Project description:Harlequin ichthyosis (HI) is the most severe form of autosomal recessive congenital ichthyosis, presenting at birth with distinctive facial features and thick, plate-like scales over the entire body. The abnormal skin barrier predisposes the patient to multiple complications, including dehydration and sepsis. Mortality rates of babies with HI have been greatly reduced since the introduction of systemic retinoid therapy. Mutations in ABCA12 have been found to lead to HI. Most of these mutations are truncation or deletion mutations in the conserved region of the protein, leading to severe loss of ABCA12 function. We report a case of HI caused by a compound heterozygous mutation (a known single nucleotide deletion and a novel single nucleotide substitution) in the ABCA12 gene.
Project description:Disruption of circadian rhythms increases the risk of several types of cancer. Mammalian cryptochromes (CRY1 and CRY2) are circadian transcriptional repressors that are related to DNA repair enzymes. While CRYs lack DNA repair activity, they modulate the transcriptional response to DNA damage, and CRY2 can promote SCFFBXL3-mediated ubiquitination of c-MYC and other targets. Here, we characterize five mutations in CRY2 observed in human cancers in The Cancer Genome Atlas. We demonstrate that two orthologous mutations of mouse CRY2 (D325H and S510L) accelerate the growth of primary mouse fibroblasts expressing high levels of c-MYC. Neither mutant affects steady state levels of overexpressed c-MYC, and they have divergent impacts on circadian rhythms and on the ability of CRY2 to interact with SCFFBXL3. Unexpectedly, stable expression of either CRY2 D325H or of CRY2 S510L robustly suppresses P53 target gene expression, suggesting that this is the primary mechanism by which they influence cell growth.
Project description:The outcome for children with high-grade gliomas (HGG) remains dismal, with a two-year survival rate of only 10-30%. Approximately half of pediatric HGGs are diffuse intrinsic pontine glioma (DIPG), a brainstem tumor that arises almost exclusively in children. Genome-wide analyses of copy number imbalances previously showed that platelet derived growth factor receptor alpha (PDGFRA) is the most frequent target of focal amplification in pediatric HGGs. To determine whether the PDGFRA is also targeted by more subtle mutations not detected by copy number analysis, we sequenced all PDGFRA coding exons from a cohort of pediatric HGGs. Somatic activating mutations were identified in 14.4% (13/90) of non-brainstem pediatric HGGs and 4.7% (2/43) of DIPGs, including missense mutations and in-frame deletions and insertions not previously described. 40% of tumors with mutation showed concurrent amplification, while 60% carried heterozygous mutations. Six different mutations impacting different domains all resulted in ligand-independent receptor activation that was blocked by small molecule inhibitors of PDGFR. Expression of mutants in p53-null primary mouse astrocytes conferred a proliferative advantage in vitro, and generated HGGs in vivo with complete penetrance when implanted into brain. The gene expression signatures reflected the spectrum of human diffuse HGGs. PDGFRA intragenic deletion of exons 8 and 9 were previously shown in adult HGG, but were not detected in 83 non-brainstem pediatric HGG and 57 DIPGs. Thus, a distinct spectrum of mutations confers constitutive receptor activation and oncogenic activity to PDGFR in childhood HGG. To better understand the consequence of PDGFRα mutation in pediatric gliomagenesis, retroviral constructs expressing wild-type PDGFRα or six selected PDGFRα mutants that affect different regions of the receptor were generated for functional studies. p53-null primary mouse astrocyte (PMA) cultures were chosen as a relevant cellular background to assess PDGFRα function.
Project description:The derivation of microglia from human pluripotent stem cells provides systems for understanding microglial biology and enables functional studies of neurological disease-causing mutations. We describe a robust method for the derivation and maintenance of microglia from human stem cells, which are phenotypically and functionally comparable to primary human microglia. We used stem cell-derived microglia to study the consequences of missense mutations in the microglial-expressed protein Triggering Receptor Expressed on Myeloid cells 2 (TREM2), which are causal for a frontotemporal dementia-like (FTD-like) syndrome and Nasu-Hakola disease (NHD). While many ligands and functions for TREM2 have been described, it is not known how TREM2 signalling dysregulation affects specific elements of microglial biology to influence disease pathogenesis. We find that mutant TREM2 accumulates in its immature form, does not undergo typical proteolysis, and is not properly trafficked to the plasma membrane of patient-derived microglia. However, in the absence of plasma membrane TREM2, microglia differentiate normally, respond to stimulation with lipopolysaccharide, and are phagocytically competent. These data indicate that dementia-associated TREM2 mutations have subtle effects on microglia biology, consistent with the late adult-onset of disease in individuals with these mutations.
Project description:BackgroundAn increasing number of NFKB1 variants are being identified in patients with heterogeneous immunologic phenotypes.ObjectiveTo characterize the clinical and cellular phenotype as well as the management of patients with heterozygous NFKB1 mutations.MethodsIn a worldwide collaborative effort, we evaluated 231 individuals harboring 105 distinct heterozygous NFKB1 variants. To provide evidence for pathogenicity, each variant was assessed in silico; in addition, 32 variants were assessed by functional in vitro testing of nuclear factor of kappa light polypeptide gene enhancer in B cells (NF-κB) signaling.ResultsWe classified 56 of the 105 distinct NFKB1 variants in 157 individuals from 68 unrelated families as pathogenic. Incomplete clinical penetrance (70%) and age-dependent severity of NFKB1-related phenotypes were observed. The phenotype included hypogammaglobulinemia (88.9%), reduced switched memory B cells (60.3%), and respiratory (83%) and gastrointestinal (28.6%) infections, thus characterizing the disorder as primary immunodeficiency. However, the high frequency of autoimmunity (57.4%), lymphoproliferation (52.4%), noninfectious enteropathy (23.1%), opportunistic infections (15.7%), autoinflammation (29.6%), and malignancy (16.8%) identified NF-κB1-related disease as an inborn error of immunity with immune dysregulation, rather than a mere primary immunodeficiency. Current treatment includes immunoglobulin replacement and immunosuppressive agents.ConclusionsWe present a comprehensive clinical overview of the NF-κB1-related phenotype, which includes immunodeficiency, autoimmunity, autoinflammation, and cancer. Because of its multisystem involvement, clinicians from each and every medical discipline need to be made aware of this autosomal-dominant disease. Hematopoietic stem cell transplantation and NF-κB1 pathway-targeted therapeutic strategies should be considered in the future.
Project description:The functional consequences of cancer-associated missense mutations are unclear for majority of proteins, here we interrogated cancer mutation databases and identified recurrently mutated positions at structural contact interface of DNA-binding domains of SOX and POU family transcription factors. We used conversion of mouse embryonic fibroblasts (MEFs) to induced pluripotent stem cells (iPSCs) as a functional read out. In this study we identified several gain-of-function mutations that enhance cellular pluripotency reprogramming by SOX2 and OCT4. Wild type SOX17 does not support pluripotency reprogramming while recurrent missense mutation SOX17-V118M converts SOX17 into a pluripotency inducer, viability of cancer cells and provides protein stability. Here, we conclude that mutational profile of SOX and OCT family factors in cancer association can give direction to design high-performance reprogramming factors.
Project description:Missense mutations account for nearly 50% of pathogenic mutations in human genetic diseases, most lack effective treatments. Gene therapies, CRISPR-based gene editing, and RNA therapies including transfer RNA (tRNA) modalities are common strategies for potential treatments of genetic diseases. However, reported tRNA therapies are for nonsense mutations, how tRNAs can be engineered to correct missense mutations have not been explored. Here, we describe missense correcting tRNAs (mc-tRNAs) as a potential therapeutic modality for correcting pathogenic missense mutations. Mc-tRNAs are engineered tRNAs that are charged with one amino acid and read codons of another amino acid in translation in human cells. We first developed a series of fluorescence protein (FP)-based reporters that indicate successful correction of missense mutations via restoration of fluorescence signals. We engineered mc-tRNAs that effectively corrected Serine and Arginine missense mutations in the reporters and confirmed the amino acid substitution by protein mass spectrometry and mc-tRNA expression by tRNA sequencing. We examined the transcriptome response to the expression of mc-tRNAs and found some mc-tRNAs induced minimum transcriptomic changes. Furthermore, we applied an Arg-tRNAGln(CUG) mc-tRNA to rescue the autolytic activity of a pathogenic CAPN3 Arg-to-Gln mutant involved in limb-girdle muscular dystrophy type 2A. These results establish a versatile pipeline for mc-tRNA engineering and demonstrate the potential of mc-tRNA as an alternative therapeutic platform for the treatment of genetic disorders.
Project description:Missense mutations account for nearly 50% of pathogenic mutations in human genetic diseases, most lack effective treatments. Gene therapies, CRISPR-based gene editing, and RNA therapies including transfer RNA (tRNA) modalities are common strategies for potential treatments of genetic diseases. However, reported tRNA therapies are for nonsense mutations, how tRNAs can be engineered to correct missense mutations have not been explored. Here, we describe missense correcting tRNAs (mc-tRNAs) as a potential therapeutic modality for correcting pathogenic missense mutations. Mc-tRNAs are engineered tRNAs that are charged with one amino acid and read codons of another amino acid in translation in human cells. We first developed a series of fluorescence protein (FP)-based reporters that indicate successful correction of missense mutations via restoration of fluorescence signals. We engineered mc-tRNAs that effectively corrected Serine and Arginine missense mutations in the reporters and confirmed the amino acid substitution by protein mass spectrometry and mc-tRNA expression by tRNA sequencing. We examined the transcriptome response to the expression of mc-tRNAs and found some mc-tRNAs induced minimum transcriptomic changes. Furthermore, we applied an Arg-tRNAGln(CUG) mc-tRNA to rescue the autolytic activity of a pathogenic CAPN3 Arg-to-Gln mutant involved in limb-girdle muscular dystrophy type 2A. These results establish a versatile pipeline for mc-tRNA engineering and demonstrate the potential of mc-tRNA as an alternative therapeutic platform for the treatment of genetic disorders.