Gadd45 mutations are uncommon in human tumour cell lines

GADD45 is an evolutionarily conserved gene that encodes a small acidic, nuclear protein and is an example of a p53 responsive gene. Gadd45 protein has been shown to interact with PCNA and also p21^waf1. It has been implicated in growth arrest, DNA repair, chromatin structure and signal transduction. The confusing biochemical data has been clarified by the demonstration that Gadd45 null mice have a phenotype strikingly similar to that of p53 null mice, being tumour prone and showing marked genomic instability. We have tested the hypothesis that mutations in the GADD45 coding region might substitute for p53 abnormalities in tumour cell lines where p53 is wild type. After generating cDNA from mRNA in a panel of 24 cell lines we sequenced the GADD45 cDNA and have demonstrated that no mutations can be observed, even in the p53 wild type cell lines. Such data suggest that Gadd45 mutations are uncommon in human cancer. From this we postulate that, despite the phenotype of the GADD45 null mouse, GADD45 is unlikely to be the key mechanistic determinant of the tumour suppressor activity of the p53 pathway.
Note on nomenclature: We have employed GADD45 to designate the gene and Gadd45 to designate the encoded protein. This gene has also be denoted GADD45 α elsewhere in the literature.     

Mutations of the P53 gene, including an intronic point mutation, in colorectal tumors.

In this study, analysis of structural changes of the p53 gene in colorectal tumors revealed point mutations detected in 8 of 14 carcinomas and 2 of 2 adenomas. Of these 10 cases with point mutations, eight had one or more missense mutations, one had a nonsense mutation, and the remaining one had, interestingly, an intronic point mutation with subsequent activation of a cryptic splice donor site in the flanking exon. This report contains the first identification of an intronic point mutation of the p53 gene in a colorectal cancer case.     

Abrogation of p53 by its antisense in MCF-7 breast carcinoma cells increases cyclin D1 via activation of Akt and promotion of cell proliferation

The p53 protein has been a subject of intense research interest since its discovery as about 50% of human cancers carry p53 mutations. Mutations in the p53 gene are the most frequent genetic lesions in breast cancers suggesting a critical role of p53 in breast cancer development, growth and chemosensitivity. This report describes the derivation and characterization of MCF-7As53, an isogenic cell line derived from MCF-7 breast carcinoma cells in which p53 was abrogated by antisense p53 cDNA. Similar to MCF-7 and simultaneously selected hygromycin resistant MCF-7H cells, MCF-7As53 cells have consistent basal epithelial phenotype, morphology, and estrogen receptor expression levels at normal growth conditions. Present work documents investigation of molecular variations, growth kinetics, and cell cycle related studies in relation to absence of wild-type p53 protein and its transactivation potential as well. Even though wild-type tumor suppressor p53 is an activator of cell growth arrest and apoptosis-mediator genes such as p21, Bax, and GADD45 in MCF-7As53 cells, no alterations in expression levels of these genes were detected. The doubling time of these cells decreased due to depletion of G0/G1 cell phase because of constitutive activation of Akt and increase in cyclin D1 protein levels. This proliferative property was abrogated by wortmannin, an inhibitor of PI3-K/Akt signaling pathway. Therefore this p53 null cell line indicates that p53 is an indispensable component of cellular signaling system which is regulated by caveolin-1 expression, involving Akt activation and increase in cyclin D1, thereby promoting proliferation of breast cancer cells.     

Germ-line p53 mutations in 15 families with Li-Fraumeni syndrome.

Germ-line mutations of the tumor-suppressor gene p53 have been observed in some families with the Li-Fraumeni syndrome (LFS), a familial cancer syndrome in which affected relatives develop a diverse set of early-onset malignancies including breast carcinoma, sarcomas, and brain tumors. The analysis of the p53 gene in LFS families has been limited, in most studies to date, to the region between exon 5 and exon 9. In order to determine the frequency and distribution of germ-line p53 mutations in LFS, we sequenced the 10 coding exons of the p53 gene in lymphocytes and fibroblast cell lines derived from 15 families with the syndrome. Germ-line mutations were observed in eight families. Six mutations were missense mutations located between exons 5 and 8. One mutation was a nonsense mutation in exon 6, and one mutation was a splicing mutation in intron 4, generating aberrant shorter p53 RNA(s). In three families, a mutation of the p53 gene was observed in the fibroblast cell line derived from the proband. However, the mutation was not found in affected relatives in two families and in the blood from the one individual, indicating that the mutation probably occurred during cell culture in vitro. In four families, no mutation was observed. This study indicates that germ-line p53 mutations in LFS are mostly located between exons 5 and 8 and that approximately 50% of patients with LFS have no germ-line mutations in the coding region of the p53 gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

A mammalian cell cycle checkpoint pathway utilizing p53 and GADD45 is defective in ataxia-telangiectasia.

Cell cycle checkpoints can enhance cell survival and limit mutagenic events following DNA damage. Primary murine fibroblasts became deficient in a G1 checkpoint activated by ionizing radiation (IR) when both wild-type p53 alleles were disrupted. In addition, cells from patients with the radiosensitive, cancer-prone disease ataxia-telangiectasia (AT) lacked the IR-induced increase in p53 protein levels seen in normal cells. Finally, IR induction of the human GADD45 gene, an induction that is also defective in AT cells, was dependent on wild-type p53 function. Wild-type but not mutant p53 bound strongly to a conserved element in the GADD45 gene, and a p53-containing nuclear factor, which bound this element, was detected in extracts from irradiated cells. Thus, we identified three participants (AT gene(s), p53, and GADD45) in a signal transduction pathway that controls cell cycle arrest following DNA damage; abnormalities in this pathway probably contribute to tumor development.     

Multiple mutations of the p53 gene in human mammary carcinoma

Alteration of the p53 tumor suppressor gene is the most common genetic abnormality in human cancer. In breast cancer, depending on the stage of disease and method of detection, mutation rates of 25-60% have been observed. Multiple mutations of p53 gene in the same tumor however, are rarely reported. In this study we explored the frequency of multiple mutations of p53 gene in mammary carcinoma in a cohort of south Florida patients. Three hundred eighty-four cases of primary breast cancer diagnosed between 1984 and 1986 at the University of Miami, Jackson Medical Center were subjects of this study. Sequence analysis of exons 5 through 8 of p53 was performed on cloned PCR-amplified DNA of formalin-fixed, paraffin-embedded tumors. Two hundred thirty-four of 384 breast cancers (61%) had p53 mutation. Of those, 36 tumors showed more than one mutation; 31 tumors had two mutations, three showed three, one tumor had five mutations, and one case carried six mutations. The majority of mutations were missense (43) followed by silent (35); and most occurred within a single exon. Our study suggests that multiple mutations of p53 suppressor gene in breast cancer are more common than currently believed.     

Human melanoma cell line UV responses show independency of p53 function.

UV radiation-induced mutation of the p53 gene is suggested as a causative event in skin cancer, including melanoma. We have analyzed here p53 mutations in melanoma cell lines and studied its stabilization, DNA-binding activity, and target gene activation by UVC. p53 was mutated in three of seven melanoma cell lines. However, high levels of p53 were detected in all cell lines, including melanoma cells with wild-type p53, with the exception of one line with a truncated form. Upon UV induction, p53 accumulated in lines with wild-type p53, and p53 target genes p21Cip1/Waf1, GADD45, and mdm2 were induced, but the induction of p21Cip1/Waf1 was significantly delayed as compared with the increase in p53 DNA-binding activity. However, despite p53 target gene induction, p53 DNA-binding activity was absent in one melanoma line with wild-type p53, and p53 target genes were induced also in cells with mutant p53. In response to UV, DNA replication ceased in all cell lines, and apoptosis ensued in four lines independently of p53 but correlated with high induction of GADD45. The results suggest that in melanoma, several p53 regulatory steps are dislodged; its basal expression is high, its activation in response to UV damage is diminished, and the regulation of its target genes p21Cip1/Waf1 and GADD45 are dissociated from p53 regulation.     

Identification of single nucleotide polymorphisms in the agouti signaling protein (ASIP) gene in some goat breeds in tropical and temperate climates

The agouti-signaling protein (ASIP) plays a major role in mammalian pigmentation as an antagonist to melanocortin-1 receptor gene to stimulate pheomelanin synthesis, a major pigment conferring mammalian coat color. We sequenced a 352 bp fragment of ASIP gene spanning part of exon 2 and part of intron 2 in 215 animals representing six goat breeds from Nigeria and the United States: West African Dwarf, predominantly black; Red Sokoto, mostly red; and Sahel, mostly white from Nigeria; black and white Alpine, brown and white Spanish and white Saanen from the US. Twenty haplotypes from nine mutations representing three intronic, one silent and five missense (p.S19R, p.N35K, p.L36V, p.M42L and p.L45W) mutations were identified in Nigerian goats. Approximately 89 % of Nigerian goats carry haplotype 1 (TGCCATCCG) which seems to be the wild type configuration of mutations in this region of the gene. Although we found no association between these polymorphisms in the ASIP gene and coat color in Nigerian goats, in-silico functional analysis predicts putative deleterious functional impact of the p.L45W mutation on the basic amino-terminal domain of ASIP. In the American goats, two intronic mutations, g.293G>A and g.327C>A, were identified in the Alpine breed, although the g.293G>A mutation is common to American and Nigerian goat populations. All Sannen and Sahel goats in this study belong to haplotypes 1 of both populations which seem to be the wild-type composite ASIP haplotype. Overall, there was no clear association of this portion of the ASIP gene interrogated in this study with coat color variation. Therefore, additional genomic analyses of promoter sequence, the entire coding and non-coding regions of the ASIP gene will be required to obtain a definite conclusion.     

Point mutation of the p53 gene resulting in splicing inhibition in small cell lung carcinoma

The p53 gene is functionally inactivated mostly by point mutations resulting in amino acid substitutions in a wide variety of human cancers. We found a novel mutation of the p53 gene in a small cell lung carcinoma cell line, Lu-143. One of the allelic p53 genes was lost accompanied by loss of heterozygosity for chromosome 17. In the remaining allelic p53 gene, there was a single-base substitution of G to T at position 1 within the splice donor site of intron 7, and the mutated intron was not spliced out during the mRNA maturation process. As a result of this mutation, larger sized p53 mRNA was expressed and no p53 specific protein was detected in this cell line. These results suggest that mutations causing splicing abnormalities are one of the molecular mechanisms for the p53 gene inactivation in human cancer.     

Splicing error in E1alpha pyruvate dehydrogenase mRNA caused by novel intronic mutation responsible for lactic acidosis and mental retardation

An intronic point mutation was identified in the E1alpha PDH gene from a boy with delayed development and lactic acidosis, an X-linked disorder associated with a partial defect in pyruvate dehydrogenase (PDH) activity. Protein analysis demonstrated a corresponding decrease in immunoreactivity of the alpha and beta subunits of the PDH complex. In addition to the normal spliced mRNA product of the E1alpha PDH gene, patient samples contained significant levels of an aberrantly spliced mRNA with the first 45 nucleotides of intron 7 inserted in-frame between exons 7 and 8. The genomic DNA analysis found no mutation in the coding regions but revealed a hemizygous intronic G to A substitution 26 nucleotides downstream from the normal exon 7 5'-splice site. Splicing experiments in COS-7 cells demonstrated that this point mutation at intron 7 position 26 is responsible for the aberrant splicing phenotype, which involves a switch from the use of the normal 5'-splice site (intron 7 position 1) to the cryptic 5'-splice site downstream of the mutation (intron 7 position 45). The intronic mutation is unusual in that it generates a consensus binding motif for the splicing factor, SC35, which normally binds to exonic enhancer elements resulting in increased exon inclusion. Thus, the aberrant splicing phenotype is most likely explained by the generation of a de novo splicing enhancer motif, which activates the downstream cryptic 5'-splice site. The mutation documented here is a novel case of intron retention responsible for a human genetic disease.     

Amplification of Mdmx (or Mdm4) directly contributes to tumor formation by inhibiting p53 tumor suppressor activity

Human tumors are believed to harbor a disabled p53 tumor suppressor pathway, either through direct mutation of the p53 gene or through aberrant expression of proteins acting in the p53 pathway, such as p14(ARF) or Mdm2. A role for Mdmx (or Mdm4) as a key negative regulator of p53 function in vivo has been established. However, a direct contribution of Mdmx to tumor formation remains to be demonstrated. Here we show that retrovirus-mediated Mdmx overexpression allows primary mouse embryonic fibroblast immortalization and leads to neoplastic transformation in combination with HRas(V12). Furthermore, the human Mdmx ortholog, Hdmx, was found to be overexpressed in a significant percentage of various human tumors and amplified in 5% of primary breast tumors, all of which retained wild-type p53. Hdmx was also amplified and highly expressed in MCF-7, a breast cancer cell line harboring wild-type p53, and interfering RNA-mediated reduction of Hdmx markedly inhibited the growth potential of these cells in a p53-dependent manner. Together, these results make Hdmx a new putative drug target for cancer therapy.     

Three novel types of splicing aberrations in the tuberous sclerosis TSC2 gene caused by mutations apart from splice consensus sequences

Disease causing aberrations in both tuberous sclerosis predisposing genes, TSC1 and TSC2, comprise nearly every type of alteration with a predominance of small truncating mutations distributed over both genes. We performed an RNA based screening of the entire coding regions of both TSC genes applying the protein truncation test (PTT) and identified a high proportion of unusual splicing abnormalities affecting the TSC2 gene. Two cases exhibited different splice acceptor mutations in intron 9 (IVS9-15G-->A and IVS9-3C-->G) both accompanied by exon 10 skipping and simultaneous usage of a cryptic splice acceptor in exon 10. Another splice acceptor mutation (IVS38-18A-->G) destroyed the putative polypyrimidine structure in intron 38 and resulted in simultaneous intron retention and usage of a downstream cryptic splice acceptor in exon 39. Another patient bore a C-->T transition in intron 8 (IVS8+281C-->T) activating a splice donor site and resulting in the inclusion of a newly recognised exon in the mRNA followed by a premature stop. These splice variants deduced from experimental results are additionally supported by RNA secondary structure analysis based on free energy minimisation. Three of the reported splicing anomalies are due to sequence changes remote from exon/intron boundaries, described for the first time in TSC. These findings highlight the significance of investigating intronic changes and their consequences on the mRNA level as disease causing mutations in TSC.     

Mutation analysis of p53 in ovarian tumors by DHPLC

Up to now, ovarian carcinomas represent a major health problem among female cancers because they are the leading cause of death from gynecological malignancy. A high proportion of these tumors selects for mutations in the p53 gene. There is evidence that inactivation of the p53 protein could indicate poor prognosis and chemoresistance of patients. To set up a fast and sensitive test for p53 defects in tumor tissues, we analyzed ovarian cancer cells by denaturing high-performance liquid chromatography (DHPLC). A primer set spanning the whole coding region of p53 with seven fragments was designed and appropriate heteroduplex detection in DHPLC analysis was elaborated. The analysis of 45 ovarian tumor specimens yielded 17 genetic alterations (38%) occurring exclusively in the malignant tissue of the patients. In addition, frequent polymorphisms present in normal compared to tumor tissue could serve as a tool for the rapid identification of loss of heterozygosity (LOH) in the tumor. We observed that LOH in intron 2 or 3 correlated well with a lack of one allele in mutated fragments. In conclusion, DHPLC screening appears to be a sensitive and effective test for genetic alterations in tumors with p53 involvement. Since p53 mutations point to a poor prognosis state in several cancers, a fast screening of tumor material for genetic variations may have implications for further individual treatment of patients.