Resolution of fluorescence intensity decays of the two tryptophan residues in glutamine-binding protein from Escherichia coli using single tryptophan mutants.

Time correlated single photon counting measurements of tryptophan (Trp) fluorescence intensity decay and other spectroscopic studies were performed on glutamine-binding protein (GlnBP) from Escherichia coli. Using site-specifically mutated forms of the protein in which tyrosine (Tyr) and phenylalanine (Phe) substitute for the Trp residues at positions 32 and 220, we have examined whether wild-type (Wtyp) intensity decay components may be assigned to specific Trp residues. Results indicate that: (a) two exponential intensity decay components are recovered from the Wtyp protein (6.16 ns, 0.46 ns); (b) the long decay component arises from Trp-220 and comprises greater than 90% of the total fluorescence emission; (c) the short component arises from Trp-32 and is highly quenched; (d) all four single-Trp mutants exhibit multiexponential intensity decays, yet equimolar mixtures of two single-Trp mutants yield only two decay components which are virtually indistinguishable from the Wtyp protein; (e) the recovery of additional components in protein mixtures is obscured by statistical noise inherent in the technique of photon counting; (f) various spectroscopic measurements suggest that Trp-Trp interactions occur in the Wtyp protein, but the Wtyp intensity decay may be closely approximated by a linear combination of intensity decays from single-Trp mutants; and (g) inferences derived independently from fluorescence and NMR spectroscopy which pertain to the presence of Trp-Trp interactions and the relative solvent exposure of the two Trp residues are in agreement.     

CYP83b1 is the oxime-metabolizing enzyme in the glucosinolate pathway in Arabidopsis

CYP83B1 from Arabidopsis thaliana has been identified as the oxime-metabolizing enzyme in the biosynthetic pathway of glucosinolates. Biosynthetically active microsomes isolated from Sinapis alba converted p-hydroxyphenylacetaldoxime and cysteine into S-alkylated p-hydroxyphenylacetothiohydroximate, S-(p-hydroxyphenylacetohydroximoyl)-l-cysteine, the next proposed intermediate in the glucosinolate pathway. The production was shown to be dependent on a cytochrome P450 monooxygenase. We searched the genome of A. thaliana for homologues of CYP71E1 (P450ox), the only known oxime-metabolizing enzyme in the biosynthetic pathway of the evolutionarily related cyanogenic glucosides. By a combined use of bioinformatics, published expression data, and knock-out phenotypes, we identified the cytochrome P450 CYP83B1 as the oxime-metabolizing enzyme in the glucosinolate pathway as evidenced by characterization of the recombinant protein expressed in Escherichia coli. The data are consistent with the hypothesis that the oxime-metabolizing enzyme in the cyanogenic pathway (P450ox) was mutated into a "P450mox" that converted oximes into toxic compounds that the plant detoxified into glucosinolates.     

Synchronized conformational fluctuations and binding site desolvation during molecular recognition

Binding site desolvation is a poorly understood prerequisite to ligand binding. Although structural fluctuations may be expected to have an important role, little is known about which fluctuations are important or the mechanism by which they promote desolvation. This investigation examines whether and how specific structural fluctuations contribute to desolvation of the ligand binding site in glycopeptide antibiotics. Backbone peptide group rotations in vancomycin, known to occur by experimental observation, were examined in this work with a two-dimensional adaptive umbrella sampling molecular dynamics simulation technique. Results indicate that energetic barriers to rotation are relatively small for two of the peptide groups intimately involved in ligand recognition. When they occur, these rotations strip water molecules away from key hydrogen bond donors and simultaneously cause significant distortions in the macrocyclic rings of the antibiotic that force water into and out of the binding site. Both events are intricately synchronized on the molecular level and have consequences that are clearly necessary to prepare the binding site for receiving a ligand. These results suggest that previously reported observations concerning structural dynamics and binding kinetics in these compounds are mechanistically linked, and they illustrate a heretofore unrecognized degree of preorganization, complexity, and synchronization that may be involved in specific molecular recognition. They also suggest that strategies for increasing antibiotic affinity through covalent dimerization may be counterproductive.     

Phytoplasmas and their interactions with hosts

Phytoplasmas are bacteria without cell walls and are responsible for plant diseases that have large economic impacts. Knowledge of their biology is limited because they are uncultivable and experimentally inaccessible in their hosts. It is a mystery how these bacteria use the sugar-rich phloem sap in which they live and how they interact with the host. This makes it difficult to develop means to control them. Recently, the full genomes of two phytoplasmas have been sequenced, allowing new insights into their requirements. Phytoplasmas contain a minimal genome and lack genes coding for ATP synthases and sugar uptake and use, making them dependent on their host. This dependency can be exploited to elucidate the particular physiology of the phloem.     

Molecular dynamics of tryptophan in ribonuclease-T1. II. Correlations with fluorescence.

The interactions of tryptophan-59 (TRP-59) and its protein environment in ribonuclease-T1 (RNAse-T1) were examined in a 50-ps molecular dynamics simulation. The simulation used was previously shown to demonstrate a fluorescence anisotropy decay that closely agreed with the experimentally determined limiting anisotropy for RNAse-T1 (Axelsen, P. H., C. Haydock, and F. G. Prendergast. 1988. Biophys. J. 54:249-258). Further characterization of TRP-59 side chain dynamics and its protein environment has now been completed and correlated to other photophysical properties of this protein. Angular fluctuations of the side chain occur at rates of 1-10 cycles/ps and are limited to +/- 0.3 radians in all directions. Side chain motions are primarily limited by nonpolar collisions, although most side chain atoms have some collisional contact with polar atoms in the adjacent protein matrix or water. The steric relationship between PRO-39 and TRP-59 changes abruptly at 16 ps into the simulation. Two types of interaction with water are observed. First, a structural water appears to H-bond with the greater than N-H group of TRP-59. Second, water frequently contacts the six-atom ring. The electrostatic field experienced by the TRP-59 rings appears to be relatively constant and featureless regardless of ring orientation. We make the following interferences from our data: The fluorescent emission of TRP-59 may be red-shifted relative to TRP in nonpolar solvents either as a result of specific interactions with the structural water or relaxations of proximal bulk water and polar protein moieties. The quenching efficiency of polar interactions with TRP-59 must be extremely low given their frequency and the high quantum yield of RNAse-T1. This low efficiency may be due to restricted and unfavorable interaction geometries. PRO-39 is located near two titratable HIS residues in RNAse-T1 and may be involved in pH-dependent fluorescence phenomena by virtue of a metastable interaction with TRP-59. The interaction of bulk water with TRP-59 illustrates features of the gated transition state model for transient exposure to exogenously added collisional quenching agents. The restrictive environment of TRP-59 suggests that extrinsic quenching can only occur via interactions with the edge of the indole six-atom ring and that the efficiency of a quencher in a protein environment is likely to be a function of molecular symmetry.     

Molecular dynamics of tryptophan in ribonuclease-T1. I. Simulation strategies and fluorescence anisotropy decay.

Molecular dynamics simulations of Ribonuclease-T1 (RNAse-T1) were performed using x-ray crystal coordinates for the enzyme and various simulation strategies. From each of the simulations, a predicted fluorescence anisotropy decay for the single-tryptophan residue was derived and compared with experimental values for the limiting anisotropy of this protein. Simulations conducted in vacuo demonstrated large displacements among some of the residues adjacent to the tryptophan side chain. As a consequence, the ring system rotates relatively unhindered through an angle far in excess of that implied by experimental data. In contrast, the explicit simulation of solvent within a stochastic boundary led to excellent agreement between simulation and experiment. In the case of RNAse-T1, the experimentally-determined limiting anisotropy is useful as a criterion of simulation accuracy in the vicinity of the tryptophan side chain.     

END‐OF‐LIFE CARE IN THE 21st CENTURY: ADVANCE DIRECTIVES IN UNIVERSAL RIGHTS DISCOURSE

This article explores universal normative bases that could help to shape a workable legal construct that would facilitate a global use of advance directives. Although I believe that advance directives are of universal character, my primary aim in approaching this issue is to remain realistic. I will make three claims. First, I will argue that the principles of autonomy, dignity and informed consent, embodied in the Oviedo Convention and the UNESCO Declaration on Bioethics and Human Rights, could arguably be regarded as universal bases for the global use of advance directives. Second, I will demonstrate that, despite the apparent consensus of ethical authorities in support of their global use, it is unlikely, for the time being, that such consensus could lead to unqualified legal recognition of advance directives, because of different understandings of the nature of the international rules, meanings of autonomy and dignity which are context‐specific and culture‐specific, and existing imperfections that make advance directives either unworkable or hardly applicable in practice. The third claim suggests that the fact that the concept of the advance directive is not universally shared does not mean that it should not become so, but never as the only option in managing incompetent patients. A way to proceed is to prioritize work on developing higher standards in managing incompetent patients and on progressing towards the realization of universal human rights in the sphere of bioethics, by advocating a universal, legally binding international convention that would outlaw human rights violations in end‐of‐life decision‐making.     

Membrane-mediated amyloidogenesis and the promotion of oxidative lipid damage by amyloid beta proteins

Evidence of oxidative stress and the accumulation of fibrillar amyloid beta proteins (Abeta) in senile plaques throughout the cerebral cortex are consistent features in the pathology of Alzheimer disease. To define a mechanistic link between these two processes, various aspects of the relationship between oxidative lipid membrane damage and amyloidogenesis were characterized by chemical and physical techniques. Earlier studies of this relationship demonstrated that oxidatively damaged synthetic lipid membranes promoted amyloidogenesis. The studies reported herein specify that 4-hydroxy-2-nonenal (HNE) is produced in both synthetic lipids and human brain lipid extracts by oxidative lipid damage and that it can account for accelerated amyloidogenesis. Abeta promotes the copper-mediated generation of HNE from polyunsaturated lipids, and in turn, HNE covalently modifies the histidine side chains of Abeta. HNE-modified Abeta have an increased affinity for lipid membranes and an increased tendency to aggregate into amyloid fibrils. Thus, the prooxidant activity of Abeta leads to its own covalent modification and to accelerated amyloidogenesis. These results illustrate how lipid membranes may be involved in templating the pathological misfolding of Abeta, and they suggest a possible chemical mechanism linking oxidative stress with amyloid formation.     

Trichoderma spp. and Bacillus spp. as growth promoters in maize (Zea mays L.)

Microbes that are beneficial to plants are used to enhance the crop growth, yield and are alternatives to chemical fertilizers. Trichoderma and Bacillus are the predominant plant growth-promoting fungi and bacteria. The objective of this study was select, characterize, and evaluate isolates of Trichoderma spp. and Bacillus spp. native from the northern region of Sinaloa, Mexico, and assess their effect on growth promotion in maize (Zea mays L.). In greenhouse conditions, four Trichoderma isolates and twenty Bacillus isolates, as well as two controls, were tested in a completely randomized design with three replicates. We selected the two best strains of Trichoderma and Bacillus: TB = Trichoderma asperellum, TF = Trichoderma virens, B14 = Bacillus cereus sensu lato and B17 = Bacillus cereus, which were evaluated in the field in a completely randomized blocks in factorial arrangement design with three replicates applying different rates of nitrogen fertilizer (0, 150 kg N/ha, and 300 kg N/ha). Treatments 5 (B17 = B. cereus) and 11 (TF = T. virens) both fertilized with 150 kg N/ha showed similar yields and they did not reveal significant differences from the treatments fertilized with 300 kg N/ha. This indicated that treatment 5 (B17= B. cereus with 150 kg N/ha) and treatment 11 (TF= T. virens with 150 kg N/ha) were efficient as growth promoters, by not showing significant differences in root volume and dry weight of foliage. The results indicated a reduction of 50% in the rate of nitrogen to fertilizer required for maize (Zea mays L.) crops. These microorganisms Trichoderma and Bacillus could be an alternative to reduce the use of chemical fertilizers in maize.     

The E46K mutation in alpha-synuclein increases amyloid fibril formation

The identification of a novel mutation (E46K) in one of the KTKEGV-type repeats in the amino-terminal region of alpha-synuclein suggests that this region and, more specifically, Glu residues in the repeats may be important in regulating the ability of alpha-synuclein to polymerize into amyloid fibrils. It was demonstrated that the E46K mutation increased the propensity of alpha-synuclein to fibrillize, but this effect was less than that of the A53T mutation. The substitution of Glu(46) for an Ala also increased the assembly of alpha-synuclein, but the polymers formed can have different ultrastructures, further indicating that this amino acid position has a significant effect on the assembly process. The effect of residue Glu(83) in the sixth repeat of alpha-synuclein, which lies closest to the amino acid stretch critical for filament assembly, was also studied. Mutation of Glu(83) to a Lys or Ala increased polymerization but perturbed some of the properties of mature amyloid. These results demonstrated that some of the Glu residues within the repeats can have significant effects on modulating the assembly of alpha-synuclein to form amyloid fibrils. The greater effect of the A53T mutation, even when compared with what may be predicted to be a more dramatic mutation such as E46K, underscores the importance of protein microenvironment in affecting protein structure. Moreover, the relative effects of the A53T and E46K mutations are consistent with the age of onset of disease. These findings support the notion that aberrant alpha-synuclein polymerization resulting in the formation of pathological inclusions can lead to disease.