Steroid receptor status and the epidemiology of breast cancer

Steroid receptor status and the epidemiology of breast cancer

Steroid Receptor Status and the Epidemiology of Breast Cancer Nancy Kreiger, PhD, Will D. King, MSc, Lynn Rosenberg, E. Aileen Clarke, MB, MSc, Julie ...

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Steroid Receptor Status and the Epidemiology of Breast Cancer Nancy Kreiger, PhD, Will D. King, MSc, Lynn Rosenberg, E. Aileen Clarke, MB, MSc, Julie R. Palmer, ScD, and Samuel Shapiro, MB, FRCP(E)

ScD,

This case-control study examined risk factors for breast cancer according to tumor estrogen receptor (ER) status and progesterone receptor (PR) status. The data included 607 cuse putients and 12 14 control subjects matched by age and residence. Of528 case patients with steroid receptor information, 67% had ER-positive tumors and 55% had PR-posirive tumors. Odds ratios for ERpositive and ER-negative breast cancer were similar with respect to menopausal smtus, uge at menarche, history of cystic breast disease, and Quetelet Index. Family history of breast cancer was a stronger risk factor for ER-negative than for ER-positive breast cancer and the odds ratios for number of births were suggestive of a diff erent effect. While ER and PR status were highly correlated, there were some differences in their associations with risk factors. Odds ratios for PRpositive and PR-negative breast cancer differed f or number of births and were suggest&e of differences with respect to menopausal status, Quetelet Index, and family history of breast cuncer. These findings do not suggest diff erent causal pathways for ER-positive and ER-negative breast cancer. However, they do indicate that PR status may play a role in the etiology of breast cuncer. Ann Epidemiol 1991; J:513-523. KEY WORDS:

case-control

Breast neophms, study.

estrogen receptors, progesterone receptors, risk fucfors,

INTRODUCTION

Both tumor estrogen receptor (ER) status and progesterone receptor (PR) status are established indicators of prognosis in the clinical course of breast cancer. ER-positive (ER+) tumors and PR-positive (PR+) tumors are associated with improved response to hormonal therapy, a longer disease-free interval, and improved survival (l-5). To determine whether steroid receptor status is important in the etiology of breast cancer, investigators have examined the relationship between receptor status and known risk factors. ER status is reportedly associated with age and race, but the literature contains inconsistent reports on the association between ERs and menopausal status, age at menopause, age at menarche, number of births, body mass, history of cystic breast disease, and family history of breast cancer (6). A smaller amount of research is available on the subject of PRs and risk factors for breast cancer. The study reported here examined the relationship between steroid receptor status and known risk factors for breast cancer. Associations with known risk factors are presented in a case-control analysis of receptor-positive and receptor-negative tumors.

From the Division of Epidemiology and Statistics, Ontario Cancer Treatment Toronoto, Ontario, Canada (N.K., W.D.K., E.A.C), and Slone Epidemiology Health, Boston University School of Medicine, Brookline, MA (L.R., J.R.P., Address reprint requests to: WIII D. King, MSC, Diwsion of Epidemiology and Treatment and Research Foundation, 7 Overlea Boulevard, Toronto, Ontario, Received November 16, 1990; revised December 2 1, 1990. 0 1991 Elsevier Science Puhhshing Co., Inc.

and Research Foundation, Unit, School of Public S.S.). Statistics, Ontario Canc.er Canada M4H 1A8.

1047-27971911503.50

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METHODS

Eligible case patients were all women who had a histologically confirmed primary carcinoma of the breast; who were newly diagnosed between 1982 and 1986; who had no previous history of cancer (with the exception of nonmelanotic carcinoma of the skin); who were 20 to 69 years old at diagnosis; who were residents of metropolitan Toronto, Ontario, Canada; and who had been referred to the Princess Margaret Hospital, the major cancer treatment hospital in metropolitan Toronto. Populationbased control subjects were matched (2 : 1) to the case patients for age (by decade) and neighborhood of residence. Potential controls were selected from tax assessment rolls for residents maintained by the Ontario Ministry of Revenue. The collection of these records is mandated by provincial law, and the records are completely updated every 3 years. Interview questionnaires were completed by 630 case patients and 1214 control subjects, representing 79% of potential case patients and 65% of potential controls. Nonparticipation among the case patients was due to patient refusals (12%) and physician refusals (9%). A further 23 case patients were excluded because controls could be not found. For the remaining 607 case patients, 1874 eligible neighbors were contacted: 1214 (65%) were interviewed, and 660 (35%) refused. Records of 528 case patients were linked to the steroid receptor files of the Ontario Cancer Registry to obtain both ER and PR concentrations. The receptor assays were carried out using the dextran-coated charcoal method to determine the amount of receptor protein in the tumor (7). An assay result was judged acceptable if the assay was done within 6 weeks of diagnosis. If more than one assay was done within a l-day period, the higher result was taken. If more than one assay was done in the 6-week period after diagnosis, the one closest in time to the date of diagnosis was taken. Data were collected with the use of a standardized structured questionnaire adAll interviews were conducted in the ministered by trained female interviewers. subjects’ homes within 6 months of diagnosis. The questionnaire covered the following areas: sociodemographic factors; medical and reproductive histories; family history of breast cancer; and histories of caffeine, alcohol, and tobacco use. Study results pertaining to alcohol consumption and diazepam use in relation to risk of breast cancer have been reported elsewhere (8, 9). Factors selected in this analysis were those considered to be established risk factors for breast cancer and those potentially hormone-related: age, menopausal status, age at menarche, number of births, Quetelet Index, history of cystic breast disease, and family history of breast cancer. Subjects who reported having menstruated within 1 year prior to diagnosis were classified as premenopausal. From the subjects’ reported height and weight, the Quetelet Index, a measure of body mass, was calculated as weight divided by height squared (kg/m3). Body mass definitions, at age 20 and at the time of diagnosis, were determined on the basis of the distribution of the Quetelet Index values for the control group: The lowest 10% were classified as low; the upper lo%, as high; and the middle 80%, as normal. Family history of breast cancer was positive if the subject reported a history of breast cancer in either her mother or her sister(s). For both ERs and PRs, receptor positive was defined as 10 femtomoles or greater specific binding sites per milligram of protein (fmolimg); receptor negative was less than 10 fmolimg.

Kreiger et al. STEROID RECEPTORS AND BREAST CANCER

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515

Data analysis was divided into two parts. First, an analysis of breast cancer case patients (case-case comparison) was done to determine if tumor receptor status varied by age and menopausal status. Second, a matched case-control analysis was carried out to estimate the relative risk of breast cancer associated with suspected risk factors, according to the receptor status of the tumor. The odds ratio (OR) was used to estimate relative risk. Conditional logistic regression models containing a term representing the interaction between the factor under study and receptor status were used to obtain matched risk estimates according to tumor status and to test for differences .between these estimates (10). Risk estimates were adjusted for all potential confounders (main effects). The P value testing for a difference between the estimates for receptor-positive and -negative disease is provided. For both case-case and case-control comparisons, separate analyses were performed for ER and PR status.

RESULTS Receptor concentrations were available for 528 (87%) of the case patients. Table 1 displays the distributions of ER and PR concentrations; 67% of case patients were ER+, and 55% were PR+. A strong positive association was found between ER and PR status: 76% of tumors were concordant with respect to their ER and PR status.

Associations with Estrogen Receptor Status Figure 1 shows the percentage of ER+ tumors among case subgroups by age and menopausal status. Excluded are postmenopausal case patients aged 20 to 39 (n = 7) and one premenopausal case patient in the age group 60 to 69 because of small frequencies and the chance of misclassification. The proportion of ER+ tumors increased with age in premenopausal case patients, from 38% in those aged 20 to 39 to 80% in those aged 50 to 59. No effect of age was evident in postmenopausal case patients: Approximately 70% in each age group had ER+ tumors. Removing case patients younger than 60 who had a hysterectomy but retained one or both ovaries did not change these results. An effect of menopausal status independent of age could be assessed only among age groups in which there was some variation in menopausal status. In those aged 40 to 49 and 50 to 59, pre- and postmenopausal case patients had a similar percentage of

TABLE Receptor status Negative

1

Distribution

of cases by tumor receptor concentrations

Concentration (fmol/mg) O-4 5-9

Total receptor-negative Positive 10-19 20-49 50-99 100-199 200-399 400-599 600+ Total receptor-positive

Estrogen No. 141 36 177 58 115 72 52 33 15 6 351

receptor Percentage 26.7 6.8 33.5 11.0 21.8 13.6 9.8 6.3 2.8 1.1 66.5

Progesterone No. 160 76 236 57 91 48 54 28 8 6 292

receptor Percentage 30.3 14.4 44.7 10.8 17.2 9.1 10.2 5.3 1.5 1.1 55.3

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Kreiger et al. STEROID RECEPTORS AND BREAST CANCER

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8070+ f! s

3 Post-menopausal

6050.

403020lo0

I 20 to 39

I 40 to 49

I 50 to 59

1 60 to 69

Age group

FIGURE 1 Percent of tumors that ate estrogen receptor-positive (ER+) according to subgroups by age and menopausal status-premenopausal (n = 209) and postmenopausal (n = 311).

ER+ tumors. For instance, in case patients aged 50 to 59, 78% of tumors were ER+ in premenopausal case patients, and 72% of tumors were ER+ in postmenopausal case patients. Case patients and matched controls with complete information on all risk factors were included in the conditional regression analysis (501 case patients, 969 control subjects). Case and control distributions according to risk factors and receptor status for those included in the analysis are shown in Table 2. Table 3 presents adjusted ORs from the matched case-control analysis of risk factors according to ER status. Postmenopausal women and women who were older at menarche were at a nonsignificantly decreased risk for both ER+ and ER-negative (ER-) disease. Women who had given birth four or more times were at decreased risk of ER+ breast cancer and at elevated risk for ER- breast cancer, with ORs of .67 and 1.34, respectively. However, neither of these risk estimates was statistically different from 1.0, and the difference between them also was not statistically significant (P = .13). An analysis that included age at first birth (in place of number of live births) in the model, compared different categories of age at first birth and nulliparity to those giving birth before the age of 2 1. The relative risks for those whose first birth came after the age of 30 were protective and not significantly different from 1.0 for both ER+ and ER- breast cancer. Nulliparity slightly increased risk for ER+ breast cancer (OR, 1.20; 95% confidence interval (CI), .72-1.89) and slightly decreased the risk for ER- breast cancer (OR, .80; 95% CI, .34-l .69). This difference was not significant (P = .41). A family history of breast cancer elevated the risk for both ER+ and ER- breast cancer. However, this risk was greater for ER- (OR, 5.69) than for ER+ (OR, 1.75) breast cancer (test of difference, P = .Ol ). A history of cystic breast disease was associated with elevated risk for both ER+ and ER- breast cancer, ORs being 3.01 and 4.2 1, respectively.

Quetelet

Index (current)

Family history of breast cancer History of cystic breast disease Quetelet Index (age 20)

Age (y) at first hirth

No. of births

Age (y) at menarche

Menopausal status

20-39

40-49 50-59 60-69 PrePost511 12-14 E-15 0 1-3 24 220 21-30 231 No births No Yes No Yes Low Normal High LOW Normal High

34.4 29.9 34.1 45.9 20.4 65.6 14.1 24.9 59.3 15.9 14.1 50.0 11.1 24.9 87.1 12.9 85.6 14.4 15.3 71.6 13.2 12.9 68.6 18.6

8.4 27.2

ER+

and controls

Cases (n = 334)

(%) of cases

Age (Y)

Distribution

Level

2

Risk factor

TABLE

8.7 27.2 34.6 29.5 35.9 64.1 16.6 68.5 14.9 18.6 65.7 15.7 11.8 58.7 10.9 18.6 93.0 7.0 94.9 5.1 12.7 73.8 13.5 11.8 75.3 12.9

Controls (n = 644)

by risk factors

14.4 24.0 59.9 16.2 19.8 47.9 8.4 24.0 85.0 15.0 83.8 16.2 18.0 74.9 7.2 18.0 67.1 15.0

25.7 29.9 23.4 21.0 52.1 47.9 19.8 65.9

Cases (n = 167)

ER-

receptor

25.2 30.8 23.4 20.6 52.3 47.7 17.5 66.8 15.7 22.7 62.8 14.5 16.3 50.5 10.5 22.7 95.7 4.3 94.1 5.9 16.9 72.6 10.5 13.5 76.6 9.9

Controls (n = 325)

and by estrogen

12.3 30.7 32.5 24.5 44.0 56.0 22.4 64.3 13.4 25.6 61.4 13.0 15.9 47.3 11.2 25.6 87.0 13.0 85.2 14.8 14.8 71.1 14.1 13.4 68.6 18.0

PR+

12.4 30.7 33.0 24.0 42.7 57.3 18.0 68.2 13.9 18.5 65.9 15.5 13.1 57.9 10.5 18.5 93.3 6.7 94.0 6.0 12.5 73.6 13.9 11.8 74.9 13.3

Controls (n = 534)

and urogesterone

Cases (n = 277)

(ER) status

74.6 7.6 16.1 67.4 16.5

16.5 25.0 28.6 29.9 35.3 64.7 17.4 67.4 15.2 23.2 57.1 19.6 16.1 51.8 8.9 23.2 85.7 14.3 84.8 15.2 17.9

PR-

4.6 16.1 73.1 10.8 13.1 76.8 10.1

16.6 25.5 28.3 29.7 39.8 60.2 15.6 67.6 16.8 21.8 63.2 14.9 13.6 53.6 11.0 21.8 94.7 5.3 95.4

Controls (n = 435)

(PR) status”

Cases (n = 224)

rece!xor

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TABLE 3 Adjusted” odds ratios (OR) and 95% confidence intervals receptor-positive (ER+) and estrogen receptor-negative (ER-) breast

ER+

Risk factor Menopausal

stat&

Age (y) at menarche

No. of births

Age (y) at first birth

Family history of breast cancer History of cystic breast disease Quetelet

Index (age 20)

Quetelet Index (current)d

ER-

Level

OR

Pre-

1.00

1.00

Post-

.88 .55-1.41 1.00 .76 .52-1.10 .77 .47-1.25 1.00 .65 .45- .93 .67 .41-1.10 1.00 .71 .45-1.10 .87 .49-1.55 1.20 .72-1.98 1.00 1.75 1.11-2.76 1.00 3.01 1.84-4.93 1.24 .82-1.87 1.00 1.06 .69-1.61 1.17 .76-1.82 1.00 1.73 1.17-2.56

.91 .53- 1.57 1.00 .91 .53- 1.58 .71 .34- 1.49 1.00 .88 .49- 1.55 1.38 .64- 2.96 1.00 .72 .38- 1.37 .55 .23- 1.33 .80 .34- 1.69 1.00 5.69 2.67-12.16 1.00 4.21 2.00- 8.87 1.04 .60- 1.78 1.00 .65 .31- 1.36 1.67 .93- 3.05 1.00 2.03 1.06- 3.87

511 12-14 z-15 0 1-3 24 520 21-30 231 No births No Yes No Yes Low Normal High Low Normal High

95% CI

(Cl) for estrogen cancers

OR

95% CI

Test

for difference

between groups P .77 .57 .87 .38 .I3 .89 .44 .41 .Ol

.46 .61 .26 .33 .68

’Estimates are adjusted in a conditmnal loglstx regressionmodel for age, menopausal status, age-menopausal status mteraction, age at menarche, number of brths, famlly history, cystic breast disease, and Quetelet Index (age 20). h Postmenopause estimate 1s a point esnmate for the odds ratm at age ot d~agnosn of 50 years. ’Age at first birth replaces no. of births in the model. ’ Quetelet Index (current) replaces Quetelet Index (age 20) m the model.

High Quetelet Index at age 20 was associated with a small elevation in the risk for ER+, but was slightly protective of ER- breast cancer. The difference between these estimates was not statistically significant (P = .26). High Quetelet Index at diagnosis elevated the risk for both ER+ and ER- disease.

Associations

with Progesterone Receptor Status

Figure 2 shows the percentage of PR+ tumors among case subgroups by age and menopausal status. As with ER status, the proportion of PR+ tumors increased with age in premenopausal case patients, from 45% in those aged 20 to 39 years, to 84% in those aged 50 to 59. No effect of age was evident in postmenopausal case patients. In age groups where there was some variation in menopausal status, premenopausal case patients accounted for a greater proportion of PR+ tumors than did postmenopausal case patients. In case patients aged 50 to 59 years, 84% of tumors were PR’ in premenopausal case patients compared to only 50% in postmenopausal case patients. Table 4 presents the ORs from the matched case-control analysis of risk factors according to case PR status. A nonsignificant difference in risk for PR+ and PRnegative (PR-) tumors was found for menopausal status (P = .ll). Postmenopausal women were found to be at decreased risk for PR’ tumors (OR, .68) and elevated risk

AEP Vol. November

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6 1991: 513-523

1, No.

3020100

I

I 20 to 39

I

I

50 to 59

40 to 49

60 to 69

Age group FIGURE 2 Percent of tumors that are progesterone subgroups by age and menopausal status-premenopausal 311).

TABLE

4

receptor-positive (PR’) according to (n = 209) and postmenopausal (n =

Adjusted” odds ratios (OR) and 95% confidence (PR+) and progesterone receptor-negative

receptor-positive

PR+

intervals (CI) for progesterone (PR-) breast cancers PR-

Risk factor

Level

OR

Menopausal statusb

PreI’ost511 12-14 215 0 l-3 24 520 21-30 231 No births No Yes No Yes LOW Normal High LOW Normal High

1.00 1.00 .68 .41-1.13 1.76 .80-3.87 1.00 1.00 .71 .48-1.05 .93 .56-1.54 .77 .45-1.32 .il .37-1.35 1.00 1.00 .61 .41- .92 .93 .57-1.51 .48 .27- .84 1.64 .86-3.09 1.00 1.00 .65 .40-1.05 .44-1.32 .76 .86 .45-1.64 .57 .28-1.18 1.25 .73-2.14 .75 .39-1.44 1.00 1.00 1.86 1.12-3.09 4.05 2.21-7.45 1.00 1.00 2.51 1.48-4.25 4.88 2.54-9.40 1.21 .77-1.90 1.14 .70-1.85 1.00 1.00 1.10 .69-1.74 .65 .35-1.21 1.24 .77-2.01 1.35 .80-2.25 1.00 1.00 1.68 1.09-2.57 2.10 1.22-3.64

Age (y) at menarche

No. of births

Age (y) at first birth‘

Family history of breast cancer History of cystic breast disease Quetelet Index (age 20)

Quetelet Index (current)d

’ Estimatesare adjusted in mteractmn, age h Postmenopause

at menarche. e&mate

a conditional number IS a point

log~st~

of births, esnmate

‘Age at first birth replacesno. of buths in d Quetelet Index (current) replacesQuetelet

regresswn

famdy for the the

95%

CI

model

OR

for age,

menopausal

history. cystic breast disease, udds ran” at age of dqnosis

model.

Index

95%

(age

20)

in the

model.

CI

staws,

and Quetelct of 50 years.

Test for difference between groups P

.I1 .41 .83 .19 .Ol .68 .42 .24 .05 .12 .87 .18 .82 .52 age-menopausal Index

(age

smtus 20).

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Kreiger et al. STEROID RECEPTORS

for PRcant

tumors

reduced There

AEP Vol. 1, No. 6 November 1991: 513-523

AND BREAST CANCER

(OR,

1.76).

risk for both

A later age at menarche PR+ and PR-

were differences

.Ol).

Women

(OR,

.48) and at higher

breast

in risk according

who gave birth

was associated

to PR status

four or more times

risk for PR-

tumors

for number

women

decreased

were

risk for PR-

significantly

different

significant

at elevated

breast

(OR,

1.64).

risk for PR+

cancer

(OR,

.75).

of births

(P =

were at lower risk for PR+ tumors In an analysis

age at first birth (in place of number of live births) in the model, birth (>30) was nonsignificantly protective for both PR’ and Nulliparous

with a nonsignifi-

cancer.

breast

Neither

from 1.0, and the difference

cancer

(OR,

of these

between

that

included

late age at first live PR- breast cancer.

them

1.25)

and

risk estimates

was

was not statistically

(I’ = .24).

A family

history

of breast

cancer

cancer

(OR,

1.86),

but was associated

cancer

(OR,

4.05).

The difference

cal significance PR+ (OR,

(P = .05).

2.51)

High Quetelet had a slight

(OR,

effect

these

breast

for PR-

the

risk for PR+ breast

elevated

estimates

risk for PR-

was of borderline elevated

breast statisti-

the risk for both

cancer.

elevated

breast

(I’ = .18). High Quetelet

cally significant

elevated

of cystic breast disease

4.88)

Index at age 20 slightly

protective

PR+ and PR-

between

A history

and PR-

moderately

with substantially

the risk for PR+ breast cancer

cancer.

This difference

Index at diagnosis

and

was not statisti-

elevated

the risk for both

tumors.

DISCUSSION Risk factors status.

were examined

An attempt

cation,

which

might

different

subgroups

studies

of risk factors

Both (11-14). tumors status

in women

with breast cancer,

was made to identify

risk groups,

be differentially be identifiable, within

associated then

breast

with

it would

cancer

stratified

within

by steroid

the larger disease

various

risk factors.

be appropriate

recegtor classifiShould

to conduct

future

subtype.

the ER and PR distributions

are highly

skewed,

in our data and in others

Good

has been

reported

on

it should

be noted

agreement,

as positive are highly

however,

or negative correlated,

(14). and

Additionally, that

similar

associated with the two measures. A strong positive association between in this analysis

concurs

with previous

on is the lack of independent after adjustment A number

increasing

findings

association

for age (10, of studies

risk factors

the

might

ER status

of

that ER and PR

be expected

age and ER+ tumor

( 12, 13, 15-19).

between

categorization

to be

status found

Also generally and menopausal

agreed status,

11, 14, 16).

that black women have a lower prevalence of ER+ too few black case tumors than do white women (13, 17, 20). 0 ur study contained patients to analyze this factor; however, removing these case patients did not alter study results. In our case-control higher

risk for ER-

reported

analysis, than

family history

for ER+ breast

of breast cancer McTiernan

cancer.

was associated with a and colleagues (11)

reported a like result, while other case-control studies reported an elevation in risk that is similar for both ER+ and ER- breast cancer ( 17, 18, 2 1). Our results concerning number of births are in agreement with several casecontrol studies that reported breast cancer but increased literature

is somewhat

a protective effect of a greater number of births for ER+ risk for ER- breast cancer (11, 15, 21). However, the

inconsistent

(17,

18).

521

Kreiger et al. STEROID RECEPTORS AND BREAST CANCER

AEP Vol. I, No. 6 November 1991: 513-523

In general, menopausal cerning

our findings

status

the relationship

strong

confirm

with ER status.

associations

of other

previous

of the relationships

reports

It is difficult risk factors

to make substantial

to ER status

in our data and the inconsistent

of age and

conclusions

because

of both

results reported

con-

the lack of

by other

investiga-

tors. Differences status,

race,

tency

in the various

of results

and

cutoff

reported

points

varied

between

cutoff

chosen

for the studies.

results

analysis,

our case-control tumors. With breast the

tumor

consistent

basis.

status

status,

of number

Quetelet

of menopausal many

our data suggest

for breast

(2) Relative

accuracy

with

may identify

other

differences

have

examined

and precision

distinct

of breast

the

those

cancer

PRs in their

analysis.

tumors

on a

for the PR assay then (11).

(2, 5, 22, 23),

cancer

in

between

for case patients

are poorer

research

PR-

found

relationship

with ER concentration

breast

In our

for PR+ and PR-

than

few have included

correlated

study.

with age and in

in risk for PR+ and

(1) It is not available

epidemiologic

etiologically

differed

and family history

but more pronounced,

cancer,

because:

under

tumors.

status,

studies

the (15).

ER and PR classifica-

However,

of births

Index,

for PR’ and PR-

(3) PR is highly

along

tumor

was found to increase

the effects

have

to date,

(21) to 30 fmol/mg

in the two analyses.

included

the ER assay (7).

between

for study,

status,

conducted

of PR+ tumors

ERs and risk factors

our data,

of concordance

receptor

studies

the percentage

Although

is seldom

negative

from 3 fmolimg

were in the same direction,

PR status

and

inconsis-

chosen

by the risk factors

of differences

ER analysis.

parameters

breast cancers

the exception

cancer

ranged

to age, menopausal

to the general

distinguishes

menopausal

were suggestive

In addition,

in case-control

ER+ tumors

analysis,

Also,

study according

of positive

were anticipated

that PR status better case-case

definition

For example,

of the high degree

similar

under

and time of test may contribute

in the literature.

to define

Because tions,

populations

stage of disease,

However,

suggest

to a greater

that

extent

PR than

does ER status. In our study,

neighborhood

by socioeconomic factors

under

status.

study,

not have introduced status

and,

hence,

cancer.

Although

pronounced since

resulting

spurious

associations,

there

differences are needed

ER and PR status.

that

to suggest were

or differences

differences different

between

pathways

according

This finding

and PRs are biologically

our results

and to clarify the relationship

important

anisms.

It is, of course,

possible

to investigate are indicative

that the relatively

further of distinct

small observed

more

is unexpected

correlated

in our data actually

breast

PR analyses,

to confirm

It is particularly

receptor

to ER status

are highly

of association

it would

to steroid

for ER+ and ER-

our ER and

to PR status were found.

patterns

on some

However,

detected.

in risk factors causal

confounding

in overmatching

according

the associations

similarities

according

were used to minimize

in the loss of associations.

not invalidate

we found enough

ER and PR status

ERs. Studies

subjects

may have resulted

possibly should

In conclusion, were not strong

controls

This approach

dependeiit

whether

or not the

pathogenic deviations

on

between mechin risk are

due to chance, but it may be that different subtypes of breast cancer are determined, in part, by different constellations of risk factors. This research was supported in part by Ontario

Ministry

of Health

research

grant 01617; the Ontario

Research Foundation, Toronto, Ontario; search Foundation, Baltimore, MD.

and the Alcoholic

Cancer Beverage

Treatment Medical

and Re-

The authors are grateful for the collaboration of the attending physicians at Princess Margaret Hospital, Sunnybrook MedIcal Centre, Toronto General Hospital, and Mt. Sinai

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Hospital. We are also grateful to the interviewers who collected the data-Anne Allen, Rosemary Chepa, Suzanne Gale, Kathleen Gillespie, Lindsay Hall, Linda Harrel, Virginia Hunter, Beverly Linden, Muriel Relton, Shirley Rothery, Irene Servos, Ann Skene-Melvin, Sybil Tinker, Kathy Carroll, Binny Heaton, Helene Katz, Maxine Newton, Barbara Walker, and Linda West; Verna Cundari and Phyllis Disenhouse who coordinated the study; and Leonard Gaetano and Marguerite Angeloni who managed the data.

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