Loss of 4.5S RNA induces the heat shock response and lambda prophage in Escherichia coli.

During depletion of 4.5S RNA, cells of Escherichia coli displayed a heat shock response that was simultaneous with the first detectable effect on ribosome function and before major effects on cell growth. Either 4.5S RNA is involved directly in regulating the heat shock response, or this particular impairment of protein synthesis uniquely induces the heat shock response. Several hours later, lambda prophage was induced and the cells lysed.

Initiation of translation is impaired in E. coli cells deficient in 4.5S RNA.

The 4.5S RNA of Escherichia coli is a small, stable RNA that is essential for cell growth but its function is not yet known. Its biosynthesis is stringently controlled, and it is processed by RNase P, a transfer RNA processing enzyme. To identify the biological role of the 4.5S species, we have characterized the physiological changes that occur when the bacterial cell is depleted of this RNA. We used a strain of E. coli in which synthesis of the 4.5S RNA can be turned off by removing an inducer of the Iac operon, resulting in cell death. We report here that an early consequence of depriving the cell of 4.5S RNA is the accumulation of translationally-defective ribosomes, which maintain their ability to elongate polypeptide chains, but can no longer participate in the initiation of protein synthesis.

Physical properties of the E. coli 4.5S RNA: first results suggest a hairpin helix of unusual thermal stability.

Hyperchromicity measurements and quasi-elastic laser light scattering (QELS) have been used to assess the solution structure of the metabolically stable E. coli 4.5S RNA. Results from thermal denaturation measurements revealed the 4.5S species to be markedly more stable than most other RNAs characterized thus far. Optical Tm's range from 79 degrees to 88 degrees with transitions approximately 25 degrees C wide. The Tm values show little dependence on ionic strength, but stability is enhanced considerably by Mg+2. In the QELS experiments the diffusion coefficient does not decrease until T greater than 70 degrees C. Neither the diffusive melting nor the diffusion coefficient at infinite dilution (D0(20,w)) show dependencies on ionic strength but both are influenced by Mg+2. The diffusion behavior is in agreement with that predicted for a rigid cylindrical molecule 125 to 160 A long and 37 to 26 A in diameter. Taken together these results are consistent with the more stable hypothetical secondary structures that can be formed, in which 70-75% of the 114 bases are paired to form a single extended hairpin helix.