Cell cycle progression in<i>Caulobacter</i>requires a nucleoid-associated protein with high AT sequence recognition

Ricci, Dante P.; Melfi, Michael D.; Lasker, Keren; Dill, David L.; McAdams, Harley H.; Shapiro, Lucy

doi:10.1073/pnas.1612579113

Cited by 38 publications

(50 citation statements)

References 95 publications

(83 reference statements)

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“…Collectively, our data suggest that GapR and, by extension, the conserved domain DUF2312 encode a NAP function critical for cellular replication. While this manuscript was under revision, the Shapiro group published an article describing the identification of the same nucleoid‐associated protein in C. crescentus (Ricci et al , ). The only overlap with our study is the DNA‐binding preference of the protein to AT‐rich DNA sequences and its essential function in cell cycle progression under standard laboratory conditions (nutrient‐rich PYE medium, 30°C).…”

Section: Discussionmentioning

confidence: 99%

Replication fork passage drives asymmetric dynamics of a critical nucleoid‐associated protein in Caulobacter

et al. 2016

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In bacteria, chromosome dynamics and gene expression are modulated by nucleoid-associated proteins (NAPs), but little is known about how NAP activity is coupled to cell cycle progression. Using genomic techniques, quantitative cell imaging, and mathematical modeling, our study in Caulobacter crescentus identifies a novel NAP (GapR) whose activity over the cell cycle is shaped by DNA replication. GapR activity is critical for cellular function, as loss of GapR causes severe, pleiotropic defects in growth, cell division, DNA replication, and chromosome segregation. GapR also affects global gene expression with a chromosomal bias from origin to terminus, which is associated with a similar general bias in GapR binding activity along the chromosome. Strikingly, this asymmetric localization cannot be explained by the distribution of GapR binding sites on the chromosome. Instead, we present a mechanistic model in which the spatiotemporal dynamics of GapR are primarily driven by the progression of the replication forks. This model represents a simple mechanism of cell cycle regulation, in which DNA-binding activity is intimately linked to the action of DNA replication.

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Section: Discussionmentioning

confidence: 99%

Replication fork passage drives asymmetric dynamics of a critical nucleoid‐associated protein in Caulobacter

et al. 2016

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“…Most of these CSPs were of unknown function at the time they were first characterized, although further studies have shown them to be highly reliable molecular markers for these groups, and biochemical studies on them are leading to discovery of novel and important functions that were hitherto unrecognized [16][17][18][19][20]. Thus, not knowing the function of a conserved protein that is uniquely shared by a given group of species should not be a cause for criticism.…”

Section: Genomic Evidence For the Cohesiveness Of The Family Borreliamentioning

confidence: 99%

Division of the genus Borrelia into two genera (corresponding to Lyme disease and relapsing fever groups) reflects their genetic and phenotypic distinctiveness and will lead to a better understanding of these two groups of microbes (Margos et al. (2016) There is inadequate evidence to support the division of the genus Borrelia. Int. J. Syst. Evol. Microbiol. doi: 10.1099/ijsem.0.001717)

Barbour

Adeolu

Gupta

2017

International Journal of Systematic and Evolutionary Microbiology

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“…S6). It has been shown that many nucleoid-associated proteins from C. crescentus, such as HU or GapR, are enriched in AT-rich chromosomal regions (39)(40)(41). Furthermore, AT-rich sequences are typically found at transcriptional promoters, which are heavily occupied by RNA polymerase or regulatory proteins.…”

Section: Mipz Binds Dna In a Sequence-independent Manner In Vivomentioning

confidence: 99%

Molecular architecture of the DNA‐binding sites of the P‐loop ATPases MipZ and ParA fromCaulobacter crescentus

Refes

Corrales-Guerrero

et al. 2019

Preprint

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Two related P-loop ATPases, ParA and MipZ, mediate the spatiotemporal regulation of chromosome segregation and cell division in Caulobacter crescentus. Both of these proteins share the ability to form dynamic concentration gradients that control the positioning of regulatory targets within the cell. Their proper localization relies on their nucleotide-dependent cycling between a monomeric and a dimeric state, driven by interaction with the chromosome partitioning protein ParB, and on the ability of the dimeric species to associate non-specifically with the nucleoid. In this study, we use a combination of genetic screening, biochemical analysis and hydrogen/deuterium exchange mass spectrometry to identify the residues mediating the interaction of MipZ with DNA. Our results show that the DNA-binding activity of MipZ relies on a series of positively charged and hydrophobic residues lining both sides of the dimer interface. MipZ thus appears to associate with DNA in a sequence-independent manner through electrostatic interactions with the DNA phosphate backbone. In support of this hypothesis, chromatin immunoprecipitation analyses did not reveal any specific target sites in vivo. When extending our analysis to ParA, we found that the architectures of the MipZ and ParA DNA-binding sites are markedly different, although their relative positions on the dimer surface and their mode of DNA binding are conserved. Importantly, bioinformatic analysis suggests that the same principles apply to other members of the P-loop ATPase family. ParA-like ATPases thus share common mechanistic features, although their modes of action have diverged considerably during the course of evolution. SIGNIFICANCEParA-like P-loop ATPases are involved in a variety of cellular processes in bacteria, including chromosome and plasmid segregation, chemoreceptor and carboxysome positioning, and division site placement. Many members of this large protein family depend on the ability to bind non-specific DNA for proper function.Although previous studies have yielded insights in the DNA-binding properties of some ParA-like ATPases, a comprehensive view of the underlying mechanisms is still lacking. Here, we combine state-of-the-art cell biological, biochemical and biophysical approaches to localize the DNA-binding regions of the ParA-like ATPases MipZ and ParA from Caulobacter crescentus. We show that the two proteins use the same interface and mode of action to associate with DNA, suggesting that the mechanistic basis of DNA binding may be conserved in the ParA-like ATPase family.

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Cell cycle progression inCaulobacterrequires a nucleoid-associated protein with high AT sequence recognition

Cited by 38 publications

References 95 publications

Replication fork passage drives asymmetric dynamics of a critical nucleoid‐associated protein in Caulobacter

Replication fork passage drives asymmetric dynamics of a critical nucleoid‐associated protein in Caulobacter

Molecular architecture of the DNA‐binding sites of the P‐loop ATPases MipZ and ParA fromCaulobacter crescentus

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