Properties of Unpaired DNA Required For Efficient Silencing in Neurospora crassa

doi:10.1534/genetics.167.1.131

Properties of Unpaired DNA Required For Efficient Silencing in Neurospora crassa

Dong W. Lee^a, Kye-Yong Seong^a, Robert J. Pratt^a, Kevin Baker^a, and Rodolfo Aramayo^a
^a Department of Biology, College of Science, Texas A&M University, College Station, Texas 77843-3258

Corresponding author: Rodolfo Aramayo, College of Science, Texas A&M University, Room 414A, Bldg. BSBW, College Station, TX 77843-3258., raramayo{at}mail.bio.tamu.edu (E-mail)

Communicating editor: J. J. LOROS

The presence of unpaired copies of a gene during meiosis triggerssilencing of all copies of the gene in the diploid ascus cellof Neurospora. This phenomenon is called meiotic silencing andon the basis of genetic studies appears to be a post-transcriptionalgene silencing (PTGS) mechanism. Previously, meiotic silencingwas defined to be induced by the presence of a DNA region lackingan identical segment in the homologous chromosome. However,the determinants of unpaired DNA remained a mystery. Using theAscospore maturation-1 (Asm-1) gene, we defined what needs tobe "unpaired" to silence a gene. For efficient silencing, anunpaired region of DNA needs to be of a sufficient size andcontain homology to the reporter transcript. The greater thesize of the loop and the larger the homology to the reportertranscript, the better the resulting meiotic silencing is. Conversely,regions not containing homology to the transcript, e.g., intergenicregions, did not silence the reporter. Surprisingly, unpairedfragments lacking a canonical promoter silenced the reporter.Additionally, we detected the unpairing-dependent loss of atranscript during meiotic silencing. Our observations furthersupport a PTGS mechanism for meiotic silencing and offer insightinto the evolutionary consequences resulting from this novelmeiotic checkpoint.

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