ABSTRACT
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Air Conditioning , Bacterial Proteins/genetics , DNA-Directed RNA Polymerases/genetics , Francisella , Flavoproteins/genetics , Water Microbiology , Base Sequence , China , DNA, Bacterial/genetics , DNA, Ribosomal/genetics , Francisella/classification , Francisella/genetics , Francisella/isolation & purification , Molecular Sequence Data , Molecular Typing , Phylogeny , /genetics , Sequence Analysis, DNAABSTRACT
Variegate porphyria (VP) results from a hereditary deficiency of protoporphyrinogen oxidase (PPOX) that is transmitted in an autosomal dominan fashion. The diagnosis is based on the clinical symptoms and is confirmed biochemically. Sometimes, however, these diagnostic tools reveal limitations in establishing the definitive diagnosis of the prevailing type of acute porphyria. In these patients, molecular genetic analyses can be useful. We performed molecular genetic studies in 13 Chilean families by PCR amplification of the PPOX gene, conformation sensitive gel electrophoresis, and automated DNA sequencing. In five symptomatic patients from different families, respectively, the biochemical data confirmed the diagnosis of VP. In seven other families, however, the biochemical studies were not conclusive. Furthermore, the original biochemical analysis in one clinically severely affected patient from a further family even suggested the diagnosis of erythropoietic protoporphyria (EPP). Beside the respective index patients, we studied 78 asymptomatic family members and 50 healthy, unrelated individuals for control purposes. In five families, the previous diagnosis of VP could be confirmed genetically. Further, half of the asymptomatic relatives revealed a mutation in the PPOX gene, consisting of three missense mutations and two deletion mutations. Mutation R168H that had been already described previously in German VP families was found in a Chilean family of German origin. Further, two novel missense mutations, designated L74P and G232S, could be detected. In four Chilean families, we found the deletion 1330deICT that had also been previously described in three Swedish VP families. The second deletion, 1239delTACAC, has not been described anywhere else but Chile and could be identified in seven families. One patient who was initially diagnosed with EPP turned out to be a compound heterozygote for mutations on both alíeles of the PPOX gene. In conclusion, our molecular genetic analyses unequivocally confirmed the diagnosis of VP in seven families who originally had revealed inconclusive biochemical data. Further, early genetic analysis allows for the identification of asymptomatic mutation carriers, thereby offering the possibility of adequate counselling and the prevention of potentially life-threatening acute porphyric attacks.
La porfiria variegata (PV), enfermedad de origen genético con forma de herencia autosómica dominante, se debe a deficiencia en la actividad protoporfirinógeno oxidasa (PPOX). Su diagnóstico se basa en antecedentes clínicos y se confirma con análisis bioquímicos. Éstos, en algunos casos, pueden presentar limitaciones para establecer el diagnóstico definitivo de la variedad de porfiria aguda, situación en que el estudio genético molecular puede resultar útil. Se efectuó estudio genético en trece familias chilenas usando amplificación del gen PPOX por PCR, electroforesis conformacional y secuenciación automática de DNA. Cinco de estas familias incluían pacientes índices sintomáticos con diagnóstico bioquímico establecido de PV; otras siete familias incluían pacientes índices con estudio bioquímico no concluyente de la variedad de porfiria aguda y, finalmente, una familia con diagnóstico previo de protoporfiria eritropoyética (PPE). Además, se estudiaron 78 familiares asintomáticos y 50 personas sanas, no relacionadas, como controles. En cinco familias el estudio genético confirmó el diagnóstico bioquímico previo de PV. El 50% de los familiares asintomáticos resultaron ser portadores de una mutación en el gen PPOX. Se identificaron tres mutaciones por sustitución de bases: la R168H, descrita en familias de origen alemán y dos nuevas mutaciones, designadas L74P y G232S. También se identificaron dos mutaciones por deleción de bases designadas 1330delCT y la 1239delTACAC. La primera, que había sido descrita previamente en tres familias suecas, se encontró en cuatro familias chilenas. La segunda se encontró en siete familias y no ha sido descrita previamente. El estudio genético permitió mostrar que un paciente que originalmente fue diagnosticado con PPE correspondía a un heterocigoto compuesto para dos mutaciones en el gen PPOX. En conclusión, los estudios moleculares permitieron confirmar el diagnóstico de PV en cinco familias, efectuar diagnóstico de PV en familias en las cuales los datos bioquímicos no eran concluyentes, corregir el diagnóstico original en una familia e identificar portadores asintomáticos entre los familiares de los pacientes índices. Los estudios genéticos moleculares ayudan a realizar un adecuado consejo genético a pacientes y familiares y hace posible practicar prevención de las crisis agudas de porfiria, las que son potencialmente mortales.
Subject(s)
Humans , Porphyria, Variegate/genetics , Protoporphyrinogen Oxidase/genetics , Chile , Flavoproteins/genetics , Genetic Predisposition to Disease , Mutation , Mitochondrial Proteins/genetics , Porphyria, Variegate/diagnosis , Porphyria, Variegate/enzymologyABSTRACT
The high birth frequency of Down syndrome (DS), trisomy 21 (T21), has been a subject of interest to the clinicians and researchers due to its complexity in phenotypic expression. In addition to the maternal age, identification of the mechanistic basis for T21 requires an understanding of the cellular-molecular events and other biochemical pathways that could promote maternal meiotic nondisjunction. Recent studies have linked the increased frequency of polymorphism of methylenetetrahydrofolate reductase (MTHFR, C677T) and methionine synthase gene (MTRR, A66G) in mothers with DS child. Based on evidence that abnormal folate and methyl metabolism can lead to DNA hypomethylation and abnormal chromosomal segregation, researchers have observed that mothers with mutation in MTHFR (C677T) and MTRR (A66G) gene have elevated levels of plasma homocysteine. This was found to be associated with a 2.6 to 2.9 fold increased risk of having child with DS compared to mothers without the mutation. Subsequent studies evaluating Italian, Irish, French, and Indian-Gujarati women could not demonstrate an association of MTHFR gene polymorphism in mothers with DS child. However, the Irish study did find an increased risk of DS associated with the MTRR polymorphism and an interactive effect of MTRR and MTHFR polymorphisms with increased risk. Interestingly, an increase in plasma homocysteine was found to be a risk factor for DS in several of the studies. Despite the differences, the published studies suggest a common theme of abnormal folate metabolism associated with increased risk of having a child with DS. These observations suggest that there seems to be a geographic variation in gene polymorphism and it could not be attributable to meiotic nondysjunction in all mothers with DS child but increased homocysteine in all different study group does suggest that there may be a gene-nutritional or gene-gene or gene-nutritional-environmental factors involved in increased frequency of meiotic nondisjunction which needs transnational and multinational study design.