The deepwater oxygen deficit in stratified shallow seas is mediated by diapycnal mixing

Seasonally stratified shelf seas are amongst the most biologically productive on the planet. A consequence is that the deeper waters can become oxygen deficient in late summer. Predictions suggest global warming will accelerate this deficiency. Here we integrate turbulence timeseries with vertical profiles of water column properties from a seasonal stratified shelf sea to estimate oxygen and biogeochemical fluxes. The profiles reveal a significant subsurface chlorophyll maximum and associated mid-water oxygen maximum. We show that the oxygen maximum supports both upward and downwards O2 fluxes. The upward flux is into the surface mixed layer, whilst the downward flux into the deep water will partially off-set the seasonal O2 deficit. The results indicate the fluxes are sensitive to both the water column structure and mixing rates implying the development of the seasonal O2 deficit is mediated by diapcynal mixing. Analysis of current shear indicate that the downward flux is supported by tidal mixing, whilst the upwards flux is dominated by wind driven near-inertial shear. Summer storminess therefore plays an important role in the development of the seasonal deep water O2 deficit.

Incursion of epizootic hemorrhagic disease into the Okanagan Valley, British Columbia in 1999

In September 1999, unusually high mortality rates in white-tailed deer and California bighorn sheep occurred in the southern Okanagan Valley. Necropsy and histopathologic findings were compatible with epizootic hemorrhagic disease (EHD); the presence of virus was not demonstrated. Subsequent serologic and polymerase chain reaction assays on sentinel cattle suggested an EHD virus incursion.

Flow and pattern formation in a binary mixture of rotating granular materials

In a horizontally rotating cylinder, size segregation, pattern formation, and its time development are studied for a binary mixture of rodlike and disklike materials at various rotational frequencies. The rodlike particles formed a network that influenced their mobility and the shape of the avalanching surface. Windows installed on the cylinder enabled us to examine and control the distribution of the components of the mixture throughout the bulk. This has allowed us to study the evolution of naturally occurring and artificially created patterns. All observed patterns had a degree of asymmetry and were unstable. The stability of a band pattern is shown to depend on its symmetry. Qualitatively, the time for the transition from one set of bands to another was inversely related to the degree of asymmetry of the pattern. In addition, we propose that the parameter D/d (diameter of the cylinder over the diameter of the grains) plays a significant role in the functional dependence of the avalanching surface current on the dynamical angle of repose, and in the segregation process itself.

Severing of F-actin by the amino-terminal half of gelsolin suggests internal cooperativity in gelsolin

Gelsolin is a Ca2+-regulated actin-binding protein that can sever, cap, and nucleate growth from the pointed ends of actin filaments. In this study we have measured the binding of the amino-terminal half of gelsolin, G1-3, to pyrene-labeled F-actin as a function of Ca2+ concentration. The rate of binding is shown to be dependent on micromolar concentrations of Ca2+. Independent experiments demonstrate that conformational changes in G1-3 are induced by micromolar concentrations of Ca2+. Titrations of pyrene-F-actin with G1-3 and gelsolin show that the quenching of pyrene fluorescence is identical in extent and stoichiometry for both G1-3 and gelsolin. In contrast, severing of F-actin by G1-3 is found to be much less efficient than is severing by gelsolin. In experiments in which F-actin severing is quantitatively measured, the filament number is found to be proportional to the 1.35 power of the G1-3 concentration. This deviation from linearity may be explained by cooperativity; the binding of two G1-3 molecules in close proximity may lead to cooperative severing of the polymer, thus increasing the severing efficiency. This model is supported by experiments that show that the efficiency of G1-3 severing of F-actin increases with increasing G1-3:F-actin ratios. Extrapolating from these results, we conclude that G4-6, the carboxyl-terminal half of gelsolin, has an active role in the severing of F-actin by intact gelsolin. Whereas F-actin severing by G1-3 is enhanced by cooperative binding of two separate G1-3 molecules, cooperativity is inherent to intact gelsolin because the cooperative partners are covalently linked.

Ca2+ regulation of gelsolin activity: binding and severing of F-actin

Regulation of the F-actin severing activity of gelsolin by Ca2+ has been investigated under physiologic ionic conditions. Tryptophan fluorescence intensity measurements indicate that gelsolin contains at least two Ca2+ binding sites with affinities of 2.5 x 10(7) M-1 and 1.5 x 10(5) M-1. At F-actin and gelsolin concentrations in the range of those found intracellularly, gelsolin is able to bind F-actin with half-maximum binding at 0.14 microM free Ca2+ concentration. Steady-state measurements of gelsolin-induced actin depolymerization suggest that half-maximum depolymerization occurs at approximately 0.4 microM free Ca2+ concentration. Dynamic light scattering measurements of the translational diffusion coefficient for actin filaments and nucleated polymerization assays for number concentration of actin filaments both indicate that severing of F-actin occurs slowly at micromolar free Ca2+ concentrations. The data suggest that binding of Ca2+ to the gelsolin-F-actin complex is the rate-limiting step for F-actin severing by gelsolin; this Ca2+ binding event is a committed step that results in a Ca2+ ion bound at a high-affinity, EGTA-resistant site. The very high affinity of gelsolin for the barbed end of an actin filament drives the binding reaction equilibrium toward completion under conditions where the reaction rate is slow.

A Kex2-related endopeptidase activity present in rat liver specifically processes the insulin proreceptor

The insulin proreceptor is cleaved by limited proteolysis post-translationally at an Arg-Lys-Arg-Arg site to generate its mature alpha- and beta-subunit form. An 35S-labelled insulin proreceptor substrate preparation and a 15-mer peptide substrate that mimics the amino acid sequence around and including the insulin proreceptor processing site (IRP-peptide) has revealed an endopeptidase activity that catalyses insulin proreceptor cleavage in a rat liver subcellular fraction. Under optimal conditions, normal 35S-labelled insulin proreceptor substrate processing by this fraction was quantitative. This fraction was not able to process an 35S-labelled insulin proreceptor variant substrate (where the Arg-1 of the tetrabasic cleavage site had been replaced by Ala-1), similarly to previous in vivo observations, suggesting that this endopeptidase activity has physiological relevance. Biochemical characterization of the insulin proreceptor/IRP-peptide processing revealed this rat liver endopeptidase activity to have a broad pH range (> 70% maximal activity between pH 5.5 and 10.0) and a pH optimum of pH 8-10. It was Ca(2+)-dependent activity, maximally active between 0.5 and 5 mM Ca2+ and half-maximally activated between 50 and 90 microM Ca2+. Endoproteolytic activity was not inhibited by group-specific inhibitors of serine-, cysteinyl or aspartyl proteinases or by 1,10-phenanthroline; however, EDTA and 1,2-cyclohexanediaminetetraacetic acid did inhibit the activity, but this was accounted for by Ca2+ chelation. The IRP-peptide substrate assay enabled measurement of an apparent Km of 22 microM and a Vmax of 18.6 pmol/min for this endopeptidase activity. These biochemical characteristics suggest that insulin proreceptor processing endopeptidase activity to be a legitimate member of the Kex2-related proprotein convertase family. Immunoblotting detected furin and PACE4 proteins (both members of this family) to be present in the rat liver subcellular fraction containing insulin proreceptor processing activity. Since the biochemical characteristics of the insulin proreceptor processing endopeptidase activity mostly resembled those of furin activity, it is likely that insulin proreceptor proteolytic maturation can be catalysed by furin in the liver.

The biosynthesis of the subtilisin-related proprotein convertase PC3, but no that of the PC2 convertase, is regulated by glucose in parallel to proinsulin biosynthesis in rat pancreatic islets

The biosynthesis of proinsulin is specifically stimulated by glucose in the pancreatic beta-cell, and this, in turn, places an increased demand on the mechanism for proinsulin to insulin conversion. Proteolytic proinsulin processing is catalyzed by two endopeptidases putatively identified as the subtilisin-related PC2 and PC3 convertases (Bennett, D. L., Bailyes, E. M., Nielson, E., Guest, P. C., Rutherford, N. G., Arden, S. D., and Hutton, J. C. (1992) J. Biol. Chem. 267, 15229-15236; Bailyes, E. M., Shennan, K. I. J., Seal, A. J., Smeekens, S. P., Steiner, D. F., Hutton, J. C., and Docherty, K. (1992) Biochem. J. 285, 391-394). In this study, we demonstrate in isolated rat pancreatic islets that the biosynthesis of PC3 was specifically stimulated by glucose relatively parallel to that of proinsulin. In contrast, however, PC2 biosynthesis was not glucose-regulated. The stimulation of PC3 and proinsulin biosynthesis was observed above a threshold of 4 mM glucose and reached a maximum (about 7-10-fold) above 10 mM glucose concentrations. Glucose stimulation for PC3 and proinsulin biosynthesis was rapid (occurring within 20 min and reaching a maximum by 60 min) and was not affected by the additional presence of actinomycin D, suggesting regulation predominantly at the translational level. Moreover, the intracellular signals for glucose-stimulated PC3 and proinsulin biosynthesis appeared to be similar, requiring the metabolism of glucose. PC3 has been implicated as the key endopeptidase in proinsulin to insulin conversion, in that it is the enzyme which preferentially initiates the process (Rhodes, C. J., Lincoln, B., and Shoelson, S. E. (1992) J. Biol. Chem. 267, 22719-22727). We suggest that co-ordinate stimulation of PC3 biosynthesis, along with that of its proinsulin substrate, elucidates an additional control point by which the mechanism of proprotein processing might be regulated.

Processing of proopiomelanocortin by insulin secretory granule proinsulin processing endopeptidases

A lysed preparation of isolated insulin secretory granules efficiently cleaved murine proopiomelanocortin (mPOMC) at physiologically important Lys-Arg processing sites. This processing was mostly attributed to an activity that co-eluted with the proinsulin processing type-II endopeptidase from anion exchange chromatography (Lys-Arg-directed; Davidson, H. W., Rhodes, C. J., and Hutton, J. C. (1988) Nature 333, 93-96). The principal peptide hormone products generated by the insulin secretory granule lysate were identified by specific radioimmunoassay and NH2-terminal microsequencing analysis of high performance liquid chromatography-separated products as alpha-melanocyte-stimulating hormone, corticotropin-like intermediate, gamma-lipotropin, beta-endorphin-(1-31), 18-kDa NH2-terminal fragment and, to a lesser extent, adrenocorticotrophin and beta-lipotropin. This processing had an acidic pH optimum (pH 5-5.5) and was Ca(2+)-dependent (K0.5 activation = 5-80 microM). With increasing Ca2+ concentrations there was an increase in the extent to which mPOMC was processed. The in vitro processing of mPOMC by the insulin secretory granule endopeptidase activity reported here is in excellent agreement with the in vivo processing of this prohormone by a combination of PC2 and PC3, candidates of prohormone endpeptidase, in gene transfer studies with cells that express the regulated secretory pathway (Thomas, L., Leduc, R., Thorne, B. A., Smeekens, S. S., Steiner, D. F., and Thomas, G. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 5297-5301).

Preferential cleavage of des-31,32-proinsulin over intact proinsulin by the insulin secretory granule type II endopeptidase. Implication of a favored route for prohormone processing

Two Ca(2+)-dependent endopeptidase activities are involved in proinsulin to insulin conversion: type I cleaves COOH-terminal to proinsulin Arg31-Arg32 (B-chain/C-peptide junction); and type II preferentially cleaves at the Lys64-Arg65 site (C-peptide/A-chain junction). To further understand the mechanism of proinsulin processing, we have investigated types I and II endopeptidase processing of intact proinsulin in parallel to that of the conversion intermediates, des-31,32-proinsulin and des-64,65-proinsulin. The type I processed des-64,65-proinsulin and proinsulin at the same rate. In contrast, the type II endopeptidase processed des-31,32-proinsulin at a much faster rate (> 19-fold; p < 0.001) than it did intact proinsulin. Furthermore, unlabeled proinsulin concentrations required for competitive inhibition of 125I-labeled des-64,65-proinsulin and 125I-proinsulin processing by a purified insulin secretory granule lysate were similar (ID50 = 14-16 microM), whereas inhibition of 125I-labeled des-31,32-proinsulin processing required a higher nonradiolabeled proinsulin concentration (ID50 = 197 microM). Synthetic peptides corresponding to the sequences surrounding Lys64-Arg65 (AC-peptide/substrate) and Arg31-Arg32 (BC-peptide/substrate) of human proinsulin were synthesized for use as specific substrates or competitive inhibitors. Cleavage of the BC-substrate by type I and AC-substrate by type II was COOH-terminal of the dibasic sequence, with similar Ca(2+)-and pH requirements previously observed for proinsulin cleavage. Apparent Km and Vmax for type I processing of the BC-substrate was Km = 20 microM; Vmax = 22.8 pmol/min, and for type II processing of the AC-substrate was Km = 68 microM; Vmax = 97 pmol/min. In competitive inhibition assays, the BC-peptide similarly blocked insulin secretory granule lysate processing of des-64,65-proinsulin and proinsulin (ID50 = 45-55 microM), but did not inhibit des-31,32-proinsulin processing. However, the AC-peptide preferentially inhibited insulin secretory granule lysate processing of des-31,32-proinsulin (ID50 = microM) compared to proinsulin (ID50 = 330 microM), and not des-64,65-proinsulin. We conclude that the type I endopeptidase recognized des-64,65-proinsulin and proinsulin as similar substrates, whereas the type II endopeptidase has a stronger preference for des-31,32-proinsulin compared to intact proinsulin. Furthermore, we suggest that in intact proinsulin there exists a constraint to efficient processing that is relieved following type I processing. Structural flexibility, in addition to the presence of Lys64-Arg65, therefore appears to be important for type II endopeptidase specificity and may provide a molecular basis for a preferential route of proinsulin conversion via des-31,32-proinsulin.

Fluorometric assay of a calcium-dependent, paired-basic processing endopeptidase present in insulinoma granules

A novel fluorogenic substrate Cbz-Arg-Ser-Lys-Arg-AMC (RSKR-AMC) was used to characterize Ca(++)-activated proteolytic activity present in purified insulinoma secretory granules. Secretory granules efficiently cleaved this substrate in a time- and protein-dependent manner; the hydrolysis rate was between 2 and 4 pmol/min/ug of protein, with an apparent Km of 55 microM. Greater than 90% of the activity against this substrate was dependent on the presence of Ca++, with half-maximal stimulation obtained at 100 microM Ca++. The pH optimum of enzymatic activity was 5.5-6, and the profile of inhibition by various proteinase inhibitors was similar to that previously described for the type I and II proinsulin processing enzymes. These biochemical characteristics and co-elution of the RSKR-AMC processing activity with the type II endopeptidase activity on anion-exchange chromatography suggest that the new assay selectively detects the Lys-Arg-directed, or type II, proinsulin processing endopeptidase. This fluorogenic assay is more quantitative, sensitive and rapid than methods previously used, and therefore presents a significant improvement for the study of similar Ca(++)-activated processing endopeptidases.

Hepatic heme synthesis in a new model of experimental hemochromatosis: studies in rats fed finely divided elemental iron

Rats fed chow containing finely divided elemental iron (from carbonyl-iron) develop hepatic iron overload resembling human hereditary hemochromatosis in that deposition of iron is primarily in periportal hepatocytes and with hepatic iron concentrations sufficiently high to be associated in the human disease with hepatic fibrosis or cirrhosis. In recent studies using this model, we reported changes in hepatic hemoproteins and heme oxygenase, the rate-controlling enzyme of heme breakdown. We now report effects of iron-loading on three enzymes of heme synthesis: 5-aminolevulinate synthase; the first and rate-controlling enzyme of the pathway, 5-aminolevulinate dehydrase (or porphobilinogen synthase), and uroporphyrinogen decarboxylase, the activity of which is decreased in porphyria cutanea tarda, a liver disease in which iron is known to play an important but still poorly understood role. Of the three enzymes, only activity of the dehydrase was altered by iron-loading: it was decreased significantly as early as 1 week after starting iron feeding, and with marked iron overload was 30 to 32% of control values. The degree of decrease was inversely related (r = -0.77 to -0.88) to the degree of iron overload and was partially reversed within 1 to 3 days when feeding of the iron-supplemented diet was stopped. The decrease in dehydrase activity was not attributable to lack of reduced glutathione or other disulfide-reducing agents or to zinc deficiency; nor was evidence found for inhibition by iron compounds or other possible inhibitors present in iron-loaded livers.(ABSTRACT TRUNCATED AT 250 WORDS)

Hepatic heme and drug metabolism in rats with chronic mountain sickness

Rats chronically exposed to hypobaric conditions develop pulmonary hypertension, right heart failure, hemoglobinemia, and in preliminary studies were recently found to have increased hepatic cytochrome P-450 content and activity of heme oxygenase, the rate-limiting enzyme for heme breakdown. To further delineate effects of chronic hypoxic, hypobaric exposure, on hepatic physiology and biochemistry, we have studied heme and drug metabolism in male Sprague-Dawley rats exposed to hypoxic conditions for 4-5 wk. Hypoxia, produced by exposure of rats to room air under hypobaric conditions (approximately 380 Torr), caused marked polycythemia [hematocrit (Hct) 70% vs. control Hct 43%], plasma hemoglobinemia, depletion of plasma haptoglobin, and decreased hemopexin concentrations. It also led to significant (20-30%) increases in concentrations of total hepatic heme and microsomal cytochrome P-450 and increased activities of heme oxygenase. In contrast, activity of 5-aminolevulinate synthase, the rate-limiting enzyme of hepatic heme synthesis, was significantly decreased in hypoxic rats and was not as inducible as in control normoxic rats. Hypoxia did not alter the rest of the heme synthetic pathway, as shown by a normal rate of conversion of 5-aminolevulinate to heme. Hypoxic exposure had no effect on the concentration of hepatic cytochrome-b5 but decreased activity of NADPH-cytochrome c reductase. Rates of metabolism of aminopyrine, benzphetamine, ethoxyresorufin, and warfarin were similar in hepatic microsomes obtained from hypoxic and normoxic rats. Thus the oxygen-requiring processes of hepatic heme and drug metabolism were well maintained despite chronic profound hypoxia sufficient to cause cardiopulmonary complications.

High-performance liquid chromatographic separation and quantitation of tetrapyrroles from biological materials

We describe a rapid, reverse-phase HPLC procedure for separating and quantifying tetrapyrroles of biological interest. This procedure uses a 5-micron C18 column and the mobile phase is ammonium phosphate (pH 3.5) with a methanol gradient that is increased from 61 to 100%. Detection is by absorbance at 405 nm or by fluorescence. Porphyrins, heme, and the heme breakdown products, biliverdin and bilirubin, can be separated from a single injection in 25 min. Injections can be made every 40 min. Limits of detection are about 0.1 pmol for porphyrins, 5 pmol for heme, and 10 pmol for biliverdin and bilirubin. We present examples of the use of the system for separating tetrapyrroles formed by primary cultures of chick embryo hepatocytes and homogenates of rat liver.

Preliminary report of the use of levamisole in the treatment of bladder cancer

Sixty-two patients with transitional cell carcinoma have been admitted to a double-blind randomized control study with levamisole as an immune adjuvant, in addition to standard therapy for noninvasive and invasive bladder cancer. Levamisole has been shown to be easily administered and is well-tolerated, especially when compared to other immune adjuvants such as bacillus Calmette-Guerin or Corynebacterium parvum. To date, there is no significant difference in the disease-free interval in the levamisole-treated group compared to the placebo group. Initial dinitrochlorobenzene (DNCB) reactivity may be an important prognostic indicator with regard to tumor recurrence. Tumor recurrence seems to be rare in those patients who are initially DNCB-positive. Total monocyte count, T lymphocyte, FC receptor cells, and PHA response showed no improvement with levamisole therapy. Monocyte chemotaxis remains the only immune function study to improve with levamisole, but the clinical significance of this test is yet to be explained.