Evidence for an RNA binding region in the Escherichia coli processing endoribonuclease RNase E

The processing endoribonuclease RNase E (Rne), which is encoded by the rne gene, is involved in the maturation process of messenger RNAs and a ribosomal RNA. A number of deletions were constructed in order to assess functional domains of the rne gene product. The expression of the deletion constructs using a T7 promoter/RNA polymerase overproduction system led to the synthesis of truncated Rne polypeptides. The smallest gene fragment in this collection that was able to complement a temperature sensitive rnets mutation and to restore the processing of 9 S RNA was a 2.3-kilobase pair fragment with a 1.9-kilobase pair N-terminal coding sequence that mediated synthesis of a 70.8-kDa polypeptide. Antibodies raised against a truncated 110-kDa polypeptide cross-reacted with the intact rne gene product and with all of the shorter C-terminal truncated polypeptides, indicating that the N-terminal part of the molecule contained strong antigenic determinants. Furthermore, by analyzing the Rne protein and the truncated polypeptides for their ability to bind substrate RNAs, we were able to demonstrate that the central part of the Rne molecule encodes an RNA binding region. Binding to substrate RNAs correlated with the endonucleolytic activity. RNAs that are not substrates for RNase E did not bind to the protein. The two mutated Rne polypeptides expressed from the cloned gene containing either the rne-3071 or ams1 mutation also had the ability to bind 9 S RNA, while their enzymatic function was completely abolished. The data presented here suggest that the endonucleolytic activity is encoded by the N-terminal part of the Rne protein molecule and that the central part of it possesses RNA binding activity.     

Study on site specific cleavage of RNA

The precursor of an RNA molecule from bacteriophage T4 infected Escherichia coli cell (p2Sp1 RNA) has the ability to cleave itself. It has been found that the site specific RNA cleavage reaction occurred at the pyridine-adenosine sequence in the presence of a monovalent cation and a non-ionic detergent. In order to investigate the mechanism of this cleavage reaction, we designed a RNA oligonucleotide (UUUAUU) and this RNA was cleavage activity at the U-A sequence.     

SnoRNAs as tools for RNA cleavage and modification

Eukaryotic small nucleolar RNAs (snoRNAs) influence rRNA synthesis at two stages: nucleolytic processing and selection of nucleotides to be ribose methylated (Nm) or converted to pseudouridine (psi). The two modification functions and some processing activities involve direct base pairing of snoRNA with rRNA. In addition to rRNA-targeting sequences, snoRNA function depends on the presence of conserved box elements involved in snoRNA synthesis and localization. The present investigation is directed at using snoRNAs as tools for two purposes: 1) introducing nucleotide modifications into novel sites in rRNA and other snoRNAs, and: 2) targeting nucleolar RNAs for destruction using snoRNA:ribozyme chimers ('snorbozymes'). Early results demonstrate that snoRNAs can be used for both applications.     

Monitoring retroviral RNA dimerization in vivo via hammerhead ribozyme cleavage

We have used a strategy for colocalization of Psi (Psi)-tethered ribozymes and targets to demonstrate that Psi sequences are capable of specific interaction in the cytoplasm of both packaging and nonpackaging cells. These results indicate that current in vitro dimerization models may have in vivo counterparts. The methodology used may be applied to further genetic analyses on Psi domain interactions in vivo.     

Preferential binding of yeast Rad4.Rad23 complex to damaged DNA

The yeast Rad4 and Rad23 proteins form a complex that is involved in nucleotide excision repair (NER). Their function in this process is not known yet, but genetic data suggest that they act in an early step in NER. We have purified an epitope-tagged Rad4.Rad23 (tRad4. Rad23) complex from yeast cells, using a clone overproducing Rad4 with a hemagglutinin-tag at its C terminus. tRad4.Rad23 complex purified by both conventional and immuno-affinity chromatography complements the in vitro repair defect of rad4 and rad23 mutant extracts, demonstrating that these proteins are functional in NER. Using electrophoretic mobility shift assays, we show preferential binding of the tRad4.Rad23 complex to damaged DNA in vitro. UV-irradiated, as well as N-acetoxy-2-(acetylamino)fluorene-treated DNA, is efficiently bound by the protein complex. These data suggest that Rad4.Rad23 interacts with DNA damage during NER and may play a role in recognition of the damage.     

Towards artificial ribonucleases: the sequence-specific cleavage of RNA in a duplex

Lanthanide complexes covalently attached to oligonucleotides have been shown to cleave RNA in a sequence-specific manner. Efficient cleavage, however, is at present limited to single-stranded RNA regions, as RNA in a duplex is considerably more resistant to strand scission. To overcome this limitation, we have designed and synthesised artificial nucleases comprising lanthanide complexes covalently linked to oligodeoxyribonucleotides which cleave a partially complementary RNA at a bulged site, in the duplex region. Strand scission occurs at or near the bulge. Cleavage of the RNA target by the metal complex can be addressed via the major or the minor groove. In an example of a competitive situation, where the cleavage moiety has access to both a bulge and a single-strand region, transesterification at the bulge is favoured. Such artificial ribonucleases may find application as antisense agents and as tools in molecular biology. In addition, the results may have importance for the design of artificial ribonucleases which are able to act with catalytic turnover.     

Phenotype-dependent differences in proteasome subunit composition and cleavage specificity in B cell lines

We have compared the subunit composition and enzymatic activity of purified 26S proteasomes from Burkitt's lymphoma (BL) cells and in vitro EBV-transformed lymphoblastoid cell lines (LCLs) of normal B cell origin. Low expression of the IFN-gamma-regulated beta low molecular mass polypeptide (Lmp)2, Lmp7, and MECL-1 was demonstrated in a panel of seven BL lines that express the germinal center cell phenotype of the original tumor. Coexpression of Lmp2 and Lmp7 with the constitutively expressed subunits delta and MB1 was demonstrated in the BL lines by immunoprecipitation and two-dimensional gel fractionation of the 20S proteasomes. Coexpression of these subunits correlated with reduced levels of chymotrypsin- and trypsin-like activities detected by the cleavage of fluorogenic substrates. Down-regulation of Lmp2 and Lmp7 and decreased chymotrypsin- and trypsin-like activities were also observed in purified proteasomes from a c-myc-transfected subline of the ER/EB2-5 LCL that has adopted a BL-like phenotype. A synthetic peptide analogue of the immunodominant epitope from the EBV nuclear Ag 4 (E4416-424Y) was cleaved by proteasomes from BLs and A1, while proteasomes from LCLs were inactive. Cleavage of the E4416-424Y peptide was not affected by treatment of the BL cells with IFN-gamma despite both significant up-regulation of Lmp2 and Lmp7 and reconstitution of chymotrypsin and trypsin-like activities against fluorogenic substrates to LCL-like levels. The results demonstrate that B cell lines representing different stages of B cell activation and differentiation express proteasomes with different subunit compositions and enzymatic activity. This may result in the generation of a distinct set of endogenous peptides and influence the immunogenicity of these cells.     

Binding of anti-CD23 monoclonal antibody to the leucine zipper motif of FcepsilonRII/CD23 on B cell membrane promotes its proteolytic cleavage. Evidence for an effect on the oligomer/monomer equilibrium

In the present study we have compared the binding of two monoclonal antibodies to CD23, EBVCS1 and mAb25, which recognize the stalk and the lectin domain, respectively, on the CD23 molecule. At 4 degreesC, EBVCS1 binds to about 10% of the receptors recognized by mAb25 on the B cell surface. At 37 degreesC, whereas mAb25 reaches its maximal binding within a few seconds, EBVCS1 requires 60 min to bind to the same extent. Stabilization of the oligomeric structure of CD23 with IgE strongly affects in a dose-dependent fashion the number of binding sites seen by EBVCS1 but not the t1/2 to reach them, suggesting that EBVCS1 binds to the coiled coil region through an allosteric mechanism. EBVCS1 rapidly down-modulates the membrane CD23 expression with a coincident increase of CD23-soluble fragments in the culture medium, an effect that is inhibited by IgE. In contrast, mAb25, as well as IgE, protects CD23 from proteolytic cleavage and stimulates its endocytosis. These results suggest that EBVCS1 unravels the coiled coil structure of CD23, rendering it more susceptible to proteolytic attack. This supports the oligomeric model proposed previously (Gould, H., Sutton, B., Edmeades, R., and Beavil, A. (1991) Monogr. Allergy 29, 28-49). The biological significance of these observations is discussed.     

Ribonuclease P substrate specificity: cleavage of a bacteriophage phi80-induced RNA

RNase P can cleave in vitro a bacteriophage phi80-induced RNA which is 62 nucleotides long [M3 RNA, G. Pieczenik et al. (1972) Arch. Biochem. Biophys. 152, 152-165] to yield two specific fragments 25 and 37 nucleotides long. As is the case for another substrate of RNase P; the precursor to Escherichia coli 4.5S RNA, the cleavage site in M3 RNA is at the end of a long double-stranded region immediately adjacent to a single-stranded segment. Similar nucleotide sequences span the cleavage site in both substrates. These and other features of the reaction of RNase P with M3 and 4.5S precursor RNA are different from some aspects of the reaction of this enzyme with tRNA precursor molecules. A qualitative scheme is presented that is directed towards the understanding of the differences in RNase P cleavage site specificity for these substrates.     

Expression of influenza B virus hemagglutinin containing multibasic residue cleavage sites

The hemagglutinin (HA) protein of influenza B virus contains a single arginine residue at its cleavage site and the HA0 precursor is not cleaved to the HA1 and HA2 subunits by tissue culture cell-associated proteases. To investigate if an HA protein could be obtained that could be cleaved by an endogenous cellular protease, the cDNA for HA of influenza B/MD/59 virus was subjected to site-specific mutagenesis. Three HA mutant proteins were constructed, through substitution or insertion of arginine residues, that have 4, 5, or 6 basic residues at their cleavage sites. Chemical cross-linking studies indicated that all three HA cleavage site mutants could oligomerize to a trimeric species, like WT HA. The three HA cleavage site mutant proteins were efficiently transported to the cell surface and bound erythrocytes in hemadsorption assays. The mutants were cleaved at a low level to HA1 and HA2 by an endogenous host cell protease and cleavage could be increased somewhat by addition of exogenous trypsin. The fusogenic activities of the HA cleavage site mutants were assessed in comparison to the WT HA protein by determining their syncytium formation ability and by using an R18 lipid-mixing assay and a NBD-taurine aqueous-content mixing assay. While the fusion activity of the WT HA protein was dependent on exogenous trypsin to activate HA, the three HA cleavage site mutant proteins were able to induce fusion in the absence of trypsin when assayed with the R18 lipid-mixing and NBD-taurine aqueous-content mixing assays, but were unable to induce syncytium formation in either the presence or absence of exogenous trypsin. Our results suggest that while the presence of a subtilisin-like protease cleavage sequence at the influenza B virus HA1/HA2 boundary does enable some HA0 molecules to be cleaved intracellularly, it alone is not sufficient for efficient cleavage.     

Expanded versions of the 16S and 23S ribosomal RNA mutation databases (16SMDBexp and 23SMDBexp)

The technique of homograft aortic root replacement in our practice has evolved as our experience has increased. This technique is described and illustrated. In most cases, aortic annuli are reduced by using various suture techniques to match the homograft. This allows for a successful implantation of a normal-sized aortic homograft root in a patient with a diseased aortic valve and annular dilatation.     

Effects of secondary structure on DNA and RNA cleavage by diplatinum(II)

The photochemistry of Pt2(pop)44- with nucleic acids has been studied using radiolabeled oligomers of DNA and RNA and high-resolution electrophoresis (pop is P2O5H22-). Photolysis of Pt2(pop)44- with duplex DNA produces an even cleavage ladder and relatively little enhancement of cleavage upon treatment with piperidine. In contrast, the cleavage pattern is far less regular with single-stranded DNA, and there is a large enhancement in cleavage upon treatment with piperidine. Accordingly, photolysis of Pt2(pop)44- with the DNA hairpin 5'-d[ATCCTATTTATAGGAT] produces a much larger piperidine enhancement at the loop and end nucleotides than in the stem. There is an additional piperidine enhancement that occurs selectively at guanine residues either in RNA or in DNA at low Mg2+ concentrations that is attributed to outer-sphere electron transfer on the basis of the known excited-state redox potentials of Pt2(pop)44- and the expected oxidative chemistry of guanine. The extent of guanine oxidation is higher compared to the extent of sugar oxidation at low Mg2+ concentrations, which can be attributed to a shallower distance dependence for electron transfer compared to that for atom transfer. The effects of Mg2+ and piperidine or aniline treatment were examined on stem-loop structures of DNA and RNA and gave partial images of the expected secondary structures.     

Ionic requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme

Metal ion requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme have been analyzed. RNA cleavage is observed when Mg2+, Sr2+, or Ca2+ are added to a 40 mM Tris-HCl buffer, indicating that these divalent cations were capable of supporting the reaction. No reaction was observed when other ions (Mn2+, Co2+, Cd2+, Ni2+, Ba2+, Na+, K+, Li+, NH4+, Rb+, and Cs+) were tested. In the absence of added metal ions, spermidine can induce a very slow ribozyme-catalyzed cleavage reaction that is not quenched by chelating agents (EDTA and EGTA) that are capable of quenching the metal-dependent reaction. Addition of Mn2+ to a reaction containing 2 mM spermidine increases the rate of the catalytic step by at least 100-fold. Spermidine also reduces the magnesium requirement for the reaction and strongly stimulates activity at limiting Mg2+ concentrations. There are no special ionic requirements for formation of the initial ribozyme-substrate complex--analysis of complex formation using native gels and kinetic assays shows that the ribozyme can bind substrate in 40 mM Tris-HCl buffer. Complex formation is inhibited by both Mn2+ and Co2+. Ionic requirements for the ribozyme-catalyzed ligation reaction are very similar to those for the cleavage reaction. We propose a model for catalysis by the hairpin ribozyme that is consistent with these findings. Formation of an initial ribozyme-substrate complex occurs without the obligatory involvement of divalent cations. Ions (e.g., Mg2+) can then bind to form a catalytically proficient complex, which reacts and dissociates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reconstitution of peptide bond formation with Escherichia coli 23S ribosomal RNA domains

It was recently demonstrated that peptide bond formation can occur using an Escherichia coli naked 23S ribosomal RNA without any of the ribosomal proteins. Here, the six domains of the 23S ribosomal RNA were individually synthesized and shown to be capable, when complexed together, of stimulating the reaction. Omission and addition experiments indicated that the activity could be reconstituted solely by domain V at a concentration 10 times higher than that of the intact 23S ribosomal RNA, whereas domain VI could enhance the activity in trans. These findings suggest that fragments of an RNA molecule have the ability to associate into a functional whole.