Background
Recurrent bacterial and fungal infections, eczema and elevated serum IgE levels characterize patients with the hyper-IgE syndrome (HIES). Known genetic causes for HIES are mutations in STAT3 and DOCK8, involved in signal transduction pathways. However, glycosylation defects have not been described in HIES. One crucial enzyme in the glycosylation pathway is Phosphoglucomutase 3 (PGM3), which catalyzes a key step in the synthesis of UDP-GlcNAc which is required for the biosynthesis of N-glycans.
Objective
To elucidate the genetic cause in HIES patients who do not carry mutations in STAT3 or DOCK8.
Methods
After establishing a linkage interval by SNP-chip genotyping and homozygosity mapping in two HIES families from Tunisia, mutational analysis was performed with selector-based, high-throughput sequencing. Protein expression was analyzed by Western blotting and glycosylation was profiled by mass spectrometry.
Results
Mutational analysis of candidate genes in a 11.9 Mb linkage region on chromosome 6 shared by two multiplex families identified two homozygous mutations in PGM3 which segregated with the disease status and followed a recessive inheritance trait. The mutations predict amino acid changes in Phosphoglucomutase-3; PGM3 (p.Glu340del and p.Leu83Ser). A third homozygous mutation (p.Asp502Tyr) and the p.Leu83Ser variant were identified in two other affected families, respectively. These hypomorphic mutations have impact on the biosynthetic reactions involving UDP-GlcNAc. Glycomic analysis revealed an aberrant glycosylation pattern in leukocytes demonstrated by a reduced level of tri-/tetra-antennary N-glycans. T cell proliferation and differentiation was impaired in patients. Most patients showed developmental delay and many had psychomotor retardation.
Conclusion
Impairment of PGM3 function leads to a novel primary (inborn) error of development and immunity, as biallelic hypomorphic mutations are associated with impaired glycosylation and a hyper-IgE-like phenotype.
In Drosophila melanogaster males, X‐chromosome monosomy is compensated by chromosome‐wide transcription activation. We found that complete dosage compensation during embryogenesis takes surprisingly long and is incomplete even after 10 h of development. Although the activating dosage compensation complex (DCC) associates with the X‐chromosome and MOF acetylates histone H4 early, many genes are not compensated. Acetylation levels on gene bodies continue to increase for several hours after gastrulation in parallel with progressive compensation. Constitutive genes are compensated earlier than developmental genes. Remarkably, later compensation correlates with longer distances to DCC binding sites. This time–space relationship suggests that DCC action on target genes requires maturation of the active chromosome compartment.
BackgroundNon-alcoholic steatohepatitis (NASH) has become a leading indication for liver transplantation. However, it often recurs in the graft and can also arise de novo in individuals transplanted for other indications. Post-transplant NASH (PT-NASH) is more aggressive and leads to accelerated fibrosis. The mechanistic basis of PT-NASH has not yet been defined and no specific therapeutic strategies are currently available.MethodsHere, we profiled the transcriptomes of livers with PT-NASH from liver transplant recipients to identify dysregulated genes, pathways, and molecular interaction networks.ResultsTranscriptomic changes in the PI3K-Akt pathway were observed in association with metabolic alterations in PT-NASH. Other significant changes in gene expression were associated with DNA replication, cell cycle, extracellular matrix organization, and wound healing. A systematic comparison with non-transplant NASH (NT-NASH) liver transcriptomes indicated an increased activation of wound healing and angiogenesis pathways in the post-transplant condition.ConclusionBeyond altered lipid metabolism, dysregulation of wound healing and tissue repair mechanisms may contribute to the accelerated development of fibrosis associated with PT-NASH. This presents an attractive therapeutic avenue to explore for PT-NASH to optimize the benefit and survival of the graft.
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