High pressures and asymmetrical stresses in the scoliotic disc in the absence of muscle loading

Background

Loads acting on scoliotic spines are thought to be asymmetric and involved in progression of the scoliotic deformity; abnormal loading patterns lead to changes in bone and disc cell activity and hence to vertebral body and disc wedging. At present however there are no direct measurements of intradiscal stresses or pressures in scoliotic spines. The aim of this study was to obtain quantitative measurements of the intradiscal stress environment in scoliotic intervertebral discs and to determine if loads acting across the scoliotic spine are asymmetric. We performed in vivo measurements of stresses across the intervertebral disc in patients with scoliosis, both parallel (termed horizontal) and perpendicular (termed vertical) to the end plate, using a side mounted pressure transducer (stress profilometry)

Methods

Stress profilometry was used to measure horizontal and vertical stresses at 5 mm intervals across 25 intervertebral discs of 7 scoliotic patients during anterior reconstructive surgery. A state of hydrostatic pressure was defined by identical horizontal and vertical stresses for at least two consecutive readings. Results were compared with similar stress profiles measured during surgery across 10 discs of 4 spines with no lateral curvature and with data from the literature.

Results

Profiles across scoliotic discs were very different from those of normal, young, healthy discs of equivalent age previously presented in the literature. Hydrostatic pressure regions were only seen in 14/25 discs, extended only over a short distance. Non-scoliotic discs of equivalent age would be expected to show large centrally placed hydrostatic nuclear regions in all discs. Mean pressures were significantly greater (0.25 MPa) than those measured in other anaesthetised patients (<0.07 MPa). A stress peak was seen in the concave annulus in 13/25 discs. Stresses in the concave annulus were greater than in the convex annulus indicating asymmetric loading in these anaesthetised, recumbent patients.

Conclusion

Intradiscal pressures and stresses in scoliotic discs are abnormal, asymmetrical and high in magnitude even in the absence of significant applied muscle loading. The origin of these abnormal stresses is unclear.     

1H-N.m.r. spectral assignments for two series of heparin-derived oligosaccharides.

Six heparin-derived oligosaccharides, ranging in size from di- to octa-saccharide and forming two closely related series differing in structure by the substitution of an unsulfated D-glucuronate for a 2-sulfated L-iduronate residue, have been characterized by 2-dimensional 1H-n.m.r. spectroscopy. In addition to providing new data on hexa- and octa-saccharides, several important changes to previously published data have been found for the two tetrasaccharides. The D-glucuronic acid H-5 proton is assigned to a resonance in the same region as resonances for the H-3 and H-4 D-glucuronate protons, rather than downfield from these resonances as earlier reported. The presence of D-glucuronic acid in the heparin sequence of the series-1 fragments affects the positions of neighboring D-glucosamine resonances, in particular shifting the anomeric proton signal in the preceding D-glucosamine 0.1-0.2 p.p.m. downfield. Resonances from the reducing-end D-glucosamines differ from internal D-glucosamine resonances both in relative position and in the degree of chemical shift difference between the H-6 and H-6' protons. This work illustrates the usefulness of two-dimensional techniques in determining heparin structure and emphasizes the need for direct analysis, rather than assignment by comparison to model compounds.     

On the coordination of inhibitors to the metal ion of carboxypeptidase A. A 113Cd and 31P NMR study

113Cd and 31P NMR have been used to investigate the interactions of inhibitors with the metal ion of bovine carboxypeptidase A, using 113Cd as a replacement for the native zinc atom. In the absence of inhibitor and over the pH range 6-9, no 113Cd resonance is visible at room temperature. Upon lowering the temperature to 270 K, however, a broad resonance can be seen at 120 ppm. These results are discussed in terms of possible sources for this resonance modulation. Binding of low molecular weight inhibitors containing potential metal-coordinating moieties results in the appearance of a sharp 113Cd resonance. These inhibitors all bind to the metal ion, a fact which is reflected in the chemical shift of the cadmium resonance and, for L-phenylalanine phosphoramidate phenyl ester, by two-bond 113Cd-31P spin-spin coupling of 30 Hz in the 31P resonance of the bound inhibitor. For inhibitors that coordinate to the metal ion via oxygen, the 113Cd chemical shift is in the range 127-137 ppm, whereas for sulfur coordination there is a downfield shift of approximately 210 ppm. The complexes of 113Cd-substituted carboxypeptidase A with the D and L isomers of thiolactic acid are distinguished by a difference of 11 ppm in the chemical shift of their cadmium resonances. The enzyme complex formed with the macromolecular inhibitor from potatoes, which fills the S1 and S2 subsites, shows one or possibly two closely spaced broad 113Cd resonances. Both the chemical shift and the line width of the 113Cd resonances of the [113Cd]carboxypeptidase-inhibitor complexes give valuable structural and dynamic information about the enzyme active site.     

Production of neosolaniol monoacetate by an undescribedFusarium species resemblingF camptoceras

Cultures of 12 South African isolates of an undescribedFusarium species resembling but distinct fromF camptoceras were analysed for the presence of diacetoxyscirpenol (DAS), neosolaniol monoacetate (NMA), and T-2 toxin, by capillary gas chromatography utilizing electron capture detection. No DAS or T-2 toxin could be detected in any of the cultures of the isolates. NMA was, however, detected in 10 of the 12 isolates at levels ranging from 310 to 2060 ng/g. The method used, was primarily developed for the determination of DAS and T-2 toxin in fungal cultures and grain samples but was found to be suitable for the coextraction of NMA at an average recovery of 80.8%, with a detection limit in the order of 100 ng/g. Supportive evidence for the presence of the NMA was obtained by capillary gas chromatography / mass spectrometry. Regarded as a relatively rare trichothecene, NMA has never been reported to occur naturally and has previously been shown to be produced by only a fewFusarium strains.     

The sensitivity of Afromontane tarns in the Maloti-Drakensberg region of South Africa and Lesotho to acidic deposition

Despite their remoteness from sources of atmospheric pollutant emissions, the Afromontane tarns in the Maloti-Drakensberg region are perfect candidates to study the negative effects of acidifying atmospheric pollution, because mountain lakes are widely recognised as sentinel ecosystems, unimpacted by direct human disturbance within their catchments. Thirty-four tarns were sampled in the Maloti-Drakensberg region and most were found to be extremely sensitive to acidic deposition, as indicated by their low acid neutralising capacity. There are very few studies of freshwater critical loads for any region within South Africa. The steady-state water chemistry model (SSWC) was adapted and used to determine critical loads, whereas exceedance was estimated relative to modelled regional deposition data, in order to understand the risk of harmful effects to aquatic ecosystems. Seventy-six percent of sampled sites across the Maloti-Drakensberg would exceed critical loads even at the lowest modelled deposition levels, but there are no current measured deposition data for the region. The sensitivity of the Maloti-Drakensberg tarns needs to be considered in future policy formulation regarding acceptable levels of acidifying atmospheric pollution from South Africa’s energy sector and indicates the need for assessing aquatic ecosystem impacts in other regions of South Africa.     

Importance of the P2 glycine of antithrombin in target proteinase specificity, heparin activation, and the efficiency of proteinase trapping as revealed by a P2 Gly --> Pro mutation.

A sequence-specific heparin pentasaccharide activates the serpin, antithrombin, to inhibit factor Xa through an allosteric mechanism, whereas full-length heparin chains containing this sequence further activate the serpin to inhibit thrombin by an alternative bridging mechanism. To test whether the factor Xa specificity of allosterically activated antithrombin is encoded in the serpin reactive center loop, we mutated the factor Xa-preferred P2 Gly to the thrombin-preferred P2 Pro. Kinetic studies revealed that the mutation maximally enhanced the reactivity of antithrombin with thrombin 15-fold and decreased its reactivity toward factor Xa 2-fold when the serpin was activated by heparin pentasaccharide, thereby transforming antithrombin into an allosterically activated inhibitor of both factor Xa and thrombin. Surprisingly, the enhanced thrombin specificity of the mutant antithrombin was attenuated when a full-length bridging heparin was the activator, due both to a reduced rate of covalent reaction of the mutant serpin and thrombin and preferred reaction of the mutant serpin as a substrate. These results demonstrate that the reactive center loop sequence determines the specificity of allosterically activated antithrombin for factor Xa and that the conformational flexibility of the P2 Gly may be critical for optimal bridging of antithrombin and thrombin by physiologic heparin and for preventing antithrombin from reacting as a substrate in the bridging complex.     

Activation of antithrombin as a factor IXa and Xa inhibitor involves mitigation of repression rather than positive enhancement

Allosteric activation of antithrombin as a rapid inhibitor of factors IXa and Xa requires binding of a high-affinity heparin pentasaccharide. The currently-accepted mechanism involves removal of a constraint on the antithrombin reactive center loop (RCL) so that the proteinase can simultaneously engage both the P1 arginine and an exosite at Y253. Recent results suggest that this mechanism is incorrect in that activation can be achieved without loop expulsion, while the exosite can be engaged in both low and high activity states. We propose a quite different mechanism in which heparin activates antithrombin by mitigating an unfavorable surface interaction, by altering its nature, and by moving the attached proteinase away from the site of the unfavorable interaction through RCL expulsion.     

77Se NMR characterization of 77Se-labeled ovine erythrocyte glutathione peroxidase

Lambs, maintained on a selenium-deficient diet supplemented with 94 atom % Na2 27SeO3, have been used as a source of 77Se-enriched erythrocyte glutathione peroxidase. After 5 months on this diet, the percentage of selenium in the enzyme derived from the supplement had reached 88%. From each monthly bleeding of two sheep, approximately 20 mg of 77Se-enriched glutathione peroxidase could be isolated in pure form. Although attempts to observe 77Se NMR signals from the native enzyme labeled with 6,6'-[77Se]diselenobis-(3-nitrobenzoic acid) failed, due to the low solubility of the enzyme, two 77Se resonances were observed after unfolding the enzyme with 8 M urea and reaction with iodoacetamide. These resonances, at 195 and 377 ppm, were from the selenoether alkylamide derivative and from protein cross-linked selenide sulfide species, respectively. Relaxation time measurements on the selenoether at 4.7 and 9.4 teslas enabled an estimate of the chemical shift anisotropy to be made. A value of less than or equal to 262 ppm was determined. Reduction of the denatured selenide sulfide species with dithiothreitol gave an observable 77Se resonance from the Se- moiety at pH 8 and from SeH at pH 4.2. The chemical form of the selenocysteine residue in the resting state enzyme most consistent with formation of the acetamide derivative and the selenide sulfide is Se- or SeH. From the magnitudes of the estimated chemical shift anisotropies, it is predicted that direct observation of selenium in the native enzyme will be feasible if the enzyme concentration can be increased to 0.25 mM tetrameric glutathione peroxidase.     

113Cd nuclear magnetic resonance of Cd(II) alkaline phosphatases

113Cd NMR spectra of 113Cd(II)-substituted Escherichia coli alkaline phosphatase have been recorded over a range of pH values, levels of metal site occupancy, and states of phosphorylation. Under all conditions resonances attributable to cadmium specifically bound at one or more of the three pairs of metal-binding sites (A, B, and C sites) are detected. By following changes in both the 113Cd and 31P NMR spectra of 113Cd(II)2 alkaline phosphatase during and after phosphorylation, it has been possible to assign the cadmium resonance that occurs between 140 and 170 ppm to Cd(II) bound to the A or catalytic site of the enzyme and the resonance occurring between 51 and 76 ppm to Cd(II) bound to B site, which from x-ray data is located 3.9 A from the A site. The kinetics of phosphorylation show that cadmium migration from the A site of one subunit to the B site of the second subunit follows and is a consequence of phosphate binding, thus precluding the migration as a sufficient explanation for half-of-the-sites reactivity. Rather, there is evidence for subunit-subunit interaction rendering the phosphate binding sites inequivalent. Although one metal ion, at A site, is sufficient for phosphate binding and phosphorylation, the presence of a second metal ion at B site greatly enhances the rate of phosphorylation. In the absence of phosphate, occupation of the lower affinity B and C sites produces exchange broadening of the cadmium resonances. Phosphorylation abolishes this exchange modulation. Magnesium at high concentration broadens the resonances to the point of undetectability. The chemical shift of 113Cd(II) in both A and B sites (but not C site) is different depending on the state of the bound phosphate (whether covalently or noncovalently bound) and gives separate resonances for each form. Care must be taken in attributing the initial distribution of cadmium or phosphate in the reconstituted enzyme to that of the equilibrium species in samples reconstituted from apoenzyme. Both 113Cd NMR and 31P NMR show that some conformational changes consequent to metal ion or phosphate binding require several days before the final equilibrium species is formed.     

Sampling Rhyparida nitida Clark (Coleoptera: Chrysomelidae) and symptoms of their damage on sugarcane

Sampling statistics were determined for larvae, pupae and adults of the chrysomelid Rhyparida nitida associated with sugarcane in Australia and for symptoms of their damage. Iwao's patchiness regression was inappropriate for modelling the mean–variance relationships of the insect counts. Taylor's power law was used to model these data and relationships were developed for counts of small, medium and large larvae, all larvae combined, pupae and adults. The mean–variance relationships of counts of live shoots and shoots killed by larvae of R. nitida were modelled using Iwao's patchiness regression; Taylor's power law was not appropriate to either data set. Relationships to determine sample sizes for fixed levels of precision and fixed-precision-level stop lines for sequential sampling of the different stages and live and dead shoots were also developed. Neither the ln(x + 1) transformation nor the Healy and Taylor transformation consistently standardised the mean–variance relationships of insect counts and the appropriate transformation should be selected on a case-by-case basis. Counts of both live and dead shoots were adequately transformed by the Iwao and Kuno transformation.