Irene Forno

The Primary Occurrence of BRAFV600E Is a Rare Clonal Event in Papillary Thyroid Carcinoma

CONTEXT BRAF(V600E) is considered a primary event, a negative prognostic marker, and a site for pharmacological intervention in papillary thyroid carcinoma (PTC). We asked whether BRAF(V600E) can occur as a subclonal event in PTC and whether this and other oncogenes can coexist in the same tumor. STUDY DESIGN We determined by pyrosequencing the percentage of mutant BRAF, NRAS, and KRAS alleles in a series of conventional PTC. We also analyzed the BRAF mutation status in PTC cell clones in culture. RESULTS BRAF(V600E) alleles were present in 41 of 72 PTC (56.9%) in the range 44.7 to 5.1% of total BRAF alleles. In four PTC samples, mutant BRAF alleles were about 50%, being therefore compatible with a clonal heterozygous mutation. In 27 PTC samples, BRAF(V600E) alleles were in the range of 25 to 5.1%. This finding was confirmed after exclusion of the presence of a large contamination by lymphoreticular cells and by the analysis of PTC cells selected by laser capture. Analysis of clones derived from a single cell confirmed the presence of two distinct PTC populations with wild-type or mutated BRAF. Simultaneous subclonal BRAF and KRAS mutations were demonstrated in two PTC. CONCLUSIONS These data demonstrate that clonal BRAF(V600E) is a rare occurrence in PTC, although frequently this cancer consists of a mixture of tumor cells with wild-type and mutant BRAF. These results suggest that BRAF mutation in PTC is a later subclonal event, its intratumoral heterogeneity may hamper the efficacy of targeted pharmacotherapy, and its association with a more aggressive disease should be reevaluated.

A High Percentage of BRAFV600E Alleles in Papillary Thyroid Carcinoma Predicts a Poorer Outcome

CONTEXT BRAF(V600E) is considered a negative prognostic marker in papillary thyroid carcinoma (PTC), but unexplained conflicting results are present in the literature. In light of the new finding that most PTC consist of a mixture of tumor cells with wild-type and mutant BRAF, we examined the associations between the percentage of BRAF(V600E) alleles and both the clinicopathological parameters at time of diagnosis and the disease outcome in a large series of PTCs. STUDY DESIGN Tumors from 168 patients with PTC were genotyped for BRAF(V600E) using BigDye Terminator sequencing and pyrosequencing, and the clinical parameters were analyzed. The associations between clinicopathological characteristics, including disease recurrence at follow-up (median 5.1 yr) and the percentage of mutant BRAF alleles were assessed. RESULTS The observed prevalence of BRAF(V600E) was higher when using pyrosequencing then when using BigDye Terminator sequencing (53.6 vs. 36.9%). In the PTC positive for BRAF(V600E), the percentage of mutant alleles ranged from 5.1 to 44.7% of the total BRAF alleles, with a median of 20.6%. The presence or the percentage of BRAF(V600E) alleles did not correlate significantly with sex, multicentricity, lymph node metastasis, or tumor stage. The percentage of BRAF(V600E) alleles directly correlated with age at diagnosis and tumor volume (R(2) = 0.223, P = 0.039, and R(2) = 0.166, P < 0.001, respectively). The percentage of BRAF(V600E) alleles (P = 0.014), tumor volume (P = 0.012), and lymph node metastasis (P = 0.008) predicted the disease outcome. The odds ratio of recurrence for PTC with BRAF(V600E) alleles of 30% or greater, compared with that for PTC with BRAF(V600E) alleles of less than 30%, was 5.31 (P = 0.002). CONCLUSIONS A high percentage of BRAF(V600E) alleles defines a PTC molecular subtype and predicts a poorer disease outcome. The analysis of BRAF mutations by pyrosequencing is useful to refine the risk stratification of patients with PTC.

The microRNA cluster C19MC is deregulated in parathyroid tumours.

A subset of over-expressed microRNAs (miRNAs) identified in parathyroid carcinomas (Ca) compared to normal glands belongs to C19MC, a cluster on chromosome 19q13.4 involved in stem cell biology and tumourigenesis. In this study, the expression of C19MC-MIR371-3 clusters and the molecular mechanisms presiding their modulation were investigated in a series of six normal parathyroids, 24 adenomas (Ad), 15 Ca and five matched metastases. The general expression levels of C19MC or MIR371-3 clusters in Ad lesions did not differ from normal glands, while they distinguished Ad from Ca at unsupervised hierarchical cluster analysis (P=0.0008). MIR517C showed the most significant difference in expression between Ca and Ad (P=0.0003) and it positively correlated with serum calcium, parathormone and tumour weight. In regard to the molecular mechanism determining C19MC cluster activation, we could detect C19MC copy number (CN) gain in ten Ca (67%) extending distal to the MIR371-3 cluster in almost all samples. Conversely, only four Ad (16%) showed C19MC amplification, with one case presenting distal genomic aberration to MIR371-3. Globally, CN variations of 19q13.4 loci were significantly associated with MIR517C up-regulation (P=0.006). Opposite to normal glands where C19MC promoter was methylated, hypomethylation occurred in 15 out of 30 analysed tumours. Though the epigenetic status did not correlate with C19MC miRNA expression levels, loss of C19MC promoter methylation was significantly associated with Ca and metastatic disease (P=0.01). In conclusion, C19MC cluster aberrations are a characteristic of Ca with respect to Ad. Altogether, these evidences point towards a role for 19q13.4 miRNA clusters as oncogenes in parathyroid tumourigenesis.

Epigenetic alterations in human parathyroid tumors

Abstract Epigenetics alterations are involved in tumorigenesis and have been identified in endocrine neoplasia. In particular, DNA methylation, microRNAs deregulations and histone methylation impairment are detected in tumors of the parathyroid glands. Parathyroid tumors are the second most common endocrine neoplasia following thyroid cancer in women, and it is associated with primary hyperparathyroidism, a disease sustained by PTH hypersecretion. Despite the hallmark of global promoter hypomethylations was not detectable in parathyroid tumors, increase of hypermethylation in specific CpG islands was detected in the progression from benign to malignant parathyroid tumors. Furthermore, deregulation of a panel of embryonic-related microRNAs (miRNAs) was documented in parathyroid tumors compared with normal glands. Impaired expression of the histone methyltransferases EZH2, BMI1, and RIZ1 have been described in parathyroid tumors. Moreover, histone methyltransferases have been shown to be modulated by the oncosuppressors HIC1, MEN1, and HRPT2/CDC73 gene products that characterize tumorigenesis of parathyroid adenomas and carcinomas, respectively. The epigenetic scenario in parathyroid tumors have just began to be decoded but emerging data highlight the involvement of an embryonic gene signature in parathyroid tumor development.

Deregulation of MiR-34b/Sox2 Predicts Prostate Cancer Progression.

Most men diagnosed with prostate cancer will have an indolent and curable disease, whereas approximately 15% of these patients will rapidly progress to a castrate-resistant and metastatic stage with high morbidity and mortality. Therefore, the identification of molecular signature(s) that detect men at risk of progressing disease remains a pressing and still unmet need for these patients. Here, we used an integrated discovery platform combining prostate cancer cell lines, a Transgenic Adenocarcinoma of the Mouse Prostate (TRAMP) model and clinically-annotated human tissue samples to identify loss of expression of microRNA-34b as consistently associated with prostate cancer relapse. Mechanistically, this was associated with epigenetics silencing of the MIR34B/C locus and increased DNA copy number loss, selectively in androgen-dependent prostate cancer. In turn, loss of miR-34b resulted in downstream deregulation and overexpression of the “stemness” marker, Sox2. These findings identify loss of miR-34b as a robust biomarker for prostate cancer progression in androgen-sensitive tumors, and anticipate a potential role of progenitor/stem cell signaling in this stage of disease.

MicroRNAs in parathyroid physiopathology

Parathyroid glands regulate calcium homeostasis through synthesis and secretion of parathormone (PTH). They sense the extracellular calcium concentration through the G-protein coupled calcium sensing receptor (CASR) and release PTH in order to preserve calcium concentration in the physiological range. Tumors of the parathyroid glands are common endocrine neoplasia associated with primary or secondary/tertiary hyperparathyroidisms. Small non-coding RNAs are regulators of gene expression able to modulate hormone synthesis, hormone release and endocrine cell proliferation. In this scenario, microRNA (miRNA) expression profiles have been investigated in parathyroid tumors, while miRNAs are involved in hypocalcemia and uremia-induced PTH release from normal parathyroid cells. Here we reviewed data about the role of miRNAs in the regulation of: 1) PTH synthesis and secretion; 2) CASR expression; 3) parathyroid cell tumorigenesis. Though studies about miRNAs in parathyroid gland pathophysiology are limited, they contribute in elucidating regulatory pathways involved in PTH release and parathyroid cell tumorigenesis.

MicroRNA deregulation in parathyroid tumours suggests an embryonic signature.

Primary hyperparathyroidism is a common endocrine disorder caused by abnormal tumour parathyroid cell proliferation. Parathyroid tumours show a great variability both in clinical features, such as the severity of PTH secretion, the rate and the pattern of cell proliferation, and genetic background. Studies aiming to develop new diagnostic markers and therapeutic approaches need a deeper definition of this variability. Dysregulation of microRNAs (miRNAs) has been shown to play an essential role in the development and progression of cancer. MiRNAs are small noncoding RNAs that inhibit the translation and stability of messenger RNAs (mRNAs). Here, data about the miRNA expression pattern in parathyroid normal and tumour glands were reviewed. Though available data in parathyroid tumours are very limited, the expression pattern of a subset of specific miRNAs clearly discriminated parathyroid carcinomas from normal parathyroid glands and, more clinically relevant, from parathyroid adenomas. Investigation showed that parathyroid tumours were characterized by an embryonic expression pattern of miRNAs such as miR-296, or the miRNA clusters C19MC and miR-371-3, typically in stem cells committed to differentiation or during human embryonic development, respectively. Further, miRNA profiles were correlated with tumour aggressive behaviour. Moreover, the interaction with the oncosuppressor menin suggests that miRNAs might modulate the function of the known oncosuppressors or oncogenes involved in parathyroid tumourigenesis and thus overseeing the tumour phenotype. In conclusion, miRNAs might provide new diagnostic markers and new therapeutic approaches by developing molecular miRNA-targeted therapies for the cure of parathyroid tumours, whose unique option is surgery.

PO-450 Interplay between coding and non-coding genome in human parathyroid tumours

Introduction Parathyroid tumours are the second most common endocrine neoplasia in women, after thyroid cancer. Mutations in the oncosuppressor CDC73 are the key event in most carcinomas whereas alterations in the tumour suppressor MEN1 (located at 11q13.1) occur in up to a third of sporadic adenomas. Although lncRNAs play a regulatory role in endocrine cancer pathogenesis, a lncRNAs profiling in human parathyroid tumours is still missing. Here, we identified a ‘molecular signature’ able to distinguish among parathyroid histotypes and a new potential epigenetic role of MEN1 in lncRNAs regulation. Material and methods Ninety lncRNAs were investigated in 4 parathyroid carcinomas (PCas), 12 adenomas (PAds) and 2 normal glands (PaNs). Hierarchical clustering (HCL) and Significance Analysis of Microarray (SAM) were performed to identify differences in lncRNAs expression. Significant lncRNAs were validated in additional 7 PCas, 26 PAds, 6 atypical PAds (aPAds) and 4 PaNs. CDC73 and MEN1 genes mutations were detected by Sanger sequencing. PAds genomic characterisation was obtained by array Comparative Genomic Hybridization (aCGH). HEK293 cells were transiently silenced for MEN1 expression to analyse MEN1-lncRNAs correlation. Results and discussions Nine lncRNAs were identified as differentially expressed in parathyroid tissues. Specifically, KCNQ1OT1 and SNHG6 were enriched in PaNs, reduced HAR1B, MEG3, HOXA3as and NEAT1 expression characterised PAds, whereas BC200, HOXA6as and WT1-AS were upregulated in PCas. HCL identified 3 clusters in which PaNs and PCas were distinctly separated, while aPAds were closer to PCas. Moreover, PAds clustered in a highly heterogeneous way. Notably, PCas and aPAds harbouring CDC73-mutations overexpressed the majority of the lncRNAs, compared to CDC73 wild-type samples. Interestingly, BACE1-AS, KCNQ1OT1, NEAT1 and SNHG6 levels in PAds were positively correlated with MEN1 levels. aCGH analysis revealed that Chr11 loss of heterozygosity (LOH) was the main chromosomal aberration in PAds. Of note, Chr11 LOH was associated with significant HAR1B upregulation and these data were confirmed in HEK293 cells knocked-down for MEN1. Conclusion Parathyroid histotypes are characterised by different lncRNAs signatures, suggesting a correlation with tumour aggressiveness and pathogenetic mechanisms. Further, our data highlight that lncRNAs profiles are related to CDC73 gene mutation status, chromosome 11 derangements and MEN1 inactivation.

Hibernation in Unusual Places: A Pure Typical Hibernoma of the Breast

than 0.8–2 kg, and being disproportionate with the other parts of body. Onset of the disease is usually in first trimester, although it may be in the second and third trimester of pregnancy. It is usually bilateral, but unilateral cases also were reported. The etiology is controversial. Increased level of hormones such as prolactin and estrogen or hypersensitivity of breast receptor has been considered, but antihormone therapies are not consistently effective. Liver failure and decreased hormone metabolism, malignancies, and immunologic and rheumatoid disorders have been implicated, although these are not documented. Some choices are considered for treating this disorder such as Bromocriptine, termination of pregnancy and surgery. Reduction mammoplasty and simple mastectomy are the available options.