Sequence and Target Specificity of the C. elegans Cell Fate Specification Factor POS-1: A Dissertation

In most metazoans, early embryogenesis is controlled by the translational regulation of maternally supplied mRNA. Sequence-specific RNA-binding proteins play an important role in regulating early embryogenesis, yet their specificities and regulatory targets are largely unknown. To understand how these RNA-binding proteins select their targets, my research focused on the C. elegans CCCH-type tandem zinc finger protein POS-1. Embryos lacking maternally supplied POS-1 die prior to gastrulation, and exhibit defects in the specification of pharyngeal, intestinal, and germline precursor cells. To identify the regulatory targets that contribute to the POS-1 mutant phenotype, we set out to determine the sequence specificity of POS-1 in vitro, and then use this information to identify regulatory targets in vivo. Using a candidate-based search, we identified a twelve-nucleotide fragment of the mex-3 3' untranslated region (3' UTR) to which POS-1 binds with high affinity. Using quantitative fluorescent electrophoretic mobility shift assays, I determined the affinity of the RNA-binding domain of POS-1 for a panel of single nucleotide mutations of this sequence, and then defined a consensus binding element based on this dataset. POS-1 recognizes the degenerate element UAU2-3RDN1-3G, where R is any purine (adenosine or guanine), and D is any base except cytosine. A bioinformatics analysis revealed the presence of this element in approximately 40% of C. elegans 3' UTRs, suggesting that POS-1 is capable of binding to and perhaps regulating many transcripts in vivo. POS-1 binding sites alone are not sufficient to pattern the expression of a reporter, suggesting that other factors may contribute to POS-1 specificity.