Purification and characterization of the d-xylose isomerase gene from Escherichia coli

A DNA fragment containing both the Escherichia coli d-xylose isomerase (d-xylose ketol-isomerase, EC 5.3.1.5) gene and the d-xylulokinase (ATP: d-xylulose 5-phosphotransferase, EC 2.7.1.17) gene has been cloned on an E. coli plasmid. The d-xylose isomerase gene was separated from the d-xylulokinase gene by the construction of a new deletion plasmid, pLX7. The d-xylose isomerase gene cloned on pLX7 was found still to be an intact gene. The precise location of the d-xylose isomerase gene on the plasmid pLX7 was further determined by the construction of two more plasmids, pLX8 and pLX9. This is believed to be the first d-xylose isomerase gene that has been isolated and extensively purified from any organism. d-Xylose isomerase, the enzyme product of the d-xylose isomerase gene, is responsible for the conversion of d-xylose to d-xylulose, as well as d-glucose to d-fructose. It is widely believed that yeast cannot ferment d-xylose to ethanol primarily because of the lack of d-xylose isomerase in yeast. d-Xylose isomerase (also known as d-glucose isomerase) is also used for the commercial production of high-fructose syrups. The purification of the d-xylose isomerase gene may lead to the following industrial applications: (1) cloning and expression of the gene in yeast to make the latter organism capable of directly fermenting d-xylose to ethanol, and (2) cloning of the gene on a high-copy-number plasmid in a proper host to overproduce the enzyme, which should have a profound impact on the high-fructose syrup technology.     

Supercritical carbon dioxide explosion as a pretreatment for cellulose hydrolysis

Summary Cellulosic material Avicel was treated with supercritical carbon dioxide to increase the reactivity of cellulose, thereby to enhance the rate and the extent of cellulose hydrolysis. Upon an explosive release of the carbon dioxide pressure, the disruption of the cellulosic structure increases the accessible surface area of the cellulosic substrate to enzymatic hydrolysis. This explosion pretreatment enhances the rate of the Avicel hydrolysis as well as increases glucose yield by as much as 50%.     

Oxygen absorption in microbiological systems of zero order reaction rate

A model of oxygen absorption in microbiological systems of zero order reaction rate is proposed. The partial differential equation was solved to predict the profile of the oxygen concentration boundary layer next to a gas-liquid interface. Generally speaking, the presence of microbial cells always helps to increase the oxygen absorption rate over that of physical absorption. Only when the microbiological reaction is slow as judged by the fact that the reaction time, t_r, is much larger than the diffusion time, t_D, can one rightfully approximate the oxygen absorption in microbiological suspensions by physical absorption.     

Avicel hydrolysis by cellulase enzyme in supercritical CO2

Summary The enzymatic hydrolysis reaction in supercritical CO₂ to produce glucose from cellulosic material Avicel was investigated. In comparison with the result from the enzymatic hydrolysis reaction of Avicel without CO₂ introduced as a reaction medium, the reaction rate and glucose concentration are increased.     

Liposomal muramyl dipeptide therapy of experimental M5076 liver metastases in mice

Summary The effectiveness ofN-acetylmuramyl-l-alanyl-d-isoglutamine (MDP) or of liposomes containing a lipophilic MDP derivative, MDP-glyceroyldipalmitate MDP-GDP in inhibiting the growth of M5076 reticulum cell sarcoma liver metastases in C57BL/6 mice has been determined. MDP (100 µg) or liposomal MDP-GDP (2.5 µmol containing 1 µg) were equally effective in inhibiting liver metastatic growth when given as a single treatment 3 days before tumor cell injection. Therapeutic treatment, initiated 3 days after tumor cell injection and continued for a period of 2 weeks, failed to inhibit metastatic growth. Activation of thioglycollate-elicited peritoneal macrophages or Kupffer cells in vitro with MDP or liposomal MDP-GDP resulted in the expression of tumoricidal activity against M5076 tumor cells. Adoptive cellular therapy with four injections of 2 × 10⁶ macrophages was ineffective: activation of the macrophages with either MDP or liposomal MDP-GDP prior to injection was effective in inhibiting liver metastatic growth. Incorporation of the macrophage toxin dichlorodimethylene diphosphonate within liposomes containing MDP-GDP abolished the ability of such liposomes to induce macrophage or Kupffer cell tumoricidal activity in vitro as well as the antitumor activity when administered 3 days before tumor cell challenge.     

Characterization of antibody covalently coupled to liposomes

We have explored the covalent coupling of fatty acids to immunoglobulin G(IgG). N-hydroxysuccinimide ester of palmitic acid (NHSP) was used to couple palmitic acid to either a mouse monoclonal antibody to the major histocompatibility antigen, H-2^k, or goat antibody to the major glycoprotein of the Molony Leukemia Virus, gp-70. The reaction was characterized in terms of the time course, input ratio of NHSP to IgG, stoichiometry of the coupling, distribution of palmitic acid in the IgG subunits, and the antigen binding capacity of the coupled antibody. Incorporation of the fatty acid modified IgG into liposomal membranes using a detergent-dialysis method was studied as a function of extent of fatty acid coupling. Finally, the binding of IgG-coated liposomes with cells expressing proper antigens was characterized. The major conclusions were: (1) the optimal molar ratio of NHSP to IgG in the reaction was between 10 and 20, which yields about 4–5 palmitoyl chains per IgG molecule; (2) at this level of coupling, the antigen binding capacity of the IgG antibody decreased about 3–4-fold; (3) incorporation of the coupled antibody into unilamellar liposomes (about 1000 Å diameter) can be achieved with a deoxycholate-dialysis method with an optimal lipid-to-protein ratio of 10:1 (w/w); (4) there were about 48 IgG molecules incorporated per liposome under these conditions; (5) the apparent dissociation constant of the liposome-bound antibody under the optimal condition was about 6–7-fold higher than that of the native antibody; (6) binding of antibody to the target cells was accompanied by binding of liposomal lipids; both bindings could be blocked by pretreatment of cell with unmodified antibody.     

Techniques for preparing hydrogel membrane capsules

Summary Techniques for preparing four kinds of hydrogel membrane capsules are described. In the present process the material being encapsulated remains in its original environment in an aqueous suspension. Also, capsule characteristics such as size, membrane thickness, pore-size and surface charge can be controlled over a wide range.     

Vortex behavior in the waldhof fermentor

This is the first part of a systematic study on the mechanisms of the Waldhof fermentor. When an agitator is rotating in a liquid, a vortex will develop on the surface. Air is dispersed into the liquid when the vortex is deep enough to reach the agitator. This is the basic mechanism of air dispersion in a Waldhof fermentor. In this work, experimental results, empirical correlations, and theoretical equations were obtained to relate the vortex depth to a number of physical factors including agitator diameter, agitator speed, tank diameter, liquid depth, liquid viscosity, and so on. The vortex depth was found a function of both Reynolds number and Froude Number.     

Role of endothelial dysfunction in the pathogenesis of reperfusion injury after myocardial ischemia

Endothelial dysfunction occurs after myocardial ischemia and reperfusion characterized by a marked reduction in endothelium-dependent relaxation (EDR) due to reduced release or action of endothelium-derived relaxing factor (EDRF). This reduced EDR occurs in coronary rings isolated from cats 2.5 min after reperfusion and in isolated perfused cat hearts 2.5 min after reperfusion. No decrease in EDR occurs before reperfusion in either preparation, suggesting that this impairment in EDR occurs during reperfusion. The decrease in EDR occurs soon after the generation of superoxide radicals by the reperfused coronary endothelium. Accumulation of neutrophils and myocardial cell injury does not occur until 3-4.5 h after reperfusion. Thus, endothelial generation of superoxide radicals acts as a trigger mechanism for endothelial dysfunction which is then amplified by neutrophil adherence and diapedesis into the ischemic region enhancing post-reperfusion ischemic injury. Agents that preserve endothelial function or inhibit neutrophil activation (e.g., superoxide dismutase, prostacyclin analogs, TGF-beta, antibodies to adhesive proteins) can protect against endothelial dysfunction and myocardial injury, if administered before reperfusion.