PubAg

Main content area

You searched for: Author "Gilbert, Donald" Remove constraint Author: "Gilbert, Donald" Subject gene expression regulation Remove constraint Subject: gene expression regulation
Start Over

Search

2  Search Results

1 - 2 of 2
Number of results to display per page

Search Results

1. Dynamic recruitment of amino acid transporters to the insect/symbiont interface

Author:
Gilbert, Donald G.,   et al.   ; Duncan, Rebecca P.; Husnik, Filip; Van Leuven, James T.; Dávalos, Liliana M.; McCutcheon, John P.; Wilson, Alex C. C.;     Show all 7 Authors
Source:
Molecular ecology 2014 v.23 no.6 pp. 1608-1623
ISSN:
0962-1083
Subject:
Acyrthosiphon pisum; Planococcus citri; amino acid transporters; bacteriocytes; evolution; gene duplication; gene expression regulation; genes; insects; quantitative polymerase chain reaction; recruitment; symbionts; symbiosis
Abstract:
... Symbiosis is well known to influence bacterial symbiont genome evolution and has recently been shown to shape eukaryotic host genomes. Intriguing patterns of host genome evolution, including remarkable numbers of gene duplications, have been observed in the pea aphid, a sap‐feeding insect that relies on a bacterial endosymbiont for amino acid provisioning. Previously, we proposed that gene duplica ...
DOI:
10.1111/mec.12627
PubMed:
24528556

2. Early transcriptional response pathways in Daphnia magna are coordinated in networks of crustacean‐specific genes

Author:
Gilbert, Donald,   et al.   ; Orsini, Luisa; Brown, James B.; Shams Solari, Omid; Li, Dong; He, Shan; Podicheti, Ram; Stoiber, Marcus H.; Spanier, Katina I.; Jansen, Mieke; Rusch, Douglas B.; Pfrender, Michael E.; Colbourne, John K.; Frilander, Mikko J.; Kvist, Jouni; Decaestecker, Ellen; De Schamphelaere, Karel A. C.; De Meester, Luc;     Show all 18 Authors
Source:
Molecular ecology 2018 v.27 no.4 pp. 886-897
ISSN:
0962-1083
Subject:
Daphnia magna; abiotic stress; cell communication; environmental impact; gene expression regulation; genes; genetic background; genotype-environment interaction; habitats; keystone species; metabolism; stress response; transcription (genetics)
Abstract:
... Natural habitats are exposed to an increasing number of environmental stressors that cause important ecological consequences. However, the multifarious nature of environmental change, the strength and the relative timing of each stressor largely limit our understanding of biological responses to environmental change. In particular, early response to unpredictable environmental change, critical to ...
DOI:
10.1111/mec.14261