TY - JOUR
T1 - Temporal Translational Control by a Metastable RNA Structure
AU - Møller-Jensen, Jakob
AU - Franch, Thomas
AU - Gerdes, Kenn
PY - 2001/9/21
Y1 - 2001/9/21
N2 - Programmed cell death by the hok/sok locus of plasmid R1 relies on a complex translational control mechanism. The highly stable hok mRNA is activated by 3'-end exonucleolytical processing. Removal of the mRNA 3' end releases a 5'-end sequence that triggers refolding of the mRNA. The refolded hok mRNA is translatable but can also bind the inhibitory Sok antisense RNA. Binding of Sok RNA leads to irreversible mRNA inactivation by an RNase III-dependent mechanism. A coherent model predicts that during transcription hok mRNA must be refractory to translation and antisense RNA binding. Here we provide genetic evidence for the existence of a 5' metastable structure in hok mRNA that locks the nascent transcript in an inactive configuration in vivo. Consistently, the metastable structure reduces the rate of Sok RNA binding and completely blocks hok translation in vitro. Structural analyses of native RNAs strongly support that the 5' metastable structure exists in the nascent transcript. Further structural analyses reveal that the mRNA 3' end triggers refolding of the mRNA 5' end into the more stable tac-stem conformation. These results provide a profound understanding of an unusual and intricate post-transcriptional control mechanism.
AB - Programmed cell death by the hok/sok locus of plasmid R1 relies on a complex translational control mechanism. The highly stable hok mRNA is activated by 3'-end exonucleolytical processing. Removal of the mRNA 3' end releases a 5'-end sequence that triggers refolding of the mRNA. The refolded hok mRNA is translatable but can also bind the inhibitory Sok antisense RNA. Binding of Sok RNA leads to irreversible mRNA inactivation by an RNase III-dependent mechanism. A coherent model predicts that during transcription hok mRNA must be refractory to translation and antisense RNA binding. Here we provide genetic evidence for the existence of a 5' metastable structure in hok mRNA that locks the nascent transcript in an inactive configuration in vivo. Consistently, the metastable structure reduces the rate of Sok RNA binding and completely blocks hok translation in vitro. Structural analyses of native RNAs strongly support that the 5' metastable structure exists in the nascent transcript. Further structural analyses reveal that the mRNA 3' end triggers refolding of the mRNA 5' end into the more stable tac-stem conformation. These results provide a profound understanding of an unusual and intricate post-transcriptional control mechanism.
U2 - 10.1074/jbc.M105347200
DO - 10.1074/jbc.M105347200
M3 - Journal article
C2 - 11461923
SN - 0021-9258
VL - 276
SP - 35707
EP - 35713
JO - Journal of Biological Chemistry
JF - Journal of Biological Chemistry
IS - 38
ER -