Found 130 results
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A
R. Adler, Clark, E., Cline, M., Conner, M., Crabbs, T., Fossey, S., Malarkey, D., Meseck, E., Vernau, W., Tornquist, S. J., McDorman, K., Rees, S., and Cockerell, G., Mission Accomplished: The ACVP/STP Coalition for Veterinary Pathology Fellows Completes Its Objectives, but Its Legacy and Spirit Live On., Vet Pathol, vol. 57, no. 4, pp. 472-475, 2020.
D. Alzhanov, Barnes, J., Hruby, D. E., and Rockey, D. D., Chlamydial development is blocked in host cells transfected with Chlamydophila caviae incA., BMC Microbiol, vol. 4, p. 24, 2004.
D. T. Alzhanov, Weeks, S. K., Burnett, J. R., and Rockey, D. D., Cytokinesis is blocked in mammalian cells transfected with Chlamydia trachomatis gene CT223., BMC Microbiol, vol. 9, p. 2, 2009.
D. T. Alzhanov, Suchland, R. J., Bakke, A. C., Stamm, W. E., and Rockey, D. D., Clonal isolation of chlamydia-infected cells using flow cytometry., J Microbiol Methods, vol. 68, no. 1, pp. 201-8, 2007.
B
L. Babrak, Danelishvili, L., Rose, S. J., and Bermudez, L. E., Microaggregate-associated protein involved in invasion of epithelial cells by Mycobacterium avium subsp. hominissuis., Virulence, vol. 6, no. 7, pp. 694-703, 2015.
L. Babrak, Danelishvili, L., Rose, S. J., Kornberg, T., and Bermudez, L. E., The environment of "Mycobacterium avium subsp. hominissuis" microaggregates induces synthesis of small proteins associated with efficient infection of respiratory epithelial cells., Infect Immun, vol. 83, no. 2, pp. 625-36, 2015.
J. P. Bannantine, Griffiths, R. S., Viratyosin, W., Brown, W. J., and Rockey, D. D., A secondary structure motif predictive of protein localization to the chlamydial inclusion membrane., Cell Microbiol, vol. 2, no. 1, pp. 35-47, 2000.
J. P. Bannantine, Stamm, W. E., Suchland, R. J., and Rockey, D. D., Chlamydia trachomatis IncA is localized to the inclusion membrane and is recognized by antisera from infected humans and primates., Infect Immun, vol. 66, no. 12, pp. 6017-21, 1998.
J. P. Bannantine and Rockey, D. D., Use of primate model system to identify Chlamydia trachomatis protein antigens recognized uniquely in the context of infection., Microbiology (Reading), vol. 145 ( Pt 8), pp. 2077-2085, 1999.
L. E. Bermudez, Danelishvili, L., Babrack, L., and Pham, T., Evidence for genes associated with the ability of Mycobacterium avium subsp. hominissuis to escape apoptotic macrophages., Front Cell Infect Microbiol, vol. 5, p. 63, 2015.
D. Bestle, Heindl, M. Ruth, Limburg, H., van, T. Van Lam, Pilgram, O., Moulton, H. M., Stein, D. A., Hardes, K., Eickmann, M., Dolnik, O., Rohde, C., Klenk, H. - D., Garten, W., Steinmetzer, T., and Böttcher-Friebertshäuser, E., TMPRSS2 and furin are both essential for proteolytic activation of SARS-CoV-2 in human airway cells., Life Sci Alliance, vol. 3, no. 9, 2020.
D. Bestle, Limburg, H., Kruhl, D., Harbig, A., Stein, D. A., Moulton, H. M., Matrosovich, M., Abdelwhab, E. M., Stech, J., and Böttcher-Friebertshäuser, E., Hemagglutinins of Avian Influenza Viruses Are Proteolytically Activated by TMPRSS2 in Human and Murine Airway Cells., J Virol, vol. 95, no. 20, p. e0090621, 2021.
D. Miranda Borducchi, Gerbase-DeLima, M., Morgun, A., Shulzhenko, N., Pombo-de-Oliveira, M. S., Kerbauy, J., and de Oliveira, J. Salvador R., Human leucocyte antigen and human T-cell lymphotropic virus type 1 associated diseases in Brazil., British journal of haematology, vol. 123, no. 5, pp. 954-5, 2003.
J. A. Brothwell, Muramatsu, M. K., Toh, E., Rockey, D. D., Putman, T. E., Barta, M. L., P Hefty, S., Suchland, R. J., and Nelson, D. E., Interrogating Genes That Mediate Chlamydia trachomatis Survival in Cell Culture Using Conditional Mutants and Recombination., J Bacteriol, vol. 198, no. 15, pp. 2131-9, 2016.
W. J. Brown, Skeiky, Y. A. W., Probst, P., and Rockey, D. D., Chlamydial antigens colocalize within IncA-laden fibers extending from the inclusion membrane into the host cytosol., Infect Immun, vol. 70, no. 10, pp. 5860-4, 2002.
W. J. Brown and Rockey, D. D., Identification of an antigen localized to an apparent septum within dividing chlamydiae., Infect Immun, vol. 68, no. 2, pp. 708-15, 2000.
C
G. Chen, Severo, M. S., Sakhon, O. S., Choy, A., Herron, M. J., Felsheim, R. F., Wiryawan, H., Liao, J., Johns, J. L., Munderloh, U. G., Sutterwala, F. S., Kotsyfakis, M., and Pedra, J. H. F., Anaplasma phagocytophilum dihydrolipoamide dehydrogenase 1 affects host-derived immunopathology during microbial colonization., Infect Immun, vol. 80, no. 9, pp. 3194-205, 2012.
J. J. Chinison, Danelishvili, L., Gupta, R., Rose, S. J., Babrak, L. M., and Bermudez, L. E., Identification of Mycobacterium avium subsp. hominissuis secreted proteins using an in vitro system mimicking the phagosomal environment., BMC Microbiol, vol. 16, no. 1, p. 270, 2016.
S. S. Chiplunkar, Silva, C. A., Bermudez, L. E., and Danelishvili, L., Characterization of membrane vesicles released by Mycobacterium avium in response to environment mimicking the macrophage phagosome., Future Microbiol, vol. 14, pp. 293-313, 2019.
H. G. Chu, Weeks, S. K., Gilligan, D. M., and Rockey, D. D., Host alpha-adducin is redistributed and localized to the inclusion membrane in chlamydia- and chlamydophila-infected cells., Microbiology (Reading), vol. 154, no. Pt 12, pp. 3848-3855, 2008.
E. D. Cram, Rockey, D. D., and Dolan, B. P., Chlamydia spp. development is differentially altered by treatment with the LpxC inhibitor LPC-011., BMC Microbiol, vol. 17, no. 1, p. 98, 2017.
E. D. Cram, Simmons, R. S., Palmer, A. L., Hildebrand, W. H., Rockey, D. D., and Dolan, B. P., Enhanced Direct Major Histocompatibility Complex Class I Self-Antigen Presentation Induced by Chlamydia Infection., Infect Immun, vol. 84, no. 2, pp. 480-90, 2016.
D
J. - Da Lin, Nishi, H., Poles, J., Niu, X., Mccauley, C., Rahman, K., Brown, E. J., Yeung, S. T., Vozhilla, N., Weinstock, A., Ramsey, S. A., Fisher, E. A., and Loke, P. 'ng, Single-cell analysis of fate-mapped macrophages reveals heterogeneity, including stem-like properties, during atherosclerosis progression and regression., JCI Insight, vol. 4, no. 4, 2019.
L. Danelishvili, Cirillo, S. L. G., Cirillo, J. D., and Bermudez, L. E., Virulent mycobacteria and the many aspects of macrophage uptake., Future Microbiol, vol. 2, no. 5, pp. 461-4, 2007.
L. Danelishvili, Chinison, J. J. J., Pham, T., Gupta, R., and Bermudez, L. E., The Voltage-Dependent Anion Channels (VDAC) of Mycobacterium avium phagosome are associated with bacterial survival and lipid export in macrophages., Sci Rep, vol. 7, no. 1, p. 7007, 2017.

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