The diabetes-prone NZO/Hl strain. Proliferation capacity of beta cells in hyperinsulinemia and hyperglycemia.

New Zealand Obese (NZO) male mice develop a polygenic juvenile-onset obesity and maturity onset hyperinsulinemia. Approximately 50% transit to chronic hyperglycemia. Here we report on the proliferation of beta cells in relation to both the individual's metabolic status and structural parameters of the endocrine pancreas. Proliferating beta cells were quantified in pancreas sections by immunoenzymatic double staining of Ki-67 protein, as a marker for proliferating cells, and endocrine non-beta cells in order to distinguish them from beta cells. In normoglycemic NZO/Hl males Ki-67 labelling indices (IKi-67) of beta cells varied between 0.14 and 1.5%, and correlated significantly with both serum insulin levels and beta cell size. There was no correlation with the glycemic status. In diabetic males, beta cell size was increased. IKi-67 varied between 1 and 3%. The data suggest that the secretory activity of beta cells triggered by glucose, entailed changes in both beta cell hypertrophy and proliferation. As shown by morphometric measurements, beta cell expansion in diabetic mice was limited, in spite of high IKi-67 values. This suggested increased death rates of beta cells.

Genetic Analysis of Substrain Divergence in Non-Obese Diabetic (NOD) Mice.

The non-obese diabetic (NOD) mouse is a polygenic model for type 1 diabetes that is characterized by insulitis, a leukocytic infiltration of the pancreatic islets. During ~35 years since the original inbred strain was developed in Japan, NOD substrains have been established at different laboratories around the world. Although environmental differences among NOD colonies capable of impacting diabetes incidence have been recognized, differences arising from genetic divergence have not been analyzed previously. We use both mouse diversity array and whole-exome capture sequencing platforms to identify genetic differences distinguishing five NOD substrains. We describe 64 single-nucleotide polymorphisms, and two short indels that differ in coding regions of the five NOD substrains. A 100-kb deletion on Chromosome 3 distinguishes NOD/ShiLtJ and NOD/ShiLtDvs from three other substrains, whereas a 111-kb deletion in the Icam2 gene on Chromosome 11 is unique to the NOD/ShiLtDvs genome. The extent of genetic divergence for NOD substrains is compared with similar studies for C57BL6 and BALB/c substrains. As mutations are fixed to homozygosity by continued inbreeding, significant differences in substrain phenotypes are to be expected. These results emphasize the importance of using embryo freezing methods to minimize genetic drift within substrains and of applying appropriate genetic nomenclature to permit substrain recognition when one is used.

The diabetes-prone NZO/Hl strain. II. Pancreatic immunopathology.

We report the first combined light and electron microscopic analysis of the pancreas during the development of type 2 diabetes in the New Zealand Obese (NZO) mouse. As in most other polygenic rodent models of type 2 diabetes, hyperglycemia associated with beta cell destruction is male sex-limited. Increasing degrees of hyperinsulinemia and transition to diabetes were clearly reflected by the islet volume fraction, by the beta cell granulation state, and by ultrastructural changes, primarily of the endoplasmic reticulum. One of the unusual histopathologic features of NZO mice of both sexes was the presence of B-lymphocyte enriched leukocytic aggregates in the pancreas. Immunocytochemical analysis of the pancreas of 52-week-old diabetic males indicated enrichment for CD19(+) B lymphocytes. Staining of adjacent sections for CD3 and CD5 indicated CD5 coexpression on some of the CD19(+) cells, suggesting the presence of the B1-B subset associated with generation of natural autoantibodies in other autoimmune-prone New Zealand mouse strains. In addition, plasma cells in peri-insular leukocytic infiltrates were identified by electron microscopy. Hence, although autoimmunity has previously proven to be a secondary manifestation of beta cell destruction in most rodent models of type 2 diabetes, the present observations suggest that B lymphocyte function, in association with male gender, may contribute to the development of insulin resistance and chronic hyperglycemia in the NZO model.