Reduced transcription of TCOF1 in adult cells of Treacher Collins syndrome patients

<p>Abstract</p> <p>Background</p> <p>Treacher Collins syndrome (TCS) is an autosomal dominant craniofacial disorder caused by frameshift deletions or duplications in the <it>TCOF1 </it>gene. These mutations cause premature termination codons, which are predicted to lead to mRNA degradation by nonsense mediated mRNA decay (NMD). Haploinsufficiency of the gene product (treacle) during embryonic development is the proposed molecular mechanism underlying TCS. However, it is still unknown if <it>TCOF1 </it>expression levels are decreased in post-embryonic human cells.</p> <p>Methods</p> <p>We have estimated <it>TCOF1 </it>transcript levels through real time PCR in mRNA obtained from leucocytes and mesenchymal cells of TCS patients (n = 23) and controls (n = 18). Mutational screening and analysis of NMD were performed by direct sequencing of gDNA and cDNA, respectively.</p> <p>Results</p> <p>All the 23 patients had typical clinical features of the syndrome and pathogenic mutations were detected in 19 of them. We demonstrated that the expression level of <it>TCOF1 </it>is 18-31% lower in patients than in controls (<it>p < 0.05</it>), even if we exclude the patients in whom we did not detect the pathogenic mutation. We also observed that the mutant allele is usually less abundant than the wild type one in mesenchymal cells.</p> <p>Conclusions</p> <p>This is the first study to report decreased expression levels of <it>TCOF1 </it>in TCS adult human cells, but it is still unknown if this finding is associated to any phenotype in adulthood. In addition, as we demonstrated that alleles harboring the pathogenic mutations have lower expression, we herein corroborate the current hypothesis of NMD of the mutant transcript as the explanation for diminished levels of <it>TCOF1 </it>expression. Further, considering that <it>TCOF1 </it>deficiency in adult cells could be associated to pathologic clinical findings, it will be important to verify if TCS patients have an impairment in adult stem cell properties, as this can reduce the efficiency of plastic surgery results during rehabilitation of these patients.</p

Induced chromosome deletions cause hypersociability and other features of Williams-Beuren syndrome in mice

The neurodevelopmental disorder Williams-Beuren syndrome is caused by spontaneous similar to 1.5 Mb deletions comprising 25 genes on human chromosome 7q11.23. To functionally dissect the deletion and identify dosage-sensitive genes, we created two half-deletions of the conserved syntenic region on mouse chromosome 5G2. Proximal deletion (PD) mice lack Gtf2i to Limk1, distal deletion (DD) mice lack Limk1 to Fkbp6, and the double heterozygotes (D/P) model the complete human deletion. Gene transcript levels in brain are generally consistent with gene dosage. Increased sociability and acoustic startle response are associated with PD, and cognitive defects with DD. Both PD and D/P males are growth-retarded, while skulls are shortened and brains are smaller in DD and D/P. Lateral ventricle (LV) volumes are reduced, and neuronal cell density in the somatosensory cortex is increased, in PD and D/P. Motor skills are most impaired in D/P. Together, these partial deletion mice replicate crucial aspects of the human disorder and serve to identify genes and gene networks contributing to the neural substrates of complex behaviours and behavioural disorders

Impact of complex NOTCH1 mutations on survival in paediatric T-cell leukaemia

<p>Abstract</p> <p>Background</p> <p>Molecular alterations occur frequently in T-ALL and the potential impact of those abnormalities on outcome is still controversial. The current study aimed to test whether <it>NOTCH1 </it>mutations and additional molecular abnormalities would impact T-ALL outcome in a series of 138 T-ALL paediatric cases.</p> <p>Methods</p> <p>T-ALL subtypes, status of <it>SIL-TAL1 </it>fusion, ectopic expression of <it>TLX3</it>, and mutations in <it>FBXW7</it>, <it>KRAS</it>, <it>PTEN </it>and <it>NOTCH1 </it>were assessed as overall survival (OS) and event-free survival (EFS) prognostic factors. OS and EFS were determined using the Kaplan-Meier method and compared using the log-rank test.</p> <p>Results</p> <p>The frequencies of mutations were 43.5% for <it>NOTCH1</it>, while <it>FBXW7</it>, <it>KRAS </it>and <it>PTEN </it>exhibited frequencies of 19.1%, 9.5% and 9.4%, respectively. In 78.3% of cases, the coexistence of <it>NOTCH1 </it>mutations and other molecular alterations was observed. In multivariate analysis no statistical association was revealed between <it>NOTCH1 </it>mutations and any other variable analyzed. The mean length of the follow-up was 68.4 months and the OS was 50.7%. <it>SIL-TAL1 </it>was identified as an adverse prognostic factor. <it>NOTCH1 </it>mutation status was not associated with outcome, while the presence of <it>NOTCH1 </it>complex mutations (indels) were associated with a longer overall survival (<it>p </it>= 0.031) than point mutations.</p> <p>Conclusion</p> <p><it>NOTCH1 </it>mutations alone or in combination with <it>FBXW7 </it>did not impact T-ALL prognosis. Nevertheless, complex <it>NOTCH1 </it>mutations appear to have a positive impact on OS and the <it>SIL-TAL1 </it>fusion was validated as a negative prognostic marker in our series of T-ALL.</p

Para que existem as regras de nomenclatura genética? Why are there rules for genetic nomenclature?

Na comunicação científica, precisamos respeitar os princípios de clareza, precisão, comunicabilidade e consistência. Para isso, existe um comitê de nomenclatura genética, cuja função é assegurar que cada gene humano tenha um nome e símbolo únicos que sejam usados consistentemente na literatura científica. Apesar dos esforços, ainda encontramos textos onde o autor se refere a um gene usando um símbolo obsoleto, ou não faz a distinção adequada entre o gene e a proteína, prejudicando a compreensão por parte do leitor. Com isso em mente, apresento uma revisão das regras de nomenclatura de genes e diversos recursos disponíveis através da Internet para encontrar os nomes adequados dos genes, enfatizando aqueles envolvidos em câncer.In scientific writings, we must strive for clarity, accuracy, objectivity, and consistency. Hence the purpose of a genetic nomenclature committee that assigns a unique name and symbol for each human gene, ensuring their unequivocal identification in the scientific literature. Despite these efforts, we still see publications using outdated symbols for genes, and authors that fail to distinguish between gene and protein in their writings. Since such mistakes can severely hinder the readers' comprehension, I present a review of gene nomenclature guidelines, and of the various Internet tools for retrieving approved gene names and symbols, highlighting those that are important in the study of cancer

Molecular analysis of the TCOF1 gene in Treacher Collins syndrome patients

A síndrome de Treacher Collins (STC) é um distúrbio do desenvolvimento craniofacial de herança autossômica dominante causada por mutações no gene TCOF1, localizado no cromossomo 5 (5q32). Utilizando as técnicas de SSCP e seqüenciamento, estabelecemos um método eficiente para a detecção de mutações no gene TCOF1, o que permitiu oferecer o teste diagnóstico aos pacientes com suspeita clínica de STC. Identificamos a mutação responsável pela síndrome em 39/43 (90,7%) dos pacientes atendidos pelo Centro de Estudos do Genoma Humano e em 23/48 (48%) dos pacientes encaminhados pelo Johns Hopkins Medical Institute. Desse modo, caracterizamos 43 novas mutações patogênicas e 16 novos polimorfismos no gene TCOF1. A detecção de uma troca de aminoácido de caráter patogênica em uma região conservada da proteína nos levou a propor a existência de um domínio funcional importante nessa região. Realizamos triagem de mutações no gene TCOF1 em 24 pacientes com anomalias faciais em estruturas derivadas do 1o e 2o arcos branquiais, mas sem diagnóstico de STC. Nenhuma mutação patogênica foi encontrada nesses casos, indicando que a STC, apesar de apresentar uma grande variabilidade clínica, é uma entidade circunscrita. Triamos também, pela primeira vez, duas famílias cujo padrão de segregação do quadro clínico sugere um padrão de herança autossômico recessivo. Também nesse caso não encontramos mutação no gene TCOF1, apesar de uma análise de segregação com marcadores da região 5q31-q34 não ter excluído essa região de uma possível relação com a síndrome. Testamos, empregando pela primeria vez ferramentas moleculares, a hipótese que as mutações esporádicas que causam a STC têm origem preferencial na linhagem germinativa de homens mais velhos. Ao contrário do sugerido pela literatura, em dez casos informativos encontramos 70% das mutações no cromossomo herdado do pai e 30% de origem materna e nenhuma correlação com aumento de idade paterna.Treacher Collins syndrome (TCS) is an autosomal dominant disorder affecting craniofacial development. The syndrome is caused by mutations in the TCOF1 gene, located in chromosome 5 (5q32). Combining SSCP and sequencing, we established an efficient method of screening for mutations in the TCOF1 gene, allowing us to offer diagnostic tests to patients with clinical signs of TCS. We detected a pathogenic mutation in 39/43 (90.7%) of patients ascertained at the Centro de Estudos do Genoma Humano and in 23/48 (48%) of patients referred to Johns Hopkins Medical Institute. We therefore characterized 43 novel pathogenic mutations and 16 novel polymorphisms in the TCOF1 gene. We described a pathogenic missense mutation located in a conserved region of the protein, which led us to propose the existence of a critical function domain in its N-terminus. After screening 24 patients with craniofacial anomalies resembling TCS but without a precise clinical diagnosis for mutations in the TCOF1 gene, we found no pathogenic mutation and concluded that, despite its broad clinical spectrum, TCS is well characterized in clinical grounds. We also screened, for the first time, two families in which the segregation of the phenotype suggested autosomal recessive inheritance. No mutation was detected in these families, despite linkage analysis with markers from 5q31-34 not excluding this region. We used molecular techniques for the first time to test the hypothesis that sporadic mutations in TCS arise preferentially in the male germ line and their frequency increases with age. As opposed to what the literature suggested, in ten informative cases we had 7 mutations of paternal origin and 3 originating in the female germ line, with no detectable age effect

Molecular analysis of the TCOF1 gene in Treacher Collins syndrome patients

A síndrome de Treacher Collins (STC) é um distúrbio do desenvolvimento craniofacial de herança autossômica dominante causada por mutações no gene TCOF1, localizado no cromossomo 5 (5q32). Utilizando as técnicas de SSCP e seqüenciamento, estabelecemos um método eficiente para a detecção de mutações no gene TCOF1, o que permitiu oferecer o teste diagnóstico aos pacientes com suspeita clínica de STC. Identificamos a mutação responsável pela síndrome em 39/43 (90,7%) dos pacientes atendidos pelo Centro de Estudos do Genoma Humano e em 23/48 (48%) dos pacientes encaminhados pelo Johns Hopkins Medical Institute. Desse modo, caracterizamos 43 novas mutações patogênicas e 16 novos polimorfismos no gene TCOF1. A detecção de uma troca de aminoácido de caráter patogênica em uma região conservada da proteína nos levou a propor a existência de um domínio funcional importante nessa região. Realizamos triagem de mutações no gene TCOF1 em 24 pacientes com anomalias faciais em estruturas derivadas do 1o e 2o arcos branquiais, mas sem diagnóstico de STC. Nenhuma mutação patogênica foi encontrada nesses casos, indicando que a STC, apesar de apresentar uma grande variabilidade clínica, é uma entidade circunscrita. Triamos também, pela primeira vez, duas famílias cujo padrão de segregação do quadro clínico sugere um padrão de herança autossômico recessivo. Também nesse caso não encontramos mutação no gene TCOF1, apesar de uma análise de segregação com marcadores da região 5q31-q34 não ter excluído essa região de uma possível relação com a síndrome. Testamos, empregando pela primeria vez ferramentas moleculares, a hipótese que as mutações esporádicas que causam a STC têm origem preferencial na linhagem germinativa de homens mais velhos. Ao contrário do sugerido pela literatura, em dez casos informativos encontramos 70% das mutações no cromossomo herdado do pai e 30% de origem materna e nenhuma correlação com aumento de idade paterna.Treacher Collins syndrome (TCS) is an autosomal dominant disorder affecting craniofacial development. The syndrome is caused by mutations in the TCOF1 gene, located in chromosome 5 (5q32). Combining SSCP and sequencing, we established an efficient method of screening for mutations in the TCOF1 gene, allowing us to offer diagnostic tests to patients with clinical signs of TCS. We detected a pathogenic mutation in 39/43 (90.7%) of patients ascertained at the Centro de Estudos do Genoma Humano and in 23/48 (48%) of patients referred to Johns Hopkins Medical Institute. We therefore characterized 43 novel pathogenic mutations and 16 novel polymorphisms in the TCOF1 gene. We described a pathogenic missense mutation located in a conserved region of the protein, which led us to propose the existence of a critical function domain in its N-terminus. After screening 24 patients with craniofacial anomalies resembling TCS but without a precise clinical diagnosis for mutations in the TCOF1 gene, we found no pathogenic mutation and concluded that, despite its broad clinical spectrum, TCS is well characterized in clinical grounds. We also screened, for the first time, two families in which the segregation of the phenotype suggested autosomal recessive inheritance. No mutation was detected in these families, despite linkage analysis with markers from 5q31-34 not excluding this region. We used molecular techniques for the first time to test the hypothesis that sporadic mutations in TCS arise preferentially in the male germ line and their frequency increases with age. As opposed to what the literature suggested, in ten informative cases we had 7 mutations of paternal origin and 3 originating in the female germ line, with no detectable age effect

Treacher Collins syndrome: clinical, genetic and molecular aspects

A síndrome de Treacher Collins (STC) é um distúrbio do desenvolvimento craniofacial de herança autossômica dominante que afeta cerca de 1 em 50.000 recém-nascidos, sendo que aproximadamente 60% dos casos são resultantes de mutações novas. A grande variabilidade observada no quadro clínico pode dificultar o diagnóstico, principalmente nos casos mais leves. Desde a identificação do gene responsável pela síndrome em 1996, já foram identificados diversos defeitos moleculares que causam a STC, a maioria dosquais são específicos para cada família, o que torna o exame de detecção de mutações bastante trabalhoso. Contudo, nos casos em que há dúvida de diagnóstico, a realização dos testes moleculares é extremamente importante. Apesar dos avanços na caracterização molecular desta doença, ainda não é possível explicar a grande variabilidade clínica observada entre os pacientes, inclusive dentro de uma mesma família. A identificação de fatores que contribuem para determinar a gravidade do quadro clínico será possivelmente omaior desafio no estudo molecular da STC, e certamente trará facilitará o aconselhamento genético para as famílias de afetados.Treacher Collins syndrome (TCS) is an autosomal dominant defect in craniofacial development affecting approximately 1150.000 newborns. Roughly 60% of cases are due to nove1 mutations. Marked clinical variability can make diagnosis difficult sometimes, especially when the patient is mildly affected. Ever since the identification of the gene associated with the syndrome in 1996, a number of different mutations causing TCS has been described. Most of these mutations are farnily-specific, mahng the screening of rnutations labor intensive but, nonetheless, extremely useful when the clinical diagnosis is uncertain. Despite recent advances in the molecular characterization of TCS, the causes of the great clinical variability observed even within members of a same family remain unknown. Identifying factors that contribute to the severity of the syndrome will probably be a major challenge for researchers on TCS, and will certainly improve genetic counseling to the families