ABSTRACT
To evaluate a novel candidate disease gene, we engaged international collaborators and identified rare, biallelic, specifically homozygous, loss of function variants in SENP7 in 4 children from 3 unrelated families presenting with neurodevelopmental abnormalities, dysmorphism, and immunodeficiency. Their clinical presentations were characterized by hypogammaglobulinemia, intermittent neutropenia, and ultimately death in infancy for all 4 patients. SENP7 is a sentrin-specific protease involved in posttranslational modification of proteins essential for cell regulation, via a process referred to as deSUMOylation. We propose that deficiency of deSUMOylation may represent a novel mechanism of primary immunodeficiency.
ABSTRACT
TESS Research Foundation (TESS) is a patient-led nonprofit organization seeking to understand the basic biology and clinical impact of pathogenic variants in the SLC13A5 gene. TESS aims to improve the fundamental understanding of citrate's role in the brain, and ultimately identify treatments and cures for the associated disease. TESS identifies, organizes, and develops collaboration between researchers, patients, clinicians, and the pharmaceutical industry to improve the lives of those suffering from SLC13A5 citrate transport disorder. TESS and its partners have developed multiple molecular tools, cellular and animal models, and taken the first steps toward drug discovery and development for this disease. However, much remains to be done to improve our understanding of the disorder associated with SLC13A5 variants and identify effective treatments for this devastating disease. Here, we describe the available SLC13A5 resources from the community of experts, to foundational tools, to in vivo and in vitro tools, and discuss unanswered research questions needed to move closer to a cure.
Overview of research in SLC13A5 citrate transporter disorder SLC13A5 citrate transporter disorder is an ultra-rare, neurodevelopmental disorder that severely impacts cognition and motor control. It is characterized by frequent, intractable seizures that develop hours or days after birth, low tone, global developmental delay, a unique, varied, and difficult to categorize movement disorder, limited expressive verbal capabilities, tooth abnormalities, and increased citrate in both the CNS and serum. Seizures are frequently medically intractable, patients are often on multiple antiseizure medications and have frequent emergency room visits and hospitalizations for status epilepticus. SLC13A5 citrate transporter disorder is caused by mutations in the SLC13A5 gene which encodes a sodium-dependent citrate transporter, NaCT. NaCT is responsible for transporting citrate, a key molecule in cellular metabolism, from the extracellular space into cells, especially in the central nervous system and the liver. NaCT has been extensively studied in multiple animal models and affects lifespan and loss of some transporter activity actually improves metabolic syndrome in all animal species tested so far while causing mild neurological dysfunction in rodents. Although not definitively proven, it is presumed that loss of neuronal cell citrate transporter activity in the brain is the cause of seizures. Since the discovery of the disorder in 2014, there has been a rapid expansion in characterization of the disease. This has been aided by development of multiple models and molecular tools for studying wild type and mutant SLC13A5 making it a tractable candidate for therapeutic development. TESS Research Foundation is dedicated to driving SLC13A5 research and supporting children and families living with the disorder. Here, we describe the available SLC13A5 resources from the community of experts, to foundational tools, to in vivo and in vitro tools, and discuss unanswered research questions needed to move closer to a cure.
ABSTRACT
Purpose: Modeling disease variants in animals is useful for drug discovery, understanding disease pathology, and classifying variants of uncertain significance (VUS) as pathogenic or benign. Methods: Using Clustered Regularly Interspaced Short Palindromic Repeats, we performed a Whole-gene Humanized Animal Model procedure to replace the coding sequence of the animal model's unc-18 ortholog with the coding sequence for the human STXBP1 gene. Next, we used Clustered Regularly Interspaced Short Palindromic Repeats to introduce precise point variants in the Whole-gene Humanized Animal Model-humanized STXBP1 locus from 3 clinical categories (benign, pathogenic, and VUS). Twenty-six phenotypic features extracted from video recordings were used to train machine learning classifiers on 25 pathogenic and 32 benign variants. Results: Using multiple models, we were able to obtain a diagnostic sensitivity near 0.9. Twenty-three VUS were also interrogated and 8 of 23 (34.8%) were observed to be functionally abnormal. Interestingly, unsupervised clustering identified 2 distinct subsets of known pathogenic variants with distinct phenotypic features; both p.Tyr75Cys and p.Arg406Cys cluster away from other variants and show an increase in swim speed compared with hSTXBP1 worms. This leads to the hypothesis that the mechanism of disease for these 2 variants may differ from most STXBP1-mutated patients and may account for some of the clinical heterogeneity observed in the patient population. Conclusion: We have demonstrated that automated analysis of a small animal system is an effective, scalable, and fast way to understand functional consequences of variants in STXBP1 and identify variant-specific intensities of aberrant activity suggesting a genotype-to-phenotype correlation is likely to occur in human clinical variations of STXBP1.