Long Conserved Fragments Upstream of Mammalian Polyadenylation Sites

Polyadenylation is a cotranscriptional nuclear RNA processing event involving endonucleolytic cleavage of the nascent, emerging pre-messenger RNA (pre-mRNA) from the RNA polymerase, immediately followed by the polymerization of adenine ribonucleotides, called the poly(A) tail, to the cleaved 3′ end of the polyadenylation site (PAS). This apparently simple molecular processing step has been discovered to be connected to transcription and splicing therefore increasing its potential for regulation of gene expression. Here, through a bioinformatic analysis of cis-PAS–regulatory elements in mammals that includes taking advantage of multiple evolutionary time scales, we find unexpected selection pressure much further upstream, up to 200 nt, from the PAS than previously thought. Strikingly, close to 3,000 long (30–500 nt) noncoding conserved fragments (CFs) were discovered in the PAS flanking region of three remotely related mammalian species, human, mouse, and cow. When an even more remote transitional mammal, platypus, was included, still over a thousand CFs were found in the proximity of the PAS. Even though the biological function of these CFs remains unknown, their considerable sizes makes them unlikely to serve as protein recognition sites, which are typically ≤15 nt. By harnessing genome wide DNaseI hypersensitivity data, we have discovered that the presence of CFs correlates with chromatin accessibility. Our study is important in highlighting novel experimental targets, which may provide new understanding about the regulatory aspects of polyadenylation

Pro-apoptotic protein–protein interactions of the extended N-AChE terminus

The N-terminally extended “synaptic” acetylcholinesterase variant N-AChE-S operates to promote apoptosis; however, the protein partners involved in this function remain unknown. Here, we report that when microinjected to fertilized mouse oocytes, N-AChE-S caused embryonic death as early as the zygotic stage. To identify the putative protein partners involved, we first tried yeast two hybrid screening, but this approach failed, probably because of the N-AChE-S-induced lethality. In contrast, sequence analysis and a corresponding peptide array revealed possible partners, which were validated by co-immunoprecipitation. These include the kinases GSK3, Aurora and GAK, the membrane integrin receptors, and the death receptor FAS. Each of these could potentially modulate N-AChE-S-induced apoptosis with possible therapeutic value for the treatment of Alzheimer’s disease