MTHFR: Genetic variants, expression analysis and COMT interaction in major depressive disorder

作者:Nielsen Maria Gabriela; Congiu Chiara; Bortolomasi Marco; Bonvicini Cristian; Bignotti Stefano; Abate Maria; Milanesi Elena; Conca Andreas; Cattane Nadia; Tessari Elisabetta; Gennarelli Massimo; Minelli Alessandra*
来源:Journal of Affective Disorders, 2015, 183: 179-186.
DOI:10.1016/j.jad.2015.05.003

摘要

Background: Methylenetetrahydrofolate recluctase (MTHFR) genetic variations have been widely studied in major depressive disorder (MDD) and antidepressants outcome. An interaction with catechol-O-methyltransferase (COMT) has also been proved affecting depression. The aim of this study was to clarify the role of the most commonly studied single nucleotide polymorphisms (SNPs) of MTHFR gene in MDD and in treatment response mechanisms, along with the impact of the interaction with COMT. Methods: A total of 613 MDD patients, of whom 389 were classified as having treatment resistant depression (TRD), and 463 controls were enrolled. The A1298C, C677T and COMT Val158Met were genotyped. Genetic data were integrated with a transcriptional level analysis in peripheral blood cells (PBCs) and fibroblasts. Results: The A1298C CC homozygotes were more frequent in MDD patients compared to controls in women, increasing twice the genetic risk to develop depression. Moreover this genotype resulted in epistasis with COMT Met carriers in association with MDD. No significant effects were obtained concerning response to treatment. Transcriptional analyses highlighted a strong correlation between the mRNA levels of MTHFR in fibroblasts and COMT genotypes whereas no significant association with MDD was found. PBCs results revealed relevant influences of environmental factors. Limitation: We did not measure Mate and homocisteine levels. Conclusion: This study showed the involvement of A1298C, Val158Met and their interaction in MDD. The transcriptional analyses supported the participation of COMT in the folate pathway, which partakes in the complex network of gene x gene and gene x environment interactions of MDD etiopathogenesis.