PUBLIC RELEASE DATE: <\/p>\n
25-Nov-2014 <\/p>\n
Contact: Alex Reid alexander.reid@tufts.edu<\/a> 617-627-4173 Tufts University @TuftsUniversity<\/p>\n Medford\/Somerville, Mass--Researchers in human genetics have known that long nucleotide repeats in DNA lead to instability of the genome and ultimately to human hereditary diseases such Freidreich's ataxia and Huntington's disease. <\/p>\n Scientists have believed that the lengthening of those repeats occur during DNA replication when cells divide or when the cellular DNA repair machinery gets activated. Recently, however, it became apparent that yet another process called transcription, which is copying the information from DNA into RNA, could also been involved. <\/p>\n A Tufts University study published online on November 20 in the journal \"Cell Reports\" by a research team lead by Sergei Mirkin, the White Family Professor of Biology at Tufts' School of Arts and Sciences, along with former graduate student Kartick Shah and graduate students Ryan McGuity and Vera Egorova, explores the relationship between transcription and the expansions of DNA repeats. It concludes that the active transcriptional state of a DNA segment containing a DNA repeat predisposes it for expansions. The print version of the study will be published on December 11. <\/p>\n \"There are a great many simple repetitive motifs in our DNA, such as GAAGAAGAA or CGGCGGCGG,\" says Mirkin. \"They are stable and cause no harm if they stay short. Occasionally, however, they start lengthening compulsively, and these uncontrollable expansions lead to dramatic changes in genome stability, gene expression, which can lead to human disease.\" <\/p>\n In their study, the researchers used baker's yeast to monitor the progress and the fundamental genetic machineries for transcription, replication and repair in genome functioning. <\/p>\n \"The beauty of the yeast system is that it provides one with a practically unlimited arsenal of tools to study the mechanisms of genome functioning,\" says Mirkin. \"We created genetic systems to track down expansions of the repeats that were positioned in either transcribed or non-transcribed parts of reporter genes.\" <\/p>\n After measuring the rate of repeat expansions in all these cases, the authors found that a repeat can expand under the condition when there is practically no transcription, but the likelihood of the expansion process is drastically (10-fold) higher when the reporter is transcriptionally active. <\/p>\n <\/p>\n See the article here: <\/p>\n A link between DNA transcription and disease-causing expansions<\/a><\/p>\n","protected":false},"excerpt":{"rendered":" PUBLIC RELEASE DATE: 25-Nov-2014 Contact: Alex Reid alexander.reid@tufts.edu<\/a> 617-627-4173 Tufts University @TuftsUniversity Medford\/Somerville, Mass--Researchers in human genetics have known that long nucleotide repeats in DNA lead to instability of the genome and ultimately to human hereditary diseases such Freidreich's ataxia and Huntington's disease. Continue reading