Functional Assessment of Lipoyltransferase-1 Deficiency in Cells, Mice, and Humans

Min Ni; Ashley Solmonson; Chunxiao Pan; Chendong Yang; Dan Li; Ashley Notzon; Ling Cai; Gerardo Guevara; Lauren G. Zacharias; Brandon Faubert; Hieu Vu; Lei Jiang; Bookyung Ko; Noriko Merida Morales; Jimin Pei; Gonçalo Vale; Dinesh Rakheja; Nick V. Grishin; Jeffrey G. McDonald; Garrett Gotway; Markey McNutt; Juan M. Pascual; Ralph J. DeBerardinis

doi:10.1016/j.celrep.2019.04.005

Functional Assessment of Lipoyltransferase-1 Deficiency in Cells, Mice, and Humans

Min Ni(Children's Medical Center), Ashley Solmonson(Children's Medical Center), Chunxiao Pan(Children's Medical Center), Chendong Yang(Children's Medical Center), Dan Li(Children's Medical Center), Ashley Notzon(Children's Medical Center), Ling Cai(Children's Medical Center), Gerardo Guevara(Children's Medical Center), Lauren G. Zacharias(Children's Medical Center), Brandon Faubert(Children's Medical Center), Hieu Vu(Children's Medical Center), Lei Jiang(City of Hope), Bookyung Ko(Children's Medical Center), Noriko Merida Morales(Children's Medical Center), Jimin Pei(Howard Hughes Medical Institute), Gonçalo Vale(The University of Texas Southwestern Medical Center), Dinesh Rakheja(The University of Texas Southwestern Medical Center), Nick V. Grishin(Howard Hughes Medical Institute), Jeffrey G. McDonald(The University of Texas Southwestern Medical Center), Garrett Gotway(The University of Texas Southwestern Medical Center), Markey McNutt(The University of Texas Southwestern Medical Center), Juan M. Pascual(The University of Texas Southwestern Medical Center), Ralph J. DeBerardinis(Children's Medical Center)

Cell Reports

April 1, 2019

10.1016/j.celrep.2019.04.005

Cited by 122Open Access

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Abstract

Inborn errors of metabolism (IEMs) link metabolic defects to human phenotypes. Modern genomics has accelerated IEM discovery, but assessing the impact of genomic variants is still challenging. Here, we integrate genomics and metabolomics to identify a cause of lactic acidosis and epilepsy. The proband is a compound heterozygote for variants in LIPT1, which encodes the lipoyltransferase required for 2-ketoacid dehydrogenase (2KDH) function. Metabolomics reveals abnormalities in lipids, amino acids, and 2-hydroxyglutarate consistent with loss of multiple 2KDHs. Homozygous knockin of a LIPT1 mutation reduces 2KDH lipoylation in utero and results in embryonic demise. In patient fibroblasts, defective 2KDH lipoylation and function are corrected by wild-type, but not mutant, LIPT1 alleles. Isotope tracing reveals that LIPT1 supports lipogenesis and balances oxidative and reductive glutamine metabolism. Altogether, the data extend the role of LIPT1 in metabolic regulation and demonstrate how integrating genomics and metabolomics can uncover broader aspects of IEM pathophysiology.

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