Correlation of umbilical cord blood hormones and growth factors with stem cell potential: implications for the prenatal origin of breast cancer hypothesis.

Introduction: Prenatal levels of mitogens may influence the lifetime breast cancer risk by driving stem cell proliferation and increasing the number of target cells, and thereby increasing the chance of mutation events that initiate oncogenesis. We examined in umbilical cord blood the correlation of potential breast epithelial mitogens, including hormones and growth factors, with hematopoietic stem cell concentrations serving as surrogates of overall stem cell potential.

Methods: We analyzed cord blood samples from 289 deliveries.

Cellular and molecular regulation of the primate endometrium: a perspective.

This contribution will trace some of the many seminal studies on the female uterus (endometrium) over the centuries and conclude with a description of some current research initiatives in our laboratory. Numerous contributions from many investigators over the years have contributed to our current understanding of endometrial function. The historical section of this chapter is intended to be a brief overall description of some of these efforts and not exhaustive.

Reproducibility of assays for steroid hormones, prolactin and insulin-like growth factor-1 in umbilical cord blood.

We assessed the reproducibility of measurements of plasma hormone and binding protein levels in umbilical cord blood collected from 30 male and female babies. They were delivered as singleton births from full-term pregnancies (gestational age >or= 37 weeks) in a cord blood donation programme. We assayed three plasma replicates from each cord blood sample at two points in time.

The 5' flanking region of the Rhesus monkey H3 (DMBT1) gene contains putative progesterone response elements.

DMBT1 (deleted in malignant brain tumors) encodes a large scavenger receptor cysteine rich (SRCR) protein with proposed tumor suppressor properties due to its frequent deletion or lack of expression in a variety of different tumors including endometrial cancers. The gene is alternatively spliced to produce a number of related proteins with suspected functions in mucosal inflammation and epithelial regeneration. Expression of DMBT1 has been demonstrated in a wide variety of cell types, mostly of epithelial origin, including tissues of the respiratory system, the alimentary system, brain, and reproductive system.

Association of fetal hormone levels with stem cell potential: evidence for early life roots of human cancer.

Intrauterine and perinatal factors have been linked to risk of childhood leukemia, testicular cancer, and breast cancer in the offspring. The pool of stem cells in target tissue has been suggested as a critical factor linking early life exposures to cancer. We examined the relation between intrauterine hormone levels and measurements of stem cell potential in umbilical cord blood.

Microarray profiling of progesterone-regulated endometrial genes during the rhesus monkey secretory phase.

Background: In the endometrium the steroid hormone progesterone (P), acting through its nuclear receptors, regulates the expression of specific target genes and gene networks required for endometrial maturation. Proper endometrial maturation is considered a requirement for embryo implantation. Endometrial receptivity is a complex process that is spatially and temporally restricted and the identity of genes that regulate receptivity has been pursued by a number of investigators.

Role of progesterone in structural and biochemical remodeling of endometrium.

The endometrial response to the varying levels of ovarian steroids is exhibited as alterations in its form and function. These changes in endometrial morphology and physiology, especially those observed during the implantation window are prerequisites to support embryo attachment and invasion. However the state of endometrial receptivity to embryo results from an operative network of several molecular events triggered by estrogen, progesterone and probably some other factors, yet to be discovered.

Temporal regulation of gene expression during the expected window of receptivity in the rhesus monkey endometrium.

Progesterone has been shown to regulate a number of genes and gene networks in the primate endometrium. This action of progesterone is essential to provide an appropriate milieu for embryo-endometrial communication that can lead to implantation and the successful initiation of pregnancy. A temporal regulation of endometrial genes is most likely required to achieve an appropriate state of receptivity in the primate endometrium.

Gene expression in the rhesus monkey endometrium: differential display and laser capture microdissection.

The primate endometrium is a complex heterogeneous tissue that requires proper maturation to achieve a hospitable environment for implantation. Endometrial differentiation and maturation is primarily controlled through the action of progesterone during the secretory phase. Many of the genes and gene networks that are involved in this process are likely to be induced or inhibited in a temporal, spatial, and cell-type specific context within the endometrium.

Assessment and application of laser microdissection for analysis of gene expression in the rhesus monkey endometrium.

We investigated the use of laser capture microdissection (LCM) to identify differences in gene expression between cell types or regions within the rhesus monkey endometrium. Different cell types were harvested from the two major regions of the endometrium during midsecretory phases (Days 21-23) of adequate artificial menstrual cycles: glandular epithelia (G) or stroma (S) from the functionalis (F) or the basalis (B). Amplification of the cDNA populations (primer-specific adaptors) was used to increase the amount of nucleic acid for further analysis.