AI Article Synopsis
- The m.1555A>G mitochondrial DNA mutation can lead to hearing loss, particularly following exposure to certain antibiotics, but it can also cause inherited hearing loss without antibiotic exposure.
- There is ongoing debate about how this mutation affects hearing; recent studies have suggested an increase in a certain type of RNA methylation (m(6) 2A) associated with mitochondrial dysfunction as a potential mechanism.
- Research involving 14 patients revealed that while RNA transcripts from transformed cells had unmethylated regions, primary cells showed all detectable transcripts were methylated, suggesting that increased RNA methylation may not be a direct cause of hearing loss and highlighting the need for further studies with human samples.
Article Abstract
The mitochondrial DNA mutation m.1555A>G predisposes to hearing loss following aminoglycoside antibiotic exposure in an idiosyncratic dose-independent manner. However, it may also cause maternally inherited hearing loss in the absence of aminoglycoside exposure or any other clinical features (non-syndromic hearing loss). Although m.1555A>G was identified as a cause of deafness more than twenty years ago, the pathogenic mechanism of this mutation of ribosomal RNA remains controversial. Different mechanistic concepts have been proposed. Most recently, evidence from cell lines and animal models suggested that patients with m.1555A>G may have more 12S rRNA N6, N6-dimethyladenosine (m(6) 2A) methylation than controls, so-called 'hypermethylation'. This has been implicated as a pathogenic mechanism of mitochondrial dysfunction but has yet to be validated in patients. 12S m(6) 2A rRNA methylation, by the mitochondrial transcription factor 1 (TFB1M) enzyme, occurs at two successive nucleotides (m.1584A and m.1583A) in close proximity to m.1555A>G. We examined m(6) 2A methylation in 14 patients with m.1555A>G, and controls, and found all detectable 12S rRNA transcripts to be methylated in both groups. Moreover, different RNA samples derived from the same patient (lymphocyte, fibroblast and lymphoblast) revealed that only transformed cells contained some unmethylated 12S rRNA transcripts, with all detectable 12S rRNA transcripts derived from primary samples m(6) 2A-methylated. Our data indicate that TFB1M 12S m(6) 2A rRNA hypermethylation is unlikely to be a pathogenic mechanism and may be an artefact of previous experimental models studied. We propose that RNA methylation studies in experimental models should be validated in primary clinical samples to ensure that they are applicable to the human situation.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4986548 | PMC |
| http://dx.doi.org/10.1093/hmg/ddu518 | DOI Listing |
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