The mechanism by which bacteria divide is not well understood. Cell division is mediated by filaments of FtsZ and FtsA (FtsAZ) that recruit septal peptidoglycan synthesizing enzymes to the division site. To understand how these components coordinate to divide cells, we visualized their movements relative to the dynamics of cell wall synthesis during cytokinesis. We found that the division septum was built at discrete sites that moved around the division plane. FtsAZ filaments treadmilled circumferentially around the division ring, driving the motions of the peptidoglycan synthesizing enzymes. The FtsZ treadmilling rate controlled both the rate of peptidoglycan synthesis and cell division. Thus, FtsZ treadmilling guides the progressive insertion of new cell wall, building increasingly smaller concentric rings of peptidoglycan to divide the cell.
One-sentence summary:Bacterial cytokinesis is controlled by circumferential treadmilling of FtsAZ filaments that drives the insertion of new cell wall.
Abstract:How bacteria produce a septum to divide in two is not well understood. This process is mediated by periplasmic cell-wall producing enzymes that are positioned by filaments of the cytoplasmic membrane-associated actin FtsA and the tubulin FtsZ (FtsAZ). To understand how these components act in concert to divide cells, we visualized their movements relative to the dynamics of cell wall synthesis during cytokinesis. We find that the division septum is built at discrete sites that move around the division plane. Furthermore, FtsAZ filaments treadmill in circumferential paths around the division ring, pulling along the associated cell-wall-synthesizing enzymes. We show that the rate of FtsZ treadmilling controls both the rate of cell wall synthesis and cell division. The coupling of both the position and activity of the cell wall synthases to FtsAZ treadmilling guides the progressive insertion of new cell wall, synthesizing increasingly small concentric rings to divide the cell.
Main Text:Cells from all domains of life must divide in order to proliferate. In bacteria, cell division involves the inward synthesis of the cell wall peptidoglycan (PG), creating a septum that cleaves the cell in two. Septation is directed by proteins that are highly conserved among bacteria. The location and activity of the septal PG synthesis enzymes are regulated by FtsZ, a tubulin homolog, which associates with the cytoplasmic side of the membrane via an actin-like protein FtsA. FtsZ can form filaments (1) and membrane-associated copolymers with FtsA (FtsAZ) (2). Together, the two proteins form a dynamic
The peptidoglycan (PG) cell wall is a peptide cross-linked glycan polymer essential for bacterial division and maintenance of cell shape and hydrostatic pressure. Bacteria in the Chlamydiales were long thought to lack PG until recent advances in PG labeling technologies revealed the presence of this critical cell wall component in Chlamydia trachomatis. In this study, we utilize bio-orthogonal D-amino acid dipeptide probes combined with super-resolution microscopy to demonstrate that four pathogenic Chlamydiae species each possess a ≤ 140 nm wide PG ring limited to the division plane during the replicative phase of their developmental cycles. Assembly of this PG ring is rapid, processive, and linked to the bacterial actin-like protein, MreB. Both MreB polymerization and PG biosynthesis occur only in the intracellular form of pathogenic Chlamydia and are required for cell enlargement, division, and transition between the microbe’s developmental forms. Our kinetic, molecular, and biochemical analyses suggest that the development of this limited, transient, PG ring structure is the result of pathoadaptation by Chlamydia to an intracellular niche within its vertebrate host.
Peptidoglycan (PG) is an essential cell wall component that maintains the morphology and viability of nearly all bacteria. Its biosynthesis requires periplasmic transpeptidation reactions which construct peptide cross-linkages between polysaccharide chains to endow mechanical strength. However, tracking transpeptidation reaction
in vivo
and
in vitro
is challenging, mainly due to the lack of efficient, biocompatible probes. Here, we report the design, synthesis, and application of rotor-fluorogenic D-amino acids (RfDAAs) enabling real-time, continuous tracking of transpeptidation reactions. These probes enable monitoring PG biosynthesis in real time through visualizing transpeptidase reactions in live cells, as well as real-time activity assays of D,D-, L,D-transpeptidases, and sortases
in vitro
. The unique ability of RfDAAs to become fluorescent when incorporated into PG provides a powerful new tool to study PG biosynthesis with high temporal resolution and prospectively enable high-throughput screening for inhibitors of PG biosynthesis.
Peptidoglycan is an essential component of the cell wall that protects bacteria from environmental stress. A carefully coordinated biosynthesis of peptidoglycan during cell elongation and division is required for cell viability. This biosynthesis involves sophisticated enzyme machineries that dynamically synthesize, remodel, and degrade peptidoglycan. However, when and where bacteria build peptidoglycan, and how this is coordinated with cell growth, have been long-standing questions in the field. The improvement of microscopy techniques has provided powerful approaches to study peptidoglycan biosynthesis with high spatiotemporal resolution. Recent development of molecular probes further accelerated the growth of the field, which has advanced our knowledge of peptidoglycan biosynthesis dynamics and mechanisms. Here, we review the technologies for imaging the bacterial cell wall and its biosynthesis activity. We focus on the applications of fluorescent d-amino acids, a newly developed type of probe, to visualize and study peptidoglycan synthesis and dynamics, and we provide direction for prospective research.
Highlights d During zinc starvation, A. baumannii expresses a putative peptidase named ZrlA d ZrlA is critical for bacterial cell envelope integrity and overcoming Zn limitation d Inactivation of zrlA increases antibiotic efficacy in vitro and during infection
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