>
Fa   |   Ar   |   En
   A Temperature-Responsive Network Links Cell Shape and Virulence Traits in a Primary Fungal Pathogen  
   
نویسنده beyhan s. ,gutierrez m. ,voorhies m. ,sil a.
منبع plos biology - 2013 - دوره : 11 - شماره : 7
چکیده    Survival at host temperature is a critical trait for pathogenic microbes of humans. thermally dimorphic fungal pathogens,including histoplasma capsulatum,are soil fungi that undergo dramatic changes in cell shape and virulence gene expression in response to host temperature. how these organisms link changes in temperature to both morphologic development and expression of virulence traits is unknown. here we elucidate a temperature-responsive transcriptional network in h. capsulatum,which switches from a filamentous form in the environment to a pathogenic yeast form at body temperature. the circuit is driven by three highly conserved factors,ryp1,ryp2,and ryp3,that are required for yeast-phase growth at 37°c. ryp factors belong to distinct families of proteins that control developmental transitions in fungi: ryp1 is a member of the wopr family of transcription factors,and ryp2 and ryp3 are both members of the velvet family of proteins whose molecular function is unknown. here we provide the first evidence that these wopr and velvet proteins interact,and that velvet proteins associate with dna to drive gene expression. using genome-wide chromatin immunoprecipitation studies,we determine that ryp1,ryp2,and ryp3 associate with a large common set of genomic loci that includes known virulence genes,indicating that the ryp factors directly control genes required for pathogenicity in addition to their role in regulating cell morphology. we further dissect the ryp regulatory circuit by determining that a fourth transcription factor,which we name ryp4,is required for yeast-phase growth and gene expression,associates with dna,and displays interdependent regulation with ryp1,ryp2,and ryp3. finally,we define cis-acting motifs that recruit the ryp factors to their interwoven network of temperature-responsive target genes. taken together,our results reveal a positive feedback circuit that directs a broad transcriptional switch between environmental and pathogenic states in response to temperature. © 2013 beyhan et al.
آدرس department of microbiology and immunology,university of california,san francisco,san francisco,ca, United States, department of microbiology and immunology,university of california,san francisco,san francisco,ca,united states,bioimaging lab,bioquimica.cl s.a.,bustos 2365,providencia,santiago,chile,facultad de ciencias biológicas,universidad andrés bello,av. república 237,santiago, Chile, department of microbiology and immunology,university of california,san francisco,san francisco,ca, United States, department of microbiology and immunology,university of california,san francisco,san francisco,ca,united states,howard hughes medical institute,university of california,san francisco,san francisco,ca, United States
 
     
   
Authors
  
 
 

Copyright 2023
Islamic World Science Citation Center
All Rights Reserved