Congenital disorder of glycosylation type Ij (CDG-Ij, DPAGT1-CDG): extending the clinical and molecular spectrum of a rare disease.

Congenital disorders of glycosylation (CDG) are caused by enzymatic defects of the formation or processing of lipid-linked oligosaccharides and glycoproteins. Since the majority of proteins is glycosylated, a defect in a singular CDG enzyme leads to a multisytemic disease with secondary malfunction of thousands of proteins. CDG-Ij (DPAGT1-CDG) is caused by a defect of the human DPAGT1 (UDP-GlcNAc: Dolichol Phosphate N-Acetylglucosamine-1-Phosphotransferase), catalyzing the first step of N-linked glycosylation. So far the clinical phenotype of only one CDG-Ij patient has been described. The patient showed severe muscular hypotonia, intractable seizures, developmental delay, mental retardation, microcephaly and exotropia. Molecular studies of this patient revealed the heterozygous mutation c.660A>G (Y170C; paternal) in combination with an uncharacterized splicing defect (maternal). Two further mutations, c.890A>T (I297F) and c.162-8G>A as a splicing defect were detected when analyzing DPAGT1 in two affected siblings of a second family. We report two new patients with the novel homozygous mutation, c.341C>G (A114 G), causing a severe clinical phenotype, characterized by hyperexcitability, intractable seizures, bilateral cataracts, progressive microcephaly and muscular hypotonia. Both our patients died within their first year of life. With the discovery of this novel mutation and a detailed clinical description we extend the clinical features of CDG-Ij in order to improve early detection of this disease.

Location and type of mutation in the LIS1 gene do not predict phenotypic severity.

BACKGROUND: Lissencephaly is a neuronal migration disorder leading to absent or reduced gyration and a broadened but poorly organized cortex. The most common form of lissencephaly is isolated, referred as classic or type 1 lissencephaly. Type 1 lissencephaly is mostly associated with a heterozygous deletion of the entire LIS1 gene, whereas intragenic heterozygous LIS1 mutations or hemizygous DCX mutations in males are less common. METHODS: Eighteen unrelated patients with type 1 lissencephaly were clinically and genetically assessed. In addition, patients with subcortical band heterotopia (n = 1) or lissencephaly with cerebellar hypoplasia (n = 2) were included. RESULTS: Fourteen new and seven previously described LIS1 mutations were identified. We observed nine truncating mutations (nonsense, n = 2; frameshift, n = 7), six splice site mutations, five missense mutations, and one in-frame deletion. Somatic mosaicism was assumed in three patients with partial subcortical band heterotopia in the occipital-parietal lobes or mild pachygyria. We report three mutations in exon 11, including a frameshift which extends the LIS1 protein, leading to type 1 lissencephaly and illustrating the functional importance of the WD domains at the C terminus. Furthermore, we present two patients with novel LIS1 mutations in exon 10 associated with lissencephaly with cerebellar hypoplasia type a. CONCLUSION: In contrast to previous reports, our data suggest that neither type nor position of intragenic mutations in the LIS1 gene allows an unambiguous prediction of the phenotypic severity. Furthermore, patients presenting with mild cerebral malformations such as subcortical band heterotopia or cerebellar hypoplasia should be considered for genetic analysis of the LIS1 gene.

Seizure control and acceptance of the ketogenic diet in GLUT1 deficiency syndrome: a 2- to 5-year follow-up of 15 children enrolled prospectively.

BACKGROUND: GLUT1 deficiency syndrome is caused by impaired glucose transport into the brain resulting in an epileptic encephalopathy, developmental delay, and a complex motor disorder. A ketogenic diet provides an alternative fuel to the brain and effectively restores brain energy metabolism. METHODS: Fifteen children with GLUT1 deficiency syndrome were enrolled prospectively for a 2.0 - 5.5-year follow-up of the effectiveness of a 3 : 1 LCT ketogenic diet. Eight patients enrolled were described previously, seven patients were novel. RESULTS: Four novel heterozygous GLUT1 mutations were identified. 10/15 patients remained seizure-free on the ketogenic diet in monotherapy. In 2/15 patients seizures recurred after 2(1/2) years despite adequate ketosis, but were controlled by add-on ethosuximide. In one patient seizures were reduced without complete seizure control. No serious adverse effects occurred and parental satisfaction with the diet was good. 2/15 patients discontinued the diet. CONCLUSION: GLUT1 deficiency syndrome represents a complex childhood encephalopathy that can be treated effectively by means of a ketogenic diet. The response to the diet did not correlate to clinical, biochemical, or genetic features of the disease. In contrast to previous reports, our results indicate that epilepsy is not always completely controlled by a ketogenic diet and can recur in a subset of patients.

An electron microscopic study of erythropoiesis in fetal and neonatal rabbits.

This investigation records the chronology of events relating to erythropoiesis in the late fetal and early neonatal rabbit. The formation of the marrow cavity in the rabbit femur and the changing cell population in the extravascular spaces are described for the period from day 24 of gestation to 8 weeks postpartum. In the fetal liver, erythropoiesis is shown to occur in typical red cell islands. As hepatic red cell production declines, lipid accumulates in the liver, much as fatty infiltration of marrow follows reduction of erythropoiesis in the marrow. The spleen appears to have erythropoietic potential although it does not normally contribute to red cell production in this animal. The spleen also appears to serve as a storage site for large numbers of platelets in the developing rabbit.

Iron-containing cytoplasmic inclusions in mouse bone marrow macrophages.

Elongated, tapered inclusions, present in the cytoplasm of macrophages in mouse bone marrow, were studied by electron microscopy. The bone marrow of adult mice that were injected with the hemolytic agent phenylhydrazine, displayed a statistically significant increase in the number of inclusions compared with bone marrow from control animals. Ultrastructural analysis demonstrated that ferritin, a known product of red cell destruction, was resent in these inclusions. It is suggested that the inclusions are derived from the degradation of phagocytosed red cells.