Mink IgG-allotypes and Aleutian disease

IgG polymorphism (allotypes H3, H4, H6 and H8 of constant region of the gamma-chain) was investigated in healthy and affected with Aleutian disease (AD) minks from two Siberian and one Danish populations. In all three populations, the expression of H3 and H4 allotypes was strongly associated with AD. Among the AD minks the frequency of H6, H8 phenotype was found to be decreased, whereas the frequency of H3, H4, H6, H8 phenotype was significantly increased. At the same time, the populational distribution of the rest phenotypes was similar among healthy and AD minks. The H3, H4, H6, H8 minks showed the highest pathomorphological characteristics of AD. Based on the data concerning mink H3 and H4, and human Gm allotypes, their role as possible genetic markers for hereditary susceptibility to distinct disease is discussed.     

Carboxyphosphonoenolpyruvate phosphonomutase, a novel enzyme catalyzing C-P bond formation.

An enzyme catalyzing the formation of an unusual C-P bond that is involved in the biosynthesis of the antibiotic bialaphos (BA) was isolated from the cell extract of a mutant (NP71) of Streptomyces hygroscopicus SF1293. This enzyme, carboxyphosphonoenolpyruvate (CPEP) phosphonomutase, was first identified as a protein lacking in a mutant (NP213) defective in one of the steps in the pathway to BA. The first 30 residues of the amino terminus of this protein were identical to those predicted by the nucleotide sequence of the gene that restored BA production to NP213. The substrate of the enzyme, a P-carboxylated derivative of phosphoenolpyruvate named CPEP, was also isolated from the broth filtrate of NP213 as a new biosynthetic intermediate of BA. CPEP phosphonomutase catalyzes the rearrangement of the carboxyphosphono group of CPEP to form the C-P bond of phosphinopyruvate.     

Very high proportion of disaturated molecular species in rat platelet diacyl-glycerophosphocholine: involvement of CoA-dependent transacylation reactions

The molecular species composition of rat platelet diacyl-glycerophosphocholine (GPC) was investigated by reverse-phase HPLC and by mass spectrometry. The two methods gave the same very high proportion of fully saturated phospholipids, the 16:0-16:0 and 16:0-18:0 species representing together about 40% of the overall molecular species. [14C]Palmitoyllyso-GPC was found to be acylated by resting platelets in equal amounts into 16:0-16:0 and into 16:0-20:4 species. The acylation rate of this lysophospholipid was increased by 3-fold and 14-fold when platelets were stimulated for 10 min with thrombin and the ionophore A23187, respectively. Essentially the same two molecular species were synthesized upon stimulation but with a higher preference for arachidonate than for palmitate. We investigated the mechanisms responsible for the incorporation of palmitate and arachidonate by examining the enzymatic acylation of [14C]palmitoyllyso-GPC by platelet homogenates. The percentage of the various molecular species formed when CoA, ATP, and Mg2+ were added excludes the CoA, ATP-dependent pathway as being involved in the acylation reactions previously observed. In the absence of ATP, CoA-independent transacylations appear to play a crucial role in the synthesis of the 16:0-20:4 species whereas the addition of CoA greatly favored dipalmitoyl-GPC synthesis. The involvement of CoA-dependent mechanisms in the synthesis of dipalmitoyl-GPC was demonstrated as follows: (i) the labeling in the sn-2 position of the dipalmitoyl-GPC synthesized in the presence of CoA was not modified when free unlabeled palmitic acid was added to the incubation medium and (ii) platelet homogenates were unable to esterify lysolecithin with added labeled palmitic acid in the presence of CoA only.     

Association of spin-labeled local anesthetics at the hydrophobic surface of acetylcholine receptor in native membranes from Torpedo marmorata

The interactions between a series of spin-labeled local anesthetic analogues and the nicotinic acetylcholine receptor (AChR) have been investigated by means of electron spin resonance (ESR) and fluorescence spectroscopy. The paramagnetic local anesthetic analogues quenched the intrinsic tryptophan fluorescence of AChR-rich membranes in an agonist-dependent manner, demonstrating a direct interaction with the AChR. The quenching efficiency was greater for the benzocaine than for the thioprocaine analogue. The protein was found to restrict directly the molecular motion of the spin-labeled analogues, as seen by the appearance of a highly anisotropic component in the ESR spectrum. The relative affinity of the population of local anesthetic probes which interacts directly with the integral protein of the AChR-rich membranes was calculated on the basis of relative association constants, Kr, determined by ESR. By comparison with the relative association constant for spin-labeled phospholipid, Kro, it was possible to differentiate between local anesthetic analogues interacting with high (Kr/Kro greater than 2), intermediate (Kr/Kro = 1.6-1.9), and low (Kr/Kro less than or equal to 1.3) specificity and to calculate the fraction of protein-associated probe in each case. Differences were observed in the presence of agonist (0.1 mM carbamylcholine) with some, but not all, of the spin-labeled derivatives. The role of the protonatable diethylammonium group in the specificity of the interaction of the procaine and thioprocaine analogues was investigated. Only in the uncharged form, or in the charged form at high ionic strength, was there a preferential association of these two local anesthetic analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ca2+ binding to calbindin D9k strongly affects backbone dynamics: measurements of exchange rates of individual amide protons using 1H NMR

One- and two-dimensional 1H NMR have been used to study the backbone dynamics in Ca2(+)-free (apo) and Ca2(+)-loaded (Ca2) calbindin D9k at pH 7.5 and 25 degrees C. Hydrogen exchange rates of all 71 backbone amide protons (NH's) have been measured for the Ca2 form by both a direct exchange-out experiment and another experiment that measures the transfer of saturation from water protons to amide protons. A large number of NH's are found to be highly protected against exchange with solvent protons. The results for the Ca2 form are related to solvent accessibility and hydrogen bonding obtained in molecular dynamics simulations of calcium-loaded calbindin. The correlation with these parameters is strong within the N-terminal half of calbindin, which is found to be more stable than the C-terminal half. The amide proton exchange in the apo form is much faster than in the Ca2 form and was studied in a series of experiments in which the exchange was quenched after different times by Ca2+ addition. This experiment is applicable to all amide hydrogens that exchange slowly in the Ca2 form. For these NH's the effects of Ca2+ removal span from a 10(2)-fold decrease to a 10(5)-fold increase of the exchange rate, and the average is a 220-fold increase. The effects on individual NH exchange rates show that the four alpha-helices are almost intact after calcium removal and that the changes in dynamics involve not only the Ca2(+)-binding region. Hydrogen bonds involving backbone NH's in the Ca2+ loops appear to be broken or weakened when calbindin releases Ca2+, whereas the beta-sheet between the Ca2+ loops is found to be present in both the Ca2 and apo forms. Large Ca2(+)-induced effects on NH exchange rates were measured for a few residues at alpha-helix ends far from the two Ca2(+)-binding sites. This may be the result of a change in interhelix angles (or the rate of interhelix angle fluctuations) on calcium binding.     

The chlorinating activity of human myeloperoxidase: high initial activity at neutral pH value and activation by electron donors

The steady-state activity of myeloperoxidase in the chlorination of monochlorodimedone at neutral pH was investigated. Using a stopped-flow spectrophotometer we were able to show that the enzymic activity at pH 7.2 rapidly declined in time. During the first 50-100 ms after addition of H2O2 to the enzyme, a turnover number of about 320 s-1 per haem was observed. However, this activity decreased rapidly to a value of about 25s-1 after 1 s. This shows that in classical steady-state activity measurements, the real activity of the enzyme at neutral pH is grossly underestimated. By following the transient spectra of myeloperoxidase during turnover it was shown that the decrease in activity was probably caused by the formation of an enzymically inactive form of the enzyme, Compound II. As demonstrated before (Bolscher, B.G.J.M., Zoutberg, G.R., Cuperus, R.A. and Wever, R. (1984) Biochim. Biophys. Acta 784, 189-191) reductants such as ascorbic acid and ferrocyanide convert Compound II, which accumulates during turnover, into active myeloperoxidase. Activity measurements in the presence of ascorbic acid showed, indeed, that the moderate enzymic activity was higher than in the absence of ascorbic acid. With 5-aminosalicylic acid present, however, the myeloperoxidase activity remained at a much higher level, namely about 150 s-1 per haem during the time interval from 100 ms to 5 s after mixing. From combined stopped-flow/rapid-scan experiments during turnover it became clear that in the presence of 5-aminosalicylic acid the initially formed Compound II was rapidly converted back to native enzyme. Presteady-state experiments showed that 5-aminosalicylic acid reacted with Compound II with a K2 of 3.2 x 10(5) M-1.s-1, whereas for ascorbic acid a K2 of 1.5 x 10(4) M-1.s-1 was measured at pH 7.2. In the presence of 5-aminosalicylic acid during the time interval in which the myeloperoxidase activity remained constant, a Km for H2O2 at pH 7.2 was determined of about 30 microM at 200 mM chloride. In the absence of reductants the same value was found during the first 100 ms after addition of H2O2 to the enzyme. The physiological consequences of these findings are discussed.     

Isolation, characterization, and expression in Escherichia coli of a cDNA encoding rat heme oxygenase-2

In a recent study (Cruse, I., and Maines, M.D. (1988) J. Biol. Chem. 263, 3348-3353), we reported the isolation of a small cDNA fragment encoding a portion of heme oxygenase-2 through immunological screening of a rat testis cDNA library in lambda gt11. We have now used this 274-base pair (bp) cDNA fragment as a hybridization probe for rescreening of the same library, and have thereby recovered a number of additional positive isolates. Of these, three candidates of approximately 900, 1100, and 1300 bp, respectively, were subsequently subcloned and sequenced. Although differing in length, the sequences of these clones were found to be otherwise identical. Moreover, the length of isolate 18B, 1284 bp, corresponded well with that of the single mRNA species (approximately 1300-1350 nucleotides) detected through Northern blot hybridization analysis of rat testis total and poly(A)+RNA. This full- or near full-length cDNA encodes a 315-amino acid protein with a molecular weight of 35,757, in good agreement with the 36,000 estimated molecular weight of heme oxygenase-2. When expressed in Escherichia coli, cDNA encodes a protein that cross-reacts with heme oxygenase-2 antiserum (as assayed by Western immunoblotting) and yields high levels of heme oxygenase activity in bacterial soluble cell extracts. Finally, computer analysis of the heme oxygenase-2 cDNA sequence indicates that the predicted amino acid sequence and hydropathy profile of the heme oxygenase-2 protein exhibit similarity with heme oxygenase-1.