The coxsackie B3 virus oriR is an element of
viral RNA thought to promote the assembly of a ribonucleoprotein
complex involved in the initiation of genome replication.
The mutual orientation of its two helical domains X and
Y is determined by a kissing interaction between the loops
of these domains. Here, a genetic approach was worked out
to identify spatial orientation-dependent recognition signals
in these helices. Spatial orientation changes (due to linear
and rotational shifts) were introduced by appropriate insertions/deletions
of a single base pair into one or both of the domains,
and phenotypic consequences caused by these mutations were
studied. The insertion of a base pair into domain Y caused
a defect in viral reproduction that could be suppressed
by a base-pair insertion into domain X. Similarly, a defect
in viral replication caused by a base-pair deletion from
domain X could be suppressed by a base-pair deletion from
domain Y. Thus, certain areas of the two domains should
cross-talk to one another in the sense that a change of
space position of one of them required an adequate reply
(change of space position) from the other. Phenotypic effects
of the local rotation of one or more base pairs (and of
some other mutations) in either domain X or domain Y suggested
that the two most distal base pairs of these domains served
as orientation-dependent recognizable signals. The results
were also consistent with the notion that the recognition
of the distal base pair of domain Y involved a mechanism
similar to the intercalation of an amino acid residue.