J.C. Haworth

Glycogen Storage Disease in Adults

Table 1 The glycogen storage diseases (GSD) include more than ten separate genetic defects that impair glycogen breakdown, primarily in liver or muscle or both. Even the types most frequently encountered (GSD-Ia and GSD-III) are uncommon, each with an incidence of approximately 1 in 100 000 births. Thus, no single institution has followed and reported on a large series of patients. The importance of several major complications was recognized only recently because only single cases were initially reported. Our study represents the largest number of adults with GSD-Ia and GSD-Ib to be included in one investigation and is the first to focus on clinical and social outcomes. Although two groups of investigators recently described the clinical course of patients with GSD in Europe and Israel, most of the patients studied were children [1, 2]. Relatively little information is available about adults with these diseases. We collected information on adults with GSD-Ia, GSD-Ib, and GSD-III in the United States and Canada in order to identify long-term complications that may be amenable to prevention and to determine the effect of the disease on education, employment, and family life. Table 1. SI Units Glycogen Storage Disease Types Ia, Ib, and III Glycogen storage disease type Ia results from deficient glucose-6-phosphatase activity in liver, kidney, and intestine [3]. Glucose-6-phosphatase is a single 35-kd protein [4]. When glucose-6-phosphatase activity is deficient, the liver is unable to hydrolyze glucose from glucose-6-phosphate that has been derived either from the metabolism of stored glycogen or from gluconeogenesis. Patients must depend on dietary carbohydrate to maintain euglycemia; during a fast of more than a few hours, the serum glucose concentration may decrease profoundly, and seizures are common in children. Mental retardation is uncommon, however, because the brain is protected by its ability to metabolize lactate that is present at high concentrations in the serum. Chronic hypoglycemia causes a sustained increase of counter-regulatory hormones, such as cortisol. In childhood, GSD-Ia typically results in poor growth and delayed puberty. Hyperuricemia occurs probably because ATP synthesis from ADP is driven by deamination of the AMP product to inosine that is subsequently metabolized to uric acid. Renal excretion of uric acid may also be decreased because lactate competes for the renal anion transporter. Fatty liver and hyperlipidemia result from the large influx of adipose-derived fatty acids into the liver in response to low insulin and high glucagon and cortisol concentrations. Anemia that is refractory to iron supplementation is believed to occur because of chronic disease. In untreated adults with GSD-Ia, the blood glucose decreases only to about 2.8 mmol/L (50 mg/dL) after an overnight fast. Symptomatic hypoglycemia is uncommon in untreated adults, but increases of counter-regulatory hormones probably persist. Adults with GSD-Ia have a high incidence of hepatic adenomas and focal segmental glomerulosclerosis [3, 5, 6]. The continuing abnormalities in counter-regulatory hormones, together with the hyperuricemia and hyperlipidemia, may be responsible for many of the complications observed in adult patients. Glycogen storage disease type Ib results from a deficiency of the glucose-6-phosphate translocase that transports glucose-6-phosphate into the lumen of the endoplasmic reticulum where it is hydrolyzed by glucose-6-phosphatase [3]. The translocase has not been purified. Without the translocase, glucose-6-phosphate cannot reach the hydrolytic enzyme; thus, patients with GSD-Ib are also unable to maintain euglycemia. The resulting metabolic consequences are identical in both forms of GSD-I. Because patients with GSD-Ib also have neutropenia and recurrent bacterial infections [3, 7], it seems likely that the glucose-6-phosphate translocase plays a role in normal neutrophil function. In GSD-III, glycogen debranching enzyme is deficient [3]. This enzyme is a 165-kd protein that contains two catalytic sites that are required for activity. The enzyme has been cloned and sequenced [8]. Normally, successive glucose residues are released from glycogen by glycogen phosphorylase until the glycogen chains are within four glucose residues of a branch point. The first catalytic activity of the debranching enzyme (oligo-1,4,-1,4-glucantransferase) transfers three of the remaining glucose residues to the terminus of another glucose chain. The second catalytic activity (amylo-1,6-glucosidase) then hydrolyzes the branch-point glucose residue. Three molecular subgroups of GSD-III have been well defined [9]; each is associated with enzyme deficiency in the liver and with childhood hypoglycemia. In adults with GSD-III, hypoglycemia is uncommon. As in GSD-I, poor growth may be prominent, but the growth rate increases before puberty, and adult height is normal [10]. Additionally, increases in transaminase levels provide evidence of hepatocellular damage, and liver biopsies show periportal fibrosis [10], perhaps related to the abnormal short-branched glycogen structure. In patients with subtype GSD-IIIb, enzyme activity and immunoreactive material are absent in liver but are present in muscle; these patients do not have a myopathy. Patients with GSD-IIIa (78% of cases) lack enzyme activity and lack immunoreactive material in liver and muscle. Patients with GSD-IIId (7% of cases) lack only the transferase activity but have normal immunoreactive material in liver and muscle. In patients with GSD-IIIa and IIId, muscle weakness may occur either in childhood or after the third decade. Cardiomyopathy is apparent only after age 30 years [9]. Treatment of Glycogen Storage Disease For only the past 10 to 15 years, children with GSD-Ia and GSD-Ib were treated with either intermittent uncooked cornstarch or a nocturnal glucose infusion given by intragastric tube. When euglycemia is maintained in this manner, growth and pubertal development are normal, and it is hoped that the late complications of GSD-I will be prevented. A high-protein diet was recommended for patients with GSD-III. Diet supplementation can increase the growth rate in children with GSD-III [11], but beneficial results on the myopathy have been less well documented. In this retrospective study of adults with GSD types Ia, Ib, and III, we found, in addition to complications frequently recognized, a high incidence of osteopenia and fractures and of nephrocalcinosis, kidney stones, and pyelonephritis. We describe the long-term outlook for adult patients with GSD who have not had optimal lifelong dietary glucose therapy. Methods Information on patients 18 years of age or older was obtained by contacting specialists in pediatric metabolism, endocrinology, gastroenterology, and genetics throughout the United States and Canada and by advertising through the Association for Glycogen Storage Diseases and The New England Journal of Medicine. No registries of patients with GSD are available. Information was included on living adult patients with GSD and patients who had died since 1967. Diagnosis of GSD had been confirmed by enzyme assay of each patient or of an affected sibling. Fifty-six physicians were individually contacted. Nineteen stated that they were not treating any adult patients with GSD. Thirteen physicians in private practice or at 1 of 12 medical centers filled out a detailed questionnaire or sent copies of clinic and hospital records that were reviewed by two of us. To obtain an estimate of how many patients might be missed by this survey, we reviewed records from a reference laboratory (Washington University) of 21 patients with GSD-Ia and of 21 patients with GSD-III who were diagnosed between 1955 and 1972. If still alive, these patients would now range in age from 18 to 64 years. Our study includes only 5 of these patients with GSD-I and 1 with GSD-III. Thus, this report incompletely represents North American patients with GSD who are currently older than 18 years of age. Clinical, radiographic, and laboratory findings at the latest visit were obtained, but data were not universally available for every item on the questionnaire. In analyzing each response, information was considered to be available only if specifically recorded; omission of information was not recorded as either a negative or a positive response. The presence of liver adenomas, nephrocalcinosis, or kidney stones was based on data from ultrasound or radiographic studies. The diagnosis of osteopenia was based on data from radiographic studies. The normal values for height were taken from the National Center for Health Statistics [12]. Normal values for serum chemistry tests [13] were used. Results Glycogen Storage Disease Type Ia Case Report Patient 1, a 43-year-old divorced father of one child, is a poultry farmer. A liver biopsy and enzymatic assay were obtained at 4 years of age because of poor growth, hypoglycemia without seizures, hepatomegaly, and frequent nosebleeds. Despite frequent meals, growth continued to be poor, puberty was delayed, and the final adult height of 168 cm was achieved after 20 years of age. Allopurinol was taken inconsistently after one of many gouty attacks beginning from 18 years of age. The patient did not complete high school. As an adult, he has smoked 2 to 4 packs of cigarettes per day. After divorcing in his 20s, he frequently skipped breakfast and failed to follow a recommended diet. Instead, his diet was high in fat and consisted primarily of foods that required little preparation, such as candy and sandwiches. He has always denied symptomatic hypoglycemia, although his serum glucose concentration after an overnight fast is about 2.8 mmol/L (50 mg/dL). Beginning in his mid-20s, he had recurrent episodes of flank pain and hematuria that were treated with antibiotics, and he passed kidney stones. At age 24, an intravenous pyelogram showed punctate calcificati

Phenotypic variability in glutaric aciduria type I: Report of fourteen cases in five Canadian Indian kindreds

We describe 14 patients with glutaric aciduria type 1 in five Canadian Indian kindreds living in Manitoba and northwest Ontario. The patients had marked clinical variability of the disease, even within families. Eight followed the typical clinical course of normal early growth and development until the onset of neurologic abnormalities, often precipitated by infection, between 6 weeks and 7 1/2 months of age. Five patients had early developmental delay; one was thought to be normal until 8 years of age. Three patients died, seven are severely mentally and physically handicapped, and four have only mild mental retardation or incoordination. Six patients had macrocephaly in the neonatal period. Computed tomography was done for 12 patients, and findings were abnormal in 11. Glutaric acid and 3-hydroxyglutaric acid were detected in increased amounts in the urine of all patients, but the concentrations were much lower than those in most other reported patients. Glutaryl coenzyme A dehydrogenase activity in skin fibroblasts, interleukin-2-dependent lymphocytes, or both, ranged from 0% to 13% of control values. There was no correlation between clinical severity and urine glutaric acid concentration or level of residual enzyme activity. We recommend that organic acid analysis of the urine be done in patients with unexplained cerebral palsy-like disorders, especially if the computed tomographic scan is abnormal. If there is suspicion of glutaric aciduria, glutaryl-coenzyme A dehydrogenase should be measured in fibroblasts or lymphocytes even if glutaric acid is not increased in the urine.

Mutations in the proenteropeptidase gene are the molecular cause of congenital enteropeptidase deficiency.

Enteropeptidase (enterokinase [E.C.3.4.21.9]) is a serine protease of the intestinal brush border in the proximal small intestine. It activates the pancreatic proenzyme trypsinogen, which, in turn, releases active digestive enzymes from their inactive pancreatic precursors. Congenital enteropeptidase deficiency is a rare recessively inherited disorder leading, in affected infants, to severe failure to thrive. The genomic structure of the proenteropeptidase gene (25 exons, total gene size 88 kb) was characterized in order to perform DNA sequencing in three clinically and biochemically proved patients with congenital enteropeptidase deficiency who were from two families. We found compound heterozygosity for nonsense mutations (S712X/R857X) in two affected siblings and found compound heterozygosity for a nonsense mutation (Q261X) and a frameshift mutation (FsQ902) in the third patient. In accordance with the biochemical findings, all four defective alleles identified are predicted null alleles leading to a gene product not containing the active site of the enzyme. These data provide first evidence that proenteropeptidase-gene mutations are the primary cause of congenital enteropeptidase deficiency.

Severe mental retardation, cataracts, short stature, and primary hypogonadism in two brothers

Two severely mentally retarded brothers are described who had a similar facial appearance, cataracts, short stature, minor digital abnormalities, and primary hypogonadism. Their parents were first cousins. Numerous laboratory investigations failed to elucidate a basic metabolic cause for their disorder.

Amerindian pyruvate carboxylase deficiency is associated with two distinct missense mutations.

We characterized the pyruvate carboxylase (PC) gene by PCR amplification, subcloning, and sequencing. The coding region has 19 exons and 18 introns spanning approximately 16 kb of genomic DNA. Screening both the cDNA and the gene of individuals with the simple A form of PC deficiency revealed an 1828G-->A missense mutation in 11 Ojibwa and 2 Cree patients and a 2229G-->T transversion mutation in 2 brothers of Micmac origin. Carrier frequency may be as high as 1/10 in some groupings. The two point mutations are located in a region of homology conserved among yeast, rat, and human PC, in the vicinity of the carboxylation domain of the enzyme. These data provide the first characterization of the human PC gene structure, the identification of common pathogenic mutations, and the demonstration of a founder effect in the Ojibwa and Cree patients.

Fetal growth retardation in cigarette-smoking mothers is not due to decreased maternal food intake

To determine whether the fetal growth-retarding effect of maternal cigarette smoking could be due to a lower dietary intake in smokers than in nonsmokers, the energy and nutrient intake of 302 smoking and 234 nonsmoking women were assessed toward the end of the last trimester of pregnancy. The women were from two socioeconomic groups which differed greatly in age, height, education, family income, racial origin, and pregnancy weight gain. Within each group, smokers had significantly smaller infants, but pregnancy weight gain was not different. Daily dietary intake of the smokers was not less than that of the nonsmokers; in fact, for some nutrients it was significantly greater. Therefore, fetal growth retardation due to smoking is not caused by the mothers diminished intake of food.

The paradox of the carnitine palmitoyltransferase type Ia P479L variant in Canadian Aboriginal populations

Investigation of seven patients from three families suspected of a fatty acid oxidation defect showed mean CPT-I enzyme activity of 5.9+/-4.9 percent of normal controls. The families, two Inuit, one First Nation, live in areas of Canada geographically very distant from each other. The CPT1 and CPT2 genes were fully sequenced in 5 of the patients. All were homozygous for the same P479L mutation in a highly conserved region of the CPT1 gene. Two patients from the first family were also homozygous for the CPT2 F352C polymorphism in the CPT2 gene. Genotyping the patients and their family members confirmed that all seven patients were homozygous for the P479L variant allele in the CPT1 gene, as were 27 of 32 family members. Three of the seven patients and two cousins had hypoketotic hypoglycemia attributable to CPT-Ia deficiency, but adults homozygous for the variant denied hypoglycemia. We screened 422 consecutive newborns from the region of one of the Inuit families for this variant; 294 were homozygous, 103 heterozygous, and only 25 homozygous normal; thus the frequency of this variant allele is 0.81. There was an infant death in one family and at least 10 more deaths in those infants (7 homozygous, 3 heterozygous) consecutively tested for the mutation at birth. Thus there is an astonishingly high frequency of CPT1 P479L variant and, judging from the enzyme analysis in the seven patients, also CPT-I deficiency in the areas of Canada inhabited by these families. Despite the deficiency of CPT-Ia which is the major rate-limiting enzyme for long chain fatty acid oxidation, clinical effects, with few exceptions, were slight or absent. One clue to explaining this paradox is that, judging from the fatty acid oxidation studies in whole blood and fibroblasts, the low residual activity of CPT-Ia is sufficient to allow a reasonable flux through the mitochondrial oxidation system. It is likely that the P479L variant is of ancient origin and presumably its preservation must have conveyed some advantage.

Cebocephaly with endocrine dysgenesis. Report of 3 cases.

Summary Three cases of cebocephaly are reported. This malformation differs from the closely allied condition of cyclopia in that the orbits are separate, although showing hypotelorism, and there is a rudimentary nose with a single nostril in the normal position. The brains of the 3 cases showed the almost identical malformation of arhinencephaly. Two cases were found to have absence ofthe pituitary gland and hypoplasia of the adrenal cortex and in addition one showed hypoplasia of the thyroid gland. The endocrine system of the third case was apparently normal. Chromosome counts in one case were normal.

Prognosis of Infants of Diabetic Mothers in Relation to Neonatal Hypoglycaemia

A prospective follow‐up study was conducted to determine whether neonatal hypoglycaemia in infants of diabetic mothers affects subsequent neurological and intellectual performance. 37 such infants (25 hypoglycaemic and 12 non‐hypoglycaemic) were examined for physical, neurological and developmental performance at an average age of 41/2 years. 11 children were abnormal, with generalised retardation and neurological abnormalities, or delays in particular areas of development; three children were possibly abnormal; and 23 children were normal. Abnormality at follow‐up could not be related to neonatal blood glucose level, to the duration of hypoglycaemia or to any other measurement made in the neonatal period, nor to any factor relating to the maternal diabetes. Compared with the normal children, the abnormal group had slightly smaller head‐circumferences at birth relative to their gestational age, but at follow‐up there was no difference in head size. At follow‐up the children of diabetic mothers tended to be shorter than average. The poor prognosis of the infants in this study was not due to brain damage caused by neonatal hypoglycaemia.

Relation of maternal cigarette smoking, obesity, and energy consumption to infant size

The dietary energy intakes of 153 public patients (94 smokers and 59 nonsmokers) and 383 Private patients (208 smokers and 175 nonsmokers) were assessed in the last month of pregnancy. Birth weight and crown-heel length of offspring were related to maternal size (weight for height) and smoking habits. Birth weight and length increased significantly with increasing maternal weight for height in the Private group but not in the Public group. In both groups, and in all weight categories, infants of smokers were lighter and shorter than those of nonsmokers. Neither the fetal growth retardation in the smokers nor the fetal growth enhancement in the overweight mothers was explainable on the basis of maternal dietary energy intake. Maternal obesity and cigarette smoking act independently of each other and maternal overweight does not protect the fetus against the growth-retarding of smoking.