Ayudas diagnósticas y diagnóstico diferencial de la enfermedad de Pompe / Diagnostic aids and differential diagnosis of Pompe disease

Introducción: La enfermedad de Pompe (EP) o glucogenosis tipo II es una enfermedad autosómica recesiva causada por mutaciones en el gen GAA que codifica para la proteína alfa-1,4-glucosidasa. Su deficiencia lleva a un almacenamiento anormal de glucógeno en los lisosomas de varias células, a través de los diferentes tejidos, lo que causa un compromiso musculoesquelético predominante. Contenidos: Los fenotipos de la enfermedad dependen de las variantes genéticas y de los niveles de la actividad enzimática residual. La enfermedad se presenta como EP de inicio infantil, EP de inicio tardío y EP intermedio, por lo que es de suma importancia su diagnóstico temprano, por medio de estudios moleculares como la secuenciación de Sanger y la secuenciación de nueva generación. Conclusiones: Se ha demostrado, mediante diferentes estudios, que las variaciones genéticas pueden diferir entre etnias, y es importante su caracterización molecular para determinar el tratamiento más adecuado, de acuerdo con el estado del material inmunológico de reacción cruzada (CRIM).

Introduction: Pompe disease (PD) or Glycogenosis Type II is a rare autosomal recessive disease caused by mutations in the GAA gene that codes for the alpha-1,4-glucosidase protein. Its deficiency leads to abnormal glycogen storage in the lysosomes of various cells throughout the different tissues causing a predominant musculoskeletal compromise. Contents: The phenotypes of the disease depend on the genetic variants and the levels of residual enzyme activity, presenting as infantile-onset PD, late-onset PD, and intermediate PD; Therefore, early diagnosis of the disease through molecular studies such as Sanger sequencing and new generation sequencing is of utmost importance. Conclusions: It has been shown through different studies that genetic variations can vary between ethnic groups and the molecular characterization of the variants is important to determine the most appropriate treatment depending on the state of the cross-reactive immunological material (CRIM)

Enfermedad de Pompe: historia, epidemiología, fisiopatología y manifestaciones clínicas / Pompe's disease: History, epidemiology, pathophysiology and clinical manifestations

Introducción: La enfermedad de Pompe o glucogenosis tipo II pertenece al grupo de las miopatías metabólicas y es producida por la deficiencia parcial o total de la enzima alfa glucosidasa ácida. La ausencia/ déficit de esta enzima genera un almacenamiento de glucógeno en el interior de los lisosomas en diversos tejidos, incluidos el músculo esquelético, el miocardio y las células del músculo liso. Se trata de una enfermedad multisistémica que puede tener un inicio temprano o tardío de los síntomas. Contenidos: En este artículo se describirán los aspectos históricos de la enfermedad, su fisiopatología y sus manifestaciones clínicas, con el énfasis puesto en su inicio temprano o tardío. Conclusiones: Es necesario reconocer la enfermedad de Pompe debido a que esta patología es susceptible de tratamiento.

Introduction: Pompe's disease or glucogenosis type II belongs to the group of metabolic myopathies and is caused by a partial or total deficiency of the acid alpha glucosidase enzyme. The lack/deficiency of this enzyme generates glycogen storage inside the lysosomes in various tissues including skeletal muscle, myocardium and smooth muscle cells. It is a multisystemic disease that can have an early onset or a late onset. Contents: In this article, the historical aspects, the pathophysiology and the clinical manifestations of the disease, will be described. Conclusions: It is necessary to recognize Pompe disease because this pathology is treatable.

Research progress of nervous system damage in Pompe disease / 中国当代儿科杂志

Pompe disease, also known as glycogen storage disease type Ⅱ, is a rare autosomal recessive disease. With the application of enzyme replacement therapy, more and more patients with Pompe disease can survive to adulthood, and nervous system-related clinical manifestations gradually emerge. Nervous system involvement seriously affects the quality of life of patients with Pompe disease, and a systematic understanding of the clinical manifestations, imaging features and pathological changes of nervous system injury in Pompe disease is of great significance for the early identification and intervention of Pompe disease. This article reviews the research progress of neurological damage in Pompe disease.

Clinical and molecular characterization of Korean children with infantile and late-onset Pompe disease: 10 years of experience with enzyme replacement therapy at a single center / 소아과

PURPOSE: Pompe disease (PD) is an autosomal recessive disorder caused by a deficiency of acid alpha-glucosidase resulting from pathogenic GAA variants. This study describes the clinical features, genotypes, changes before and after enzyme replacement therapy (ERT), and long-term outcomes in patients with infantile-onset PD (IOPD) and late-onset PD (LOPD) at a tertiary medical center. METHODS: The medical records of 5 Korean patients (2 male, 3 female patients) diagnosed with PD between 2002 and 2013 at Samsung Medical Center in Seoul, Republic of Korea were retrospectively reviewed for data, including clinical and genetic characteristics at diagnosis and clinical course after ERT. RESULTS: Common initial symptoms included hypotonia, cyanosis, and tachycardia in patients with IOPD and limb girdle weakness in patients with LOPD. Electrocardiography at diagnosis revealed hypertrophic cardiomyopathy in all patients with IOPD who showed a stable disease course during a median follow-up period of 10 years. Patients with LOPD showed improved hepatomegaly and liver transaminase level after ERT. CONCLUSION: As ERT is effective for treatment of PD, early identification of this disease is very important. Thus, patients with IOPD should be considered candidates for clinical trials of new drugs in the future.

Clinical and gene mutation analysis of three children with late-onset glycogen storage disease type Ⅱ with hypertrophic cardiomyopathy / 中华儿科杂志

Objective@#To investigate the clinical and laboratory features of three children with late-onset type Ⅱ glycogen storage disease(GSD) who presented with hypertrophic cardiomyopathy and to analyze the effect of five mutations identified on the acid-α-glucosidase (GAA) activity and stability.@*Method@#Three cases of children with muscle weakness were included in this study.GAA activity was analyzed in Dried Blood Spot of the patients.DNA was extracted from peripheral blood in all the patients and their parents and subjected to polymerase chain reaction and directly sequencing of GAA gene.Five mutant pcDNA3.1-myc-his-GAA expression plasmids(p.G478R, p.P361L, p.P266S, p.Q323X, p.R672Q) were constructed and transient instantaneously transfected into 293T cells to analyze the enzyme activity and stability of GAA.@*Result@#All the three children had the onset of disease at 3 years or 1.5 years of age.They presented with developmental delay, muscle weakness and hypertrophic cardiomyopathy.GAA activity of 3 patients was 2.65, 3.55 and 1.51 pmol(punch·h)(8.00-98.02)respectively. Genetic analysis found 5 mutations (p.G478R, p. P361L, p. P266S, p. Q323X, p. R672Q), and all of these 3 cases had clinical manifestations and were diagnosed as late-onset type Ⅱ glycogen storage disease.Five mutant pcDNA3.1-myc-his-GAA expression plasmids were transfected into 293T cells.Five mutant enzyme activities were found to be only 9.9%-22.5% of the wild-type enzyme activity and the protein expression of the five mutants was 32.0%-63.9% compared with the wild type.@*Conclusion@#This study reports 3 children with late-onset GSD Ⅱ accompanied by hypertrophic cardiomyopathy and compensatory stage of cardiac function in addition to limb muscle weakness.Five pathogenic mutations were identified, and these 5 mutations result in decreased GAA activity and GAA expression by in vitro functional analysis.

Guidelines for the diagnosis, treatment and clinical monitoring of patients with juvenile and adult Pompe disease / Diretriz para o diagnóstico, tratamento e acompanhamento clínico de pacientes com doença de Pompe juvenil e do adulto

ABSTRACT Pompe disease (PD) is a potentially lethal illness involving irreversible muscle damage resulting from glycogen storage in muscle fiber and activation of autophagic pathways. A promising therapeutic perspective for PD is enzyme replacement therapy (ERT) with the human recombinant enzyme acid alpha-glucosidase (Myozyme®). The need to organize a diagnostic flowchart, systematize clinical follow-up, and establish new therapeutic recommendations has become vital, as ERT ensures greater patient longevity. A task force of experienced clinicians outlined a protocol for diagnosis, monitoring, treatment, genetic counseling, and rehabilitation for PD patients. The study was conducted under the coordination of REBREPOM, the Brazilian Network for Studies of PD. The meeting of these experts took place in October 2013, at L’Hotel Port Bay in São Paulo, Brazil. In August 2014, the text was reassessed and updated. Given the rarity of PD and limited high-impact publications, experts submitted their views.

RESUMO A doença de Pompe (DP) é uma doença grave, potencialmente letal, devida ao depósito de glicogênio na fibra muscular e ativação de vias autofágicas. Tratamento promissor para a DP é a reposição enzimática com a enzima recombinante humana alfa-glicosidase ácida (rhAGA -Myozyme®). A necessidade de organizar uma propedêutica diagnóstica, sistematizar o seguimento clínico e sedimentar as novas recomendações terapêuticas tornaram-se vitais à medida que o tratamento permite uma maior longevidade aos pacientes. Uma força-tarefa de clínicos experientes no manejo da DP foi constituída para elaborar um protocolo para o diagnóstico, acompanhamento clínico, tratamento, aconselhamento genético, entre outras considerações voltadas ao paciente adulto. O estudo foi realizado sob a coordenação da Rede Brasileira de Estudos da Doença de Pompe (REBREPOM). Diante da raridade da DP e escassez de trabalhos de alto impacto de evidência científica, os especialistas emitiram suas opiniões.

Enfermedad de Pompe: reporte de caso / Disease Pompe: report of case

Objetivo. Se describe el caso de un paciente masculino de siete meses de edad, evaluado por cardiología a los quince días de vida por antecedente de muerte súbita cardíaca de hermana a los cuatro meses, no se sospechó nada pese a consanguinidad de padres y diagnóstico temprano del paciente de cardiomiopatía. Evoluciona con un cuadro clínico de infecciones respiratorias a repetición desde los tres meses (bronquiolitis recurrente), falla de medro y cuadro de neumonía reciente y fallece a los ocho días de la consulta con la genetista. Métodos. El abordaje inicial fue la realización de un ecocardiograma a los quince días de nacido por antecedente de muerte súbita de hermana a los cuatro meses por cardiomegalia y consanguinidad de los padres. Continúa con deterioro clínico a través de los meses por lo que se remite a genética, se toman pruebas enzimáticas en gota de sangre seca, el paciente fallece antes de recibir el diagnóstico de Enfermedad de Pompe. Resultados. Se enfocó al paciente con un posible diagnóstico de Enfermedad de Pompe solicitándose enzima lisosomal alfa-glucosidasa (GAA) en muestra de gota de sangre seca y reporte final de la secuenciación genética.

Objective. It is a case of a seven months male patient, evaluated by cardiology fifteen days after he was born secondary, to sudden cardiac death of his sister of four months, nothing suspicious despite consanguinity of parents and early diagnosis of the patient with Cardiomyopathy. Evolved with the following clinical conditions recurrent respiratory infections from three months (recurrent bronchiolitis), widespread malnutrition and recent pneumonia. Died eight days after the consultation with the geneticist. Methods. The initial approach was to perform echocardiogram at fifteen days old, because of history of the sudden death of his sister of four months, cardiomegaly and parental consanguinity. Clinical deterioration continues through months so he is referred to genetic, enzymatic tests, taken in dried blood, the patient dies before receiving the diagnosis of Pompe disease. Results. The patient was focused with a possible diagnosis ofPompe Disease so lysosomal enzyme α-glucosidase (GAA) sample was requested in dried blood and genetic sequencing final report to define diagnosis.

Review on Molecular Diagnostic Techniques in Friedreich’s Ataxia.

Friedreich’s ataxia is a commonly inherited neurodegenerative disease with an autosomal recessive pattern of inheritance, and was described by Nikolaus Friedreich first in 1863. Friedreich’s ataxia is caused due to hyperexpansion of the intronic GAA trinucleotide repeats or mutations in the FXN gene on chromosome 9q13. This gene codes for a mitochondrial protein, frataxin, which is highly conserved in many species and has functions in iron-sulfur cluster biosynthesis. Friedreich’s ataxia mainly results from a deficiency of the frataxin protein, due to mutations in the FXN gene. Formation of sticky DNA, formation of DNA-RNA hybrid and epigenetic changes, including methylation of DNA and histone modifications, are the proposed mechanisms for disruption of FXN gene expression. Most cases of Friedreich’s ataxia are homozygous and caused due to expansion of the GAA trinucleotide repeat in the first intron of the FXN gene, however, some cases can be heterozygous, with GAA expansion in one allele and point mutation or deletion in the FXN gene on the other allele. Therefore, diagnosis of the disease based on only the clinical symptoms becomes difficult. Molecular diagnosis is, therefore, important, in order to detect GAA repeat expansions as well as mutations in the FXN gene. This review represents an overview of the molecular diagnostic studies in Friedreich’s ataxia, including an overview of the disease, as well as the gene and protein involved in the disease and techniques that can be useful in diagnosis of the Friedreich’s ataxia. The described methods include tools that are based on analysis of DNA as well as analysis of mRNA and protein levels. A brief description of mutations found in compound heterozygous Friedreich’s ataxia patients, is also provided.

DNA triplex structures in neurodegenerative disorder, Friedreich’s ataxia.

It is now established that a small fraction of genomic DNA does adopt the non-canonical B-DNA structure or ‘unusual’ DNA structure. The unusual DNA structures like DNA-hairpin, cruciform, Z-DNA, triplex and tetraplex are represented as hotspots of chromosomal breaks, homologous recombination and gross chromosomal rearrangements since they are prone to the structural alterations. Friedreich’s ataxia (FRDA), the autosomal recessive degenerative disorder of nervous and muscles tissue, is caused by the massive expansion of (GAA) repeats that occur in the first intron of Frataxin gene X25 on chromosome 9q13-q21.1. The purine strand of the DNA in the expanded (GAA) repeat region folds back to form the (R∙R*Y) type of triplex, which further inhibits the frataxin gene expression, and this clearly suggests that the shape of DNA is the determining factor in the cellular function. FRDA is the only disease known so far to be associated with DNA triplex. Structural characterization of GAA-containing DNA triplexes using some simple biophysical methods like UV melting, UV absorption, circular dichroic spectroscopy and electrophoretic mobility shift assay are discussed. Further, the clinical aspects and genetic analysis of FRDA patients who carry (GAA) repeat expansions are presented. The potential of some small molecules that do not favour the DNA triplex formation as therapeutics for FRDA are also briefly discussed.

Two Patients with Atypical Infantile Pompe Disease Presenting with Hypertrophic Cardiomyopathy

Pompe disease (glycogen storage disease type II) is an autosomal recessive disorder caused by deficiency of acid-alpha-glucosidase (GAA) resulting in lysosomal glycogen accumulation in multiple tissue, particularly cardiac and skeletal muscle. The classic infantile form of Pompe disease is characterized by marked cardiomegaly, respiratory failure and severe generalized hypotonia. Most patients die from cardiorespiratory failure or respiratory infection within the first year or two of life without treatment. A "non-classic" phenotype presents with less severe clinical feature and slow progression of disease. We report two patients with non-classic infantile Pompe disease from one family manifested hypertrophic cardiomyopathy and progressive proximal weakness.

Fenotipo y genotipo de once pacientes con Ataxia de Friedreich / Friedreic's Ataxia: Phenotype and Genotype in Eleven Patients

Introducción: La ataxia de Friedreich (FRDA) es una enfermedad autosómica recesiva debida a una mutación en el gen X25. Dicho gen está localizado en el cromosoma 9 y codifica para la proteína frataxina. La enfermedad es causada por la repetición del trinucleótido GAA. En individuos normales la secuencia GAA se encuentra repetida entre siete y veintidós veces, mientras que, en pacientes con ataxia de Friedreich GAA puede estar repetida cientos o miles de veces. Objetivos: Evaluar si existe correlación entre el tamaño de la expansión, la edad de inicio de FRDA y su severidad en la muestra seleccionada. Métodos: - Se estudiaron once pacientes con fenotipo típico de ataxia de Friedreich. El análisis molecular por PCR determinó la expansión del trinucleótido GAA. Se analizó la correlación entre la edad de inicio de FRDA y su progresión con el número de repeticiones GAA. Resultados y conclusiones: - El análisis molecular por PCR mostró ocho pacientes homocigotos para la expansión, y tres negativos. El promedio del tamaño de las expansiones en los alelos es 622±5 con un promedio correspondiente de la edad inicio de FRDA 13±8. Para el tamaño de la muestra no se observó una correlación estadística significativa entre la edad de inicio de la enfermedad y el número de repeticiones, pero sí una tendencia a correlacionarse de forma inversa (p<0.11). El diagnóstico molecular de FRDA sumado a la comprensión de su fisiología y a la utilización de los criterios de inclusión de Harding, constituye un paso importante en el logro de un tratamiento óptimo de la enfermedad.

Introduction: - Friedreich's ataxia is an autosomal recessive disease due to a mutation in gene X25. This gene codes for frataxin and it is located on chromosome 9. The disease is caused by a triplet particular sequence of bases (GAA). Normally, the GAA sequence is repeated 7 to 22 times, but in people with Friedreich's ataxia, it can be repeated hundreds or even over thousand times. Objectives: To determine if there is a correlation between clinical and molecular findings in our FRDA patients. Methods: Eleven patients with the typical Friedreich´s ataxia phenotype were studied by PCR we determined the size of the GAA expansions, and analyzed the correlation of age at onset and rate of disease progression with the number of GAA repetitions. Results and conclusions: Molecular analysis by PCR showed eight homozygous patients for the expansion and three negative. The average of the size of the expansions in the allele was of 622±5 with an average in the age of beginning of 13±8. For the sample size, there was no significant statistical correlation between the age of beginning of the disease and the number of repetitions, although there was like an inverse correlation. Besides understanding of FRDA physiology and the Harding clinical inclusion criteria, molecular diagnosis is an important step in the achievement of an optimal therapeutic treatment.