PROJECT SUMMARY The Ccr4-Not complex is the major regulator of codon optimality-mediated messenger RNA decay, a mechanism that is intimately tied to translation rate. The disruption of co-translational mRNA decay events can have major physiological effects, leading to haploinsufficiency or contributing to cancer. For instance, CNOT3, a subunit of the Ccr4-Not complex, was recently identified as a tumor suppressor that is mutated in 7.9% of adult T-cell acute lymphoblastic leukemias (T-ALLs). Recent work in our lab identified that Not5 (yeast homolog of human CNOT3) directly binds to the E-site of slowly translating ribosomes, leading to the preferential decay of non-optimal mRNA transcripts. This interaction was recently found to be conserved in humans, suggesting a mechanism for how cells use the mRNA decay machinery to alter transcript levels. Though the structure of Not5 interacting with elongating ribosomes has been resolved, nothing is currently known about how Not5 interacts with members of the Ccr4-Not complex to facilitate mRNA decay. Thus, teasing apart how the decay machinery mechanistically regulates the degradation of mRNA will be critical in understanding how cells regulate transcript levels as well as open avenues of therapeutic intervention for a broad range of haploinsufficiency diseases and cancer. To address this gap in knowledge, I will mechanistically dissect how the Ccr4-Not complex assembles onto actively translating ribosomes and assess how the subunits of this complex coordinate the removal of the poly-A tail and 5’-cap of mRNAs using the budding yeast, Saccharomyces cerevisiae as a model system. Preliminary data from our lab shows that Not5 binding to the ribosomal E-site is necessary for the recruitment of the mRNA decay factor, Dhh1, to translating ribosomes, but the details of this recruitment pathway remain opaque. We do not yet understand if Not5 is involved in the recruitment of the remaining mRNA decay factors and how this recruitment might coordinate decay events. Likewise, the loss Dhh1 is known to exhibit decapping defects and recently we found that the loss of this factor also exhibits defects in pol-A tail removal of mRNAs, meaning Dhh1 recruitment may serve to bridge these 3’-5’ decay events. I hypothesize that Not5 recruits the remaining Ccr4-Not subunits to actively translating ribosomes resulting in the timely decay of mRNA transcripts. I will address this hypothesis through the following specific aims: Aim 1) I will systematically determine the assembly of the Ccr4- Not complex subunits onto the translating mRNP structure and determine if this assembly is Not5- dependent. Aim 2) I will characterize the contacts between Dhh1 and the Ccr4-Not complex to determine if their interaction mediates the 3’-5’ communication of mRNA decay. The proposed studies will enhance our mechanistic insight into how mRNA half-lives are regulated and provide the basis for detailed understanding of this role in human disease.