Cyclic nucleotide phosphodiesterase activities in Neurospora crassa.

Cyclic nucleotide phosphodiesterase activities in soluble Neurospora crassa mycelial extracts were resolved into two peaks, phosphodiesterase I and II, by chromatography on DEAE-cellulose columns. Phosphodiesterase I hydrolysed cyclic AMP and cyclic GMP equally well. Phosphodiesterase II was active on cyclic GMP but scarcely active on cyclic AMP. Phosphodiesterase I was resolved by gel filtration and sucrose-density-gradient centrifugation into three peaks having molecular weights of about 57 000, 125 000 and 225 000. This suggests that this enzyme activity has at least three aggregation forms, tentatively defined as monomeric, dimeric and tetrameric. Similarly, phosphodiesterase II was resolved into two forms, having molecular weights of about 170 000 and 320 000. Evidence on the interconversion between phosphodiesterase I forms was obtained.     

Human alpha-fucosidase. Purification and properties.

Human placental alpha-fucosidase (EC 3.2.1.51) has been extensively purified and partially characterized with respect to kinetic and structured properties. Although the enzyme seems to be separated by DEAE-cellulose chromatography in two forms which differ in their molecular weight and thermostability, an interconversion between the two forms takes place during storage and/or electrofocusing so that the same peaks of activity, revealed by the latter technique, are found before and after DEAE-cellulose chrome. The heterogeneous peaks of activity revealed by isoelectrofocusing show a reproducible pattern in the different tissues examined, except in serum where their pI values are consistently more acidic.     

Identification of two forms of progesterone receptor from chick oviduct cytosol using non-denaturing gel electrophoresis

Non-denaturing polyacrylamide gel electrophoresis and non-denaturing agarose gel electrophoresis have been used to resolve [3H]R5020-binding components from chick oviduct cytosol. From both gel systems 2 peaks of bound radioactivity are resolved which display these properties of authentic progesterone receptor: binding of R5020: steroid specificity, saturability, and restriction to target tissues. The two peaks are approximately equal in magnitude, and there is no evidence for interconversion of the 2 peaks. The presence or absence of 10-20 mM sodium molybdate during cytosol preparation had no effect on the magnitude or mobility of either peak. Neither peak contains salt-dissociable components which affect its electrophoretic properties, suggesting a possible alteration of native receptor forms during electrophoresis.     

Longitudinal exchange: an alternative strategy towards quantification of dynamics parameters in ZZ exchange spectroscopy

Longitudinal exchange experiments facilitate the quantification of the rates of interconversion between the exchanging species, along with their longitudinal relaxation rates, by analyzing the time-dependence of direct correlation and exchange cross peaks. Here we present a simple and robust alternative to this strategy, which is based on the combination of two complementary experiments, one with and one without resolving exchange cross peaks. We show that by combining the two data sets systematic errors that are caused by differential line-broadening of the exchanging species are avoided and reliable quantification of kinetic and relaxation parameters in the presence of additional conformational exchange on the ms-μs time scale is possible. The strategy is applied to a bistable DNA oligomer that displays different line-broadening in the two exchanging species.     

Characterization of cell-surface glycopeptides from mouse cerebral cortex that inhibit cell growth and protein synthesis.

The occurrence of multiple forms of rat prolactin with different molecular weights (size heterogeneity) was studied with anterior pituitary extracts, purified rat prolactin and 125I-labelled rat prolactin. In each case, three main forms of the hormone were detected by gel filtration on Sephadex G-100: a major one (80--90%) corresponding to monomeric prolactin (mol.wt. 22000--25000), a peak (8--20%) that could be a dimer (mol.wt. 45000--50000) and a small quantity (1--5%) of a component of much greater molecular weight. On freezing and thawing of 125I-labelled rat prolactin, there was little interconversion of monomer and 'dimer' peaks, but both were converted substantially to very high-molecular-weight material. All three peaks of 125I-labelled rat prolactin could be precipitated by anti-(rat prolactin) serum and all three gave similar patterns of radioactive peptides after digestion with chymotrypsin followed by high-voltage paper electrophoresis. On sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, the monomer peak of 125I-labelled prolactin migrated as a single component of mol.wt. 22000, the very high-molecular-weight peak largely dissociated to a component running in the same position as the monomer, and the 'dimer' peak migrated partly as a component of mol.wt. 45000 and partly as a component migrating with monomeric prolactin. No treatment was found that could dissociate the 'dimer' peak completely to monomeric prolactin.     

Classical hybrid Monte-Carlo simulation of the interconversion of hexabromocyclododecane stereoisomers

The interconversion of the six main stereoisomers of the flame retardant hexabromocyclododecane (HBCD) is investigated by means of statistical thermodynamics using classical force-fields. ( ± )-α-, ( ± )-β- and ( ± )-γ-HBCD interconvert by swapping of absolute configurations on the three different (BrHC–CHBr)-moieties. The approach avoids saddle-point energy computations, but relies on classical thermodynamic simulation and pursues three consecutive steps. First, the application of classical hybrid Monte-Carlo simulations for quantum mechanical processes is justified. Second, the problem of insufficient convergence properties of hybrid Monte-Carlo methods for the generation of low temperature canonical ensembles is solved by an interpolation approach. Third, it is shown how free energy differences among stereoisomers are derived and how they can be used for the computation of interconversion rates. The simulation results confirm the experimentally observed interconversion rates and correctly identify α-HBCD as a thermodynamical sink in the oscillating mixture of stereoisomers.     

Conformational heterogeneity of quinoxaline peptides in solution.

The conformational heterogeneity of several quinoxaline antibiotics, a class of naturally occurring quinoxaline peptides with antitumor properties, and their synthetic analogues was investigated in polar and nonpolar solvents by high performance liquid chromatography (HPLC) with uv photodiode array detection, uv-absorbance, low-temperature phosphorescence, and nmr techniques. Multiple peak formation and interconversion in the HPLC and 1H-nmr analysis of triostin A, its under-N-methylated synthetic analogues (des-N-tetramethyltriostin A [TANDEM] and [N-MeCys3, N-MeCys7]-TANDEM [MCTAN-DEM]), and echinomycin were examined as a function of temperature, solvent polarity, and residence time in solution prior to analysis. Slow interconversion between HPLC peaks, ascribed to the presence of multiple solution conformers, was exhibited by these peptides although at very different interconversion rates. Among the triostins, the rate of interconversion appeared to vary with the degree of N-methylation of the residues in the cyclic depsipeptide chain. Interconversion of the n and p conformers of triostin A in chloroform occurred on a chromatographic timescale (a few minutes with kn----p calculated to be 0.02 s-1 at 25 degrees C) while the solution conformers of TANDEM in methanol equilibrated very slowly to one preferred conformer over a period of several weeks at ambient temperature. MCTANDEM, a synthetic analogue of triostin A with an intermediate degree of N-methylation of the residues in the peptide ring, consisted of an equilibrium mixture of n and p conformers in methanol that interconverted on a chromatographic time scale. Two additional conformers of MCTANDEM developed within a few weeks' residence time in methanol at ambient temperature. Echinomycin was found to exist in methanol as an interconverting mixture of at least four minor conformers in addition to the major isoform (95% by peak area) of the peptide. The solution conformers of the quinoxaline peptides investigated in this report are most likely a consequence of hindered rotation about the N-methylated peptide bonds in the depsipeptide ring and/or intramolecular hydrogen bonding.     

Purification and characterization of two forms of cyclic GMP-dependent protein kinase from bovine aorta

Cyclic GMP-dependent protein kinase in extracts of bovine aortic tissue eluted from DEAE-cellulose ion-exchange resins as two distinct peaks of activity. This elution pattern was preserved when the peaks were combined, precipitated with ammonium sulfate, dialyzed, and rechromatographed. Proteolysis did not appear to account for the two forms of kinase because (i) aging of the extract did not cause interconversion of the two forms, and (ii) both forms retained cGMP sensitivity unlike the proteolytically formed monomer. In addition, treatment with saturating concentrations of cGMP (10 microM) did not cause interconversion of the two forms. The first peak of cGMP-dependent protein kinase eluting from DEAE-cellulose (form 1) had a slightly greater mobility on gradient sodium dodecyl sulfate-polyacrylamide gels than the second peak (form 2). On native, nondenaturing gradient polyacrylamide gels, however, form 2 displayed the greater electrophoretic mobility. Furthermore, form 1, when bound to cAMP-agarose, appeared to exchange more rapidly with cGMP than form 2 when subjected to affinity chromatography. Peptide maps generated from the two forms by protease treatment were very similar, although trypsin produced a unique peptide in form 1 and Streptomyces griseus protease gave rise to unique peptides in forms 1 and 2. Phosphorylation did not appear to account for the physical differences because both enzymes could be phosphorylated to similar extents and dephosphorylation using alkaline phosphatase did not result in the conversion of one form to the other. These results suggest that either differences in primary structure or post-translational modification, other than phosphorylation, are responsible for the presence of two forms of cGMP-dependent protein kinase in aortic tissue.     

Mutants of the Formyltetrahydrofolate Interconversion Pathway of SACCHAROMYCES CEREVISIAE

Thirteen mutants of Saccharomyces cerevisiae that lack one or more of the three enzyme activities of the pathway for interconversion of tetrahydrofolate coenzymes at the formate level of oxidation have been isolated. They do not require adenine. All fail to complement mutations in the ade3 locus. Mutations that greatly reduce activity for one enzyme also reduce activity for the other two interconversion enzymes. The three enzyme activities cochromatograph on TEAE-cellulose columns. A mutation that eliminates synthetase activity also alters the chromatographic behavior of the remaining cyclohydrolase and dehydrogenase activities. It is suggested that the three activities reside in an enzyme complex encoded by the ade3 locus.     

Site-specific NMR monitoring of cis-trans isomerization in the folding of the proline-rich collagen triple helix

Understanding the folding of the proline-rich collagen triple helix requires consideration of the effects of proline cis-trans isomerization and may shed light on the misfolding of collagen in connective tissue diseases. Folding was monitored in real time by heteronuclear 2D NMR spectroscopy for the (15)N labeled positions in the triple-helical peptide T1-892 [GPAGPAGPVGPAGARGPAGPOGPOGPOGPOGV]. In the equilibrium unfolded monomer form, each labeled residue showed multiple peaks with interconversion rates consistent with cis-trans isomerization of Gly-Pro and Pro-Hyp bonds. Real-time NMR studies on the folding of T1-892 showed slow decay of monomer peaks and a concomitant increase in trimer peaks. Gly25 in the C-terminal rich (Gly-Pro-Hyp)(4) domain folds first, consistent with its being a nucleation domain. Analysis of the kinetics indicates that the folding of Gly25 is biphasic and the slower step represents cis-trans isomerization of imino acids. This illustrates that nucleation is limited by cis-trans isomerization. Monitoring Gly6, Gly10, Ala12, and Gly13 monomer and trimer peaks captures the C- to N-terminal propagation of the triple helix, which is also limited by Gly-Pro cis-trans isomerization events. The zipper-like nature of the propagation process is confirmed by the slower rate of folding of Ala6 compared to Gly13, reflecting the larger number of isomerization events encountered by the more N-terminal Ala6. The cis-trans isomerization events at multiple proline residues is a complex statistical process which can be visualized by these NMR studies.     

Redox potentials of algal and cyanobacterial flavodoxins.

The redox potentials of flavodoxins from the cyanobacteria Synechococcus PCC 6301 (formerly Anacystis nidulans) and Nostoc strain MAC, and from the red alga Chondrus crispus, were determined by potentiometric titration. For the oxidized-semiquinone interconversion the potentials at pH 7.0 of the three flavodoxins were between -210 and -235 mV, and these were pH-dependent over the range pH 6.9-8.2. For the semiquinone-reduced interconversion the potentials of the cyanobacterial flavodoxins were close to -414 mV, and that for the algal flavodoxin, -370 mV, is the highest reported in this group of flavoproteins.     

Kinetic properties of F0F1-ATPases. Theoretical predictions from alternating-site models.

We present an analysis of models based on current structural concepts of the F0F1 synthases, accounting for coupling between proton transport and ATP synthesis. It is assumed that each of the three alpha beta-subunits of the synthase can exist in three different conformational states E, Eo and E*. Proton translocation is coupled to cyclic interconversion of the conformations of the alpha beta-subunits. The conformational changes of these subunits are assumed to be coordinated so that all three interconvert simultaneously, in a rate-limiting transition. Binding and release of the ligands ATP, ADP, Pi, and protons are assumed to be equilibrium steps. In one family of models, interconversion of the alpha beta-subunits of F1 is coupled to the translocation event in F0 acting as a proton carrier. In a second family of models, protons combine with F0F1 and are translocated during the interconversion step in a chemiport. Kinetic tests involving the mutual effects of [ATP], [ADP], H+', and H+" are described, allowing us to make a distinction between the different models and submodels.     

Interaction of hypohalous acids and heme peroxidases with unsaturated phosphatidylcholines

The formation of chlorohydrins, bromohydrins, and iodohydrins from 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) by the myeloperoxidase-hydrogen peroxide-halide system was evaluated by means of matrix-assisted laser desorption/ionisation time-of-flight (MALDI-TOF) mass spectrometry. This approach allows to detect different kinds of the halogenation reaction even in one mass spectrum. Using a mixture of Cl-, Br-, I-, and SCN- at physiological concentrations, a bromination of POPC dominates by the MPO-hydrogen peroxide-halide system. Hypothiocyanite does apparently not react with the double bond of POPC, but increasing amounts of SCN- cause a decrease of the bromohydrin peaks. An interconversion between different hypohalous acids produced by the myeloperoxidase-hydrogen peroxide-halide system determines the pattern of halogenohydrins in POPC. Especially, hypochlorous acid is able to oxidise Br- to hypobromous acid.     

Biochemical and developmental characterization of multiple forms of catalase in tobacco leaves

Leaf extracts of both Nicotiana tabacum and Nicotiana sylvestris contain multiple forms of catalase (H₂O₂:H₂O₂ oxidoreductase, EC 1.11.1.6) which are separable at different pH values by chromatofocusing columns. Marked changes in distribution of these catalases occur during seedling development and leaf maturation. The form of catalase eluting first (peak 1) was predominant during early seedling growth and present at all stages of development. Two more acidic forms (peaks 2 and 3) appeared later and comprised 29% of the total activity by 11 days postgermination. Mature leaves of N. tabacum contained peak 1 catalase, but peaks 2 and 3 represented 62% of the total activity. No interconversion of peaks 1, 2, and 3 was detected. The three forms of catalase differed in thermal stability with peak 1 > peak 2 peak 3. For N. sylvestris, t_½ at 55°C was 31.5 and 3.0 min for peaks 1 and 3, respectively, and for N. tabacum, t_½ was 41.5 and 3.2 min, respectively. All forms of catalase in tobacco show peroxidatic (measured as ethanol to acetaldehyde conversion) as well as catalatic activities. However, for both Nicotiana species the ratio peroxidatic/catalatic activity is at least 30-fold higher in peak 3 than in peaks 1 and 2. Chromatofocusing of extracts from spinach leaves separated at least four peaks of catalase activity, one of which had a 10-fold higher ratio of peroxidatic/catalatic activity than the others. Short-term growth (5 days) of tobacco seedlings under atmospheric conditions suppressing photorespiration (1% CO₂/21% O₂) reduced total catalase activity and caused a decline in peak 1 catalase and a substantial increase in the activity of peaks 2 and 3 relative to air-grown seedlings at the same stage.     

Ligand binding to heme proteins. VI. Interconversion of taxonomic substates in carbonmonoxymyoglobin.

The kinetic properties of the three taxonomic A substates of sperm whale carbonmonoxy myoglobin in 75% glycerol/buffer are studied by flash photolysis with monitoring in the infrared stretch bands of bound CO at nu(A0) approximately 1967 cm-1, nu(A1) approximately 1947 cm-1, and nu(A3) approximately 1929 cm-1 between 60 and 300 K. Below 160 K the photodissociated CO rebinds from the heme pocket, no interconversion among the A substates is observed, and rebinding in each A substate is nonexponential in time and described by a different temperature-independent distribution of enthalpy barriers with a different preexponential. Measurements in the electronic bands, e.g., the Soret, contain contributions of all three A substates and can, therefore, be only approximately modeled with a single enthalpy distribution and a single preexponential. The bond formation step at the heme is fastest for the A0 substate, intermediate for the A1 substate, and slowest for A3. Rebinding between 200 and 300 K displays several processes, including geminate rebinding, rebinding after ligand escape to the solvent, and interconversion among the A substates. Different kinetics are measured in each of the A bands for times shorter than the characteristic time of fluctuations among the A substates. At longer times, fluctuational averaging yields the same kinetics in all three A substates. The interconversion rates between A1 and A3 are determined from the time when the scaled kinetic traces of the two substates merge. Fluctuations between A1 and A3 are much faster than those between A0 and either A1 or A3, so A1 and A3 appear as one kinetic species in the exchange with A0. The maximum-entropy method is used to extract the distribution of rate coefficients for the interconversion process A0 <--> A1 + A3 from the flash photolysis data. The temperature dependencies of the A substate interconversion processes are fitted with a non-Arrhenius expression similar to that used to describe relaxation processes in glasses. At 300 K the interconversion time for A0 <--> A1 + A3 is 10 microseconds, and extrapolation yields approximately 1 ns for A1 <--> A3. The pronounced kinetic differences imply different structural rearrangements. Crystallographic data support this conclusion: They show that formation of the A0 substate involves a major change of the protein structure; the distal histidine rotates about the C(alpha)-C(beta) bond, and its imidazole sidechain swings out of the heme pocket into the solvent, whereas it remains in the heme pocket in the A1 <--> A3 interconversion. The fast A1 <--> A3 exchange is inconsistent with structural models that involve differences in the protonation between A1 and A3.     

Temperature, pH, and solvent isotope effects on cytochrome c peroxidase mutant N82A studied by proton NMR

The mutant of baker's yeast cytochrome c peroxidase-CN with Ala82 in place of Asn82, [N82A]CcPCN, exhibits a complex solution behavior featuring dynamic interconversion among three enzyme forms that so far have only been detected by NMR spectroscopy. Proton NMR studies of [N82A]CcPCN reveal resonances from each of the three enzyme forms and show that the interconversion among forms is controlled by the pH, temperature, and isotope composition (H₂O vs. D₂O) of the buffer solution. No evidence for a key hydrogen bond between His52 and heme-coordinated cyanide is found in any of the enzyme forms, indicating that disruption of the extensive distal hydrogen bonding network is the source of this phenomenon.     

Conformational and kinetic studies of synthetic polypeptides by NMR

The α-helix–coil transition of poly-L -leucine, poly-L -alanine and poly-L -methionine in chloroform–trifluoroacetic acid system was studied by nuclear magnetic resonance (NMR) and optical rotatory dispersion (ORD). The kinetics of the hydrogen–deuterium exchange in the peptide was also followed in these polymers by means of NMR. Two types of the NMR spectra and the hydrogen–deuterium exchange reaction were found, corresponding to the high and low molecular weight polypeptides. In high molecular weights, the NH and α-CH resonance lines gave single peaks and the hydrogen–deuterium exchange was expressed as a single first order reaction. In low molecular weights, the NH and α-CH lines were separated into two peaks, corresponding to helical and random-coiled states, respectively, and the exchange react ion was expressed as super-position of a very rapid exchange reaction in the random-coiled part and another slow exchange reaction of the first order in the helical part. These results suggest that the helix–coil interconversion of low molecular weight polypeptides has a longer relaxation time (? 4.5 × 10^?3 sec) than that of high molecular weight polypeptides.     

A novel D-leucine-containing Conus peptide: diverse conformational dynamics in the contryphan family.

A Conus peptide family (the contryphans) is noteworthy because of the presence of a post-translationally modified D-amino acid in all members of the family. A new contryphan peptide, Leu-contryphan-P, was isolated from the venom of Conus purpurascens; the sequence of this peptide is: Gly-Cys-Val-D-Leu-Leu-Pro-Trp-Cys-OH. This is the first known occurrence of D-leucine in a Conus peptide. The discovery of Leu-contryphan-P suggests that there may be branches of the contryphan peptide family that diverge much more in sequence than previously anticipated. Several natural contryphans provide dramatic examples of interconversion between multiple conformational states in small constrained peptides. The contryphans that have 4-trans-hydroxyproline and D-tryptophan in positions 3 and 4, respectively, exhibit two peaks under reverse-phase HPLC conditions, indicating interconversion between two discrete conformations. However, [L-Trp4]contryphan-Sm (with L-Trp substituted for D-Trp) exhibits a single, broad peak that elutes later than the natural peptide, suggesting that D-Trp stabilizes a conformation in which hydrophobic residues are buried. Leucontryphan-P which has valine and D-leucine instead of 4-trans-hydroxyproline and D-tryptophan shows only a single peak that elutes much later than the other contryphans.     

Role of de novo protein synthesis in the interconversion of glucose transport systems in the yeast Pichia ohmeri

Glucose-repressed cells of the yeast Pichia ohmeri IGC 2879 transported glucose by facilitated diffusion. Derepression led to the formation of a glucose/proton symport and the simultaneous reduction of the facilitated diffusion capacity by about 70%. Cycloheximide prevented this interconversion indicating its dependence on de novo protein synthesis (proteosynthetic interconversion). In buffer with 2% glucose the glucose/proton symport suffered irreversible inactivation while the facilitated diffusion system was simultaneously restored. This reverse interconversion process did not require de novo protein synthesis as indicated by its lack of sensitivity to cycloheximide (degradative interconversion). Thus the glucose/proton symport system appeared to consist of about 70% of the facilitated diffusion proteins turned silent through association with additional protein(s) the latter being sensitive to glucose-induced repression and glucose-induced inactivation.     

Secondary metabolite profiling of the model legume <Emphasis Type="Italic">Lotus japonicus</Emphasis> during its symbiotic interaction with <Emphasis Type="Italic">Mesorhizobium loti</Emphasis>

Plant secondary metabolites, particularly flavonoids, are key components in the early stages of nitrogen-fixing symbiosis. Despite their importance, the endogenous secondary metabolites involved in symbiosis have not yet been identified in the model legume Lotus japonicus. We therefore determined changes in the secondary metabolic profile of Lotus japonicus roots in response to its symbiont. Analysis of the root secondary metabolite profiles 1 week after inoculation with Mesorhizobium loti revealed quantitative changes in the level of 14 phenolic peaks when compared with non-inoculated control plants. These changes affected compounds from most phenolic classes, possibly resulting from interconversion between classes since the total phenolic level remained constant. In addition, the use of 2 M. loti strains differing only in their capacity to synthesise Nod factor revealed that, although Nod factor signalling induced accumulation of a specific subset of 4 phenolic peaks, most changes were induced in response to both rhizobial strains.