Your search keyword '"Zamakhaeva S"' showing total 6 results

1. Methylotrophic producers of bioplastics (Review)

Author

Zamakhaeva, S. A., Fedorov, D. N., and Trotsenko, Yu. A.

Published

2017

2. Structure and mechanism of biosynthesis of Streptococcus mutans cell wall polysaccharide.

Author

Rush JS, Zamakhaeva S, Murner NR, Deng P, Morris AJ, Kenner CW, Black I, Heiss C, Azadi P, Korotkov KV, Widmalm G, and Korotkova N

Subjects

Biofilms growth & development, Glycosyltransferases metabolism, Glycosyltransferases genetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Humans, Polysaccharides metabolism, Polysaccharides biosynthesis, Glycerophosphates metabolism, Glucose metabolism, Streptococcus mutans metabolism, Streptococcus mutans genetics, Cell Wall metabolism, Rhamnose metabolism, Rhamnose biosynthesis, Polysaccharides, Bacterial biosynthesis, Polysaccharides, Bacterial metabolism

Abstract

Streptococcus mutans, the causative agent of human dental caries, expresses a cell wall attached Serotype c-specific Carbohydrate (SCC) that is critical for cell viability. SCC consists of a polyrhamnose backbone of →3)α-Rha(1 → 2)α-Rha(1→ repeats with glucose (Glc) side-chains and glycerol phosphate (GroP) decorations. This study reveals that SCC has one predominant and two more minor Glc modifications. The predominant Glc modification, α-Glc, attached to position 2 of 3-rhamnose, is installed by SccN and SccM glycosyltransferases and is the site of the GroP addition. The minor Glc modifications are β-Glc linked to position 4 of 3-rhamnose installed by SccP and SccQ glycosyltransferases, and α-Glc attached to position 4 of 2-rhamnose installed by SccN working in tandem with an unknown enzyme. Both the major and the minor β-Glc modifications control bacterial morphology, but only the GroP and major Glc modifications are critical for biofilm formation., Competing Interests: Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published

2025

3. O -glycosylation of intrinsically disordered regions regulates homeostasis of membrane proteins in streptococci.

Author

Rahman MM, Zamakhaeva S, Rush JS, Chaton CT, Kenner CW, Hla YM, Tsui HT, Uversky VN, Winkler ME, Korotkov KV, and Korotkova N

Abstract

Proteins harboring intrinsically disordered regions (IDRs) lacking stable secondary or tertiary structures are abundant across the three domains of life. These regions have not been systematically studied in prokaryotes. Our genome-wide analysis identifies extracytoplasmic serine/threonine-rich IDRs in several biologically important membrane proteins in streptococci. We demonstrate that these IDRs are O -glycosylated with glucose by glycosyltransferases GtrB and PgtC2 in Streptococcus pyogenes and Streptococcus pneumoniae , and with N-acetylgalactosamine by a Pgf-dependent mechanism in Streptococcus mutans . Absence of glycosylation leads to a defect in biofilm formation under ethanol-stressed conditions in S. mutans . We link this phenotype to the C-terminal IDR of a post-translocation secretion chaperone PrsA. O -glycosylation of the IDR protects this region from proteolytic degradation. The IDR length attenuates the efficiency of glycosylation and, consequently, the expression level of PrsA. Taken together, our data reveal that O -glycosylation of IDRs functions as a dynamic switch of protein homeostasis in streptococci., Competing Interests: Competing interests The authors declare no competing interests.

Published

2024

4. Structure and mechanism of biosynthesis of Streptococcus mutans cell wall polysaccharide.

Author

Rush JS, Zamakhaeva S, Murner NR, Deng P, Morris AJ, Kenner CW, Black I, Heiss C, Azadi P, Korotkov KV, Widmalm G, and Korotkova N

Abstract

Streptococcus mutans, the causative agent of human dental caries, expresses a cell wall attached Serotype c- specific Carbohydrate (SCC) that is critical for cell viability. SCC consists of a repeating →3)α-Rha(1→2)α-Rha(1→ polyrhamnose backbone, with glucose (Glc) side-chains and glycerol phosphate (GroP) decorations. This study reveals that SCC has one major and two minor Glc modifications. The major Glc modification, α-Glc, attached to position 2 of 3-rhamnose, is installed by SccN and SccM glycosyltransferases and is the site of the GroP addition. The minor Glc modifications are β-Glc linked to position 4 of 3-rhamnose installed by SccP and SccQ glycosyltransferases, and α-Glc attached to position 4 of 2-rhamnose installed by SccN working in tandem with an unknown enzyme. Both the major and the minor β-Glc modifications control bacterial morphology, but only the GroP and major Glc modifications are critical for biofilm formation.

Published

2024

5. PplD is a de-N-acetylase of the cell wall linkage unit of streptococcal rhamnopolysaccharides.

Author

Rush JS, Parajuli P, Ruda A, Li J, Pohane AA, Zamakhaeva S, Rahman MM, Chang JC, Gogos A, Kenner CW, Lambeau G, Federle MJ, Korotkov KV, Widmalm G, and Korotkova N

Subjects

Acetylglucosamine metabolism, Bacterial Proteins metabolism, Crystallography, X-Ray, Glucosamine analogs & derivatives, Glucosephosphates, Histones, Humans, Nitrous Acid, Peptidoglycan chemistry, Peptidoglycan metabolism, Streptococcal Infections microbiology, Streptococcus mutans, Acetylesterase metabolism, Cell Wall metabolism, Polysaccharides, Bacterial metabolism, Streptococcus metabolism

Abstract

The cell wall of the human bacterial pathogen Group A Streptococcus (GAS) consists of peptidoglycan decorated with the Lancefield group A carbohydrate (GAC). GAC is a promising target for the development of GAS vaccines. In this study, employing chemical, compositional, and NMR methods, we show that GAC is attached to peptidoglycan via glucosamine 1-phosphate. This structural feature makes the GAC-peptidoglycan linkage highly sensitive to cleavage by nitrous acid and resistant to mild acid conditions. Using this characteristic of the GAS cell wall, we identify PplD as a protein required for deacetylation of linkage N-acetylglucosamine (GlcNAc). X-ray structural analysis indicates that PplD performs catalysis via a modified acid/base mechanism. Genetic surveys in silico together with functional analysis indicate that PplD homologs deacetylate the polysaccharide linkage in many streptococcal species. We further demonstrate that introduction of positive charges to the cell wall by GlcNAc deacetylation protects GAS against host cationic antimicrobial proteins., (© 2022. The Author(s).)

Published

2022

6. Modification of cell wall polysaccharide guides cell division in Streptococcus mutans.

Author

Zamakhaeva S, Chaton CT, Rush JS, Ajay Castro S, Kenner CW, Yarawsky AE, Herr AB, van Sorge NM, Dorfmueller HC, Frolenkov GI, Korotkov KV, and Korotkova N

Subjects

Cell Division, Cell Wall chemistry, Polysaccharides chemistry, Streptococcus mutans cytology, Cell Wall metabolism, Polysaccharides metabolism, Streptococcus mutans metabolism

Abstract

In ovoid-shaped, Gram-positive bacteria, MapZ guides FtsZ-ring positioning at cell equators. The cell wall of the ovococcus Streptococcus mutans contains peptidoglycan decorated with serotype c carbohydrates (SCCs). In the present study, we identify the major cell separation autolysin AtlA as an SCC-binding protein. AtlA binding to SCC is attenuated by the glycerol phosphate (GroP) modification. Using fluorescently labeled AtlA constructs, we mapped SCC distribution on the streptococcal surface, revealing enrichment of GroP-deficient immature SCCs at the cell poles and equators. The immature SCCs co-localize with MapZ at the equatorial rings throughout the cell cycle. In GroP-deficient mutants, AtlA is mislocalized, resulting in dysregulated cellular autolysis. These mutants display morphological abnormalities associated with MapZ mislocalization, leading to FtsZ-ring misplacement. Altogether, our data support a model in which maturation of a cell wall polysaccharide provides the molecular cues for the recruitment of cell division machinery, ensuring proper daughter cell separation and FtsZ-ring positioning., (© 2021. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2021