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J. Biol. Chem., Vol. 277, Issue 36, 32746-32752, September 6, 2002
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and
From the Division of Clinical Biochemistry, Department of Internal
Medicine, University Medical Center, CH-1211
Geneva 4, Switzerland
There is controversy whether or not upstream
stimulatory factors (USF) regulate the glucose responsiveness of
L-pyruvate kinase (L-PK) promoter activity in hepatocytes. It has been
suggested that USF-2 is required for glucose stimulation of L-PK
promoter activity in single islet 
-cells and INS-1 cells (Kennedy,
H. J., Viollet, B., Rafiq, I., Kahn, A., and Rutter, G. A. (1997) J. Biol. Chem. 272, 20636-20640). In the
present study, the tet-on system has been employed to achieve tightly
controlled and inducible expression of USF-1 and -2 and their
dominant-negative mutants DN-USF-1 (
bTDU1) and -2 (TDU2) in INS-1
cells. Quantitative Northern blot analysis shows that neither basal
level nor glucose responsiveness of endogenous L-PK mRNA is
affected by overexpression of USF-1 and -2. Likewise, the L-PK
expression is unaltered by dominant-negative suppression of USF
function. Western blotting demonstrates that USF-1 and -2 and DN-USF-1
and -2 proteins are stably expressed in nuclear fractions of INS-1
cells. Immunofluorescence staining indicates the uniform induction of
these transgene-encoded proteins in the cell nuclei. Electrophoretic
mobility shift assays using the L-PK promoter segment reveal
that induction of USF-1 and -2 dramatically enhances the USF binding
activity, whereas DN-USF-1 and -2 abolish binding. DN-USF-1 and -2 exert their dominant-negative effect by forming non-functional
heterodimers with endogenous USF proteins. Carbohydrate response
element-binding protein (ChREBP) was recently shown to regulate the
glucose responsiveness of the L-PK promoter activity in hepatocytes. We
now report the presence of this transcription factor in rat islets and
INS-1 cells. Glucose stimulates ChREBP transcription in INS-1 cells, as
shown by nuclear run-on experiments. Overexpression of ChREBP in INS-1
cells using the tet-on system results in a left shift of glucose
responsiveness of L-PK expression and an enhanced L-PK promoter
activity. Both endogenous and doxycycline-induced ChREBP proteins bind
to the L-PK promoter in a glucose-dependent manner. These
unprecedented results suggest that ChREBP rather than USF mediates
glucose-promoted L-PK expression in insulin-secreting cells.
To whom correspondence should be addressed. Tel.: 41-22-702-5570;
Fax: 41-22-702-5543; E-mail: Haiyan.Wang@medicine.unige.ch.
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