p21(Waf1) is required for cellular senescence but not for cell cycle arrest induced by the HDAC inhibitor sodium butyrate.

Cell senescence is characterized by senescent morphology and permanent loss of proliferative potential. HDAC inhibitors (HDACI) induce senescence and/or apoptosis in many types of tumor cells. Here, we studied the role of cyclin-kinase inhibitor p21(waf1) (Cdkn1n gene) in cell cycle arrest, senescence markers (cell hypertrophy, SA-ßGal staining and accumulation of γH2AX foci) in p21(Waf1+/+) versus p21(Waf1-/-) mouse embryonic fibroblast cells transformed with E1A and cHa-Ras oncogenes (mERas). While short treatment with the HDACI sodium butyrate (NaB) induced a reversible G(1) cell cycle arrest in both parental and p21(Waf1-/-) cells, long-term treatment led to dramatic changes in p21(Waf1+/+) cells only: cell cycle arrest became irreversible and cells become hypertrophic, SA-ßGal-positive and accumulated γH2AX foci associated with mTORC1 activation. The p21(Waf1+/+) cells lost their ability to migrate into the wound and through a porous membrane. Suppression of migration was accompanied by accumulation of vinculin-staining focal adhesions and Ser3-phosphorylation of cofilin, incapable for F-actin depolymerization. In contrast, the knockout of the p21(Waf1) abolished most of the features of NaB-induced senescence, including irreversibility of cell cycle arrest, hypertrophy, additional focal adhesions and block of migration, γH2AX foci accumulation and SA-ßGal staining. Rapamycin, a specific inhibitor of mTORC1 kinase, decreased cellular hypertrophy, canceled coffilin phosphorylation and partially restored cell migration in p21(Waf1+/+) cells. Taken together, our data indicate a new role of p21(Waf1) in cell senescence, which may be connected not only with execution of cell cycle arrest, but also with the development of mTOR-dependent markers of cellular senescence.

The role of the MKK6/p38 MAPK pathway in Wip1-dependent regulation of ErbB2-driven mammary gland tumorigenesis.

There is increasing evidence for the role of wild-type p53 induced phosphatase 1 (Wip1) phosphatase in the regulation of tumorigenesis. To evaluate Wip1 as a breast cancer oncogene, we generated a mouse strain with targeted expression of Wip1 to the breast epithelium. We found that these mice are prone to cancer when intercrossed with transgenics expressing the ErbB2 oncogene but not conditional knockouts for Brca2. This tumor-prone phenotype of Wip1 is fully eliminated through attenuation of proliferation by activating the MKK6/p38 mitogen-activated protein kinases (MAPK) cascade in mice bearing a constitutively active form of MKK6. We propose that Wip1 phosphatase operates within the MKK6/p38 MAPK signaling pathway to promote ErbB2-driven mammary gland tumorigenesis.

Genomic instability in Gadd45a-/- cells is coupled with S-phase checkpoint defects.

Gadd45a is a p53-regulated gene whose protein product, like p53, is involved in maintenance of genome stability. Specifically, deletion of Gadd45a leads to extensive aneuploidy as a consequence of centrosome amplification and subsequent abnormal segregation of chromosomes during mitosis. S-phase checkpoints were investigated in Gadd45a(-/-) cells to determine possible defects contributing to the uncoupling of centrosome duplication and DNA replication. In the presence of hydroxyurea, Gadd45a(-/-) mouse embryo fibroblasts show increased centrosome amplification coupled with loss of a sustained S-phase checkpoint. Gadd45a deletion allows another form of genomic instability, gene amplification, when p21 (Cdkn1a gene product) is deleted also. Gene amplification in Gadd45a(-/-)p21(-/-) cells correlated with loss of both G(1) and S-phase checkpoints. Multiple conditions of nutrient deprivation failed to prevent DNA synthesis in Gadd45a(-/-) cells. Gadd45a is therefore required for proper S-phase control and checkpoints under multiple conditions of nutrient deprivation. It is proposed that loss of S-phase control may account for both the uncoupling of DNA replication and centrosome duplication, and conferring gene amplification proficiency in cells lacking Gadd45a(-/-). This is of particular importance for solid tumors, which may lack sufficient nutrients yet are unable to elicit checkpoints preventing genomic instability under these conditions.

Gadd45a acts as a modifier locus for lymphoblastic lymphoma.

GADD:45a-/- and p53-/- mice and cells derived from them share similar phenotypes, most notably genomic instability. However, p53-/- mice rapidly develop a variety of neoplasms, while Gadd45a-/- mice do not. The two proteins are involved in a regulatory feedback loop, whereby each can increase the expression or activity of the other, suggesting that common phenotypes might result from similar molecular mechanisms. Mice lacking both genes were generated to address this issue. Gadd45a-/-p53-/- mice developed tumors with a latency similar to that of tumor-prone p53-/- mice. However, while p53-/- mice developed a variety of tumor types, nearly all Gadd45a-/-p53-/- mice developed lymphoblastic lymphoma (LBL), often accompanied by mediastinal masses as is common in human patients with this tumor type. Deletion of Gadd45a in leukemia/lymphoma-prone AKR mice decreased the latency for LBL. These results indicate that Gadd45a may act as modifier locus for T-cell LBL, whereby deletion of Gadd45a enhances development of this tumor type in susceptible mice. Gadd45a is localized to 1p31.1, and 1p abnormalities have been described in T-cell lymphomas. Related human tumor samples did not show Gadd45a deletion or mutation, although changes in expression could not be ruled out.

A nucleotide excision repair master-switch: p53 regulated coordinate induction of global genomic repair genes.

The tumor suppressor gene p53 is mutated in many human cancers. One of its major roles is as a transcription factor, and its many effector genes control key cellular processes including cell cycle checkpoints and apoptosis. An important role in DNA repair is also emerging for both p53 itself and some of its effector genes. The products of two p53-regulated genes, GADD45a and DDB2, are now known to participate in the global genomic repair (GGR) sub-pathway of nucleotide excision repair (NER). We recently reported the induction of a third GGR gene, XPC, following exposure of normal human peripheral blood lymphocytes to gamma-rays. We now show that XPC is induced in a variety of human cell lines in response to both ionizing and ultra-violet (UV) radiation and alkylating agents, and that this induction requires wild-type p53.

Induction of gene expression as a monitor of exposure to ionizing radiation.

The complex molecular responses to genotoxic stress are mediated by a variety of regulatory pathways. The transcription factor TP53 plays a central role in the cellular response to DNA-damaging agents such as ionizing radiation, but other pathways also play important roles. In addition, differences in radiation quality, such as the exposure to high-LET radiation that occurs during space travel, may influence the pattern of responses. The premise is developed that stress gene responses can be employed as molecular markers for radiation exposure using a combination of informatics and functional genomics approaches. Published studies from our laboratory have already demonstrated such transcriptional responses with doses of gamma rays as low as 2 cGy, and in peripheral blood lymphocytes (PBLs) irradiated ex vivo with doses as low as 20 cGy. We have also found several genes elevated in vivo 24 h after whole-body irradiation of mice with 20 cGy. Such studies should provide insight into the molecular responses to physiologically relevant doses, which cannot necessarily be extrapolated from high-dose studies. In addition, ongoing experiments are identifying large numbers of potential biomarkers using microarray hybridization and various irradiation protocols including expression at different times after exposure to low- and high-LET radiation. Computation-intensive informatics analysis methods are also being developed for management of the complex gene expression profiles resulting from these experiments. With further development of these approaches, it may be feasible to monitor changes in gene expression after low-dose radiation exposure and other physiological stresses that may be encountered during manned space flight, such as the planned mission to Mars.

Oligomerization of human Gadd45a protein.

Gadd45a is an 18-kDa acidic protein that is induced by genotoxic and certain other cellular stresses. The exact function of this protein is not known. However, there is evidence for its involvement in growth control, maintenance of genomic stability, DNA repair, cell cycle control, and apoptosis. Consistently, Gadd45a has previously been shown to interact in vitro and/or in vivo with a number of proteins playing central roles in these cellular processes: proliferating cell nuclear antigen, p21(Cip1/Waf1), Cdc2-CyclinB complex, MTK1, and histones. Adding to this complexity, we have found that Gadd45a self-associates in solution, both in vitro and when expressed in the cell. Moreover, Gadd45a can complex with the two other members of the Gadd45 family of stress-induced proteins, human Gadd45b (MyD118) and Gadd45g (CR6). Gel-exclusion chromatography, native gel electrophoretic analysis, enzyme-linked immunosorbent assay, and chemical cross-linking showed that recombinant Gadd45a forms dimeric, trimeric, and tetrameric species in vitro, the dimers being the predominant form. Deletion mutant and peptide scanning analyses suggest that Gadd45a has two self-association sites: within N-terminal amino acids 33-61 and within 40 C-terminal amino acids. Despite the low abundance of Gadd45a in the cell, oligomer-forming concentrations can probably be achieved in the foci-like nuclear structures formed by the protein upon overexpression. Evidence for a potential role of Gadd45a self-association in altering DNA accessibility on damaged nucleosomes is presented.

Physiological function as regulation of large transcriptional programs: the cellular response to genotoxic stress.

The responses to ionizing radiation and other genotoxic environmental stresses are complex and are regulated by a number of overlapping molecular pathways. One such stress signaling pathway involves p53, which regulates the expression of over 100 genes already identified. It is also becoming increasingly apparent that the pattern of stress gene expression has some cell type specificity. It may be possible to exploit these differences in stress gene responsiveness as molecular markers through the use of a combined informatics and functional genomics approach. The techniques of microarray analysis potentially offer the opportunity to monitor changes in gene expression across the entire set of expressed genes in a cell or organism. As an initial step in the development of a functional genomics approach to stress gene analysis, we have recently demonstrated the utility of cDNA microarray hybridization to measure radiation-stress gene responses and identified a number of previously unknown radiation-regulated genes. The responses of some of these genes to DNA-damaging agents vary widely in cell lines from different tissues of origin and different genetic backgrounds. While this again highlights the importance of a cellular context to genotoxic stress responses, it also raises the prospect of expression-profiling of cell lines, tissues, and tumors. Such profiles may have a predictive value if they can define regions of 'expression space' that correlate with important endpoints, such as response to cancer therapy regimens, or identification of exposures to environmental toxins.

Initiation of a G2/M checkpoint after ultraviolet radiation requires p38 kinase.

Response to genotoxic stress can be considered as a multistage process involving initiation of cell-cycle arrest and maintenance of arrest during DNA repair. Although maintenance of G2/M checkpoints is known to involve Chk1, Chk2/Rad53 and upstream components, the mechanisms involved in its initiation are less well defined. Here we report that p38 kinase has a critical role in the initiation of a G2 delay after ultraviolet radiation. Inhibition of p38 blocks the rapid initiation of this checkpoint in both human and murine cells after ultraviolet radiation. In vitro, p38 binds and phosphorylates Cdc25B at serines 309 and 361, and Cdc25C at serine 216; phosphorylation of these residues is required for binding to 14-3-3 proteins. In vivo, inhibition of p38 prevents both phosphorylation of Cdc25B at serine 309 and 14-3-3 binding after ultraviolet radiation, and mutation of this site is sufficient to inhibit the checkpoint initiation. In contrast, in vivo Cdc25C binding to 14-3-3 is not affected by p38 inhibition after ultraviolet radiation. We propose that regulation of Cdc25B phosphorylation by p38 is a critical event for initiating the G2/M checkpoint after ultraviolet radiation.

Dimethylbenzanthracene carcinogenesis in Gadd45a-null mice is associated with decreased DNA repair and increased mutation frequency.

Mice lacking the Gadd45a gene are susceptible to ionizing radiation-induced tumors. Increased levels of Gadd45a transcript and protein are seen after treatment of cells with ionizing radiation as well as many other agents and treatments that damage DNA. Because cells deficient in Gadd45a were shown to have a partial defect in the global genomic repair component of the nucleotide excision repair pathway of UV-induced photoproducts, dimethylbenzanthracene (DMBA) carcinogenesis was investigated because this agent produces bulky adducts in DNA that are also repaired by nucleotide excision repair. Wild-type mice and mice deficient for Gadd45a were injected with a single i.p. dose of DMBA at 10-14 days of age. The latency for spontaneous deaths was slightly decreased for Gadd45a-null mice compared with wild-type mice. At 17 months, all surviving animals were killed, and similar percentages of each genotype were found to have tumors. However, nearly twice as many Gadd45a-null than wild-type mice had multiple tumors, and three times as many had multiple malignant tumors. The predominant tumor types in wild-type mice were lymphoma and tumors of the intestines and liver. In Gadd45a-null mice, there was a dramatic increase in female ovarian tumors, male hepatocellular tumors, and in vascular tumors in both sexes. In wild-type mice, this dose of DMBA induced a >5-fold increase in Gadd45a transcript in the spleen and ovary, whereas the increase in liver was >20-fold. Nucleotide excision repair, which repairs both UV- and DMBA-induced DNA lesions, was substantially reduced in Gadd45a-null lymphoblasts. Mutation frequency after DMBA treatment was threefold higher in Gadd45a-null liver compared with wild-type liver. Therefore, lack of basal and DMBA-induced Gadd45a may result in enhanced tumorigenesis because of decreased DNA repair and increased mutation frequency. Genomic instability, decreased cell cycle checkpoints, and partial loss of normal growth control in cells from Gadd45a-null mice may also contribute to this process.

Activation of Gadd34 by diverse apoptotic signals and suppression of its growth inhibitory effects by apoptotic inhibitors.

DNA damage has many cellular consequences including, in some cases, apoptosis. Expression of Gadd34 was shown to be increased by ionizing radiation only in cells that undergo rapid apoptosis following this treatment. The effects of various other apoptosis-inducing agents as well as apoptosis-inhibiting genes on regulation of Gadd34 were investigated. In many cell types, agents which have been reported to lead to increased intracellular ceramide levels led to an increase in Gadd34 transcript levels. These included TNFalpha, the ceramide analog C-2 ceramide, dimethyl sphingosine and anti-Fas antibody as well as ionizing radiation. Induction of Gadd34 by ionizing radiation was coincident with the onset of apoptosis and increased as apoptosis progressed. In a short-term transfection assay, more than 30% of Gadd34-transfected cells exhibited nuclear fragmentation by 48 hours. Apoptosis, as well as induction of Gadd34 by apoptotic stimuli, was attenuated by the apoptosis inhibitors, Bcl-2, cowpox virus CrmA and herpes simplex virus ICP34.5. Thus, activation of Gadd34 is a downstream event in apoptotic signaling pathways and may directly contribute to the apoptotic process.

Gene expression profiles for monitoring radiation exposure.

Previous demonstrations that the dose, dose rate, radiation quality, and elapsed time since ionising radiation exposure result in variations in the response of stress genes suggest that gene expression signatures may be informative markers of radiation exposure. Defining sets of genes that ate specific for different outcomes of interest will be key to such an approach. A generalised post-exposure prolile may identify exposed individuals within a population, while more specific fingerprints may reveal details of a radiation exposure. Changes in gene expression in human cell lines occur after as little as 0.02 Gy rays, and in peripheral blood lymphocytes alter as little as 0.2 Gy. Diverse genes are also elevated in vivo in mice 24 h after 0.2 Gy irradiation. Ongoing microarray analyses meanwhile continue to identify large numbers of potential biomarkers from varied irradiation protocols. Development of computation-intensive informatics analysis methods will be needed for management of the complex gene expression profiles resulting from such experiments. Although the preliminary data are encouraging, significant work remains before meaningful correlations with risk or practical assessment of exposure can be made by gene expression profiling.

Biological indicators for the identification of ionizing radiation exposure in humans.

While the effects of acute high-dose irradiation are well-documented, less is known about the effects of low level chronic radiation exposure. Physical dosimetry cannot always be relied upon, so dose estimates and determination of past radiation exposure must often be based upon biological indicators. Some of the established methods used in the assessment of nuclear accidents are reviewed here, including cytogenetic analyses, mutation-based assays and electron spin resonance. As interest in research on low-level radiation exposures expands, there is an increasing need for new biomarkers that can identify exposed individuals in human populations. Developments in high-throughput gene expression profiling may enable future development of a rapid and noninvasive testing method for application to potentially exposed populations.

An informatics approach identifying markers of chemosensitivity in human cancer cell lines.

We have used a sensitive and reproducible method of measuring mRNA expression to compare basal levels of 10 transcripts in the 60 cell lines of the National Cancer Institute's in vitro anticancer drug screen (NCI-ACDS) under conditions of exponential growth. The strongest correlation among these target genes was between levels of CIP1/WAF1 and BAX. Levels of the three major growth arrest and DNA damage-inducible gene transcripts, (GADD34, GADD45, and GADD153), which are coordinately regulated in response to many stresses, were also correlated across the 60 cell lines. Although the stress induction of several of the transcripts studied here has been shown to be dependent on wild-type p53 status, basal levels of only CIP1/WAF1 and BAX were found to correlate with p53 status. As expected, basal expression of O6 alkyl guanine alkyl-transferase correlated well with resistance to O6-alkylating agents (r = -0.44) but not with resistance to alkylators with different mechanisms of action (r = -0.04). When basal expression levels of the 10 genes across the NCI-ACDS panel were compared with sensitivities to a panel of 122 standard chemotherapy agents, the most striking relationship was a strong negative correlation (r = -0.3) between basal BCL-X levels and sensitivity to drugs in all of the mechanistic classes except one class of antimetabolites. Sensitivities to a maximally diverse sample of 1200 from 70,000 compounds tested in the NCI-ACDS of agents were also negatively correlated with BCL-X levels. A novel application of factor analysis revealed that the newly discovered associations were independent of previously demonstrated sensitivity factors such as p53 mutation status and native population doubling time. A similar pattern of correlation was seen for Bcl-X(L) protein levels. Conversely, BAX and BCL2, two other genes associated with regulation of apoptosis, showed no overall correlation with drug sensitivities. This suggests that BCL-X may play a unique role in general resistance to cytotoxic agents, with the cell lines demonstrating relative resistance to 70,000 cytotoxic agents in the NCI-ACDS being characterized by high BCL-X expression.

Identification of potential mRNA biomarkers in peripheral blood lymphocytes for human exposure to ionizing radiation.

Since early in the Atomic Age, biological indicators of radiation exposure have been sought, but currently available methods are not entirely satisfactory. Using cDNA microarray hybridization to discover new potential biomarkers, we have identified genes expressed at increased levels in human peripheral blood lymphocytes after ex vivo irradiation. We recently used this technique to identify a large set of ionizing radiation-responsive genes in a human cell line (Oncogene 18, 3666-3672, 1999). The present set of radiation markers in peripheral blood lymphocytes was identified 24 h after treatment, and while the magnitude of mRNA induction generally decreased over time, many markers were still significantly elevated up to 72 h after irradiation. In all donors, the most highly responsive gene identified was DDB2, which codes for the p48 subunit of XPE, a protein known to play a crucial role in repair of ultraviolet (UV) radiation damage in DNA. Induction of DDB2, CDKN1A (also known at C1P1/WAF1) and XPC showed a linear dose-response relationship between 0.2 and 2 Gy at 24 and 48 h after irradiation, with less linearity at earlier or later times. These results suggest that relative levels of gene expressions in peripheral blood cells may provide estimated of environmental radiation exposures.

BRCA1 activation of the GADD45 promoter.

Breast cancer susceptibility gene BRCA1 has been implicated in the control of gene regulation and such regulated genes are thought to mediate the biological role of BRCA1. Overexpression of BRCA1 induces GADD45, a p53-regulated and stress-inducible gene. However, the molecular mechanism by which BRCA1 induces the expression GADD45 remains unclear. In this report, we have shown that the GADD45 promoter is strongly activated following expression of wild-type BRCA1. In contrast, both the tumor-derived BRCA1 mutants (p1749R and Y1853insA) and truncated BRCA1 mutant protein (Delta500 - 1863 BRCA1), which lack transactivation activity, were unable to activate the GADD45 promoter, indicating that the BRCA1-mediated activation of the GADD45 promoter requires normal transcriptional properties of BRCA1. BRCA1 did not induce the c-Jun and c-fos promoters, which rules out a general effect of BRCA1 on other immediate-responsive genes. Expression of the human papillomavirus E6 and the dominant-negative mutant p53 proteins had no effect on the induction of the GADD45 promoter by BRCA1, suggesting that activation of the GADD45 promoter by BRCA1 is independent of cellular p53 function. With the 5'-deletion analysis, the BRCA1-responsive element of the GADD45 promoter was mapped at the region from -121 to -75. Disruption of this region resulted in the abrogation of BRCA1 activation of the GADD45 promoter. Taken together, these results demonstrate that the mechanism by which BRCA1 induces GADD45 is mainly through the transactivation of the GADD45 promoter, further demonstrating the evidence that GADD45 acts as one of the BRCA1-regulated genes. Oncogene (2000) 19, 4050 - 4057.

The TRAIL decoy receptor TRUNDD (DcR2, TRAIL-R4) is induced by adenovirus-p53 overexpression and can delay TRAIL-, p53-, and KILLER/DR5-dependent colon cancer apoptosis.

The cell surface decoy receptor proteins TRID (also known as DcR1 or TRAIL-R3) and TRUNDD (DcR2, TRAIL-R4) inhibit caspase-dependent cell death induced by the cytotoxic ligand TRAIL in part because of their absent or truncated cytoplasmic death domains, respectively. We previously identified the death domain containing proapoptotic TRAIL death receptor KILLER/DR5 (TRAIL-R2) as an upregulated transcript following exposure of cancer cells, with wild-type but not with mutant or degraded p53 proteins, to a cytotoxic dose of adriamycin. In the present studies we provide evidence that expression of the TRAIL decoy receptors TRUNDD and TRID increases following infection of cancer cells with p53-expressing adenovirus (Ad-p53), in a manner similar to other p53 target genes such as KILLER/DR5 and p21WAF1/CIP1. Subsequent overexpression of TRUNDD in colon cancer cell lines caused a significant delay in killing induced by TRAIL. Furthermore, cotransfection of TRUNDD with either p53 or KILLER/DR5 (at a 4:1 DNA ratio) in colon cancer cells decreased cell death caused by either gene. This protective effect of TRUNDD was not dependent on the presence of TRAIL, and overexpression of TRUNDD did not alter the protein levels of either p53 or KILLER/ DR5. Further deletion studies showed that whereas protection by TRUNDD against TRAIL-mediated apoptosis did not require an intact intracellular domain (ICD), the first 43 amino acids of the ICD of TRUNDD were needed for protection against cell death induced by p53 or KILLER/DR5. Our results suggest a model in which the TRAIL decoy receptors may be induced by p53, thereby attenuating an apoptotic response that appears to involve KILLER/DR5. Therefore, the p53-dependent induction of TRUNDD may provide a mechanism to transiently favor cell survival over cell death, and overexpression of TRUNDD may be another mechanism of escape from p53-mediated apoptosis in gene therapy experiments.

Death and decoy receptors and p53-mediated apoptosis.

Recently, several tumor necrosis factor receptor 1 (TNF-R1) and Fas-related death receptors have been discovered and include DR3, DR4, DR5 and DR6. These receptors contain an extracellular region containing varying numbers of cysteine-rich domains and an intracellular region that contains the death domain. The death receptors are activated in a ligand-dependent or independent manner and transduce apoptotic signals via their respective intracellular death domains. In addition to death receptors, several decoy molecules have also been identified and include DcR1/TRID, DcR2/TRUNDD, DcR3 and osteoprotegrin (OPG). The decoy molecules do not transduce apoptotic signals but rather compete with the death receptors for ligand binding and thereby inhibit ligand-induced apoptosis. Recent evidence suggests that p53 upregulates the expression of death receptors Fas and DR5, and thus, may mediate apoptosis in part via Fas and/or DR5. However, p53 also regulates the expression of TRAIL decoy receptors DcR1/TRID and DR2/TRUNDD. Although the significance of p53-dependent regulation of decoy receptors remains unclear, evidence suggests that DcR1/TRUNDD appears to inhibit 53-mediated apoptosis. It is, therefore, possible that p53 may blunt its DR5-dependent apoptotic effects by controlling the levels of decoy receptors.

The central region of Gadd45 is required for its interaction with p21/WAF1.

Cell cycle arrest represents an important response to genotoxic stress and the tumor suppressor p53 has been described to act as a critical effector in this biological event. Upon stress, p53 becomes transcriptionally active and up-regulates the transcription of downstream effector genes, which contain p53 recognition sites in their regulatory regions. Among the genes activated are p21 and GADD45, each of which independently exhibits growth-suppressive activity. The Gadd45 protein has been described to form a complex with p21, and thus, work was undertaken to map the regions of Gadd45 involved in this interaction and to examine the roles of those two proteins in growth suppression. In this report, a Gadd45 overlapping peptide library and a series of Gadd45 deletion mutants were used to define the domains of Gadd45 involved in the association with p21. Results using both in vitro and in vivo methods have shown that the interaction of Gadd45 with p21 involves a central region of Gadd45. Interestingly, the p21-binding domain of Gadd45 also encodes the Cdc2-binding activity, indicating that the central region of Gadd45 may serve as an important "core," through which Gadd45 protein is able to present cross-talk with other cell cycle regulators. In addition, GADD45 inhibition of Cdc2 kinase activity was compared with Myd118 and CR6, two other members of the GADD45 family. GADD45 was shown to generate the strongest inhibitory effect on Cdc2 activity. Finally, results from short-term survival assays further demonstrated that p21 and GADD45 act upon different cellular pathways to exert their growth-suppressive function.