A metabolic signature for NADSYN1-dependent congenital NAD deficiency disorder
Justin O. Szot, Hartmut Cuny, Ella M.M.A. Martin, Delicia Z. Sheng, Kavitha Iyer, Stephanie Portelli, Vivien Nguyen, Jessica M. Gereis, Dimuthu Alankarage, David Chitayat, Karen Chong, Ingrid M. Wentzensen, Catherine Vincent-Delormé, Alban Lermine, Emma Burkitt-Wright, Weizhen Ji, Lauren Jeffries, Lynn S. Pais, Tiong Y. Tan, James Pitt, Cheryl A. Wise, Helen Wright, Israel D. Andrews, Brianna Pruniski, Theresa A. Grebe, Nicole Corsten-Janssen, Katelijne Bouman, Cathryn Poulton, Supraja Prakash, Boris Keren, Natasha J. Brown, Matthew F. Hunter, Oliver Heath, Saquib A. Lakhani, John H. McDermott, David B. Ascher, Gavin Chapman, Kayleigh Bozon, Sally L. Dunwoodie
Justin O. Szot, Hartmut Cuny, Ella M.M.A. Martin, Delicia Z. Sheng, Kavitha Iyer, Stephanie Portelli, Vivien Nguyen, Jessica M. Gereis, Dimuthu Alankarage, David Chitayat, Karen Chong, Ingrid M. Wentzensen, Catherine Vincent-Delormé, Alban Lermine, Emma Burkitt-Wright, Weizhen Ji, Lauren Jeffries, Lynn S. Pais, Tiong Y. Tan, James Pitt, Cheryl A. Wise, Helen Wright, Israel D. Andrews, Brianna Pruniski, Theresa A. Grebe, Nicole Corsten-Janssen, Katelijne Bouman, Cathryn Poulton, Supraja Prakash, Boris Keren, Natasha J. Brown, Matthew F. Hunter, Oliver Heath, Saquib A. Lakhani, John H. McDermott, David B. Ascher, Gavin Chapman, Kayleigh Bozon, Sally L. Dunwoodie
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Research Article Reproductive biology

A metabolic signature for NADSYN1-dependent congenital NAD deficiency disorder

Abstract

Nicotinamide adenine dinucleotide (NAD) is essential for embryonic development. To date, biallelic loss-of-function variants in 3 genes encoding nonredundant enzymes of the NAD de novo synthesis pathway — KYNU, HAAO, and NADSYN1 — have been identified in humans with congenital malformations defined as congenital NAD deficiency disorder (CNDD). Here, we identified 13 further individuals with biallelic NADSYN1 variants predicted to be damaging, and phenotypes ranging from multiple severe malformations to the complete absence of malformation. Enzymatic assessment of variant deleteriousness in vitro revealed protein domain–specific perturbation, complemented by protein structure modeling in silico. We reproduced NADSYN1-dependent CNDD in mice and assessed various maternal NAD precursor supplementation strategies to prevent adverse pregnancy outcomes. While for Nadsyn1+/– mothers, any B3 vitamer was suitable to raise NAD, preventing embryo loss and malformation, Nadsyn1–/– mothers required supplementation with amidated NAD precursors (nicotinamide or nicotinamide mononucleotide) bypassing their metabolic block. The circulatory NAD metabolome in mice and humans before and after NAD precursor supplementation revealed a consistent metabolic signature with utility for patient identification. Our data collectively improve clinical diagnostics of NADSYN1-dependent CNDD, provide guidance for the therapeutic prevention of CNDD, and suggest an ongoing need to maintain NAD levels via amidated NAD precursor supplementation after birth.

Authors

Justin O. Szot, Hartmut Cuny, Ella M.M.A. Martin, Delicia Z. Sheng, Kavitha Iyer, Stephanie Portelli, Vivien Nguyen, Jessica M. Gereis, Dimuthu Alankarage, David Chitayat, Karen Chong, Ingrid M. Wentzensen, Catherine Vincent-Delormé, Alban Lermine, Emma Burkitt-Wright, Weizhen Ji, Lauren Jeffries, Lynn S. Pais, Tiong Y. Tan, James Pitt, Cheryl A. Wise, Helen Wright, Israel D. Andrews, Brianna Pruniski, Theresa A. Grebe, Nicole Corsten-Janssen, Katelijne Bouman, Cathryn Poulton, Supraja Prakash, Boris Keren, Natasha J. Brown, Matthew F. Hunter, Oliver Heath, Saquib A. Lakhani, John H. McDermott, David B. Ascher, Gavin Chapman, Kayleigh Bozon, Sally L. Dunwoodie

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Figure 3

Functional assessment of NADSYN1-variant proteins corresponding to gene variants identified in affected individuals.

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Functional assessment of NADSYN1-variant proteins corresponding to gene ...
(A) NADSYN1 activity of purified variant proteins compared with wild-type NADSYN1 protein in the presence of glutamine as substrate. One-way ANOVA with Dunnett’s post hoc test. (B) NADSYN1 activity of purified variant proteins compared with wild-type NADSYN1 protein in the presence of ammonia as substrate. One-way ANOVA with Dunnett’s post hoc test. (C) Average NADSYN1 activity of variant protein relative to wild-type protein activity with respect to positions of variant sites in functional protein domains. ***P < 0.001, ****P < 0.0001; n = 4 experiments. WT, wild-type NADSYN1 protein; Control, negative control (untransfected cell lysate).