[Significance of clinical examination concerning arteriosclerosis]

According to the number of deaths by major cause, Malignant neoplasma takes the first rank as the cause of death and then heart disease as a second and next rank to cerebrovascular disease since 1985, instead of top rank of cerebrovascular by that time. However, heart disease and cerebrovascular could be supposed as a arteriosclerosis disease fundamentally, arteriosclerosis disease (heart disease plus cerebrovascular) is usually top of rank in the cause of death since the Showa era. Therefore, it is great significance to make studies of risk factor on the arteriosclerosis in the laboratory medicine.

Molecular characterization of a human group A rotavirus isolated from an adult with severe dehydrating diarrhea and its relationship to strains concurrently circulating among children

BACKGROUND

While group A rotavirus is widely accepted as an important etiology of acute gastroenteritis in children, this agent rarely causes severe diarrhea in adults and, thus, is not considered by physicians to be an etiological agent for such diseases.

OBJECTIVES

None of the reports describing such rare cases in adults has examined the causative strains genetically in detail.

STUDY DESIGN

We determined the G type, the gene 4 genotype, the electropherotype, and the genomic RNA constellation (genogroup) of a group A rotavirus strain isolated from an adult with severe diarrhea. This patient, the first documented case of rotavirus diarrhea in adult in Japan, suffered from severe dehydrating diarrhea with 'rice-water' appearance, vomiting and little abdominal pain, presenting a clinical picture typical of cholera.

RESULTS

Rotavirus antigen and genomic RNA were detected in the stool but other enteric pathogens including Vibrio cholerae responsible for the disease were not isolated. Molecular characterization revealed that the patient was infected with a strain of the DS-1 genogroup with G2 and gene 4 genotype 4 which was circulating among children during the same period.

CONCLUSIONS

The result that the same group A rotavirus strain was isolated from children and an adult underlines the necessity of examining rotavirus in adults with acute diarrhea.

Direct expression of a synthetic gene in Escherichia coli: purification and physicochemical properties of human initiation factor 4E

An artificial synthetic gene coding for human eIF-4E was cloned into an expression vector and direct expression was attempted in Escherichia coli [BL21(DE3) strain] under the control of T7 promoter. The active gene product which was induced in high yield (ca. 4 mg/100 ml) by isopropyl-beta-D-thiogalactopyranoside was purified to homogeneity by a two-step chromatographic procedure with a good yield (ca. 74%), and was confirmed to be recombinant human eIF-4E by amino acid composition and sequence analyses, isoelectric focusing, and absorption spectral measurements. The identity of three-dimensional structures between the recombinant and native human eIF-4Es was confirmed by CD and fluorescence measurements.

Structures of heat-stable and unstable homologues of the sweet protein mabinlin. The difference in the heat stability is due to replacement of a single amino acid residue

There are several analogues of the sweet protein mabinlin. In previous studies, we purified the heat-stable analogue, mabinlin II, from the seeds of Capparis masaikai Lévl. and determined its amino acid sequence [Liu, X., Maeda, S., Hu, Z., Aiuchi, T., Nakaya, K. & Kurihara, Y. (1993) Eur. J. Biochem. 211, 281-287] and the disulfide structure [Nirasawa, S., Liu, X., Nishino, T. & Kurihara, Y. (1993) Biochim. Biophys. Acta 1202, 277-280]. We have now purified four additional homologues of mabinlin. The sweet activities of mabinlin III and mabinlin IV were unchanged by incubation for 1 h at 80 degrees C, as was found previously for mabinlin II, while the sweet activity of mabinlin I-1 was completely abolished by a 1-h incubation at 80 degrees C. The circular dichroic spectrum showed that alpha-helical structures of mabinlins II-IV were unchanged by the 1-h incubation at 80 degrees C, while the alpha-helical structures of mabinlin I-1 were completely destroyed by the 1-h incubation in parallel with the decrease of the sweet activity. To compare the structures of the heat-stable and unstable homologues, we determined their amino acid sequences and the disulfide array. The positions of four disulfide bridges of mabinlin I-1 were the same as those of mabinlin II, suggesting that the disulfide bridges do not contribute to the difference in the heat stability among the homologues. There was a high similarity among amino acid sequences of the homologoues. Only three amino acid residues (A-chain residues at positions 22 and 32 and B-chain residue at position 47) were different between mabinlin I-1 and mabinlin III. A-chain residue at position 32 was lacking in mabinlin IV and the A-chain residue at position 22 was identical in both mabinlin I-1 and mabinlin II. The B-chain residue at position 47 was the only residue present in all three heat-stable homologues (mabinlins II-IV) and is not present in the unstable homologue (mabinlin I-1). This suggests that the difference in the heat stability of mabinlin is due to the difference in a B-chain residue at position 47; the difference in the heat-stable homologues is due to the presence of an arginine residue and the difference of the unstable homologue is due to the presence of glutamine.(ABSTRACT TRUNCATED AT 400 WORDS)

Genetic analysis of equine rotavirus by RNA-RNA hybridization

Serotype G3 equine rotaviruses isolated in Japan made up a common genogroup and were classified into two different genotypes. The genomes of serotype G3 equine rotaviruses with an identical electropherotype (isolated from 1982 to 1989) were very closely related to each other regardless of the year in which they were isolated. Serotype G3 equine rotavirus BI originating from England belonged to the same genogroup of serotype G3 equine rotaviruses isolated in Japan, although BI was classified as having a different genotype. The genomes of both serotype G10 equine rotavirus R-22 and serotype G10 calf rotavirus were closely related to each other.

Formation of sheared G:A base pairs in an RNA duplex modelled after ribozymes, as revealed by NMR

The thermal stability and structure of an RNA duplex, r(GGACGAGUCC)2, the base sequence of which was modelled after both a hammerhead ribozyme and a lead ribozyme, were studied by CD and NMR. We previously demonstrated that the corresponding DNA duplex, d(GGACGAGTCC)2, formed unique 'sheared' G:A base pairs, where an amino proton, instead of an imino proton, of G is involved in the hydrogen bonding, and G and A bases are arranged 'side by side' instead of 'head to head' (Nucleic Acids Res. (1993) 21, 5418-5424). CD melting profiles showed that the RNA duplex is thermally more stable than the corresponding DNA duplex. NMR studies revealed that sheared G:A base pairs are formed in the RNA duplex, too, although the overall structure of the RNA is the A form, which differs from the B form taken on by the corresponding DNA. A model building study confirmed that sheared G:A base pairs can be accommodated in the double helical structure of the A form. A difference between the RNA and DNA duplexes in the stacking interaction involving G:A mismatch bases is also suggested. The demonstration that sheared G:A base pairs can be formed not only in DNA but also in RNA suggests that this base pairing plays an important role regarding the RNA structure.

[Molecular diagnosis of infectious diseases]

Application of techniques originally developed for the analyses of nucleic acids to the diagnosis and characterization of infectious diseases is increasingly practiced. This tendency has been intensified after the introduction of the polymerase chain reaction (PCR). With the PCR, the molecular diagnostic assays have achieved a high sensitivity that parallels and often exceeds the sensitivity of various culture methods. This means that we are entering a new era in which a new gold standard is to be established. In this review, we summarized the basic principle of molecular diagnostic methods, presented, as an example, the application of such techniques to the study of rotaviruses, the single most important etiological agent of acute diarrhea in children, and finally discussed briefly possible future trends of molecular diagnostics for infectious diseases at large.

Crystal structure of RNase T1(Y45W) complexed with 3'AMP and GflpA

We have previously reported the crystallization of a mutant RNase T1(Y45W) with a synthetic modified trinucleotide ApGflpA [Hakoshima, T. et al. (1990) J. Biochem. 108, 695-698]. In the present report, we describe the crystal structure refined at 2.4 A resolution. During the refinement process, we found that the ApGflpA molecule was cleaved at the phosphodiester bond between the 5'-terminal adenosine and the subsequent 2'-fluoroguanosine. At the end of the refinement (R = 17.1%), it was supposed that the resulting molecules, i.e., 3'AMP and GflpA, were separately bound to the enzyme. In the complex structure, the binding-site of the enzyme was occupied by the guanine base of GflpA via a similar interaction to that of the enzyme complexed with 2'GMP, while the phosphate group of GflpA was not bound to the active site. The guanosine adopted the anti orientation on the glycosyl torsion angle with a C2'-endo-C3'-exo sugar pucker. This conformation resulted in the phosphate group protruding from the active site. The phosphate group of 3'AMP was bound to the active site of the enzyme and oriented itself toward the solvent region. This orientation was different from that of 2'AMP bound to the RNase T1(Y45W).

NMR studies of G:A mismatches in oligodeoxyribonucleotide duplexes modelled after ribozymes

The structures of two oligodeoxyribonucleotide duplexes, the base sequences of which were modelled after both a hammerhead ribozyme and a small metalloribozyme, were studied by NMR. Both duplexes contain adjacent G:A mismatches; one has a PyGAPu:PyGAPu sequence and the other a PyGAPy:PuGAPu sequence. It is concluded on the basis of many characteristic NOEs that in both duplexes G:A base pairs are formed in the unique 'sheared' form, where an amino proton instead of an imino proton of G is involved in the hydrogen bonding, and G and A bases are arranged 'side by side' instead of 'head to head'. A photo-CIDNP experiment, which gives unique and independent information on the solvent accessibility of nucleotide bases, also supports G:A base pairing rather than a bulged-out structure of G and A residues. This is the first demonstration that not only the PyGAPu:PyGAPu sequence but also the PyGAPy:PuGAPu sequence can form the unique sheared G:A base pairs. Taking the previous studies on G:A mismatches into account, the idea is suggested that a PyGA:GAPu sequence is a minimum and essential element for the formation of the sheared G:A base pairs. The sheared G:A base pairs in the PyGAPu:PyGAPu sequence are suggested to be more stable than those in the PyGAPy:PuGAPu sequence. This is explained rationally by the idea proposed above.

Crystal structure of ribonuclease Ms (as a ribonuclease T1 homologue) complexed with a guanylyl-3',5'-cytidine analogue

A ribonuclease T1 homologue, ribonuclease Ms (RNase Ms) from Aspergillus saitoi, has been crystallized as a complex with a substrate analogue GfpC where the 2'-hydroxyl (2'-OH) group of guanosine in guanylyl-3',5'-cytidine (GpC) is replaced by the 2'-fluorine (2'-F) atom to prevent transesterification. The crystal structure of the complex was solved at 1.8-A resolution to a final R-factor of 0.204. The role of His92 (RNase T1 numbering) as the general acid catalyst was confirmed. Of the two alternative candidates for a general base to abstract a proton from the 2'-OH group, His40 and Glu58 were found close to the 2'-F atom, making the decision between the two groups difficult. We then superposed the active site of the RNase Ms/GfpC complex with that of pancreatic ribonuclease S (RNase S) complexed with a substrate analogue UpcA, a phosphonate analogue of uridylyl-3',5'-adenosine (UpA), and found that His12 and His119 of RNase A almost exactly coincided with Glu58 and His92, respectively, of RNase Ms. Similar superposition with a prokaryotic microbial ribonuclease, RNase St [Nakamura, K. T., Iwahashi, K., Yamamoto, Y., Iitaka, Y., Yoshida, N., & Mitsui, Y. (1982) Nature 299, 564-566], also indicated Glu58 as a general base. Thus the present comparative geometrical studies consistently favor, albeit indirectly, the traditional as well as the most recent notion [Steyaert, J., Hallenga, K., Wyns, L., & Stanssens, P. (1990) Biochemistry 29, 9064-9072] that Glu58, rather than His40, must be the general base catalyst in the intact enzymes of the RNase T1 family.

Determination of bovine rotavirus G and P serotypes by polymerase chain reaction

Among bovine rotaviruses there are two major G serotypes (G6 and G10) and three P serotypes (P1, P5, and P11, each of which is defined on the basis of the VP4 antigenic specificity of NCDV, UK and KK-3, respectively). The nucleotide sequence of a P11 gene (KK-3) was determined. The predicted KK-3 VP4 contained 772 amino-acids and showed 96% amino-acid identity with B223 VP4, an American prototype of P11 bovine rotavirus. Comparative analysis of the genes determining the G and P serotypes of bovine rotaviruses allowed us to develop polymerase chain reaction (PCR)-based assays which distinguished two G serotypes and three P serotypes commonly found in bovine rotaviruses. For determination of G serotypes, a 1013 bp fragment of the VP7 gene was first reverse-transcribed and then amplified with a pair of generic primers. In a second PCR amplification, the 5' generic primer and two different typing primers (either G6- or G10-specific) were used to generate fragments whose sizes served to identify the G serotype. Similarly, for determination of P serotypes, an 864 bp fragment of the VP4 gene was first reverse-transcribed and then amplified with another pair of generic primers. In a second PCR amplification, the 5' generic primer and three different typing primers, each one specific to one of the three P serotypes, were used to generate fragments whose sizes served to identify the P serotype. These assays were able to identify the G and P serotypes of six reference bovine rotavirus strains.

Charged collagen structure mediates the recognition of negatively charged macromolecules by macrophage scavenger receptors

Macrophage scavenger receptors mediate the recognition of a wide range of negatively charged macromolecules including modified low density lipoproteins (LDL). Truncated bovine receptors lacking residues 330-342, which include the conserved lysine cluster of a collagen-like domain, were unable to degrade modified LDL in spite of their expression on the cell surface. Substitution of lysine 337 into alanine abolished the acetyl-LDL degradation and binding at 37 degrees C, but did not abolish the 4 degrees C binding. In contrast, substitution of more than 2 lysines in this region are needed to abolish the oxidized LDL degradation and 37 degrees C binding. Based on computational modeling of this domain, we propose that a "charged collagen" structure containing a lysine cluster forms a positively charged groove which specifically interacts with negatively charged ligands.

Structural studies of DNA and RNA containing AG base pairs by NMR

Base pairing between A and G residues has been suggested in some ribozymes and the structure derived from this non-standard base pairing could play a crucial role in enzymatic actions of the ribozymes. We have studied the structures of three DNAs and an RNA that base sequences were modeled after the ribozymes by NMR. It was found that the A and G residues can form a basepair in a very unique fashion both in the DNAs and RNA. "Side" instead of "head to head" alignment of the two bases was found, where an amino proton instead of an imino proton of the G residue is involved in the hydrogen bonding. As a result of the unique basepairing, certain bases stack over the bases of the opposite strand instead of over the ones of the same strand. It was also shown that the formation and thermal stability of this unique AG basepair depend on the neighbouring base sequences. Moreover existence of the unique AG basepairs was suggested in a real small metalloribozyme itself.

[Automatic analyzing systems for blood chemistry and urinalysis]

We constructed two new automatic analyzing systems for blood chemistry and urinalysis. The blood chemistry system consists of centrifuge station, on-line allotting station, belt line, Hitachi 736 -60, -40, off-line allotting station, storage allotting station and sample stocker, these are connected with belt line. If only specimens are set and switched on, analytical process from serum separation to measurement is advanced automatically, and then printed out the analytical results, it is the highest speed of 1.8 test/sec, in the world. Urinalysis system consists of qualitative analyzing station, quantitative analyzing station and urinary sediment analyzer, two station are logically coupled with belt line. It is a unique system of urinalysis that qualitative and quantitative analysis of urine is logically done by computerizing program.

Thermal degradation of RNA-RNA hybrids during hybridization in solution

Degradation of single-stranded RNA molecules at high temperatures was examined in relation to the kinetics of RNA-RNA hybridization in solution. Eleven species (ranging from 670 bases to 3300 bases) of single-stranded RNAs transcribed from rotavirus genomic RNAs degraded significantly after 16 h of incubation at 65 degrees C. The hybridization of these 11 RNA molecules to the corresponding genomic RNAs, however, was completed within 30 min of incubation. Partially homologous hybrids that were once formed at an early time of incubation gradually degraded in proportion to the length of incubation at 65 degrees C. Thus, the length of hybridization has a critical effect on the final hybridization results. Furthermore, thermal hydrolysis of single-stranded RNA molecules provides a plausible explanation why the percent of nucleotide sequence mismatch allowed to form a stable hybrid in the RNA-RNA hybridization assays for rotavirus genes is much less than that predicted by calculation.

Deletion of internal sequence on the HDV-ribozyme: elucidation of functionally important single-stranded loop regions

In elucidating functionally important single-stranded loop regions derived mainly from three models in genomic hepatitis delta virus (HDV) ribozyme possessing self-cleavage activity, we have constructed several internal deletion variants of the HDV133 molecule (654-786 nt on genomic RNA) by oligonucleotide-directed mutagenesis. When self-cleavage activities were compared among variants, the HDV133DI-1 (deletion of 701-718 nt) and HDV133DI-3 (deletion of 740-752 nt) ribozyme could maintain their self-cleavage activity, despite at reduced level. However, the activity could be regained in both mutants by some extent under partially denaturing conditions. These results suggest that the above two single-stranded RNA loop regions in HDV ribozyme are not part of the catalytic core but might be involved in the stability of the molecule. In contrast, deletion mutants such as HDV133DI-2 (deletion of 696-722 nt), HDV88DI-1 (deletion of 701-718 nt), HDV88DI-2 (deletion of 696-722 nt), and HDV88DI-4 (deletion of 733-760 nt) abolished catalytic activity. These results suggest that the remaining single-stranded regions of bases between 726-731 and 762-766 in the HDV88 ribozyme may be the potential regions to interact with Mg2+ ions.

Three-dimensional structure of a mutant ribonuclease T1 (Y45W) complexed with non-cognizable ribonucleotide, 2'AMP, and its comparison with a specific complex with 2'GMP

The crystal structure of a mutant ribonuclease T1 (Y45W) complexed with a non-cognizable ribonucleotide, 2'AMP, has been determined and refined to an R-factor of 0.159 using X-ray diffraction data at 1.7 A resolution. A specific complex of the enzyme with 2'GMP was also determined and refined to an R-factor of 0.173 at 1.9 A resolution. The adenine base of 2'AMP was found at a base-binding site that is far apart from the guanine recognition site, where the guanine base of 2'GMP binds. The binding of the adenine base is mediated by a single hydrogen bond and stacking interaction of the base with the imidazole ring of His92. The mode of stacking of the adenine base with His92 is similar to the stacking of the guanine base observed in complexes of ribonuclease T1 with guanylyl-2',5'-guanosine, reported by Koepke et al., and two guanosine bases, reported by Lenz et al., and in the complex of barnase with d(GpC), reported by Baudet & Janin. These observations suggest that the site is non-specific for base binding. The phosphate group of 2'AMP is tightly locked at the catalytic site with seven hydrogen bonds to the enzyme in a similar manner to that of 2'GMP. In addition, two hydrogen bonds are formed between the sugar moiety of 2'AMP and the enzyme. The 2'AMP molecule adopts the anti conformation of the glycosidic bond and C-3'-exo sugar pucker, whereas 2'GMP is in the syn conformation with C-3'-endo-C'-2'-exo pucker. The mutation enhances the binding of 2'GMP with conformational changes of the sugar ring and displacement of the phosphate group towards the interior of the catalytic site from the corresponding position in the wild-type enzyme complex. Comparison of two crystal structures obtained provides a solution to the problem that non-cognizable nucleotides exhibit unexpectedly strong binding to the enzyme, compared with high specificity in nucleolytic activity. The results indicate that the discrimination of the guanine base from the other nucleotide bases at the guanine recognition site is more effective than that estimated from nucleotide-binding experiments so far.

[Quantitative assays for C-reactive protein: a review]

C-reactive protein (CRP) is a single most important test among various serological tests which are routinely performed in clinical laboratories. While qualitative assays for CRP are being replaced by quantitative assays, standardization among various laboratories has become an urgent issue. The results of the past three-year surveys conducted by the Japanese Medical Association showed that the coefficients of variation (CV) for CRP assays ranged between 12.6% and 46.9% (1990), although these figures gradually changed for the better. These results clearly indicate that a CRP value obtained in one laboratory cannot be compared directory with that obtained in another laboratory. Every assay for CRP is considered to show good reproducibility, however, which is predicted by the results of within-run precision tests (CV:3.9-7.8%). It is very important to establish standardization for CRP assays but one has to conclude that the path toward this goal is very difficult when one takes into consideration various factors inherent to immunological reactions of macromolecules including possible microheterogeneity of CRP molecules.

Interaction of bleomycin with deoxyribonucleic acid oligomer: proton nuclear magnetic resonance titration study using novel bleomycin complexes with Ni2+ and VO3+

Two metal complexes of bleomycin (BLM), BLM-Ni2+ and BLM-VO3+ are used for studying interactions between BLM and deoxyribonucleic acid (DNA) by nuclear magnetic resonance. Although these BLMs do not mediate DNA strand scission under the usual conditions, they bind to DNA in the same manner as the active metal complexes of bleomycin (BLM-Fe2+ and BLM-Co3+). A self-complementary dodecanucleotide, d(CCCCAGCTGGGG), having a single site for cleavage was synthesized. d(CCCCAATTGGGG), which contains no -GpC- sequence, was also synthesized. The BLM-metal complexes were shown to bind specifically to the GpC site by circular dichroism and fluorescence titration studies. We assigned all the resonances for imino protons and phosphorus, and most of the nonexchangeable proton resonances of d(CCCCAGCTGGGG). No substantial change in the chemical shifts of these signals was observed upon titration with either BLM-Ni2+ or BLM-VO3+. This result is not consistent with a model of the strong intercalation of the BLMs between the base-pairs. The BLMs bind to DNA in a different manner, and DNA does not change its conformation upon binding with BLMs.

Conformation of 2'GMP bound to a mutant ribonuclease T1 (Y45W) determined by X-ray diffraction and NMR methods

The crystal structure of a mutant ribonuclease T1 (Y45W) complexed with a specific inhibitor, 2'GMP, has been determined by X-ray diffraction and refined at 1.9 A resolution to a conventional R-factor of 0.164. The mode of recognition of the guanine base by the enzyme is similar to that found for the wild-type ribonuclease T1 complexed with 2'GMP. The binding of the guanine base is clearly enhanced by maximum overlapping of the indole ring of Trp45 and the base. The glycosyl torsion angle of the inhibitor is in the syn conformation and the sugar exhibits a C3'-endo type pucker, which differs from that observed in the crystal of the complex between the wild-type ribonuclease T1 and 2'GMP. Analysis of 500-MHZ NMR spectra has also indicated that the 2'GMP molecule as bound to the mutant enzyme in solution exhibits a C3'-endo type pucker, similar to that bound to the wild-type enzyme in solution [Inagaki, Shimada, & Miyazawa (1985) Biochemistry 24, 1013-1020].

NMR studies for identification of dI:dG mismatch base-pairing structure in DNA

One- and two-dimensional NMR experiments have been undertaken to investigate deoxyinosine:deoxyguanosine (dI:dG) base pairing in a self-complementary dodecadeoxyribonucleotide, d(C1-G2-C3-I4-A5-A6-T7-T8-G9-G10-G11-G12) (designated IG-12), duplex. The NMR data indicate formation of a dI(syn):dG(anti) base pair in a B-DNA helix. This unusual base pairing results in altered NOE patterns between the base protons (H8 and H2) of the I4 residue and the sugar protons of its own and the 5'-flanking C3 residues. The dI(syn):dG(anti) base pair is accommodated in the B-DNA duplex with only a subtle distortion of the local conformation. Identification of the dI:dG base pairing in this study confirms that a hypoxanthine base can form hydrogen-bonded base pairs with all of the four normal bases, C, A, T, and G, in DNA.

Hydrophobic effects on protein/nucleic acid interaction: enhancement of substrate binding by mutating tyrosine 45 to tryptophan in ribonuclease T1

Hydrophobic effects on binding of ribonuclease T1 to guanine bases of several ribonucleotides have been proved by mutating a hydrophobic residue at the recognition site and by measuring the effect on binding. Mutation of a hydrophobic surface residue to a more hydrophobic residue (Tyr45----Trp) enhances the binding to ribonucleotides, including mononucleotide inhibitor and product, and a synthetic substrate-analog trinucleotide as well as the binding to dinucleotide substrates and RNA. Enhancements on binding to non-substrate ribonucleotides by the mutation have been observed with free energy changes ranging from -2.2 to -3.9 kJ/mol. These changes are in good agreement with that of substrate binding, -2.3 kJ/mol, which is calculated from Michaelis constants obtained from kinetic studies. It is shown, by comparing the observed and calculated changes in binding free energy with differences in the observed transfer free energy changes of the amino acid side chains from organic solvents to water, that the enhancement observed on guanine binding comes from the difference in the hydrophobic effects of the side chains of tyrosine and tryptophan. Furthermore, a linear relationship between nucleolytic activities and hydrophobicity of the residues (Ala, Phe, Tyr, Trp) at position 45 is observed. The mutation could not change substantially the base specificity of RNase T1, which exhibits a prime requirement for guanine bases of substrates.

Non-cognizable ribonucleotide, 2'AMP, binds to a mutant ribonuclease T1 (Y45W) at a new base-binding site but not at the guanine-recognition site

Complex of a mutant ribonuclease T1 (Y45W) with a non-cognizable ribonucleotide, 2'AMP, has been determined and refined by X-ray diffraction at 1.7 A resolution. The 2'AMP molecule locates at a new base-binding site which is remote from the guanine-recognition site, where 2'GMP was found to be bound. The nucleotide adopts the anti conformation of the glycosidic bond and C3'-exo sugar pucker. There exists a single hydrogen bond between the adenine base and the enzyme, and, therefore, the site found is apparently a non-specific binding site. The results indicate that the binding of 2'AMP to the guanine-recognition site is weaker than that to the new binding site.