Oral sialic acid supplementation in NANS-CDG: Results of a single center, open-label, observational pilot study.

NANS-CDG is a congenital disorder of glycosylation (CDG) caused by biallelic variants in NANS, encoding an essential enzyme in de novo sialic acid synthesis. It presents with intellectual developmental disorder (IDD), skeletal dysplasia, neurologic impairment, and gastrointestinal dysfunction. Some patients suffer progressive intellectual neurologic deterioration (PIND), emphasizing the need for a therapy. In a previous study, sialic acid supplementation in knockout nansa zebrafish partially rescued skeletal abnormalities. Here, we performed the first in-human pre- and postnatal sialic-acid study in NANS-CDG. In this open-label observational study, 5 patients with NANS-CDG (range 0-28 years) were treated with oral sialic acid for 15 months. The primary outcome was safety. Secondary outcomes were psychomotor/cognitive testing, height and weight, seizure control, bone health, gastrointestinal symptoms, and biochemical and hematological parameters. Sialic acid was well tolerated. In postnatally treated patients, there was no significant improvement. For the prenatally treated patient, psychomotor and neurologic development was better than two other genotypically identical patients (one treated postnatally, one untreated). The effect of sialic acid treatment may depend on the timing, with prenatal treatment potentially benefiting neurodevelopmental outcomes. Evidence is limited, however, and longer-term follow-up in a larger number of prenatally treated patients is required.

Novel Treatment for Congenital Disorder of Glycosylation in a Patient with Novel Homozygote Mutation of PMM2: A Case Report and Review Literature.

BACKGROUND: In Congenital Disorder of Glycosylation (CDG) type Ia, homozygous mutations of the PMM2 gene cause phosphomannomutase 2 dysfunction. CASE PRESENTATION: Herein, a 10-month-old girl, is presented with severe hypotonia, along with inappropriately normal mental status and normal facies. High 2-ketoglutaric acid was detected in her urine, therefore, the diagnosis of 2-Ketoglutarate dehydrogenase complex (KDHC) deficiency was made for this patient. A high dose of vitamin B1 was administered because thiamine is considered a co-factor in this inborn error of metabolism. She responded very well to the daily administration of 500 mg/day vitamin B1 and stood up without help 5 months later. She had also experienced a seizure, which responded well to pyridoxine. Then, she grew up into a 3.5-years-old child who could talk and walk normally. Recently, whole-exome sequencing was performed for her, which showed homozygote mutation of PMM2, therefore, the diagnosis was changed from KDHC deficiency to PMM2-CDG. CONCLUSION: Paying attention to the pathophysiology of inborn errors of metabolism is necessary while considering the defective enzyme co-factor, which may help us to find an option for the treatment of such rare diseases.

D-galactose supplementation in individuals with PMM2-CDG: results of a multicenter, open label, prospective pilot clinical trial.

PMM2-CDG is the most prevalent congenital disorder of glycosylation (CDG) with only symptomatic therapy. Some CDG have been successfully treated with D-galactose. We performed an open-label pilot trial with D-galactose in 9 PMM2-CDG patients. Overall, there was no significant improvement but some milder patients did show positive clinical changes; also there was a trend toward improved glycosylation. Larger placebo-controlled studies are required to determine whether D-galactose could be used as supportive treatment in PMM2-CDG patients.Trial registration ClinicalTrials.gov Identifier: NCT02955264. Registered 4 November 2016, https://clinicaltrials.gov/ct2/show/NCT02955264.

Clinical and biochemical improvement with galactose supplementation in SLC35A2-CDG.

PURPOSE: We studied galactose supplementation in SLC35A2-congenital disorder of glycosylation (SLC35A2-CDG), caused by monoallelic pathogenic variants in SLC35A2 (Xp11.23), encoding the endoplasmic reticulum (ER) and Golgi UDP-galactose transporter. Patients present with epileptic encephalopathy, developmental disability, growth deficiency, and dysmorphism. METHODS: Ten patients with SLC35A2-CDG were supplemented with oral D-galactose for 18 weeks in escalating doses up to 1.5 g/kg/day. Outcome was assessed using the Nijmegen Pediatric CDG Rating Scale (NPCRS, ten patients) and by glycomics (eight patients). RESULTS: SLC35A2-CDG patients demonstrated improvements in overall Nijmegen Pediatric CDG Rating Scale (NPCRS) score (P = 0.008), the current clinical assessment (P = 0.007), and the system specific involvement (P = 0.042) domains. Improvements were primarily in growth and development with five patients resuming developmental progress, which included postural control, response to stimuli, and chewing and swallowing amelioration. Additionally, there were improvements in gastrointestinal symptoms and epilepsy. One patient in our study did not show any clinical improvement. Galactose supplementation improved patients' glycosylation with decreased ratios of incompletely formed to fully formed glycans (M-gal/disialo, P = 0.012 and monosialo/disialo, P = 0.017) and increased levels of a fully galactosylated N-glycan (P = 0.05). CONCLUSIONS: Oral D-galactose supplementation results in clinical and biochemical improvement in SLC35A2-CDG. Galactose supplementation may partially overcome the Golgi UDP-galactose deficiency and improves galactosylation. Oral galactose is well tolerated and shows promise as dietary therapy.

[Deep venous thrombosis treated by rivaroxaban in a young patient with type Ia carbohydrate-deficient glycoprotein (CDG) syndrome]. / Thrombose veineuse profonde traitée par rivaroxaban chez une jeune patiente atteinte de carbohydrate-deficient glycoprotein syndrome de type Ia.

Congenital disorders of glycosylation (CDG) are rare inborn diseases of glycan component of N-glycosylated proteins. We report here the case of a 28-year-old patient with CDG syndrome type Ia, who presented with a deep venous thrombosis in the left suro-popliteal vein with no known triggers or antecedents. The patient was treated with rivaroxaban for six months. Blood tests performed after discontinuing anticoagulant treatment showed multiple abnormalities affecting the proteins involved in haemostasis (both coagulation factors and inhibitors), i.e. a combined factor XI, antithrombin and protein C deficiency (35%, 41%, and 42% respectively) associated with a moderate increase of FVIII (179%) and VWFAg (163%) without inflammation. Patient results are here discussed with regard to the limited number of articles addressing haemostasis in this rare disease, as the occurrence of deep venous thrombosis remains uncommon in the literature.

Seizures and stupor during intravenous mannose therapy in a patient with CDG syndrome type 1b (MPI-CDG).

MPI-CDG (formally called CDG 1b), caused by phosphomannose isomerase (MPI) deficiency, leads to hypoglycaemia, protein losing enteropathy, hepatopathy, and thrombotic events, whereas neurologic development remains unaffected. Dietary supplementation of mannose can reverse clinical symptoms by entering the N-glycosylation pathway downstream of MPI. When oral intake of mannose in patients with MPI-CDG is not possible, e.g. due to surgery, mannose has to be given intravenously. We report a patient with MPI-CDG on intravenous mannose therapy that showed severe depression of consciousness and seizures without apparent cause. EEG and cranial MRI findings were compatible with metabolic coma whereas extended laboratory examinations including repeated blood glucose measurements were normal. Importantly, an intravenous bolus of glucose immediately led to clinical recovery and EEG improvement. Mannose did not interfere with glucose measurement in our assay. We suggest that in patients with MPI-CDG, intravenous mannose infusion can lead to intracellular ATP deprivation due to several mechanisms: (1) in MPI deficiency, mannose 6-P cannot be isomerised to fructose 6-P and therefore is unavailable for glycolysis; (2) animal data has shown that accumulating intracellular mannose 6-P inhibits glycolysis; and (3) elevated intracellular mannose 6-P may induce an ATP wasting cycle of dephosphorylation and rephosphorylation ("honey bee effect"). The mannose-induced metabolic inhibition may be overcome by high-dose glucose treatment. We caution that, in patients with MPI-CDG, life-threatening central nervous system disturbances may occur with intravenous mannose treatment. These may be due to intracellular energy failure. Clinical symptoms of energy deficiency should be treated early and aggressively with intravenous glucose regardless of blood glucose levels.