Increased Transactivation Associated with SOX3 Polyalanine Tract Deletion in a Patient with Hypopituitarism

Backgound and Aims: Correct gene dosage of SOX3 is critical for the development of the hypothalamo-pituitary axis. Both overdosage of SOX3, as a result of gene duplication, and loss of function resulting from expansion of the first polyalanine (PA) tract are associated with variable degrees of hypopituitarism, with or without mental retardation. The aim of this study was to further investigate the contribution of SOX3 in the etiology of hypopituitarism and the mechanisms involved in the phenotypic variability. Methods: We screened 154 patients with congenital hypopituitarism and an undescended posterior pituitary for mutations in SOX3 and variability in the length of the first PA tract. In addition, 300 patients with variable septooptic dysplasia were screened for variability of the PA tract. Results: We report a novel 18-base pair deletion (p.A243_A248del6, del6PA) in a female patient with hypopituitarism resulting in a 2-fold increase in transcriptional activation in vitro, compared with wild-type SOX3. We also identified a previously reported seven-alanine expansion (p.A240_A241ins7, +7PA) in two male siblings with isolated GH deficiency and a distinct phenotype, in addition to the nonsynonymous variant p.R5Q in an unrelated individual; this appears to have no functional effect on the protein. In contrast to +7PA, del6PA maintained its ability to repress beta-catenin mediated transcription in vitro. Conclusion: This is the first study to report that PA tract deletions associated with hypopituitarism have functional consequences in vitro, possibly due to increased activation of SOX3 target genes. In addition, we have expanded the phenotypic spectrum associated with PA tract expansion (+7PA) mutations to include panhypopituitarism or isolated GH deficiency, with or without mental retardation. (J Clin Endocrinol Metab 96: E685-E690, 2011)

Alternative generation of CNS neural stem cells and PNS derivatives from neural crest-derived peripheral stem cells

Neural crest-derived stem cells (NCSCs) from the embryonic peripheral nervous system (PNS) can be reprogrammed in neurosphere (NS) culture to rNCSCs that produce central nervous system (CNS) progeny, including myelinating oligodendrocytes. Using global gene expression analysis we now demonstrate that rNCSCs completely lose their previous PNS characteristics and acquire the identity of neural stem cells derived from embryonic spinal cord. Reprogramming proceeds rapidly and results in a homogenous population of Olig2-, Sox3-, and Lex-positive CNS stem cells. Low-level expression of pluripotency inducing genes Oct4, Nanog, and Klf4 argues against a transient pluripotent state during reprogramming. The acquisition of CNS properties is prevented in the presence of BMP4 (BMP NCSCs) as shown by marker gene expression and the potential to produce PNS neurons and glia. In addition, genes characteristic for mesenchymal and perivascular progenitors are expressed, which suggests that BMP NCSCs are directed toward a pericyte progenitor/mesenchymal stem cell (MSC) fate. Adult NCSCs from mouse palate, an easily accessible source of adult NCSCs, display strikingly similar properties. They do not generate cells with CNS characteristics but lose the neural crest markers Sox10 and p75 and produce MSC-like cells. These findings show that embryonic NCSCs acquire a full CNS identity in NS culture. In contrast, MSC-like cells are generated from BMP NCSCs and pNCSCs, which reveals that postmigratory NCSCs are a source for MSC-like cells up to the adult stage.

Genome-wide methylation and transcriptome analysis in penile carcinoma: uncovering new molecular markers

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Comprehensive genome methylation and whole genome expression analysis in penile carcinoma: Uncovering new molecular markers

Background: Penile carcinoma (PeCa) is frequently associated with high morbidity rates. Unlikely of the vast majority of tumors, there is no molecular markers described that are able to assist in diagnosis and prognosis or with potential to be therapeutic targets in PeCa. Patients and methods: DNA methylation status (244K Human DNA Methylation Microarray platform, Agilent Technologies) and large-scale expression analysis (4x44K Whole Human Genome Microarray, Agilent Technologies) were performed in 35 and 37 PeCa, respectively. Quantitative bisulfite pyrosequencing (qBP) and RT-qPCR were used to validate the findings in 93 samples. HPV status was assessed using the Linear Array HPV Genotyping kit (Roche Molecular Diagnostics, CA, USA). Results: Methylome analysis revealed 171 hypermethylated and 449 hypomethylated CpGs sites and the transcriptome profiling showed 2986 down- and 2817 over-expressed genes. HPV positivity was found in 32.7% of the cases, mainly the HPV16. The integrative analysis in 32 PeCa revealed a panel of 96 genes with inverse correlation between methylation and gene expression levels. The CpG hypermetlylation and gene downexpression, was confirmed for TWIST1, RSOP2, SOX3, SOX17, CD133, OTX2, HOXA3 and MEIS. In addition, BIRC5, DNMT1 and DNMT3B presented low levels of methylation and overexpression. The comparison of the results with clinical findings revealed that LIN28A, NKX2.2, NKX2.3, LHX5, BDNF, FOXA1 and CDX2 were associated with poor prognosis features. Conclusion: Putative prognostic markers were detected revealing that DNA methylation modulates the expression of several genes in PeCa. These data may prove instrumental for biomarker discovery in clinics and molecular epidemiology of PeCa.

Studio di Mutazioni Geniche e Variazioni Copy-Number implicate nel deficit combinato degli Ormoni Ipofisari(CPHD)

La crescita normale di un individuo è il risultato dell’azione coordinata di molteplici ormoni e recettori codificati da geni e a tal proposito, discreto interesse è stato dato ai geni tipici dell’asse del GH. Tuttavia altri geni, più a monte di questi e responsabili dello sviluppo dell’ipofisi contribuiscono alla crescita normale o patologica. Alcuni geni studiati sono POU1F1, PROP1, LHX3, LHX4, HESX1, SOX3 e svariate loro mutazioni sono state identificate come causa di panipopituarismo (CPHD=Combined Pituitary Hormone Deficiency). In realtà la ricerca genetica non spiega ancora molte anomalie ipofisarie e molte mutazioni devono ancora essere identificate. Uno degli scopi del dottorato, svoltosi nel laboratorio di Genetica molecolare di Pediatria, è stata l’identificazione di mutazioni geniche da un gruppo di pazienti CPHD considerando in particolare i geni POU1F1, LHX3, SOX3, non ancora messi a punto presso il laboratorio. L’approccio sperimentale si è basato sulle seguenti fasi: prelievo delle informazioni di sequenza da GeneBank, progettazione di primers per amplificare le porzioni esoniche, messa a punto delle fasi della PCR e del sequenziamento, analisi della sequenza e confronto con le informazioni di sequenza depositate allo scopo di rintracciare eventuali mutazioni o varianti. La bassa percentuale di mutazioni in questi geni non ha permesso finora di rintracciare mutazioni nelle porzioni esoniche salvo che in un soggetto, nell’esone 6 di LHX3b (nuova mutazione, recessiva eterozigote, c.1248A>G implicata nella mutazione p.T377A della sequenza proteica). Un metodo di screening di questa mutazione impiegando l’enzima di restrizione SacII è stato usato, senza rilevare nessun altra occorrenza dell’allele mutato in 53 soggetti di controllo. Oltre alla messa a punto del sequenziamento e di alcune tecniche di analisi di singoli SNP o piccoli INDELs per i 3 geni, la ricerca svolta è stata orientata all’impiego di metodi di rilevamento di riarrangiamenti genetici comportanti ampie delezioni e/o variazioni del copy-number di esoni/interi geni detto MLPA (Multiplex Ligation-dependent Probe Amplification) e progettato da MRC-Holland. Il sequenziamento infatti non permette di rilevare tali alterazioni quando sono ampie ed in eterozigosi. Per esempio, in un’ampia delezione in eterozigosi, l’intervallo delimitato dai primers usati per la PCR può non includere totalmente la porzione interessata da delezione su un cromosoma cosicché la PCR ed il sequnziamento si basano solo sulle informazioni dell’altro cromosoma non deleto. Un vantaggio della tecnica MLPA, è l’analisi contemporanea di una quarantina di siti posti su svariati geni. Questa metodo tuttavia può essere affetto da un certo margine di errore spesso dipendente dalla qualità del DNA e dovrebbe essere affiancato e validato da altre tecniche più impegnativa dal punto di vista sperimentale ma più solide, per esempio la Real Time PCR detta anche PCR quantitativa (qPCR). In laboratorio, grazie all’MLPA si è verificata la condizione di delezione eterozigote di un paziente “storico” per il gene GH1 e la stessa mutazione è stata rilevata anche con la qPCR usando lo strumento Corbett Rotor Gene 6000 (Explera). Invece un’analisi solo con la qPCR di variazioni del copy-number (CNV) per SOX3 in pazienti maschili non ha ancora evidenziato anomalie. Entrambe le tecniche hanno aspetti interessanti, il miglior approccio al momento sembra un’analisi iniziale di pazienti con l’MLPA, seguita dalla verifica di un eventuale esito anomalo impiegando la real-time PCR.

The human sex-reversing ATRX gene has a homologue on the marsupial Y chromosome, ATRY: Implications for the evolution of mammalian sex determination

Mutations in the ATRX gene on the human X chromosome cause X-linked α-thalassemia and mental retardation. XY patients with deletions or mutations in this gene display varying degrees of sex reversal, implicating ATRX in the development of the human testis. To explore further the role of ATRX in mammalian sex differentiation, the homologous gene was cloned and characterized in a marsupial. Surprisingly, active homologues of ATRX were detected on the marsupial Y as well as the X chromosome. The Y-borne copy (ATRY) displays testis-specific expression. This, as well as the sex reversal of ATRX patients, suggests that ATRY is involved in testis development in marsupials and may represent an ancestral testis-determining mechanism that predated the evolution of SRY as the primary mammalian male sex-determining gene. There is no evidence for a Y-borne ATRX homologue in mouse or human, implying that this gene has been lost in eutherians and its role supplanted by the evolution of SRY from SOX3 as the dominant determiner of male differentiation.

46,XX doença do desenvolvimento sexual testicular : a propósito de um caso clínico

Trabalho Final do Curso de Mestrado Integrado em Medicina, Faculdade de Medicina, Universidade de Lisboa, 2014

Epigenetic regulation in neural crest development : role of DNA methyltransferases 3A and 3B

The neural crest is a group of migratory, multipotent stem cells that play a crucial role in many aspects of embryonic development. This uniquely vertebrate cell population forms within the dorsal neural tube but then emigrates out and migrates long distances to different regions of the body. These cells contribute to formation of many structures such as the peripheral nervous system, craniofacial skeleton, and pigmentation of the skin. Why some neural tube cells undergo a change from neural to neural crest cell fate is unknown as is the timing of both onset and cessation of their emigration from the neural tube. In recent years, growing evidence supports an important role for epigenetic regulation as a new mechanism for controlling aspects of neural crest development. In this thesis, I dissect the roles of the de novo DNA methyltransferases (DNMTs) 3A and 3B in neural crest specification, migration and differentiation. First, I show that DNMT3A limits the spatial boundary between neural crest versus neural tube progenitors within the neuroepithelium. DNMT3A promotes neural crest specification by directly mediating repression of neural genes, like Sox2 and Sox3. Its knockdown causes ectopic Sox2 and Sox3 expression at the expense of neural crest territory. Thus, DNMT3A functions as a molecular switch, repressing neural to favor neural crest cell fate. Second, I find that DNMT3B restricts the temporal window during which the neural crest cells emigrate from the dorsal neural tube. Knockdown of DNMT3B causes an excess of neural crest emigration, by extending the time that the neural tube is competent to generate emigrating neural crest cells. In older embryos, this resulted in premature neuronal differentiation. Thus, DNMT3B regulates the duration of neural crest production by the neural tube and the timing of their differentiation. My results in avian embryos suggest that de novo DNA methylation, exerted by both DNMT3A and DNMT3B, plays a dual role in neural crest development, with each individual paralogue apparently functioning during a distinct temporal window. The results suggest that de novo DNA methylation is a critical epigenetic mark used for cell fate restriction of progenitor cells during neural crest cell fate specification. Our discovery provides important insights into the mechanisms that determine whether a cell becomes part of the central nervous system or peripheral cell lineages.