Autophagy is a cellular catabolic process that relies on the cooperation of autophagosomes and lysosomes. During starvation, the cell expands both compartments to enhance degradation processes. We found that starvation activates a transcriptional program that controls major steps of the autophagic pathway, including autophagosome formation, autophagosome-lysosome fusion and substrate degradation. The transcription factor EB (TFEB), a master gene for lysosomal biogenesis, coordinated this program by driving expression of autophagy and lysosomal genes. Nuclear localization and activity of TFEB were regulated by serine phosphorylation mediated by the extracellular signal-regulated kinase 2, whose activity was tuned by the levels of extracellular nutrients. Thus, a mitogen-activated protein kinase-dependent mechanism regulates autophagy by controlling the biogenesis and partnership of two distinct cellular organelles.
A lysosome-to-nucleus signalling mechanism senses and regulates the lysosome via mTOR and TFEBUnder basal conditions TFEB, a master regulator of lysosomal biogenesis, is sequestered in the cytosol due to mTORC1-dependent phosphorylation at the lysosomal membrane. Nutrient starvation or lysosomal dysfunction inhibit mTORC1 activity and induce nuclear translocation of TFEB inducing target gene expression.
The lysosomal-autophagic pathway is activated by starvation and plays an important role in both cellular clearance and lipid catabolism. However, the transcriptional regulation of this pathway in response to metabolic cues is currently uncharacterized. Here we show that the transcription factor EB (TFEB), a master regulator of lysosomal biogenesis and autophagy, is induced by starvation through an autoregulatory feedback loop and exerts a global transcriptional control on lipid catabolism via PGC1α and PPARα. Thus, during starvation a transcriptional mechanism links the autophagic pathway to cellular energy metabolism. The conservation of this mechanism in Caenorhabditis elegans suggests a fundamental role for TFEB in the evolution of the adaptive response to food deprivation. Viral delivery of TFEB to the liver prevented weight gain and metabolic syndrome in both diet-induced and genetic mouse models of obesity, suggesting a novel therapeutic strategy for disorders of lipid metabolism.
The rapid accrual of knowledge in genomic medicine has prompted the reanalysis of preexisting data. 1,2 We clinically reanalyzed data from two patient series that had undergone diagnostic proband-only exome sequencing.
Importance: While congenital malformations and genetic diseases are a leading cause of early infant death, the contribution of single-gene disorders in this group is undetermined. Objective: To determine the diagnostic yield and utility of clinical exome sequencing in critically ill infants. Design, setting, participants: Clinical exome sequencing was performed on 278 unrelated infants within the first 100 days of life, admitted to Texas Children’s Hospital in Houston, over a period of five years, between December 2011 and January 2017. Exome sequencing types included proband exome, trio exome, and critical trio exome, a rapid genomic assay for seriously-ill infants. Main outcomes and measures: Indications for testing, diagnostic yield of clinical exome sequencing, turnaround time, molecular findings, patient age at diagnosis, and impact on medical management in a group of critically ill infants suspected to have genetic disorders. Results: Clinical indications for exome sequencing included a wide range of medical concerns. Overall, molecular diagnosis was achieved in 102/278 infants by clinical exome sequencing with a diagnostic yield of 36.7%. The diagnosis affected medical management in 53/102 (52.0%) of infants, with substantial impact on informed redirection of care, initiation of new subspecialist care, medication/dietary modifications, and furthering life-saving procedures in select patients. Critical trio exome revealed a molecular diagnosis in 32/63 infants (50.8%) at 33.1±5.6 days of life with turnaround time (TAT) of 13.0 ± 0.4 days. Clinical care was altered by the diagnosis in 23/32 (71.9%) patients. The diagnostic yield, patient age at diagnosis, and medical impact in the group that underwent critical trio exome is significantly different comparing to regular exome testing. For deceased infants (n=81), genetic disorders were molecular diagnosed in 39 (48.1%) by exome sequencing with implications for recurrence risk counseling. Conclusions and relevance: Exome sequencing is a powerful tool for the diagnostic evaluation of critically ill infants with suspected monogenic disorders in the neonatal and pediatric ICUs, leading to notable impact on clinical decision-making.
The underlying genetic etiology of rhabdomyolysis remains elusive in a significant fraction of individuals presenting with recurrent metabolic crises and muscle weakness. Using exome sequencing, we identified bi-allelic mutations in TANGO2 encoding transport and Golgi organization 2 homolog (Drosophila) in 12 subjects with episodic rhabdomyolysis, hypoglycemia, hyperammonemia, and susceptibility to life-threatening cardiac tachyarrhythmias. A recurrent homozygous c.460G>A (p.Gly154Arg) mutation was found in four unrelated individuals of Hispanic/Latino origin, and a homozygous ∼34 kb deletion affecting exons 3-9 was observed in two families of European ancestry. One individual of mixed Hispanic/European descent was found to be compound heterozygous for c.460G>A (p.Gly154Arg) and the deletion of exons 3-9. Additionally, a homozygous exons 4-6 deletion was identified in a consanguineous Middle Eastern Arab family. No homozygotes have been reported for these changes in control databases. Fibroblasts derived from a subject with the recurrent c.460G>A (p.Gly154Arg) mutation showed evidence of increased endoplasmic reticulum stress and a reduction in Golgi volume density in comparison to control. Our results show that the c.460G>A (p.Gly154Arg) mutation and the exons 3-9 heterozygous deletion in TANGO2 are recurrent pathogenic alleles present in the Latino/Hispanic and European populations, respectively, causing considerable morbidity in the homozygotes in these populations.
BackgroundExome sequencing is now being incorporated into clinical care for pediatric and adult populations, but its integration into prenatal diagnosis has been more limited. One reason for this is the paucity of information about the clinical utility of exome sequencing in the prenatal setting.MethodsWe retrospectively reviewed indications, results, time to results (turnaround time, TAT), and impact of exome results for 146 consecutive “fetal exomes” performed in a clinical diagnostic laboratory between March 2012 and November 2017. We define a fetal exome as one performed on a sample obtained from a fetus or a product of conception with at least one structural anomaly detected by prenatal imaging or autopsy. Statistical comparisons were performed using Fisher’s exact test.ResultsPrenatal exome yielded an overall molecular diagnostic rate of 32% (n = 46/146). Of the 46 molecular diagnoses, 50% were autosomal dominant disorders (n = 23/46), 41% were autosomal recessive disorders (n = 19/46), and 9% were X-linked disorders (n = 4/46). The molecular diagnostic rate was highest for fetuses with anomalies affecting multiple organ systems and for fetuses with craniofacial anomalies. Out of 146 cases, a prenatal trio exome option designed for ongoing pregnancies was performed on 62 fetal specimens, resulting in a diagnostic yield of 35% with an average TAT of 14 days for initial reporting (excluding tissue culture time). The molecular diagnoses led to refined recurrence risk estimates, altered medical management, and informed reproductive planning for families.ConclusionExome sequencing is a useful diagnostic tool when fetal structural anomalies suggest a genetic etiology, but other standard prenatal genetic tests did not provide a diagnosis.Electronic supplementary materialThe online version of this article (10.1186/s13073-018-0582-x) contains supplementary material, which is available to authorized users.
De novo variants in DDX3X account for 1–3% of unexplained intellectual disability (ID) cases and are amongst the most common causes of ID especially in females. Forty‐seven patients (44 females, 3 males) have been described. We identified 31 additional individuals carrying 29 unique DDX3X variants, including 30 postnatal individuals with complex clinical presentations of developmental delay or ID, and one fetus with abnormal ultrasound findings. Rare or novel phenotypes observed include respiratory problems, congenital heart disease, skeletal muscle mitochondrial DNA depletion, and late‐onset neurologic decline. Our findings expand the spectrum of DNA variants and phenotypes associated with DDX3X disorders.
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