Phospholipid phase transitions in homogeneous nanometer scale bilayer discs.
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Nanoscale protein supported phospholipid bilayer discs, or Nanodiscs, were produced for the purpose of studying the phase transition behavior of the incorporated lipids. Nanodiscs and vesicles were prepared with two phospholipids, dipalmitoyl phosphatidylcholine and dimyristoyl phosphatidylcholine, and the phase transition of each was analyzed using laurdan fluorescence and differential scanning calorimetry. Laurdan is a fluorescent probe sensitive to the increase of hydration in the lipid bilayer that accompanies the gel to liquid crystalline phase transition. The emission intensity profile can be used to derive the generalized polarization, a measure of the relative amount of each phase present. Differential scanning calorimetry was used to further quantitate the phase transition of the phospholipids. Both methods revealed broader transitions for the lipids in Nanodiscs compared to those in vesicles. Also, the transition midpoint was shifted 3-4 degrees C higher for both lipids when incorporated into Nanodiscs. These findings are explained by a loss of cooperativity in the lipids of Nanodiscs which is attributable to the small size of the Nanodiscs as well as the interaction of boundary lipids with the protein encircling the discs. The broad transition of the Nanodisc lipid bilayer better mimics the phase behavior of cellular membranes than vesicles, making Nanodiscs a 'native-like' lipid environment in which to study membrane associated proteins. (+info)
Divalent cations increase lipid order in erythrocytes and susceptibility to secretory phospholipase A2.
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Elevated concentrations of intracellular calcium in erythrocytes increase membrane order and susceptibility to secretory phospholipase A2. We hypothesize that calcium aids the formation of domains of ordered lipids within erythrocyte membranes by interacting directly with the inner leaflet of the cell membrane. The interface of these domains with regions of more fluid lipids may create an environment with weakened neighbor-neighbor interactions that would facilitate phospholipid migration into the active site of bound secretory phospholipase A2. This hypothesis was investigated by determining the effects of seven other divalent ions on erythrocyte membrane properties. Changes in membrane order were assessed with steady-state fluorescence spectroscopy and two-photon microscopy with an environment-sensitive probe, laurdan. Each ion increased apparent membrane order in model membranes and in erythrocytes when introduced with an ionophore, suggesting that direct binding to the inner face of the membrane accounts for the effects of calcium on membrane fluidity. Furthermore, the degree to which ions affected membrane properties correlated with the ionic radius and electronegativity of the ions. Lastly, erythrocytes became more susceptible to enzyme hydrolysis in the presence of elevated intracellular levels of nickel and manganese, but not magnesium. These differences appeared related to the ability of the ions to induce a transition in erythrocyte shape. (+info)
Immediate response of the DnaK molecular chaperone system to heat shock.
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The familiar heat shock response in cells comprises the enhanced expression of molecular chaperones. In recent experiments with the Hsp70 system of Escherichia coli, the co-chaperone GrpE has been found to undergo a reversible thermal transition in the physiological temperature range. Here, we tested whether this thermal transition is of functional significance in the complete DnaK/DnaJ/GrpE chaperone system. We found that a mere increase in temperature resulted in a higher fraction of fluorescence-labeled peptides being sequestered by DnaK. This direct adaptation of the DnaK/DnaJ/GrpE chaperone system to heat shock conditions may serve to bridge the time lag of enhanced chaperone expression. (+info)
cis-Effect of DnaJ on DnaK in ternary complexes with chimeric DnaK/DnaJ-binding peptides.
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Chimeric peptides, comprising a DnaK-binding sequence of L-amino acid residues (motif k) and an exclusive DnaJ-binding sequence of D-amino acid residues (motif j) connected through a 22-residue linker, were examined as minisubstrates for the DnaK chaperone system. The DnaJ-stimulated ATPase activity of DnaK was three times higher in the presence of the chimeric peptides pjk or pkj than in the simultaneous presence of the corresponding single-motif peptides ala-p5 (k motif) plus D-p5 (j motif). Apparently, pjk and pkj mimic unfolded proteins by forming ternary (ATP x DnaK) x peptide x DnaJ complexes which favor cis-interaction of DnaJ with DnaK. Consistent with this interpretation, the specific stimulatory effect of the chimeric peptides was abolished by either single-motif peptide in excess. (+info)
Acrylodan-conjugated cysteine side chains reveal conformational state and ligand site locations of the acetylcholine-binding protein.
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We undertook cysteine substitution mutagenesis and fluorophore conjugation at selected residue positions to map sites of ligand binding and changes in solvent exposure of the acetylcholine-binding protein from Lymnaea stagnalis, a nicotinic receptor surrogate. Acrylodan fluorescence emission is highly sensitive to its local environment, and when bound to protein, exhibits changes in both intensity and emission wavelength that are reflected in the degree of solvent exclusion and the effective dielectric constant of the environment of the fluorophore. Hence, cysteine mutants were generated based on the acetylcholine-binding protein crystal structure and predicted ligand binding sites, and fluorescence parameters were assayed on the acrylodan-conjugated proteins. This approach allows one to analyze the environment around the conjugated fluorophore side chain and the changes induced by bound ligand. Introduction of an acrylodan-cysteine conjugate at position 178 yields a large blue shift with alpha-bungarotoxin association, whereas the agonists and alkaloid antagonists induce red shifts reflecting solvent exposure at this position. Such residue-selective changes in fluorescence parameters suggest that certain ligands can induce distinct conformational states of the binding protein, and that mutually exclusive binding results from disparate portals of entry to and orientations of the bound alpha-toxin and smaller acetylcholine congeners at the binding pocket. Labeling at other residue positions around the predicted binding pocket also reveals distinctive spectral changes for alpha-bungarotoxin, agonists, and alkaloid antagonists. (+info)
Novel sensors of the regulatory switch on the regulatory light chain of smooth muscle Myosin.
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Smooth muscle myosin can be switched on by phosphorylation of Ser-19 of the regulatory light chain. Our previous photocross-linking results suggested that an element of the structural mechanism for the regulatory switch was a phosphorylation-induced motion of the regulatory light chain N terminus (Wahlstrom, J. L., Randall, M. A., Jr., Lawson, J. D., Lyons, D. E., Siems, W. F., Crouch, G. J., Barr, R., Facemyer, K. C., and Cremo, C. R. (2003) J. Biol. Chem. 278, 5123-5131). Here we used three different approaches to test this notion, which are reactivity of cysteine thiols, pyrene and acrylodan spectral analysis, and pyrene fluorescence quenching. All methods detected significant differences between the unphosphorylated and phosphorylated regulatory light chain N termini in heavy meromyosin, a double-headed subfragment with an intact regulatory switch. These differences were not observed for subfragment-1, a single-headed, unregulated subfragment. In the presence of either ATP or ADP, phosphorylation increased the solvent exposure and decreased the polarity of the environment about position 23 of the regulatory light chain of heavy meromyosin. These phosphorylation-induced structural changes were not as evident in the absence of nucleotides. Nucleotide binding to unphosphorylated heavy meromyosin caused a decrease in exposure and an increase in polarity of the N terminus, whereas the effects of nucleotide on phosphorylated heavy meromyosin were the opposite. We showed a direct correlation between the kinetics of nucleotide binding/turnover and the conformational change reported by acrylodan at position 23 of the regulatory light chain. Acrylodan-A23C also reports the heads up (extended) to flexed (folded) transition in unphosphorylated heavy meromyosin. This is the first demonstration of direct coupling of nucleotide binding to conformational changes in the N terminus of the regulatory light chain. (+info)
Bladder tumours in rubber workers: a factory study 1946-1995.
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BACKGROUND: Prior to December 1949, some British rubber industry workers were inadvertently exposed to the human bladder carcinogen beta-naphthylamine, which was present as a contaminant (at 0.25%) in antioxidants used in manufacturing. This study follows a composite cohort of 6450 men employed at a large tyre factory either during the 'at-risk' period or just after it. METHODS: A group of 2090 at-risk men (employed 1945-1949) and 3038 men, first employed only after January 1950, when the carcinogen had been removed, were followed for their bladder cancer morbidity and mortality experiences. RESULTS: Fifty-eight tumours were registered for those at risk, whereas only 33.9 were expected at national standardized registration rates [SRRN = 171 and 95% confidence interval (CI) = 130-221]. Thirty-nine bladder tumours were reported for the post-1950 intake, whereas 38.3 were expected (SRRN = 102 and 95% CI = 72-139). The use of mortality data did not reveal any underlying hazard because 12 of the 58 at-risk workers with tumours were still alive at the study end date. In only 16 instances was bladder cancer actually certified as the underlying cause of death. Plotting cases by their location of work on a factory plan assisted the interpretation. CONCLUSIONS: A statistically significant elevated risk of bladder cancer for the exposed workforce was evident, but this reversed when the carcinogen was removed from processing in October 1949. The use of morbidity (incidence) data in long-term studies of occupational bladder cancer should be the required methodology if the hazard and risk are not to be underestimated. (+info)
Site-specific chemical modification of interleukin-1 beta by acrylodan at cysteine 8 and lysine 103.
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Acrylodan, which normally modifies cysteine residues, was employed to derivatize recombinant interleukin-1 beta (rIL-1 beta) under native conditions, using a reagent:protein ratio of 3:1. Two major covalent protein/acrylodan adducts were generated and subsequently purified by DEAE TSK 5PW ion exchange chromatography. Peptide mapping and mass spectrometry were used to locate the probe on the modified proteins. Both modified proteins carried one molecule of acrylodan each, one at Cys-8 and the other at Lys-103. Neither Cys-71 nor any of the other 13 lysine residues of rIL-1 beta was modified. Cysteine 71 is inaccessible to acrylodan, but the unusual specificity for Lys-103 could be caused by the location of that residue at the bottom of a hydrophobic pocket which might specifically bind the reagent. No double-labeled protein was detected, indicating that the introduction of the label at either site interferes with the labeling at the other. Both acrylodan-modified proteins exhibited bioactivity in the thymocyte proliferation assay at a level equivalent to that of the unmodified control protein (1.7 x 10(7) units/mg), which shows that the modification of either the Cys-8 or Lys-103 position with acrylodan does not interfere with the cellular bioactivities of the respective proteins. Furthermore, receptor binding assays yielded a Kd = 32.0 +/- 4.8 pM for the Lys-103-labeled protein, Kd = 69.5 +/- 12.7 pM for the unmodified protein, and Kd = 75.0 +/- 11.6 pM for the Cys-8-labeled protein. Thus, Cys-8 or Lys-103 modification of rIL-1 beta by acrylodan also does not interfere with the ability of the molecule to bind to its receptor. The slightly higher affinity of the Lys-103-labeled protein for the receptor suggests that the positive charge on this residue in the native molecule may interfere with IL-1 receptor binding. The two fluorescent labeled IL-1 proteins described herein should provide interesting probes for the study of IL-1/IL-1 receptor interactions. (+info)