In Vivo Cross-Linking Sheds Light on the Salmonella Divisome in Which PBP3 and PBP3SAL Compete for Occupancy.

IF 2.6 2区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Molecular Microbiology Pub Date : 2024-11-01 Epub Date: 2024-09-04 DOI:10.1111/mmi.15309
Sónia Castanheira, David López-Escarpa, Alberto Paradela, Francisco García-Del Portillo
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引用次数: 0

Abstract

Bacterial cell division is orchestrated by proteins that assemble in dynamic complexes collectively known as the divisome. Essential monofunctional enzymes with glycosyltransferase or transpeptidase (TPase) activities, FtsW and FtsI respectively, engage in the synthesis of septal peptidoglycan (sPG). Enigmatically, Salmonella has two TPases that can promote cell division independently: FtsI (PBP3) and the pathogen-specific paralogue PBP3SAL. How Salmonella regulates the assembly of the sPG synthase complex with these two TPases, is unknown. Here, we characterized Salmonella division complexes in wild-type cells and isogenic mutants lacking PBP3 or PBP3SAL. The complexes were cross-linked in vivo and pulled down with antibodies recognizing each enzyme. Proteomics of the immunoprecipitates showed that PBP3 and PBP3SAL do not extensively cross-link in wild type cells, supporting the presence of independent complexes. More than 40 proteins cross-link in complexes in which these two TPases are present. Those identified with high scores include FtsA, FtsK, FtsQLB, FtsW, PBP1B, SPOR domain-containing proteins (FtsN, DedD, RlpA, DamX), amidase activators (FtsX, EnvC, NlpD) and Tol-Pal proteins. Other cross-linked proteins are the protease Prc, the elongasome TPase PBP2 and, D,D-endo- and D,D-carboxypeptidases. PBP3 and PBP3SAL localize at midcell and compete for occupying the division complex in response to environmental cues. Thus, a catalytic-dead PBP3SAL-S300A variant impairs cell division in a high osmolarity and acidic condition in which it is produced at levels exceeding those of PBP3. Salmonella may therefore exploit an 'adjustable' divisome to exchange TPases for ensuring cell division in distinct environments and, in this manner, expand its colonization capacities.

Abstract Image

体内交联揭示了沙门氏菌分裂体中 PBP3 和 PBP3SAL 竞相占据的情况。
细菌细胞分裂是由蛋白质协调的,这些蛋白质组装成动态复合物,统称为分裂体。具有糖基转移酶或转肽酶(TPase)活性的基本单功能酶(分别为 FtsW 和 FtsI)参与合成隔膜肽聚糖(sPG)。令人费解的是,沙门氏菌有两种能够独立促进细胞分裂的 TP 酶:FtsI(PBP3)和病原体特异性旁系 PBP3SAL。沙门氏菌如何调节与这两种 TP 酶组装的 sPG 合成酶复合物尚不清楚。在这里,我们对野生型细胞和缺乏 PBP3 或 PBP3SAL 的同源突变体中的沙门氏菌分裂复合物进行了鉴定。复合物在体内交联,并用识别每种酶的抗体将其拉下。免疫沉淀物的蛋白质组学研究表明,PBP3 和 PBP3SAL 在野生型细胞中并不广泛交联,这支持了独立复合物的存在。在存在这两种 TP 酶的复合物中,有 40 多种蛋白质发生交联。其中得分较高的包括 FtsA、FtsK、FtsQLB、FtsW、PBP1B、含 SPOR 结构域的蛋白(FtsN、DedD、RlpA、DamX)、酰胺酶激活剂(FtsX、EnvC、NlpD)和 Tol-Pal 蛋白。其他交联蛋白包括蛋白酶 Prc、伸长体 TP 酶 PBP2 以及 D,D-内切酶和 D,D-羧肽酶。PBP3 和 PBP3SAL 定位于细胞中部,并根据环境线索竞争占据分裂复合体。因此,催化死亡的 PBP3SAL-S300A 变体在高渗透压和酸性条件下会损害细胞分裂,而在这种条件下,它的产生水平超过了 PBP3。因此,沙门氏菌可能会利用 "可调节的 "分裂体来交换 TP 酶,以确保细胞在不同环境中的分裂,从而扩大其定植能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Molecular Microbiology
Molecular Microbiology 生物-生化与分子生物学
CiteScore
7.20
自引率
5.60%
发文量
132
审稿时长
1.7 months
期刊介绍: Molecular Microbiology, the leading primary journal in the microbial sciences, publishes molecular studies of Bacteria, Archaea, eukaryotic microorganisms, and their viruses. Research papers should lead to a deeper understanding of the molecular principles underlying basic physiological processes or mechanisms. Appropriate topics include gene expression and regulation, pathogenicity and virulence, physiology and metabolism, synthesis of macromolecules (proteins, nucleic acids, lipids, polysaccharides, etc), cell biology and subcellular organization, membrane biogenesis and function, traffic and transport, cell-cell communication and signalling pathways, evolution and gene transfer. Articles focused on host responses (cellular or immunological) to pathogens or on microbial ecology should be directed to our sister journals Cellular Microbiology and Environmental Microbiology, respectively.
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