Douglas Hanahan

Hybrid insulin genes reveal a developmental lineage for pancreatic endocrine cells and imply a relationship with neurons

Insulin appears in the developing mouse pancreas at embryonic day 12 (e12). Transgenic mice harboring three distinct hybrid genes utilizing insulin gene regulatory information first express the transgene product two days earlier, at e10, in a few cells of the pancreatic bud. Throughout development and postnatal life, all of the insulin-producing (beta) cells coexpress the hybrid insulin gene. In addition, islet cells containing glucagon, somatostatin, pancreatic polypeptide, and the neuronal enzyme tyrosine hydroxylase coexpress the transgene when they first arise. Similarly, coexpression of these normally distinct islet cell markers occurs during differentiation of the four endocrine cell types. The transgene product also appears transiently during embryogenesis in cells of the neural tube and in neural crest. The results suggest a common precursor for the endocrine cells of the pancreas. Moreover, they imply a relationship between neural and pancreatic endocrine tissue.

Glucagon gene regulatory region directs oncoprotein expression to neurons and pancreatic a cells

The regulatory region of the rat preproglucagon gene targets expression of the SV40 large T oncoprotein to two cell types in transgenic mice, the pancreatic alpha cells and a set of neurons localized in the hindbrain, both of which normally produce preproglucagon. Additional neurons in the forebrain and midbrain stain for T antigen but do not express the endogenous glucagon gene. Synthesis of T antigen in endocrine alpha cells results in the heritable development of pancreatic glucagonomas. In brains of transgenic mice from three independent lineages, expression of the hybrid gene begins at embryonic day 12 in neuroblasts of the hindbrain, where it continues throughout adult life, most notably in the medulla. Remarkably, oncoprotein expression in both proliferating neuroblasts and mature neurons has no apparent consequences, either phenotypic or tumorigenic. Expression of the hybrid glucagon gene in both neurons and islet cells supports a possible interrelationship between these cell types.

Endothelial cell tumors develop in transgenic mice carrying polyoma virus middle T oncogene

Inoculation of newborn mice with the murine polyoma (Py) virus leads to tumor formation in a wide range of tissues. In order to investigate viral oncogenesis, we generated transgenic mice carrying either the Py large T antigen (LT) gene or the Py middle T antigen (MT) gene linked to Py early region regulatory sequences. While Py LT mice exhibit no phenotype, Py MT mice develop multifocal tumors of the vascular endothelium. These hemangiomas are lethal to the animals and can be passaged in vivo. Transgene RNAs and protein are present in both hemangiomas and the testes of these mice, and the Py middle T protein in both tissues is complexed to a cellular tyrosine kinase. The expression of complexed middle T protein in both tumorigenic endothelial cells and unperturbed testes implies that endothelial cells may be particularly susceptible to the action of the middle T oncogene. These observations indicate that Py middle T disrupts the normal strict controls on vascular growth, and suggest that Py MT transgenic mice will provide a model for studying the control of angiogenesis.

Diabetes induced in male transgenic mice by expression of human H-ras oncoprotein in pancreatic beta cells

Transgenic mice expressing an insulin-promoted H-ras hybrid gene in pancreatic beta cells developed beta-cell degeneration and diabetes. The disease was manifested in male mice by hyperglycemia, glycosuria, and reduced plasma insulin levels, which appeared around 5 months of age and led to premature death. Histological analyses revealed large holes within the islets of Langerhans and a reduced number of beta cells. The destruction of the islets was not associated with an obvious inflammatory activity. Ultrastructural analysis showed extensive engorgement in the endoplasmic reticulum of the residual beta cells from diabetic males. The females carrying the insulin-promoted ras gene did not manifest any of the physiological abnormalities observed in males and showed only minor histological and ultrastructural changes, even at much greater ages.

Transplantation of β cells from transgenic mice into nude athymic diabetic rats restores glucose regulation

We have shown that elevated plasma D-glucose levels in experimentally-induced diabetic nude athymic rats can be reduced by intraperitoneal transplantation of microcarrier-attached insulin producing beta cells from the mouse pancreatic beta cell line, beta TC-1. The reduction in the level of hyperglycemia was observed as early as two days following cell transplantation and was associated with a concomitant increase in plasma insulin levels. beta TC-1 cell transplanted diabetic rats had plasma D-glucose levels similar to those found in non-diabetic control animals and remained normoglycemic throughout the 39 day experimental period. The beta TC-1 cell transplanted diabetic rats also had near normalization of body weight, food and water intake and of urine output when compared to control diabetic and non-diabetic rats. Similarly, they exhibited improved blood glucose clearance following intravenous D-glucose administration. These results suggest that beta TC-1 cells regulate D-glucose homeostasis following transplantation into diabetic rat recipients in a manner similar to that of endogenous pancreatic beta cells.

Targeted Expression of Viral Genes to Pancreatic β Cells in Transgenic Mice

Viral agents have been implicated in destructive disorders of β cells, the insulin-producing cells of the pancreatic islets of Langerhans. The clinical manifestations of insulin-dependent diabetes mellitis (IDDM) result from β cell destruction. Several epidemiological studies have implied a correlation between viral infection and diabetes, although the etiology of the disease is certainly more complex than a simple cause and effect relationship [1]. Mice exposed to certain viral agents (e.g., encephlomyocarditis virus) have been found to exhibit lymphocyte infiltration, necrosis, and degranulation of the pancreatic islets, accompanied by hyperglycemia that persists for varying periods of time [2].

MECHANISMS OF DNA-MEDIATED TRANSFORMATION IN ANIMAL CELLS

ABSTRACT Certain cultured cell lines can readily be transformed by exogenous DNA when given as a calcium phosphate coprecipitate. Although stable transformants, detected by biochemical selection, can arise from exposure of 10 6 cells to as little as 10 pg of a purified gene such efficient gene transfer requires the use of vast excesses of carrier DNA. Cells which incorporate a selectable marker, such as thymidine kinase, are also likely to be cotransformed with significant amounts of carrier DNA. By adding well defined DNA sequences to the carrier it is possible to construct cell lines containing virtually any defined DNA sequence. Genetic and biochemical data indicate that selectable markers and carrier DNA become covalently linked in the transformed cell.