Cytotoxic principles From the Sap of Kalmia latifolia - ACS Publications

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CYTOTOXIC PRINCIPLES FROM THE SLAPOF KAL31IA LA TIFOLIA 8 c s . i ~D . ?~I.~SCISI and J . 11.EDTT-ARDS .Sc1100l o j Piiariiiacj, L-nk'ersiix of C o t z u e c t i c ~ ~Storrs, i, CT 06268

-~BsrR.ii:T.-Exanlination

of the sap of Knltiiia let-drochalcones have been synthesized and tested for c)-totoxic activity. 2',3,3',l,4'-Peiitah!-dros~-dih~drochalc~ne (8) has been found t o be q - t o t o s i c and to have marginal activity iti viL.0. Seven nen- dihydrochalcones are described.

Ruliniu laiijolia L. (Mountain laurel) i; a \\-ell-kno\~-iiperennial herb of the family Ericacrae, commonly found in the xood.5 of Connecticut. Previous chemical inveatigatiori of the species has demonstrated the presence of the toxic diterpenoid grayanotosin I (andromedotoxin. acet!-landromedol) [l] (I)! the dihydroclialcones phlorizin [2] (2); the glyco.de of phloretin [3], and asebotin [4] (3). The toxicity of the grayanotoxins is well established in vit'o. For example, 1 has an LD30 (I.P. in mice) of about 1.3 nig kg (A), but no in vitro cytotoxicity data have been published.

1

5'

3'

6

OH

5

U

2 4'OH, 6'OGlu. 3 4'OH, G'OH. 1 l ' O l I e , G'OGlu.

.ICa clas-. the diliydroclialcone- -eem t o be remarkably free of toxicity in laborator) animal- ( 5 ) and 1 1 1 i itro te-ting again-t the 9KB cell line indicates EDjo value- gmerall? > 20 p g nil ((3). Recently lion ever. uvaretiii. a 3'-benzyldihj-drochalcorie iqolated from L-earia 483

484

JOURNAL OF SATCRAL PRODUCTS

[VOL.

42,KO. 5

acumiwata, and some of its derivatives have shown activity ( T / C 132-144) in the P38S lymphocytic leukemia screen ( 7 ) . DISCUSSIOK Sormal solvent extraction of oven-dried K . Zatijolia gave fractionf n hich were inactive in the P388 system, whereas the expressed sap (leave. and stems) had reproducible activity (T, C = 150). Further solvent fractionation of the concentrated sap with chloroforni, ethyl acetate, and butanol gave active extracts (see experimental). The butanol extract was subjected to chroniatographj- over silica gel with chloroform, ethyl acetate, ethyl acetate-ethanol. and ethanol used sequentially as eluting solvents. The fractionation n-as followed by a quantitative, in zitro, cytotoxicity screen involving the single cell plating of 9KB cells. Briefly, inocula of ca 200, 2000, and 20,000 9KB cells IT-ere made; the test compound at 1, 10 and 100pg ml was added. After incubation and staining, the cell colonies were counted, thus giving a direct determination of surviving cells. This screening procedure is different from that used by the Kational Cancer Institute. The modification Tr-as developed so that test results could be obtained quickly (in about tTJ-0 weeks); the single plating technique has the additional advantage that it s h o w changes in cell morphology in response to the drug under test, and further that it can differentiate betx-een, for example. the death of half the cells and a decrease in growth rate of 50%, and betneen cell multiplication and cell g r o d i nithout division. Neither of these is possible if the S C I protocol is follon-ed. The chloroform fractions from the column were uniformly inactive and were not further investigated. Elution with ethyl acetate yielded a n hite crystalline compound, mp 262-4", which was identified as phloretin [3]. The dihydrochalcone had an EDjo of 28 pg nil but proved to be inactive in exten3ive in eizio testing. The initial tests had used a saline vehicle, but since it was felt that [3] might still be the active component of the sap and that there might be a transport or solubility problem, additional vehicles were investigated. No increased activity was observed in tween-80, saline and alcohol, or Klucel. A careful tlc-examination of the ethyl acetate fractions, vliich contained [3] and which 13-ere more active iiz aitro than the purified phloretin, indicated the presence of an additional component having the same Rfas [3] in our analytical system. The compound was identified [ 5 ] . The acetophenone had an EDSO as 2',6'-dih~-droxy-4'methoxyacetophenone of 4 . i p g 'ml, but had no activity iit tieo. Further elution u-ith ethyl acetate gave asebotin [4],which was inactive i?t titro, and grayanotoxin I [l].which n a s mildly active in titro (ED60 60 p g ml) but \yas toxic iiz ziao (no survivors at > I 3 mg kg). Further chromatography gave phlorizin [2], 13-hich was inactive in titro.

OH G'OH. 6 6'OGlu. 5

0

~ E P - O C T 19791

~ X C I S IASD E D M ARDS :

48.5

RAL\IIA LATIFOLIA

.Ilthough some of the compound> isolated from the sap were cytotoxic to a degree. none v a s active zit zizo. K e uere unable t o identify any crude fractions having greater iiz rztro activity than the original butanol extract; thus. further investigation mubt rely on iiz i z i o testing t o guide the fractionation. I n vien of the above finding.. 11-e undertook the synthesis of beveral dihydrochalcone. arid acetophenones in order to explore their potential as cytotoxic agent\. The compounds and their activities are liqted in tables 1 and 2. Eighteen T ~ B L1.E Cell survival data for dihx drochalcones.

Compoun i Sumber

______

I

6'

3'

2'

~

~H H -H OH H OH OH OH OH H

H

H OJle OVe H

H

OH

H H

OH H

OH

H

OH OH ~H H H

OH 10 16 9 15

H

I

H

H

OH

H

12 13

OMe

11

H

H 2

OH OH OH

4

OH

E

H H

H I H

H H 3

OH

OH H

H H

OH H OUe OH H

OH H OJIe H H

OH

OH

OH OH OJIe

H

H

3

.__

I H

H

H

I H

H

I H

H H

H H H H

OH

H

OH H OH OH

H

H

OH

H

OH

H

H

H

H H

H H OH

H OJIe OJIe

H H

'0"H OH OH

0 0 0 0

OH OH

20

03Ie

46

H

H OH H OH OH

OH

4

_ _ ~

OH OH OH OH OH OH

H

H

OH

H

OH

H H

H

H

H

OH

H H

OH H

E

H

0

H

H

OH

OH ~, "H

H

OGlu OGlu

H

' O H

H

OH

I H

0 0 0 0 0 0 0 0 0 5 0

OH

OH

100 100 100 100 100 100 100 95 IiO E9 9 i6 76 71 5e 5i 52 50

0

H

H

100 100

0 0

2s

20 2 5 100

0

4;

100

100

100

TABLE 2. Cell survival d a t a for acetophenones. I

I

7 Survivors at

Compound Sumber 2'

I >

14

6

I

OH^

OH OH OH OH

I ~H

1I

I

3' H H H

OH

41

OH

H H

I OlIe ~

OlIe OlIe OH

H I

H H

OH ' OH

Ol1e

~

29 0 0 39 0

'

100 0 100 100 81

1 1

4 i

~

dihydrochalcones n ere synthe.ized by condeniation of a n acetophenone n ith a suitable aromatic aldehyde in the presence of 6 0 5 KOH (5) to give the clialcone. follon ed by reductioii, tlie 1 emainiiig three required .pecial procedure- (iee experimeriial) . The synthetic dihydrochalcone ~ h o ing v the most pron1i.e in Z I Z i itro activity n-a- ~ ' . : 3 . . 3 ' . ~ . ~ ' - p e n t a l i ~ - ~ 1 ~ 0 ~ ~ -[SI. c l i an-hich l c o 1 i e had an ED ,o of 3..7 p g nil. tlie conipouiid n a i a1.0 marginall!- active iiz i z i o (T C = 1 % at 65

JOURXAL OF SATURAL PRODUCTS

4SG

[VOL.

42, so. 5

mg Bg). The synthesis of asebotin [4] \\as through the glucoside pleoside [6], a natural product of unknown stereochemistry. isolated from Pleopoltis thzotbergimzu and not previously synthesized (9). A%Knoenigs-Ihorr syntheqis using 5 and tetra 0-acetyl-a-D-bronioglucoqe in toluene. in the prewice of CdCOa (lo), gave the required tetraacetate. which x-as deacetylated to 6 under Zemplen conditions (11). The y-nthetic and natural pleoqideq xT-ere identical (tlc, ir, optical rotation). The natural product is, thuq, a P-glucoqide.

EXPERI_71ESTALi PRELIMIS-IRIFRacTIo~.~TIos.-Fresh leaves and stems of Kalniia Lai$oi'ia L. (Ericaceae) were chopped in a silage mill, and a hydraulic press was used t o express t h e sap (5 l i t e r s ) . T h e s a p was concentrated a t 40" t o about I f of i t s original volume and extracted t o give t h e follow-ing chloroform [log; 138 (loo), 157 (12.5); Bd@nil]: ethyl fractions 1n-t: T,'C (dose mg;kg); ED acetate 3 g ; 120 (100)) 113 (50); 98 fig1 1; butanol 121g: 166 1200), 120 (400); 14 figlml); aqueous residue (T/C:104). CHROXITOGR.IPHY O F THE BCTAXOL EXTR.iCT.-The butanol extract was subjected t o chromatography over silica gel (1 k g ) ; 500 ml fractions were collected. K O active compounds n-ere uted b\- chloroform (fraction 1-21). Fractions 29+30 (ethyl acetate) contained 2.75 gm of white needles m p 282-4" from ethanol water :lit (13) 262-4'3, i r and tlc (systems a-g) identical i t h an authentic sample. Fractions 34-14 (ethyl acetate) xvere combined on t h e basis of tlc analysis (system g) and rechromatographed over silica (80 gm) with e t h y l acetate-ethanol, 20,'l as t h e eluting solvent. Lisebotin14; was eluted in the early fractions: t h e glycoside n a s identified 12:- eo-chromatography (systems h , i) with an authentic sample, and by hydrolysis t o asebogeniii and correlation of the aglycone with authentic material. L a t e r fractions contained phlorizin [2]; t h e glycoside vas identical x-ith authentic material (ir, mp, tlc) and gave 3 on acid hydrolysis. Tlc (system g) of those fractions containing 2 and 4 indicated the probable presence of grayanotosin I [l] (blue color n i t h Godin's reagent (14)): confirmation was provided b>- eo-chromatography of t h e compound present in t h e extracts, n-ith authentic grayanotozin I in several solvent systems (a, e, and g ) . 1SOL.LTIOK OF 2',6'-DIHTDROXI-~'-~lETHOXY.~CETOPHESOSE [5].-sap (150 ml) n a s diluted with water (150 ml) and extracted with et,her (5 s 100 m l ) . After drying, evaporation, preparative layer chromatography (silica gel: chloroform-methanol, 8 , ' l ) , and further t l c (silica gel; chloroform), pure 5 was obtained. alp, ir, and tlc behavior were identical with synrhetic material (see belo-iv).

2',6'-DIHYDRoXY-~'-~lETHOXT.\CETOPHESO~E [5]

ASD

~',6'-DIVETHOXT-2'-HYDROXYY.~CETO-

[14].-The method of Cave11 and RIac?\Iillan (15) gave 5 , mp 138", and 14, m p 85-86", in 2T and 14% yields, respectively.

PHESOSE

PLEOSIDE [6].--Compound 5 (0.182 gm, 1 mR1) and CdC03 (0.344 gm, 2mSI) --ere added t,o d r y toluene (20 ml) in a flame-dried round-bottom flask (100 m l ) . Tetra-0-acetyl-a-Dbromoglucose (0.822 gm, 2mM) was dissolved in d r y toluene (20 ml) and added t o the stirred, refluxing mixture over 1 h r . T h e mixture was heated a t reflux for an additional 30 min and filtered hot through a pad of Celite. T h e filtrate was evaporated t o an oil x h i c h crystallized overnight. Crystallization from methanol gave t h e tetraacetate as white crystals: 0.195 gm (38",), mp 182-3" (lit m p 119-20" (9))2;6: 2.02 (s;12H), 2.50 (s;3H),2.74 (s;3H), 4.14 (bs;2H), 5.25 (s;3H), 6.02 (d, J = 2 H z ; I H ) , 6.10 (d, J = 2 H z ; l H ) , and 13.20 ( s ; l H ) ; ms: 512 (Rf-), 453.138 (11-OAc) : C23H2j013-OA~ requires 453.139. This tetraacetate (40 mg, 0.078mRI) n-as suspended in d r y methanol (5 m l ) . T h e suspension was treated with S a O 1 I e [2 ml of a solution prepared by adding S a (2.3 mg) t o methanol (5 ml)] and stirred a t room temperature for 2 h r . T h e mixture was neutralized with DoR-ex 50 (H+ form), filtered, and evaporated. Crystallization from ethyl acetate-hexane gave 6, 22 IMPS were determined on a Kofler hot stage apparatus and are uncorrected. S m r spectra were obtained on a Hitachi Perkin-Elmer R-24 spectrometer in DB-acetone unless othernise noted Mass spectra n-ere recorded on a C E C 21-llOB spectrometer I r spectra n e r e recorded on a Beckman Acculab 3 spectrophotometer Tlc analysis n a s on silica gel using t h e folloning systems a chloroform-methanol, 15 1. b ethyl acetate-hexane-acetic acid, 50/50/0 5 , c ethyl acetate-ethanol, 20 1 d e t h r l acetate-isopropanol-nater, 6 2/1, e chloroform-benzeneethanoI, 75 25'3 f benzene-methanol-acetic acid, i5,25 3, g e t h y l acetate-ethanol, 20 1 toluene-acetic acid-formic acid, 5 4 1 I . chloroform-acetic acid-formic acid, 5/41 1 T isualization n a s mith Godin s reagent (12) or diazotized p-nitroaniIine/lO% Sa2C03. I E e z t o testing mas carried out b y t h e Kationsl Cancer Institute, S I H , Bethesda, RID.

SEP-OCT

19791

XISCISI

ASD EDKAKDS

:

Ii.iLm.I

LATIFOLIA

4s;

nig (80C2),nip 180-5' flit mp 200-3' ( 9 ) ) : vnias 3400, 2895, lGl0 and 1505 em-': [a;D=-40.3'. ( c = 0 . 1 5 ~pyridine) , (lit :a]D=--I1.6" ( 9 ) ) .

PREP.\R.ITIOS OF DIHI-DROCH.ILCOSES.- Escept in t h e cases of compounds 15 and 16, The acetophenone (0.02 nil and t h e benzaldehyde 10.02 mole) n-ere dissolved in a minimum volume of ethanol. T h e solution n-as cooled in ice. Cold aqueous KOH (605,18.2 gm, 0,445 mole) was added slowl>-. T h e reaction mistiire m-as kept a t room temperature for 3 days and acidified b y pouring into ice-cold 3; HC1. The precipitate was rapidly filtered and washed n-ith Cold water. T h e crude chalcones n-ere crystallized from ethanol, and suhsequently reduced in a Parr hydrogenator a t 3 atmosphere pressure over 55; P d , C. T h e dihydrochalcones were ane or benzene-hexane. waleh et oi. (16) n-as followed in t h e preparation of 15. Hesperitin w a s isomerized n-ith 2.T; K O H t o give 16. Seven of t h e dihj-drochalcones had not lieen previouslJ- described. E a c h one had spect ral (ir, nmr, and nisi characteristics compatible n i t h t h e assigned structure; t h e observed and calculated values for tlie molecular ioiis, the nips and v c o , are recorded below. Compound S o .

-

8

9 10 11 12 13

nip ' 98-101 155-G 142-4 147-9 137-9 90-2 106-7

vco cni-l

Formula

1650 1020 1620 1615 1055 1G50 1610

CijH1403 C:,H;;Oj

CiaH:,01 CIIHI~O: CI:HiEO;

C;SHi:O8 C:;Hi.O:

Calculated N I T Observed 31W 242.0943 250,0786 258. os91 258.0891 272.104T 242.0943 286,1204

242.0541 290.0766 258.OS9G 25s. os94 27%.1045 242. G544 286.1'204

SISlxLE CELL I'L.\TISG iCLOSIZC,) P R O C E D K R E . CELLS: GROV TH COSDITIoSS.--The human 9KB cells viere maintained in culture as monola?-ers. T h e cells were grown in D M E (Dulhecco s llodifieil 3Iininial Essential Xediuni oi Eagle! and 553 calf seriini. Plastic dishes (60x 15 nim) were seeded xT-ith 1 x loficells and used after incitbating 24 lira a t 37". F o r testing, cells from the monolaj-ers TT-ere dispersed into suspensions of single cells Kith a tr>-psin-EDT.1 solution 10.05(; -rypsin, S u t r i t i o n a l Biochemical Corporation: 1 3 0 0 and 5 ?; 10-= 11 E D T A , ethylenedinminetetraacetic acid in Saline D ) , counted in a hemocytometer, and plated in 11NE supplemented n-ith 10'; calf seruni plus the test compound (see lielow). T h e progeny from individual cells n-hich siirvive esposiire t o t h e test conipoiind iorni niacroscopicallj- visible colonies in 14 days a t 37'. These colonies were Jyashed Kith non-sterile P B S (phosphate bufiered saline), fixed n-ith 1 0 5 formalin, Stailled with Giesnia, and coiinted over a photographic light box. SaIrPLE PREP.\R.iTIOS.-The compound tcj be tested was dissolved in eitk.er ethanol or water and added t o t h e DJIE and 1 0 5 calf serum solution t o a final concentration of 100 p g m l . This sol.ition n-as sterilized bj- filtration through a niillipore filter, and further dilutions x e r e made (10 and 1 pg nil).

CO~\IPOCSD TESTISG PROCEDTRE: EFFECT o s PL.ITISG EFFICIESCI- OF SISGLE cELLs.-The general testing included three dose levels of t h e test compound which %-ere measured by \?eight a t 100, 10, and 1 f i g nil per sample, with duplicates for each sample. T h e cells n-ere plated a t three levels: 200, 2000, and 20,000 cells per dish with duplicates for each dish. Controls (DME and 10'; calf seruni and ethanol or water) were plated in duplicate at 200,2000, and 20,OCO cells per plate. .%CKSOWLEDGMEKTS This a o r k was supported bj- grant number C-4 15230 02/03 awarded b y t h e Kational Cancer Institute. This financial assistance is gratefully acknon-ledged. We n i s h t o thank D r . Philip Marcus, Director of t h e cell culture facility a t the University of Connecticut, which is supported by S C I program project grant C-4 14T33, for his help in establishing t h e in n'itro screen. We thank the following for authentic samples, Dr. G . H. Constantine, Oregon S t a t e L-niversit>- igrayanotosin I ) : D r . H . Hikino, Pharmaceutical Institute, Tohokn Universit)., Japan ipleoside); and D r . T. Terai, Osaka Institute of Technology, Japan (asebotin). Received 9 .April 1979.

:Hikin0 (9) made t h e t e t r a a c e t a t e from 6 with acetic anhydride and pyridine. H i s analytical figures (C,5-1.3T;H,5.31) correspond b e t t e r t o a pentacetate (C,54.16; HJ5.47) than t o t h e t e t r a a c e t a t e (C,53.5: H,5.47).

488

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PRODUCTS

[VOL.

42,

NO.

3

LITERATURE CITED 1. W.H. Tallent, 11.L. Riethof and E. C. Horning, J . A m . Chem. Soc., 79, 4548 (1957). 2. .I. H. W I L L I i v s , in Compnraizie P h y t o c h e t m s t r ~ (T. Swain E d . ) Academic Press, London 196G p. 301. 3. E. Bourquelot and h.Fichtenholz, C. R . .Icad. Scz., 154, 526 (1912). 4. P. 11.Scott, B . B. Coldwell and G. S Wiberg, Food C o m e t . Toxicol., 9, 179 (19T1). 5. -1.K. Booth and D. J . Robbins, .-igricultural Research Publication CAi4-18, Western Regional Research Laboratory, USDA, Albanj , Calif., 1968. 6. J . 11. Edwards, P . W . LeQuesne and R . F. Raffauf, J . A\ht. Prod., Manuscription in preparation. 7. J . R. Cole, S J . Torrance, R . 11.Wiedhof, S. Arora and R . B . Bates, J . O r g . Chenr , 41, 1852 (19%) 8. E. F. K u r t h , J . -4191. C h e w . Soc., 61, 861 (1939). 9. H . Hikino, C . Konno and T . Takemoto, I’akzcgaki~ Zasshz, 89, 3i2 (1969). 10. R . B . Conrow and S. Bernstein, J . Org. Chem., 36, 863 11971). 11. (2. ZPmnlen. R e r . Dtsrh Cheni. Ges.. 76. 112 1194.1) 12. P. Godin, S a f z i r e , (London), 174, 134 (19%). 13. C. Bride1 and J. Kramer, C. R . A c n d . Sci., 193, 748 (1931). 14. G. H . Constantine, K . Sheth and P. J . Catalfomo, J . Phnrnz. Sci., 56, 1518 (1957) 15. B. D. Cave11 and J. Mac11illan. J . Chem. Soc. i C ) . 310 11967). 16. 11.Swaleh, W-U-Rahman and h1. 0. Farooq, Indzan J . Chem., 2, 3T5 (1964) --I-----,

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I-

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