The presence of blood in the transfer catheter negatively influences outcome at embryo transfer.

BACKGROUND: Embryo transfer (ET) influences pregnancy rates in patients undergoing assisted reproduction. Data are conflicting as to which variables affect ET success. This study examines variables that may affect outcome after ET in assisted reproductive technology patients who had high-quality embryos transferred. METHODS: Over a 23 month period, 669 consecutive cycles were examined. Only patients having grade I and grade II embryos, or blastocyst transfers, were included in this retrospective analysis. A total of 584 consecutive cycles met study criteria. At the time of ET, the following variables were recorded: aborted first attempt at ET; presence of blood and/or mucus in or on the transfer catheter after ET; ease of ET as judged by provider; need for mock embryo transfer immediately before the actual transfer and retention of embryos in the transfer catheter. These variables were retrospectively analysed for their impact on implantation rate (IR) and clinical pregnancy rate (CPR). RESULTS: There were 290 gestations (49.7% CPR). Multiple attempts at ET, subjective difficulty of ET, performance of a sham pass immediately prior to embryo transfer, and presence of mucus on or in the catheter did not affect the CPR or IR. No difference was noted in the mean age of patients having or lacking any of these factors. There was a significant association between the presence of blood on or in the catheter and decreased IR (P = 0.015) and CPR (P = 0.004). Retained embryos also decreased IR (P = 0.03). Multivariable analysis confirmed that the presence of blood on the transfer catheter was the most important of these transfer characteristics in predicting IR (P = 0.042) and CPR (P = 0.018). CONCLUSIONS: These results suggest that when only high-grade embryos or blastocysts are transferred, the presence of blood on the catheter is associated with decreased IR and CPR in assisted reproduction.

Estrogenic activity is increased for an antiestrogen by a natural mutation of the estrogen receptor.

The estrogen receptor (ER) functions as a ligand-activated transcription factor which mediates the actions of estrogens and antiestrogens in target tissues. Other investigators have shown that artificial point mutations in the transcriptional activation domain AF-2 of the ligand binding domain (LBD) of the ER can increase the estrogenic properties of antiestrogens, determined by transcriptional activation of estrogen-responsive reporter constructs cotransfected into cells. Although these data provide valuable information about ER function there is no evidence that these mutations occur naturally. We have taken a different approach and examined the naturally occurring codon 351 asp --> tyr mutation in the LBD of ER to stimulate the expression of an endogenous target gene. This approach avoids dependence on artificial reporter constructs and their idealized estrogen response elements (EREs). In this report we describe the regulation of transforming growth factor alpha (TGF alpha) mRNA by estradiol and the antiestrogens keoxifene and ICI 182,780 in our stable transfectants of ER-negative MDA-MB-231 breast cancer cells, which express either the wild-type (S30 cells) or codon 351 asp --> tyr mutant ER (BC-2 cells). The mutant receptor was identified in a tamoxifen-stimulated human breast tumor. Our results demonstrate, for the first time, that a naturally occurring mutation in the ER changes the pharmacology of the antiestrogen keoxifene by increasing estrogenic activity, and that keoxifene exhibits a gene-specific estrogen-like effect with mutant ER but not with wild-type ER. The pure antiestrogen ICI 182,780 maintained complete antagonistic activities in both ER transfectants, demonstrating that its action is unaffected by the mutation.

Nomegestrol acetate, a clinically useful 19-norprogesterone derivative which lacks estrogenic activity.

The estrogenic activity of various 19-norprogestin derivatives has been identified by several laboratories. We have previously hypothesized that the estrogenic activity of these compounds stems from the absence of a methyl group at the 19 position, as various progestins that have a methyl group at this position are not estrogens. To test this hypothesis more directly, we now compare the progestin megestrol acetate against its 19-nor analogue nomegestrol acetate. We also compare these compounds to known estrogens (estradiol, norgestrel, RU486) as well as compounds known to be devoid of estrogenic activity at concentrations as high as 10(-6) M (medroxyprogesterone acetate, R5020, ICI 182780). In growth assays using the MCF-7 and T47D:A18 human breast cancer cell lines, we find that only estradiol, norgestrel and RU486 stimulate proliferation, and this effect can be blocked by the pure antiestrogen ICI 182780. Furthermore, in transient transfection studies using a luciferase reporter construct containing three tandem copies of the Xenopus vitellogenin A2 estrogen response element, estradiol, norgestrel and RU486 can stimulate transcription, while none of the other compounds act as estrogens. Transcriptional stimulation by the estrogenic compounds can be blocked by ICI 182780. Our results demonstrate that the lack of a 19-methyl is not the major determinant for estrogenic activity in 19-norprogestins. We suggest that the 17-hydroxyl group more accurately defines estrogenic action.

A naturally occurring estrogen receptor mutation results in increased estrogenicity of a tamoxifen analog.

We previously identified a codon 351 (Asp-->Tyr) mutant estrogen receptor (ER) in a tamoxifen-stimulated human breast tumor line. To examine its biological activity, we have constructed cell lines from the ER-negative human breast cancer cell line MDA-MB-231 that stably express either the wild type (S30) or mutant ER (BC-2). ER expression was confirmed by Western blot, ligand-binding studies, and ER-enzyme immunoassay. The growth characteristics of the S30 and BC-2 cell lines were compared when treated with estradiol, fixed-ring 4-hydroxytamoxifen [(fr) 4-OH TAM], or ICI 182,780. (fr) 4-OH TAM is a stable, high affinity tamoxifen analog. Many investigators have recognized that growth of ER-negative cell lines stably transfected with ER is inhibited by estradiol. Similarly, both S30 and BC-2 cell lines are inhibited by estradiol in a concentration-dependent manner. (fr) 4-OH TAM has no effect on S30 proliferation but inhibits the growth of BC-2 cells. The pure antiestrogen ICI 182,780 can block the growth-inhibitory effect of estradiol in both cell lines and the growth-inhibitory effect of (fr) 4-OH TAM in the BC-2 cells. In transient transfection analyses using a luciferase reporter plasmid containing two copies of the Xenopus vitellogenin A2 estrogen response element, estradiol stimulated luciferase transcription through both the wild type and mutant estrogen receptors, while (fr) 4-OH TAM stimulated transcription to a greater extent through the mutant receptor. These results demonstrate that the estrogenicity of (fr) 4-OH TAM is increased by binding to the codon 351 mutant ER, and that ER activation and growth inhibition are associated.

Increasing the number of tandem estrogen response elements increases the estrogenic activity of a tamoxifen analogue.

There have been several reports of women who have tumor relapse while on tamoxifen therapy, followed by tumor regression after tamoxifen withdrawal. In such apparently tamoxifen-stimulated tumors, there is likely a genetic change which increases the estrogenicity of tamoxifen. In this study, we determine if increasing the number of estrogen response elements (EREs) in the promoter region of a reporter gene can alter the agonistic activity of fixed-ring 4-hydroxytamoxifen. We show that increasing the number of EREs in the promotor region increases the transcriptional response of the reporter plasmid to estradiol. We also find that while fixed-ring 4-hydroxytamoxifen is unable to stimulate transcription when one ERE is present, transcriptional activation can occur with multiple EREs. These results demonstrate that ERE amplification could explain the agonistic properties of tamoxifen, and suggests a novel mechanism to explain tamoxifen-stimulated breast cancer growth.

The biological action of cDNAs from mutated estrogen receptors transfected into breast cancer cells.

While tamoxifen may inhibit breast cancer proliferation, mutations in the estrogen receptor could potentially result in breast cancer cells which can circumvent the tamoxifen blockade. Previously, we identified a mutation at codon 351 in the estrogen receptor from a tamoxifen-stimulated human breast cancer. This receptor was stably transfected into the estrogen receptor-negative human breast cancer cell line MDA-MB-231 (clone 10A). Clones were compared to stably transfected cell lines containing either the wild type or codon 400 mutant estrogen receptor to study the effect of either estradiol or the tamoxifen analogue, fixed-ring 4-hydroxytamoxifen ((fr)4-OH TAM), on cell growth and reporter gene activation. (fr)4-OH TAM reduced the growth rate in cell lines containing mutant estrogen receptors, while the cell line containing the wild type estrogen receptor is minimally influenced by (fr)4-OH TAM. We then needed to show that the ligand-estrogen receptor interaction resulted in estrogen receptor activation. As a ligand-dependent transcription factor, estrogen receptor activation is measured by its ability to stimulate reporter gene (luciferase) transcription when bound to an estrogenic ligand. We found that the wild type estrogen receptor is activated by estradiol but not by the tamoxifen analogue, while the codon 351 estrogen receptor is activated by both (fr)4-OH TAM and estradiol.

Norgestrel and gestodene stimulate breast cancer cell growth through an oestrogen receptor mediated mechanism.

There is great concern over the long-term influence of oral contraceptives on the development of breast cancer in women. Oestrogens are known to stimulate the growth of human breast cancer cells, and this laboratory has previously reported (Jeng & Jordan, 1991) that the 19-norprogestin norethindrone could stimulate the proliferation of MCF-7 human breast cancer cells. We studied the influence of the 19-norprogestins norgestrel and gestodene compared to a 'non' 19-norprogestin medroxyprogesterone acetate (MPA) on MCF-7 cell proliferation. The 19-norprogestins stimulated proliferation at a concentration of 10(-8) M, while MPA could not stimulate proliferation at concentrations as great as 3 x 10(-6) M. The stimulatory activity of the 19-norprogestins could be blocked by the antioestrogen ICI 164,384, but not by the antiprogestin RU486. Transfection studies with the reporter plasmids containing an oestrogen response element or progesterone response element (vitERE-CAT, pS2ERE-CAT, and PRE15-CAT) were performed to determine the intracellular action of norgestrel and gestodene. The 19-norprogestins stimulated the vitERE-CAT activity maximally at 10(-6) M, and this stimulation was inhibited by the addition of ICI 164,384. MPA did not stimulate vitERE-CAT activity. A single base pair alteration in the palindromic sequence of vitERE (resulting in the pS2ERE) led to a dramatic decrease in CAT expression by the 19-norprogestins, suggesting that the progestin activity required specific response element base sequencing. PRE15-CAT activity was stimulated by norgestrel, gestodene and MPA at concentrations well below growth stimulatory activity. This stimulation could be blocked by RU486. These studies suggest that the 19-norprogestins norgestrel and gestodene stimulate MCF-7 breast cancer cell growth by activating the oestrogen receptor.

A risk-benefit assessment of tamoxifen therapy.

Tamoxifen is the endocrine treatment of choice for all women with hormonally responsive breast cancer. 30 years of experience in both the laboratory and clinical setting have shown tamoxifen to be an effective adjuvant treatment with minor short term adverse effects. However, as therapeutic use has extended to 5 years and beyond, and as clinical trials begin which will assess the effectiveness of tamoxifen as a preventive treatment, concern about possible long term adverse effects is justified. Tamoxifen has an estrogen-like influence on the skeletal and cardiovascular systems, resulting in decreases in both postmenopausal bone loss and low density lipoprotein (LDL) levels. These effects will, it is hoped, result in decreases in the incidences of osteoporosis and coronary heart disease, which are major causes of morbidity and mortality in the postmenopausal age group. Tamoxifen therapy also results in decreased rates of contralateral breast cancer. Long term tamoxifen treatment may result in a small increase in the incidence of endometrial and/or hepatocellular carcinoma, but with millions of women taking tamoxifen for long periods, such small increases in incidence translate to a significant number of women at risk. Tamoxifen is clearly beneficial for short term treatment, but the clinical decision of tamoxifen use in the long term must be made on the individual benefits versus risks of tamoxifen treatment.

The estrogenic activity of synthetic progestins used in oral contraceptives.

BACKGROUND: Oral contraceptives (OC) contain an orally active estrogen in combination with an orally active synthetic progestin derived from 19-nortestosterone. OC have had an enormous positive impact on public health for the past three decades, and in the main, there has been a remarkably low incidence of troublesome side effects. Although estrogens are implicated in an increased incidence of breast and endometrial cancer, epidemiologic studies have not provided convincing evidence to support a direct correlation between OC use and an increase in breast cancer incidence. By contrast, OC do cause a decrease in the incidence of endometrial and ovarian carcinoma. During the past decade, several isolated reports have linked an increased incidence of breast cancer with the use of synthetic progestins. No mechanism for the proliferative potential of progestins has been offered. Therefore, the authors investigated this problem to formulate a hypothesis, based on laboratory data, that might be evaluated in populations at risk. METHODS: The synthetic progestins (19-nortestosterone derivatives) chosen for the study were norethynodrel, norethindrone, norgestrel (levonorgestrel), and gestodene. These were compared with the actions of medroxyprogesterone acetate (MPA). To determine whether the progestins produced their effects via the ER, the cells were transfected with a chloramphenicol acetyl transferase (CAT) reporter gene containing an estrogen response element only activated by ER. RESULTS: The 19-nortestosterone derivatives all stimulated the growth of estrogen receptor (ER)-positive but not ER-negative breast cancer cells in culture. Antiestrogens, but not the antiprogestin mifepristone (also known as RU 486), inhibited progestin-stimulated cell proliferation. MPA did not stimulate cell proliferation. All the synthetic progestins that increased replication also activated CAT. Activation was blocked by antiestrogens but not by mifepristone; the synthetic progestin MPA was inactive. CONCLUSIONS: These studies provided direct evidence that some synthetic progestins exert estrogenic effects through the ER. The results demonstrated that progestins can have a dual effect on estrogen target tissues either to stimulate or differentiate cells. The results suggest that some beneficial estrogen-like effects could be produced by synthetic progestins (e.g., bone preservation), but epidemiologic studies of OC use should focus of the "total estrogen" content to establish whether some formulations place some groups of women at greater risk of having breast cancer.