p53 promotes selection for Fas-mediated apoptotic resistance.

Although p53 inactivation is implicated as a mechanism to explain diminished apoptotic response, it is clear that tumor cells that possess transcriptionally functional p53 can also be resistant to diverse apoptotic stimuli. We hypothesize that oncogenic activation and DNA damage are sufficient stimuli to increase the p53-dependent transcription of Fas and thereby establish a situation in which cell to cell contact could be a selective pressure to either lose p53 function or inactivate components of the Fas death pathway. Examination of genetically matched tumor cell lines that possessed either wild-type or null p53 loci indicated that cells possessing functional p53 increased their surface levels of Fas and Fas ligand (FasL) in response to DNA damage. In contrast, stress induced by changes in the tumor microenvironment such as decreased oxygen did not up-regulate Fas or FasL. Cells with wild-type p53 underwent Fas-mediated killing in the presence of either FasL-expressing killer cells or activating Fas antibodies, whereas cells in which p53 was deleted or inactivated were protected from such killing. Furthermore, Fas and FasL expression and induction became transcriptionally repressed in transformed cells with wild-type p53 with increasing passage, whereas other p53 downstream targets and functions, such as p21 inducibility and cell cycle arrest, remained intact. Repression of the Fas locus could be reverted by treatment with the histone deacetylase inhibitor trichostatin A. These results support a model of tumor progression in which oncogenic transformation drives tumor cells to lose either p53 or their Fas sensitivity as a means of promoting their survival and evade immune surveillance.

Endocrine modulators of necrotic neuron death.

In recent years, there has been extraordinary progress in understanding the cellular and molecular cascades that mediate neuron death following necrotic insults. With this knowledge has come the recognition of ways in which these cascades can be modulated by extrinsic factors, altering the likelihood of subsequent neuron death. In this review, we consider the ability of a variety of hormones to modulate necrotic death cascades. Specifically, we will examine the ability of the stress hormones glucocorticoids and corticotropin-releasing factor, of thyroid hormone, and of pre-ischemic exposure to catecholamines to augment necrotic neuron death. In contrast, estrogen, insulin and postischemic exposure to catecholamines appear to decrease necrotic neuron death. We review the heterogeneous mechanisms that are likely to mediate these hormone effects, some possible clinical implications and the therapeutic potentials of these findings.

Perinatal cocaine exposure inhibits the development of the male SDN.

The sexually dimorphic nucleus of the hypothalamus (SDN) is involved in sexual differentiation of the rat brain. Perinatal cocaine exposure was found to significantly reduce the volume of the male rat SDN (P < 0.001) while having no effect upon the volume of the female SDN. Pregnant dams and their pups were exposed to either saline, 7.5, 15, or 30 mg/kg of cocaine from gestational day 15 through postnatal day 10. Litter size, pup weight, male-female sex ratio, and gross birth defects were unaffected, but maternal weight gain was significantly reduced in cocaine-treated dams. These findings imply that males perinatally exposed to cocaine during their critical period of SDN differentiation may exhibit compromised coital capabilities as well as impaired gonadotropin regulation.