FDXR variants cause adrenal insufficiency and atypical sexual development
Emanuele Pignatti, Jesse Slone, María Ángeles Gómez Cano, Teresa Margaret Campbell, Jimmy Vu, Kay-Sara Sauter, Amit V. Pandey, Francisco Martínez-Azorín, Marina Alonso-Riaño, Derek E. Neilson, Nicola Longo, Therina du Toit, Clarissa D. Voegel, Taosheng Huang, Christa E. Flück
Emanuele Pignatti, Jesse Slone, María Ángeles Gómez Cano, Teresa Margaret Campbell, Jimmy Vu, Kay-Sara Sauter, Amit V. Pandey, Francisco Martínez-Azorín, Marina Alonso-Riaño, Derek E. Neilson, Nicola Longo, Therina du Toit, Clarissa D. Voegel, Taosheng Huang, Christa E. Flück
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Research Article Endocrinology Genetics

FDXR variants cause adrenal insufficiency and atypical sexual development

Abstract

Genetic defects affecting steroid biosynthesis cause cortisol deficiency and differences of sex development; among these defects are recessive mutations in the steroidogenic enzymes CYP11A1 and CYP11B, whose function is supported by reducing equivalents donated by ferredoxin reductase (FDXR) and ferredoxin. So far, mutations in the mitochondrial flavoprotein FDXR have been associated with a progressive neuropathic mitochondriopathy named FDXR-related mitochondriopathy (FRM), but cortisol insufficiency has not been documented. However, patients with FRM often experience worsening or demise following stress associated with infections. We investigated 2 female patients with FRM carrying the potentially novel homozygous FDXR mutation p.G437R with ambiguous genitalia at birth and sudden death in the first year of life; they presented with cortisol deficiency and androgen excess compatible with 11-hydroxylase deficiency. In addition, steroidogenic FDXR-variant cell lines reprogrammed from 3 patients with FRM fibroblasts displayed deficient mineralocorticoid and glucocorticoid production. Finally, Fdxr-mutant mice allelic to the severe p.R386W human variant showed reduced progesterone and corticosterone production. Therefore, our comprehensive studies show that human FDXR variants may cause compensated but possibly life-threatening adrenocortical insufficiency in stress by affecting adrenal glucocorticoid and mineralocorticoid synthesis through direct enzyme inhibition, most likely in combination with disturbed mitochondrial redox balance.

Authors

Emanuele Pignatti, Jesse Slone, María Ángeles Gómez Cano, Teresa Margaret Campbell, Jimmy Vu, Kay-Sara Sauter, Amit V. Pandey, Francisco Martínez-Azorín, Marina Alonso-Riaño, Derek E. Neilson, Nicola Longo, Therina du Toit, Clarissa D. Voegel, Taosheng Huang, Christa E. Flück

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Figure 3

Sequence and structure analysis of mutations in FDXR.

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Sequence and structure analysis of mutations in FDXR. (A) A 3D model of ...
(A) A 3D model of human FDXR displayed as a ribbon diagram. The positions of the phenylalanine 51, proline 74, arginine 155, arginine 193, arginine 386, and glycine 437 residues are indicated. The structural model of human FDXR is based on a known 3D structure of the bovine protein as described in the Methods section. The diagram is colored using a rainbow palette with blue at N-terminus and red at C-terminus. Cofactors (NADP, FAD) are shown as stick models, while amino acids phenylalanine 51, proline 74, arginine 155, arginine 193, arginine 386, and glycine 437 are shown as spheres. (B) The evolutionary sequence conservation of FDXR. Most of the mutations reported in this study are highly conserved across species and are predicted to have structural roles. Sequences are colored based on amino acid conservation, with dark blue being the least conserved and dark red being the most conserved, while yellow indicates that no prediction could be made. (C) A complex of FDXR and FDX1 proteins showing the locations of mutated residues, which are not at the FDXR-FDX interface and are predicted not to have a direct effect on FDX-FDXR interaction. (D) Stability and flexibility analysis of mutated FDXR structures compared with WT FDXR. An increased flexibility was observed for amino acid changes F51L and R193H (shown in red), indicating decreased stability that was supported by differential free energy calculations. Decreased flexibility due to P74L, R155W, R386W, and G537R mutations is shown in blue.