Genetic and phenotypic heterogeneity suggest therapeutic implications in SCN2A-related disorders.

Mutations in SCN2A, a gene encoding the voltage-gated sodium channel Nav1.2, have been associated with a spectrum of epilepsies and neurodevelopmental disorders. Here, we report the phenotypes of 71 patients and review 130 previously reported patients. We found that (i) encephalopathies with infantile/childhood onset epilepsies (≥3 months of age) occur almost as often as those with an early infantile onset (<3 months), and are thus more frequent than previously reported; (ii) distinct phenotypes can be seen within the late onset group, including myoclonic-atonic epilepsy (two patients), Lennox-Gastaut not emerging from West syndrome (two patients), and focal epilepsies with an electrical status epilepticus during slow sleep-like EEG pattern (six patients); and (iii) West syndrome constitutes a common phenotype with a major recurring mutation (p.Arg853Gln: two new and four previously reported children). Other known phenotypes include Ohtahara syndrome, epilepsy of infancy with migrating focal seizures, and intellectual disability or autism without epilepsy. To assess the response to antiepileptic therapy, we retrospectively reviewed the treatment regimen and the course of the epilepsy in 66 patients for which well-documented medical information was available. We find that the use of sodium channel blockers was often associated with clinically relevant seizure reduction or seizure freedom in children with early infantile epilepsies (<3 months), whereas other antiepileptic drugs were less effective. In contrast, sodium channel blockers were rarely effective in epilepsies with later onset (≥3 months) and sometimes induced seizure worsening. Regarding the genetic findings, truncating mutations were exclusively seen in patients with late onset epilepsies and lack of response to sodium channel blockers. Functional characterization of four selected missense mutations using whole cell patch-clamping in tsA201 cells-together with data from the literature-suggest that mutations associated with early infantile epilepsy result in increased sodium channel activity with gain-of-function, characterized by slowing of fast inactivation, acceleration of its recovery or increased persistent sodium current. Further, a good response to sodium channel blockers clinically was found to be associated with a relatively small gain-of-function. In contrast, mutations in patients with late-onset forms and an insufficient response to sodium channel blockers were associated with loss-of-function effects, including a depolarizing shift of voltage-dependent activation or a hyperpolarizing shift of channel availability (steady-state inactivation). Our clinical and experimental data suggest a correlation between age at disease onset, response to sodium channel blockers and the functional properties of mutations in children with SCN2A-related epilepsy.

Controversies and research agenda in nephropathic cystinosis: conclusions from a "Kidney Disease: Improving Global Outcomes" (KDIGO) Controversies Conference.

Nephropathic cystinosis is an autosomal recessive metabolic, lifelong disease characterized by lysosomal cystine accumulation throughout the body that commonly presents in infancy with a renal Fanconi syndrome and, if untreated, leads to end-stage kidney disease (ESKD) in the later childhood years. The molecular basis is due to mutations in CTNS, the gene encoding for the lysosomal cystine-proton cotransporter, cystinosin. During adolescence and adulthood, extrarenal manifestations of cystinosis develop and require multidisciplinary care. Despite substantial improvement in prognosis due to cystine-depleting therapy with cysteamine, no cure of the disease is currently available. Kidney Disease: Improving Global Outcomes (KDIGO) convened a Controversies Conference on cystinosis to review the state-of-the-art knowledge and to address areas of controversies in pathophysiology, diagnostics, monitoring, and treatment in different age groups. More importantly, promising areas of investigation that may lead to optimal outcomes for patients afflicted with this lifelong, systemic disease were discussed with a research agenda proposed for the future.

Programmed Cell Death in Cystinosis.

Cystinosis is a lethal autosomal recessive disease that has been known clinically for over 100 years. There are now specific treatments including dialysis, renal transplantation and the orphan drug, cysteamine, which greatly improve the duration and quality of patient life, however, the cellular mechanisms responsible for the phenotype are unknown. One cause, programmed cell death, is clearly involved. Study of extant literature via Pubmed on "programmed cell death" and "apoptosis" forms the basis of this review. Most of such studies involved apoptosis. Numerous model systems and affected tissues in cystinosis have shown an increased rate of apoptosis that can be partially reversed with cysteamine. Proposed mechanisms have included changes in protein signaling pathways, autophagy, gene expression programs, and oxidative stress.

The incidence of atubular glomeruli in nephropathic cystinosis renal biopsies.

Nephropathic cystinosis results from lysosomal cystine storage and, if untreated with cysteamine, results in end-stage renal disease by 10 years of age. The renal Fanconi syndrome occurs in the first year of life and is accompanied by a characteristic "swan neck" deformity of the proximal renal tubule. The linkage between cystine storage, Fanconi syndrome, and renal failure has not been understood. This study reports the presence of substantial numbers of atubular glomeruli (ATG) in end-stage cystinotic renal tissue. Compared to normal renal tissue, cystinotic kidneys at end stage had 69% atubular glomeruli and 30% atrophic glomeruli. Normal renal tissue had 4% ATG and 0% atrophic glomeruli (p<0.0001 for both comparisons). These nonfunctioning nephrons may be the end result of cell loss from the tubules and represent the final stage of the swan neck deformity. The process is consistent with the previously reported increased apoptosis in renal tubule cells due to lysosomal cystine storage.

Microvesicle delivery of a lysosomal transport protein to ex vivo rabbit cornea.

Therapeutic use of transmembrane proteins is limited because of irreversible denaturation when away from their native lipid membrane. Mutations in lysosomal membrane transport proteins cause many lethal disorders including cystinosis which results from mutations in CTNS, which codes for the lysosomal cystine transport protein, cystinosin. Cystinosin-deficient fibroblasts, including keratocytes (corneal fibroblasts) accumulate lysosomal cystine. Cystinosis patients develop highly painful corneal cystine crystals, resulting in severe visually debilitating photophobia. The only available therapy is daily treatment with cysteamine eye drops. We have previously shown that microvesicles containing functional cystinosin are spontaneously produced by infecting Spodoptera frugiperda cells (Sf9) with baculovirus containing human wt CTNS. Infecting Sf9 cells for 3 days at a MOI of 1 yields 1011microvesicles /ml with a modal diameter of 90 nm. Addition of these vesicles to cultures of cystinotic fibroblasts produces cystine depletion over the course of 96 h, which persists for 2 weeks. In this paper we show that addition of such microvesicles containing cystinosinGFP to ex vivo rabbit ocular globes yields punctate perinuclear green fluorescence in the corneal keratocytes. These results support potential therapeutic use of these cystinosin containing microvesicles in treating cystinotic corneal keratopathy with the advantage of administering twice/month instead of daily topical administration.

Lysosomal cystine augments apoptosis and causes the phenotype in cystinosis.

Nephropathic cystinosis is a lethal inborn error of metabolism that destroys kidney function by age 10 years. It is characterized by lysosomal cystine accumulation. How the cystine causes the phenotype is an open question. We propose that during apoptosis, permeablized lysosomes permit cystine to reach the cytosol where mixed disulfide formation occurs, augmenting apoptosis by interaction with a variety of pro-apoptotic proteins.

Leigh syndrome in a girl with a novel DLD mutation causing E3 deficiency.

We present the biochemical and molecular diagnosis of dihydrolipoamide dehydrogenase deficiency (also known as E3 deficiency) and Leigh syndrome in a 14-year-old girl with learning disability and episodic encephalopathy and ketoacidosis. The diagnosis was based on values of plasma amino acids and urine organic acids, obtained during acute encephalopathy, lactic ketoacidosis, and liver failure, precipitated by infectious mononucleosis. Enzymatic and molecular analyses confirmed dihydrolipoamide dehydrogenase deficiency. E3 activity from cultured skin fibroblasts ranged from 9-29% of the mean. Molecular analysis revealed compound heterozygosity for novel and known pathogenic mutations (p.I353T and p.G136del, respectively). The patient received dietary augmentation and continuous renal replacement therapy, given her severe, persistent lactic acidosis. Acute decompensation resulted in magnetic resonance imaging changes involving the posterior aspect of the putamen, lateral, and medial thalami, substantia nigra, lateral geniculate bodies, and splenium of the corpus callosum. The cortex and subcortical white matter of the right and left occipital lobes and perirolandic region were also affected. In our review of molecularly confirmed patients with dihydrolipoamide dehydrogenase deficiency, Leigh syndrome was common. Our patient, whose most severe decompensation occurred at a more advanced age than previously reported, provides further evidence of the heterogeneous presentations of dihydrolipoamide dehydrogenase deficiency.

A review of the role of enhanced apoptosis in the pathophysiology of cystinosis.

The role of lysosomal cystine in development of the phenotype in cystinosis is problematic, in that the cystine is effectively isolated from the rest of cellular metabolism. Several models have been proposed, but most do not provide a mechanism for such an interaction. During early apoptosis the lysosomes are permeablized, providing such access. We have shown that lysosomal cystine enhances apoptosis in cultured normal and cystinotic fibroblasts and cultured renal proximal tubule epithelial cells, that the process occurs via mixed disulfide (cysteinylation) formation, and that PKC delta is involved. Further, the "swan neck" deformity of proximal renal tubules, long a hallmark of cystinosis, is explicable via this model, as is the renal failure that results from progression of tubule cell loss to atubular glomeruli. Modification of this process by other genes may explain the milder forms of the disease.

Increased apoptosis in cystinotic fibroblasts and renal proximal tubule epithelial cells results from cysteinylation of protein kinase Cdelta.

Cystinosis is a rare genetic disease characterized by defective lysosomal cystine transport and increased lysosomal cystine. How lysosomal cystine causes the lethal nephropathic phenotype is unknown. It was shown recently that cultured fibroblasts and renal proximal tubule epithelial cells whose lysosomes are cystine-loaded display a two-fold or greater increase in apoptosis after both intrinsic and extrinsic stimuli. The mechanism for the increased apoptosis is unknown. Protein kinase Cdelta (PKCdelta) is a proapoptotic protein kinase that has been shown in vitro to be activated via cysteinylation. This report now shows that PKCdelta forms disulfide bonds specifically with cystine that is released from lysosomes in cultured fibroblasts and renal proximal tubule epithelial cells during apoptosis. PKCdelta in cystinotic fibroblasts and renal proximal tubule epithelial cells have a four- to six-fold greater association with its substrate, lamin B, and a 2.5-fold increase in specific activity after TNF-alpha exposure. Both RNA inhibition and chemical inhibition of PKCdelta resulted in a significant decrease in apoptosis in cystinotic cells but not in normal cells. It is proposed that abnormally increased apoptosis plays a role in evolution of the cystinotic phenotype.

Potential role of apoptosis in development of the cystinotic phenotype.

Much still remains unclear about the proximal biochemical effects of mutations on development of the phenotype in inborn errors of metabolism. Cystinosis is an example of this phenomenon. We have recently shown that cystinotic cells undergo apoptosis at a two- to fourfold higher rate than controls. Cystinotic cells pre-treated with cysteamine, normalizing cystine content, display a four- to fivefold decrease in apoptosis, while normal cells pre-treated with cystine dimethylester, increasing lysosomal cystine, exhibit a fivefold increase in apoptosis. We speculate that cystine exits the lysosomal compartment during early apoptosis and affects apoptotic proteins in the cytosol, causing an inappropriate commitment to proceed to cell death. The resulting chronic hypocellularity could account for all the characteristics of the nephropathic cystinotic phenotype. The milder variants of cystinosis may result from modifying mutations within an apoptotic protein, ablating the proapoptotic effects of cystine. Failure of the mouse knockout for cystinosis to show renal involvement may be the result of differences in apoptotic processes between man and mouse. Apoptosis is a major final common pathway for many disease states. Therefore, a better understanding of the effect of lysosomal cystine on apoptosis may help to clarify development of other diseases.

Sucrose-induced vacuolation results in increased expression of cholesterol biosynthesis and lysosomal genes.

Mammalian cells cultured in the presence of high concentrations of sucrose demonstrate large, phase-lucent, osmotically swollen vacuoles. Three normal human fibroblast cell lines exposed to 100 mM of sucrose for 24 h demonstrated increased expression of lysosomal, intracellular vesicle trafficking, cholesterol biosynthesis, and fatty acid metabolism genes. Most steps of the cholesterol biosynthesis pathway were upregulated including HMG CoA reductase, which catalyzes the rate-limiting step of cholesterol biosynthesis. The lysosomal genes neuraminidase, CLN3, and CLCN5 and the small GTP-binding proteins Rab7L1 and Arl7 were also increased. A Rab7L1-GFP fusion protein was overexpressed in human fibroblasts and was demonstrated to localize primarily to the Golgi apparatus, and in some cells to the membranes bounding vesicles in the perinuclear region. Increased levels of the transcription factor C/EBP were found in nuclear extracts from cells exposed to sucrose for 12 h, relative to matched controls suggesting regulation of gene expression following sucrose-induced vacuolation may be coordinated, at least in part, by the transcription factor C/EBP. Sucrose-induced vacuolation is a useful model in which to study the regulation of lysosomal gene expression and biogenesis.