Biology Reference
In-Depth Information
(editors),
Pacific Symposium on Biocomputing
, World Scientific, Singapore, pages
29-40, 1999.
[7]
J.L. DeRisi, V. R. Iyer, and P. O. Brown. Exploring the metabolic and genetic control
of gene expression on a genomic scale.
Science
, 278: 680-686, 1997.
[8]
J. Fan, X. Yang, W. Wang, W. H. Wood, K. G. Becker, and M. Gorospe. Global
analysis of stress-regulated mRNA turnover by using cDNA arrays.
Proc. Nat. Acad.
Sci.
, 99(16): 10611-10616, 2002.
[9]
L. Fu, P. Bounelis, N. Dey, B. L. Browne, R. B. Marchase, and D. M. Bedwell.
The posttranslational modification of phosphoglucomutase is regulated by galactose
induction and glucose repression in Saccharomyces cerevisiae.
J. Bacteriol.
, 7(11):
3087-3094, 1995.
[10]
J. Garcia-Martinez, A. Aranda, and J. E. Perez-Ortin. Genomic run-on evaluates tran-
scription rates for all yeast genes and identifies gene regulatory mechanisms.
Mol.
Cell
, 15: 303-313, 2004.
[11]
A. P. Gasch. The environmental stress response: a common yeast response to di-
verse environmental stresses. In S. Hohmann and W.H. Mager (editors),
Ye as t St re s s
Responses
, Springer, Berlin, pages 11-70, 2003.
[12]
J. L. Hargrove and F. H. Schmidt. The role of mRNA and protein stability in gene
expression.
FA S E B J .
, 3: 2360-2370, 1989.
[13]
K. Hirayoshi and J. T. Lis. Nuclear run-on assays: assessing transcription by measur-
ing density of engaged RNA polymerases.
Methods in Enzymology
, 304: 351-362,
1999.
[14]
S. Ji. The Bhopalator: a molecular model of the living cell based on the concepts of
conformons and dissipative structures.
J. theoret. Biol.
, 116: 399-426, 1985.
[15]
G. Jona, M. Choder, and O. Gileadi. Glucose starvation induces a drastic reduction in
the rates of both transcription and degradation of mRNA in yeast.
Biochim. Biophys.
Acta
, 1491: 37-48, 2000.
[16]
M. Johnnston. Feasting, fasting and fermenting: glucose sensing in yeast and other
cells.
Trends Genetics
, 15(1): 29-33, 1999.
[17]
D. Kondepudi and I. Prigogine.
Modern Thermodynamics: From Heat Engine to
Dissipative Structures
. John Wiley and Sons, Inc., Chichester, 1998.
[18]
K. M. Kuhn, J. L. DeRisi, P. O. Brown, and P. Sarnow. Global and specifictransla-
tional regulation in the genomic response of saccharomyces cerevisiae to nonfermen-
tal carnbon source.
Mol. Cell. Biol.
, 21(3): 916-927, 2001.
[19]
J. Legen, S. Kemp, K. Krause, B. Profanter, R. G. Hermann, and R. M. Maier. Com-
parative analysis of plastid transcription profiles of entire plastid chromosomes from
tobacco attributed to wild-type and PEP-deficient transcription machineries.
Plant J.
,
31: 171-188, 2002.
[20]
K. K. Leuther and S. A. Johnston. Nondissociation of GAL4 and GAL80 in vivo after
galactose induction.
Science
, 256(5061): 33-1335, 1992.
A. L. Mosley, J. Lakshmann, B. K. Aryal, and S. Ozcan. Glucose-mediated phospho-
rylation converts the transcription factor Rgt1 from a repressor to an activator.
J. Biol.
Chem.
, 278 (12): 10322-10327, 2003.
[21]
[22]
A. C. Pease, D. Solas, E. J. Sullivan, M. T. Cronin, C. P. Holmes, and P. A. Fodor.
Light-generated oligonucleotide arrays for rapid DNA sequence analysis.
Proc. Nat.
Acad. Sci. USA
, 91: 5022-5026, 1994.
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