two unique loci in Arabidopsis. Nine Al-sensitive mutants (als) were also isolated. Complementation analysis revealed that of the nine als mutants, eight represent unique loci, indicating that Al sensitivity is genetically complex in Arabidopsis. The characterization of mutants with altered Al sensitivity will provide greater insights into the mechanisms of Al toxicity and resistance on a molecular and biochemical level.     

Identification of Salmonella typhimurium invasiveness loci.

Salmonella typhimurium is capable of entering into (invading) nonphagocytic host cells. To systematically identify the bacterial genes necessary for this process, 15,000 Tn10dCm random transposon mutants of S. typhimurium were individually screened for invasiveness, using the human colonic epithelial Caco-2 cell line. Four hundred and eighty-eight mutants had decreased levels of invasiveness; most were nonmotile. However, five mutants, representing four loci, were completely motile. Further characterization of these five mutants showed that they were also unable to enter the dog kidney epithelial cell line MDCK and the mouse macrophage line J774.A1. In contrast to the parental strain, they were unable to disrupt the transepithelial resistance of polarized epithelial monolayers, nor were they able to penetrate across these epithelial barriers. Three of the four classes of mutants remained virulent in mice. The results confirm several aspects of S. typhimurium invasiveness: (i) intact motility enhances invasiveness of cultured cells; (ii) S. typhimurium invasiveness is multifactorial, and at least six distinct genetic loci are involved; and (iii) invasion loci involved in uptake into epithelial cells are also needed for uptake into cultured phagocytic cells. The results also emphasize that decreased levels of invasiveness eliminate bacterial penetration of polarized epithelial barriers and invasiveness loci mutants are not necessarily avirulent.     

Impact of mitochondrial activity on the cell wall composition and on the resistance to tannic acid in Saccharomyces cerevisiae

In screening for resistance to tannic acid, mutants of Saccharomyces cerevisiae with an altered cell wall composition were recently isolated. Here we show that these mutants were all respiratory deficient. Cytoplasmic petite mutants isolated after ethidium bromide mutagenesis were resistant to tannic acid and had cell wall characteristics similar to the mutants isolated by screening for tannic acid resistance as shown by the lower sensitivity to zymolyase, a cell wall hydrolyzing enzyme, and by a changed sensitivity to calcofluor white, a molecule interfering with the cell wall assembly. Reintroducing active mitochondria to a tannic-acid-resistant mutant reduced the tannic acid resistance and zymolyase resistance to the wild-type level, showing that a mitochondrial mutation was responsible for the changes in cell wall composition and in tannic acid sensitivity.     

Staphylococcus aureus mutants with increased lysostaphin resistance

Staphylococcus simulans secretes lysostaphin, a bacteriolytic enzyme that specifically binds to the cell wall envelope of Staphylococcus aureus and cleaves the pentaglycine cross bridges of peptidoglycan, thereby killing staphylococci. The study of S. aureus mutants with resistance to lysostaphin-mediated killing has revealed biosynthetic pathways for cell wall assembly. To identify additional genes involved in cell wall envelope biosynthesis, we have screened a collection of S. aureus strain Newman transposon mutants for lysostaphin resistance. Bursa aurealis insertion in SAV2335, encoding a polytopic membrane protein with predicted protease domain, caused a high degree of lysostaphin resistance, similar to the case for a previously described femAB promoter mutant. In contrast to the case for this femAB mutant, transposon insertion in SAV2335, herein named lyrA (lysostaphin resistance A), did not cause gross alterations of cell wall cross bridges such as truncations of pentaglycine to tri- or monoglycine. Also, inactivation of LyrA in a methicillin-resistant S. aureus strain did not precipitate a decrease in beta-lactam resistance as observed for fem (factor essential for methicillin resistance) mutants. Lysostaphin bound to the cell wall envelopes of lyrA mutants in a manner similar to that for wild-type staphylococci. Lysostaphin resistance of lyrA mutants is attributable to altered cell wall envelope properties and may in part be due to increased abundance of altered cross bridges. Other lyr mutants with intermediate lysostaphin resistance carried bursa aurealis insertions in genes specifying GTP pyrophosphokinase or enzymes of the purine biosynthetic pathway.     

Biosynthesis and properties of the plant cell wall

The characterization of cell wall mutants of Arabidopsis thaliana, combined with biochemical approaches toward the purification and characterization of glycosyltransferases, has led to significant advances in understanding cell wall synthesis and the properties of cell walls. New insights have been gained into the formation of cellulose and the functions of the matrix polysaccharides rhamnogalacturonan-II and xyloglucan.     

Classification and identification of Arabidopsis cell wall mutants using Fourier-Transform InfraRed (FT-IR) microspectroscopy

We have developed a novel procedure for the rapid classification and identification of Arabidopsis mutants with altered cell wall architecture based on Fourier-Transform Infrared (FT-IR) microspectroscopy. FT-IR transmission spectra were sampled from native 4-day-old dark-grown hypocotyls of 46 mutants and the wild type treated with various drugs. The Mahalanobis distance between mutants, calculated from the spectral information after compression with the Discriminant Variables Selection procedure, was used for alpha hierarchical cluster analysis. Despite the completely unsupervised nature of the classification procedure, we show that all mutants with cellulose defects appeared in the same cluster. In addition, mutant alleles of similar strength for several unrelated loci were also clustered, which demonstrates the sensitivity of the method to detect a wide array of cell wall defects. Comparing the cellulose-deficient cluster with the cluster that contained wild-type controls led to the identification of wave numbers that were diagnostic for altered cellulose content in the context of an intact cell wall. The results show that FT-IR spectra can be used to identify different classes of mutants and to characterize cell wall changes at a microscopic level in unknown mutants. This procedure significantly accelerates the identification and classification of cell wall mutants, which makes cell wall polysaccharides more accessible to functional genomics approaches.     

Peptidoglycan composition in heterogeneous Tn551 mutants of a methicillin-resistant Staphylococcus aureus strain.

It was shown that Tn551 inactivation of two chromosomal (so-called auxiliary) loci other than the mec gene result in a dramatic reduction of methicillin resistance and decreased cell wall turnover and autolytic capacity in a methicillin-resistant Staphylococcus aureus strain (de Jonge, B. L. M., de Lencastre, H., and Tomasz, A. (1990) J. Bacteriol. 173, 1105-1110). To understand the mechanistic basis of these phenomena we have examined the status of the autolytic enzymes and the muropeptide composition of peptidoglycan using reversed-phase high-performance liquid chromatography and mass spectral analyses. While no differences could be detected in the number of autolytic hydrolases, the mutants showed major changes in peptidoglycan composition. Nine prominent muropeptides of the parental strain each carrying a pentaglycyl substituent were missing from the cell wall of one group of mutants. The second mutant lacked four parental muropeptides which were composed of the unsubstituted disaccharide pentapeptide and its alanyl-tetraglycine derivative. The auxiliary genes are genetic determinants involved with the biosynthesis of peptidoglycan precursors, the presence of which in the cell wall may be needed for optimal cell wall turnover.     

Morphological and physiological study of autolytic-defective Streptococcus faecium strains.

Three autolytic-defective mutants of Streptococcus faecium (S. faecalis ATCC 9790) were isolated. All three autolytic-defective mutants exhibited the following properties relative to the parental strain: (i) slower growth rates, especially in chemically defined medium; (ii) decreased rates of cellular autolysis and increased survival after exposure to antibiotics which block cell wall biosynthesis; (iii) decreased rates of cellular autolysis when treated with detergents, suspended in autolysis buffers, or grown in medium lacking essential cell wall precursors; (iv) a reduction in the total level of cellular autolytic enzyme (active plus latent forms of the enzyme); (v) an increased ratio of latent to active forms of autolysin; and (vi) increased levels of both cellular lipoteichoic acid and lipids.     

Biogenesis of mitochondria 27

Summary The isolation and characterization of five new mutants affecting mitochondrial protein synthesis in S. cerevisiae is reported. Each mutation confers in vivo resistance to the macrolide antibiotic spiramycin which acts by inhibiting mitochondrial protein synthesis in sensitive yeast. The mutants are distinguishable on the basis of their in vivo cross resistance to other antibiotics, their biochemical properties and genetic behaviour. Genetic analysis indicates the mode of inheritance to be nuclear for one mutation and cytoplasmic for the other four. Recombination analysis performed on crosses between different cytoplasmic determinants, together with data from monofactorial crosses of each determinant with sensitive strains, demonstrates at least two and possibly three cytoplasmic genetic loci conferring spiramycin resistance.The protein synthesizing activities of mitochondria isolated from the mutant strains range in response to spiramycin and other antibiotics from strong resistance through partial resistance to complete sensitivity. Based on this data the mutants showing strong antibiotic resistance in vitro might be simply classified as mitochondrial ribosome mutants and mutants sensitive in vitro as mitochondrial membrane mutants; however mutants showing partial resistances are not so readily accommodated in either class. The diverse biochemical properties cannot be correlated with the different genetic loci described; indeed three mutations, each resulting in different biochemical behaviour appear to occur at the same locus. The results are interpreted as providing further evidence for an earlier proposal of mitochondrial membrane-ribosome interactions.     

Enterococcal surface protein Esp does not facilitate intestinal colonization or translocation of Enterococcus faecalis in clindamycin-treated mice

Enterococcal surface protein (Esp) is a cell wall-associated protein of Enterococcus faecalis that has been identified as a potential virulence factor. We used a mouse model to examine whether Esp facilitates intestinal colonization or translocation of E. faecalis to mesenteric lymph nodes. After clindamycin treatment, similar levels of high-density colonization were established after orogastric inoculation of an E. faecalis isolate containing the esp gene within a large pathogenicity island and an isogenic mutant created by allelic replacement of the esp gene with a chloramphenicol resistance cassette (P=0.7); translocation to mesenteric lymph nodes was detected in 3 of 12 (25%) mice in both groups. Isogenic mutants of FA2-2 (a plasmid-free derivative of E. faecalis strain JH2) with or without the esp gene failed to establish colonization of clindamycin-treated mice. These results suggest that Esp does not facilitate intestinal colonization or translocation of E. faecalis.     

Disruption of the <Emphasis Type="Italic"> Saccharomyces cerevisiae </Emphasis>cell-wall pathway gene <Emphasis Type="Italic"> SLG1</Emphasis> causes hypersensitivity to the antitumor drug bleomycin

Bleomycin is an antitumor drug that damages DNA via a free radical-dependent mechanism, and yeast mutants defective in DNA repair are hypersensitive to the drug. To identify possible pathways that may contribute to bleomycin resistance in yeast, we characterized a panel of bleomycin-sensitive mutants that were previously isolated by insertion mutagenesis using the transposon miniTn3::Leu2::LacZ::AMP( R). One of these mutants harbored a single insertion in the SLG1 gene, which encodes a cell membrane protein that senses cell wall stress, and functions to maintain cell wall function by activating the protein kinase C signaling pathway. Deletion of the SLG1 gene in parental strains caused hypersensitivity to bleomycin, and this correlated with an accumulation of damaged DNA. A plasmid that expresses the native SLG1 gene or that increases PKC1 gene dosage restored bleomycin resistance to the slg1Delta mutant. Two-dimensional gel electrophoresis revealed that exposure to bleomycin triggered the expression of certain proteins, presumably to maintain cell wall function, in a Slg1-dependent manner. In addition, mutants lacking cell wall function were found to be hypersensitive to bleomycin. We conclude that mutants deficient in proteins that maintain cell wall function are severely compromised in their ability to limit bleomycin entry into the cell. Therefore, these mutants are burdened with increased genotoxicity upon exposure to bleomycin in the medium. Our results show that major mechanisms other than DNA repair are operating in yeast to mediate bleomycin resistance.     

Locus-specific Changes in Cell Wall Composition Characteristic of Osmotic Mutants of Neurospora crassa

The osmotic phenotype of Neurospora crassa is characterized by inhibition of growth at high osmolalities of growth medium. Mutations at six osmotic loci of linkage group I were examined to assess the biochemical and physiological effects of these mutants. Isolated cell walls from 23 osmotic strains were compared with the wild type with regard to quantitative levels of the following components: percentage of total dry weight, total glucose, alkali-soluble glucose, nonglucose carbohydrates, amino acids, glucosamine, galactosamine, and a compound tentatively identified as quinovosamine. The last component has not previously been observed in N. crassa cell walls. Although the cell wall dry weight content of osmotic mutants was not altered, walls isolated from all of the osmotic strains had less alkali-insoluble glucose than those from the wild type. In addition, all of the loci except cut exhibited other consistent differences from the wild type. The os-1, os-3, and os-5 mutants had low levels of alkali-soluble glucose. The os-3 and os-5 mutants had high levels of nonglucose carbohydrates, and flm-2 had a low level of nonglucose carbohydrates. The os-4 mutants had low levels of galactosamine and amino acids and high levels alkali-soluble glucose. An os-1 mutant, B135, produced less of the whole alkali-soluble fraction of the cell wall.     

Suppression of autolysis and cell wall turnover in heterogeneous Tn551 mutants of a methicillin-resistant Staphylococcus aureus strain.

Isogenic Tn551 mutants of a highly and uniformly methicillin-resistant strain of Staphylococcus aureus were tested for their rates of autolysis and cell wall degradation in buffer and for cell wall turnover during growth. The normal (relatively fast) autolysis and turnover rates of the parent strain were retained in a Tn551 mutant in which the insert was located within the mec gene and which produced undetectable levels of penicillin-binding protein 2A. On the other hand, autolysis and cell wall turnover rates were greatly reduced in auxiliary mutants, i.e., mutants in which the transposon caused conversion of the high-level and uniform resistance of the parent strain to a variety of distinct heterogeneous expression types and greatly decreased resistance levels. All of these mutants contained an intact mec gene and produced normal amounts of penicillin-binding protein 2A, and one of the mutations was located in the femA region of the staphylococcal chromosome (B. Berger-Bachi, L. Barberis-Maino, A. Strassle, and F. H. Kayser, Mol. Gen. Genet. 219:263-269, 1989). Autolysis rates were related to the degree of residual methicillin resistance and to the sites of Tn551 insertion. Fast cell wall turnover may help expression of high-level methicillin resistance by providing a mechanism for the excision of abnormal (and potentially lethal) structural elements of the cell wall synthesized by the bacteria in the presence of methicillin.     

Development of a host-genotype-independent counterselectable marker and a high-frequency conjugative delivery system and their use in genetic analysis of Enterococcus faecalis

Enterococcus faecalis is a gram-positive commensal bacterium of the gastrointestinal tract. E. faecalis is also an opportunistic pathogen that frequently exhibits resistance to available antibiotics. Despite the clinical significance of the enterococci, genetic analysis has been restricted by limitations inherent in the available genetic tools. To facilitate genetic manipulation of E. faecalis, we developed a conjugative delivery system for high-frequency introduction of cloned DNA into target strains of E. faecalis and a host-genotype-independent counterselectable marker for use in markerless genetic exchange. We used these tools to construct a collection of E. faecalis mutant strains carrying defined mutations in several genes, including ccfA, eep, gelE, sprE, and an alternative sigma factor (sigH). Furthermore, we combined these mutations in various permutations to create double mutants, triple mutants, and a quadruple mutant of E. faecalis that enabled tests of epistasis to be conducted on the pheromone biosynthesis pathway. Analysis of cCF10 pheromone production by the mutants revealed that both the ccfA2 and delta eep10 mutations are epistatic to mutations in gelE/sprE. To our knowledge, this represents the first example of epistasis analysis applied to a chromosomally encoded biosynthetic pathway in enterococci. Thus, the advanced tools for genetic manipulation of E. faecalis reported here enable efficient and sophisticated genetic analysis of these important pathogens.