Effects of Colonization, Luminescence, and Autoinducer on Host Transcription During Development of the Squid-vibrio Association

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2008 Aug 7

PMID 18682555

Citations 49

Authors

Carlene K Chun

Joshua V Troll

Irina Koroleva

Bartley Brown

Liliana Manzella

Einat Snir

Hakeem Almabrazi

Todd E Scheetz

Maria de Fatima Bonaldo

Thomas L Casavant

M Bento Soares

Edward G Ruby

Margaret J McFall-Ngai

Affiliations

Soon will be listed here.

Abstract

The light-organ symbiosis between the squid Euprymna scolopes and the luminous bacterium Vibrio fischeri offers the opportunity to decipher the hour-by-hour events that occur during the natural colonization of an animal's epithelial surface by its microbial partners. To determine the genetic basis of these events, a glass-slide microarray was used to characterize the light-organ transcriptome of juvenile squid in response to the initiation of symbiosis. Patterns of gene expression were compared between animals not exposed to the symbiont, exposed to the wild-type symbiont, or exposed to a mutant symbiont defective in either of two key characters of this association: bacterial luminescence or autoinducer (AI) production. Hundreds of genes were differentially regulated as a result of symbiosis initiation, and a hierarchy existed in the magnitude of the host's response to three symbiont features: bacterial presence > luminescence > AI production. Putative host receptors for bacterial surface molecules known to induce squid development are up-regulated by symbiont light production, suggesting that bioluminescence plays a key role in preparing the host for bacteria-induced development. Further, because the transcriptional response of tissues exposed to AI in the natural context (i.e., with the symbionts) differed from that to AI alone, the presence of the bacteria potentiates the role of quorum signals in symbiosis. Comparison of these microarray data with those from other symbioses, such as germ-free/conventionalized mice and zebrafish, revealed a set of shared genes that may represent a core set of ancient host responses conserved throughout animal evolution.

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