Talal Mousallem

The CLN9 Protein, a Regulator of Dihydroceramide Synthase

A new variant of a group of pediatric neurodegenerative diseases known as neuronal ceroid lipofuscinosis (NCL) or Batten disease has been identified. It is termed CLN9-deficient. CLN9-deficient fibroblasts have a distinctive phenotype of rapid growth and increased apoptosis and diminished levels of ceramide, dihydroceramide, and sphingomyelin. Transfection with CLN8 but not other NCL genes corrected growth and apoptosis in CLN9-deficient cells, although the entire CLN8 sequence was normal. CLN8 is one of the TRAM-Lag1-CLN8 proteins containing a Lag1 motif. The latter imparts (dihydro)ceramide synthase activity to yeast cells. Transfection with the yeast gene Lag1 Sc and the human homolog LASS1 increased ceramide levels and partially corrected growth and apoptosis in CLN9-deficient cells. LASS2,-4,,-5, and -6 also corrected growth and apoptosis. Dihydroceramide levels and dihydroceramide synthase activity were markedly diminished in CLN9-deficient cells. Sequencing of LASS1, LASS2, LASS4, LASS5, and LASS6 genes was normal, and expression levels were increased or normal in CLN9-deficient cells by reverse transcription-PCR. N-(4-Hydroxyphenyl)retinamide (4-HPR), a dihydroceramide synthase activator, corrected growth and apoptosis and increased dihydroceramide synthase activity. Ceramide levels dropped further, and there was no increase in de novo ceramide synthesis, probably due to the effects of 4-HPR as activator of dihydroceramide synthase and inhibitor of dihydroceramide desaturase. Fumonisin B1, a dihydroceramide synthase inhibitor, exaggerated the CLN9-deficient phenotype of accelerated growth, decreased ceramide and increased apoptosis. This was neutralized by 4-HPR. We conclude that the CLN9 protein may be a regulator of dihydroceramide synthase and that 4-HPR could be developed as a treatment for CLN9-deficient patients.

Synergistic control of T cell development and tumor suppression by diacylglycerol kinase α and ζ

Diacylglycerol (DAG) kinases (DGKs) are a family of enzymes that convert DAG to phosphatidic acid (PA), the physiologic functions of which have been poorly defined. We report here that DGK α and ζ synergistically promote T cell maturation in the thymus. Absence of both DGKα and ζ (DGKα−/−ζ−/−) results in a severe decrease in the number of CD4+CD8− and CD4−CD8+ single-positive thymocytes correlating with increased DAG-mediated signaling. Positive selection, but not negative selection, is impaired in DGKα−/−ζ−/− mice. The developmental blockage in DGKα−/−ζ−/− mice can be partially overcome by treatment with PA. Furthermore, decreased DGK activity also promotes thymic lymphomagenesis accompanying elevated Ras and Erk1/2 activation. Our data demonstrate a synergistic and critical role of DGK isoforms in T cell development and tumor suppression, and indicate that DGKs not only terminate DAG signaling but also initiate PA signaling in thymocytes to promote positive selection.

CLN3p Impacts Galactosylceramide Transport, Raft Morphology, and Lipid Content

Juvenile neuronal ceroid lipofuscinosis (JNCL) belongs to the neuronal ceroid lipofuscinoses characterized by blindness/seizures/motor/cognitive decline and early death. JNCL is caused by CLN3 gene mutations that negatively modulate cell growth/apoptosis. CLN3 protein (CLN3p) localizes to Golgi/Rab4-/Rab11-positive endosomes and lipid rafts, and harbors a galactosylceramide (GalCer) lipid raft-binding domain. Goals are proving CLN3p participates in GalCer transport from Golgi to rafts, and GalCer deficits negatively affect cell growth/apoptosis. GalCer/mutant CLN3p are retained in Golgi, with CLN3p rescuing GalCer deficits in rafts. Diminishing GalCer in normal cells by GalCer synthase siRNA negatively affects cell growth/apoptosis. GalCer restores JNCL cell growth. WT CLN3p binds GalCer, but not mutant CLN3p. Sphingolipid content of rafts/Golgi is perturbed with diminished GalCer in rafts and accumulation in Golgi. CLN3-deficient raft vesicular structures are small by transmission electron microscopy, reflecting altered sphingolipid composition of rafts. CLN1/CLN2/CLN6 proteins bind to lysophosphatidic acid/sulfatide, CLN6/CLN8 proteins to GalCer, and CLN8 protein to ceramide. Sphingolipid composition/morphology of CLN1-/CLN2-/CLN6-/CLN8- and CLN9-deficient rafts are altered suggesting changes in raft structure/lipid stoichiometry could be common themes underlying these diseases.

CLN5 and CLN8 protein association with ceramide synthase: Biochemical and proteomic approaches

Four patients with juvenile neuronal ceroid lipofuscinoses, a childhood neurodegenerative disorder that was previously described as CLN9 variant, are reclassified as CLN5 disease. CLN5‐deficient (CLN5−/−) fibroblasts demonstrate adhesion defects, increased growth, apoptosis, and decreased levels of ceramide, sphingomyelin, and glycosphingolipids. The CLN8 protein (CLN8p) corrects growth and apoptosis in CLN5−/− cells. Related proteins containing a Lag1 motif (CerS1/2/4/5/6) partially corrected these deficits, with CerS1, which is primarily expressed in brain, providing the best complementation, suggesting CLN5p activates CerS1 and may co‐immunoprecipitate with it. CLN8p complements CLN5‐deficient cells, consolidating the interrelationship of CLN5p/CLN8p, whose potential roles are explored as activators of (dihydro)ceramide synthases. Homozygosity mapping using microarray technology led to identification of CLN5 as the culprit gene in previously classified CLN9‐defective cases. Similar to CLN5−/−cells, ceramide synthase activity, C16/C18:0/C24:0/C24:1 ceramide species, measured by MS is decreased in CLN8−/− cells. Comparison of normal versus CLN5−/− cell CerS1‐bound proteins by immunoprecipitation, differential gel electrophoresis, and MS revealed absence of γ‐actin in CLN5−/− cells. The γ‐actin gene sequence is normal in CLN5−/− derived DNA. The γ‐actin‐bound proteins, vimentin and histones H2Afz/H3F3A/Hist1H4, were absent from the γ‐actin protein complex in CLN5−/− cells. The function of CLN5p may require vimentin and the histone proteins to bind γ‐actin. Defective binding could explain the CLN5−/− cellular phenotype. We explore the role of the CLN5/CLN8 proteins in ceramide species specific sphingolipid de novo synthesis, and suggest that CLN5/CLN8 proteins are more closely related than previously believed.

Future therapies for food allergy.

Food allergy affects 3.9% of US children and is increasing in prevalence. The current standard of care involves avoidance of the triggering food and treatment for accidental ingestions. While there is no current curative treatment, there are a number of therapeutic strategies under investigation. Allergen specific therapies include oral and sublingual immunotherapy with native food protein as well as recombinant food proteins. Allergen non-specific therapies include a Chinese herbal formula (FAHF-2) and the use of anti-IgE monoclonal antibody therapy. Although none of these treatments are ready for clinical use, these therapeutic strategies present promising options for the future of food allergy.

Bone marrow transplantation for CVID-like humoral immune deficiency associated with red cell aplasia

Patients with common variable immunodeficiency (CVID) have a higher incidence of autoimmune disease, which may mark the disease onset; however, anemia secondary to pure red cell aplasia is an uncommon presenting feature. Here, we describe a case of CVID‐like humoral immune deficiency in a child who initially presented with red cell aplasia and ultimately developed progressive bone marrow failure. Although bone marrow transplantation (BMT) has been associated with high mortality in CVID, our patient was successfully treated with a matched sibling BMT and engrafted with >98% donor chimerism and the development of normal antibody titers to diphtheria and tetanus toxoids.