Correction of Familial LCAT Deficiency by AAV-hLCAT Prevents Renal Injury and Atherosclerosis in Hamsters-Brief Report.

[Figure: see text].

Current Status of Familial LCAT Deficiency in Japan.

Lecithin cholesterol acyltransferase (LCAT) is a lipid-modification enzyme that catalyzes the transfer of the acyl chain from the second position of lecithin to the hydroxyl group of cholesterol (FC) on plasma lipoproteins to form cholesteryl acylester and lysolecithin. Familial LCAT deficiency is an intractable autosomal recessive disorder caused by inherited dysfunction of the LCAT enzyme. The disease appears in two different phenotypes depending on the position of the gene mutation: familial LCAT deficiency (FLD, OMIM 245900) that lacks esterification activity on both HDL and ApoB-containing lipoproteins, and fish-eye disease (FED, OMIM 136120) that lacks activity only on HDL. Impaired metabolism of cholesterol and phospholipids due to LCAT dysfunction results in abnormal concentrations, composition and morphology of plasma lipoproteins and further causes ectopic lipid accumulation and/or abnormal lipid composition in certain tissues/cells, and serious dysfunction and complications in certain organs. Marked reduction of plasma HDL-cholesterol (HDL-C) and corneal opacity are common clinical manifestations of FLD and FED. FLD is also accompanied by anemia, proteinuria and progressive renal failure that eventually requires hemodialysis. Replacement therapy with the LCAT enzyme should prevent progression of serious complications, particularly renal dysfunction and corneal opacity. A clinical research project aiming at gene/cell therapy is currently underway.

[Lecithin:Cholesterol Acyltransferase Deficiency, from genes to therapy]. / Deficit di lecitina:colesterolo aciltransferasi, dalla genetica alla terapia.

LCAT synthesizes most of the plasma cholesteryl esters, and plays a major role in HDL metabolism. Mutations in the LCAT gene cause two syndromes, familial LCAT deficiency (FLD) and fish-eye disease (FED), both characterized by severe alterations in plasma lipoprotein profile. Renal disease is the major cause of morbidity and mortality in FLD cases, but an established therapy is not currently available. The present therapy of LCAT deficiency is mainly aimed at correcting the dyslipidemia associated with the disease and at delaying evolution of chronic nephropathy. LCAT deficiency represents a candidate disease for enzyme replacement therapy. In vitro and in vivo studies proved the efficacy of recombinant human LCAT (rhLCAT) in correcting dyslipidemia, and rhLCAT is presently under development.

Gene-manipulated Adipocytes for the Treatment of Various Intractable Diseases.

Although protein replacement is an effective treatment for serum protein deficiencies such as diabetes and hemophilia, recombinant protein products are not available for all rare inherited diseases due to the instability of the recombinant proteins and/or to cost. Gene therapy is the most attractive option for treating patients with such rare diseases. To develop an effective ex vivo gene therapy-based protein replacement treatment requires recipient cells that differ from those used in standard gene therapy, which is performed to correct the function of the recipient cells. Adipose tissue is an expected source of proliferative cells for cell-based therapies, including regenerative medicine and gene transfer applications. Based on recent advances in cell biology and extensive clinical experience in transplantation therapy for adipose tissue, we focused on the mature adipocyte fraction, which is the floating fraction after collagenase digestion and centrifugation of adipose tissue. Proliferative adipocytes were propagated from the floating fraction by the ceiling culture technique. These cells are designated as ceiling culture-derived proliferative adipocytes (ccdPAs). We first focused on lecithin:cholesterol acyltransferase (LCAT) deficiency, an inherited metabolic disorder caused by lcat gene mutation, and ccdPAs as a therapeutic gene vehicle for LCAT replacement therapy. In our recent in vitro and animal model studies, we developed an adipose cell manipulation procedure using advanced gene transduction methods and transplantation scaffolds. We herein introduce the progress made in novel adipose tissue-based therapeutic strategies for the treatment of protein deficiencies and describe their future applications for other intractable diseases.

Familial LCAT deficiency in a child with nephrotic syndrome.

BACKGROUND: Lecitin cholesterol acyltransferase (LCAT) deficiency comprises a group of rare disorders related to HDL metabolism. These disorders are characterized by ophthalmologic, hematologic, and renal findings. Case diagnosis/treatment: A 15-year-old female who presented with nephrotic syndrome and hypertension was diagnosed with LCAT deficiency by renal biopsy and LCAT enzyme activity. Her edema and hypertension improved with diuretic and antihypertensive therapies. Continued care of her LCAT deficiency is ongoing. CONCLUSION: Although rare, LCAT deficiency should be in the differential diagnosis of nephrotic syndrome in the setting of abnormally low HDL cholesterol levels.

Novel missense variants in LCAT and APOB genes in an Italian kindred with familial lecithin:cholesterol acyltransferase deficiency and hypobetalipoproteinemia.

BACKGROUND: Lecithin:cholesterol acyltransferase (LCAT) is responsible for cholesterol esterification in plasma. Mutations of LCAT gene cause familial LCAT deficiency, a metabolic disorder characterized by hypoalphalipoproteinemia. Apolipoprotein B (apoB) is the main protein component of very-low-density lipoproteins and low-density lipoprotein (LDL). Mutations of APOB gene cause familial hypobetalipoproteinemia, a codominant disorder characterized by low plasma levels of LDL cholesterol and apoB. OBJECTIVE: This was a genetic and biochemical analysis of an Italian kindred with hypobetalipoproteinemia whose proband presented with hypoalphalipoproteinemia and severe chronic kidney disease. METHODS: Plasma lipids and apolipoproteins, cholesterol esterification, and high-density lipoprotein (HDL) subclass distribution were analyzed. LCAT and APOB genes were sequenced. RESULTS: The proband had severe impairment of plasma cholesterol esterification and high preß-HDL content. He was heterozygote for the novel LCAT P406L variant, as were two other family members. The proband's wife and children presented with familial hypobetalipoproteinemia and were heterozygotes for the novel apoB H1401R variant. Cholesterol esterification rate of apoB H1401R carriers was reduced, likely attributable to the low amount of circulating LDL. After renal transplantation, proband's lipid profile, HDL subclass distribution, and plasma cholesterol esterification were almost at normal levels, suggesting a mild contribution of the LCAT P406L variant to his pretransplantation severe hypoalphalipoproteinemia and impairment of plasma cholesterol esterification. CONCLUSION: LCAT P406L variant had a mild effect on lipid profile, HDL subclass distribution, and plasma cholesterol esterification. ApoB H1401R variant was identified as possible cause of familial hypobetalipoproteinemia and resulted in a reduction of cholesterol esterification rate.

[LCAT deficiency: a nephrological diagnosis]. / Il deficit di LCAT: una diagnosi nefrologica.

A genetic mendelian autosomal recessive condition of deficiency of lecithin- cholesterol acyltransferase (LCAT) can produce two different diseases: one highly interesting nephrologic picture of complete enzymatic deficiency (lecithin:cholesterol acyltransferase deficiency; OMIM ID #245900; FLD), characterized by the association of dyslipidemia, corneal opacities, anemia and progressive nephropathy; and a partial form (fish eye disease; OMIM ID #136120; FED) with dyslipidemia and progressive corneal opacities only. The diagnosis of FLD falls first of all under the competence of nephrologists, because end-stage renal disease appears to be its most severe outcome. The diagnostic suspicion is based on clinical signs (corneal opacities, more severe anemia than expected for the degree of chronic renal failure, progressive proteinuric nephropathy) combined with histology obtained by kidney biopsy (glomerulopathy evolving toward sclerosis with distinctive lipid deposition). However, the final diagnosis, starting with a finding of extremely low levels of HDL-cholesterol, requires collaboration with lipidology Centers that can perform sophisticated investigations unavailable in common laboratories. To be heterozygous for a mutation of the LCAT gene is one of the monogenic conditions underlying primary hypoalphalipoproteinemia (OMIM ID #604091). This disease, which is characterized by levels of HDL-cholesterol below the 5th percentile of those of the examined population (<28 mg/dL for Italians), has heritability estimates between 40% and 60% and is considered to be a predisposing condition for coronary artery disease. Nevertheless, some monogenic forms, and especially those associated with LCAT deficiency, seem to break the rule, confirming once more the value of a proper diagnosis before drawing prognostic conclusions from a laboratory marker. As in many other rare illnesses, trying to discover all the existing cases will contribute to allow studies broad enough to pave the way for further therapies, in this case also fostering the production by industries of the lacking enzyme by genetic engineering. Epidemiological studies, although done on selected populations such as hypoalphalipoproteinemia patients on dialysis and with the effective genetic tools of today, have been disappointing in elucidating the disease. Spreading the clinical knowledge of the disease and its diagnostic course among nephrologists seems to be the best choice, and this is the aim of our work.

Lecithin-cholesterol acyltransferase deficiency presenting with acute pancreatitis: effect of infusion of normal plasma on triglyceride-rich lipoproteins.

A 38-year-old Asian man presented with acute pancreatitis, marked hypertriglyceridaemia and macroproteinuria, 20 years after the diagnosis of lecithin-cholesterol acyltransferase (LCAT) deficiency. After recovery, he exhibited macroproteinuria and chylomicronaemia despite treatment with a very-low-fat diet. Infusion of normal plasma significantly increased the proportion of cholesterol esters in the patient's plasma and significantly lowered chylomicron-triglyceride levels, but not proteinuria. We conclude that renal dysfunction may be a late manifestation of LCAT deficiency and that it may lead to severe chylomicronaemia and acute pancreatitis. Infusion of normal plasma corrects the dyslipidaemia in LCAT deficiency, but in the short term does not improve renal function.

[Clinical features of lecithin-cholesterol acyltransferase deficiency]. / Obraz kliniczny deficytu acylotransferazy lecytynowo-cholesterolowej.

Lecithin-cholesterol acyltransferase (LCAT) is involved in esterify of free cholesterol and in the cholesterol esters transport from peripheral tissues to the liver. Genetically dependent lack of enzyme activity leads to Fish Eye Disease and to familial LCAT deficiency. There are specific abnormalities of plasma lipids and lipid deposits in multiple tissues (familial LCAT deficiency) or in corneal only (Fish Eye Disease). Clinical features of familial LCAT deficiency include corneal opacities, anemia, and proteinuria. Renal failure is the most frequent complication, occurring in the fourth decade. Treatment of familial LCAT deficiency is based on infusions of plasma or whole blood and on kidney transplantation.

Decreased sodium influx and abnormal red cell membrane lipids in a patient with familial plasma lecithin: cholesterol acyltransferase deficiency.

Red cell membrane metabolism in familial lecithin:cholesterol acyltransferase (LCAT) deficiency was investigated. The family presented here is the third case discovered in Japan. An increase of free cholesterol was observed in the red cell membranes, concomitant with increased phosphatidyl choline. Osmotic fragility of the patient's red cells was diminished rather than increased. Red cell survival (51Cr T1/2) was shortened (15 days). Sodium influx was markedly decreased, although sodium efflux, both ouabain-sensitive and ouabain-insensitive, was normal. The activity of acetyl-cholinesterase as a marker of the outer leaflet of the red cell membranes was decreased, while the activity of glyceraldehyde-3-phosphate dehydrogenase as a marker of the inner leaflet was normal. No abnormalities of adenosine triphosphatases in red cell membranes were observed. These results suggest that the alteration of cholesterol metabolism in the plasma of LCAT deficiency increases the red cell membrane cholesterol and affects the functions of the red cell membranes, especially of the outer leaflet, which may result in decreased sodium influx.