Identification and characterization of rns4/vps32 mutation in the RNase T1 expression-sensitive strain of Saccharomyces cerevisiae: Evidence for altered ambient response resulting in transportation of the secretory protein to vacuoles

We previously reported a genetic analysis of the growth-inhibitory effect caused by the overexpression of the Aspergillus oryzae rntA gene, encoding RNase T1 (Ribonuclease T1), in Saccharomyces cerevisiae. Subsequently, rns (ribonuclease T1 sensitive) mutants with mutations in the rns1 (DSL1), rns2 (UMP1), and rns3 (SEC17) genes, were identified. In the present study, rns4 (VPS32/SNF7) gene mutation was identified by complementation of tunicamycin sensitivity. While the rns4 mutant exhibited sensitivity to ambient stress conditions (200 mM CaCl(2), 1M NaCl and pH 8.0), genome-wide expression analysis revealed a similar pattern of genes up-regulated as was observed under nitrogen depletion condition by Gasch et al. [Mol. Biol. Cell 11 (2000) 4241]. Notably, the genes participating in autophagy (ATG4 and ATG8), the genes encoding a vacuolar protease (PRB1), vacuolar protease inhibitors (PAI3, PBI2 and TFS1) and YHR138c (a PBI2 homolog) were up-regulated in the rns4 mutant. Interestingly, the RNase T1*-GFP fusion protein (*inactive form) expressed in the rns4 mutant strain localized at the ER and vacuole under both stress or no-stress conditions. In contrast, the RNase T1*-GFP fusion protein expressed in the wild-type strain could not be detected under no-stress conditions, however, a stress-dependent localization of the fusion protein was observed at the vacuole. Since, the rns4 mutant exhibited a partial starvation-like response in spite of a rich ambient environment, leading to transportation of the secretory protein to the vacuole and accumulation in the endoplasmic reticulum, the present findings implicate a novel role for Rns4/Vps32 in proper response and adaptation to ambient conditions.     

Conformational stability and activity of ribonuclease T1 and mutants. Gln25----Lys, Glu58----Ala, and the double mutant

Ribonuclease T1 (RNase T1) and mutants Gln25----Lys, Glu58----Ala, and the double mutant were prepared from a chemically synthesized gene, cloned and expressed in Escherichia coli. The wild-type RNase T1 prepared from the cloned gene was identical in every functional and physical property examined to RNase T1 prepared from Aspergillus oryzae. Urea and thermal unfolding experiments show that Gln25----Lys is 0.9 kcal/mol more stable and Glu58----Ala is 0.8 kcal/mol less stable than wild-type RNase T1. In the double mutant, these contributions cancel and the stability does not differ significantly from that of wild-type RNase T1. For the double mutant, the dependence of delta G on urea concentration is significantly greater than for wild-type RNase T1 or the single mutants. This suggests that the double mutant unfolds more completely in urea than the other proteins. The activity of Gln25----Lys is identical with that of wild-type RNase T1. The activities of Glu58----Ala and the double mutant are 7% of wild-type when GpC hydrolysis is measured (due to a 35-fold decrease in kcat), and 37% of wild-type when RNA hydrolysis is measured. Thus, Glu58 is important, but not essential to the activity of RNase T1.     

Low Levels of RNase H Activity in Escherichia coli FB2 rnh Result from a Single-Base Change in the Structural Gene of RNase H

The DNA coding for RNase H from a mutant strain of Escherichia coli (FB2) was cloned into plasmid pBR322. DNA sequence analysis and the exchange of a portion of the mutant and wild-type genes revealed that a single-base alteration (C-->T) in the coding region of the structural gene for RNase H is responsible for the difference in RNase H activity of the wild-type and mutant cells.     

A thermoresistant mutant of ribonuclease T1 having three disulfide bonds

Molecular-dynamic calculations predict that, if Tyr24 and Asn84 are each replaced by a Cys residue, it should be possible to form a third disulfide bond in ribonuclease T1 (RNase T1) between these residues, with only minimal conformational changes at the catalytic site. The gene encoding such a mutant variant of RNase T1 (Tyr24----Cys24, Asn84----Cys84) was constructed by the cassette mutagenesis method using a chemically synthesized gene. In order to reduce the toxic effect of the mutant enzyme (RNase T1S) on an Escherichia coli host, we arranged for the protein to be secreted into the periplasmic space by using a vector that harbors a gene for an alkaline phosphatase signal peptide under the control of the trp promoter. The nucleolytic activity of RNase T1S toward pGpC was approximately the same as that of RNase T1 at 37 degrees C (pH 7.5). Moreover, at 55 degrees C, RNase T1S retained nearly 70% of its activity while the activity of the wild-type enzyme was reduced to less than 10%. RNase T1S was also more resistant to denaturation by urea than the wild-type enzyme. However, unlike RNase T1, RNase T1S was irreversibly and almost totally inactivated by boiling at 100 degrees C for 15 min.     

Ribonuclease D is not essential for the normal growth of Escherichia coli or bacteriophage T4 or for the biosynthesis of a T4 suppressor tRNA

Transposon Tn10-mediated rearrangement was used to isolate a strain of Escherichia coli carrying a deletion in the rnd region which is known to encode the structural gene for the putative 3' tRNA processing nuclease, RNase D. Genetic analysis indicated that about 0.4-0.5 min of the chromosome in the 39.5-40.0 min region was deleted. The mutant strain was devoid of RNase D activity, but other RNase activities were unaffected. The viability of the mutant strain and its normal growth characteristics indicate that RNase D is not essential for E. coli survival. The normal plating efficiency in this mutant host of wild type T4 and a T4 psu1+-amber double mutant indicates that RNase D is also not required for T4 growth or psu1+-tRNA processing. The implications of these findings for the role of RNase D in bacterial and bacteriophage tRNA metabolism, and the possible involvement of alternative enzymes, are discussed.     

Increase in nucleolytic activity of ribonuclease T1 by substitution of tryptophan 45 for tyrosine 45

The preparation and analysis of a mutant ribonuclease (RNase) T1 which possesses higher nucleolytic activity than the wild-type enzyme are described. The gene for the mutant RNase T1 (Tyr45----Trp45), in which a single amino acid at the binding site of the guanine base has been changed, was constructed by the cassette mutangenesis method using a chemically synthesized gene [Ikehara, M. et al. (1986) Proc. Natl Acad. Sci. USA 83, 4695-4699]. In order to reduce the nucleolytic activity of the enzyme in vivo, this gene was expressed in Escherichia coli as a fused protein connected through methionine residues to other proteins at both the N- and C-termini. After liberation from the fused protein by cleavage with cyanogen bromide at the methionine junctions, the mutant RNase T1 was purified by column chromatography. The nucleolytic activity toward pGpC increased to 120% of that of wild-type RNase T1. The kinetic parameters of the mutant enzyme demonstrate that this higher nucleolytic activity is due to a higher affinity for the substrate, probably because of an increased stacking effect in the binding pocket for the guanine base. This mutant enzyme also possessed a higher nucleolytic activity against pApC than wild-type RNase T1.     

Contribution of histidine residues to the conformational stability of ribonuclease T1 and mutant Glu-58----Ala

The pK values of the histidine residues in ribonuclease T1 (RNase T1) are unusually high: 7.8 (His-92), 7.9 (His-40), and 7.3 (His-27) [Inagaki et al. (1981) J. Biochem. 89, 1185-1195]. In the RNase T1 mutant Glu-58----Ala, the first two pK values are reduced to 7.4 (His-92) and 7.1 (His-40). These lower pKs were expected since His-92 (5.5 A) and His-40 (3.7 A) are in close proximity to Glu-58 at the active site. The conformational stability of RNase T1 increases by over 4 kcal/mol between pH 9 and 5, and this can be entirely accounted for by the greater affinity for protons by the His residues in the folded protein (average pK = 7.6) than in the unfolded protein (pk approximately 6.6). Thus, almost half of the net conformational stability of RNase T1 results from a difference between the pK values of the histidine residues in the folded and unfolded conformations. In the Glu-58----Ala mutant, the increase in stability between pH 9 and 5 is halved (approximately 2 kcal/mol), as expected on the basis of the lower pK values for the His residues in the folded protein (average pK = 7.1). As a consequence, RNase T1 is more stable than the mutant below pH 7.5, and less stable above pH 7.5. These results emphasize the importance of measuring the conformational stability as a function of pH when comparing proteins differing in structure.     

Processing of bacteriophage T4 tRNAs: a precursor of species 1 RNA

A precursor molecule of species 1 RNA, p2Sp1, that accumulates when an rne (RNase E-) mutant is infected with a T4 deletion mutant (delta 27) is also found after infection of an rne host mutant by different deletion mutants or wild type bacteriophage T4. Low levels of this molecule were also found in a wild-type host infected with a wild-type T4. This precursor molecule accumulates at higher concentrations at 43 degrees C as compared to 30 degrees C or 37 degrees C. Structural analysis of the precursor molecules from the different sources has shown a complete identity of p2Sp1 RNA isolated from the different sources. Therefore, we suggest that this precursor is a normal intermediate in processing of T4 tRNAs, and that it is unrelated to a particular T4 deletion strain. Since RNase E does not process this precursor, its accumulation in an rne mutant reflects an interaction between RNase E and the enzyme that processes this intermediate.     

Selection and characterization of randomly produced mutants in the gene coding for M1 RNA

The gene for M1 RNA, the catalytic subunit of RNase P of Escherichia coli, was subjected to random chemical mutagenesis in vitro. Mutations were selected by electrophoresis in denaturing gradient gels. Twenty-seven different mutants of the gene for M1 RNA were selected, and in 24 cases the mutations were identified as single base substitutions. The mutant forms of M1 RNA were analyzed in vitro for catalytic activity in the absence and in the presence of the protein subunit of RNase P (C5 protein). The structure of mutant RNAs was probed by limited digestion with ribonuclease T1; a correlation between reduced catalytic activity of mutant M1 RNAs and perturbations in secondary and tertiary structure was noted in many cases. The results indicate the involvement of specific regions of the M1 RNA molecule in the catalytic function of RNase P, in the binding of the C5 protein, and in substrate binding.     

Effect of the disease-causing mutations identified in human ribonuclease (RNase) H2 on the activities and stabilities of yeast RNase H2 and archaeal RNase HII

Eukaryotic ribonuclease (RNase) H2 consists of one catalytic and two accessory subunits. Several single mutations in any one of these subunits of human RNase H2 cause Aicardi-Goutières syndrome. To examine whether these mutations affect the complex stability and activity of RNase H2, three mutant proteins of His-tagged Saccharomyces cerevisiae RNase H2 (Sc-RNase H2*) were constructed. Sc-G42S*, Sc-L52R*, and Sc-K46W* contain single mutations in Sc-Rnh2Ap*, Sc-Rnh2Bp*, and Sc-Rnh2Cp*, respectively. The genes encoding the three subunits were coexpressed in Escherichia coli, and Sc-RNase H2* and its derivatives were purified in a heterotrimeric form. All of these mutant proteins exhibited enzymatic activity. However, only the enzymatic activity of Sc-G42S* was greatly reduced compared to that of the wild-type protein. Gly42 is conserved as Gly10 in Thermococcus kodakareansis RNase HII. To analyze the role of this residue, four mutant proteins, Tk-G10S, Tk-G10A, Tk-G10L, and Tk-G10P, were constructed. All mutant proteins were less stable than the wild-type protein by 2.9-7.6 degrees C in T(m). A comparison of their enzymatic activities, substrate binding affinities, and CD spectra suggests that the introduction of a bulky side chain into this position induces a local conformational change, which is unfavorable for both activity and substrate binding. These results indicate that Gly10 is required to make the protein fully active and stable.     

Mechanism of action of RNase T. II. A structural and functional model of the enzyme

A detailed structural and functional model of E. coli RNase T was generated based on sequence analysis, homology modeling, and experimental observation. In the accompanying article, three short sequence segments (nucleic acid binding sequences (NBS)) important for RNase T substrate binding were identified. In the model, these segments cluster to form a positively charged surface patch. However, this patch is on the face of the RNase T monomer opposite the DEDD catalytic center. We propose that by dimerization, the NBS patch from one subunit is brought to the vicinity of the DEDD center of the second monomer to form a fully functional RNase T active site. In support of this model, mutagenetic studies show that one NBS1 residue, Arg(13), sits at the catalytic center despite being on the opposite side of the monomer. Second, the complementarity of the RNase T subunits through the formation of homodimers was demonstrated by reconstitution of partial RNase T activity from monomers derived from two inactive mutant proteins, one defective in catalysis and one in substrate binding. These data explain why RNase T must dimerize to function. The model provides a detailed framework on which to explain the mechanism of action of RNase T.     

Domain swapping in ribonuclease T1 allows the acquisition of double-stranded activity

A mutant of ribonuclease T1 (RNase T1), denoted RNase Talpha, that is designed to recognize double-stranded ribonucleic acid was created. RNase Talpha carries the structure of RNase T1 except for a part of its loop L3 domain, which has been swapped for a corresponding domain from alpha-sarcin. The RNase Talpha maintains the pleated beta-sheet structure and retains the guanyl-specific ribonuclease activity of the wild-type RNase T1. A steady-state kinetic study on the RNase Talpha-catalyzed transesterification of GpU dinucleoside phosphates reveals a slightly reduced K(m) value of 6.94 x 10(-7) M. When the stranded specificity is examined, RNase Talpha catalyzes the hydrolysis of guanine base not only of single-stranded but also, as by design, of double-stranded RNA. The change of stranded specificity suggests the feasibility of using domain swapping to make a substrate-specific ribonuclease. This study suggests that the loop L3 in RNase T1 can be used as a 'cassette player' for inserting a functional domain to make ribonuclease of various specificities.     

Opposite roles of the dmd gene in the control of RNase E and RNase LS activities

When the dmd gene of bacteriophage T4 is defective, expression of middle genes starts normally but drops abruptly. However, the residual expression of middle genes at late stages continues at a higher rate in cells infected with a dmd mutant than with the wild type. In order to understand the complex effects of the dmd gene, we followed changes in the quantity of mRNA from a middle gene, uvsY. The uvsY mRNA was degraded rapidly by RNase LS at middle stages but stabilized at late stages, suggesting that RNase LS targets middle-gene mRNAs only at middle stages. Furthermore, another RNase targeting middle mRNAs at late stages is also suggested to be inactivated when dmd is mutated. We found that RNase E was involved in the degradation of uvsY mRNA. Judging from the processing of gene-32 mRNA, RNase E activity declines after the beginning of the middle stage when dmd is defective.     

Dissection of the structural and functional role of a conserved hydration site in RNase T1

The reoccurrence of water molecules in crystal structures of RNase T1 was investigated. Five waters were found to be invariant in RNase T1 as well as in six other related fungal RNases. The structural, dynamical, and functional characteristics of one of these conserved hydration sites (WAT1) were analyzed by protein engineering, X-ray crystallography, and (17)O and 2H nuclear magnetic relaxation dispersion (NMRD). The position of WAT1 and its surrounding hydrogen bond network are unaffected by deletions of two neighboring side chains. In the mutant Thr93Gln, the Gln93N epsilon2 nitrogen replaces WAT1 and participates in a similar hydrogen bond network involving Cys6, Asn9, Asp76, and Thr91. The ability of WAT1 to form four hydrogen bonds may explain why evolution has preserved a water molecule, rather than a side-chain atom, at the center of this intricate hydrogen bond network. Comparison of the (17)O NMRD profiles from wild-type and Thr93Gln RNase T1 yield a mean residence time of 7 ns at 27 degrees C and an orientational order parameter of 0.45. The effects of mutations around WAT1 on the kinetic parameters of RNase T1 are small but significant and probably relate to the dynamics of the active site.