Literature DB >> 31177437

Co-infection Assay to Determine Yersinia pestis Competitive Fitness in Fleas.

Athena Lemon1, Amelia Silva-Rohwer1, Janelle Sagawa1, Viveka Vadyvaloo2.   

Abstract

Co-infection refers to the simultaneous infection of a host by multiple pathogenic organisms. Experimental co-infection studies using a mutant and its isogenic wild type have proven to be profoundly sensitive to analysis of pathogen factor mutation-associated fitness effects in in vivo models of infectious disease. Here we discuss the use of such co-infection experiments in studying the interaction between Yersinia pestis and its flea vector to more sensitively determine the critical bacterial determinants for Y. pestis survival, adaptation, and transmission from fleas. This chapter comprises two main sections, the first detailing how to infect fleas with mutant and wild type Y. pestis strains, and secondly how to process infected fleas and specifically quantify distinct Y. pestis strain burdens per flea. The Y. pestis competitive fitness co-infection model in fleas is insightful in evaluating the consequence of a mutation which may not be obvious in single-strain flea infections where there is less selective pressure.

Entities:  

Keywords:  Co-infection; Competitive fitness; Flea infection; Transmission factors; Yersinia pestis

Mesh:

Year:  2019        PMID: 31177437      PMCID: PMC8895293          DOI: 10.1007/978-1-4939-9541-7_11

Source DB:  PubMed          Journal:  Methods Mol Biol        ISSN: 1064-3745


  15 in total

1.  LXVII. Observations on the mechanism of the transmission of plague by fleas.

Authors:  A W Bacot; C J Martin
Journal:  J Hyg (Lond)       Date:  1914-01

2.  Induction of the Yersinia pestis PhoP-PhoQ regulatory system in the flea and its role in producing a transmissible infection.

Authors:  Roberto Rebeil; Clayton O Jarrett; James D Driver; Robert K Ernst; Petra C F Oyston; B Joseph Hinnebusch
Journal:  J Bacteriol       Date:  2013-02-22       Impact factor: 3.490

3.  Survival and reproduction of artificially fed cat fleas, Ctenocephalides felis Bouché (Siphonaptera: Pulicidae).

Authors:  S E Wade; J R Georgi
Journal:  J Med Entomol       Date:  1988-05       Impact factor: 2.278

4.  Yersinia pestis infection and laboratory conditions alter flea-associated bacterial communities.

Authors:  Ryan T Jones; Sara M Vetter; John Montenieiri; Jennifer Holmes; Scott A Bernhardt; Kenneth L Gage
Journal:  ISME J       Date:  2012-08-16       Impact factor: 10.302

5.  A Single Amino Acid Change in the Response Regulator PhoP, Acquired during Yersinia pestis Evolution, Affects PhoP Target Gene Transcription and Polymyxin B Susceptibility.

Authors:  Hana S Fukuto; Viveka Vadyvaloo; Joseph B McPhee; Hendrik N Poinar; Edward C Holmes; James B Bliska
Journal:  J Bacteriol       Date:  2018-04-09       Impact factor: 3.490

6.  Global gene expression profiling of Yersinia pestis replicating inside macrophages reveals the roles of a putative stress-induced operon in regulating type III secretion and intracellular cell division.

Authors:  Hana S Fukuto; Anton Svetlanov; Lance E Palmer; A Wali Karzai; James B Bliska
Journal:  Infect Immun       Date:  2010-06-21       Impact factor: 3.441

7.  Hfq regulates biofilm gut blockage that facilitates flea-borne transmission of Yersinia pestis.

Authors:  Katherine A Rempe; Angela K Hinz; Viveka Vadyvaloo
Journal:  J Bacteriol       Date:  2012-02-10       Impact factor: 3.490

8.  Transmission of Yersinia pestis from an infectious biofilm in the flea vector.

Authors:  Clayton O Jarrett; Eszter Deak; Karen E Isherwood; Petra C Oyston; Elizabeth R Fischer; Adeline R Whitney; Scott D Kobayashi; Frank R DeLeo; B Joseph Hinnebusch
Journal:  J Infect Dis       Date:  2004-07-12       Impact factor: 5.226

9.  Congo red-agar plating medium for detecting pigmentation in Pasteurella pestis.

Authors:  M J Surgalla; E D Beesley
Journal:  Appl Microbiol       Date:  1969-11

10.  A LysR-Type Transcriptional Regulator, RovM, Senses Nutritional Cues Suggesting that It Is Involved in Metabolic Adaptation of Yersinia pestis to the Flea Gut.

Authors:  Viveka Vadyvaloo; Angela K Hinz
Journal:  PLoS One       Date:  2015-09-08       Impact factor: 3.240
View more
  5 in total

1.  Yersiniabactin contributes to overcoming zinc restriction during Yersinia pestis infection of mammalian and insect hosts.

Authors:  Sarah L Price; Viveka Vadyvaloo; Jennifer K DeMarco; Amanda Brady; Phoenix A Gray; Thomas E Kehl-Fie; Sylvie Garneau-Tsodikova; Robert D Perry; Matthew B Lawrenz
Journal:  Proc Natl Acad Sci U S A       Date:  2021-11-02       Impact factor: 11.205

2.  Biovar-related differences apparent in the flea foregut colonization phenotype of distinct Yersinia pestis strains do not impact transmission efficiency.

Authors:  Athena Lemon; Janelle Sagawa; Kameron Gravelle; Viveka Vadyvaloo
Journal:  Parasit Vectors       Date:  2020-07-01       Impact factor: 3.876

Review 3.  Animal Models of Type III Secretion System-Mediated Pathogenesis.

Authors:  Julia A Hotinger; Aaron E May
Journal:  Pathogens       Date:  2019-11-22

Review 4.  The Diverse Roles of the Global Transcriptional Regulator PhoP in the Lifecycle of Yersinia pestis.

Authors:  Hana S Fukuto; Gloria I Viboud; Viveka Vadyvaloo
Journal:  Pathogens       Date:  2020-12-11

5.  Putative Horizontally Acquired Genes, Highly Transcribed during Yersinia pestis Flea Infection, Are Induced by Hyperosmotic Stress and Function in Aromatic Amino Acid Metabolism.

Authors:  Luary C Martínez-Chavarría; Janelle Sagawa; Jessica Irons; Angela K Hinz; Athena Lemon; Telmo Graça; Diana M Downs; Viveka Vadyvaloo
Journal:  J Bacteriol       Date:  2020-05-11       Impact factor: 3.490
  5 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.