The translocation stage of protein synthesis is
a highly conserved process in all cells. Although the components
necessary for translocation have been delineated, the mechanism
of this activity has not been well defined. Ribosome movement
on template mRNA must allow for displacement of tRNA–mRNA
complexes from the ribosomal A to P sites and P to E sites,
while ensuring rigid maintenance of the correct reading
frame. In Escherichia coli, translocation of the
ribosome is promoted by elongation factor G (EF-G). To
examine the role of EF-G and rRNA in translocation we have
characterized mutations in rRNA genes that can suppress
a temperature-sensitive (ts) allele of fusA, the
gene in E. coli that encodes EF-G. This analysis
was performed using the ts E. coli strain PEM100,
which contains a point mutation within fusA. The
ts phenotype of PEM100 can be suppressed by either of two
mutations in the decoding region of the 16S rRNA when present
in combination with a mutation at position 2058 in the
peptidyltransferase domain of the 23S rRNA. Communication
between these ribosomal domains is essential for coordinating
the events of the elongation cycle. We propose a model
in which EF-G promotes translocation by modulating this
communication, thereby increasing the efficiency of this
fundamental process.