Familial hyperinsulinism maps to chromosome 11p14-15.1, 30 cM centromeric to the insulin gene.

Familial hyperinsulinism (HI) is the most common cause of persistent neonatal hyperinsulinaemic hypoglycemia. Linkage analysis in 15 families (12 Ashkenazi Jewish, 2 consanguineous Arab, 1 non-Jewish Caucasian) mapped HI to chromosome 11p14-15.1 (lod score = 9.5, theta = 0 at D11S921). Recombinants localized the disease locus to the 6.6 cM interval between D11S926 and D11S928. In Jewish families, association (p = 0.003) with specific D11S921/D11S419 haplotypes suggested a founder effect. This locus, which is important for normal glucose-regulated insulin secretion, represents a candidate gene for studies of other diseases of beta-cell dysfunction including non-insulin-dependent diabetes mellitus (NIDDM).

Linkage-disequilibrium mapping without genotyping.

Genomic mismatch scanning (GMS) is a technique that enriches for regions of identity by descent (IBD) between two individuals without the need for genotyping or sequencing. Regions of IBD selected by GMS are mapped by hybridization to a microarray containing ordered clones of genomic DNA from chromosomes of interest. Here we demonstrate the feasibility and efficacy of this form of linkage-mapping, using congenital hyperinsulinism (HI), an autosomal recessive disease, whose relatively high frequency in Ashkenazi Jews suggests a founder effect. The gene responsible (SUR1) encodes the sulfonylurea receptor, which maps to chromosome 11p15.1. We show that the combination of GMS and hybridization of IBD products to a chromosome-11 microarray correctly maps the HI gene to a 2-Mb region, thereby demonstrating linkage-disequilibrium mapping without genotyping.

[Hyperinsulinism in infancy and childhood: when an insulin level is not always enough]. / Hyperinsulinisme de l'enfant et de l'adolescent: quand la détermination de la concentration en insuline n'est pas toujours suffisante.

Hypoglycemia in infants and children can lead to seizures, developmental delay, and permanent brain damage. Hyperinsulinism (HI) is the most common cause of both transient and permanent disorders of hypoglycemia. HI is characterized by dysregulated insulin secretion, which results in persistent mild to severe hypoglycemia. The various forms of HI represent a group of clinically, genetically, and morphologically heterogeneous disorders. Congenital hyperinsulinism is associated with mutations of SUR-1 and Kir6.2, glucokinase, glutamate dehydrogenase, short-chain 3-hydroxyacyl-CoA dehydrogenase, and ectopic expression on beta-cell plasma membrane of SLC16A1. Hyperinsulinism can be associated with perinatal stress such as birth asphyxia, maternal toxemia, prematurity, or intrauterine growth retardation, resulting in prolonged neonatal hypoglycemia. Mimickers of hyperinsulinism include neonatal panhypopituitarism, drug-induced hypoglycemia, insulinoma, antiinsulin and insulin-receptor stimulating antibodies, Beckwith-Wiedemann Syndrome, and congenital disorders of glycosylation. Laboratory testing for hyperinsulinism may include quantification of blood glucose, plasma insulin, plasma beta-hydroxybutyrate, plasma fatty acids, plasma ammonia, plasma acylcarnitine profile, and urine organic acids. Genetic testing is available through commercial laboratories for genes known to be associated with hyperinsulinism. Acute insulin response (AIR) tests are useful in phenotypic characterization. Imaging and histologic tools are also available for diagnosing and classifying hyperinsulinism. The goal of treatment in infants with hyperinsulinism is to prevent brain damage from hypoglycemia by maintaining plasma glucose levels above 700 mg/L (70 mg/dL) through pharmacologic or surgical therapy. The management of hyperinsulinism requires a multidisciplinary approach that includes pediatric endocrinologists, radiologists, surgeons, and pathologists who are trained in diagnosing, identifying, and treating hyperinsulinism.

Impaired metabolic function and signaling defects in phagocytic cells in glycogen storage disease type 1b.

Patients with glycogen storage disease (GSD) type 1b (1b), in contrast to patients with GSD type 1a (1a), are susceptible to recurrent bacterial infections suggesting an impairment in their immune system. In this study, phagocytic cell (neutrophil and monocyte) respiratory burst activity, as measured by superoxide anion generation, oxygen consumption, and hexose monophosphate shunt activity, was markedly reduced in both neutrophils and monocytes from GSD 1b patients as compared with either GSD 1a patients or healthy adult control cells. Degranulation, unlike respiratory burst activity, was not significantly different in neutrophils from GSD 1b patients as compared with controls. Both neutrophils and monocytes from GSD 1b patients showed decreased ability to elevate cytosolic calcium in response to the chemotactic peptide f-Met-Leu-Phe. In addition, calcium mobilization in response to ionomycin was also attenuated suggesting decreased calcium stores. Thus, reduced phagocytic cell function in GSD 1b is associated with diminished calcium mobilization and defective calcium stores. Defective calcium signaling is associated with a selective defect in respiratory burst activity but not degranulation.

Relationship between unusual hepatic acyl coenzyme A profiles and the pathogenesis of Reye syndrome.

This study examines the relationship between impaired fatty acid oxidation and the pathogenesis of Reye syndrome. We present a hypothesis proposing that many clinical signs of this childhood disease are caused by accumulation of unusual acyl CoA esters, precursors to deacylated metabolites found in the patients' blood and urine. A new method was developed to measure acyl CoA compounds in small human liver biopsy samples, offering several advantages over previous techniques. A major finding was an accumulation in Reye syndrome patients of short- and medium-chain acyl CoA intermediates of fatty acid and branched-chain amino acid oxidation. These metabolites included octanoyl, isovaleryl, butyryl, isobutyryl, propionyl, and methylmalonyl CoA esters. The findings were explained in a model of hepatic fatty acid oxidation involving three interrelated pathways: mitochondrial beta-oxidation, peroxisomal beta-oxidation, and omega-oxidation in the endoplasmic reticulum. The results suggest that pathogenesis in Reye syndrome stems from generalized mitochondrial damage resulting in accumulation of acyl CoA esters. High levels of these compounds lead to inhibition of mitochondrial pathways for ureogenesis, gluconeogenesis, and fatty acid oxidation. The inhibited pathways, in turn, could cause the hyperammonemia, hypoglycemia, and hypoketonemia observed in patients. The model also explains underlying biochemical differences between patients with Reye syndrome and medium-chain acyl CoA dehydrogenase deficiency, another disorder of fatty acid metabolism. Acetyl CoA levels, in the latter disease, were dramatically decreased, compared with both human controls and Reye syndrome patients.

Molecular basis and characterization of the hyperinsulinism/hyperammonemia syndrome: predominance of mutations in exons 11 and 12 of the glutamate dehydrogenase gene. HI/HA Contributing Investigators.

Glutamate dehydrogenase (GDH) is allosterically activated by the amino acid leucine to mediate protein stimulation of insulin secretion. Children with the hyperinsulinism/hyperammonemia (HI/HA) syndrome have symptomatic hypoglycemia plus persistent elevations of plasma ammonium. We have reported that HI/HA may be caused by dominant mutations of GDH that lie in a unique allosteric domain that is encoded within GDH exons 11 and 12. To examine the frequency of mutations in this domain, we screened genomic DNA from 48 unrelated cases with the HI/HA syndrome for exon 11 and 12 mutations in GDH. Twenty-five (52%) had mutations in these exons; 74% of the mutations were sporadic. Clinical manifestations included normal birth weight, late onset of hypoglycemia, diazoxide responsiveness, and protein-sensitive hypoglycemia. Enzymatic studies of lymphoblast GDH in seven of the mutations showed that all had reduced sensitivity to inhibition with GTP, consistent with an increase in enzyme activity. Mutations had little or no effect on enzyme responses to positive allosteric effectors, such as ADP or leucine. Based on the three-dimensional structure of GDH, the mutations may function by impairing the binding of an inhibitory GTP to a domain responsible for the allosteric and cooperativity properties of GDH.

Hyperinsulinism caused by paternal-specific inheritance of a recessive mutation in the sulfonylurea-receptor gene.

Neonatal hyperinsulinism (HI) is a genetic disorder of pancreatic beta-cells characterized by failure to suppress insulin secretion in the presence of hypoglycemia, resulting in brain damage or death if not adequately treated. Germline mutations in four genes have been associated with HI. Some patients have focal regions of beta-cell proliferation (focal HI). Seventy HI probands in whom at least one SUR-1 mutation was identified were studied. Clinical data from patients with two SUR-1 mutant alleles were compared with those from patients with single paternally inherited mutations. Thirty-seven probands were homozygous or compound heterozygous for SUR-1 mutations. In 33 probands, only a single mutation was identified, and in 31, the parental origin of the proband could be determined; in 29, the mutation was on the paternal allele (P < 0.0002). For three of these, pancreatic tissue was available and showed focal beta-cell hyperplasia. DNA extracted from the focal lesion and adjacent normal pancreas revealed loss of the maternal chromosome 11p15, resulting in reduction to homozygosity for the SUR-1 mutation within the focal lesion only. Using the Tdt-mediated dUTP nick end labeling (TUNEL) reaction, apoptotic beta-cells were identified exclusively within the focal region. At diagnosis, disease severity was similar in patients with paternally inherited mutations and those with two mutations. For patients who did not undergo surgery, those with only paternal mutations entered clinical remission within 16 +/- 6.2 months, compared with 48 +/- 23 months for those with two SUR-1 mutations (P = 0.001). In conclusion, we identified a novel mechanism to explain the pathophysiology of focal HI and provide evidence to suggest that this entity may be self-limiting, since affected beta-cells undergo apoptosis.

A nonsense mutation in the inward rectifier potassium channel gene, Kir6.2, is associated with familial hyperinsulinism.

ATP-sensitive potassium (K[ATP]) channels are an essential component of glucose-dependent insulin secretion in pancreatic islet beta-cells. These channels comprise the sulfonylurea receptor (SUR1) and Kir6.2, a member of the inward rectifier K+ channel family. Mutations in the SUR1 subunit are associated with familial hyperinsulinism (HI) (MIM:256450), an inherited disorder characterized by hyperinsulinism in the neonate. Since the Kir6.2 gene maps to human chromosome 11p15.1 (1,2), which also encompasses a locus for HI, we screened the Kir6.2 gene for the presence of mutations in 78 HI probands by single-strand conformation polymorphism (SSCP) and nucleotide sequence analyses. A nonsense mutation, Tyr-->Stop at codon 12 (designated Y12X) was observed in the homozygous state in a single proband. 86Rb+ efflux measurements and single-channel recordings of COS-1 cells co-expressing SUR1 and either wild-type or Y12X mutant Kir6.2 proteins confirmed that K(ATP) channel activity was abolished by this nonsense mutation. The identification of an HI patient homozygous for the Kir6.2/Y12X allele affords an opportunity to observe clinical features associated with mutations resulting in an absence of Kir6.2. These data provide evidence that mutations in the Kir6.2 subunit of the islet beta-cell K(ATP) channel are associated with the HI phenotype and also suggest that the majority of HI cases are not attributable to mutations in the coding region of the Kir6.2 gene.

Dysregulation of insulin secretion in children with congenital hyperinsulinism due to sulfonylurea receptor mutations.

Mutations in the high-affinity sulfonylurea receptor (SUR)-1 cause one of the severe recessively inherited diffuse forms of congenital hyperinsulinism or, when associated with loss of heterozygosity, focal adenomatosis. We hypothesized that SUR1 mutations would render the beta-cell insensitive to sulfonylureas and to glucose. Stimulated insulin responses were compared among eight patients with diffuse hyperinsulinism (two mutations), six carrier parents, and ten normal adults. In the patients with diffuse hyperinsulinism, the acute insulin response to intravenous tolbutamide was absent and did not overlap with the responses seen in either adult group. There was positive, albeit significantly blunted, acute insulin response to intravenous dextrose in the patients with diffuse hyperinsulinism. Graded infusions of glucose, to raise and then lower plasma glucose concentrations over 4 h, caused similar rises in blood glucose but lower peak insulin levels in the hyperinsulinemic patients. Loss of acute insulin response to tolbutamide can identify children with diffuse SUR1 defects. The greater response to glucose than to tolbutamide indicates that ATP-sensitive potassium (KATP) channel-independent pathways are involved in glucose-mediated insulin release in patients with diffuse SUR1 defects. The diminished glucose responsiveness suggests that SUR1 mutations and lack of KATP channel activity may contribute to the late development of diabetes in patients with hyperinsulinism independently of subtotal pancreatectomy.

Structures of bovine glutamate dehydrogenase complexes elucidate the mechanism of purine regulation.

Glutamate dehydrogenase is found in all organisms and catalyses the oxidative deamination of l-glutamate to 2-oxoglutarate. However, only animal GDH utilizes both NAD(H) or NADP(H) with comparable efficacy and exhibits a complex pattern of allosteric inhibition by a wide variety of small molecules. The major allosteric inhibitors are GTP and NADH and the two main allosteric activators are ADP and NAD(+). The structures presented here have refined and modified the previous structural model of allosteric regulation inferred from the original boGDH.NADH.GLU.GTP complex. The boGDH.NAD(+).alpha-KG complex structure clearly demonstrates that the second coenzyme-binding site lies directly under the "pivot helix" of the NAD(+) binding domain. In this complex, phosphates are observed to occupy the inhibitory GTP site and may be responsible for the previously observed structural stabilization by polyanions. The boGDH.NADPH.GLU.GTP complex shows the location of the additional phosphate on the active site coenzyme molecule and the GTP molecule bound to the GTP inhibitory site. As expected, since NADPH does not bind well to the second coenzyme site, no evidence of a bound molecule is observed at the second coenzyme site under the pivot helix. Therefore, these results suggest that the inhibitory GTP site is as previously identified. However, ADP, NAD(+), and NADH all bind under the pivot helix, but a second GTP molecule does not. Kinetic analysis of a hyperinsulinism/hyperammonemia mutant strongly suggests that ATP can inhibit the reaction by binding to the GTP site. Finally, the fact that NADH, NAD(+), and ADP all bind to the same site requires a re-analysis of the previous models for NADH inhibition.

Characterization of somatogenic and lactogenic binding sites in isolated rat hepatocytes.

Suspensions of rat hepatocytes isolated enzymatically by the method of Berry and Friend were used to study the binding of 125I-labeled human (hGH) and bovine (bGH) growth hormones and ovine prolactin (oPRL). Displacement of these labeled hormones by their unlabeled analogues was analyzed by means of Scatchard plots and affinity constants (K) and the number of binding sites per cell (q) were calculated. Specificity of binding was studied using hGH, bGH oPRL and rat growth hormone (rGH) and rat prolactin (rPRL). Rat hepatocytes contained two types of binding sites which bound hGH. The first, somatogenic, was specific for the growth-promoting hormones bGH and rGH. The second, lactogenic, was specific for lactogenic hormones, oPRL and rPRL. Human GH, which has both lactogenic and growth-promoting properties in rodents, bound to both sites. The somatogenic binding sites were present in both males and females, and the number of sites was similar in females and in males and was not affected by hypophysectomy. The lactogenic binding sites were present only in females, and the number of lactogenic and somatogenic sites was similar (40,000/cell). The affinity of hGH for the lactogenic binding sites was less than for the somatogenic (0.37 X 10(9) vs. 1 X 10(9)M-1). The lactogenic binding sites were lost when female rats were hypophysectomized and could not be restored by estrogen treatment.

Suppression of insulin oversecretion by subcutaneous recombinant human insulin-like growth factor I in children with congenital hyperinsulinism due to defective beta-cell sulfonylurea receptor.

Congenital hyperinsulinism (HI) is the most common cause of persistent hypoglycemia in infants under 1 yr of age. HI is most often due to defective glucose-insulin coupling by the beta-cell sulfonylurea receptor (SUR1) or glutamate dehydrogenase. HI-induced hypoglycemia carries significant morbidity, and current therapies are suboptimal. Insulin-like growth factor I (IGF-I) decreases insulin secretion in vitro and in healthy adults in vivo. We postulated that recombinant human IGF-I (rhIGF-I) could benefit children with HI and hypoglycemia by decreasing insulin levels and improving fasting tolerance. We enrolled nine subjects in an open label trial of rhIGF-I: eight children, ages 1 month to 11 yr, with HI due to identified mutations of SUR1 (n = 5) or clinically unresponsive to diazoxide, which acts via the SUR (n = 3), and one adult, age 32 yr, with HI due to defective glutamate dehydrogenase-1. All had suboptimal glycemic control and served as their own controls. Subjects underwent 24-h glucose monitoring under their home regimens, followed by a supervised fasting study. The controlled fast was terminated when the subject became hypoglycemic (blood glucose, <50 mg/dL) or developed symptoms consistent with hypoglycemia. The fast was repeated 2 days later with administration of rhIGF-I at 40 microg/kg, s.c., every 12 h. At the start of fasting rhIGF-I lowered the mean serum insulin level by 70% (21.0 +/- 11.1 vs. 6.3 +/- 2.2 microIU/mL; P < 0.04) and lowered the mean serum C peptide level by 43% (2.1 +/- 0.7 vs. 1.2 +/- 0.6 ng/mL; P < 0.04). rhIGF-I suppression of insulin and C peptide persisted throughout the fast. The duration of fasting did not change significantly with rhIGF-I treatment. We have directly demonstrated that rhIGF-I inhibits insulin oversecretion in children with HI due to defective SUR1. Our data suggest that IGF inhibition of insulin secretion does not require an intact SUR. rhIGF-I is unlikely to be effective monotherapy for HI, but may provide synergy to inhibit insulin secretion when combined with agents acting via IGF-independent mechanisms.

Dual regulation of insulin-like growth factor binding protein-1 levels by insulin and cortisol during fasting.

Insulin-like growth factor (IGF) binding protein-1 (IGFBP-1) gene transcription is known to be inhibited by insulin in vivo and in vitro. Levels of IGFBP-1 typically rise during fasting but also rise after acute hypoglycemia, including that induced by insulin, through an unknown mechanism that may involve counterregulatory hormones such as cortisol. To study the regulation of IGFBP-1 secretion during fasting, we measured IGFBP-1, insulin, cortisol, GH, and glucose during the course of standardized fasting studies in a total of 21 children. The fasting studies lasted 13-32 h and were terminated for a whole-blood glucose concentration of less than 50 mg/dL (2.8 mmol). Of the children studied, 9 children had no disorder, 8 had ketotic hypoglycemia, 2 had isolated GH deficiency, and 2 had fatty acid oxidation disorders. During fasting, IGFBP-1 rose above the mean baseline levels of 28+/-5 ng/mL to a mean level+/-SEM of 336+/-59 ng/mL at the time of hypoglycemia (P=0.001). IGFBP-1 was strongly associated with serum insulin and cortisol levels over the entire course of fasting (P < 0.0001)). The interaction of the 2 hormones across time was also strongly significant (P < 0.0001). There was no statistically significant association between IGFBP-1 and GH or glucose. At the time of hypoglycemia, insulin levels were suppressed to 1.7 microU/mL or less, and there was no correlation between IGFBP-1 levels at the end of fasting and final insulin level. In contrast, cortisol levels correlated with IGFBP-1 in the final hypoglycemic sample (r=0.56, P < 0.01). Partial correlation analysis revealed that the relationship between IGFBP-1 and cortisol was unchanged when the data was controlled for insulin levels. These data show that insulin and cortisol both regulate IGFBP-1 secretion during fasting; the effects of insulin and cortisol are strong during the course of fasting. Significant hypoglycemia stimulates a further rise in IGFBP-1, which seems to be regulated, in part, by cortisol. The cortisol-induced rise in IGFBP-1 during fasting and during hypoglycemia potentially serves to prevent the hypoglycemic effects of free IGFs.

Hyperinsulinism/hyperammonemia syndrome in children with regulatory mutations in the inhibitory guanosine triphosphate-binding domain of glutamate dehydrogenase.

The hyperinsulinism/hyperammonemia (HI/HA) syndrome is a form of congenital hyperinsulinism in which affected children have recurrent symptomatic hypoglycemia together with asymptomatic, persistent elevations of plasma ammonium levels. We have shown that the disorder is caused by dominant mutations of the mitochondrial enzyme, glutamate dehydrogenase (GDH), that impair sensitivity to the allosteric inhibitor, GTP. In 65 HI/HA probands screened for GDH mutations, we identified 19 (29%) who had mutations in a new domain, encoded by exons 6 and 7. Six new mutations were found: Ser(217)Cys, Arg(221)Cys, Arg(265)Thr, Tyr(266)Cys, Arg(269)Cys, and Arg(269)HIS: In all five mutations tested, lymphoblast GDH showed reduced sensitivity to allosteric inhibition by GTP (IC(50), 60--250 vs. 20--50 nmol/L in normal subjects), consistent with a gain of enzyme function. Studies of ATP allosteric effects on GDH showed a triphasic response with a decrease in high affinity inhibition of enzyme activity in HI/HA lymphoblasts. All of the residues altered by exons 6 and 7 HI/HA mutations lie in the GTP-binding domain of the enzyme. These data confirm the importance of allosteric regulation of GDH as a control site for amino acid-stimulated insulin secretion and indicate that the GTP-binding site is essential for regulation of GDH activity by both GTP and ATP.

Acute insulin responses to leucine in children with the hyperinsulinism/hyperammonemia syndrome.

Mutations of glutamate dehydrogenase cause the hyperinsulinism/hyperammonemia syndrome by desensitizing glutamate dehydrogenase to allosteric inhibition by GTP. Normal allosteric activation of glutamate dehydrogenase by leucine is thus uninhibited, leading us to propose that children with hyperinsulinism/hyperammonemia syndrome will have exaggerated acute insulin responses to leucine in the postabsorptive state. As hyperglycemia increases beta-cell GTP, we also postulated that high glucose concentrations would extinguish abnormal responsiveness to leucine in hyperinsulinism/hyperammonemia syndrome patients. After an overnight fast, seven hyperinsulinism/hyperammonemia syndrome patients (aged 9 months to 29 yr) had acute insulin responses to leucine performed using an iv bolus of L-leucine (15 mg/kg) administered over 1 min and plasma insulin measurements obtained at -10, -5, 0, 1, 3, and 5 min. The acute insulin response to leucine was defined as the mean increase in insulin from baseline at 1 and 3 min after an iv leucine bolus. The hyperinsulinism/hyperammonemia syndrome group had excessively increased insulin responses to leucine (mean +/- SEM, 73 +/- 21 microIU/ml) compared with the control children and adults (n = 17) who had no response to leucine (1.9 +/- 2.7 microU/ml; P < 0.05). Four hyperinsulinism/hyperammonemia syndrome patients then had acute insulin responses to leucine repeated at hyperglycemia (blood glucose, 150-180 mg/dl). High blood glucose suppressed their abnormal baseline acute insulin responses to leucine of 180, 98, 47, and 28 microU/ml to 73, 0, 6, and 19 microU/ml, respectively. This suppression suggests that protein-induced hypoglycemia in hyperinsulinism/hyperammonemia syndrome patients may be prevented by carbohydrate loading before protein consumption.

Hyperinsulinism in infancy: diagnosis by demonstration of abnormal response to fasting hypoglycemia.

The metabolic adaptation to fasting in infants with hyperinsulinism was examined to see whether a characteristic abnormality could be found that would aid in the diagnosis of this disorder. Seven infants under 1 year of age with hyperinsulinism were studied; 7 control infants of similar age and 12 children with ketotic hypoglycemia served as contrast groups. At the time of hypoglycemia, four of the seven infants with hyperinsulinism did not have elevated levels of insulin. However, levels of beta-hydroxybutyrate were significantly lower in the infants with hyperinsulinism than in the control and ketotic hypoglycemic groups. Levels of free fatty acids were also lower in the infants with hyperinsulinism. Expected levels and normal limits for beta-hydroxybutyrate, insulin, and free fatty acids when plasma glucose is below 40 mg/100 ml were estimated by combining the control and ketotic hypoglycemic groups. Using these values as standards, the diagnosis of hyperinsulinism can be made by evaluation of the response to fasting hypoglycemia. The application of this approach is illustrated by three case examples.

Massive hepatomegaly, steatosis, and secondary plasma carnitine deficiency in an infant with cystic fibrosis.

Hepatomegaly and steatosis are common findings in children with cystic fibrosis and are most often attributed to malnutrition. An infant fed a carnitine-free soy formula is described. Massive hepatomegaly and steatosis developed in the baby at a time of severe viral respiratory illness, prolonged fasting, hypoglycemia, and hypoketonuria. The infant was found to have secondary plasma carnitine deficiency and excessive loss of carnitine in the urine as part of a more generalized renal tubular dysfunction accompanying vitamin D deficiency and secondary hyperparathyroidism. With correction of the metabolic abnormalities and institution of a high carnitine diet, the hepatomegaly disappeared, plasma carnitine returned to normal levels, and the renal carnitine loss ceased. The findings suggest that secondary carnitine deficiency may play a role in fatty infiltration of the liver in patients with cystic fibrosis, especially during times of severe fasting stress.

Metabolic fuel and hormone responses to fasting in newborn infants.

To examine why newborn infants frequently cannot maintain adequate levels of plasma glucose in the interval between delivery and the time they are first fed, circulating metabolic fuel and regulatory hormone concentrations were determined in 44 healthy infants at the end of an eight-hour postnatal fast. Plasma glucose fell below 40 mg/100 ml prior to eight hours in four of 24 term-appropriate-for-gestational-age (AGA), two of nine preterm-AGA, five of six term-small-for-gestational-age (SGA), and three of five preterm-SGA infants. Fuel and hormone patterns in the premature and SGA infants were not different from those found in term-AGA infants. Results in these neonates differed in two areas from the response to fasting seen later in life. In fasted term-AGA infants, ketones were low (beta-hydroxybutyrate 0.29 +/- 0.04 mM/liter) despite elevated concentrations of fatty acid precursors (1.4 +/- 0.07 mM/liter), and the group of infants studied failed to demonstrate the increase in plasma ketones with lower glucose levels (r = ".23, P = .07) which is found in older children. Levels of glucose precursors were two to three times higher in term-AGA infants (lactate 2.9 +/- 0.2 mM/liter; alanine 0.48 +/- 0.02 mM/liter) than levels found beyond the neonatal period and, in contrast to older children and adults, were not diminished in infants with lower plasma glucose (lactate, r = -.28, P less than .035; alanine, r = -33, P less than .02). These differences between the responses to postnatal fasting and those seen beyond the neonatal period suggest that the capacity for both hepatic ketone synthesis and gluconeogenesis is not fully developed at birth.

Hypoglycemia, hypotonia, and cardiomyopathy: the evolving clinical picture of long-chain acyl-CoA dehydrogenase deficiency.

Inherited defects in fatty acid oxidation, which have been described and diagnosed with increasing frequency in the last decade, are most commonly attributed to a deficiency in the activity of medium-chain acyl-CoA dehydrogenase. Few cases of the related enzyme defect of long-chain acyl-CoA dehydrogenase activity have been reported. An infant with documented long-chain acyl-CoA dehydrogenase deficiency is described with a detailed metabolic profile, long-term clinical follow-up, and response to treatment. This patient is compared with the seven previously published cases of this disorder in order to stress the unique features of the initial presentation, more subtle late manifestations of the disease, and clinical and biochemical differentiation from the more common medium-chain acyl-CoA dehydrogenase deficiency. This report stresses the enlarging spectrum of the clinical presentation and natural history of this defect in fatty acid oxidation.

Decreased oxygenation and hyperlipemia during intravenous fat infusions in premature infants.

Eighteen appropriate-for-gestational-age premature infants with birth weights ranging from 0.77 to 1.89 kg received 1 gm/kg of body weight of fat emulsion, intravenously, over a four-hour period. Infants less than 1 week of age developed a significant decrease in PO2 levels (P < 5.0) during the fat infusion period. There were no changes in other pulmonary function parameters. Infants less than 1 week of age also developed significantly higher peak levels of plasma triglycerides than infants 2 to 3 weeks old (P < .05). A correlation between increment in triglyceride levels and postnatal age was demonstrated (r = .75), with the younger infants presenting the higher triglyceride levels. This study demonstrates that: (1) small premature infants receiving intravenous fat are more susceptible to hyperlipemia and hypoxemia during the first week of life; (2) hypoxemia associated with intravenous fat infusion does not result from changes in lung dynamics; (3) the capacity to tolerate intravenous fats is enhanced after the first week of life.