Zakiya Whatley scite author profile

FtsZ, a bacterial tubulin homologue, is a cytoskeletal protein that assembles into protofilaments that are one subunit thick. These protofilaments assemble further to form a "Z ring" at the center of prokaryotic cells. The Z ring generates a constriction force on the inner membrane and also serves as a scaffold to recruit cell wall remodeling proteins for complete cell division in vivo. One model of the Z ring proposes that protofilaments associate via lateral bonds to form ribbons; however, lateral bonds are still only hypothetical. To explore potential lateral bonding sites, we probed the surface of Escherichia coli FtsZ by inserting either small peptides or whole fluorescent proteins (FPs). Among the four lateral surfaces on FtsZ protofilaments, we obtained inserts on the front and back surfaces that were functional for cell division. We concluded that these faces are not sites of essential interactions. Inserts at two sites, G124 and R174, located on the left and right surfaces, completely blocked function, and these sites were identified as possible sites for essential lateral interactions. However, the insert at R174 did not interfere with association of protofilaments into sheets and bundles in vitro. Another goal was to find a location within FtsZ that supported insertion of FP reporter proteins while allowing the FtsZ-FPs to function as the sole source of FtsZ. We discovered one internal site, G55-Q56, where several different FPs could be inserted without impairing function. These FtsZ-FPs may provide advances for imaging Z-ring structure by superresolution techniques.IMPORTANCE One model for the Z-ring structure proposes that protofilaments are assembled into ribbons by lateral bonds between FtsZ subunits. Our study excluded the involvement of the front and back faces of the protofilament in essential interactions in vivo but pointed to two potential lateral bond sites, on the right and left sides. We also identified an FtsZ loop where various fluorescent proteins could be inserted without blocking function; these FtsZ-FPs functioned as the sole source of FtsZ. This advance provides improved tools for all fluorescence imaging of the Z ring and may be especially important for superresolution imaging.KEYWORDS green fluorescent protein, mEos, mMaple, superresolution, tubulin, Venus F tsZ (filamentous temperature sensitive Z), a bacterial homologue of tubulin, assembles the cytoskeletal framework of the Z ring, which constricts to divide the cell. FtsZ forms protofilaments (pfs), which are considered the building blocks of the Z ring. The Z ring serves as a scaffold for recruitment of downstream cell division proteins, which are mostly involved in remodeling the peptidoglycan wall, generating the septum and eventually the new poles. FtsZ by itself can generate a constriction force when reconstituted in liposomes and is thought to provide a primary force to constrict

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Mutations that Separate the Functions of the Proofreading Subunit of the Escherichia coli Replicase

Whatley

2015

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The dnaQ gene of Escherichia coli encodes the ε subunit of DNA polymerase III, which provides the 3′ → 5′ exonuclease proofreading activity of the replicative polymerase. Prior studies have shown that loss of ε leads to high mutation frequency, partially constitutive SOS, and poor growth. In addition, a previous study from our laboratory identified dnaQ knockout mutants in a screen for mutants specifically defective in the SOS response after quinolone (nalidixic acid) treatment. To explain these results, we propose a model whereby, in addition to proofreading, ε plays a distinct role in replisome disassembly and/or processing of stalled replication forks. To explore this model, we generated a pentapeptide insertion mutant library of the dnaQ gene, along with site-directed mutants, and screened for separation of function mutants. We report the identification of separation of function mutants from this screen, showing that proofreading function can be uncoupled from SOS phenotypes (partially constitutive SOS and the nalidixic acid SOS defect). Surprisingly, the two SOS phenotypes also appear to be separable from each other. These findings support the hypothesis that ε has additional roles aside from proofreading. Identification of these mutants, especially those with normal proofreading but SOS phenotype(s), also facilitates the study of the role of ε in SOS processes without the confounding results of high mutator activity associated with dnaQ knockout mutants.

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The Prospects of Artificial Endosymbioses

Kerney¹,

Whatley²,

Rivera³

et al. 2017

Amer. Scientist

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The Epsilon Subunit of DNA Polymerase III in the Bacterial Response to Quinolones

Whatley

DiDomenico

et al. 2017

The FASEB Journal

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Quinolones are widely prescribed, broad‐spectrum antibacterial drugs. Despite their widespread use, the molecular mechanisms of quinolone cytotoxicity are not clearly understood. Quinolones target topoisomerases, preventing the resealing of otherwise transient DNA breaks. Poisoned topoisomerase, or stabilized cleavage complexes, are not sufficient for cell death. The goal of this study is to determine how stabilized cleavage complexes are converted into irreversible double strand DNA breaks (DSBs) that accumulate and drive quinolone cytotoxicity.Previous studies identified an unexpected connection between dnaQ and quinolone‐induced DNA damage in Escherichia coli. The ɛ subunit of DNA polymerase III, encoded by dnaQ, is an exonuclease providing the 3′ ‐> 5′ proofreading activity of the core. The absence of ɛ causes higher mutation rates, slow growth, constitutive SOS, and a defective SOS response following quinolone treatment. We found that these phenotypes are separable, which implies that ɛ has multiple, separable roles, aside from proofreading.We explore the role of ɛ‐β interaction in quinolone‐induced DSB generation. Using two different types of cell lysis in conjunction with pulsed‐field gel electrophoresis, we distinguished between latent breaks at the cleavage complex and overt chromosomal breaks due to additional processing. We provide evidence that supports the replication run‐off model of DSB generation, whereby a stronger ɛ‐β interaction causes the replicase to physically interact with stabilized cleavage complexes rather than stalling or disassembling.Support or Funding InformationGettysburg College Research & Professional Development Grant & Howard Hughes Medical Institute ‐ Cross‐Disciplinary Sciences Institute at Gettysburg College

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Zakiya Whatley

Probing for Binding Regions of the FtsZ Protein Surface through Site-Directed Insertions: Discovery of Fully Functional FtsZ-Fluorescent Proteins

Mutations that Separate the Functions of the Proofreading Subunit of the Escherichia coli Replicase

The Prospects of Artificial Endosymbioses

The Epsilon Subunit of DNA Polymerase III in the Bacterial Response to Quinolones

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