Involvement of intracellular labile zinc in suppression of DEVD-caspase activity in human neuroblastoma cells

Age-related tissue Zn deficiency may contribute to neuronal and glial cell death by apoptosis in Alzheimer's dementia. To investigate this, we studied the effects of increasing or decreasing the levels of intracellular labile Zn on apoptosis of human neuroblastoma BE(2)-C cells in vitro. BE(2)-C cells were primed for 18 h with butyrate (1 mM) before addition of staurosporine (1 microM), an effector enzyme of apoptosis, for a further 3 h to induce DEVD-caspase activity. An increase in intracellular Zn using Zn ionophore pyrithione suppressed DEVD-caspase activity, while a decrease in intracellular Zn induced by Zn chelator TPEN mimicked staurosporine by activating DEVD-caspase in butyrate-primed cells. The distribution of intracellular Zn in the cells was demonstrated with the UV-excitable Zn-specific fluorophore Zinquin. Confocal images showed distinct cytoplasmic and cytoskeletal fluorescence. We propose that Zn decreases the level of apoptosis in neuronal cells exposed to toxins, possibly by stabilizing their cytoskeleton.     

Bacterial cell disruption: a key unit operation in the recovery of intracellular products

The need for microbial cell disruption has hindered the large scale production of commercial biotechnological products of intracellular derivation. The intracellular nature of many recombinant products and the potential use of the bacterial storage product, PHB as a commodity thermoplastic have renewed interest in the improvement of this unit operation. This paper provides a review of processes of a mechanical, physical, chemical or biological nature used for cell disruption on both the laboratory and large scale. Applicability of the techniques to large scale operation is discussed. Modification of existing processes is suggested for the reduction of energy requirements and improved process economics. The requirements for the liberation of granular intracellular products such as inclusion bodies and virus-like yeast particles are distinguished from those for the liberation of soluble products, mainly proteinaceous in nature. The integrated nature of the process with both upstream and downstream processes is addressed. Finally, the recent approach of selective liberation of soluble products of interest is reviewed.     

Hydrolysis of proteins and peptides in a hermetically sealed microcapillary tube: high recovery of labile amino acids

A method for the hydrolysis of peptides and proteins in a hermetically sealed microcapillary tube has been developed. The method is based on the concept that oxidative degradation of labile amino acids during acid hydrolysis of proteins and peptides at high temperature can be reduced to a minimum by limiting the ratio of air to liquid (v/v, less than 1:10) in a microcapillary tube. Furthermore, the physical constraints imposed by the capillary tube will restrict the exposure of the protein solution to air at a very limited area at the meniscus of the liquid. This method eliminates the necessity of time-consuming sealing under vacuum and/or flushing with nitrogen to remove oxygen in the hydrolysis tube. High recovery of labile amino acids can be obtained in a reproducible manner. Because of the simplicity and high reproducibility of the method described, it could be the method of choice for the hydrolysis of protein and peptide intended for quantitative amino acid analysis. Performic acid oxidation is performed at 50 degrees C for 10 min instead of 4 to 20 h at 0 degrees C to achieve an equally good yield of cysteic acid and methionine sulfone from peptides and proteins.     

Effect of clofibrate on intracellular enzyme distribution in the rat liver

The effect of chronic administration of a hypolipaemic agent--clofibrate--on the subcellular distribution of liver enzymes in male rats was studied. Clofibrate produced an increase in the number of peroxisomes and also enhanced the activity of aconitase and histidine: glyoxylate aminotransferase (HGA) in liver homogenate. Differential centrifugation of homogenate revealed an elevation of the relative amounts of catalase, HGA and isocitrate dehydrogenase in the soluble cell fraction in clofibrate pretreated animals. Clofibrate induced peroxisomal HGA but failed to alter the amounts of catalase, urate oxidase and isocitrate dehydrogenase in the particles. In both the experimental and control groups the activity of aconitase, malate dehydrogenase (NAD+), creatine phosphokinase and glutathione reductase was observed in mitochondrial fractions and was not detected in purified peroxisomes.     

Characterization of an intracellular insulin-degrading enzyme in human erythrocytes

Using conventional techniques of ammonium sulfate fractionation and Sephadex gel column chromatography, insulin-degrading enzyme was partially purified from lysate of human erythrocytes. The enzymatic activity was measured by the trichloroacetic acid precipitation method. Compared to trypsin, the enzyme was highly specific for insulin. The apparent molecular weight of the enzyme was 160,000 Da, the optimum pH was the 7.4 to 7.8 range, and the Km value for insulin for the partially purified enzyme was 162 nM. Bacitracin and N-ethylmaleimide were potent inhibitors, while chloroquine, ethylenediaminetetraacetate, antipain, and soybean trypsin inhibitor failed to inhibit the activity of the enzyme. Like most nucleated cells, human erythrocytes not only have the membranal insulin receptors, but also possess the cytosolic specific insulin-degrading enzyme. Insulin internalization and degradation are shown to be due to the receptor and the enzyme acting in concert as in many nucleated cells. Anucleated erythrocytes have both these entities for possible internalization and degradation of insulin.     

Direct process integration of cell disruption and fluidised bed adsorption in the recovery of labile microbial enzymes

The practical feasibility and generic applicability of the direct integration of cell disruption by bead milling with the capture of intracellular products by fluidised bed adsorption has been demonstrated. Pilot-scale purification of the enzyme L-asparaginase from unclarified Erwinia chrysanthemi disruptates exploiting this novel approach yielded an interim product which rivalled or bettered that produced by the current commercial process employing discrete operations of alkaline lysis, centrifugal clarification and batch adsorption. In addition to improved yield and quality of product, the process time during primary stages of purification was greatly diminished. Two cation exchange adsorbents, CM HyperD LS (Biosepra/Life Technologies) and SP UpFront (custom made SP form of a prototype stainless steel/agarose matrix, UpFront Chromatography) were physically and biochemically evaluated for such direct product sequestration. Differences in performance with regard to product capacity and adsorption/desorption kinetics were demonstrated and are discussed with respect to the design of adsorbents for specific applications. In any purification of L-asparaginase (pI = 8.6), product-debris interactions commonly diminish the recovery of available product. It was demonstrated herein, that immediate disruptate exposure to a fluidised bed adsorbent promoted concomitant reduction of product in the liquid phase, which clearly counter-acted the product-debris interactions to the benefit of product yield.     

Prediction of the pilot-scale recovery of a recombinant yeast enzyme using integrated models

This article describes the rapid prediction of recovery process performance for a new recombinant enzyme product on the basis of a broad portfolio of computer models and highly targeted experimentation. A process model for the recombinant system was generated by linking unit operation models in an integrated fashion, with required parameter estimation and physical property determination accomplished using data from scale-down studies. This enabled the generic modeling framework established for processing of a natural enzyme from bakers' yeast to be applied. An experimental study of the same operations at the pilot scale showed that the process model gave a conservative prediction of recombinant enzyme recovery. The model successfully captured interactions leading to a low overall product yield and indicated the need for further study of precipitate breakage in the feed zone of a disc stack centrifuge in order to improve performance. The utility of scale-down units as an aid to fast model generation and the advantage of integrating computer modeling and scale-down studies to accelerate bioprocess development are highlighted.     

Residue Met(156) contributes to the labile enzyme conformation of coagulation factor VIIa

Serine protease activation is typically controlled by proteolytic cleavage of the scissile bond, resulting in spontaneous formation of the activating Ile(16)-Asp(194) salt bridge. The initiating coagulation protease factor VIIa (VIIa) differs by remaining in a zymogen-like conformation that confers the control of catalytic activity to the obligatory cofactor and receptor tissue factor (TF). This study demonstrates that the unusual hydrophobic Met(156) residue contributes to the propensity of the VIIa protease domain to remain in a zymogen-like conformation. Mutation of Met(156) to Gln, which is found in the same position of the highly homologous factor IX, had no influence on the amidolytic and proteolytic activity of TF-bound VIIa. Furthermore, the mutation did not appreciably stabilize the labile Ile(16)-Asp(194) salt bridge in the absence of cofactor. VIIa(Gln156) had increased affinity for TF, consistent with a long range conformational effect that stabilized the cofactor binding site in the VIIa protease domain. Notably, in the absence of cofactor, amidolytic and proteolytic function of VIIa(Gln156) were enhanced 3- and 9-fold, respectively, compared with wild-type VIIa. The mutation thus selectively influenced the catalytic activity of free VIIa, identifying the Met(156) residue position as a determinant for the zymogen-like properties of free VIIa.     

Catalase is a key enzyme in seed recovery from ageing during priming

Ageing induces seed deterioration expressed as the loss of seed vigour and/or viability. Priming treatment, which consists in soaking of seeds in a solution of low water potential, has been shown to reinvigorate aged seeds. We investigate the importance of catalase in oxidation protection during accelerated ageing and repair during subsequent priming treatment of sunflower (Helianthus annuus L.) seeds. Seeds equilibrated to 0.29 g H₂O g⁻¹ dry matter (DM) were aged at 35 °C for different durations and then primed by incubation for 7 days at 15 °C in a solution of polyethylene glycol 8000 at −2 MPa. Accelerated ageing affected seed germination and priming treatment reversed partially the ageing effect. The inhibition of catalase by the addition of aminotriazol during priming treatment reduced seed repair indicating that catalase plays a key role in protection and repair systems during ageing. Ageing was associated with H₂O₂ accumulation as showed by biochemical quantification and CeCl₃ staining. Catalase was reduced at the level of gene expression, protein content and affinity. Interestingly, priming induced catalase synthesis by activating expression and translation of the enzyme. Immunocytolocalization of catalase showed that the enzyme co-localized with H₂O₂ in the cytosol. These results clearly indicate that priming induce the synthesis of catalase which is involved in seed recovery during priming.     

Real-time NMR monitoring of intermediates and labile products of the bifunctional enzyme UDP-apiose/UDP-xylose synthase

The conversion of UDP-α-d-glucuronic acid to UDP-α-d-xylose and UDP-α-d-apiose by a bifunctional potato enzyme UDP-apiose/UDP-xylose synthase was studied using real-time nuclear magnetic resonance (NMR) spectroscopy. UDP-α-d-glucuronic acid is converted via the intermediate uridine 5′-β-l-threo-pentapyranosyl-4″-ulose diphosphate to UDP-α-d-apiose and simultaneously to UDP-α-d-xylose. The UDP-α-d-apiose that is formed is unstable and is converted to α-d-apio-furanosyl-1,2-cyclic phosphate and UMP. High-resolution real-time NMR spectroscopy is a powerful tool for the direct and quantitative characterization of previously undetected transient and labile components formed during a complex enzyme-catalyzed reaction.     

Cell-selective intracellular delivery of a foreign enzyme to endothelium in vivo using vascular immunotargeting.

Vascular immunotargeting, the administration of drugs conjugated with antibodies to endothelial surface antigens, has the potential for drug delivery to the endothelium. Our previous cell culture studies showed that biotinylated antibodies to PECAM-1 (a highly expressed endothelial surface antigen) coupled with streptavidin (SA, a cross-linking protein that facilitates anti-PECAM internalization and targeting) may provide a carrier for the intracellular delivery of therapeutic enzymes. This paper describes the PECAM-directed vascular immunotargeting of a reporter enzyme (beta-galactosidase, beta-Gal) in intact animals. Intravenous injection of [125I]SA-beta-Gal conjugated with either anti-PECAM or IgG led to a high 125I uptake in liver and spleen, yet beta-Gal activity in these organs rapidly declined to the background levels, suggesting rapid degradation of the conjugates. In contrast, anti-PECAM/[125I]SA-beta-Gal, but not IgG/[125I]SA-beta-Gal, accumulated in the lungs (36.0+/-1.3 vs. 3.9+/-0.6% injected dose/g) and induced a marked elevation of beta-Gal activity in the lung tissue persisting for up to 8 h after injection (10-fold elevation 4 h postinjection). Using histochemical detection, the beta-Gal activity in the lungs was detected in the endothelial cells of capillaries and large vessels. The anti-PECAM carrier also provided 125I uptake and beta-Gal activity in the renal glomeruli. Predominant intracellular localization of anti-PECAM/SA-beta-Gal was documented in the PECAM-expressing cells in culture by confocal microscopy and in the pulmonary endothelium by electron microscopy. Therefore, vascular immunotargeting is a feasible strategy for cell-selective, intracellular delivery of an active foreign enzyme to endothelial cells in vivo, and thus may be potentially useful for the treatment of acute pulmonary or vascular diseases.     

Photoreactivating enzyme from Euglena and the control of its intracellular level

Photoreactivating (PR) enzyme activity has already been demonstrated by us in cell-free extracts of Euglena gracilis var. bacillaris Pringsheim using the Hemophilus transformation assay. This activity can also be detected in extracts using a direct non-biological assay for the photorepair of thymine dimers in DNA. PR enzyme is found in extracts of both wild-type cells and cells of an aplastidic mutant, W₃BUL, lacking detectable chloroplast DNA, indicating that the PR enzyme is neither coded nor translated exclusively in the chloroplast, but is probably coded in the nucleus and translated in the cytoplasm. Growing cultures of wild-type cells manifest a large increase in PR enzyme activity in vitro upon entering stationary phase. This correlates with the increased photoreactivability of chloroplast inheritance in vivo in stationary phase cells, previously found for Euglena, and suggests that a substantial part of the newly synthesized PR enzyme is available to repair plastid DNA. When dark-grown nondividing wild-type cells are exposed to light, there is a large increase in the specific activity of PR enzyme measured in vitro. This increase is prevented by cycloheximide but not by chloramphenicol or streptomycin, indicating that the enzyme is synthesized on 87s cytoplasmic ribosomes rather than 68s chloroplast ribosomes. Wavelengths of light effective for PR of chloroplast DNA in vivo are also effective for the light induction of PR enzyme. A brief illumination (45 min) of dark-grown nondividing wild-type cells triggers the synthesis of PR enzyme which continues in the absence of light. Growing cultures of W₃BUL also exhibit a preferential synthesis of PR enzyme in the staionary phase of growth, but the specific activity in vitro is consistently ten times higher than that of wild-type. Dark-grown non-dividing cultures of W₃BUL also show a cycloheximide-sensitive light induction of PR enzyme synthesis which, however, is dependent on the continued presence of light. The light induction of PR enzyme synthesis can be regarded as the induction of an enzyme by one of its substrates.     

Optimal operation of high-pressure homogenization for intracellular product recovery

An optimal control methodology for the homogenization of bacterial cells to recover intracellular products is presented. A Fluent computational fluid dynamics (CFD) model is used to quantify the hydrodynamic forces present in the homogenizer, and empirical models are used to relate these forces to experimentally obtained cell disruption and product recovery data. The optimal homogenizer operation, in terms of either constant cell breakage or maximum intracellular product recovery, is determined using these empirical models. We illustrate this methodology with an Escherichia coli bacterial system used to produce DNA plasmids. Homogenization is performed using an industrial APV–Gaulin high-pressure homogenizer. The modeling and optimization results for this E. coli–DNA plasmid system show good agreement with the experimental data.