Your search keyword '"Frigeni, Marta"' showing total 4 results

1. Functional and molecular studies in primary carnitine deficiency.

Author

Frigeni M, Balakrishnan B, Yin X, Calderon FRO, Mao R, Pasquali M, and Longo N

Subjects

Amino Acid Substitution, Animals, Biological Transport, CHO Cells, Cardiomyopathies diagnosis, Carnitine genetics, Cricetinae, Cricetulus, DNA Mutational Analysis, Exons genetics, Fibroblasts metabolism, Gene Frequency, Humans, Hyperammonemia diagnosis, Hypoglycemia diagnosis, Muscular Diseases diagnosis, Mutation, Mutation, Missense, Solute Carrier Family 22 Member 5 metabolism, Cardiomyopathies genetics, Carnitine deficiency, Carnitine metabolism, Genetic Variation, Hyperammonemia genetics, Hypoglycemia genetics, Muscular Diseases genetics, Solute Carrier Family 22 Member 5 genetics

Abstract

Primary carnitine deficiency is caused by a defect in the OCTN2 carnitine transporter encoded by the SLC22A5 gene. It can cause hypoketotic hypoglycemia or cardiomyopathy in children, and sudden death in children and adults. Fibroblasts from affected patients have reduced carnitine transport. We evaluated carnitine transport in fibroblasts from 358 subjects referred for possible carnitine deficiency. Carnitine transport was reduced to 20% or less of normal in fibroblasts of 140 out of 358 subjects. Sequencing of the 10 exons and flanking regions of the SLC22A5 gene in 95 out of 140 subjects identified causative variants in 84% of the alleles. The missense variants identified in our patients and others previously reported (n = 92) were expressed in CHO cells. Carnitine transport was impaired by 73 out of 92 variants expressed. Prediction algorithms (Polyphen-2, SIFT) correctly predicted the functional effects of expressed variants in about 80% of cases. These results indicate that mutations in the coding region of the SLC22A5 gene cannot be identified in about 16% of the alleles causing primary carnitine deficiency. Prediction algorithms failed to determine the functional effects of amino acid substitutions in this transmembrane protein in about 20% of cases. Therefore, functional studies in fibroblasts remain the best strategy to confirm or exclude a diagnosis of primary carnitine deficiency., (© 2017 Wiley Periodicals, Inc.)

Published

2017

2. Carnitine transport and fatty acid oxidation.

Author

Longo N, Frigeni M, and Pasquali M

Subjects

Adult, Age of Onset, Biological Transport, Carnitine deficiency, Carnitine therapeutic use, Caveolins metabolism, Energy Metabolism, Fasting physiology, Fatty Acid Transport Proteins metabolism, Fatty Acid-Binding Proteins metabolism, Humans, Infant, Newborn, Kidney metabolism, Mutation, Neonatal Screening, Organ Specificity, Organic Cation Transport Proteins deficiency, Organic Cation Transport Proteins genetics, Oxidation-Reduction, Solute Carrier Family 22 Member 5, Carnitine metabolism, Fatty Acids metabolism, Organic Cation Transport Proteins metabolism

Abstract

Carnitine is essential for the transfer of long-chain fatty acids across the inner mitochondrial membrane for subsequent β-oxidation. It can be synthesized by the body or assumed with the diet from meat and dairy products. Defects in carnitine biosynthesis do not routinely result in low plasma carnitine levels. Carnitine is accumulated by the cells and retained by kidneys using OCTN2, a high affinity organic cation transporter specific for carnitine. Defects in the OCTN2 carnitine transporter results in autosomal recessive primary carnitine deficiency characterized by decreased intracellular carnitine accumulation, increased losses of carnitine in the urine, and low serum carnitine levels. Patients can present early in life with hypoketotic hypoglycemia and hepatic encephalopathy, or later in life with skeletal and cardiac myopathy or sudden death from cardiac arrhythmia, usually triggered by fasting or catabolic state. This disease responds to oral carnitine that, in pharmacological doses, enters cells using the amino acid transporter B(0,+). Primary carnitine deficiency can be suspected from the clinical presentation or identified by low levels of free carnitine (C0) in the newborn screening. Some adult patients have been diagnosed following the birth of an unaffected child with very low carnitine levels in the newborn screening. The diagnosis is confirmed by measuring low carnitine uptake in the patients' fibroblasts or by DNA sequencing of the SLC22A5 gene encoding the OCTN2 carnitine transporter. Some mutations are specific for certain ethnic backgrounds, but the majority are private and identified only in individual families. Although the genotype usually does not correlate with metabolic or cardiac involvement in primary carnitine deficiency, patients presenting as adults tend to have at least one missense mutation retaining residual activity. This article is part of a Special Issue entitled: Mitochondrial Channels edited by Pierre Sonveaux, Pierre Maechler and Jean-Claude Martinou., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

3. PRIMARY CARNITINE DEFICIENCY: THE EFFECT OF 4-PHENYLBUTYRIC ACID ON NATURAL MUTATIONS.

Author

Frigeni, Marta, Ingoglia, Filippo, Balakrishnan, Bijina, Pasquali, Marzia, and Longo, Nicola

Subjects

*CARNITINE

Published

2023

4. Wide tolerance to amino acids substitutions in the OCTN1 ergothioneine transporter.

Author

Frigeni, Marta, Iacobazzi, Francesco, Yin, Xue, and Longo, Nicola

Subjects

*ORGANIC cation transporters, *DRUG tolerance, *AMINO acids, *SUBSTITUTION reactions, *CELL membranes, *CARNITINE, *GENETIC mutation

Abstract

Background Organic cation transporters transfer solutes with a positive charge across the plasma membrane. The novel organic cation transporter 1 (OCTN1) and 2 (OCTN2) transport ergothioneine and carnitine, respectively. Mutations in the SLC22A5 gene encoding OCTN2 cause primary carnitine deficiency, a recessive disorders resulting in low carnitine levels and defective fatty acid oxidation. Variations in the SLC22A4 gene encoding OCTN1 are associated with rheumatoid arthritis and Crohn disease. Methods Here we evaluate the functional properties of the OCTN1 transporter using chimeric transporters constructed by fusing different portion of the OCTN1 and OCTN2 cDNAs. Their relative abundance and subcellular distribution was evaluated through western blot analysis and confocal microscopy. Results Substitutions of the C-terminal portion of OCTN1 with the correspondent residues of OCTN2 generated chimeric OCTN transporters more active than wild-type OCTN1 in transporting ergothioneine. Additional single amino acid substitutions introduced in chimeric OCTN transporters further increased ergothioneine transport activity. Kinetic analysis indicated that increased transport activity was due to an increased V max , with modest changes in K m toward ergothioneine. Conclusions Our results indicate that the OCTN1 transporter is tolerant to extensive amino acid substitutions. This is in sharp contrast to the OCTN2 carnitine transporter that has been selected for high functional activity through evolution, with almost all substitutions reducing carnitine transport activity. General significance The widespread tolerance of OCTN1 to amino acid substitutions suggests that the corresponding SLC22A4 gene may have derived from a recent duplication of the SLC22A5 gene and might not yet have a defined physiological role. [ABSTRACT FROM AUTHOR]

Published

2016