The removal of N-terminal translation initiator Met by methionine aminopeptidase (MetAP) is often crucial for the function and stability of proteins. On the basis of crystal structure and sequence alignment of MetAPs, we have engineered Escherichia coli MetAP by the mutation of three residues, Y168G, M206T, Q233G, in the substrate-binding pocket. Our engineered MetAPs are able to remove the Met from bulky or acidic penultimate residues, such as Met, His, Asp, Asn, Glu, Gln, Leu, Ile, Tyr, and Trp, as well as from small residues. The penultimate residue, the second residue after Met, was further removed if the antepenultimate residue, the third residue after Met, was small. By the coexpression of engineered MetAP in E. coli through the same or a separate vector, we have successfully produced recombinant proteins possessing an innate N terminus, such as onconase, an antitumor ribonuclease from the frog Rana pipiens. The N-terminal pyroglutamate of recombinant onconase is critical for its structural integrity, catalytic activity, and cytotoxicity. On the basis of N-terminal sequence information in the protein database, 85%-90% of recombinant proteins should be produced in authentic form by our engineered MetAPs.
Ribonucleases with antitumor activity are mainly found in the oocytes and embryos of frogs, but the role of these ribonucleases in frog development is not clear. Moreover, most frog ribonuclease genes have not been cloned and characterized. In the present study, a group of ribonucleases were isolated from Rana catesbeiana (bullfrog). These ribonucleases in mature oocytes, namely RC-RNase, RC-RNase 2, RC-RNase 3, RC-RNase 4, RC-RNase 5 and RC-RNase 6, as well as liver-specific ribonuclease RC-RNase L1, were purified by column chromatographs and detected by zymogram assay and western blotting. Characterization of these purified ribonucleases revealed that they were highly conserved in amino acid sequence and had a pyroglutamate residue at their N-termini, but possessed different specific activities, base specificities and optimal pH values for their activities. These ribonucleases were cytotoxic to cervical carcinoma HeLa cells, but their cytotoxicities were not closely correlated to their enzymatic specific activities. Some other amino acid residues in addition to their catalytic residues were implicated to be involved in the cytotoxicity of the frog ribonucleases to tumor cells. Because the coding regions lack introns, the ribonuclease genes were cloned by PCR using genomic DNA as template. Their DNA sequences and amino acid sequences are homologous to those of mammalian ribonuclease superfamily, approximately 50 and approximately 25%, respectively.
The Rana catesbeiana (bullfrog) ribonucleases, which belong to the RNase A superfamily, exert cytotoxicity toward tumor cells. RC-RNase, the most active among frog ribonucleases, has a unique base preference for pyrimidine-guanine rather than pyrimidine-adenine in RNase A. Residues of RC-RNase involved in base specificity and catalytic activity were determined by sitedirected mutagenesis, k cat /K m analysis toward dinucleotides, and cleavage site analysis of RNA substrate. The results show that Pyr-1 (N-terminal pyroglutamate), Lys-9, and Asn-38 along with His-10, Lys-35, and His-103 are involved in catalytic activity, whereas Pyr-1, Thr-39, Thr-70, Lys-95, and Glu-97 are involved in base specificity. The cytotoxicity of RC-RNase is correlated, but not proportional to, its catalytic activity. The crystal structure of the RC-RNase⅐d(ACGA) complex was determined at 1.80 Å resolution. Residues Lys-9, His-10, Lys-35, and His-103 interacted directly with catalytic phosphate at the P 1 site, and Lys-9 was stabilized by hydrogen bonds contributed by Pyr-1, Tyr-28, and Asn-38. Thr-70 acts as a hydrogen bond donor for cytosine through Thr-39 and determines B 1 base specificity. Interestingly, Pyr-1 along with Lys-95 and Glu-97 form four hydrogen bonds with guanine at B 2 site and determine B 2 base specificity.Ribonucleases are found widely within living organisms and are thought to play an important role in the metabolism of RNA. Recently, it has been shown that several members of the bovine ribonuclease superfamily exhibit biological functions in addition to intrinsic ribonucleolytic activities. Human eosinophil-derived neurotoxin and eosinophil cationic protein exert neurotoxicity (1) as well as antiparasitic activity (2), human angiogenin induces blood vessel formation (3), and frog ribonuclease exhibits antitumor activity (4, 5). Ribonucleolytic activity is essential for the biological functions of these proteins (6 -12).Bovine pancreatic ribonuclease, known as RNase A, in the ribonuclease superfamily is well characterized and is a valuable model for the study of structure-function relationships and protein refolding (13,14). It consists of 124 amino acid residues linked with four pairs of disulfide bridges and possesses a substrate preference for pyrimidine-adenosine in the RNA sequence but no cytotoxicity toward tumor cells. There are three subsites within RNase A molecule: the P 1 site, at which phosphodiester bond cleavage occurs; the B 1 site, for binding pyrimidine, which donates oxygen via its ribose to the scissile bond; and the B 2 site, for binding the adenine ring on the opposite site of the scissile bond. Three amino acid residues, His-12, Lys-41, and His-119, at the P 1 site are involved in catalytic activity. Four amino acid residues, Thr-45, Asp-83, Phe-120, and Ser-123, at the B 1 site are involved in the binding of the 5Ј-ribonucleoside, pyrimidine, whereas two residues, Asn-71 and Glu-111, at the B 2 site are involved in the binding of the 3Ј-ribonucleoside, adenosine (14 -18).A new group of ribon...
Onconase, a cytotoxic ribonuclease from Rana pipiens, possesses pyroglutamate (Pyr) at the N-terminus and has a substrate preference for uridine-guanine (UG). To identify residues responsible for onconase's cytotoxicity, we cloned the rpr gene from genomic DNA and expressed it in Escherichia coli BL21(DE3). The recombinant onconase with Met at the N-terminus had reduced thermostability, catalytic activity and antigenicity. Therefore, we developed two methods to produce onconase without Met. One relied on the endogeneous E.coli methionine aminopeptidase and the other relied on the cleavage of a pelB signal peptide. The Pyr1 substitutional variants maintained similar secondary structures to wild-type onconase, but with less thermostability and specific catalytic activity for the innate substrate UG. However, the non-specific catalytic activity for total RNAs varied depending on the relaxation of base specificity. Pyr1 promoted the structural integrity by forming a hydrogen bond network through Lys9 in alpha1 and Val96 in beta6, and participated in catalytic activity by hydrogen bonds to Lys9 and P(1) catalytic phosphate. Residues Thr35 and Asp67 determined B(1) base specificity, and Glu91 determined B(2) base specificity. The cytotoxicity of onconase is largely determined by structural integrity and specific catalytic activity for UG through Pyr1, rather than non-specific activity for total RNAs.
Rana catesbeiana ribonuclease (RC-RNase) is a pyrimidine-guanine sequence-specific ribonuclease found in R. catesbeiana (bullfrog) oocytes. It possesses both ribonuclease activity and cytotoxicity against tumor cells. We report here for the first time the cloning of RC-RNase cDNA from liver rather than from oocytes where RC-RNase is stored. An internal fragment of cDNA was obtained by reverse transcription-PCR using deduced oligonucleotides as primers. Full-length cDNA was obtained by 5-and 3-RACE technique. The cDNA clone, named rcr gene, contained a 5-untranslated region, a putative signal peptide (22 amino acids), a mature protein (111 amino acids), a 3-untranslated region, and a polyadenylation site. The cDNA which encoded the mature protein was fused upstream with a modified pelB signal peptide DNA and inserted into pET11d for expression in Escherichia coli strain BL21(DE3). The secretory RC-RNase in the culture medium was enzymatically active and was purified to homogeneity. The recombinant RC-RNase had the same amino acid sequence, specific activity, substrate specificity, antigenicity, and cytotoxicity as that of native RC-RNase from frog oocytes. Amino acid residues His-10, Lys-35, and His-103 are involved in RC-RNase catalytic activity. Ribonucleolytic activity was involved in and may be essential for RC-RNase cytotoxicity. DNA sequence analysis showed that RC-RNase had approximately 45% identity to that of RNase superfamily genes. This indicates that RC-RNase is a distinct ribonuclease gene in the RNase superfamily.
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