AssociaÃÃo da presenÃa de Helicobacter pylori e dos genÃtipos caga e vaca com as alteraÃÃes moleculares dos supressores tumorais P53 e P27 nos adenocarcinomas gÃstricos / Tumor suppressors alterations by Helicobacter pylori association in gastric adenocarcinomas

Angela Rosa AndrÃ

13 June 2008

CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / O carcinoma gÃstrico à a segunda causa de morte por cÃncer no mundo. No Cearà à o segundo mais freqÃente entre os homens e o terceiro entre as mulheres. Dos cÃnceres gÃstricos os adenocarcinomas representam em torno de 95%. A doenÃa tem sido associada a fatores genÃticos e ambientais sendo demonstrada Ãntima relaÃÃo com a infecÃÃo por Helicobacter pylori, principalmente associada à presenÃa do gene cagA e genÃtipos vacAs1m1. Entretanto, apesar dos mecanismos pelos quais a bactÃria promove a carcinogÃnese gÃstrica ainda nÃo estarem esclarecidos, uma das hipÃteses seria atravÃs da inativaÃÃo de supressores tumorais. O objetivo do presente trabalho foi verificar, em adenocarcinomas gÃstricos, se a presenÃa de H. pylori, e de seus genes cagA e vacA, està relacionada com a mutaÃÃo e/ou alteraÃÃo na expressÃo protÃica dos supressores tumorais p53 e p27. Neste estudo, 74 amostras de pacientes foram analisadas quanto à presenÃa de H. pylori, cagA+ e os genÃtipos de vacA, pela reaÃÃo em cadeia da polimerase (PCR). A anÃlise mutacional do gene p53 foi realizada por PCR-SSCP e a detecÃÃo da mutaÃÃo/superexpressÃo do p53 e expressÃo da proteÃna p27 pelo mÃtodo imunohistoquÃmico. A bactÃria foi detectada em 95% das amostras, das quais 63% eram cagA(+). Dentre os alelos de vacA, observou-se predomÃnio de s1 (74%) e m1 (82%), associados em 69% dos casos. Na anÃlise mutacional do p53 verificou-se que 72% dos casos exibiram alteraÃÃo no padrÃo de mobilidade eletroforÃtica, sendo esta associada significativamente à presenÃa do gene cagA. Por outro lado, apenas 29% dos casos apresentaram detecÃÃo pelo mÃtodo imunohistoquÃmico, nÃo sendo encontrada associaÃÃo com a H. pylori. A proteÃna p27 demonstrou acentuada reduÃÃo em sua expressÃo (detectada em apenas 19% dos casos), nÃo demonstrando atividade compensatÃria em relaÃÃo à proteÃna p53 mutada e sem associaÃÃo estatÃstica dos casos negativos com a presenÃa da H. pylori. Finalmente, os resultados sugerem que estes supressores simultaneamente inativados podem ser o ponto chave da desregulaÃÃo do ciclo celular que, associados a outros fatores, favoreÃam o desenvolvimento e progressÃo dos adenocarcinomas gÃstricos. Hà indÃcios de que a presenÃa bacteriana, e dos seus genes cagA(+) e vacA/s1m1, possam influenciar, de forma nÃo esclarecida, as alteraÃÃes moleculares ocorridas nos supressores tumorais p53 e p27. / Gastric carcinoma is the second cause of death by cancer in the world. On State of Ceara-Brazil is the second most frequent type of cancer in men and third in women. Adenocarcinomas account for approximately 95% of all malignant gastric neoplasms. It has been associated to genetic and environmental factors and a intimate relationship between the infection by the bacteria Helicobacter pylori and the gastric carcinoma have been related. The presence of the cagA gene and specific genotypes (s1m1) of the gene vacA have been detected in more pathogenic strains. Although the precise molecular mechanisms by which H. pylori could promote the process of gastric carcinogenesis are under investigation, one hypothesized mechanism involves the tumor supressor genes inactivation. The aim of the present study was to verify if the presence of Helicobacter pylori, cagA and vacA genes is related to mutations in the tumor supressor gene p53 and altered expression of p53 and p27 proteins in gastric adenocarcinomas. Seventy-four (74) samples were analyzed to detect the presence of H. pylori, cagA and genotypes of vacA by Polymerization Chain Reaction (PCR). The mutational analysis of p53 gene was performed by PCR-SSCP (Polymerization Chain Reaction for analysis of the Single-strand Conformation Polymorphism). Analysis of mutation or overexpression of p53 protein and p27 expression was detected by the immunohistochemical method. The bacteria was detected in 95% of the samples, 63% was cagA(+). Among the vacA allele it was observed prevalence of s1 (74%) and m1 (82%), associated in 69% of the cases. Mutation analysis of p53 demonstrated 72% of the cases with altered electrophoretic mobility; The alterations were significatively more frequent in the presence of the cagA gene. Immunohistochemical analysis detected only 29% of cases with the expression of p53 protein. The protein p27 showed accentuated reduction in its expression (detected in only 19% of the cases), it has not demonstrated compensatory activity in relation to the p53 altered protein, neither association to H. pylori presence. Finally, these data suggest that simultaneous inactivation of these tumor suppressors genes may be the key point of deregulation of the cellular cycle that, associated to the other factors, favor the development and progression of the gastric cancer. There is some evidence that the bacterial presence, cagA and vacA/s1m1 genes, may influence, in a not understood way, the alterations observed in the tumor suppressors p53 and p27.

Neoplasias GÃstricas

CarcinogÃnese gÃstrica

Adenocarcinoma gÃstrico

Helicobacter pylori

Supressores tumorais

Gene p53

ProteÃna p53

ProteÃna p27

p27Kip1

Helicobacter pylori

Gastric adenocarcinoma

Tumor suppressors

Gastric carcinogenesis

p53 gene

p27 protein

CANCEROLOGIA

Characterization of the Cis and Trans Acting Factors that Influence p53 IRES Function

Arandkar, Sharath Chandra

January 2012

p53 is a nodal tumor suppressor protein that acts as a major defense against cancers. Approximately 50% of human tumours have mutations in p53 gene. Among its myriad features, the most distinctive is the ability to elicit both apoptotic death and cell cycle arrest. p53 has several isoforms. Most of them are produced by either internal promoter activity of the gene or alternate splicing of the pre-mRNA. Apart from these mechanisms, p53 mRNA has also been shown to be translated into two isoforms, the full-length p53 (FL-p53) and a truncated isoform ΔN-p53, which acts as a dominant-negative inhibitor of FL-p53. Under conditions of cellular stress, the canonical mode of translation initiation is compromised. To maintain the synthesis of proteins important for cell survival and cell-fate decisions, a subset of cellular mRNAs utilizes a non-canonical mode of translation initiation. The 5’ untranslated region of these mRNAs are highly structured and function as Internal Ribosome Entry Site (IRES). Previously, from our laboratory it has been shown that translation of p53 and its N-terminally truncated isoform ΔN-p53 can be initiated by IRES mediated mechanism. IRES mediated translation of ΔNp53 was maximum at G1-S phase but that of FL-p53 was maximum at the G2-M phase. Interestingly in case of a human genetic disorder X-linked dyskeratosis congenita (X-DC), aberrant IRES mediated p53 translation has been reported. It has also been reported that during oncogenic induced senescence (OIS) a switch between cap-dependent to IRES meditated translation occurs in p53 mRNA. From our laboratory, we have also demonstrated that polypyrimidine tract binding protein (PTB) positively regulates the IRES activities of both the p53 isoforms by shuttling from nucleus to the cytoplasm during genotoxic stress conditions. It is very important to understand how these two isoforms are regulated and in turn control the cellular functions. In the first part of the thesis, to investigate the importance of the structural integrity of the cis acting elements within p53 RNA, we have compared the secondary structure of the wild-type RNA with cancer-derived silent mutant p53 RNAs having mutations in the IRES elements such as L22L (CTA to CTG) a natural cancer mutation and Triple Silent Mutation (mutations were present at the wobble position of codon 17, 18, 19). These mutations result in the conformational alterations of p53 IRES RNA that abrogates the IRES function ex vivo significantly. It appears that these mutant RNAs failed to bind some trans-acting factors (p37, p41/44 etc) which might be critical for the IRES function. By super-shift assay using anti hnRNPC1/C2 antibody, we have demonstrated that the TSM mutant showed reduced binding to this protein factor. Partial knockdown of hnRNP C1/C2 showed significant decrease in p53 IRES activity and reduced synthesis of ΔN-p53. Also we have showed that introducing compensatory mutations in TSM mutant RNA rescued the secondary structure as well as function of p53 IRES. Further, the role of another silent point mutation in the coding sequence of p53 was investigated. Silent mutation (CCG to CCA) at codon 36 (P36P) showed decreased IRES activity. The mutation also resulted in differential binding of cellular proteins. Taken together, our observations suggest pivotal role of some specific trans acting factors in regulating the p53-IRES function, which in turn influences the synthesis of different p53 isoforms. In the second part of the thesis, p53 IRES RNA interacting proteins were identified using RNA affinity approach. Annexin A2 and PTB associated Splicing Factor (PSF/SFPQ) were identified and their interaction with p53 IRES RNA in vitro and ex vivo was studied. Interestingly, in the presence of Ca2+ ions Annexin A2 showed increased binding with p53 IRES. By competition UV crosslinking we have showed Annexin A2 and PSF interact specifically with p53 IRES. Toe printing assay results showed the putative contact points of Annexin A2 and PSF proteins on p53 IRES RNA. Interestingly, both proteins showed extensive toe-prints in the neighbourhood of the initiator AUG region of p53. Further, competition UV-crosslinking reveals the interplay of these two proteins. Annexin A2 and PSF appear to compete each other for binding with p53 IRES. PSF is known to interact with PTB protein. Since PTB also interacts with p53 IRES and positively regulates the translation, we wanted to study the interplay between PTB and PSF proteins binding with p53 IRES. To address this, we have performed competition UV crosslinking experiment and showed that increasing concentrations of PTB decreases PSF and p53 IRES interaction. However, increasing concentrations of PSF does not decrease or increase in PTB p53 IRES interaction. Results suggest that both Annexin A2 and PSF proteins play important role in regulation of p53 IRES activity. To address the physiological role of Annexin A2 and PSF proteins on p53 IRES activity, these proteins were partially knocked down in cellulo. This in turn showed decrease in p53 IRES activity in dual luciferase assays as well as in the steady state levels of both the p53 isoforms in transient transfection experiments. Heightened or continued expression of p53 protein is very important under stress where IRES-dependent translation supersedes normal cap-dependent translation. Results showed that expression of Annexin A2 under doxorubicin and thapsigargin induced stress are important for maintenance of both p53 IRES activity and steady state levels of p53 isoforms. Earlier from our laboratory we have showed that the IRES responsible for ∆N-p53 translation is active at G1/S phase while the IRES responsible for full length p53 translation is active at G2/M phase. Subcellular localization of the trans-acting factors plays a pivotal role in regulation of IRES activity of cellular mRNA. In this context we wanted to study the nuclear and cytoplasm localization of Annexin A2 under different cell cycle stages. We have seen Annexin A2 protein is dispersed in nucleus and cytoplasm at G1/S boundary, but post-G2 phase it moved from nucleus to cytoplasm. Further we wanted to investigate the effect of Annexin A2 and PSF on expression of p53 transactivated genes. Partial knock down of Annexin A2 and PSF proteins showed decrease in p21 luciferase activity. By real-time PCR analysis, we have also showed decrease in expression of different p53 targets upon silencing of Annexin A2 protein. Taken together, our observations suggest pivotal role of cis acting and trans-acting factors in regulating the p53-IRES function, which in turn influences the synthesis of p53 isoforms.

Tumor Supressor Protein p53

Cancer Therapy

p53 RNA

IRES RNA

Annexin A2 - p53 IRES Function

p53 Gene Expression - Regulation

p53 Mediated Apoptosis

Cis Acting Factors - p53 IRES Function

p53 IRES Function

p53 Isoforms

p53 mRNA

p53 IRES RNA

Molecular Biology