p53 Stabilization Induces Cell Growth Inhibition and Affects IGF2 Pathway in Response to Radiotherapy in Adrenocortical Cancer Cells

Adrenocortical carcinoma (ACC) is a very rare endocrine tumour, with variable prognosis, depending on tumour stage and time of diagnosis. However, it is generally fatal, with an overall survival of 5 years from detection. Radiotherapy usefulness for ACC treatment has been widely debated and seems to be dependent on molecular alterations, which in turn lead to increased radio-resistance. Many studies have shown that p53 loss is an important risk factor for malignant adrenocortical tumour onset and it has been reported that somatic mutations in TP53 gene occur in 27 to 70% of adult sporadic ACCs. In this study, we investigated the role of somatic mutations of the TP53 gene in response to ionizing radiation (IR). We studied the status of p53 in two adrenocortical cell lines, H295R and SW-13, harbouring non-functioning forms of this protein, owing to the lack of exons 8 and 9 and a point mutation in exon 6, respectively. Moreover, these cell lines show high levels of p-Akt and IGF2, especially H295R. We noticed that restoration of p53 activity led to inhibition of growth after transient transfection of cells with wild type p53. Evaluation of their response to IR in terms of cell proliferation and viability was determined by means of cell count and TUNEL assay.wtp53 over-expression also increased cell death by apoptosis following radiation in both cell lines. Moreover, RT-PCR and Western blotting analysis of some p53 target genes, such as BCL2, IGF2 and Akt demonstrated that p53 activation following IR led to a decrease in IGF2 expression. This was associated with a reduction in the active form of Akt. Taken together, these results highlight the role of p53 in response to radiation of ACC cell lines, suggesting its importance as a predictive factor for radiotherapy in malignant adrenocortical tumours cases.


Introduction
Adrenocortical carcinoma (ACC) is a very rare endocrine tumour, with an incidence estimated at approximately 1 to 2 cases per 1 million people every year in the general adult population [1,2], while in the infant population of Southern Brazil the frequency of this malignancy is relatively high, ranging from 3,4 to 4,2 per million children [3,4]. Statistical age distribution follows a bimodal trend, with a first peak occurring in early childhood and a second one in the fourth and fifth decades of life [2,5].
ACCs show variable prognosis, depending on tumour stage and time of diagnosis, although they are generally fatal, with an overall survival of 5 years from detection [6]. Frequency of metastasis associated with ACC varies depending on the study, ranging from 30% to 85% of patients with distant metastasis at the time of presentation [7].
Currently, the therapy that seems to produce best results in ACC cases is surgical resection of the adrenal mass. However, postoperative disease-free survival at 5 years is only around 30% and recurrence rates are up to 85%. Medical therapy with o,p'DDD (ortho, para', dichloro-, diphenyl-, dichloroethane, or mitotane) and other cytotoxic drugs is limited by important side effects. Therefore, other adjuvant treatment options after complete tumour removal are needed [8,9].
Radiotherapy has often been considered ineffective for ACC treatment. In fact, up to 58% of patients do not show a significant response. Although data collected from patients treated with adjuvant tumour bed irradiation demonstrated that radiotherapy may be effective in reducing the high rate of local recurrence of ACC, the high variability in the observed effects suggests that more surveys are needed in order to fully understand the effective therapeutic role of radiotherapy [8,10]. At present, it is thought that radiotherapy should be individualized, while taking into account parameters such as tumour size, resection status, Ki-67 index and tumour spread [11].
Moreover, the variability of the responses observed highlighted the importance of identification of genetic and molecular alterations involved in the resistance of some tumours to radiotherapy [2,12]. At present, knowledge of genetic alterations leading to ACC predisposition is quite poor. However, many studies have shown that p53 loss is an important risk factor for malignant adrenocortical tumour onset. Patients affected by Li-Fraumeni syndrome, who inherit germline mutations of TP53, are more likely to develop malignant adrenocortical tumours. Moreover, a specific mutation in codon 337 (R337H) seems to be responsible for the majority of cases of ACC in the child population of Southern Brazil. Furthermore, it has been also reported that somatic mutations in TP53 gene occur in 25 to 70% of adult sporadic ACCs [2,9].
In this study, we investigated the role of p53 in response to ionizing radiation (IR) in ACC in vitro models. Specifically, we analysed the status of TP53 gene in two human ACC cell lines, H295R and SW-13, and we found that this gene is mutated in both cell lines, which are partially resistant to IR at a dose of 6 Gy, as previously demonstrated [13]. The over-expression of IGF2 mRNA is another typical feature of ACC found in H295R cell line. Here, we showed that the restoration of p53 activity, by transfection of wild type p53 ( wt p53), led to inhibition of growth and induced cell death by apoptosis following IR administration in both cell lines. We also noticed a reliable decrease in IGF2 gene expression and a reduction in Akt activation following IR treatment in cells over-expressing wild type p53.
Taken together, these results highlight the importance of p53 in cellular response to IR in ACC cell lines. They also indicate a molecular mechanism involving IGF2, thus strengthening the effectiveness of radiotherapy as adjuvant treatment in ACC.

TP53 mRNA analysis
In a previous paper by our group [13], a large deletion in TP53 gene, affecting exons 8 and 9, was discovered in H295R cell line. We performed sequencing analysis of TP53 coding sequence in these cells to evaluate the effect of this deletion on mRNA production. We found that a shorter mRNA is transcribed, where exon 7 is directly bound to exon 10 ( Figure 1, panel A, top). Consistent with that, RT-PCR analysis of TP53, was carried out using primers flanking exons 8 and 9 region. This revealed a shorter mRNA product, lacking 211 base pairs ( Figure 1, panel B).
The deletion of exons 8 and 9 determines an amino acid sequence change starting from codon 261, which also introduces a premature stop codon at amino acid position 274 ( Figure 1, panel C, top). According to our previous data, this mRNA was shown to be translated into a shorter protein, whose molecular weight is about 44 kDa (Figure 1, panel D).
Sequencing analysis of TP53 coding sequence in SW-13 cells confirmed the presence of a homozygous point mutation in exon 6 (r.577c.u), which was described for the first time by Reincke et al. Effect of wild type TP53 on cell proliferation and response to ionizing radiation To assess the significance of TP53 mutations on cell proliferation, we transiently transfected H295R and SW-13 cells with empty vector (mock) or a vector expressing the wild type form of TP53 (WT) and evaluated the effect on cell growth 24, 48 and 72 hours after transfection. We also evaluated the effect of TP53 restoration in response to irradiation at dose of 6 Gy.
The same analysis was performed on radio-resistant ovarian adenocarcinoma SK-OV-3 cells, which do not express either p53 protein or mRNA [15].
In H295R cells ( Figure 2, panel A, left), no significant growth inhibition was observed in cells expressing wild type p53 compared with cells transfected with empty vector (211% after 48 h and 29% at 72 h). This indicates that p53 alone is not able to induce a stable growth arrest in these cells. IR did not significantly alter cell proliferation in cells transfected with empty vector (24% after 72 h), whereas the effect of irradiation on cell growth was evident in cells expressing wt p53. This effect was evident at 48 h after transfection (218% compared to mock irradiated cells; p,0.05) and strengthened at 72 h after transfection (48 h after irradiation), when growth inhibition reached 225% (p,0.01).
Unlike our previous report [13], in this work we improved transfection efficiency by using pBABE-neo-p53 vector, containing the MMLV Long Terminal Repeat. Morgenstern and Land [16] support the ability of this vector to greatly improve gene expression in many cell lines.
Similar results were observed in SW-13 cell line ( Figure 2, panel A, right). Cells transfected with empty vector or p53-vector showed a very similar proliferation trend. Moreover, irradiation did not significantly affect cell proliferation in cells transfected with empty vector. On the contrary, a strong effect of IR treatment in cells expressing wt p53 was evident at 24 h after irradiation (48 h after transfection), with 28% of cell growth inhibition (p,0.05) compared with irradiated cells transfected with empty vector. The effect was even greater at 72 h after transfection, when we observed 31% of growth inhibition in WT irradiated cells compared with control (p,0.01).
In SK-OV-3 cells (Figure 2, panel A, bottom), the restoration of wt p53 induced a slight inhibition of cell growth, which however did not exceed 17% after 72 h. We also observed that IR treatment at a dose of 6 Gy induced a growth inhibition of 227% (p,0.05) after 24 h in cells transfected with empty vector, which reached 235% (p,0.01) after 48 h. However, the presence of wt p53 strengthened the effect of IR treatment. In fact, we observed a cell growth inhibition of 220% (p,0.01) 24 h after irradiation in cells expressing p53 compared with those transfected with empty vector. This effect increased after 48 h (228%; p,0.01).
The importance of p53 in SK-OV-3 cells response to irradiation was further confirmed by the observation that cells transfected with empty vector began to recover 72 h after IR treatment, while those expressing wt p53 continued to be inhibited (data not shown).
In H295R and SW-13 cell lines, the effect of p53 stabilization on cyclin E and cyclin D1 was evaluated, as these proteins contribute to cell proliferation by accelerating the G1 phase of cell cycle [17,18]. At 72 h after transfection with empty vector (mock) or p53 vector (WT), we observed a decrease in cyclin E and cyclin D1 expression levels in samples expressing wt p53 irradiated with a dose of 6 Gy, in both H295R (Figure 2, panel B) and SW-13 ( Figure 2, panel C) cells. This result hence indicates that IR treatment is able to slow the proliferation rate of our cell lines in a p53-dependent manner.
These data indicate that restoration of wt p53 expression in H295R and SW-13 cell lines is not sufficient to exert an effect on cell proliferation. The presence of the wild type form of p53 appears to be fundamental for growth inhibition of these cells in response to irradiation, as cells transfected with empty vector are p53 and Radiotherapy Effect in Adrenal Cancer PLOS ONE | www.plosone.org hardly affected by this treatment. However, wt p53-expressing cells are significantly inhibited.
In SK-OV-3 cells, the effect of IR is stronger than in H295R and SW-13 cells, even in samples transfected with empty vector, suggesting that this cell line is more sensitive to irradiation than ACC cell lines. Nevertheless, the maximum growth inhibition is reached when the wild type form of p53 is expressed, indicating that this protein is involved in the response to IR in SK-OV-3 cells as well.

Stabilization of p53 in response to ionizing radiation
Wild type p53 over-expression was assessed by RT-PCR and Western blotting. p53 levels significantly increased in H295R and SW-13 cell lines at 24 h after transfection with pBABE-neo-p53 vector and were maximum at 48 h. At 72 h from transfection, we observed a decrease in p53 levels, which seemed to be due to a reduction in TP53 mRNA, probably because of the loss of transfected vectors ( Figure S2).
However, in cells transfected with wild type p53 subjected to IR treatment, the effect on cell proliferation was strongest after 72 hours after transfection (48 h after irradiation). Therefore, expression levels of p53 were evaluated by RT-PCR and Western blotting in H295R, SW-13 and SK-OV-3 cells at the same time point.
Real Time RT-PCR analysis confirmed that TP53 gene is overexpressed in all samples transfected with pBABE-neo-p53 vector ( Figure 3, panels A, C, E), either irradiated or not. Compared with mock, TP53 mRNA was 5-and 3-fold more expressed in H295R and SW-13 cells, respectively. According to Yaginuma and Westphal [15], in SK-OV-3 cells, no TP53 mRNA was detectable in mock samples, contrary to cells transfected with p53-vector.
Although TP53 mRNA levels were higher in p53-transfected cells, they did not vary between WT irradiated and non-irradiated cells. On the contrary, p53 protein levels appeared to be significantly higher in p53-transfected cells subjected to IR treatment compared with the non-irradiated ones. In actual fact, in H295R cells the levels of wild type p53 increased 3 fold in irradiated WT cells compared with p53-transfected, non-irradiated cells (Figure 3, panel B). However, the endogenous form of p53 (p53 D8-9 ) was not modulated by radiation treatment. SW-13 cells Treatment of H295R and SW-13 cells with different radiation doses (4, 6 and 8 Gy) confirmed that TP53 mRNA expression levels were not influenced by IR ( Figure S3, panels A, C). The administration of a radiation dose of 4 Gy did not induce a significant variation in p53 protein either. On the contrary, p53 was upregulated after the administration of radiation doses of 6 and 8 Gy; however, no significant changes were observed between these two doses ( Figure S3, panels B, D), indicating that IR The increase in p53 protein levels observed in irradiated samples is not due to an increase in TP53 expression, since mRNA levels were not affected by radiation. This may be explained by an activation of p53 by IR, which translates in a stabilization of this protein only in cells subjected to this treatment. The stabilization of p53 may be considered predictive of its activation, thus explaining the effect on cell proliferation only observed in samples which received irradiation.

TUNEL analysis of cell death
As p53 is a well-known inducer of the apoptotic process in response to genotoxic stresses [19,20], we performed a TUNEL assay in order to analyse the presence of apoptosis in H295R, SW-13 and SK-OV-3 cell lines transfected with empty vector (mock) or p53-vector (WT), either irradiated or not.
As expected, no signs of apoptosis were detectable in samples not subjected to treatment with IR (data not shown). Apoptotic cell death was also absent in irradiated cells transfected with empty vector, whereas samples in which the wild type form of p53 was expressed appeared to be positive to TUNEL staining in all cell lines ( Figure 4, panel A), indicating that the presence of a functional p53 is necessary for the induction of cell death in response to radiotherapy.
Apoptosis was detectable at 48 h after transfection of wt p53 and increased at 72 h after transfection (48 h after irradiation) in all cell lines ( Figure 4, panels A, B; Table S1). Apoptotic cell death increased by 2.6 fold at 48 h in irradiated H295R cells transfected with p53-vector compared with cells transfected with empty vector  Table S1).
Since many reports demonstrated that p53 is able to repress BCL2 expression in response to an apoptotic stimulus [21][22][23], we analysed BCL2 mRNA levels in cells treated with IR, either expressing the wild type form of TP53 (WT) or not (mock), at 48 h and 72 h after transfection. RT-PCR analysis revealed that BCL2 expression levels decreased in irradiated cells only when wt p53 was present, whereas they held steady in samples transfected with empty vector. In accordance with TUNEL assay results, BCL2 levels began to decrease starting from 48 h and minimum levels were observed at 72 h after transfection ( Figure 4, panel C, D, E).
These data confirm that wild type p53 is required for the induction of cell death by apoptosis and down-regulation of BCL2 in response to irradiation in H295R and SW-13 cells. Moreover, the absence of these effects in irradiated cells expressing only the endogenous mutant p53 seems to indicate that these mutants are non-functioning proteins are in no way influenced by IR treatment.
Effect on IGF2 expression IGF-II represents the main marker of ACC [24,25] and its expression is tightly regulated by p53 [26,27]. Since we demonstrated that wt p53 is able to reduce cell proliferation and induce apoptosis in ACC cell lines in response to IR, we also investigated the effect of p53 activation on IGF2 expression. RT-PCR analysis of IGF2 mRNA expression in H295R cells ( Figure 5, panel A) revealed that irradiation did not alter IGF2 levels in samples transfected with empty vector. However, IGF2 expression was reduced at 48 h after transfection (24 h after irradiation) and dramatically decreasing at 72 h after transfection (242%; p,0.01) in cells expressing wild type p53.
Similar results were observed in the SW-13 cell line ( Figure 5, panel B), although these cells express very low levels of IGF2 mRNA. Even in this case, no effect on IGF2 expression was observed after IR administration in cells expressing endogenous mutant p53, while a strong decrease in IGF2 mRNA levels was observed in cells transfected with wt p53 vector. This decrease was maximum at 72 h after transfection (235%; p,0.05).

Effect on Akt activation
Finally, we investigated the effect of IR on Akt activation in H295R and SW-13 cell lines either transfected with p53 vector (WT) or not (mock). This protein, in fact, is a main downstream effector of IGF-II signalling pathway and a key negative regulator of the apoptotic process.
Western blotting analysis of total Akt and of its phosphorylated active form in H295R ( Figure 6, panel A) and SW-13 ( Figure 6, panel B) cells revealed that Akt was present in all samples and was not influenced by wt p53 expression (data not shown). On the contrary, densitometric analysis of p-Akt normalized to total Akt showed that cells transfected with p53 vector displayed a marked decrease in Akt phosphorylation in response to IR compared with controls, meaning that p53 activation may be able to repress the activity of the anti-apoptotic protein Akt.
In accordance with our data concerning cell proliferation and apoptosis, the effect on Akt phosphorylation was evident at 48 h after transfection (216% in H295R and 217% in SW-13 cells,

Discussion
ACC is an aggressive and heterogeneous malignancy and most of therapeutic options are often unsuccessful, thus indicating that alternative therapeutic strategies for ACC are needed [8,9]. Reported toxicity of radiation therapy is mild to moderate, suggesting that radiotherapy may represent a valid choice. However, response rates to this treatment are highly variable. For a long time, ACC has been considered a radio-resistant tumour [2,10], but over the last few years, many authors have demonstrated some effectiveness of radiotherapy [10,11,13,28]. However, more studies are required to fully understand its real therapeutic potential. Recently, some indications about patient selection for radiotherapy of the tumour bed have been defined, based on resection status and histopathologic features of the neoplasm [11]. The importance of an individualized decision regarding radiotherapy has also been highlighted [10,11].
Therefore, identification of other factors affecting radioresponsiveness may help the clinician in defining the best therapeutic approach. Extensive evidence over the last two decades reporting that p53 is required for efficacy of radiation therapy has generated considerable interest in developing strategies in tumours with defective p53 [17,18,29]. In fact, many reports have found a correlation between TP53 mutations and radio-resistance in many cancer cell lines [30][31][32][33].
p53 function is frequently altered or lost in ACC. An association between TP53 mutations and Li-Fraumeni syndrome has been found in more than 70% of families affected by this pathology, which means a higher risk of developing ACC, especially during childhood [4,9]. Somatic mutations of TP53 gene are often found in adult sporadic ACCs, with a frequency ranging from 20% to 70%, depending on the study. Moreover, LOH in 17p13 locus occurs in about 85% of cases of ACC, but not in benign adrenocortical adenomas [2,9]. Although, these statistics strongly suggest an extensive role for TP53 mutations in ACC onset, currently no data exist for the association between TP53 status and radiotherapy efficacy in ACC. Therefore, we investigated the role of p53 protein in the response to this treatment in two cell lines derived from this tumour. The purpose was to evaluate the importance of p53 as a predictive factor for the outcome of radiation therapy, which might be useful for improving patients' prognosis and living conditions.
Our study was conducted on H295R and SW-13 cell models. H295R cells were obtained from a functional human ACC which have the ability to produce steroid hormones. In fact, they express steroidogenic enzymes CYP11A, HSD3B2, CYP11B1, CYP21, CYP17, CYP11B2, 3b-hydroxysteroid sulfotransferase, and aromatase (CYP19). They are also responsive to ACTH and Angiotensin-II stimulation [34]. On the contrary, the SW-13 cell line derives from a small cell carcinoma in the adrenal cortex. These cells are not able to produce steroids and their exact histopathologic origin has not been completely elucidated [34].
These cell lines, especially H295R, are typical of ACC and represent two useful models since they carry different mutations in the TP53 gene. Deletion of exons 8 and 9 in H295R cells has previously been described by our group [13], while H193Y mutation in SW-13 cells was identified by Reincke et al. [14]. However, no data is available about the impact of these mutations on p53 function. A polymorphism in codon 72 (P72R) was also identified in the SW-13 cell line. The effect of this polymorphism on p53 activity has been widely debated [35]. A major susceptibility to cancer has been observed in homozygous carriers of the arginine allele and a reduction in disease-free and overall survival has been found in proline/arginine heterozygous patients with breast cancer [35,36].
p53 mutant in H295R cells lacks part of the DNA binding domain and the entire C-terminal domain and SW-13 cells bare a homozygous point mutation in DBD, suggesting that p53 activity in these cell lines is completely lost.
We evaluated the effect of p53 restoration in ACC cell lines and in p53 2/2 ovarian adenocarcinoma SK-OV-3 cells. It was previously demonstrated that lack of p53 is responsible for SK-OV-3 cells insensitivity to radiation treatment at low doses, while reintroduction of wild type p53 determines an effect on cell growth and viability in response to irradiation [32,33]. Here, we demonstrate that transfection of SK-OV-3 cells with a construct harboring type TP53 cDNA induces inhibition of cell proliferation and apoptosis in response to irradiation. Treatment of SK-OV-3 cells with a dose of 6 Gy induced a certain effect on cell proliferation even in samples transfected with empty vector. However, this effect was temporary since cells began to recover at 72 h after irradiation. Cell growth inhibition in irradiated cells was more relevant and long-lasting when wt p53 was present. Moreover, cell death was only present in p53-expressing cells after irradiation, thus confirming that functional p53 is necessary for apoptotic response induced by irradiation.
We found that over-expression of wild type TP53 is not able to induce a strong effect on cell proliferation or apoptosis in H295R and SW-13 cell lines. However, the presence of wild type p53 is required for inhibition of cell proliferation and induction of apoptotic cell death in response to IR treatment.
We noticed an increase in p53 levels after irradiation in our cell lines. This is due to the stabilization of the protein rather than to an enhanced transcription of the gene, suggesting its activation. In fact, p53, is maintained at low levels in resting cells and its stabilization in response to different stress stimuli represents a wellknown mechanism which allows cells to preserve genome integrity after a DNA-damaging event. Inhibition of p53 function is mainly driven by Mdm2, which reduces the ability of p53 to activate gene expression and also participates in its degradation. Many posttranslational modifications affecting both p53 and Mdm2 prevent p53 degradation, thus allowing this protein to promote cell cycle arrest, senescence and apoptosis [37,38]. In our cell models, wt p53 activity was also confirmed by the observation that only p53transfected, irradiated samples were subjected to apoptosis, while non-irradiated and mock-transfected, irradiated cells were not. This indicates that the activation of wild type p53 is necessary for the induction of cell death following irradiation. Moreover, transcriptional activity of p53 was also enhanced, as was demonstrated by inhibition of the anti-apoptotic gene BCL2, whose expression is regulated by p53 [21][22][23]. BCL2 levels were not influenced by irradiation in the absence of wt p53, whereas restoration of p53 led to a strong decrease in its expression.
Hence, these findings confirm that stabilization of p53 following IR is necessary to induce apoptosis in ACC and SK-OV-3 cell lines. Moreover, our results shed new light on the functional characterization of H295R and SW-13 p53 mutants. In fact, when cells expressing the endogenous mutant forms of p53 were subjected to IR treatment, we observed no effect on apoptosis or BCL2 expression, thus indicating that the mutations we identified cause a loss of the ability of p53 to induce apoptosis. Nevertheless, further studies would be required in order to fully characterize these mutants.
Considering these results, our findings also stress the importance of early ACC diagnosis, in order to undertake irradiation treatment during early stages of tumour development, virtually before the onset of mutations in the TP53 gene. Moreover, new therapeutic approaches, based on mutant or inactive p53 reactivation by small molecules, like nutlins, PRIMA-1 and RITA [39,40], associated with radiotherapy, may be considered. Furthermore, retrospective and prospective studies aiming at the evaluation of p53 status in patients who undergo radiotherapy may be very useful, in order to confirm the effective relationship between p53 activity and radio-responsiveness in ACC.
Finally, we investigated the ability of wt p53 to repress IGF2 expression. Insulin-like growth factor II (IGF-II) is over-expressed in more than 90% of ACCs [24,41,42] and represents the major marker that allows the distinction between benign adenomas and malignant tumours [24,25]. Moreover, IGF2 over-expression is considered a negative prognostic factor in ACC cases [2,24]. Several studies demonstrated that p53 can inhibit IGF2, either directly, through regulation of IGF2 P3 promoter activity, or indirectly, through the regulation of DNA methyltransferases (Dnmt) expression. This allows the maintenance of a correct methylation pattern of the imprinting control region (ICR) at the IGF2/H19 loci [26,27].
Here, we demonstrate that p53 activation in response to IR treatment is able to induce a strong effect on IGF2 expression in ACC cell lines and especially in H295R cells, where we observed an almost complete suppression of IGF2 levels. Moreover, we also evaluated the effect of IR administration on the anti-apoptotic protein Akt. It is one of the main downstream targets of IGF-II and was found to be hyper-activated in ACC [43,44]. We observed a marked decrease in Akt activation levels in our cell lines, which is consistent with the induction of apoptosis seen in cells expressing wt p53 subjected to irradiation. The activation of Akt through IGF-II/IGF-1R signaling is in fact involved in the regulation of many cell processes such as cell growth, division and survival. In particular, Akt mediates the inhibition of BAD (Bcl-2associated agonist of cell death), thus stimulating Bcl-2 activity. Moreover, up-regulation of IGF-1R pathway is associated with increased radio-resistance through the down-regulation of proapoptotic factors Bax and Ku70/80, and the over-expression of anti-apoptotic proteins MVP (Major Vault Protein) and Bcl-2 [45,46]. The ability of p53 to induce apoptosis and to inhibit Bcl-2, either directly or through repression of the IGF-II/Akt pathway, is therefore fundamental for cellular response to IR damage. The absence of these effects in irradiated H295R and SW-13 cells expressing only endogenous mutants of p53 clearly indicates that the wild type form of this protein is required to inhibit the aberrantly activated IGF-II/Akt signal transduction pathway in ACC.
Further studies are required to understand the exact mechanism leading to IGF2 down-regulation by p53 after irradiation. However, the repression of IGF-II/Akt pathway activity represents an important therapeutic goal. As a matter of fact, several in vitro and in vivo studies demonstrated that over-expression of IGF-1R and aberrant activation of Akt are associated with increased radio-resistance and favor genetic instability after a radiationinduced DNA damage, by promoting non-homologous end joining (NHEJ) repair pathway over homologous recombination (HR). This happens through the repression of Ku70/80 protein and the over-expression of MVP [46]. The inhibitory effect of wt p53 on IGF-II and Akt may thus promote tumour radioresponsiveness and prevent the onset of aberrant phenotypes due to non-specific recombination, which is one of the major limits to radiation-based therapies.
Furthermore, given the prognostic value of IGF2 in ACC, inhibition of its expression by radiation-activated p53 may be helpful in reducing ACC aggressiveness, thus lessening the probability of disease recurrence. It may also increase diseasefree and overall survival.
In conclusion, our study demonstrates that functional p53 is able to induce cell growth inhibition and apoptosis in response to radiotherapy in ACC cell lines, independently from their differentiation status and endocrine characteristics. This finding may be important for the integration of recommendations regarding radiotherapy practice suggested by Polat et al. [11], who believe that the decision on radiotherapy should be individualized in patients with localized tumours and R0 status. Therefore, we postulate that p53 status should be taken into consideration during therapeutic planning, since the presence of wild type p53 may represent a favorable predictive factor for radiotherapy in ACC cases.

Cell lines
Human adrenocortical carcinoma cell lines H295R and SW-13, ovarian adenocarcinoma cell line SK-OV-3 and prostate carcinoma-derived LNCaP cells were obtained from American Type Culture Collection (ATCC; LGC Standards Srl, Sesto San Giovanni, MI, Italy) and were cultured in the recommended media, according to standard mammalian tissue culture protocols and sterile technique.
Cells were cultured in a 37uC incubator in an atmosphere of 5% CO 2 in humidified air.

Transfection and treatment
Cells were plated in 6-well plates, 80-90% confluent, cultured 24 h and then transiently transfected with empty vector (pBABEneo) or p53 vector (pBABE-neo-p53), using FuGENE HD Transfection Reagent (Roche, Basel, Switzerland), according to manufacturer's instructions. pBABE vectors were kindly provided by Dr. Silvia Soddu and were chosen as they contain the Moloney murine leukemia virus (MMLV) Long Terminal Repeat, which has been proven to improve gene expression in a number of cell lines, compared with other internal promoters [16].
Cells were also co-transfected with a plasmid expressing Green Fluorescence Protein (pEGFP; Clontech, Saint-Germain-en-Laye, France). The ratio between pEGFP and pBABE vectors was 1:9 and transfection efficiency was evaluated by direct visualization of GFP-expressing cells by fluorescence microscopy. An estimated transfection efficiency of ,60% has been obtained.
24 h after transfection, cells were irradiated by a Varian Clinac 600 c/d 6MV photon beam with a single radiation dose of 6 Gy. In order to test the dose of choice, lower doses (4 Gy) and higher doses (8 Gy) were administered. Further analysis was performed until 72 h post transfection (48 h after irradiation).
Cell proliferation was evaluated by cell count using a haemocytometer (Sigma-Aldrich). The presence of necrosis following radiation treatment was assessed by trypan blue staining. After trypsinization, cells were suspended in DPBS 16 and mixed with equal volume of trypan blue 0,4% (Lonza), and the percentage of stained cells was then determined.

TUNEL assay
After transfection and irradiation, total cells were harvested and washed in DPBS 16. Nearly 100.000 cells per sample were centrifuged on poly-L-lysine coated coverslips and then fixed with 4% formaldehyde for 20 minutes at room temperature. Apoptosis was assessed using In Situ Cell Death Detection Kit, POD (Roche), according to manufacturer's instructions. Positive controls were incubated with 300 U DNAse for 10 minutes at room temperature. Samples were also stained with Hoechst 33342 (Sigma-Aldrich), diluted 50 ng/mL in methanol, by incubation at 37uC for 10 minutes. Fluorescence of cells was detected using an epifluorescence microscopy (Leica Microsystems Srl, Milan, Italy), using channels able to detect green fluorescence, which is typical of TUNEL-positive cells (540 nm) and blue fluorescence, emitted by Hoechst 33342 (455 nm). At least ten randomly chosen fields per sample were photographed and subsequently analysed using ImageJ software (Image Processing and Analysis in Java, version 1.39 u). Percentage of apoptosis was determined by comparing TUNEL-positive cells with total, Hoechst-stained cells. Significant differences between samples were evaluated using ANOVA and Student's t tests.

RT-PCR and Real Time RT-PCR analysis
RNA of H295R, SW-13 and SK-OV-3 cells was prepared as described in the TP53 sequencing paragraph. RT-PCR analysis of TP53, BCL2 and IGF2 expression were carried out in a 50 ml reaction volume containing 2 ml of cDNA, using the following primers: TP53 Real Time RT-PCR analysis was performed on a iCycler iQ instrument (Bio-Rad Laboratories, Hercules, CA, USA). TP53 mRNA expression levels were analysed using 25 ml of iQ SYBR Green Supermix (Bio-Rad Laboratories) and 2 ml of cDNA in a final volume of 50 ml. Samples were analysed in triplicate and relative quantification was performed by analysing the expression levels of the endogenous control GAPDH. The relative changes in TP53 gene expression were calculated with the 2 2DDCt method [47].

Western blotting analysis
After medium removal, cells were washed and scraped into PBS. Total protein extracts were obtained by suspension of cellular pellets with 70 ml of extraction buffer, sonication on ice and centrifugation at 200006g. Protein concentrations were determined by Bradford colorimetric assay (Bio-Rad Laboratories). SDS-PAGE on 10% polyacrylamide gel was performed using 50 mg of protein extracts and proteins were then transferred on a nitrocellulose membrane. Membrane was blocked for 1 hour with 5% non-fat dry milk in DPBS 16containing 0,1% Tween 20 (Bio-Rad Laboratories) at room temperature and then incubated with specific antibodies overnight at +4uC. The antibodies used were p53(DO-1) 1:500 (Santa Cruz Biotechnology, CA, USA), cyclin E 1:250 (BD Biosciences, Franklin Lakes, NJ USA), cyclin D1 1:250 (BD Biosciences), Akt-pSer473 1:400 (Santa Cruz Biotechnology), Akt 1,2,3 1:100 (Santa Cruz Biotechnology), vinculin 1:1000 (Sigma-Aldrich). The visualization of the antigens was done with enhanced chemiluminescence (ECL) detection reagents (Thermo Fisher Scientific Inc., Rockford, IL, USA) after incubation with a goat anti-mouse or goat anti-rabbit secondary antibody (Sigma-Aldrich) for 1 hour at room temperature. Quantitative analysis was performed using ImageJ software.

Statistical analysis
All values obtained are means of at least three independent experiments performed in duplicate. Results are presented as mean value 6 S.D. (standard deviation). Control and treated groups were compared using the analysis of variance (ANOVA) test; in addition, a comparison of individual treatments was also performed, using Student's t test. In all analyses, a p-value of p53 and Radiotherapy Effect in Adrenal Cancer ,0.05 was considered statistically significant. Data were processed using Assistat (version 7.6b) and Microsoft Excel software. Figure S1 Expression levels of p53 in SW-13 and LNCaP cell lines. Western blotting analysis of p53 levels in SW-13 adrenocortical carcinoma cell line (mutated p53) and LNCaP prostate carcinoma cells (wild type p53), showing a 4-fold higher expression of p53 in SW-13 cells. Bands' intensities were quantified using ImageJ, and vinculin was used for normalization (#, p,0.01). (TIF)  Figure S3 Dose-dependent effect of ionizing radiations on p53 stabilization. H295R and SW-13 cells were transfected with empty vector (mock) or p53-vector (WT) and then untreated (2IR) or treated with different doses of ionizing radiations (4, 6 and 8 Gy). Expression levels of p53 were evaluated by RT-PCR and Western blotting at 72 h after transfection (48 h after irradiation). (A) Inverted images relative to semi-quantitative RT-PCR analysis of TP53 gene expression in H295R cell line. A significant increase in mRNA levels is observable in all samples transfected with pBABE-neo-p53 vector (WT), while irradiation at different doses did not influence TP53 levels. (B) Western blotting analysis of p53 in H295R cells shows not significant variation in wt p53 expression after irradiation at a dose of 4 Gy, while ionizing radiation (IR) treatment with higher doses significantly induces p53 accumulation, indicating protein stabilization. (C) RT-PCR analysis of TP53 expression in SW-13 cell line shows mRNA overexpression in samples transfected with p53-vector (WT) compared with those transfected with empty vector (mock). No significant change in TP53 levels is observable after IR treatment. (D) The effect of IR on p53 protein levels was evaluated by Western blotting in SW-13 cell line. Low doses (4 Gy) did not induce significant changes in p53 expression compared with nonirradiated control (2IR). At higher dose (6 and 8 Gy), no effect was observed in samples transfected with empty vector (mock), while there is a significant increase in p53 levels in cells transfected with pBABE-neo-p53 (WT), consisting with the stabilization of wild type p53. Results are representative of at least three independent experiments. Bands' intensities were quantified with ImageJ software using GAPDH and vinculin for normalization. (*, p,0.05; #, p,0.01).

(TIF)
Table S1 TUNEL analysis after wt p53 over-expression and irradiation. H295R, SW-13 and SK-OV-3 cell lines were transfected with empty vector (mock) or p53-vector (WT) and subjected to ionizing radiation treatment at a dose of 6 Gy. Percentage of apoptosis was evaluated at 48 and 72 h after transfection (24 and 48 h from irradiation), by comparing TUNEL positive cells with Hoechst-positive, total, cells using ImageJ software. (DOC)