Other polymorphisms such as in intron 8 of the FTO gene has been linked to an increased LDK378 solubility dmso risk of developing melanoma [66]. While the functional consequences of single nucleotide polymorphisms in the intronic region of FTO are still unknown, loss-of-function mutations of FTO in humans lead to an autosomal-recessive lethal syndrome of severe growth retardation, microcephaly, psychomotor delay, cardiac deficits, and multiple malformations, and at least some of these effects may be due to impaired proliferation and accelerated senescence [67]. Similarly,
Fto deficiency in mice leads to postnatal lethality, growth retardation, and multiple malformations [62]. The only limited information available about AlkBH5 indicated an essential role in gametogenesis. AlkBH5 expression is highest in primary spermatocytes in the mouse testes, and its inactivation leads to testis atrophy and infertility due to failure to enter and proceed through spermatogenic differentiation [54]. In summary, it is not fully understood how m6A affects the fate of methylated mRNAs and lncRNAs. While some evidence suggests that m6A occurrence in mRNA is inversely correlated to stability [52], it remains unclear whether specific locations within a transcript dictates distinct
roles in RNA processing. What does become clear however is that m6A deposition plays essential roles in mRNA metabolism, PF-562271 in vitro and both m6A methylases and demethylases are crucial during embryonic development and homeostasis of the central nervous, cardiovascular and reproductive systems. Furthermore, aberrant m6A methylation pathways are linked to a range of human diseases including infertility, obesity as well as developmental and neurological disorders. In only a couple years, our understanding about RNA methylation pathways advanced with remarkable speed and the importance of RNA methylation and its role in human diseases is now widely recognized. However,
the precise molecular pathways and cellular processes regulated by these modifications are still largely unclear. Furthermore, we only described current advances on m5C and m6A methylation, but a large number of other intriguing chemical modifications 4-Aminobutyrate aminotransferase exist in RNAs. Thus, our current knowledge only scratches the surface of the many roles of post-transcriptional modifications in modulating transcriptional and translational processes. Further advances in the field will rely on the development of new system-wide strategies to first, reliably detect m5C in mRNA or other low abundant RNAs, second, map m6A at single nucleotide resolution and third, to identify other RNA modifications. To fully understand the biological roles of RNA methylation, it will be required to identify all RNA methylases, de-methylases, the regulatory pathways that control their activity and their specific RNA targets. A major goal will be to dissect the precise mechanisms how RNA modifications affect global and specific protein production.