The structures of polio-, coxsackie-, and rhinovirus polymerases have revealed a conserved yet unusual protein conformation surrounding their buried N termini where a beta-strand distortion results in a solvent-exposed hydrophobic amino acid at residue 5. In a previous study, we found that coxsackievirus polymerase activity increased or decreased depending on the size of the amino acid at residue 5 and proposed that this residue becomes buried during the catalytic cycle. In this work, we extend our studies to show that poliovirus polymerase activity is also dependent on the nature of residue 5 and further elucidate which aspects of polymerase function are affected. Poliovirus polymerases with mutations of tryptophan 5 retain wild-type elongation rates, RNA binding affinities, and elongation complex formation rates but form unstable elongation complexes. A large hydrophobic residue is required to maintain the polymerase in an elongation-competent conformation, and smaller hydrophobic residues at position 5 progressively decrease the stability of elongation complexes and their processivity on genome-length templates. Consistent with this, the mutations also reduced viral RNA production in a cell-free replication system. In vivo, viruses containing residue 5 mutants produce viable virus, and an aromatic phenylalanine was maintained with only a slightly decreased virus growth rate. However, nonaromatic amino acids resulted in slow-growing viruses that reverted to wild type. The structural basis for this polymerase phenotype is yet to be determined, and we speculate that amino acid residue 5 interacts directly with template RNA or is involved in a protein structural interaction that stabilizes the elongation complex.