RESUMO
TAF8 is part of the transcription factor TFIID complex. TFIID is crucial for recruiting the transcription factor complex containing RNA polymerase II. TAF8 deficiency was recently reported as causing a severe neurodevelopmental disorder in eight patients. We have ascertained three Muslim Arab couples with fetal brain malformations. Clinical, imaging, pathological, biochemical, and molecular analyses were performed. Pre-natal ultrasound performed in four pregnancies revealed massive cerebellar atrophy, microcephaly, cerebral and corpus callosum (CC) anomalies. Pre-natal MRI studies of two of the affected fetuses confirmed microcephaly, small vermis, abnormal sulcation pattern with malformation, and shortening of CC. The fetuses were found to carry a novel likely pathogenic homozygous variant (c.45 + 5 G > A) of TAF8, predicted to affect splicing and presenting autosomal recessive inheritance. Post-mortem examinations confirmed the imaging studies in one fetus. Dysmorphic features including hypertelorism, wide nasal bridge, clinodactyly, and hirsutism were present. Western blotting analysis in fibroblasts of an affected fetus demonstrated a significant reduction of TAF8 protein. We determined high expression levels of TAF8 which progressively diminish in fetal brains of WT mice. We report for the first time the fetal presentation of TAF8 deficiency due to a novel genetic variant, and study TAF8 presence during fetal and neonatal periods in mouse brains. Our study may contribute to understanding the role of TAF8 in the developing human brain.
RESUMO
Background: NGLY1 is an enigmatic enzyme with multiple functions across a wide range of species. In humans, pathogenic genetic variants in NGLY1 are linked to a variable phenotype of global neurological dysfunction, abnormal tear production, and liver disease presenting the rare autosomal recessive disorder N-glycanase deficiency. We have ascertained four NGLY1 deficiency patients who were found to carry a homozygous nonsense variant (c.1294G > T, p.Glu432*) in NGLY1. Methods: We created an ngly1 deficiency zebrafish model and studied the nervous and musculoskeletal (MSK) systems to further characterize the phenotypes and pathophysiology of the disease. Results: Nervous system morphology analysis has shown significant loss of axon fibers in the peripheral nervous system. In addition, we found muscle structure abnormality of the mutant fish. Locomotion behavior analysis has shown hypersensitivity of the larval ngly1 (-/-) fish during stress conditions. Conclusion: This first reported NGLY1 deficiency zebrafish model might add to our understanding of NGLY1 role in the development of the nervous and MSK systems. Moreover, it might elucidate the natural history of the disease and be used as a platform for the development of novel therapies.