RNAPs (RNA polymerases) are complex molecular machines containing structural domains that co-ordinate the movement of nucleic acid and nucleotide substrates through the catalytic site. X-ray images of bacterial, archaeal and eukaryotic RNAPs have provided a wealth of structural detail over the last decade, but many mechanistic features can only be derived indirectly from such structures. We have therefore implemented a robotic high-throughput structure-function experimental system based on the automatic generation and assaying of hundreds of site-directed mutants in the archaeal RNAP from Methanocaldococcus jannaschii. In the present paper, I focus on recent insights obtained from applying this experimental strategy to the bridge-helix domain. Our work demonstrates that the bridge-helix undergoes substantial conformational changes within a narrowly confined region (mjA' Ala(822)-Gln(823)-Ser(824)) during the nucleotide-addition cycle. Naturally occurring radical sequence variations in plant RNAP IV and V enzymes map to this region. In addition, many mutations within this domain cause a substantial increase in the RNAP catalytic activity ('superactivity'), suggesting that the RNAP active site is conformationally constrained.