AUTHOR=Wang Ting , Ma Jun , Zhang Qin , Gao Ang , Wang Qi , Li Hong , Xiang Jingjing , Wang Benjing 

TITLE=Expanded Newborn Screening for Inborn Errors of Metabolism by Tandem Mass Spectrometry in Suzhou, China: Disease Spectrum, Prevalence, Genetic Characteristics in a Chinese Population

JOURNAL=Frontiers in Genetics

VOLUME=10

YEAR=2019

URL=https://www.frontiersin.org/journals/genetics/articles/10.3389/fgene.2019.01052

DOI=10.3389/fgene.2019.01052

ISSN=1664-8021

ABSTRACT=<p>Expanded newborn screening for inborn errors of metabolism (IEMs) by tandem mass spectrometry (MS/MS) could simultaneously analyze more than 40 metabolites and identify about 50 kinds of IEMs. Next generation sequencing (NGS) targeting hundreds of IMEs-associated genes as a follow-up test in expanded newborn screening has been used for genetic analysis of patients. The spectrum, prevalence, and genetic characteristic of IEMs vary dramatically in different populations. To determine the spectrum, prevalence, and gene mutations of IEMs in newborns in Suzhou, China, 401,660 newborns were screened by MS/MS and 138 patients were referred to genetic analysis by NGS. The spectrum of 22 IEMs were observed in Suzhou population of newborns, and the overall incidence (excluding short chain acyl-CoA dehydrogenase deficiency (SCADD) and 3-Methylcrotonyl-CoA carboxylase deficiency (3-MCCD)) was 1/3,163. The prevalence of each IEM ranged from 1/401,660 to 1/19,128, while phenylketonuria (PKU) (1/19,128) and Mild hyperphenylalaninemia (M-HPA) (1/19,128) were the most common IEMs, followed by primary carnitine uptake defect (PCUD) (1/26,777), SCADD (1/28,690), hypermethioninemia (H-MET) (1/30,893), 3-MCCD (1/33,412) and methylmalonic acidemia (MMA) (1/40,166). Moreover, 89 reported mutations and 51 novel mutations in 25 IMEs-associated genes were detected in 138 patients with one of 22 IEMs. Some hotspot mutations were observed for ten IEMs, including <italic>PAH</italic> gene c.728G &gt; A, c.611A &gt; G, and c.721C &gt; T for Phenylketonuria, <italic>PAH</italic> gene c.158G &gt; A, c.1238G &gt; C, c.728G &gt; A, and c.1315+6T &gt; A for M-HPA, <italic>SLC22A5</italic> gene c.1400C &gt; G, c.51C &gt; G, and c.760C &gt; T for PCUD, <italic>ACADS</italic> gene c.1031A &gt; G, c.164C &gt; T, and c.1130C &gt; T for SCAD deficiency, <italic>MAT1A</italic> gene c.791G &gt; A for H-MET, <italic>MCCC1</italic> gene c.639+2T &gt; A and c.863A &gt; G for 3-MCCD, <italic>MMUT</italic> gene c.1663G &gt; A for MMA, <italic>SLC25A13</italic> gene c.IVS16ins3Kb and c.852_855delTATG for cittrullinemia II, <italic>PTS</italic> gene c.259C &gt; T and c.166G &gt; A for Tetrahydrobiopterin deficiency, and <italic>ACAD8</italic> gene c.1000C &gt; T and c.286C &gt; A for Isobutyryl coa dehydrogenase deficiency. All these hotspot mutations were reported to be pathogenic or likely pathogenic, except a novel mutation of <italic>ACAD8</italic> gene c.286C &gt; A. These mutational hotspots could be potential candidates for gene screening and these novel mutations expanded the mutational spectrum of IEMs. Therefore, our findings could be of value for genetic counseling and genetic diagnosis of IEMs.</p>