Education & Certifications

  • Bachelor of Arts, Princeton University, Molecular Biology (2010)

Research & Scholarship

Lab Affiliations


All Publications

  • The putative Poc complex controls two distinct Pseudomonas aeruginosa polar motility mechanisms MOLECULAR MICROBIOLOGY Cowles, K. N., Moser, T. S., Siryaporn, A., Nyakudarika, N., Dixon, W., Turner, J. J., Gitai, Z. 2013; 90 (5): 923-938


    Each Pseudomonas aeruginosa cell localizes two types of motility structures, a single flagellum and one or two clusters of type IV pili, to the cell poles. Previous studies suggested that these motility structures arrive at the pole through distinct mechanisms. Here we performed a swimming motility screen to identify polar flagellum localization factors and discovered three genes homologous to the TonB/ExbB/ExbD complex that have defects in both flagella-mediated swimming and pilus-mediated twitching motility. We found that deletion of tonB3, PA2983 or PA2982 led to non-polar localization of the flagellum and FlhF, which was thought to sit at the top of the flagellar localization hierarchy. Surprisingly, these mutants also exhibited pronounced changes in pilus formation or localization, indicating that these proteins may co-ordinate both the pilus and flagellum motility systems. Thus, we have renamed PA2983 and PA2982, pocA and pocB, respectively, for polar organelle co-ordinator to reflect this function. Our results suggest that TonB3, PocA and PocB may form a membrane-associated complex, which we term the Poc complex. These proteins do not exhibit polar localization themselves, but are required for increased expression of pilus genes upon surface association, indicating that they regulate motility structures through either localization or transcriptional mechanisms.

    View details for DOI 10.1111/mmi.12403

    View details for Web of Science ID 000327374300002

    View details for PubMedID 24102920

  • Cell Size Control in Yeast CURRENT BIOLOGY Turner, J. J., Ewald, J. C., Skotheim, J. M. 2012; 22 (9): R350-R359


    Cell size is an important adaptive trait that influences nearly all aspects of cellular physiology. Despite extensive characterization of the cell-cycle regulatory network, the molecular mechanisms coupling cell growth to division, and thereby controlling cell size, have remained elusive. Recent work in yeast has reinvigorated the size control field and suggested provocative mechanisms for the distinct functions of setting and sensing cell size. Further examination of size-sensing models based on spatial gradients and molecular titration, coupled with elucidation of the pathways responsible for nutrient-modulated target size, may reveal the fundamental principles of eukaryotic cell size control.

    View details for DOI 10.1016/j.cub.2012.02.041

    View details for Web of Science ID 000303967600019

    View details for PubMedID 22575477

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