Generation of mice that conditionally express the activation domain of Notch2.

The Notch pathway is an intercellular signaling mechanism frequently used for controlling cell fate during organogenesis. There are four structurally related Notch receptors in mice and humans, and Notch1 and Notch2 are essential genes. In this report we describe the construction of a transgenic mouse strain that expresses the Notch2 intracellular domain in response to cell lineage specific expression of Cre recombinase. This approach bypasses the requirement for ligand- receptor interaction and allows the direct determination of the consequences of Notch2 activation in vivo. Exogenous expression of the Notch2 intracellular domain resulted in the developmental arrest of secondary heart field derived cardiomyocytes during the transition from immature alpha-Smooth Muscle Actin expressing cells to mature alpha-Actinin positive cardiomyocytes. In contrast, a cell nonautonomous mesenchymal expansion was observed in semilunar valves. This new conditionally expressed allele of Notch2 can be used in studies by investigators interested in the effects of Notch2 activation in vivo.

Differential activation of kinases in ex vivo and in vivo irradiated mice lymphocytes.

Various kinases, such as tyrosine, protein kinase C (PKC) and MAP kinase, play important role in the cellular response to radiation, but little is known about the specific response in the whole animal. Most studies, except a few, are based on single cells. There is a paucity of data where signaling following whole body irradiation is concerned. In this study a comparison has been made between the activities of these kinases following ex vivo and in vivo irradiation. Tyrosine kinase activity showed no difference in the lymphocytes irradiated ex vivo or in vivo. A significant differential dose-dependent response could be observed in PKC activity. PKC was seen to be activated at the higher dose, i.e., 1 Gy in, in vivo irradiated lymphocytes, whereas in ex vivo irradiated lymphocytes, PKC was seen to be activated at the lower dose, i.e., 0.1 Gy. MAP kinase activity was seen to decrease with an increasing dose in ex vivo irradiated lymphocytes. In vivo MAP kinase activity was seen to increase as the dose increased, with maximum activation at 3 Gy. These kinases are being used to manipulate the tumor response to radiotherapy. Thus it is essential to study the behavior of the above kinases in the whole animal because the difference in response of a single cell to the whole animal may be different.

Dose-dependent differential expression of protein kinase C isozymes in mouse lymphocytes after gamma irradiation in vivo and ex vivo.

Protein kinase C (PKC, now known as Prkc) plays an important role in the response of cells to radiation, but little is known about the specific response of each isozyme in the radiation-induced response of cells in whole animals. However, most studies are based on single cells. There is a paucity of data on signaling after whole-body irradiation. In this study, a comparison has been made between the expression of Prkc isozymes after in vivo and ex vivo irradiation. There was a significant difference in the dose response of the isozymes. In animals in which lymphocytes were irradiated ex vivo, the expression of the Prkca isozyme was found to be maximum at 3 Gy, while in vivo irradiation did not increase the expression beyond that of 1 Gy. Prkcd was marginally activated after 0.1 Gy ex vivo irradiation, whereas there was significant activation of expression after in vivo irradiation with 3 Gy. The response of Prkcz was found to be similar to that of Prkcd. Prkc is a crucial enzyme that is being used to manipulate the response of tumors to radiotherapy. Conventional radiotherapy is delivered at low doses, and hence only those isozymes that are activated at these doses should be taken into consideration. Moreover, the differences between the response of a single cell and that of the whole animal must be considered.