Lizocimo sukeliami bakterijų apvalkalėlio pažeidimai ir Lactococcus lactis ląstelių atsakas į juos / Response of lactococcus lactis to cell envelope damage caused by lysozyme

Solopova, Ana

25 June 2014

Šiame darbe tirtas gramteigiamųjų ir gramneigiamųjų bakterijų atsakas į natyvaus ir katalitiškai neaktyvaus lizocimo bei jo 9 aminorūgščių katijoninio peptido sukeltus ląstelės apvalkalo pažeidimus. Panaudojant potenciometrinius metodus, buvo nustatyta, kad šie junginiai sukelia viduląstelinio K+ ištekėjimą iš L. lactis, B. subtilis ir P. aeruginosa ląstelių ir dalinę jų citoplazminės membranos depoliarizaciją, tačiau natyvus, kaitintas lizocimas ir 9a peptidas skirtingai veikia L. lactis apvalkalėlio laidumą. Peptidas bei kaitintas lizocimas sukelia staigesnį K+ jonų ištekėjimą ir membranos įtampos sumažėjimą nei natyvus lizocimas. Peptido sukeliamas K+ jonų ištekėjimas yra grįžtamas. Taip pat buvo įvertintas įvairių mutantinių L. lactis padermių jautrumas lizocimui. Pastebėta, kad kuo padermė atsparesnė lizocimui, tuo vėliau prasideda K+ jonų ištekėjimas iš šios padermės ląstelių. Pasitelkus DNR mikrogardelių metodą, buvo tiriamas lizocimo bei peptido poveikis L. lactis MG1363 bei ΔoppA ląstelių genų raiškos pokyčiams. Nustatyta, jog peptidu ir lizocimu veiktose ląstelėse iššaukiama dvikomponentės valdymo sistemos CesSR raiška ir sukeliamas nuo SpxB priklausomas ląstelių atsparumas lizocimui. Gauti rezultatai rodo, jog lizocimas ir 9a peptidas sukelia kiek skirtingus L. lactis transkriptomo pokyčius: lizocimas savitai skatina nuo N-deacetilazės priklausomo atsparumo mechanizmo įsijungimą, taip pat skiriasi OpuA sistemą koduojančių genų raiška. / We used potenciometric measurments to investigate the response of Gram-positive and Gram-negative bacteria to cell envelope stress, caused by native and heat-inactivated lysozyme and lysozyme-derived 9 amino acid peptide. It was found that these antimicrobial compounds induce leakage of K+ outside the cells of L. lactis, B. subtilis and P. aeruginosa and cause partial depolarization of bacterial cytoplasmic membrane. We observed different response of L. lactis cells to these compounds – peptide and heat-inactivated lysozyme cause more rapid efflux of K+ ions than native lysozyme. Peptide has a reversible effect on K+ leakage. Sensitivity of different mutant strains of L. lactis to lysozyme was studied. It was shown that more resistant the strain is, the later the leakage of K+ ions is induced by lysozyme. To investigate the genome-wide response of L. lactis MG1363 and ΔoppA strains to lysozyme and 9 a.a. peptide, changes of gene expression after challenging cells with these antimicrobial compounds were analysed using DNA microarrays. It was estimated, that lysozyme and lysozyme-derived 9a.a. peptide induce CesSR system and SpxB-mediated response. It was also shown that L. lactis response to 9a.a. peptide and lysozyme differs. Lysozyme specifically induces PgdA-mediated resistance mechanism. Changes of expression of OpuA system in lysozyme and peptide treated cells are also different.

Lactococcus

Lizocimas

Lysozyme

Cell envelope stress

Intramembrane signal transduction and cell envelope stress response in <i>Bacillus subtilis</i> / Intramembrane Signaltransduktion und Zellhüllstress-Antwort in <i>Bacillus subtilis</i>

Jordan, Sina

01 November 2007

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Zellhüllstress

Bacillus subtilis

Zweikomponenten-System

Regulation

cell envelope stress

Bacillus subtilis

two-component system

regulation

42.3

Phyletic Distribution and Diversification of the Phage Shock Protein Stress Response System in Bacteria and Archaea

Popp, Philipp F, Gumerov, Vadim M., Andrianova, Ekaterina P., Bewersdorf, Lisa, Mascher, Thorsten, Zhulin, Igor B., Wolf, Diana

19 March 2024

Maintaining cell envelope integrity is of vital importance for all microorganisms. Not surprisingly, evolution has shaped conserved protein protection networks that connect stress perception, transmembrane signal transduction, and mediation of cellular responses upon cell envelope stress. The phage shock protein (Psp) stress response is one such conserved protection network. Most knowledge about the Psp response derives from studies in the Gram-negative model bacterium Escherichia coli, where the Psp system consists of several well-defined protein components. Homologous systems were identified in representatives of the Proteobacteria, Actinobacteria, and Firmicutes. However, the Psp system distribution in the microbial world remains largely unknown. By carrying out a large-scale, unbiased comparative genomics analysis, we found components of the Psp system in many bacterial and archaeal phyla and describe that the predicted Psp systems deviate dramatically from the known prototypes. The core proteins PspA and PspC have been integrated into various (often phylum-specifically) conserved protein networks during evolution. Based on protein domain-based and gene neighborhood analyses of pspA and pspC homologs, we built a natural classification system for Psp networks in bacteria and archaea. We validate our approach by performing a comprehensive in vivo protein interaction study of Psp domains identified in the Gram-positive model organism Bacillus subtilis and found a strong interconnected protein network. Our study highlights the diversity of Psp domain organizations and potentially diverse functions across the plethora of the microbial landscape, thus laying the ground for studies beyond known Psp functions in underrepresented organisms.

info:eu-repo/classification/ddc/570

ddc:570

Synthesis and mechanism-of-action of a novel synthetic antibiotic based on a dendritic system with bow-tie topology

Revilla-Guarinos, Ainhoa, Popp, Philipp F., Dürr, Franziska, Lozano-Cruz, Tania, Hartig, Johanna, de la Mata, Francisco Javier, Gómez, Rafael, Mascher, Thorsten

21 May 2024

Over the course of the last decades, the continuous exposure of bacteria to antibiotics—at least in parts due to misprescription, misuse, and misdosing—has led to the widespread development of antimicrobial resistances. This development poses a threat to the available medication in losing their effectiveness in treating bacterial infections. On the drug development side, only minor advances have been made to bring forward novel therapeutics. In addition to increasing the efforts and approaches of tapping the natural sources of new antibiotics, synthetic approaches to developing novel antimicrobials are being pursued. In this study, BDTL049 was rationally designed using knowledge based on the properties of natural antibiotics. BDTL049 is a carbosilane dendritic system with bow-tie type topology, which has antimicrobial activity at concentrations comparable to clinically established natural antibiotics. In this report, we describe its mechanism of action on the Gram-positive model organism Bacillus subtilis. Exposure to BDTL049 resulted in a complex transcriptional response, which pointed toward disturbance of the cell envelope homeostasis accompanied by disruption of other central cellular processes of bacterial metabolism as the primary targets of BDTL049 treatment. By applying a combination of whole-cell biosensors, molecular staining, and voltage sensitive dyes, we demonstrate that the mode of action of BDTL049 comprises membrane depolarization concomitant with pore formation. As a result, this new molecule kills Gram-positive bacteria within minutes. Since BDTL049 attacks bacterial cells at different targets simultaneously, this might decrease the chances for the development of bacterial resistances, thereby making it a promising candidate for a future antimicrobial agent.

info:eu-repo/classification/ddc/570

ddc:570