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Citation Rajagopal A, Rao AU, Amigo J, Tian M, Upadhyay SK, Hall C, Uhm S, Mathew MK, Fleming MD, Paw BH, Krause M, Hamza I. Haem homeostasis is regulated by the conserved and concerted functions of HRG-1 proteins. Nature, 2008.
PubMed ID 18418376
Short Description Haem homeostasis is regulated by the conserved and concerted functions of HRG-1 proteins.
GEO Record: GSE8696 Platform: GPL200
Download gene-centric, log2 transformed data: WBPaper00031703.ce.mr.csv
# of Conditions 9
Full Description 1316625150_help Haems are metalloporphyrins that serve as prosthetic groups for various biological processes including respiration, gas sensing, xenobiotic detoxification, cell differentiation, circadian clock control, metabolic reprogramming and microRNA processing. With a few exceptions, haem is synthesized by a multistep biosynthetic pathway comprising defined intermediates that are highly conserved throughout evolution. Despite our extensive knowledge of haem biosynthesis and degradation, the cellular pathways and molecules that mediate intracellular haem trafficking are unknown. The experimental setback in identifying haem trafficking pathways has been the inability to dissociate the highly regulated cellular synthesis and degradation of haem from intracellular trafficking events. Caenorhabditis elegans and related helminths are natural haem auxotrophs that acquire environmental haem for incorporation into haemoproteins, which have vertebrate orthologues. Here we show, by exploiting this auxotrophy to identify HRG-1 proteins in C. elegans, that these proteins are essential for haem homeostasis and normal development in worms and vertebrates. Depletion of hrg-1, or its paralogue hrg-4, in worms results in the disruption of organismal haem sensing and an abnormal response to haem analogues. HRG-1 and HRG-4 are previously unknown transmembrane proteins, which reside in distinct intracellular compartments. Transient knockdown of hrg-1 in zebrafish leads to hydrocephalus, yolk tube malformations and, most strikingly, profound defects in erythropoiesis-phenotypes that are fully rescued by worm HRG-1. Human and worm proteins localize together, and bind and transport haem, thus establishing an evolutionarily conserved function for HRG-1. These findings reveal conserved pathways for cellular haem trafficking in animals that define the model for eukaryotic haem transport. Thus, uncovering the mechanisms of haem transport in C. elegans may provide insights into human disorders of haem metabolism and reveal new drug targets for developing anthelminthics to combat worm infestations.
Experimental Details:
WBPaper00031703:4uM_hemin_A
WBPaper00031703:4uM_hemin_B
WBPaper00031703:4uM_hemin_C
WBPaper00031703:20uM_hemin_A
WBPaper00031703:20uM_hemin_B
WBPaper00031703:20uM_hemin_C
WBPaper00031703:500uM_hemin_A
WBPaper00031703:500uM_hemin_B
WBPaper00031703:500uM_hemin_C.
Tags 1316625150_help
Method: microarray, Species: Caenorhabditis elegans, Topic: response to chemical