Ribonucleic acid synthesis termination protein rho function: effects of conditions that destabilize ribonucleic acid secondary structure

The dependence fo rate of adenosine 5'-triphosphate (ATP) hydrolysis catalyzed by ribonucleic acid (RNA) synthesis termination protein rho from Escherichia coli with T7 RNA as cofactor is used to probe the nature of the interaction between rho and RNA. In general, reaction conditions that destabilize the secondary structure of the RNA enhance its cofactor activity. This is indicated by the effects of MgCl2 concentration, spermidine, temperature, dimethyl sulfoxide, and pretreatment of the RNA with formaldehyde. These results suggest that a functional interaction between rho and RNA depends either on the presence of a sufficiently large single-stranded region in the RNA or on the ability of rho to unwind double helices in the RNA. It is also shown that changes in reaction conditions that increase RNA secondary structure and decrease the rho protein adenosine triphosphate phosphohydrolase (rhoATPase) activity with isolated T7 RNA also decrease the stringency of rho action in RNA synthesis termination. On the other hand, monovalent salts decrease rhoATPase activity with isolated T7 RNA and binding of rho to T7 RNA independently of the MgCl2 concentration and thus the relative stability of the RNA secondary structure.     

An RNA-dependent ATPase from Chlamydomonas reinhardII

An RNA-dependent ATPase has been isolated from extracts of Chlamydomonas reinhardii. The enzyme catalyzes the hydrolysis of ATP, dATP, CTP and dCTP to the corresponding nucleoside diphosphate and Pi in the presence of Mg2+ or Mn2+ and an RNA cofactor. In 1 mM MgCl2 it displays the greatest activity with poly(A), poly(I) and poly(U); and somewhat lower activity with poly(C) and T7 RNA. Although the enzyme is active with single-stranded DNA, all the single-stranded RNAs tested were significantly more effective cofactors than any of the single or double-stranded DNAs tested. A comparison of this ATPase with other RNA-dependent ATPases indicates that is has more in common with the ATPase isolated from the nuclei of animal cells than with the RNA synthesis termination protein rho, the major RNA-dependent ATPase from Escherichia coli. Although chloroplasts of C. reinhardii are known to contain many bacterial-like gene expression components, the presence of an enzyme with close homology to the E. coli rho protein was not detected.     

Mutant rho factors with increased transcription termination activities. II. Identification and functional dissection of amino acid changes

We have determined the nucleotide sequences of three mutant rho genes encoding hyperfunctional rho proteins (rho S) together with their parent allele, rho-ts702. These mutant rho factors contain the following amino acid changes as deduced from their sequences: (1) the thermo-labile mutant, rho-ts702, has Thr304 substituting for Ala; (2) rho S-77 and rho S-81, which are selectively altered in the primary polynucleotide binding site, share an identical mutation, Leu3----Phe; (3) rho S-82, which is altered in both the primary and secondary polynucleotide binding sites, carries three amino acid substitutions together, Leu3----Phe, Asp156----Asn and Thr323----Ile. Dissection and functional characterization of each mutation in rho S-82 have revealed that Ile323 alone is responsible for alterations in both the secondary RNA interaction and the terminator selectivity observed with the original mutant, rho S-82. Taken together, these results not only confirm our proposal in the accompanying paper that the primary and secondary RNA binding sites differently contribute in determining the overall efficiency and site-specificity of termination, respectively, but also support the possibility that these binding sites exist as structurally distinct domains in rho protein. In contrast, Asn156 was shown to cause decreased termination efficiency, though it had no influence on RNA interactions. Thus, this amino acid residue appears to be associated with still another rate-determining step of termination, for instance, interactions between rho and RNA polymerase. On the basis of Chou-Fasman secondary structure predictions as well as amino acid sequence comparison with F1-ATPase, we discuss how the proposed domains are structurally and functionally related to the putative ATPase reactive center of rho protein.