Mapping RNA-protein interactions in ribonuclease P from Escherichia coli using disulfide-linked EDTA-Fe

The protein subunit of Escherichia coli ribonuclease P (which has a cysteine residue at position 113) and its single cysteine-substituted mutant derivatives (S16C/C113S, K54C/C113S and K66C/C113S) have been modified using a sulfhydryl-specific iron complex of EDTA-2- aminoethyl 2-pyridyl disulfide (EPD-Fe). This reaction converts C5 protein, or its single cysteine-substituted mutant derivatives, into chemical nucleases which are capable of cleaving the cognate RNA ligand, M1 RNA, the catalytic RNA subunit of E. coli RNase P, in the presence of ascorbate and hydrogen peroxide. Cleavages in M1 RNA are expected to occur at positions proximal to the site of contact between the modified residue (in C5 protein) and the ribose units in M1 RNA. When EPD-Fe was used to modify residue Cys16 in C5 protein, hydroxyl radical-mediated cleavages occurred predominantly in the P3 helix of M1 RNA present in the reconstituted holoenzyme. C5 Cys54-EDTA-Fe produced cleavages on the 5' strand of the P4 pseudoknot of M1 RNA, while the cleavages promoted by C5 Cys66-EDTA-Fe were in the loop connecting helices P18 and P2 (J18/2) and the loop (J2/4) preceding the 3' strand of the P4 pseudoknot. However, hydroxyl radical-mediated cleavages in M1 RNA were not evident with Cys113-EDTA-Fe, perhaps indicative of Cys113 being distal from the RNA-protein interface in the RNase P holoenzyme. Our directed hydroxyl radical-mediated footprinting experiments indicate that conserved residues in the RNA and protein subunit of the RNase-P holoenzyme are adjacent to each other and provide structural information essential for understanding the assembly of RNase P.     

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.     

Sequence changes in both flanking sequences of a pre-tRNA influence the cleavage specificity of RNase P.

The cleavage specificities of the RNase P holoenzymes from Escherichia coli and the yeast Schizosaccharomyces pombe and of the catalytic M1 RNA from E. coli were analyzed in 5'-processing experiments using a yeast serine pre-tRNA with mutations in both flanking sequences. The template DNAs were obtained by enzymatic reactions in vitro and transcribed with phage SP6 or T7 RNA polymerase. The various mutations did not alter the cleavage specificity of the yeast RNase P holoenzyme; cleavage always occurred predominantly at position G + 1, generating the typical seven base-pair acceptor stem. In contrast, the specificity of the prokaryotic RNase P activities, i.e. the catalytic M1 RNA and the RNase P holoenzyme from E. coli, was influenced by some of the mutated pre-tRNA substrates, which resulted in an unusual cleavage pattern, generating extended acceptor stems. The bases G - 1 and C + 73, forming the eighth base pair in these extended acceptor stems, were an important motif in promoting the unusual cleavage pattern. It was found only in some natural pre-tRNAs, including tRNA(SeCys) from E. coli, and tRNAs(His) from bacteria and chloroplasts. Also, the corresponding mature tRNAs in vivo contain an eight base pair acceptor stem. The presence of the CCA sequence at the 3' end of the tRNA moiety is known to enhance the cleavage efficiency with the catalytic M1 RNA. Surprisingly, the presence or absence of this sequence in two of our substrate mutants drastically altered the cleavage specificity of M1 RNA and of the E. coli holoenzyme, respectively. Possible reasons for the different cleavage specificities of the enzymes, the influence of sequence alterations and the importance of stacking forces in the acceptor stems are discussed.     

Mutations affecting two distinct functions of the RNA component of RNase P.

The effect of structural changes on the functions of the RNA component (M1 RNA) of ribonuclease P (RNase P) of Escherichia coli has been studied using the thermosensitive mutants of the rnpB gene. One of the mutants, ts709, has two G--A substitutions at positions 89 and 365 from the 5' end of M1 RNA. Of these substitutions, the one at position 89 from the 5' end is responsible for the phenotype of this mutant. Although the RNase P activity of ts709 is thermosensitive, the mutant M1 RNA has the same catalytic activity as the wild-type RNA. M1 RNA of another mutant, ts2418, has a G--A substitution at position 329. This mutant RNA has extremely low catalytic activity. The upstream mutational site of ts709 appears to play a role in the association with the protein subunit, whereas the mutational site of ts2418 is related to the catalytic function of M1 RNA.     

The precursor tRNA 3'-CCA interaction with Escherichia coli RNase P RNA is essential for catalysis by RNase P in vivo

The L15 region of Escherichia coli RNase P RNA forms two Watson-Crick base pairs with precursor tRNA 3'-CCA termini (G292-C75 and G293-C74). Here, we analyzed the phenotypes associated with disruption of the G292-C75 or G293-C74 pair in vivo. Mutant RNase P RNA alleles (rnpBC292 and rnpBC293) caused severe growth defects in the E. coli rnpB mutant strain DW2 and abolished growth in the newly constructed mutant strain BW, in which chromosomal rnpB expression strictly depended on the presence of arabinose. An isosteric C293-G74 base pair, but not a C292-G75 pair, fully restored catalytic performance in vivo, as shown for processing of precursor 4.5S RNA. This demonstrates that the base identity of G292, but not G293, contributes to the catalytic process in vivo. Activity assays with mutant RNase P holoenzymes assembled in vivo or in vitro revealed that the C292/293 mutations cause a severe functional defect at low Mg2+ concentrations (2 mM), which we infer to be on the level of catalytically important Mg2+ recruitment. At 4.5 mM Mg2+, activity of mutant relative to the wild-type holoenzyme, was decreased only about twofold, but 13- to 24-fold at 2 mM Mg2+. Moreover, our findings make it unlikely that the C292/293 phenotypes include significant contributions from defects in protein binding, substrate affinity, or RNA degradation. However, native PAGE experiments revealed nonidentical RNA folding equilibria for the wild-type versus mutant RNase P RNAs, in a buffer- and preincubation-dependent manner. Thus, we cannot exclude that altered folding of the mutant RNAs may have also contributed to their in vivo defect.     

Negative complementation in aspartate transcarbamylase. Analysis of hybrid enzyme molecules containing different arrangements of polypeptide chains from wild-type and inactive mutant catalytic subunits.

A comprehensive set of hybrid molecules of aspartate transcarbamylase (ATCase) from Escherichia coli has been constructed of wild-type and mutationally altered catalytic chains. The mutant enzymes that were virtually devoid of activity contained a replacement of Gly-128 in the catalytic polypeptide chains by either Asp or Arg. The kinetic properties of these hybrid enzyme-like molecules were analyzed to evaluate the basis for the unusual quaternary constraint demonstrated by an intersubunit hybrid containing one wild-type catalytic subunit, one inactive mutant subunit (containing the Gly to Asp replacement), and three wild-type regulatory subunits. A similar intersubunit hybrid was constructed from the wild-type catalytic subunit and the mutant in which Gly-128 was replaced by Arg, and it too demonstrated a pronounced decrease in activity relative to that expected for a hybrid containing three active sites. Moreover, neither of these hybrid holoenzymes exhibited the cooperativity with respect to aspartate that is characteristic of wild-type ATCase. In contrast, hybrid holoenzymes containing at least one wild-type chain in each catalytic subunit showed cooperativity. Also, hybrid enzymes containing different arrangements of five, four, three, or two wild-type catalytic chains with an appropriate complement of mutant chains had specific activities proportional to the number of wild-type chains in the holoenzymes. Exceptions were observed only in hybrids in which one of the two subunits in the holoenzyme was composed completely of mutant catalytic chains. For these hybrids the negative complementation was manifested as a much lower enzyme activity than expected from the number of wild-type chains in the enzyme and the loss of cooperativity. Thus, the activity and allosteric properties of these hybrids is dependent on the arrangement of catalytic chains in the holoenzyme, in contrast to results obtained for hybrids containing native and chemically modified catalytic chains. Intrasubunit hybrid catalytic trimers containing one or two wild-type chains exhibited one-third and two-thirds the activity of the intact wild-type catalytic subunit, respectively, indicating the dominant negative effect that was seen in intersubunit hybrid holoenzymes is absent within trimers.     

Phylogenetic comparative mutational analysis of the base-pairing between RNase P RNA and its substrate.

We have studied the base-pairing between the 3'-terminal CCA motif of a tRNA precursor and RNase P RNA by a phylogenetic mutational comparative approach. Thus, various derivatives of the Escherichia coli tRNA(Ser)Su1 precursor harboring all possible substitutions at either the first or the second C of the 3'-terminal CCA motif were generated. Cleavage site selection on these precursors was studied using mutant variants of M1 RNA, the catalytic subunit of E. coli RNase P, carrying changes at positions 292 or 293, which are involved in the interaction with the 3'-terminal CCA motif. From our data we conclude that these two C's in the substrate interact with the well-conserved G292 and G293 through canonical Watson-Crick base-pairing. Cleavage performed using reconstituted holoenzyme complexes suggests that this interaction also occurs in the presence of the C5 protein. Furthermore, we studied the interaction using various derivatives of RNase P RNAs from Mycoplasma hyopneumoniae and Mycobacterium tuberculosis. Our results suggest that the base-pairing between the 3'-terminal CCA motif and RNase P is present also in other bacterial RNase P-substrate complexes and is not limited to a particular bacterial species.     

Mapping RNA-protein interactions in ribonuclease P from Escherichia coli using electron paramagnetic resonance spectroscopy

Ribonuclease P (RNase P) is a catalytic ribonucleoprotein (RNP) essential for tRNA biosynthesis. In Escherichia coli, this RNP complex is composed of a catalytic RNA subunit, M1 RNA, and a protein cofactor, C5 protein. Using the sulfhydryl-specific reagent (1-oxyl-2,2,5, 5-tetramethyl-Delta3-pyrroline-3-methyl)methanethiosulfonate (MTSL), we have introduced a nitroxide spin label individually at six genetically engineered cysteine residues (i.e., positions 16, 21, 44, 54, 66, and 106) and the native cysteine residue (i.e., position 113) in C5 protein. The spin label covalently attached to any protein is sensitive to structural changes in its microenvironment. Therefore, we expected that if the spin label introduced at a particular position in C5 protein was present at the RNA-protein interface, the electron paramagnetic resonance (EPR) spectrum of the spin label would be altered upon binding of the spin-labeled C5 protein to M1 RNA. The EPR spectra observed with the various MTSL-modified mutant derivatives of C5 protein indicate that the spin label attached to the protein at positions 16, 44, 54, 66, and 113 is immobilized to varying degrees upon addition of M1 RNA but not in the presence of a catalytically inactive, deletion derivative of M1 RNA. In contrast, the spin label attached to position 21 displays an increased mobility upon binding to M1 RNA. The results from this EPR spectroscopy-based approach together with those from earlier studies identify residues in C5 protein which are proximal to M1 RNA in the RNase P holoenzyme complex.     

Characterization of two mutants of the LLC-PK1 porcine kidney cell line affected in the catalytic subunit of the cAMP-dependent protein kinase

The catalytic (C) subunit activity of the cAMP-dependent protein kinase (cAMP-PK) from the mutant cell lines, FIB4 and FIB6, is only 10% compared with the parent cell line, LLC-PK1 [Jans and Hemmings (1986) FEBS Lett. 205, 127-131]. In order to understand the nature of the mutant phenotypes the cAMP-PK from parent and mutant cell lines was studied in more detail. Analysis of mutant cAMP-PK activity by ion-exchange chromatography revealed that kinase activity associated with type I holoenzyme of both FIB4 and FIB6 was only 5% parental, and the activity of the type II holoenzyme was about 20% parental. The type I regulatory (RI) subunits associated with the type I were also found to be reduced by 70-80% in both mutants, whereas the type II R subunit levels were similar to that of the parent. The residual kinase activity associated with the type I holoenzyme from FIB4 and FIB6 could not be activated by cAMP whereas the type II holoenzyme was activated by cAMP (Ka of 5.5 X 10(-8) M), and showed normal affinities for Kemptamide and ATP. A polyclonal antibody to the catalytic subunit was used to quantify the level of this protein in wild-type and mutant cells. This analysis showed that FIB4 and FIB6 had nearly normal levels of C subunit, suggesting that the C subunit synthesized by the mutants was mostly inactive. As both type I and type II cAMP-PK holoenzymes were abnormal, the most likely explanation of the mutant phenotype is a defect either in the structural gene for the C subunit or in an enzyme involved in its posttranslational processing. However, a second lesion affecting the RI subunit cannot be ruled out at this moment.     

Probing the architecture of the B. subtilis RNase P holoenzyme active site by cross-linking and affinity cleavage

Bacterial ribonuclease P (RNase P) is a ribonucleoprotein complex composed of one catalytic RNA (PRNA) and one protein subunit (P protein) that together catalyze the 5' maturation of precursor tRNA. High-resolution X-ray crystal structures of the individual P protein and PRNA components from several species have been determined, and structural models of the RNase P holoenzyme have been proposed. However, holoenzyme models have been limited by a lack of distance constraints between P protein and PRNA in the holoenzyme-substrate complex. Here, we report the results of extensive cross-linking and affinity cleavage experiments using single-cysteine P protein variants derivatized with either azidophenacyl bromide or 5-iodoacetamido-1,10-o-phenanthroline to determine distance constraints and to model the Bacillus subtilis holoenzyme-substrate complex. These data indicate that the evolutionarily conserved RNR motif of P protein is located near (<15 Angstroms) the pre-tRNA cleavage site, the base of the pre-tRNA acceptor stem and helix P4 of PRNA, the putative active site of the enzyme. In addition, the metal binding loop and N-terminal region of the P protein are proximal to the P3 stem-loop of PRNA. Studies using heterologous holoenzymes composed of covalently modified B. subtilis P protein and Escherichia coli M1 RNA indicate that P protein binds similarly to both RNAs. Together, these data indicate that P protein is positioned close to the RNase P active site and may play a role in organizing the RNase P active site.     

Dissecting the domain structure of the regulatory subunit of cAMP-dependent protein kinase I and elucidating the role of MgATP

A truncated regulatory subunit of cAMP-dependent protein kinase I was constructed which contained deletions at both the carboxyl terminus and at the amino terminus. The entire carboxyl-terminal cAMP-binding domain was deleted as well as the first 92 residues up to the hinge region. This monomeric truncated protein still forms a complex with the catalytic subunit, and activation of this complex is mediated by cAMP. The affinity of this mutant holoenzyme for cAMP and its activation by cAMP are nearly identical to holoenzyme formed with a regulatory subunit having only the carboxyl-terminal deletion and very similar to native holoenzyme. The off rate for cAMP from both mutant regulatory subunits, however, is monophasic and very fast relative to the biphasic off rate seen for the native regulatory subunit. The effects of NaCl, urea, and pH on cAMP binding are also very similar for the mutant and native holoenzymes. Like the native type I holoenzyme, both mutant holoenzymes bind ATP with a high affinity. The positive cooperativity seen for MgATP binding to the native holoenzyme, however, is abolished in the double deletion mutant. The Hill coefficient for ATP binding to this mutant holoenzyme is 1.0 in contrast to 1.6 for the native holoenzyme. The Kd (cAMP) is increased by approximately 1 order of magnitude for both mutant forms of the holoenzyme in the presence of MgATP. A similar shift is seen for the native holoenzyme. Further characterization of the MgATP-binding properties of the wild-type holoenzyme indicates that a binary complex containing catalytic subunit and MgATP is required, in particular, for reassociation with the cAMP-bound regulatory subunit. This binary complex is required for rapid dissociation of the bound cAMP and is probably responsible for the observed reduction in cAMP-binding affinity for the type I holoenzyme in the presence of MgATP.     

RNA-dependent folding and stabilization of C5 protein during assembly of the E. coli RNase P holoenzyme

The pre-tRNA processing enzyme ribonuclease P is a ribonucleoprotein. In Escherichia coli assembly of the holoenzyme involves binding of the small (119 amino acid residue) C5 protein to the much larger (377 nucleotide) P RNA subunit. The RNA subunit makes the majority of contacts to the pre-tRNA substrate and contains the active site; however, binding of C5 stabilizes P RNA folding and contributes to high affinity substrate binding. Here, we show that RNase P ribonucleoprotein assembly also influences the folding of C5 protein. Thermal melting studies demonstrate that the free protein population is a mixture of folded and unfolded conformations under conditions where it assembles quantitatively with the RNA subunit. Changes in the intrinsic fluorescence of a unique tryptophan residue located in the folded core of C5 provide further evidence for an RNA-dependent conformational change during RNase P assembly. Comparisons of the CD spectra of the free RNA and protein subunits with that of the holoenzyme provide evidence for changes in P RNA structure in the presence of C5 as indicated by previous studies. Importantly, monitoring the temperature dependence of the CD signal in regions of the holoenzyme spectra that are dominated by protein or RNA structure permitted analysis of the thermal melting of the individual subunits within the ribonucleoprotein. These analyses reveal a significantly higher Tm for C5 when bound to P RNA and show that unfolding of the protein and RNA are coupled. These data provide evidence for a general mechanism in which the favorable free energy for formation of the RNA-protein complex offsets the unfavorable free energy of structural rearrangements in the RNA and protein subunits.     

Functional role of putative critical residues in Mycobacterium tuberculosis RNase P protein

RNase P is involved in processing the 5⿲ end of pre-tRNA molecules. Bacterial RNase P contains a catalytic RNA subunit and a protein subunit. In this study, we have analyzed the residues in RNase P protein of M. tuberculosis that differ from the residues generally conserved in other bacterial RNase Ps. The residues investigated in the current study include the unique residues, Val27, Ala70, Arg72, Ala77, and Asp124, and also Phe23 and Arg93 which have been found to be important in the function of RNase P protein components of other bacteria. The selected residues were individually mutated either to those present in other bacterial RNase P protein components at respective positions or in some cases to alanine. The wild type and mutant M. tuberculosis RNase P proteins were expressed in E. coli, purified, used to reconstitute holoenzymes with wild type RNA component in vitro, and functionally characterized. The Phe23Ala and Arg93Ala mutants showed very poor catalytic activity when reconstituted with the RNA component. The catalytic activity of holoenzyme with Val27Phe, Ala70Lys, Arg72Leu and Arg72Ala was also significantly reduced, whereas with Ala77Phe and Asp124Ser the activity of holoenzyme was similar to that with the wild type protein. Although the mutants did not suffer from any binding defects, Val27Phe, Ala70Lys, Arg72Ala and Asp124Ser were less tolerant towards higher temperatures as compared to the wild type protein. The K_m of Val27Phe, Ala70Lys, Arg72Ala and Ala77Phe were >2-fold higher than that of the wild type, indicating the substituted residues to be involved in substrate interaction. The study demonstrates that residues Phe23, Val27 and Ala70 are involved in substrate interaction, while Arg72 and Arg93 interact with other residues within the protein to provide it a functional conformation.     

Molecular modeling of the three-dimensional structure of the bacterial RNase P holoenzyme

Bacterial ribonuclease P (RNase P), an enzyme involved in tRNA maturation, consists of a catalytic RNA subunit and a protein cofactor. Comparative phylogenetic analysis and molecular modeling have been employed to derive secondary and tertiary structure models of the RNA subunits from Escherichia coli (type A) and Bacillus subtilis (type B) RNase P. The tertiary structure of the protein subunit of B.subtilis and Staphylococcus aureus RNase P has recently been determined. However, an understanding of the structure of the RNase P holoenzyme (i.e. the ribonucleoprotein complex) is lacking. We have now used an EDTA-Fe-based footprinting approach to generate information about RNA-protein contact sites in E.coli RNase P. The footprinting data, together with results from other biochemical and biophysical studies, have furnished distance constraints, which in turn have enabled us to build three-dimensional models of both type A and B versions of the bacterial RNase P holoenzyme in the absence and presence of its precursor tRNA substrate. These models are consistent with results from previous studies and provide both structural and mechanistic insights into the functioning of this unique catalytic RNP complex.     

The recognition by RNase P of precursor tRNAs

We have generated mutants of M1 RNA, the catalytic subunit of Escherichia coli RNaseP, and have analyzed their properties in vitro and in vivo. The mutations, A333----C333, A334----U334, and A333 A334----C333 U334 are within the sequence UGAAU which is complementary to the GT psi CR sequence found in loop IV of all E. coli tRNAs. We have examined: 1) whether the mutant M1 RNAs are active in processing wild type tRNA precursors and 2) whether they can restore the processing defect in mutant tRNA precursors with changes within the GT psi CR sequence. As substrates for in vitro studies we used wild type E. coli SuIII tRNA(Tyr) precursor, and pTyrA54, a mutant tRNA precursor with a base change that could potentially complement the U334 mutation in M1 RNA. The C333 mutation had no effect on activity of M1 RNA on wild type pTyr. The U334 mutant M1 RNA, on the other hand, had a much lower activity on wild type pTyr. However, use of pTyrA54 as substrate instead of wild type pTyr did not restore the activity of the U334 mutant M1 RNA. These results suggest that interactions via base pairing between nucleotides 331-335 of M1 RNA and the GT psi CG of pTyr are probably not essential for cleavage of these tRNA precursors by M1 RNA. For assays of in vivo function, we examined the ability of mutant M1 RNAs to complement a ts mutation in the protein component of RNaseP in FS101, a recA- derivative of E. coli strain A49. In contrast to wild type M1 RNA, which complements the ts mutation when it is overproduced, neither the C333 nor the U334 mutant M1 RNAs was able to do so.     

RNase P from bacteria. Substrate recognition and function of the protein subunit

RNase P recognizes many different precursor tRNAs as well as other substrates and cleaves all of them accurately at the expected position. RNase P recognizes the tRNA structure of the precursor tRNA by a set of interactions between the catalytic RNA subunit and the T- and acceptor-stems mainly, although residues in the 5-leader sequence as well as the 3-terminal CCA are important. These conclusions have been reached by several studies on mutant precursor tRNAs as well as cross-linking studies between RNase P RNA and precursor tRNAs. The protein subunit of RNase P seems also to affect the way that the substrate is recognized as well as the range of substrates that can be used by RNase P, although the protein does not seem to interact directly with the substrates. The interaction between the protein and RNA subunits of RNase P has been extensively studiedin vitro. The protein subunit sequence is not highly conserved among bacteria, however different proteins are functionally equivalent as heterologous reconstitution of the RNase P holoenzyme can be achieved in many cases.Abbreviations C5 protein protein subunit fromE. coli RNase P - EGS external guide sequence - M1 RNA RNA subunit formE. coli RNase P - ptRNA precursor tRNA - RNase P ribonuclease P     

The S49 Kin- cell line transcribes and translates a functional mRNA coding for the catalytic subunit of cAMP-dependent protein kinase

The S49 mouse lymphoma mutant cell line Kin- is resistant to the cytotoxic effects of elevated cAMP levels, has no detectable cAMP-dependent protein kinase activity, and has depressed levels of cAMP-binding regulatory subunits. We demonstrate that although the Kin- cell line lacks detectable catalytic subunit protein, these cells express wild-type levels of mRNA for both C alpha and C beta catalytic subunit isoforms. Translation of C alpha mRNA appears to be normal in the Kin- cell, based on the observation that C alpha mRNA associates with large polyribosomes in both wild-type and Kin- cells. We cloned the C alpha cDNA from Kin- cells and show that its transient expression in another cell type leads to activation of a cAMP-sensitive luciferase reporter gene, suggesting that functional C alpha protein is made. In addition to having catalytic activity, the C alpha subunit from Kin- cells is inhibited in the presence of mouse RI alpha regulatory subunit, indicating that formation of the holoenzyme complex is normal. We suggest that the mutation responsible for the Kin- phenotype is in a cellular component that directly or indirectly causes Kin- catalytic subunit protein to be degraded rapidly.     

Kinetics of the processing of the precursor to 4.5 S RNA, a naturally occurring substrate for RNase P from Escherichia coli.

A study was made of the cleavage by M1 RNA and RNase P of a non-tRNA precursor that can serve as a substrate for RNase P from Escherichia coli, namely, the precursor to 4.5 S RNA (p4.5S). The overall efficiency of cleavage of p4.5S by RNase P is similar to that of wild-type tRNA precursors. However, unlike the reaction with wild-type tRNA precursors, the reaction catalyzed by the holoenzyme with p4.5S as substrate has a much lower Km value than that catalyzed by M1 RNA with the same substrate, indicating that the protein subunit plays a crucial role in the recognition of p4.5S. A model hairpin substrate, based on the sequence of p4.5S, is cleaved with greater efficiency than the parent molecule. The 3'-terminal CCC sequence of p4.5 S may be as important for cleavage of this substrate as the 3'-terminal CCA sequence is for cleavage of tRNA precursors.     

Functional characterization of the conserved amino acids in Pop1p, the largest common protein subunit of yeast RNases P and MRP

RNase P and RNase MRP are ribonucleoprotein enzymes required for 5'-end maturation of precursor tRNAs (pre-tRNAs) and processing of precursor ribosomal RNAs, respectively. In yeast, RNase P and MRP holoenzymes have eight protein subunits in common, with Pop1p being the largest at >100 kDa. Little is known about the functions of Pop1p, beyond the fact that it binds specifically to the RNase P RNA subunit, RPR1 RNA. In this study, we refined the previous Pop1 phylogenetic sequence alignment and found four conserved regions. Highly conserved amino acids in yeast Pop1p were mutagenized by randomization and conditionally defective mutations were obtained. Effects of the Pop1p mutations on pre-tRNA processing, pre-rRNA processing, and stability of the RNA subunits of RNase P and MRP were examined. In most cases, functional defects in RNase P and RNase MRP in vivo were consistent with assembly defects of the holoenzymes, although moderate kinetic defects in RNase P were also observed. Most mutations affected both pre-tRNA and pre-rRNA processing, but a few mutations preferentially interfered with only RNase P or only RNase MRP. In addition, one temperature-sensitive mutation had no effect on either tRNA or rRNA processing, consistent with an additional role for RNase P, RNase MRP, or Pop1p in some other form. This study shows that the Pop1p subunit plays multiple roles in the assembly and function of of RNases P and MRP, and that the functions can be differentiated through the mutations in conserved residues.