Pancreatectomized swine as a model of diabetes mellitus

The development of a model of diabetes mellitus using swine offers the potential for new investigations in the study of human diabetic complications. In particular, animal models for the study of accelerated atherosclerosis associated with diabetes are important and presently lacking. Swine were selected because they have a natural susceptibility to atherosclerosis and have plasma lipoprotein patterns which are close to those of humans. Diabetes mellitus was induced in nine miniature swine by total pancreatectomy. Following surgery, they were maintained on porcine derived insulin at doses predicated on blood glucose levels. Pancreatic enzymes were replaced by dietary supplementation. Eight of the nine pigs were pancreatectomized successfully and stabilized with insulin. After initial weight loss, the pancreatectomized pigs maintained growth rates comparable to controls. Hypoglycemia and bacterial infections were the major problems experienced. Post-operative survival ranged from 50 days to 455 days. Our study shows that swine can be pancreatectomized successfully and maintained as insulin dependent animals, presenting a realistic model for research on the complications of diabetes.     

Continuous ethanol production by a flocculent strain of Zymomonas mobilis

Summary Cell retention and ethanol production using the flocculent bacterium Zymomonas mobilis NRRL B-12526 were studied in three bioreactor configurations. The flocculent growth characteristic of this strain and a special reactor design were combined to achieve relatively high cell concentrations in a continuous bioreactor for the conversion of glucose to ethanol.Research sponsored by the Office of Energy Research, U.S. Department of Energy, under contract W-7405-eng-26 with the Union Carbide Corporation.     

Microbial accumulation of neptunium

Summary Resting cells of several species of microorganisms removed neptunium (Np) from an aqueous solution. Concentrations of up to 15 mg Np per g cells (dry weight) were obtained. Maximum uptake byMicrococcus luteus occurred in less than 10 min.Operated by Martin Marietta Energy Systems, Inc. for the U.S. Department of Energy under Contract No. DE-AC05-84OR21400.     

Unusual structure of nuclei in a B–mutant strain of Schizophyllum commune with intercellular nuclear migration

Serial sections of multinucleate hyphae of a B–mutant strain of Schizophyllum commune , in which intercellular nuclear migration takes place, revealed appendages attached to nuclei. The appendages were strand–like organelles surrounded by a membrane with an electron–dense content. In addition, the outer membranes of the envelopes of adjacent nuclei were often joined and surface sections of these nuclei showed fibrous material with only a few nuclear pores. These ultrastructural features have not been reported before in the vegetative hyphae of S. commune , and they are suggested to be necessary for intercellular nuclear movement. The appendages may create the force or may result from the force necessary for the movement of the nucleus, while the joining of the outer membranes of the nuclear envelopes makes possible simultaneous movement of several nuclei, although only one has an appendage. The fibrous material in the nuclear envelope may facilitate sliding of the nuclei through the cytoplasm.