Patricia A. Estes

XactMice: humanizing mouse bone marrow enables microenvironment reconstitution in a patient-derived xenograft model of head and neck cancer

The limitations of cancer cell lines have led to the development of direct patient-derived xenograft models. However, the interplay between the implanted human cancer cells and recruited mouse stromal and immune cells alters the tumor microenvironment and limits the value of these models. To overcome these constraints, we have developed a technique to expand human hematopoietic stem and progenitor cells (HSPCs) and use them to reconstitute the radiation-depleted bone marrow of a NOD/SCID/IL2rg−/− (NSG) mouse on which a patient’s tumor is then transplanted (XactMice). The human HSPCs produce immune cells that home into the tumor and help replicate its natural microenvironment. Despite previous passage on nude mice, the expression of epithelial, stromal and immune genes in XactMice tumors aligns more closely to that of the patient tumor than to those grown in non-humanized mice—an effect partially facilitated by human cytokines expressed by both the HSPC progeny and the tumor cells. The human immune and stromal cells produced in the XactMice can help recapitulate the microenvironment of an implanted xenograft, reverse the initial genetic drift seen after passage on non-humanized mice and provide a more accurate tumor model to guide patient treatment.

Mechanisms Controlling Steroid Receptor Binding to Specific DNA Sequences

Mammalian progesterone receptors activated by hormone binding in nuclei of intact cells exhibit substantially higher binding activity for specific DNA sequences than receptors bound with hormone and activated in cell-free cytosol. Differences in DNA-binding activity occur despite the fact that both activated receptor forms sediment at 4S on sucrose gradients and are apparently dissociated from the heat shock protein 90. This suggests that hormone-induced release of heat shock protein 90 from receptors is necessary, but not sufficient for maximal activation of DNA binding. This report is a review of studies from our laboratories that have examined the role of receptor interaction with other nuclear protein factor(s), and receptor dimerization in solution, as additional regulatory steps involved in the process of receptor activation and binding to specific gene sequences.

Immunoaffinity Purification and Structural Analysis of Human Breast Cancer Progesterone Receptors

Progesterone receptors (PR) are well established as an important clinical marker in breast cancer in predicting patient response to adjuvant endocrine therapies1 and as markers of disease aggressiveness.2 Development of antibodies specific for human PR and methods for their use in the immunocytochemical detection of receptors in breast tumors would be of value clinically in providing a number of advantages over the biochemical ligand binding assays that are currently in use for routine PR determinations. Immunocytochemistry for example, will make PR screening accessible to most pathology laboratories, is possible to perform with cellular aspirates and very small tissue samples, and will provide information on cellular heterogeneity and PR content in individual cells which itself may be of diagnostic value.