1: J Appl Physiol. 2004 Dec;97(6):2207-13. Epub 2004 Aug 13. 

Regulation of Egr-1, SRF, and Sp1 mRNA expression in contracting skeletal muscle
cells.

Irrcher I, Hood DA.

Dept. of Kinesiology and Health Science, York University, Toronto, Ontario,
Canada M3J 1P3.

The early cellular signals associated with contractile activity initiate the
activation and induction of transcription factors that regulate changes in
skeletal muscle phenotype. The transcription factors Egr-1, Sp1, and serum
response factor (SRF) are potentially important mediators of mitochondrial
biogenesis based on the prevalence of binding sites for them in the promoter
regions of genes encoding mitochondrial proteins, including PGC-1 alpha, the
important regulator of mitochondrial biogenesis. Thus, to further define a role
for transcription factors at the onset of contractile activity, we examined the
time-dependent alterations in Egr-1, Sp1, and SRF mRNA and the levels in
electrically stimulated mouse C(2)C(12) skeletal muscle cells. Early transient
increases in Egr-1 mRNA levels within 30 min (P < 0.05) of contractile activity
led to threefold increases (P < 0.05) in Egr-1 protein by 60 min. The increase
in Egr-1 mRNA was not because of increased stability, as Egr-1 mRNA half-life
after 30 min of stimulation showed only a 58% decline. Stimulation of muscle
cells had no effect on Sp1 mRNA but led to progressive increases (P < 0.05) in
SRF mRNA by 30 and 60 min. This was not matched by increases in SRF protein but
occurred coincident with increases (P < 0.05) in SRF-serum response element DNA
binding at 30 and 60 min as a result of SRF phosphorylation on serine-103. To
assess the importance of the recovery period, 12 h of continuous contractile
activity was compared with four successive 3-h bouts, with an intervening 21-h
recovery period after each bout. Continuous contractile activity led to a
twofold increase (P < 0.05) in Egr-1 mRNA, no change in SRF mRNA, and a 43%
decrease in Sp1 mRNA expression. The recovery period prevented the decline in
Sp1 mRNA, produced a decrease in Egr-1 mRNA, and had no effect on SRF mRNA. Thus
continuous and intermittent contractile activity evoked different specific
transcription factor expression patterns, which may ultimately contribute to
divergent qualitative, or temporal patterns of, phenotypic adaptation in muscle.

PMID: 15310743 [PubMed - indexed for MEDLINE]


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2: Gastroenterology. 2004 Jun;126(7):1809-18. 

Serum response factor promotes re-epithelialization and muscular structure
restoration during gastric ulcer healing.

Chai J, Baatar D, Tarnawski A.

Department of Medicine/Gastroenterology, VA Medical Center, 5901 East Seventh
Street, Long Beach, CA 90822, USA.

BACKGROUND & AIMS: Serum response factor (SRF) regulates transcription of
immediate early genes and muscle genes. In this study, we examined the role of
SRF in gastric ulcer healing and the mechanisms involved. METHODS: Gastric
ulcers were induced in rats by serosal application of acetic acid. Gastric
specimens were obtained sequentially after ulcer induction for analyses of SRF
messenger RNA (mRNA), protein expression, and for immunohistochemistry. We
examined the role of SRF in ulcer healing by local injection of an SRF
expression plasmid into ulcers (gene therapy). To elucidate the cellular
mechanisms of the action of SRF, we examined the effect of SRF overexpression on
actin dynamics, cell migration, and proliferation in rat gastric epithelial cell
(RGM1) and smooth muscle cell (A7R5). To determine the clinical relevance, we
examined SRF expression in human gastric ulcer specimens. RESULTS: Gastric
ulceration activated SRF expression in epithelial cells lining regenerating
glands and in myofibroblasts and smooth muscle cells of granulation tissue. SRF
up-regulation in human gastric ulcers was similar to that found in rat gastric
ulcers. Gene therapy with SRF significantly accelerated experimental gastric
ulcer healing and promoted re-epithelialization and muscle restoration.
Overexpression of SRF in RGM1 and A7R5 cells accelerates migration and
proliferation of these cells by promoting actin polymerization and activation of
immediately early genes. CONCLUSIONS: Activation of SRF is an important
component of ulcer healing. SRF promotes migration and proliferation of gastric
epithelial and smooth muscle cells, which are essential for re-epithelialization
and restoration of muscular structures.

PMID: 15188176 [PubMed - indexed for MEDLINE]


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3: J Biol Chem. 2001 Jul 6;276(27):24531-9. Epub 2001 May 7. 

Differential usage of signal transduction pathways defines two types of serum
response factor target gene.

Gineitis D, Treisman R.

Transcription Laboratory, Imperial Cancer Research Fund Laboratories, 44
Lincoln's Inn Fields, London WC2A 3PX, United Kingdom.

Activation of the transcription factor serum response factor (SRF) is dependent
on Rho-controlled changes in actin dynamics. We used pathway-specific inhibitors
to compare the roles of actin dynamics, extracellular signal-regulated kinase
(ERK) signaling, and phosphatidylinositol 3-kinase in signaling either to SRF
itself or to four cellular SRF target genes. Serum, lysophosphatidic acid,
platelet-derived growth factor, and phorbol 12-myristate 13-acetate (PMA) each
activated transcription of a stably integrated SRF reporter gene dependent on
functional RhoA GTPase. Inhibition of mitogen-activated protein kinase-ERK
kinase (MEK) signalling reduced activation of the SRF reporter by all stimuli by
about 50%, except for PMA, which was effectively blocked. Inhibition of
phosphatidylinositol 3-kinase slightly reduced reporter activation by serum and
lysophosphatidic acid but substantially inhibited activation by platelet-derived
growth factor and PMA. Reporter induction by all stimuli was absolutely
dependent on actin dynamics. Regulation of the SRF (srf) and vinculin (vcl)
genes was similar to that of the SRF reporter gene; activation by all stimuli
was Rho-dependent and required actin dynamics but was largely independent of MEK
activity. In contrast, activation of fos and egr1 occurred independently of RhoA
and actin polymerization but was almost completely dependent on MEK activation.
These results show that at least two classes of SRF target genes can be
distinguished on the basis of their relative sensitivity to RhoA-actin and
MEK-ERK signaling pathways.

PMID: 11342553 [PubMed - indexed for MEDLINE]


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4: Mol Cell Biol. 2001 Apr;21(8):2933-43. 

Serum response factor is required for immediate-early gene activation yet is
dispensable for proliferation of embryonic stem cells.

Schratt G, Weinhold B, Lundberg AS, Schuck S, Berger J, Schwarz H, Weinberg RA,
Ruther U, Nordheim A.

Interfakultares Institut fur Zellbiologie, Abteilung Molekularbiologie,
Universitat Tubingen, 72076 Tubingen, Germany.

Addition of serum to mitogen-starved cells activates the cellular
immediate-early gene (IEG) response. Serum response factor (SRF) contributes to
such mitogen-stimulated transcriptional induction of many IEGs during the G0-G1
cell cycle transition. SRF is also believed to be essential for cell cycle
progression, as impairment of SRF activity by specific antisera or antisense RNA
has previously been shown to block mammalian cell proliferation. In contrast,
Srf(-/-) mouse embryos grow and develop up to E6.0. Using the embryonic stem
(ES) cell system, we demonstrate here that wild-type ES cells do not undergo
complete cell cycle arrest upon serum withdrawal but that they can mount an
efficient IEG response. This IEG response, however, is severely impaired in
Srf(-/-) ES cells, providing the first genetic proof that IEG activation is
dependent upon SRF. Also, Srf(-/-) ES cells display altered cellular morphology,
reduced cortical actin expression, and an impaired plating efficiency on
gelatin. Yet, despite these defects, the proliferation rates of Srf(-/-) ES
cells are not substantially altered, demonstrating that SRF function is not
required for ES cell cycle progression.

PMID: 11283270 [PubMed - indexed for MEDLINE]


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5: J Biol Chem. 2000 Aug 18;275(33):25681-9. 

Activation of serum response factor in the depolarization induction of Egr-1
transcription in pancreatic islet beta-cells.

Bernal-Mizrachi E, Wice B, Inoue H, Permutt MA.

Washington University School of Medicine, Division of Endocrinology, Diabetes
and Metabolism, St. Louis, MO 63110, USA. aplab1@imgate.wustl.edu

The results of the current studies define the major elements whereby glucose
metabolism in islet beta-cells leads to transcriptional activation of an early
response gene in insulinoma cell lines and in rat islets. Glucose stimulation
(2-20 mm) resulted in a 4-fold increase in Egr-1 mRNA at 30 min, as did the
depolarizing agents KCl and tolbutamide. This response was inhibited by
diazoxide and EGTA, indicating that beta-cell depolarization and Ca(2+) influx,
respectively, are essential. Pharmacological inhibition of the Egr-1 induction
by H89 (48%) and calmidazolium (35%), but not by mitogen-activated protein
kinase/extracellular signal-regulated kinase kinase 1 and 2 or
phosphatidylinositol 3-kinase inhibitors, implied that protein kinase A and
Ca(2+)/calmodulin pathways are involved. Deletion mapping of the Egr-1 promoter
revealed that the proximal -198 base pairs containing two serum response
elements (SREs) and one cAMP-response element retained the depolarization
response. Depolarization resulted in phosphorylation of cAMP-response
element-binding protein, yet partial inhibition by a dominant negative
cAMP-response element-binding protein, along with a robust response of a
cAMP-response element-mutated Egr-1 promoter suggested the presence of a second
Ca(2+)-responsive element. Depolarization activation of 5XSRE-LUC and serum
response factor (SRF)-GAL4 constructs, along with activation of SRF-GAL4 by
co-transfection with constitutively active calmodulin kinase IV and protein
kinase A, and binding of Ser(103)-phosphorylated SRF in nuclear extracts,
indicated that the SRE.SRF complexes contribute to the Ca(2+)-mediated
transcriptional regulation of Egr-1. The results of the current experiments
demonstrate for the first time SRE-dependent transcription and the role of SRF,
a transcription factor known to be a major component of growth responses, in
glucose-mediated transcriptional regulation in insulinoma cells.

PMID: 10829028 [PubMed - indexed for MEDLINE]


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6: J Biol Chem. 2000 Jul 21;275(29):22418-26. 

Granulocyte colony-stimulating factor induces Egr-1 up-regulation through
interaction of serum response element-binding proteins.

Mora-Garcia P, Sakamoto KM.

Department of Pediatrics, Division of Hematology/Oncology, School of Medicine,
Los Angeles, California 90095, USA.

Granulocyte colony-stimulating factor (G-CSF) stimulates the proliferation and
maturation of myeloid progenitor cells both in vitro and in vivo. We showed that
G-CSF rapidly and transiently induces expression of egr-1 in the NFS60 myeloid
cell line. Transient transfections of NFS60 cells with recombinant constructs
containing various deletions of the human egr-1 promoter identified the serum
response element (SRE) between nucleotides (nt) -418 and -391 as a critical
G-CSF-responsive sequence. The SRE (SRE-1) contains a CArG box, the binding site
for the serum response factor (SRF), which is flanked at either side by an ETS
protein binding site. We demonstrated that a single copy of the wild-type SRE-1
in the minimal promoter plasmid, pTE2, is sufficient to induce transcriptional
activation in response to G-CSF and that both the ETS protein binding site and
the CArG box are required for maximal transcriptional activation of the
pTE2-SRE-1 construct. In electromobility shift assays using NFS60 nuclear
extracts, we identified SRF and the ETS protein Fli-1 as proteins that bind the
SRE-1. We also demonstrated through electrophoretic mobility shift assays, using
an SRE-1 probe containing a CArG mutation, that Fli-1 binds the SRE-1
independently of SRF. Our data suggest that SRE-binding proteins potentially
play a role in G-CSF-induced egr-1 expression in myeloid cells.

PMID: 10806199 [PubMed - indexed for MEDLINE]


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7: Oncogene. 1999 Dec 2;18(51):7319-27. 

Expression of the SRF gene occurs through a Ras/Sp/SRF-mediated-mechanism in
response to serum growth signals.

Spencer JA, Misra RP.

Department of Biochemistry, Medical College of Wisconsin, Milwaukee, Wisconsin,
WI 53226, USA.

Serum Response Factor (SRF) plays a central role in the transcriptional response
of mammalian cells to a variety of extracellular signals. It is a key regulator
of many cellular early response genes which are believed to be involved in cell
growth, differentiation, and development. The mechanism by which SRF activates
transcription in response to mitogenic agents has been extensively studied,
however, less is known about regulation of the SRF gene itself. Previously, we
identified distinct regulatory elements in the SRF promoter that play a role in
activation, including an ETS domain binding site, an overlapping Sp1/Egr-1
binding site, and two SRF binding sites. We further showed that serum induces
the SRF gene by a mechanism that requires an intact SRF binding site, also
termed a CArG box. In the present study we demonstrate that in response to
stimulation by cells by lysophosphatidic acid (LPA) or whole serum, the SRF
promoter is upregulated by a bipartite pathway that requires both an Sp1 factor
binding site and the CArG motifs for maximal stimulation. The CArG box-dependent
component of this pathway is targeted by Rho mediated signals, and the Sp1
binding site dependent component is targeted by Ras mediated signals.

PMID: 10602487 [PubMed - indexed for MEDLINE]


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8: Mol Endocrinol. 1999 Apr;13(4):619-31. 

Ternary complex factors Elk-1 and Sap-1a mediate growth hormone-induced
transcription of egr-1 (early growth response factor-1) in 3T3-F442A
preadipocytes.

Clarkson RW, Shang CA, Levitt LK, Howard T, Waters MJ.

Department of Physiology and Pharmacology, University Queensland, St. Lucia,
Australia.

In our search for transcription factors induced by GH, we have analyzed
immediate early gene activation in a model of GH-dependent differentiation. Here
we describe the activation of early growth response factor-1 (egr-1) in
GH-stimulated 3T3-F442A preadipocytes and the transcription factors responsible
for its transactivation. Binding activity of egr-1 in electrophoretic mobility
shift assay (EMSA) increased transiently 1 h after GH stimulation, accompanied
by a concomitant increase in egr-1 mRNA. egr-1 induction appeared not to be
related to proliferation since it was amplified in quiescent preadipocytes at a
time when cells were refractive to GH-stimulated DNA synthesis. Truncations of
the proximal 1 kb of the egr-1 promoter revealed that a 374-bp region (-624 to
-250) contributes about 80% of GH inducibility in 3T3-F442A cells and
approximately 90% inducibility in CHO-K1 cells. This region contains three
juxtaposed SRE (serum response element)/Ets site pairs known to be important for
egr-1 activity in response to exogenous stimuli. Site-specific mutations of
individual SRE and Ets sites within this region each reduced GH inducibility of
the promoter. Use of these site-specific mutations in EMSA showed that
disruption of either Ets or SRE sites abrogated ternary complex formation at the
composite sites. DNA binding of ternary complexes, but not binary complexes, in
EMSA was rapidly and transiently increased by GH. EMSA supershifts indicated
these ternary complexes contained serum response factor (SRF) and the Ets
factors Elk-1 and Sap-1a. Coexpression of Sap-1a and Elk-1 resulted in a marked
increase in GH induction of egr-1 promoter activity, although transfection with
expression vectors for either Ets factor alone did not significantly enhance the
GH response. We conclude that GH stimulates transcription of egr-1 primarily
through activation of these Ets factors at multiple sites on the promoter and
that stabilization of ternary complexes with SRF at these sites maximizes this
response.

PMID: 10194767 [PubMed - indexed for MEDLINE]


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9: J Biol Chem. 1999 Jan 15;274(3):1801-13. 

Regulation of MCL1 through a serum response factor/Elk-1-mediated mechanism
links expression of a viability-promoting member of the BCL2 family to the
induction of hematopoietic cell differentiation.

Townsend KJ, Zhou P, Qian L, Bieszczad CK, Lowrey CH, Yen A, Craig RW.

Departments of Pharmacology and Toxicology, Dartmouth Medical School, Hanover,
New Hampshire 03755-3835, USA.

Proliferation, differentiation, and apoptosis are tightly regulated during
hematopoiesis, allowing amplification along specific lineages while preventing
excessive proliferation of immature cells. The MCL1 member of the BCL2 family is
up-regulated during the induction of monocytic differentiation (approximately
10-fold with 12-O-tetradecanoylphorbol 13-acetate (TPA)). MCL1 has effects
similar to those of BCL2, up-regulation promoting viability, but differs from
BCL2 in its rapid inducibility and its pattern of expression. Nuclear factors
that regulate MCL1 transcription have now been identified, extending the
previous demonstration of signal transduction through mitogen-activated protein
kinase. A 162-base pair segment of the human MCL1 5'-flank was found to direct
luciferase reporter activity, allowing approximately 10-fold induction with TPA
that was suppressible upon inhibition of the extracellular signal-regulated
kinase (ERK) pathway. Serum response factor (SRF), Elk-1, and Sp1 bound to
cognate sites within this segment, SRF and Elk-1 acting coordinately to affect
both basal activity and TPA inducibility, whereas Sp1 affected basal activity
only. Thus, the mechanism of the TPA-induced increase in MCL1 expression seen in
myelomonocytic cells at early stages of differentiation involves signal
transduction through ERKs and transcriptional activation through SRF/Elk-1. This
finding provides a parallel to early response genes (e.g. c-FOS and EGR1) that
affect maturation commitment in these cells and therefore suggests a means
through which enhancement of cell viability may be linked to the induction of
differentiation.

PMID: 9880563 [PubMed - indexed for MEDLINE]


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10: EMBO J. 1998 Aug 3;17(15):4414-25. 

The Spemann organizer-expressed zinc finger gene Xegr-1 responds to the MAP
kinase/Ets-SRF signal transduction pathway.

Panitz F, Krain B, Hollemann T, Nordheim A, Pieler T.

Institut fur und Molekulare Zellbiologie, Universitat Gottingen, Germany.

The transcriptional activity of a set of genes, which are all expressed in
overlapping spatial and temporal patterns within the Spemann organizer of
Xenopus embryos, can be modulated by peptide growth factors. We identify Xegr-1,
a zinc finger protein-encoding gene, as a novel member of this group of genes.
The spatial expression characteristics of Xegr-1 during gastrulation are most
similar to those of Xbra. Making use of animal cap explants, analysis of the
regulatory events that govern induction of Xegr-1 gene activity reveals that, in
sharp contrast to transcriptional regulation of Xbra, activation of Ets-serum
response factor (SRF) transcription factor complexes is required and sufficient
for Xegr-1 gene expression. This finding provides the first indication for
Ets-SRF complexes bound to serum response elements to be activated during
gastrulation. MAP kinase signalling cascades can induce and sustain expression
of both Xegr-1 and Xbra. Ectopic Xbra can induce Xegr-1 transcription by an
indirect mechanism that appears to operate via primary activation of fibroblast
growth factor secretion. These findings define a cascade of events that links
Xbra activity to the signal-regulated control of Xegr-1 transcription in the
context of early mesoderm induction in Xenopus laevis.

PMID: 9687509 [PubMed - indexed for MEDLINE]


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11: Neurosci Lett. 1998 Jan 30;241(2-3):87-90. 

Differential time course of angiotensin-induced AP-1 and Krox proteins in the
rat lamina terminalis and hypothalamus.

Blume A, Seifert K, Lebrun CJ, Mollenhoff E, Gass P, Unger T, Herdegen T.

Department of Pharmacology, University of Kiel, Germany.

We studied the time course of expression of the inducible transcription factors
(ITF) c-Fos, FosB, c-Jun, JunB, JunD, Krox-20 and Krox-24, induced by a single
intracerebroventricular injection of angiotensin II, in the subfornical organ
(SFO), median preoptic nucleus (MnPO) paraventricular nucleus (PVN) and
supraoptic nucleus (SON). c-Fos and Krox-24 were expressed rapidly in neurons of
all four areas but completely disappeared after 4 h. FosB showed a delayed but
persistent expression between 4 h and 24 h in the MnPO and PVN. c-Jun was
induced in the MnPO, SFO and PVN after 1.5 h and in the SON after 4 h. JunB was
selectively expressed in the MnPO and SFO and the level of JunD did not change.
The expression of the pre-existing transcription factors SRF, CREB and ATF-2
which contribute to the transcriptional control of jun, fos and krox genes, was
not affected by Ang II. Thus, we could show for the first time that an acute
stimulation of AT receptors results in continual changes in ITF expression over
24 h.

PMID: 9507927 [PubMed - indexed for MEDLINE]


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12: Oncogene. 1997 Jan 16;14(2):213-21. 

FLI1 and EWS-FLI1 function as ternary complex factors and ELK1 and SAP1a
function as ternary and quaternary complex factors on the Egr1 promoter serum
response elements.

Watson DK, Robinson L, Hodge DR, Kola I, Papas TS, Seth A.

Center for Molecular and Structural Biology, Medical University of South
Carolina, Charleston 29425, USA.

The ETS gene products are a family of transcriptional regulatory proteins that
contain a highly conserved and structurally unique DNA binding domain, termed
the ETS domain. Several ETS proteins bind to DNA as monomers, however it has
been shown that the DNA binding activity is enhanced or modulated in the
presence of other factors. By differential display and whole genome PCR
techniques, we have recently shown that the Erg1 gene is a target for ETS
proteins. The Egr1 promoter contains multiple ETS binding sites, three of which
exist as parts of two serum response elements (SREI and SREII). The SRE is a
cis-element that regulates the expression of many growth factor responsive
genes. ELK1 and SAP1a have been shown to form ternary complexes with SRF on the
SRE located in the c-fos promoter. Similarly, we examined whether the ELK1,
SAP1a, FLI1, EWS-FLI1, ETS1, ETS2, PEA3 and PU.1 proteins can form ternary
complexes with SRF on the Egr1 SREI and II. Our results demonstrate that indeed
ELK1, SAPla, FLI1 and EWS-FLI1 are able to form ternary complexes with SRF on
Egr1 SREs. In addition, ELK1 and SAP1a can also form quarternary complexes on
the Egr1 SREI. However, the proteins ETS1, ETS2, PEA3 and PU.1 were unable to
form ternary complexes with SRF on either the Egr1 or c-fos SREs. Our data
demonstrate that FLI1 and EWS-FLI1 constitute new members of a subgroup of ETS
proteins that can function as ternary complex factors and further implicate a
novel function for these ETS transcription factors in the regulation of the Egr1
gene. By amino acid sequence comparison we found that, in fact, 50% of the amino
acids present in the B-box of SAP1a and ELK1, which are required for interaction
with SRF, are identical to those present in both FLI1 (amino acids 231- 248) and
EWS-FLI1 proteins. This B-box is not present in ETS1, ETS2, PEA3 or PU.1 and
these proteins were unable to form ternary complexes with SRF and Egrl-SREs or
c-fos SRE. Furthermore, deletion of 194 amino terminal amino acids of FLI1 did
not interfere with its ability to interact with SRF, in fact, this truncation
increased the stability of the ternary complex. The FLI1 protein has a unique
R-domain located next to the DNA binding region. This R-domain may modulate the
interaction with SRF, providing a mechanism that would be unique to FLI1 and
EWS-FLI1, thus implicating a novel function for these ETS transcription factors
in the regulation of the Egr1 gene.

PMID: 9010223 [PubMed - indexed for MEDLINE]


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13: Gene. 1989 Aug 15;80(2):325-36. 

Structure, chromosome mapping and regulation of the mouse zinc-finger gene
Krox-24; evidence for a common regulatory pathway for immediate-early
serum-response genes.

Janssen-Timmen U, Lemaire P, Mattei MG, Revelant O, Charnay P.

Differentiation Programme, European Molecular Biology Laboratory, Heidelberg,
F.R.G.

The structure of Krox-24, a mouse zinc-finger-encoding gene that is transiently
activated during G0/G1 transition, has been established. Krox-24 is located on
mouse chromosome 18, bands C-D. The gene product, as anticipated for a putative
DNA-binding protein, is localized within the cell nucleus. The Krox-24
5'-flanking region contains a series of serum response elements (SREs) similar
to the SRE observed upstream of the c-fos proto-oncogene. These elements can
substitute for the c-fos SRE, their effect is cumulative and they bind the same
cellular factor, the serum response factor (SRF), as the c-fos SRE. This
suggests that the SRE and its cognate protein are likely to be involved in the
regulation of Krox-24 and presumably of other immediate-early serum response
genes. SRE and SRF therefore constitute key components in the regulatory pathway
leading from mitogenic stimulation to cellular proliferation.

PMID: 2511075 [PubMed - indexed for MEDLINE]


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