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Osmotic Regulation Section, Laboratory of Kidney and Electrolyte Metabolism, National Heart, Lung and Blood Institute, National Institutes of Health, Bethesda, Maryland 20892-1603
The molecular
mechanisms underlying adaptation to hyperosmotic stress through the
accumulation of organic osmolytes are largely unknown. Yet, among
organisms, this is an almost universal phenomenon. In mammals, the
cells of the renal medulla are uniquely exposed to high and variable
salt concentrations; in response, renal cells accumulate the osmolyte
sorbitol through increased transcription of the aldose reductase (AR)
gene. In cloning the rabbit AR gene, we found the first evidence of an
osmotic response region in a eukaryotic gene. More recently, we
functionally defined a minimal essential osmotic response element (ORE)
having the sequence CGGAAAATCAC(C) (bp 
1105 to 1094). In
the present study, we systematically replaced each base with every
other possible nucleotide and tested the resulting
sequences individually in reporter gene constructs. Additionally, we categorized hyperosmotic response by electrophoretic mobility shift assays of a 17-bp sequence (1108 to 1092)
containing the native ORE as a probe against which the
test constructs would compete for binding. In this manner, binding
activity was assessed for the full range of osmotic responses obtained.
Thus we have arrived at a functional consensus for the mammalian ORE,
NGGAAAWDHMC(N). This finding should accelerate the discovery of genes
previously unrecognized as being osmotically regulated.
osmoregulation; osmotic stress; organic osmolytes; gene regulation; gene expression
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