Active cell death (ACD) in hormone-dependent tissues such as the prostate and mammary gland is readily induced by hormone ablation and by treatment with anti-androgens or anti-estrogens, calcium channel agonists and TGF beta. These agents induce a variety of genes within the hormone-dependent epithelial cells including TRPM-2, transglutaminase, poly(ADP-ribose) polymerase, Hsp27 and several other unidentified genes. Not all epithelial cells in the glands are equally sensitive to the induction of ACD. In the prostate, the secretory epithelial cells that are sensitive to hormone ablation are localized in the distal region of the prostatic ducts, and are in direct contact with the neighboring stroma. In contrast, the epithelial cells in the proximal regions of the ducts are more resistant to hormone ablation, probably because the permissive effects of the stroma are attenuated by the presence of the basal epithelial cells, which are intercalated between the epithelium and stroma. The underlying biology of ACD in prostate and mammary glands, and its relevance to hormone resistance, is discussed in this review.
After weaning, the mammary gland ceases lactation and involutes. The wet weight of the gland decreases by 70% within 4 days of weaning. This involves significant tissue remodelling as the ducts regress and return to the resting state. The presence of apoptotic bodies in the luminal epithelial compartment 2 to 3 days after weaning provides clear evidence that a substantial proportion of the regression is attributable to the induction of active cell death (ACD) of the epithelial cells. These changes in the architecture of the gland were found to be mirrored by changes in gene expression. The steady-state level of beta-casein mRNA decreased rapidly after weaning from the high levels seen during lactation to undetectable levels by 8 days after weaning. The steady-state levels of expression of a number of genes associated with ACD, including TRPM-2, tissue transglutaminase (TGase) and poly(ADP-ribose) polymerase (PARP), increased transiently during this time-frame. The steady-state level of TRPM-2 mRNA increased 2 days after weaning, reaching a peak on day 4, and decreasing to undetectable levels by day 8 after weaning. The steady-state levels of two other mRNAs, TGase and PARP, showed very similar kinetics. In contrast, the mRNA for Hsp 27, which has been shown to be induced during prostate regression, was not significantly induced in the regressing mammary gland. In-situ hybridization demonstrated that the TRPM-2, TGase and PARP genes were expressed predominantly in the luminal epithelial cells of the ducts. These cells expressed beta-casein mRNA during lactation, and underwent ACD after weaning. While the ultrastructural changes in the mammary gland after weaning, and the induction of TRPM-2, TGase and PARP mRNAs, are reminiscent of apoptosis in the prostate, several features of the process are different. Most notably, the disruption of the secretory processes and the lack of increased expression of Hsp 27 in the regressing mammary gland suggest that there may be a number of important events in ACD that are not common to all cells.
We have developed a novel library-to-library cross-screening technology to clone unique mRNAs that are expressed during tissue regression. We have cloned a number of regression selected genes (RSG) that are expressed during the regression of the mammary gland and ventral prostate of the rat after the removal of the respective trophic hormone. In this investigation, we have characterized one of these genes, RSG-2, that is homologous to cathepsin B, a thiol protease that has been previously identified as one of the extracellular proteases which is activated in metastatic cells. The steady-state levels of RSG-2 mRNA in the normal prostate are low but detectable. In the regressing prostate, RSG-2 mRNA levels peak at 3-4 days after castration, at the time that tissue regression is maximal. The gene is induced in a similar fashion in the regressing mammary gland. Using in situ hybridization, we have established that RSG-2 mRNA is expressed in the luminal epithelial cells of the prostate and mammary gland that are known to undergo active cell death, suggesting that it may be a general marker for secretory epithelial cell death. Analysis of the distribution of the cathepsin B protein by immunofluorescence microscopy demonstrates that there is diffuse, but punctate, expression of the protein in all of the luminal epithelial cells of the normal prostate and mammary gland. However, at early times after hormone ablation in both glands, the majority of the increase in cathepsin B protein appears to result from redistribution to the basal aspect of the cells. At later time points, there appears to be increased amounts of the protein which is localized to the apoptotic bodies. These results suggest that RSG-2, or cathepsin B, is required for the local degradation of the basement membrane. which is one of the earliest morphologically recognizable events of active cell death.
Cell adhesion molecules (CAMs) are intimately involved in a variety of cellular processes, including development, cell growth, apoptosis, and differentiation. Interaction of CAMs with components of the extracellular matrix (ECM), growth factors, and other CAMs provides an intricate regulatory mechanism for a diverse range of cellular responses. Embigin is a developmentally expressed protein that is a member of the immunoglobulin superfamily (IgSF) class of CAMs. We have identified embigin as a gene expressed during tissue regression in rat prostate and lactating mammary gland following hormonal ablation. In the absence of the appropriate hormone, the secretory epithelial cells of these two tissues undergo successive waves of apoptotic cell death co‐incident with extensive reorganization of the surviving tissue. Using Northern analysis, in situ hybridization analysis, RT‐PCR, and Western analysis, we have characterized the expression of embigin mRNA and protein in both regressing prostate and mammary gland. During development of the prostate gland, increased expression of embigin is correlated with the appearance of highly organized lumenal and ductal structures. Embigin is also expressed in a variety of adult tissues including heart, liver, lung, and brain. Zoo‐blot analysis with the rat embigin cDNA indicates that embigin homologs exist in species as diverse as Homo sapiens and Drosophila melanogaster, suggesting that it has been highly conserved during evolution. Embigin protein is expressed at readily detectable levels in a variety of prostate and mammary cancer cell lines, and in some cell lines the expression of embigin appears to be down‐regulated in the presence of ECM. Our data have led us to propose a model in which embigin functions as a regulator of cell/ECM interactions during development and in the homeostasis of normal adult tissues. Dev. Genet. 21:268–278, 1997. © 1997 Wiley‐Liss, Inc.
The Role of Homophilic Binding in Anti-tumor Antibody R24 Recognition of Molecular Surfaces
The murine antibody R24 and mouse-human FvIgG1() chimeric antibody chR24 are specific for the cell-surface tumor antigen disialoganglioside GD3. Xray diffraction and surface plasmon resonance experiments have been employed to study the mechanism of "homophilic binding," in which molecules of R24 recognize and bind to other molecules of R24 though their heavy chain variable domains. R24 exhibits strong binding to liposomes containing disialoganglioside GD3; however, the kinetics are unusual in that saturation of binding is not observed. The binding of chR24 to GD3-bearing liposomes is significantly weaker, suggesting that cooperative interactions involving antibody constant regions contribute to R24 binding of membranebound GD3. The crystal structures of the Fabs from R24 and chR24 reveal the mechanism for homophilic binding and confirm that the homophilic and antigen-binding idiotopes are distinct. The homophilic binding idiotope is formed largely by an anti-parallel -sheet dimerization between the H2 complementarity determining region (CDR) loops of two Fabs, while the antigen-binding idiotope is a pocket formed by the three CDR loops on the heavy chain. The formation of homophilic dimers requires the presence of a canonical conformation for the H2 CDR in conjunction with participation of side chains. The relative positions of the homophilic and antigen-binding sites allows for a lattice of GD3-specific antibodies to be constructed, which is stabilized by the presence of the cell membrane. This model provides for the selective recognition by R24 of cells that overexpress GD3 on the cell surface.
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