Anne M. Campbell scite author profile

Mycobacteriophages are viruses that infect mycobacterial hosts such as Mycobacterium smegmatis and Mycobacterium tuberculosis. All mycobacteriophages characterized to date are dsDNA tailed phages, and have either siphoviral or myoviral morphotypes. However, their genetic diversity is considerable, and although sixty-two genomes have been sequenced and comparatively analyzed, these likely represent only a small portion of the diversity of the mycobacteriophage population at large. Here we report the isolation, sequencing and comparative genomic analysis of 18 new mycobacteriophages isolated from geographically distinct locations within the United States. Although no clear correlation between location and genome type can be discerned, these genomes expand our knowledge of mycobacteriophage diversity and enhance our understanding of the roles of mobile elements in viral evolution. Expansion of the number of mycobacteriophages grouped within Cluster A provides insights into the basis of immune specificity in these temperate phages, and we also describe a novel example of apparent immunity theft. The isolation and genomic analysis of bacteriophages by freshman college students provides an example of an authentic research experience for novice scientists.

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Structure of the Helicobacter pylori Cag type IV secretion system

Chung

Sheedlo

Campbell

et al. 2019

166

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Bacterial type IV secretion systems (T4SSs) are molecular machines that can mediate interbacterial DNA transfer through conjugation and delivery of effector molecules into host cells. The Helicobacter pylori Cag T4SS translocates CagA, a bacterial oncoprotein, into gastric cells, contributing to gastric cancer pathogenesis. We report the structure of a membrane-spanning Cag T4SS assembly, which we describe as three sub-assemblies: a 14-fold symmetric outer membrane core complex (OMCC), 17-fold symmetric periplasmic ring complex (PRC), and central stalk. Features that differ markedly from those of prototypical T4SSs include an expanded OMCC and unexpected symmetry mismatch between the OMCC and PRC. This structure is one of the largest bacterial secretion system assemblies ever reported and illustrates the remarkable structural diversity that exists among bacterial T4SSs.

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Structure of the Helicobacter pylori Cag Type IV Secretion System

Chung

Sheedlo

Campbell

et al. 2020

Biophysical Journal

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A Nonoligomerizing Mutant Form of Helicobacter pylori VacA Allows Structural Analysis of the p33 Domain

et al. 2016

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Helicobacter pylori secretes a pore-forming VacA toxin that has structural features and activities substantially different from those of other known bacterial toxins. VacA can assemble into multiple types of water-soluble flower-shaped oligomeric structures, and most VacA activities are dependent on its capacity to oligomerize. The 88-kDa secreted VacA protein can undergo limited proteolysis to yield two domains, designated p33 and p55. The p33 domain is required for membrane channel formation and intracellular toxic activities, and the p55 domain has an important role in mediating VacA binding to cells. Previous studies showed that the p55 domain has a predominantly ␤-helical structure, but no structural data are available for the p33 domain. We report here the purification and analysis of a nonoligomerizing mutant form of VacA secreted by H. pylori. The nonoligomerizing 88-kDa mutant protein retains the capacity to enter host cells but lacks detectable toxic activity. Analysis of crystals formed by the monomeric protein reveals that the ␤-helical structure of the p55 domain extends into the C-terminal portion of p33. Fitting the p88 structural model into an electron microscopy map of hexamers formed by wild-type VacA (predicted to be structurally similar to VacA membrane channels) reveals that p55 and the ␤-helical segment of p33 localize to peripheral arms but do not occupy the central region of the hexamers. We propose that the amino-terminal portion of p33 is unstructured when VacA is in a monomeric form and that it undergoes a conformational change during oligomer assembly. Helicobacter pylori is a Gram-negative bacterium that persistently colonizes the stomach in about half of the human population worldwide (1-3). Most people tolerate the presence of this organism for long periods without any adverse consequences, but a small subset of H. pylori-infected individuals develop gastric adenocarcinoma or peptic ulcer disease.H. pylori is a relatively noninvasive organism that lives in the gastric mucus layer overlying gastric epithelial cells, sometimes adhering to the gastric epithelium. Many H. pylori-induced alterations in the gastric mucosa are attributable to the actions of secreted bacterial proteins on host cells (4-6). One such protein is the secreted vacuolating toxin, VacA (4, 7-10). VacA causes multiple alterations in gastric epithelial cells, including swelling of endosomes (vacuolation) (11, 12), permeabilization of mitochondrial membranes, and activation of mitogen-activated protein kinases (4, 7-9). In addition to its effects on gastric epithelial cells, VacA can disrupt the functions of many types of immune cells (T cells, B cells, neutrophils, eosinophils, and monocytes) (4, 7-9, 13-16). The cellular activities of VacA are attributed mainly to its ability to form anion-selective channels in host cells (17-21). VacA lacks sequence similarity to any other known bacterial toxins.H. pylori strains isolated from unrelated individuals are genetically heterogeneous, and the risk of developing gastric...

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Determinants of Raft Partitioning of the Helicobacter pylori Pore-Forming Toxin VacA

et al. 2018

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, a Gram-negative bacterium, is a well-known risk factor for gastric cancer. vacuolating cytotoxin A (VacA) is a secreted pore-forming toxin that induces a wide range of cellular responses. Like many other bacterial toxins, VacA has been hypothesized to utilize lipid rafts to gain entry into host cells. Here, we used giant plasma membrane vesicles (GPMVs) as a model system to understand the preferential partitioning of VacA into lipid rafts. We show that a wild-type (WT) toxin predominantly associates with the raft phase. Acid activation of VacA enhances binding of the toxin to GPMVs but is not required for raft partitioning. VacA mutant proteins with alterations at the amino terminus (resulting in impaired membrane channel formation) and a nonoligomerizing VacA mutant protein retain the ability to preferentially associate with lipid rafts. Consistent with these results, the isolated VacA p55 domain was capable of binding to lipid rafts. We conclude that the affinity of VacA for rafts is independent of its capacity to oligomerize or form membrane channels.

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Anne M. Campbell

Expanding the Diversity of Mycobacteriophages: Insights into Genome Architecture and Evolution

Structure of the Helicobacter pylori Cag type IV secretion system

Structure of the Helicobacter pylori Cag Type IV Secretion System

A Nonoligomerizing Mutant Form of Helicobacter pylori VacA Allows Structural Analysis of the p33 Domain

Determinants of Raft Partitioning of the Helicobacter pylori Pore-Forming Toxin VacA

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