Mu Jialin, Li Yulin, Sun Meng, Li Panpan, Wang Jingyun, Zou Hui
Newborn Screening Center, Jinan Maternal and Child Care Hospital, Jinan, P.R.China.
Medicine (Baltimore). 2024 Dec 20;103(51):e40957. doi: 10.1097/MD.0000000000040957.
The high clinical heterogeneity of hypermethioninemia caused by MAT1A gene defects has resulted in a paucity of studies examining the association between clinical phenotypes, biochemical characteristics, and gene mutations in this patient group. Furthermore, the indications for therapeutic interventions in patients remain unclear. The objective of this study is to provide a foundation for clinical diagnosis, genetic counseling, and follow-up management of hypermethioninemia caused by MAT1A gene defects.
A retrospective analysis of children with hypermethioninemia at Jinan Maternal and Child Health Hospital from January 2016 to December 2023 was performed using tandem mass spectrometry (MS/MS). The screened and diagnosed children were tested for gene mutations using second-generation sequencing technology and confirmed using Sanger sequencing.
Newborn MS/MS screening for diseases demonstrated an elevated methionine level, which was outside the reference range. Upon recalling the newborns, the methionine levels remained elevated, necessitating further refinement of genetic testing. Ultimately, genetic testing confirmed hypermethioninemia, which was attributed to a mutation in the MAT1A gene.
The intervention for the patients in this study took the following forms: regular follow-up without treatment (n = 3), intake of methionine-free milk powder without any medication (n = 4), intake of methionine-free milk powder with some medication, and eventually liver transplantation (n = 1).
A total of 14 mutation types were detected, including 3 compound heterozygous mutation types (c.926G > T, c.37_38delCT, and c.316G > A) that have not been previously reported. One patient had monoheterozygous mutations, including the novel mutation c.550-1G > A. Eight cases were monitored over time, 7 of which demonstrated typical growth and development. One infant with growth retardation was fed a special formula lacking methionine. The patient underwent liver transplantation. Subsequent follow-up examinations showed methionine and homocysteine levels within normal limits and no further neurological manifestations.
Compound heterozygous mutations c.874C > T and c.896G > A may result in higher levels of methionine, affecting the central nervous system. For newborns with initial methionine levels of >500 µmol/L, treatment with a low-Met diet is recommended. Liver transplantation may be beneficial for children with severe hypermethioninemia, particularly in preventing central nervous system damage.
由MAT1A基因缺陷引起的高甲硫氨酸血症临床异质性高,导致针对该患者群体临床表型、生化特征和基因突变之间关联的研究较少。此外,患者治疗干预的指征仍不明确。本研究的目的是为MAT1A基因缺陷引起的高甲硫氨酸血症的临床诊断、遗传咨询和随访管理提供依据。
采用串联质谱法(MS/MS)对济南市妇幼保健院2016年1月至2023年12月期间的高甲硫氨酸血症患儿进行回顾性分析。对筛查和诊断出的患儿采用二代测序技术检测基因突变,并通过Sanger测序进行确认。
新生儿疾病MS/MS筛查显示甲硫氨酸水平升高,超出参考范围。召回新生儿后,甲硫氨酸水平仍升高,需要进一步完善基因检测。最终,基因检测确诊为高甲硫氨酸血症,归因于MAT1A基因的突变。
本研究中患者的干预措施如下:定期随访不治疗(n = 3)、摄入无甲硫氨酸奶粉且未用药(n = 4)、摄入无甲硫氨酸奶粉并使用一些药物,最终进行肝移植(n = 1)。
共检测到14种突变类型,包括3种此前未报道的复合杂合突变类型(c.926G>T、c.37_38delCT和c.316G>A)。1例患者为单杂合突变,包括新突变c.550-1G>A。对8例患者进行了长期监测,其中7例生长发育正常。1例生长发育迟缓的婴儿喂养了缺乏甲硫氨酸的特殊配方奶粉。该患者接受了肝移植。后续随访检查显示甲硫氨酸和同型半胱氨酸水平在正常范围内,无进一步神经系统表现。
复合杂合突变c.874C>T和c.896G>A可能导致更高水平的甲硫氨酸,影响中枢神经系统。对于初始甲硫氨酸水平>500µmol/L的新生儿,建议采用低甲硫氨酸饮食治疗。肝移植可能对严重高甲硫氨酸血症患儿有益,尤其是在预防中枢神经系统损伤方面。
