SLC35A1-CDG

SLC35A1-CDG is a rare inherited disorder that mainly affects the vascular systems of the body. It forms part of a large group of disorders called congenital disorders of glycosylation. It is caused by mutations in the SLC35A1 gene, located in the sixth chromosome.

Signs and symptoms

The following list comprises the symptoms of this condition (as listed by the HPO):

• Increased susceptibility to bleeding
• Structural abnormalities of the megakaryocytes
• Platelet granule anomalies
• Cellulitis
• Giant platelets (platelets larger than 7 micrometers)
• Low oxygen level in blood
• Neutropenia
• Pneumonia
• Longer time for injured areas on the skin to stop bleeding
• Pulmonary hemorrhage
• Respiratory distress
• Increased susceptibility of getting bruises
• Thrombocytopenia

Complications

There are various complications associated with this condition, all of which are associated with the symptoms listed above.

For example, the hypoxemia (decreased blood oxygen level) can result in hypoxia which will affect the heart and brain more severely if left untreated.

Diagnosis

This condition can be diagnosed by doing whole genome sequencing and by physical examination.

Genetics

Like the name implies, this condition is caused by mutations in the SLC35A1 gene, located in the long arm of the sixth chromosome. These mutations are inherited following an autosomal recessive manner, meaning that only people who are homozygous for the gene mutation are going to show the traits associated with it.

Treatment

Treatment is symptom-focused:

• Cellulitis can be treated with prescribed oral antibiotics.
• Hypoxemia can be treated with methods such as the use of oxygen tanks.
• Pneumonia treatment varies depending on the severity of said affliction, but generally, mild pneumonia can be treated with antibiotics, drinking liquids regularly, and by taking a rest. Other treatment methods include the use of pain-killers for reducing pain and fever which typically accompany pneumonia cases.
• Pulmonary hemorrhage treatment varies depending on whether or not it's localized, but in these cases (localized bleeding) methods such as bronchostopic therapy and surgery can help treat it.
• Respiratory distress treatment aims for the cause, but generally supplemental oxygen, mechanical ventilation machines, and medication can help treat it.

Prevalence

Like other congenital disorders of glycosylation, this condition is extremely rare, with (according to OMIM) only 3 un-related patients described in medical literature to date. (August 2022)

Cases

The following list comprises the only 3 cases of SLC35A1 ever reported in history (according to the OMIM page for the condition: #603585 CONGENITAL DISORDER OF GLYCOSYLATION, TYPE IIf; CDG2F)

• 2001: Willig et al. describes the first case of SLC35A1-CDG in medical history, a 4 month old male child who suffered from a spontaneous bleeding incident in the posterior chamber of his right eye which occurred alongside cutaneous hemorrhages, further laboratory studies revealed thrombocytopenia and neutropenia. In the next 30 months (2 years and 6 months) of his life, he suffered from high amounts of episodic multi-systemic bleeding, with one of these episodes including a severe pulmonary hemorrhage. The child also suffered from frequent recurrent bacterial infections, he later died from complications of a bone marrow transparent when he was 37 months (3 years, 1 month) old. In 2005, Martinez-Duncker et al. found two compound heterozygous missense mutations in the SLC35A1 gene of said child, out of those two mutations, one was a pathogenic truncating mutation, while the other was a common single-nucleotide polymorphism.
• 2013: Mohamed et al. describes the case of a 22-year old woman who was the child of consanguineous parents of Turkish origin. She started developing paychomotor delays and generalized tonic-clonic seizures at the age of 7 (even though she was normally developing before this age), and she then developed behavioural problems during puberty. She had microcephaly, a mild case of ataxia, decreased reflexes of the lower distal extremities, hypotonia, intellectual disability, a systolic cardiac murmur associated with aortic insufficiency, hypotelorism, flat occiput, deep-set eyes, shortened philtrum, webbed neck, clinodactyly of the fingers, bunions on both feet, and joint hypermobility by the time she was 20. Further laboratory studies showed macrothrombocytopenia, proteinuria, amino aciduria, and decreased amounts of coagulation factors. She perished when she was 22 years old because of post-surgery complications. Genetic testing of said woman revealed a homozygous missense mutation on the SLC35A1 gene, when genetic testing was performed on her parents, it was revealed that they were heterozygous carriers of the mutation. In vitro functional expression studies showed that this mutation (named Q101H) lead to CMP-Sia transport activity that was reduced by 50% compared to healthy control subjects. Mammalian cells that were deficient of SLC35A1 (due to the Q101H mutation) showed polysialic acid expression restoration that was reduced by 15% compared to the wild type version of the gene.
• 2017: Ng et al. describes a 12 year old girl of German descent, said child was born hypotonic and developed seizures alongside oro-facial tics at the age of 4 months. EEGs from a medically induced partial seizure revealed focal spikes alongside polyspikes. She had severe encephalopathy, severe psychomotor delays, and moderate intellectual disability (she had an IQ of less than 55), speech difficulties, ataxic-dyskinetic movements. Other features included nystagmus and autistic-like symptoms. Laboratory studies showed a serum transferrin CDG type II pattern and a combined defect in N- and O-glycosylation. After the use of whole exome sequencing, she was found to have compound heterozygous missense mutations (which were later termed as T156R and E196K) in the SLC35A1 gene, said mutations were confirmed by doing Sanger sequencing. Studies done on the cells of the child showed lowered amounts of N- and O-glycans which ended up as sialic acid alongside a severe loss of SLC35A1 transport function.

See also

• SRD5A3-CDG
• PMM2 deficiency

References