`
`]. Steroid Biochem. Molec. Biol. Vol. 59, No. 5/6, pp. 449—457, 1996
`Copyright © 1996 Elsevier Science Ltd. All rights reserved
`Printed in Great Britain
`0960—0760/96 $15.00 + 0.00
`
`PII: S0960-0760(96)00140-9
`
`RU 58668: Further In Vitro And In Vivo
`
`Pharmacological Data Related to its
`Antitumoral Activity
`
`P. Van de Velde,‘* F. Nique,1 P. Planchon,2 G. PrévostflL
`J. Brémaud,1 M. C. Hameau,l V. Magnien,2 D. Philibertl and
`G. Teutsch1
`
`’Roussel Uclaf, 102 Route de Noisy, 93235, Romainville Cedex, France and ZIOCMH, 129 Avenue de Stalingrad,
`93000, Bobigny, France
`
`Previous studies with the pure antiestrogen RU 58668 showed that this compound proved to be
`highly antiproliferative in vitro, and to be the only antiestrogenic compound so far known to induce
`long-term regression of MCF—7 tumours implanted into nude mice. In order to obtain more insight
`into the therapeutic potential of this 'molecule, we performed a new set of experiments in vitro and
`in vivo in comparison with tamoxifen andlor ICI 182,780. In vitro, 1 nM RU 58668 induced an ac-
`cumulation of MCF—7 cells in GOIGl phases of the cell cycle within 48 h and, in contrast to trans-4-
`hydroxy-tamoxifen, blocked the invasiveness of ras-transfected MCF—7 cells into the chick embryo
`heart during the three weeks of co-culture. An in viva dose-effect relationship study showed that
`RU 58668 induced a regression of MCF—7 tumour with as low a dose as 10 mglkglweek, and that such
`an effect can not be obtained either with a sublethal dose of adriamycin or with ICI 182,780,
`(2—250 mglkglweek). This reduction in the tumour volumes accords with histological modifications
`of the tumours, which showed a decrease in the ratio of epithelial cells over the tumoral mass, and
`with a concomitant decrease in their regrowth potential when reimplanted into naive nude mice.
`Taken together, these results suggest a promising usefulness for RU 58668 in the treatment of meta-
`static breast cancer in women. Copyright © 1996 Elsevier Science Ltd.
`
`3'. Steroid Biochem. Melee. Biol., Vol. 59, No. 5/6, pp. 449—457, 1996
`
`INTRODUCTION
`
`Partly agonistic antiestrogens, such as tamoxifen, have
`been widely used in the treatment of estrogen recep-
`tor-positive metastatic breast cancer for more than 20
`years. In addition, partly successful attempts at treat-
`ing non-mammary tumours which express the estro-
`gen receptor have been reported with tamoxifen or
`derivatives [1—7]. The use of “pure” antiestrogens,
`without partial agonistic activity, however, has been
`suggested for many years [8], because the estrogenic
`component of tamoxifen could be directly linked to
`the occurrence of secondary tumours, especially at the
`endometrial level [9]. It could also be one of the par—
`
`
`ameters involved in the escape of advanced tumours
`from tamoxifen treatment, as suggested by in vivo stu-
`dies in mice [10], and may even be directly involved
`in the stimulation of breast cancer metastasis [11]. In
`other respects, it has been postulated that mammary
`tumour growth could be stimulated by autocrine or
`paracrine growth factors which could replace the es—
`trogenic stimulation [12, 13]. Under growth factor—
`stimulating conditions, mixed antiestrogens are poor
`inhibitors of cell growth in vitro [14, 15], even if an
`indirect effect of tamoxifen on tumoral growth has
`been described in vivo, via a decrease of circulating
`growth factors [16].
`This led the ICI group to synthesize the first pure
`antiestrogens, exemplified by ICI 164,384 [17] and
`ICI 182,780 [14, 18],
`the latter being in phase II
`clinical trials [19, 20]. We recently described a new
`pure antiestrogen,
`llfi-[4-[5-[(4,4,5,5,5,-pentafluoro—
`penty1)sulfony1]pentyloxy]phenyl]-estra-1,3,5 (10)—tri-
`449
`
`*Correspondence to P. Van de Velde. Tel: +33 1 49 91 59 20;
`Fax: +33 1 49 91 39 00.
`'l'Present address:
`Institut Henri Beaufour,
`91966 Les Ulis, France.
`Received 21 Mar. 1996; accepted 26 Jun. 1996.
`
`av. du Canada,
`
`5
`
`
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`AstraZeneca Exhibit 2033 p. 1
`InnoPharma Licensing LLC v. AstraZeneca AB IPR2017-00900
`
`
`
`450
`
`P. Van de Velde et al.
`
`[15, 21-23],
`ene—3,17fi—diol: RU 58668 (scheme 1)
`which displayed improved in vitro antiproliferative ac-
`tivities when compared to ICI 182,780 and similar
`antiuterotrophic activities
`in mice or
`rats. When
`tested for
`their
`activities
`on MCF~7
`tumours
`
`implanted in nude mice, RU 58668 was the only
`compound able to induce a long—lasting reduction (at
`least 25 weeks) of the tumour volume [23]. When
`administered monthly at at dose of 250 mg/kg as sub—
`cutaneous oily injections, tamoxifen and ICI 182,780
`slowed down, or at the best stopped, tumoral growth
`without inducing a tumour regression [15]. In order
`to get more insight
`into the causes of this striking
`difference between the in viva antitumoral activities of
`
`the two “pure antiestrogens”, we performed a set of
`new experiments. First, the dose/antitumoral activity
`relationships of RU 58668 and ICI 182,780 were stu—
`died in order to compare the doses of the two com—
`pounds which would induce the maximal effect.
`Second,
`experiments on the regrowth ability of
`tumour fragments excised from animals previously
`treated with these two compounds and tamoxifen
`were carried out, along with histological examination
`of the tumoral
`tissues. In addition,
`in vitro experi—
`ments were undertaken to study the effect of RU
`58668 on the kinetics and intensity of cell cycle modi—
`fications. Invasiveness of the very highly tumorigenic
`ras—transfected MCF—7
`(MCF—7vht)
`in
`chick
`embryonic heart was also studied to evaluate the in—
`fluence of this compound on the metastatic potential
`of MCF—7 nodules into non—tumoral tissues.
`
`MATERIALS AND METHODS
`
`Chemicals
`
`Bromodeoxyuridine (BrdUrd), propidium iodide,
`trisodium citrate and 3,3’-diaminobenzidine were pur-
`chased
`from Sigma.
`Fluorescein
`isothiocyanate
`(FITC) was from Becton Dickinson and fetal calf
`serum (FCS) from Boehringer Mannheim, Germany.
`Unless otherwise stated, all
`the culture media were
`obtained from Gibco.
`
`In vitro studies
`
`(HTB 22 from
`Cell cycle analysis. MCF—7 cells
`ATCC) were seeded (5 x 105 cells)
`in Dulbecco
`modified essential medium (DMEM) without phenol
`red supplemented with 10% dextran charcoal-treated
`FCS into 25 cm2 flasks. Concentrations of RU 58668
`
`(0.01—1 nM) were added at the cell seeding time. Cell
`cycle analysis was performed as described by Khoch—
`bin et al.
`[24]. To isolate cells in S-phase, BrdUrd
`was added to the culture medium for 15 min at 37°C,
`cells were then trypsinized, washed in phosphate—buf-
`fered saline (PBS) and fixed with 70% ethanol. Incor—
`porated BrdUrd was
`revealed with a monoclonal
`antibody anti-BrdUrd conjugated with FITC. To
`
`quantify the DNA content, cells were centrifuged and
`resuspended in a staining solution containing 7.6 ,uM
`propidium iodide and 4 mM trisodium citrate for
`10 min at 37°C. Double-stained cells were analysed in
`the PAC Scan flow cytometer (Becton Dickinson).
`
`Dot-plots obtained after cytofluorometric analysis
`allowed the determination of labelled cells (S—phase)
`from unlabelled cells (GO/G1 and G2 — M phase).
`Invasiveness of tumorigenic cells. The human breast
`cancer cell—line MCF—7ras, a generous gift of C.
`Sommers (Georgetown University, Washington, DC,
`USA.) was established after the transfection of the
`Hras oncogene in the MCF—7 ductal adenocarcinoma
`cell—line [25]. A very highly tumorigenic MCF—7 line
`(MCF—7vht) was obtained by injecting monolayers of
`MCF—7ras cells (2 x 106/01 ml) subcutaneously near
`the mammary gland of 5—week—old female Swiss nude
`mice (Iffa Cre'do, Les Oncins, France). After
`six
`weeks, one mouse was killed, the tumour was cut out,
`cut into pieces of 1—2 mm3 and cultured in a 25 cm2
`flask with DMEM supplemented with 10% FCS.
`This process was performed twice.
`ICI
`The dose effect
`relationship of RU 58668,
`182,780
`and
`trans—4—hydroxy—tamoxifen
`(4-OH—
`tamoxifen) on the growth of these cells, cultured as a
`monolayer in DMEM without phenol red, in the pre-
`sence of 5% charcoal—stripped serum, has been carried
`out in 24 multiwells. The cell growth was evaluated by
`a fluorimetric DNA assay as previously described [15].
`Furthermore, invasiveness properties of the MCF—
`7vht were evaluated, using the following protocol:
`cells were scraped from the plastic flask surface, the
`pellet was harvested in 1 ml of DMEM without phe-
`nol red, with 10% charcoal—stripped serum (FCS),
`1% glutamine and 1% sodium pyruvate and placed
`on top of a semi—solid medium composed of 1%
`Noble agar (Difco) in distilled water at a 1:1 ratio
`and 2 x DME medium supplemented with 20% FCS
`in 60 mm Petri dishes,
`in order
`to obtain solid
`nodules. These nodules were subcultured once a
`
`week by cutting small pieces with microsurgical scis—
`sors. Fresh heart fragments were dissected from a 8-
`day embryonic chick and closely joined side by side to
`MCF—7vht nodules in culture medium with or with—
`out 0.1 nM RU 58668 or 4-OH—tamoxifen in the
`
`three—week culture,
`a
`absence of estradiol. After
`nodule—heart fragment complexes were fixed overnight
`in Bouin’s fixative, embedded in paraffin and pro—
`cessed for histological examination. The presence of
`epithelial cells in chick embryonic heart was revealed
`by the three—step indirect method using murine
`monoclonal antibodies to cytokeratin gp 56 kD (KLl,
`Immunotech, France)
`as
`first antibody (dilution
`1:400). The second antibody was a rabbit peroxidase—
`conjugated anti-mouse IgGs
`(Dakopatts Co.
`Inc.,
`Denmark)
`(dilution 1:20). The third antibody was
`a
`pig
`peroxidase—conjugated
`anti-rabbit
`IgGs
`(Dakopatts)
`(dilution 1:20). The 3,3’—diaminobenzi-
`
`
`
`AstraZeneca Exhibit 2033 p. 2
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`
`Further Pharmacological Studies of RU 58668
`
`451
`
`dine was used as peroxidase-substrate—chromogen and
`Harris haematoxylin as counterstain.
`
`In vivo studies
`
`MCF—7 cell culture and tumour settlement. MCF—7
`
`cells from ATCC (HTB 22) were routinely cultured
`and
`subpassaged
`in minimal
`essential medium
`(MEM) with phenol red in the presence of 5% FCS
`as previously described [15]
`in 75 cm2 flasks. When
`subconfluent, the MCF—7 cells were trypsinized and
`resuspended in the above-mentioned medium at a
`density of 5 x107 cells/ml. One hundred microlitres
`of this suspension was injected subcutaneously into
`the right mammary fat pad of four to five week old
`female balb/ca nude mice (Iffa Credo). Tumour
`growth was stimulated by a weekly percutaneous ad-
`ministration of 5 mg/kg estradiol
`(E2) dissolved in
`10 ,ul ethanol. When tumours reached 250—500 mm3
`(calculated as width2 Xlength/Z),
`the animals were
`killed and the tumours cut into small pieces for reim—
`plantation. All the experiments were carried out with
`tumour fragments obtained from a single tumour.
`Dose activity relationship of RU 58668 on MCF—7
`tumours. Nude mice were
`subcutaneously
`(s.c.)
`implanted with 1—2 mm pieces of MCF—7 tumour,
`obtained as described above, and received a weekly
`administration of 5 ing/kg E2 percutaneously (p.c.)
`for five weeks. Animals were then randomized accord-
`
`ing to their tumour volume (week 0) and treated
`weekly with 0.25 mg/kg E2 alone, or with a weekly
`subcutaneous injection of 2, 10, 50 or 250 mg/kg of
`test compounds, suspended in arachis oil. A control
`group received E2+ the sublethal dose of 10 mg/kg
`adriamycin by intraperitoneal route in saline on weeks
`0 and 3. The tumour volume was checked every week
`and, at the end of the experiment (week five), the ani—
`mals were killed by cervical dislocation and the
`tumours and uteri were removed and weighed. The
`
`tumour evolution was calculated as the ratio: tumour
`volume on week five/tumour volume on week 0.
`
`Incidence of a pretreatment with RU 58668 on tumour
`regrowth. After a five-week induction of the tumours,
`mice were randomized into four groups of five ani-
`mals which received a weekly administration of
`0.25 mg/kg E2 alone or along with two s.c. injections
`of 250 mg/kg RU 58668, ICI 182,780 or tamoxifen
`(one on week 0 and one on week five). On week 10,
`the animals were killed and each tumour was cut into
`
`1—2 mm pieces which were reimplanted into five
`naive nude mice leading to groups of 25 animals bear—
`ing tumours previously treated by E2, E2+ RU
`58668, E2+ ICI 182,780 or E2+ tamoxifen. The
`growth of these tumours was stimulated by a weekly
`administration of 5 mg/kg E2 for six weeks. The
`tumour growth was checked every week in order to
`evaluate the incidence of the previous treatment on
`their evolution into non-treated mice.
`
`the
`correlate
`to
`In order
`studies.
`Histological
`regrowth profiles with histological parameters, a 14-
`week experiment, in which animals received 250 mg/
`kg test compounds on weeks 0, 5 and 10 along with
`0.25 mg/kg E2 weekly, was carried out. On week 14,
`mice were killed and the tumours were removed and
`
`fixed in Bouin’s solution, embedded in paraffin and
`processed for histological examination. Preparations
`were stained with Masson’s trichrome technique in
`which collagen appears in green, cell nuclei in crim—
`son red and cytoplasm in light brown.
`
`RESULTS
`
`In vitro studies
`
`Eflect on the MCF—7 cell cycle. Table 1 presents the
`compared fractions of MCF—7 cells in GO/Gl, in S
`and in G2 + M phases, either untreated or treated
`
`Table 1. Distribution of MCF—7 cells in the various phases of the cell cycle
`24h
`
`Control
`
`4-0H—tamoxifen
`
`ICI 182,780
`~
`
`R1158668
`
`1o—9
`10‘8
`10'7
`10‘6
`1o-11
`10—10
`10—9
`10—11
`10””
`10—9
`
`(30K31(%0
`
`45
`
`44
`45
`45
`46
`49
`50
`
`S(%0
`
`35
`
`34
`34
`35
`32
`31
`29
`
`G2/M(%)
`
`G0/G1(%)
`
`19
`
`22
`20
`19
`23
`21
`21
`
`52
`41
`48
`49
`55
`53
`54
`57
`51
`54
`59
`
`48h
`
`S(%)
`
`27
`35
`31
`28
`23
`24
`25
`18
`24
`22
`16
`
`G2/M(%)
`
`21
`23
`21
`23
`22
`22
`21
`25
`24
`24
`25
`
`Cells were untreated or treated with 0.01 to lnM of the pure antiestogens for 24 or 48 h or with 1 nM to 1 uM of 4-OH-tamoxifen for
`48 h. At appropriate times, bromodeoxyuridine (BrdUrd; Sigma) was incorporated in cells in the S-phase. Incorporated BrdUrd was
`revealed with a monoclonal antibody anti-BrdUrd conjugated with fluorescein isothiocyanate (FITC; Becton Dickinson). To quantify
`DNA content, cells were resuspended in a staining solution containing 7.6 uM propidium iodide. Double-stained cells were analysed in
`the FAC Scan flow cytometer (Becton Dickinson). Dot-plots obtained after cytofluorometric analysis allow the determination of 60/
`G1, S-phase and G2 — M phase.
`
`
`
`AstraZeneca Exhibit 2033 p. 3
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`452
`
`P. Van de Velde et al.
`
`0.035 ,4; 0.010 nM, 0.09 i 0.03 nM and 1.4 i 0.6 nM
`(mean: SEM of three or four experiments). More—
`over,
`the two former compounds induced a nearly
`complete inhibition of cell growth (290%), whereas
`4—OH-tamoxifen induced only a limited growth inhi-
`bition (50—60%) of the MCF—7vht cell line.
`Efi‘ect on invasiveness of MCF—7vht in chick embryonic
`heart. Striking differences between 4—OH—tamoxifen
`and RU 58668 were also observed on the in vitro inhi-
`
`invasiveness in chick embryo
`bition of MCF—7vht
`heart. Fig. 2b shows chick embryonic heart after a
`three week contact with a nodule of MCF—7vht in the
`
`presence of RU 58668 at 10‘9 M. No epithelial cells,
`stained with the specific epithelial cell antibody KL]
`cytokeratin, had invaded the heart fragment. At the
`same concentration, 4-OH—tamoxifen (Fig. 2c) was
`unable to prevent invasiveness as shown by the pre-
`sence of several stained cells in the embryonic tissue
`(see arrows). In the untreated-control group, embryo-
`nic tissue cannot be distinguish from MCF—7vht cells
`(Fig. 2a).
`
`In vivo studies
`
`Dose activity relationship of MCF—7 tumours implanted
`in nude mice. A dose activity relationship study was
`undertaken in order
`to determine
`the maximal
`
`tumour inhibitory effect of RU 58668 in this model.
`As shown in Fig. 3, the maximal antitumoral activity
`of RU 58668 and ICI 182,780 was reached at the
`dose of 50 mg/kg weekly: RU 58668 induced a re-
`gression of the tumours, whereas ICI 182,780 was
`only able to slow down the tumour growth (respective
`ratio
`of
`tumour
`volumes:
`0.35 i 0.05
`and
`1.72 -l_- 0.39, P< 0.01). A higher dose of the two com-
`pounds (250 mg/kg/week) did not induce significantly
`stronger effects. The regression of MCF—7 tumours
`induced by RU 58668 was observed at doses starting
`from 10 mg/kg/week. On the contrary, ICI 182,780
`was not able to induce any regression of the tumours
`on that model, whatever the doses used. Nevertheless,
`in these animals, the two compounds displayed simi-
`lar antiuterotrophic effects at equivalent doses (Fig. 4).
`In order to test
`the sensitivity of these MCF—7
`tumours to chemotherapeutic agents used in the
`clinic, we chose the established drug adriamycin. The
`dose used (two injections of 10 mg/kg) was the high—
`est one compatible with the toxicity of the compound.
`In this model, adriamycin only led to a decrease in
`tumoral growth, without regression, an effect signifi-
`cantly smaller than that of 10 mg/kg/week RU 58668
`(respective ratios of tumour volume at the end of the
`experiment: 1.56 i 0.18 and 0.61 i 0.07, P< 0.01).
`The relatively poor effect of adriamycin in this model
`shows that these tumours have a strong growing abil-
`ity when implanted in nude mice.
`Effect of RU 58668 on tumour regrowth. We have pre—
`viously shown that RU 58668 induced the regression
`of E2—stimulated MCF—7 tumours implanted in nude
`
`with 4—OH-tamoxifen, ICI 182,780 or RU 58668.
`Treatment of MCF—7 cells with 10'9M RU 58668
`for 48 h resulted in a 40% decrease of the number of
`
`cells in S-phase with a corresponding increase in the
`number of cells in GO/Gl phase. The experiment
`with RU 58668 was carried out
`three times. It
`is
`
`interesting to note that a reproducible and significant
`(P< 0.05) effect of RU 58668 on the cell cycle
`appeared after only 24h. Only the presented exper-
`iment compared the three compounds at 24 and 48 h.
`In this experiment 4-OH—tamoxifen and ICI 182,780
`seem to be inactive at 24 h. Low concentration
`
`(1 nM) of 4—OH-tamoxifen increased S-phase at 48 h.
`One micromole of that compound was required for
`reducing the cell number in S—phase. After a five-day
`treatment no difference could be observed between
`
`treated and untreated groups, all cells being accumu-
`lated in GO/Gl phases. This effect
`in the control
`group is related to the cell confluence.
`Ejfect on in vitro proliferation of MCF—7vht. The ras—
`transfected MCF—7vht cell line, cultured in the pre—
`sence of 5% stripped serum, showed a two to three
`times higher “spontaneous” proliferation rate than
`standard MCF—7 (data not shown). This allowed us
`to study the effect of test compounds on the growth
`of these cells, without any exogenous stimulating
`agent. Fig.
`1 shows the activity of RU 58668, ICI
`182,780 and 4-OH-tamoxifen after a seven-day cul-
`ture of MCF—7vht cells. RU 58668 was 2.5 times
`
`more potent than ICI 182,780 and 40 times more
`potent than 4-OH-tamoxifen to inhibit the growth of
`these
`cells,"
`with
`respective
`IC5o’s
`of
`
`EFFECT ON ras-TRANSFECTED MCF-7 CELL LINE
`
`
`
`+ RU 58668
`
`-—O— ICI 182,780
`+ 4-0H-tamoxifen
`
`100
`
`80
`
`60
`
`40
`
`20
`
`DNA("/0ofcontrol)
`
`o
`10-12
`
`10'11
`
`10-10
`
`10-9
`
`10 ‘3
`
`10 '7
`
`10 '6
`
`concentration (M)
`
`Fig. 1. In vitro activity of RU 58668, ICI 182,780 and 4-OH-
`tamoxifen on the MCF—7vht cells. The ras-transfected MCF-
`7vht cells were cultured in DMEM without phenol red in the
`presence of 5% charcoal-stripped serum and the indicated
`concentration of test compounds. Medium was changed
`every two to three days, and the DNA was assayed after eight
`days. Results are mean 1 SEM of three or four experiments.
`
`
`
`AstraZeneca Exhibit 2033 p. 4
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`
`454
`
`200
`
`180
`
`160
`
`140
`
`_. NO
`
`H OO
`
`00O
`
`0‘O
`
`bO
`
`20
`
`
`
`Uteriweight(mg)
`
`P. Van de Velde er al.
`
`
`
`0
`
`2
`
`20
`
`50
`
`250
`
`Dose (mg/kg/week)
`
`lowest weights, suggesting that RU 58668 is able to
`induce qualitative modifications in the tumours.
`Histological studies. After a separate 14-week exper—
`iment, designed with the classical protocol comparing
`RU 58668,
`ICI 182,780 and tamoxifen,
`tumours
`were submitted to histological examination. Those
`from RU 58668—treated animals (Fig. 7D) displayed a
`high level of collagen (which appears in green) and a
`lower density of epithelial cells (which appear in red)
`than controls (Fig. 7A). Tumours from RU 58668-
`treated animals displayed a fibroadenomateous aspect.
`Tumours excised from ICI 182,780 (Fig. 7C) or 4—
`OH—tamoxifen-treated (Fig. 7B) animals displayed in-
`termediate histological profiles. In addition, necrotic
`structures, recognized by the loss of nuclear details
`with karyorrhexis or extreme pyknosis and the loss of
`nuclear staining characteristics, were seen consistently
`in control and tamoxifen—treated tumours, in contrast
`to ICI 182,780 and RU 58668—treated tumours (data
`not shown).
`
`Fig. 4. Dose effect relationship of RU 58668 and ICI 182,780
`on mice uteri weight. At the end of the five-week experiment
`described in Fig. 3, the animals were killed and the uteri
`were removed and weighed. On this parameter, RU 58668
`and [CI 182,780 displayed the same activity. *P< 0.05;
`**P< 0.01 vs E2 (Mann-Whitney test).
`
`DISCUSSION
`
`This paper describes in vitro and in viva exper-
`iments carried out in order to complete the pharma-
`cological profile of RU 58668 and to gain more
`
`E2
`E2 + tamoxifen
`
`as
`
`volumeweekn/volumeweek0
`
`
`
`E2 + ICI 182,780
`
`E2 + RU 58668
`
`weeks
`
`Fig. 5. MCF—7 tumour evolution over 10 weeks. After five weeks of tumour growth stimulation before week 0,
`mice were randomly allocated to groups of five animals and received, for 10 weeks, a weekly p.c. adminis-
`tration of 250 uglkg E2 with or without a single s.c. injection of 250 mglkg test compounds on weeks 0 and five.
`The animals were killed on week 10, and small pieces of each tumour were reimplanted into nude mice as
`described in Fig. 6.
`
`
`
`AstraZeneca Exhibit 2033 p. 6
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`
`
`Further Pharmacological Studies of RU 58668
`
`455
`
`Previous treatments :
`
`
`
`E2
`
`E2 + tamoxifen
`
`E2 + ICI 182,780
`
`E2 + RU 58668
`
`200
`
`175
`
`150
`
`125
`
`100
`
`75
`
`50
`
`25
`
`
`
`
`
`tumorvolume(mm3)
`
`Fig. 6. Growth of EZ-stimulated tumour pieces coming from the experiment described in Fig. 5. Tumour
`pieces from the experiment described in Fig. 5 were implanted into nude mice and their growth was stimu-
`lated by a weekly p.c. administration of S mglkg estradiol without any other treatment.
`
`weeks
`
`insight into its improved efficacy over ICI 182,780, in
`the model of MCF—7 tumours implanted in mice that
`had previously been shown.
`
`The effect of RU 58668 on the MCF—7 cell cycle
`
`(Table 1) giving rise to an accumulation of cells in
`the GO/Gl phases was significant after 24 h at 10—9 M
`and more pronounced after 48 h. ICI 182,780 had no
`effect at 24 h but at 48 h the effect was close to that
`
`caused by RU 58668. The issue of this timing differ-
`ence between the two compounds observed in this in
`vitro test is still difficult to correlate with what occurs
`
`in animals. Other in vitro experiments with MCF—7
`
`cells, whose growth is endogenously stimulated by a
`stable transfection with the ras oncogene (MCF—
`
`Table 2. Weight of tumours and uteri of the experiment described
`in Fig. 6
`
`Original source of
`tumours
`
`Estradiol
`E2 + tamoxifen
`E2 + ICI 182,780
`E2 + RU 58668
`
`Tumour
`weight(mg)
`
`91.1: 15.7
`80.2 i 12.4
`46.0 i 9.8"
`25.4 i 4.3“
`
`(n = 25)
`(n = 24)
`(n = 20)
`(n = 24)
`
`Uterus
`weight(mg)
`
`123.9 i 8.3
`129.8 i 6.0
`128.2 i 5.2
`126.6 i 4.9
`
`After the previous treatment stated, small pieces of tumours were
`reimplanted into naive nude mice and their growth was stimu-
`lated for six weeks with. 5 mg/kg estradiol; the animals were then
`killed and the tumours and uteri removed and weighed.
`*P< 0.05 vs E2.
`**P< 0.01 vs E2 (Mann—\Whitney test).
`
`7vht), also do not explain the differences seen in viva
`between the two compounds (Fig. 1).
`One could have argued that higher doses of ICI
`182,780 could have induced a decrease in the tumour
`volume, not found so far with a 250 mg/kg/month
`treatment. Our results (Fig. 3), however, show that
`such an assumption has to be excluded because,
`if
`both compounds displayed a similar quantitative ac—
`tivity (maximal effect at the weekly dose of 50 mg/kg),
`they showed a very different qualitative pattern
`(regression, compared to week 0, of the tumour
`volume with RU 58668, and a slowing down of the
`tumour growth with ICI 182,780). With respect to
`tumour volume, RU 58668 produces the same effect
`as ICI 182,780 but at doses 25—125 times lower.
`
`removed from RU 58668—
`tumour pieces,
`Small
`treated mice, displayed a lower growth ability, when
`reimplanted into naive animals,
`than those coming
`from E2,
`tamoxifen or ICI 182,780-treated mice.
`This suggests that pretreatment with RU 58668, and
`to a less extent ICI 182,780, caused a sustained
`growth inhibition of the reimplanted tumours.
`Histological examination of tumours treated with
`estradiol plus RU 58668 for 14 weeks showed a
`decrease in the ratio of epithelial cells to stroma com—
`pared to that treated with estradiol alone; this could
`be one explanation for
`the above-described slow-
`growing aspect of
`these tumours, but does not
`exclude the possibility of a retentive effect of RU
`58668 on the dividing ability of MCF—7 cells.
`
`
`
`AstraZeneca Exhibit 2033 p. 7
`
`
`
`
`
`Further Pharmacological Studies of RU 58668
`
`457
`
`feedback production of estradiol by the ovaries follow-
`ing the binding of the two pure antiestrogens to the
`hypothalamo-pituary estrogen receptors, could also be
`involved. However, with regard to this last point, pre—
`vious results showed nearly the same antitumoral
`potency difference between RU 58668 and ICI
`182,780 between va and non-va nude mice [21].
`These data suggest that RU 58668 may be an effec—
`tive drug for the treatment of metastatic mammary
`carcinoma in women.
`
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`
`
`AstraZeneca Exhibit 2033 p. 9
`
`