Quaternary structure of pigeon liver malic enzyme

Pigeon liver malic enzyme (EC 1.1.1.40) has a double dimer quaternary structure. The NADP+ analogs, aminopyridine adenine dinucleotide phosphate and nicotinamide-1,N6-ethenoadenosine dinucleotide phosphate, bind to the enzyme anti-cooperatively. In the presence of non-cooperative competing ligand NADP+, the binding parameter Hill coefficients of these analogues changed very little. Binding of L-malate with enzyme-AADP+ complex first enhanced then reduced the nucleotide fluorescence. Two L-malate binding sites, with Kd values of 23-30 and 270-400 microM, respectively. for the tight and weak binding sites were postulated. A hybrid model between the sequential and pre-existing asymmetrical models was proposed for the pigeon liver malic enzyme.     

Novel UGA-suppressors in Escherichia coli K-12

UGA-specific nonsense suppressors from Escherichia coli K-12 were isolated and characterized. One of them (Su+UGA-11) was identified as a mutant of the prfB gene for the peptide releasing factor RF2. It appears that in this strain, while peptide release at sites of UGA mutations is retarded, the UGA stop codon is read through even in the absence of a tRNA suppressor, exhibiting a novel type of passive nonsense suppression. Three suppressors (Su+UGA-12, -16 and -34) were capable of restoring the streptomycin sensitive phenotype in resistant bacteria (strAr). Because of their drug-related phenotype, these are possibly mutations in the components of the ribosomal machinery, particularly those concerned with peptide release at UGA nonsense codons. A tRNA suppressor was also obtained which was derived from the tRNA(Trp) gene. In this strain, a long region between rrnC (84.5 min) and rrnB (89.5 min) was duplicated and one of the duplicated genes of tRNA(Trp) was mutated to the suppressor. The mechanism of UGA-suppression is discussed in terms of translation termination at the nonsense codon in both active and passive fashions.     

Full-length sequence of the cDNA for human erythroid beta-spectrin

Spectrin is the major molecular consituent of the red cell membrane skeleton. We have isolated overlapping human erythroid beta-spectrin cDNA clones and determined 6773 base pairs of contiguous nucleotide sequence. This includes the entire coding sequence of beta-spectrin. The sequence translates into a 2137 amino acid, 246-kDa peptide. beta-Spectrin is found to consist of three distinct domains. Domain I, at the N terminus, is a 272-amino acid region lacking resemblance to the spectrin repetitive motif. Sequences in this region exhibit striking sequence homology, at both nucleotide and amino acid levels, to the N-terminal "actin-binding" domains of alpha-actinin and dystrophin. Between residues 51 and 270 there is 55% amino acid identity to human dystrophin, with only four single amino acid gaps in alignment. Domain II consists of 17 spectrin repeats. Several sequence variations are observed in typical repeat structure. Homology to alpha-actinin extends beyond domain I into the N-terminal portion of domain II. Domain III, 52 amino acid residues at the C terminus, does not adhere to the spectrin repeat motif. Combining knowledge of spectrin primary structure with previously reported functional studies, it is possible to make several inferences regarding structure/function relationships within the beta-spectrin molecule.     

Purification of Trypanosoma cruzi surface proteins involved in adhesion to host cells

We have identified four surface 83 kDa proteins of pI values 6.3, 6.4, 6.5 and 6.6 in T. cruzi trypomastigotes which specifically bind to rat heart myoblasts. These proteins were purified by isoelectric focusing and anion-exchange chromatography in an FPLC system. These 83 kDa proteins inhibit the attachment of trypomastigotes to myoblasts in a concentration-dependent manner, indicating that these trypomastigote proteins mediate the attachment of trypomastigotes to heart myoblasts.     

Affinity enhancement of bispecific antibody against two different epitopes in the same antigen.

For the enhancement of antibody binding affinity, a bispecific antibody against two different epitopes in human chorionic gonadotropin hormone, one is in alpha-subunit and the other is in beta-subunit, was prepared by chemical recombination using 5,5'-dithiobis(2-nitrobenzoic acid). The epitopes recognized by antibodies were investigated by competitive radioimmunoassay, two-site sandwich radioimmunoassay and additivity assay and a proper epitope pair was chosen for preparation of the bispecific antibody. This bispecific antibody has dual specificity and as much as 17.2-fold higher affinity than that of monoclonal antibody with higher affinity by dual antigen binding radioimmunoassay and Scatchard plot analysis.     

Formation of 2-methyltryptophan in the biosynthesis of thiostrepton: isolation of S-adenosylmethionine:tryptophan 2-methyltransferase

L-2-Methyltryptophan was found to be an intermediate in the biosynthesis of the antibiotic thiostrepton. It was isolated from growing cultures and resting cells of Streptomyces laurentii in trapping experiments after the application of labeled L-methionine or L-tryptophan. Its formation from L-tryptophan and S-adenosylmethionine was studied in a cell-free extract of S. laurentii. Although several attempts to purify the soluble methyltransferase by standard methods failed, some of its characteristics could be determined in the crude extract. The enzyme has a sharp pH optimum at pH 7.8. The apparent Km value for S-adenosylmethionine is 120 microM and the Ki value for S-adenosylhomocysteine is 480 microM. The enzyme is not stereoselective with respect to D- or L-tryptophan, but the D-isomer is converted at a slower rate than the L-isomer. Indolepyruvic acid is also methylated, while indole is not a substrate. The methyl group is transferred with retention of its configuration, contrary to most other methyltransferase reactions.     

Stabilization of Z-DNA by demethylation of thymine bases: 1.3-A single-crystal structure of d(m5CGUAm5CG)

Methylation of cytosine bases at the C5 position has been known to stabilize Z-DNA. We had previously predicted from calculations of solvent-accessible surfaces that the methyl group at the same position of thymine has a destabilizing effect on Z-DNA. In the current studies, the sequence d(m5CGUAm5CG) has been crystallized and its structure solved as Z-DNA to 1.3-A resolution. A well-defined octahedral hexaaquomagnesium complex was observed to bridge the O4 oxygens of the adjacent uridine bases at the major groove surface, and four well-structured water molecules were found in the minor groove crevice at the d(UA) dinucleotide. These solvent interactions were not observed in the previously published Z-DNA structure of the analogous d(m5CGTAm5CG) sequence. A comparison of the thymine and uridine structures supports our prediction that demethylation of thymine bases helps to stabilize Z-DNA. A comparison of this d(UA)-containing Z-DNA structure with the analogous d(TA) structure shows that access of the O4 position is hindered by the C5 methyl of thymine due to steric and hydrophobic inhibition. In the absence of the methyl group, a magnesium-water complex binds to and slightly affects the structure of the Z-DNA major groove surface. This perturbation of the solvent structure at the major groove surface is translated into a much larger 1.41-A widening of the minor groove crevice, thereby allowing the specific binding of two water molecules at well-defined sites of each internal d(UA) base pair. Possible mechanisms by which modifications at the major groove surface of Z-DNA can affect the solvent properties of the minor groove crevice are discussed.     

Site-directed mutagenesis of glycine-14 and two "critical" cysteinyl residues in Drosophila alcohol dehydrogenase

Three amino acid residues (glycine-14, cysteine-135, and cysteine-218) previously speculated to be important for the structure and function of Drosophila melanogaster alcohol dehydrogenase have been investigated by using site-directed mutagenesis followed by kinetic analysis and chemical modification. Mutating glycine-14 to valine (G14V) virtually inactivates Drosophila ADH, and substitution of alanine at this position (G14A) causes a 31% decrease in activity. Thermal denaturation and kinetic and inhibition studies further demonstrate that replacing glycine-14 with either alanine or valine leads to structural changes in the NAD binding domain. These results provide direct evidence for the role played by glycine-14 in maintaining the correct conformation in the NAD binding domain. On the other hand, changing of cysteine-135, -218, or both to alanine (C135A, C218A, and C135A/C218A) causes no decrease in the catalytic activity of the enzyme, indicating that neither of the cysteinyl residues is essential for catalysis. C135A and wild-type enzyme are both inactivated by DTNB. In contrast, C218A and C135A/C218A are unaffected by DTNB treatment. DTNB modification of cysteine-218 can be prevented by the substrates NAD and 2-propanol, suggesting that cysteine-218 may be in the vicinity of the active site. Cysteine-135 which is normally insensitive to DTNB becomes accessible in the presence of 2-propanol and/or NAD, suggesting a conformational change induced by binding of these substrates.     

14-Fluorobacteriorhodopsin and other fluorinated and 14-substituted analogues. An extra, unusually red-shifted pigment formed during dark adaptation

Five vinyl-substituted fluororetinal analogues (8-F, 10-F, 12-F, 14-F, and 13,14-F2) were found to give bacteriorhodopsin analogues with properties similar to those of the parent system. Of these, only 14-fluororetinal was found to give an extra red-shifted BR analogue (lambda max less than or equal to 680 nm) in equilibrium with the normal 587-nm pigment. The 680-nm pigment was enriched upon irradiation. It rearranged to the 587-nm pigment at room temperature (delta E [symbol: see text] = 20.8 kcal/mol). Chromophore extraction experiments revealed the all-trans geometry for the 680-nm pigment. 14-Chlororetinal gave a similarly red-shifted pigment while 14-methylretinal did not. A scheme for dark adaptation of the 14-halogenated bacteriorhodopsins has been proposed in which the new red-shifted pigment was assigned the all-trans, 15-syn geometry.     

The N-terminal amino group essential for the biological activity of notexin from Notechis scutatus scutatus venom

Notexin from Notechis scutatus scutatus snake venom was modified with trinitrobenzenesulfonic acid, and the major trinitrophenylated (TNP) derivative was separated by high-performance liquid chromatography. Modification resulted in the incorporation of only one TNP group on the N-terminal alpha-amino group. The TNP derivative showed a precipitous decrease in enzymatic activity and lethal toxicity, whereas the antigenicity remained unchanged. However, trinitrophenylation did not significantly affect the secondary structure of the toxin molecule as revealed by the CD spectra. The results, that the modification reaction was accelerated by the Ca2+ and that the TNP derivative retains its affinity for Ca2+, indicate that the N-terminal alpha-amino group did not participate in the Ca2(+)-binding. The TNP derivative could be regenerated with hydrazine hydrochloride. The biological activities of the regenerated notexin are almost the same as those of native notexin. These results suggest that the N-terminal alpha-amino group is essential for the phospholipase A2 activity and lethal toxicity of notexin, and that incorporation of the TNP group on the N-terminal alpha-amino group might give rise to a distortion of the active conformation of notexin.