Metabolism Shapes the Cell

Sperber, Anthony M; Herman, Jennifer K.

doi:10.1128/jb.00039-17

Cited by 48 publications

(31 citation statements)

References 121 publications

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“…Unlike eukaryotic cells which have distinct stages of cell cycle and growth, prokaryotes like E. coli coordinate cytoplasmic growth, DNA replication and cell division simultaneously to achieve balanced growth. It has been argued that it is cellular metabolism that efficiently coordinates these processes (Sperber and Herman, 2017). Several metabolic pathways, for example TCA cycle (Monahan et al, 2014), nitrogen metabolism (Beaufay et al, 2015), pyruvate metabolism (Monahan et al, 2014), glucose metabolism (Hill et al, 2013;Weart et al, 2007), etc., have been implicated to control cell shape and size.…”

Section: Discussionmentioning

confidence: 99%

“…However, mutations (or other loss of function such as inhibition by an antibiotic) in metabolic enzymes are also known to cause filamentation (Fonville et al, 2010;Sperber and Herman, 2017). A well-studied example is thymineless death (TLD) where cells acquire filamentous phenotype upon severe deprivation of essential metabolite thymine (Ahmad et al, 1998).…”

Section: Introductionmentioning

confidence: 99%

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Metabolic response to point mutations reveals principles of modulation of in vivo enzyme activity and phenotype

Bhattacharyya

Bershtein

Adkar

et al. 2019

Preprint

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Understanding genotype-phenotype relationship is a central problem in modern biology. Here we report that several destabilizing mutations in E. coli Dihydrofolate Reductase (DHFR) enzyme result in pronounced yet reversible filamentation of bacterial cells. We find that drop in DHFR activity in the mutants results in massive metabolic shifts leading to significant excess of dUMP and dCTP in the pyrimidine biosynthesis pathway. Both deoxyribonucleotides inhibit downstream essential enzyme Thymidylate Kinase (Tmk) which phosphorylates dTMP, eventually leading to almost complete loss of the DNA building block dTTP. Severe imbalance in deoxyribonucleotide levels ultimately leads to DNA damage, SOS response and filamentation. Supplementation of dTMP in the medium competitively alleviates Tmk inhibition and rescues filamentation, thereby illustrating a classic case of enzyme inhibition by structural mimic of its cognate ligand. Overall, this study highlights the complex interconnected nature of the metabolic network, and the fundamental role of folate metabolism in shaping the cell.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Metabolic response to point mutations reveals principles of modulation of in vivo enzyme activity and phenotype

Bhattacharyya

Bershtein

Adkar

et al. 2019

Preprint

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“…In its absence, cells grow larger than normal, resulting in division defects. The genetic connection between ActH and Noc, and the linkage between metabolism genes and lytH / actH , reinforce the importance for cell division of ensuring that cell wall synthesis is properly integrated with primary metabolic pathways inside the cell 29–31 .…”

Section: Discussionmentioning

confidence: 86%

The cell cycle in Staphylococcus aureus is regulated by an amidase that controls peptidoglycan synthesis

Schaefer

Santiago

et al. 2019

Preprint

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13Bacteria are protected by a polymer of peptidoglycan that serves as an exoskeleton. In 14 Staphylococcus aureus, the enzymes that assemble peptidoglycan move during the cell cycle from 15 the periphery, where they are active during growth, to the division site where they build the 16 partition between daughter cells. But how peptidoglycan synthesis is regulated throughout the cell 17 cycle is not understood. Here we identify a membrane protein complex that spatially regulates S. 18 aureus peptidoglycan synthesis. This complex consists of an amidase that removes peptide chains 19 from uncrosslinked peptidoglycan and a partner protein that controls its activity. Typical amidases 20 act after cell division to hydrolyze peptidoglycan between daughter cells so they can separate. 21 130 peptidoglycan that is not, or at least not extensively, crosslinked. 131Slowing peptidoglycan synthesis rescues lytH deletion defects 132 We next investigated how LytH could regulate cell division. The division defects resulting 133 from lytH deletion implied LytH is important for FtsZ assembly. We found using a functional 134 FtsZ-sGFP fusion 5 that FtsZ is frequently mislocalized in ∆lytH cells ( Fig. 4a and Supplementary 135 157 misplaced septa or peripheral puncta ( Fig. 5a and Supplementary Fig. 14). By measuring the ratio 158

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“…On the other hand, the velocity of FtsZ treadmilling is not correlated with the rate of PG synthesis determined by FDAA incorporation or the rate of septum closure of Eco cells (13, 52). These differences suggest that additional metabolic (e.g., PG precursor pools) and structural (e.g., PG width and outer membrane synthesis) constraints may influence the relative rates of FtsZ treadmilling, bPBP complex movement, and PG synthesis in different bacteria (53, 54).…”

Section: Discussionmentioning

confidence: 99%

Movement Dynamics of Divisome and Penicillin-Binding Proteins (PBPs) in Cells of Streptococcus pneumoniae

Perez

Cesbron

Shaw

et al. 2018

Preprint

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27Bacterial cell division and peptidoglycan (PG) synthesis are orchestrated by the 28 coordinated dynamic movement of essential protein complexes. Recent studies show 29 that bidirectional treadmilling of FtsZ filaments/bundles is tightly coupled to and limiting 30 for both septal PG synthesis and septum closure in some bacteria, but not in others. 31 Here we report the dynamics of FtsZ movement leading to septal and equatorial ring 32 formation in the ovoid-shaped pathogen, Streptococcus pneumoniae (Spn). 33 Conventional and single-molecule total internal reflection fluorescence microscopy 34 (TIRFm) showed that nascent rings of FtsZ and its anchoring and stabilizing proteins 35 FtsA and EzrA move out from mature septal rings coincident with MapZ rings early in 36 cell division. This mode of continuous nascent ring movement contrasts with a failsafe 37 streaming mechanism of FtsZ/FtsA/EzrA observed in a ΔmapZ mutant and another 38 Streptococcus species. This analysis also provides several parameters of FtsZ 39 treadmilling in nascent and mature rings, including treadmilling velocity in wild-type cells 40 and ftsZ(GTPase) mutants, lifetimes of FtsZ subunits in filaments and of entire FtsZ 41 filaments/bundles, and the processivity length of treadmilling of FtsZ filament/bundles. 42 In addition, we delineated the motion of the septal PBP2x transpeptidase and its FtsW 43 glycosyl transferase binding partner relative to FtsZ treadmilling in Spn cells. Five lines 44 of evidence support the conclusion that movement of the bPBP2x:FtsW complex in 45 septa depends on PG synthesis and not on FtsZ treadmilling. Together, these results 46 support a model in which FtsZ dynamics and associations organize and distribute septal 47 PG synthesis, but do not control its rate in Spn. 48 3 SIGNIFICANCE 49 This study answers two long-standing questions about FtsZ dynamics and its 50 relationship to septal PG synthesis in Spn for the first time. In previous models, FtsZ 51 concertedly moves from midcell septa to MapZ rings that have reached the equators of 52 daughter cells. Instead, the results presented here show that FtsZ, FtsA, and EzrA 53 filaments/bundles move continuously out from early septa as part of MapZ rings. In 54 addition, this study establishes that the movement of bPBP2x:FtsW complexes in septal 55 PG synthesis depends on and likely mirrors new PG synthesis and is not correlated with 56 the treadmilling of FtsZ filaments/bundles. These findings are consistent with a 57 mechanism where septal FtsZ rings organize directional movement of bPBP2x:FtsW 58 complexes dependent on PG substrate availability.59 60 Cell division in most bacteria is mediated by the tubulin homolog, FtsZ, which 61 polymerizes into dynamic filaments and bundles at the middle or toward the pole of 62 dividing cells (1, 2). Polymerization of FtsZ filaments/bundles initiates sequential binding 63 of a series of proteins that ultimately assemble into a controlled divisome machine for 64 septal peptidoglycan (PG) synthesis l...

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Metabolism Shapes the Cell

Cited by 48 publications

References 121 publications

Metabolic response to point mutations reveals principles of modulation of in vivo enzyme activity and phenotype

Metabolic response to point mutations reveals principles of modulation of in vivo enzyme activity and phenotype

The cell cycle in Staphylococcus aureus is regulated by an amidase that controls peptidoglycan synthesis

Movement Dynamics of Divisome and Penicillin-Binding Proteins (PBPs) in Cells of Streptococcus pneumoniae

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