Báo cáo khoa học: Ixocarpalactone A isolated from the Mexican tomatillo shows potent antiproliferative and apoptotic activity in colon cancer cells pot

SW480 cells treated with IxoA showed cell cycle arrest in the G2⁄ M phase, up-regu-lation of hyper-phosphorylated retinoblastoma, and down-reguup-regu-lation of E2F-1 and DP-1.. SW480 ce

shows potent antiproliferative and apoptotic activity

in colon cancer cells

Juliana K Choi1, Genoveva Murillo2, Bao-Ning Su3, John M Pezzuto4, A D Kinghorn3and

Rajendra G Mehta2

1 Department of Surgical Oncology, College of Medicine, University of Illinois at Chicago, IL, USA

2 Carcinogenesis and Chemoprevention Division, Life Sciences Group, IIT Research Institute, Chicago, IL, USA

3 Medicinal Chemistry and Pharmacognosy, College of Pharmacy, Ohio State University, Columbus, OH, USA

4 Department of Medicinal Chemistry and Molecular Pharmacology, School of Pharmacy and Pharmaceutical Sciences, Purdue University, West Lafayatte, IN, USA

As the third leading cause of cancer deaths, colon

cancer continues to be a major cause of mortality in

the United States [1] Several epidemiological studies

have indicated a correlation between diet and colon

cancer risk [2–4] Diet is considered one of the most

important environmental factors in colon cancer

development, particularly those characterized by

decreased consumption of fruits and vegetables and

increased intake of meats and fats [5–7] Westerniza-tion of diets, or greater intake of meats and fats, has been linked with an increased incidence of colon can-cer, providing support for the influence of diet on colon cancer development [6,8,9] Therefore, the dis-covery of novel chemopreventive agents of natural origin has been targeted, with fruits and vegetables being of key interest

Keywords

apoptosis; colon cancer; ixocarpalactone A;

Physalis philadelphica; tomatillo

Correspondence

R G Mehta, Carcinogenesis and

Chemoprevention Division, IIT Research

Institute, 10 West 35th Street, Chicago,

IL 60616, USA

Fax: +1 312 567 4931

Tel: +1 312 567 4970

E-mail: RMehta@iitri.org

(Received 20 September 2006, accepted

27 October 2006)

doi:10.1111/j.1742-4658.2006.05560.x

Physalis philadelphica Lam, commonly known as a tomatillo, is a staple

of the Mesoamerican cuisine In our laboratory, an ethyl acetate-soluble extract and four withanolides [ixocarpalactone A (IxoA), ixocarpalac-tone B, philadelphicalacixocarpalac-tone B, and withaphysacarpin] were isolated Stud-ies conducted on Hepa-1c1c7 hepatoma cells revealed that withanolides were potent inducers of quinone reductase, suggesting possible cancer chemo-protective activity Here we evaluated the antiproliferative properties of the withanolides in SW480 human colon cancer cells IxoA, which is present in the edible part of the tomatillo, was selected for further evaluation SW480 cells treated with IxoA showed cell cycle arrest in the G2⁄ M phase, up-regu-lation of hyper-phosphorylated retinoblastoma, and down-reguup-regu-lation of E2F-1 and DP-1 On the basis of flow cytometry analysis, ethidium bro-mide⁄ acridine orange, and 4¢,6-diamidino-2-phenylindole staining, it was found that IxoA induces apoptosis in SW480 cells Moreover, increased concentrations of the pro-apoptotic protein, BIM⁄ BOD, were found by western blot analysis and immunocytochemistry Morphological examina-tion revealed vacuole formaexamina-tion in cells treated with IxoA, and Oil Red O staining showed that the vacuole content was nonlipid Furthermore, immunocytochemistry demonstrated increased concentrations of mucin 3 in IxoA-treated SW480 cells These findings suggest that chemicals present in tomatillos (e.g IxoA) may have cancer chemopreventive properties

Abbreviations

DAPI, 4¢,6-diamidino-2-phenylindole; IxoA, ixocarpalactone A; IxoB, ixocarpalactone B; MTT,

3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazolium bromide; PhilB, philadelphicalactone B; pRb, hyperphosphorylated retinoblastoma; Rb, retinoblastoma; Withpc, withaphysacarpin.

The beneficial effects of fruits and vegetables have

been attributed among other things to the high content

of bioactive compounds [10] Studies conducted in the

last two decades have shown that these bioactive

compounds have important roles in the prevention

of chronic diseases, including cancer, diabetes and

hypercholesterolemia [11] Noteworthy examples of

plant-derived substances that have been shown to

reduce experimental colon carcinogenesis are

indole-3-carbinol from cruciferous vegetables such as brussel

sprouts and broccoli [12], curcumin from the root of

Curcuma [13], and epigallocatechin gallate from tea

[14] Some of these agents are currently being

investi-gated in clinical trials for the prevention or treatment

of cancer [15]

The use of plant-derived agents to prevent the onset

or delay progression of the carcinogenic process has

attracted considerable interest, with much attention

aimed at understanding the mode of action by which

they function Several cellular signaling pathways

involved in apoptosis, proliferation, cell cycle, and

angiogenesis, all processes implicated in many cancers,

have been shown to be modulated by chemopreventive

agents Natural agents derived from dietary sources,

unlike conventional single-site agents, offer the ability

to exhibit multisite mechanisms of action Moreover, a

role for these compounds in combinatorial therapy

with more traditional chemotherapeutics has been

suggested, with the aim of lowering the toxicity and

enhancing the efficacy of treatments of more advanced

cancers

As part of our continuing search for novel,

plant-derived cancer chemopreventive agents [16,17], we have

evaluated a number of plants originating from

differ-ent parts of the world Physalis philadelphica is an

example of such a plant The fruit of P philadelphica

(Fig 1A), commonly known as tomatillos, husk

toma-toes, ground cherries, jamberries or fresadillas [18], are

everyday components of the Mexican and Guatemalan

diet [19] Several medicinal properties have been

attrib-uted to P philadelphica, e.g antibacterial properties

against respiratory infections caused by

Staphylococ-cus aureus, StreptococStaphylococ-cus pneumoniae, and

Streptococ-cus pyogenes [20] Moreover, in Guatemala, the

tomatillo was believed to have health benefits against

gastrointestinal disorders [21]

Previously in our laboratory, an ethyl acetate-soluble

extract and four withanolides [ixocarpalactone A

(IxoA)], ixocarpalactone B (IxoB),

philadelphicalac-tone B (PhilB), and withaphysacarpin (Withpc)] were

isolated in pure form All four have been shown to

be present in the leaves and stems of P philadelphica

[22] Furthermore, IxoA and Withpc have been found

in the fresh fruits of P philadelphica [23] Earlier studies demonstrated that IxoA possessed quinone reductase activity with an IC50 (concentration that produces 50% inhibition) of 7.54 lm in Hepa-1c1c7 mouse hepatoma cells IxoA was also shown to inhibit the transformation of the murine epidermal JB6 cell with an IC50of 0.26 lm [23] On the basis of these results, we selected IxoA (Fig 1B) for further investigations

Results

Treatment with P philadelphica extract and withanolide isolates inhibits growth of human colon cancer cells

The antiproliferative effects of ethyl acetate-soluble extract from P philadelphica were evaluated in a human colon cancer cell line (SW480) For these stud-ies, cells were treated at a concentration range of 1–

20 lgÆmL)1 for 2–7 days As shown in Fig 2A, extract treatment demonstrated significant growth inhibition

in treated SW480 cells, with 85% inhibition at

5 lgÆmL)1 and 100% at doses ‡ 10 lgÆmL)1 Next the effects of the four isolates, IxoA, IxoB, PhilB and

A

B

OH OH

O O OH

O

OH O

Fig 1 (A) Tomatillo fruit (B) Structure of IxoA.

Withpc, were evaluated using the same cell line As

illustrated in Fig 2B, all four compounds significantly

suppressed cell proliferation in a dose-dependent

man-ner ranging from 80% to 99%, at 1 lm and 10 lm,

respectively Similar findings were observed in the

HT-29 and SW620 human colon cancer cell lines (data not

shown)

IxoA was selected for further evaluation for the

fol-lowing reasons: it is found in the edible fruit of the

tomatillo plant, it has previously been reported to have

potent quinone reductase activity in hepatoma cells,

and because it has been shown to inhibit the

transfor-mation of murine epidermal JB6 cells with an IC50 of

0.26 lm [23] Therefore, cell growth studies with IxoA

were conducted in three additional human colon

can-cer cell lines (HT-29, Caco-2 and HCT116 in addition

to SW480) As shown in Fig 2C, dose-dependent

inhi-bition was evident in all four cell lines studied after

5 days of treatment IxoA showed equal or greatest

inhibition in SW480 cells, with percentage inhibitions

ranging from 19.0 to 100% at concentrations of 0.1–

10.0 lm, respectively

Subsequently, the time-dependent effects of IxoA

were evaluated in the SW480 cells For these

experi-ments, cells were treated for 1–7 days with doses

ran-ging from 250 nm to 10.0 lm As shown in Fig 2D,

by day 2 after treatment, > 60%, > 83%, and 100%

growth inhibition was noted for cells treated with

IxoA at 1.0 lm, 2.5 lm, and 7.5 lm, respectively The

growth inhibition remained evident until day 7 after treatment

SW480 cells treated with IxoA for 1 day also showed a large percentage of growth inhibition; how-ever, consistent with a time-dependent pattern, the per-centage inhibition was not as great as observed at longer time points After 1 day of IxoA treatment, 58.1%, 67.6%, 87.1% and 90.3% inhibition was observed at 2.5, 5.0, 7.5 and 10.0 lm IxoA, respect-ively The IC50 for 1 day of IxoA treatment was 1.66 lm To ensure a minimum of 50% inhibition of SW480 proliferation at shorter time points (1 day), a concentration of 5.0 lm IxoA was used for subsequent studies

IxoA treatment induces G2/M cell cycle arrest

in SW480 cells

To determine whether the antiproliferative actions of IxoA were mediated by an arrest in the cell cycle, SW480 cells were treated with 5 lm IxoA for 12–24 h and analyzed by flow cytometric analysis Cell cycle analysis demonstrated that 5 lm IxoA treatment resul-ted in an accumulation of cells in the G2⁄ M phase of the cell cycle, as shown in Fig 3A,B At 12 h, a 20.0% increase in SW480 cells arrested in G2⁄ M was observed, and at 24 h a 20.2% increase (Fig 3C) Flow cytometric analysis was repeated in HT-29 cells, and similar results were obtained (data not shown)

Fig 2 Percentage growth inhibition of human colon cancer cells treated with

P philadelphica extract and ⁄ or withanolide isolates (A) Effect of ethyl acetate-soluble extract from P philadelphica on SW480 human colon cancer cells Cells were seeded in 96-well plates as described in Experimental procedures and treated with the indicated concentrations of treatment or vehicle (Me 2 SO) Cell proliferation was determined by MTT assay at 2, 3, 4, 5 and

7 day time points by measuring the absorb-ance of formazan at 570 nm The data are mean ± SD from triplicate wells (B) The effects of IxoA, IxoB, PhilB and Withpc on SW480 cells were measured at 5 days (C) The effect of IxoA on HT29, Caco-2, HCT116 and SW480 human colon cancer cell lines was measured at 5 days (D) Effect of IxoA on SW480 cells at 1, 2, 4, 5,

6 and 7 days The experimental procedures for (B), (C) and (D) were the same as in (A).

Hyperphosphorylated retinoblastoma (pRb) is

up-regulated, whereas E2F-1 and DP-1 are

down-regulated in SW480 cells treated with IxoA

Given that IxoA induced G2⁄ M cell cycle arrest,

west-ern blot analysis was used to examine the effects of

this compound in G2-related proteins These studies

revealed an increased expression of pRb with a

simul-taneous decrease in the expression of retinoblastoma

(Rb) in SW480 cells exposed to 5 lm IxoA for 24–

72 h Densitometric analysis revealed 28.5–51.9%

increase in pRb and 4.5–41.4% reduction in Rb

com-pared with the control band (b-actin) Western blot

analysis demonstrated that E2F-1

expres-sion was down-regulated by 7.3–54.3% when

com-pared with b-actin DP-1 expression varied from

29.3% up-regulated at 24 h to 51.8% down-regulated

at 48 h (compared with b-actin) No significant

chan-ges in cyclin A and cdk1 concentrations were observed

(Fig 4)

IxoA induces apoptosis in SW480 cells

The effects of IxoA on apoptosis were measured by

four independent assays Initially, acridine orange⁄

ethi-dium bromide staining was used to evaluate apoptosis

in SW480 cells treated with IxoA SW480 cells were

treated with 5 lm IxoA for 24 h, stained with acridine

orange⁄ ethidium bromide and examined by fluorescent

microscopy Morphological changes characteristic of

apoptosis, including fragmented nuclei, blebbing, and

irregular cytoplasmic membranes, were evident in the

nuclei of IxoA-treated cells Treatment with IxoA for

24 h revealed 54% of the SW480 cells were orange

in color (late apoptosis), 36% were observed to be

B

Fig 3 Effect of IxoA on cell cycle

distribu-tion in SW480 cells Cells were prepared for

flow cytometry analysis as described in

Experimental procedures (A) SW480 cells

were treated with vehicle (Me2SO) as

con-trol for 12 h (B) or with IxoA 5 l M (C)

Percentages of cells in each cell cycle phase

at 12, 18 and 24 h An increase in the

num-ber of cells arrested in the G2 ⁄ M phase of

the cell cycle is observed at each time

point.

Fig 4 Western blot analyses of G2-related proteins SW480 cells were treated with 5 l M IxoA for 24-72 h As described in Experi-mental procedures, cell lysate was collected, and western blot ana-lysis was conducted to determine the protein expression of pRb and Rb, E2F-1, DP-1, cdk1 and cyclin A Cell lysate was also collec-ted from untreacollec-ted (Untxd) SW480 cells at each time point, and protein expression was compared between untreated and treated SW480 cells All bands were compared with b-actin bands using densitometric analysis The percentage change for each protein compared with b-actin bands is indicated as up-regulation (+) or down-regulation (–).

blebbing (early apoptosis), and 9% were a green color

(live cells) (Fig 5B–D) The control cells, treated with

vehicle (Me2SO) were 19% orange, 7% blebbing, and

73% green in color (Fig 5A)

To better evaluate nuclear fragmentation, a feature

of apoptotic cells, the fluorescent DNA-binding dye,

4¢,6-diamidino-2-phenylindole (DAPI) was used As

shown in Fig 6, cells treated with 5 lm IxoA for 24 h

displayed the typical morphological features,

con-densed and fragment nuclei, of apoptotic cells

Members of the BH3 domain-only pro-apoptotic

proteins, including BIM⁄ BOD, have been shown to

have a critical role in initiating the apoptotic program

by antagonizing the function of the antiapoptotic

BCL-2 and activating BAX and BAK [24] Therefore,

the expression of BIM⁄ BOD was evaluated by western

blot analysis As shown in Fig 7A, exposure of

SW480 cells to IxoA increased expression of BIM⁄

BOD SW480 cells treated with 5 lm IxoA for 24, 48 and 72 h revealed a 20%, 35%, and 64% up-regula-tion, respectively, in BIM⁄ BOD compared with the control band (b-actin) upon evaluation by densito-metry After these studies, the effects of IxoA on BIM⁄ BOD were examined by immunocytochemistry (Fig 7B,C) Treatment with 5 lm IxoA for 24 h increased BIM⁄ BOD protein staining This result complements those obtained by western blot analysis

Vacuole content detection Treatment of SW480 cells with 5 lm IxoA for 24 h induced the formation of multiple vacuoles within each cell To determine the content of these vacuoles, Oil Red O, a red stain specific for lipids, was used to stain the SW480 cells Figure 8A,B show that the vacuole content was not positive for the presence of

A

C

E

B

D

Fig 5 Cell apoptosis and morphological changes in the nuclei of SW480 cells trea-ted with or without IxoA were identified by fluorescent staining with acridine

orange ⁄ ethidium bromide Non-viable cells had orange-stained nuclei, and viable cells had green-stained nuclei under fluorescent microscopy (A) Control SW480 cells were treated with Me2SO The green color indi-cates viability (B–D) SW480 cells were trea-ted with 5 l M IxoA for 24 h Blebbing of the membrane, chromatin aggregation, and nuc-lear condensation (B and C) were criteria used to identify apoptotic cells (D) The orange color indicates non-viable cells Ori-ginal magnification, 40· (E) Percentage distribution is presented for control and treatment.

Fig 6 Morphological evidence of apoptosis

in SW480 cells stained with DAPI (A) Con-trol cells treated with Me2SO had intact nuclei (B) After 24 h, the nuclei of SW480 cells treated with 5 l M IxoA showed nuclear fragmentation and chromatin condensation characteristic of apoptosis Magnification, 40·.

lipid, as no red color was detected in the IxoA-treated

cells Increased concentrations of mucin 3, however,

were observed by immunocytochemical analysis

(Fig 8C,D) Increased mucin 3 protein staining was

observed in SW480 cells treated for 24 h with 5 lm

IxoA, suggesting that the vacuole content includes

mucin

Discussion

This study was part of a large-scale investigation of

the efficacy of natural products as chemopreventive

agents, particularly those found in the diet [25] Thus

far, over 200 active compounds have been identified as chemopreventive agents, including resveratrol [26,27], brassinin [28,29], and deguelin [30,31] Resveratrol is present in grapes, red wine and peanuts, brassinin is from Chinese cabbage, and deguelin is from an Afri-can plant, Mundule sericea The success of these nat-ural products as anticancer agents led us to evaluate

an additional plant, P philadelphica or more com-monly known as the tomatillo, to determine its efficacy

as a chemopreventive agent Because of the efficacy of fruits and vegetables against colon cancer [2–4,8,9], we elected to study the effects of tomatillos against colon cancer in vitro

A

Fig 7 BIM ⁄ BOD, a BH3-region only pro-apoptotic protein, was investigated to further characterize the apoptosis observed in IxoA-treated SW480 cells (A) SW480 cells were treated with 5 l M IxoA for 24–72 h Cell lysate was collected (also from untreated SW480 cells at each time point), and western blot analysis was conducted to determine the protein expression of BIM ⁄ BOD Protein expression was compared between untreated and treated SW480 cells, and BIM ⁄ BOD expression was shown to increase at each time point All bands were com-pared with b-actin bands using densitometric analysis (B) Immunocytochemistry was also performed on SW480 cells to confirm BIM ⁄ BOD expression Control cells were treated with Me 2 SO for 24 h (C) SW480 cells treated with 5 l M IxoA for 24 h confirmed up-regulation of BIM ⁄ BOD Magnification, 40·.

Fig 8 Identification of vacuole content in

treated SW480 cells The formation of

mul-tiple vacuoles within the cells was observed

after treatment of SW480 cells with 5 l M

IxoA for 24 h SW480 cells were plated,

treated and fixed as described in

Experimen-tal procedures Oil Red O staining

counter-stained with hematoxylin was then

performed to distinguish the vacuole

con-tent as lipid or non-lipid (A) SW480 cells

treated with Me 2 SO for 24 h served as

controls (B) SW480 cells treated with 5 l M

IxoA for 24 h did not stain red, indicating a

non-lipid vacuole content Also,

immunocyto-chemistry was performed on SW480 cells

to investigate mucin 3 expression (C)

Me2SO-treated SW480 cells served as

con-trols (D) SW480 cells treated with 5 l M

IxoA for 24 h showed increased mucin 3

protein staining Magnification, 40·.

Our rationale for selecting tomatillos for evaluation

has been described previously [16,17,23] Briefly, plants

are selected on the basis of information about its

expected antiproliferative activity, nontoxic nature,

and from information received from the population

that uses the plant for medicinal purposes Then,

selec-ted plant parts are extracselec-ted with ethyl acetate and

evaluated for activity using select in vitro bioassays,

including induction of quinone reductase with Hepa

1c1c7 cells and inhibition of transformation with JB6

cells [23,32] After in vitro bioassays, the mouse

mam-mary gland organ culture (MMOC) model is used to

select active agents for further evaluation [33] Chosen

extracts are then fractionated using an HPLC solvent

system, and all fractions are evaluated in in vitro

bioas-says specific to the extract Pure compounds are then

isolated from active fractions and the structure of the

compound is determined The activity of the

chemo-preventive agent is then confirmed in experimental

carcinogenesis models as shown in this study

Using the above screening process, we have

identi-fied and evaluated a novel chemopreventive agent

Upon fractionation of the ethyl acetate-soluble

toma-tillo extract, we discovered four compounds with

chemopreventive potential Although all four

com-pounds showed significant antiproliferative activity in

colon cancer cells, we elected to focus on IxoA because

of its abundance in the leaves and stems of the plant

and its presence in the fruits

To examine the mechanism that might account for

the effects of IxoA in colon cancer cells, we

investi-gated its effects on cell cycle distribution A noticeable

accumulation of colon cancer cells in the G2⁄ M phase

of the cell cycle occurred, with a concomitant decrease

of cells in the G0⁄ G1 phase This suggests that IxoA

has a pronounced effect on colon cancer proliferation

which is due to cell cycle arrest In support of this

observation, SW480 cells cultured with IxoA (5 lm)

for 24–72 h showed an increased level of expression of

pRb and a decreased level of expression of E2F-1 and

DP-1 (at 48 h) E2F-1 and DP-1 are known to exist in

a complex and act synergistically in E2F

site-depend-ent transcriptional activation [34], and pRb can inhibit

transcriptional activation of E2F [35] Therefore,

IxoA-induced pRb inhibition of E2F-1 and DP-1 may

account for the accumulation of cells at the G2⁄ M

phase of the cell cycle We show here that sustained

G2⁄ M arrest induced by IxoA may be

E2F-1-depend-ent and involves an increase in expression of the

mito-tic regulator, pRb

In addition, IxoA was shown for the first time to

induce apoptosis in SW480 human colon cancer cells

To investigate the effects of IxoA on apoptosis, we

used acridine orange⁄ ethidium bromide staining and DAPI staining and found a marked increase in the per-centage of apoptotic cells in SW480 cells exposed to IxoA for 24 h Additional apoptotic studies focused on BIM⁄ BOD, a BH3 region-only pro-apoptotic Bcl-2 family member [36–38] Pro-apoptotic proteins are divi-ded into two subgroups, those that possess BH1, BH2 and BH3 regions and those that only possess the BH3 region [36,39] Pro-apoptotic proteins induce the release

of cytochrome c from the mitochondria, and their abil-ity to achieve this depends on a hydrophobic pocket and an amphipathic a-helix The BH1, BH2 and BH3 regions form a hydrophobic pocket, which binds to a BH3 region of another protein, and the BH3 region consists of an amphipathic a-helix Furthermore, some Bcl-2 family members have exposed BH3 regions, whereas other members have buried BH3 regions that require cleavage to expose the BH3 region and activate cytochrome c release BH3 region-only proteins with exposed BH3 regions, such as BIM⁄ BOD, appear to represent a death ligand, which can neutralize certain pro-survival members of the Bcl-2 family [38,39] On the basis of immunoblotting and immunocytochemistry results obtained to date, the mechanism of IxoA-induced apoptosis appears to involve the interaction of IxoA with BIM⁄ BOD death receptors

Treatment of SW480 cells with IxoA also caused the formation of numerous vacuoles To identify the con-tent of these vacuoles, we began by staining for lipids using Oil Red O We were interested in lipid build-up because several studies have indicated that fatty acids such as linoleic acid may hold anticancer properties [40,41], and perhaps a build-up of fatty acids was triggering apoptosis or cell cycle arrest However, Oil Red O staining revealed that the vacuole content was not lipid Next, the vacuole content was tested for mucin formation A common feature of colonic neoplasia is altered concentrations of mucin Compared with normal colon, colon cancers have been reported

to express decreased concentrations of mucin 3 [42,43] Secreted isoforms of mucin 3 have been reported to protect the colonic epithelial surface [44], and immuno-cytochemical analysis performed on SW480 cells treated with IxoA demonstrated increased mucin 3 concentrations compared with untreated cells This suggests that the vacuole content may include mucin 3, which may play a protective role

In summary, the data reveal that IxoA shows potent antiproliferative and apoptosis activity in human colon cancer cells The evidence presented here suggests for the first time that IxoA present in tomatillos may have chemopreventive or therapeutic value in the manage-ment of colon cancer

Experimental procedures

Physalis philadelphica extract and withanolide

isolates

An ethyl acetate-soluble extract of P philadelphica as well

as four withanolides, IxoA, IxoB, PhilB, and Withpc, were

isolated as previously described [23,32]

Antibodies

The mouse monoclonal antibodies used for these studies

included Rb (clone 1F8), E2F-1 Ab-7 (clone KH129),

cdk1⁄ p34cdc2 Ab-3 (clone A17.1.1 + POH-1), cyclin A

(clone CYA06), and mucin 3 Ab-1 (clone M3.1) as well as

rabbit polyclonal antibody against Bcl-2-related ovarian

death gene (BIM⁄ BOD; clone 1F8), which were purchased

from NeoMarkers (Fremont, CA, USA) Rabbit polyclonal

DP-1 (clone K-20) sc-610 antibody and goat polyclonal

b-actin (clone I-19) antibody were purchased from Santa

Cruz Biotechnology (Santa Cruz, CA, USA)

Cell lines and culture conditions

SW480, SW620, HT-29, Caco-2 and HCT116 human colon

cancer cells were obtained from the American Tissue

Cul-ture Collection (Manassas, VA, USA) The cells were

cul-tured in RPMI 1640 medium supplemented with 10% fetal

bovine serum, 2 mm l-glutamine and 1% antibiotic⁄

antimycotic solution (10 UÆlL)1 penicillin, 10 lgÆlL)1

streptomycin and 25 lgÆmL)1amphotericin B) at 37C in a

5% CO2humidified atmosphere

Growth inhibition assay

The antiproliferative effects of IxoA, IxoB, PhilB, Withpc,

and ethyl acetate-soluble extract were evaluated in human

colon cancer cells using the

3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazolium bromide (MTT) assay (TACS MTT cell

proliferation assay kit; Trevigen, Gaithersburg, MD, USA)

Cells were seeded in 96-well plates at a density of 5· 102per

well Cell viability was analyzed at various time points

between 1 and 7 days after treatment with extract or vehicle

(Me2SO) After treatment with extract, cells were incubated

with MTT tetrazolium reagent for 2 h at 37C, and the

absorbance of formazan was then measured at 570 nm Each

treatment was performed in triplicate, and the percentage cell

growth inhibition was calculated by comparison of the

absorbance readings of the control and treated cells

Fluorescence-activated cell sorter analyses

SW480 cells were treated with or without IxoA for 12, 18

and 24 h, harvested with trypsin, and washed with

NaCl⁄ Pi After the final wash, the cells were resuspended in

1.0 mL NaCl⁄ Pi and 9.0 mL ice-cold 70% ethanol The samples were stored at)20 C until staining In preparation for staining, cells were washed three times with NaCl⁄ Pi and resuspended in 0.3 mL citrate buffer [250 mm sucrose,

40 mm trisodium citrate, 0.05% (v⁄ v) Me2SO, pH 7.6] The samples were then stained with propidium iodide using a previously described method [45]

Apoptosis studies Acridine orange⁄ ethidium bromide staining SW480 cells with or without IxoA treatment were centri-fuged and suspended in NaCl⁄ Pi, followed by the addition

of the acridine⁄ ethidium mixture Fluorescent microscopy was used to distinguish nonviable cells with orange-stained nuclei from viable cells with green-stained nuclei, which do not absorb ethidium bromide The percentage of apoptotic cells and those with highly condensed or fragmented nuclei was determined quantitatively

DNA-binding dye, DAPI staining SW480 cells with or without IxoA treatment were also eval-uated by DAPI staining For this, cells were grown on glass microscope slides, fixed in formalin and methanol, and stained with DAPI Stained nuclei were visualized using a fluorescent microscope Blebbing of the membrane, chroma-tin aggregation, and nuclear condensation were used as cri-teria to identify cells undergoing apoptosis

Western blot analysis Treated and control SW480 cells were lysed in freshly pre-pared extraction buffer (20 mm Hepes, pH 7.9, 400 mm NaCl, 0.1% Nonidet P-40, 10% glycerol, 1 mm sodium vanadate, 1 mm NaF, 1 mm dithiothreitol, 1 mm phenyl-methanesulfonyl fluoride, 10 lgÆmL)1aprotinin, 10 lgÆmL)1 leupeptin) for 45 min on ice Lysate was centrifuged at

15 000 g for 10 min using the Eppendorf 5417R centrifuge, supernatant collected, and protein concentration was deter-mined using a modified Lowry method (Bio-Rad, Hercules,

CA, USA) Samples were separated using 7.5–12.0% poly-acrylamide gels and⁄ or ready-made gradient gels from Bio-Rad, and transferred to nitrocellulose membranes The membranes were blocked in 5% milk followed by incuba-tion with appropriate primary antibodies for 2 h at room temperature The membranes were then washed and incuba-ted for 45 min at room temperature with the corresponding secondary antibodies The chemiluminescence reaction was performed using the ECL system and protocol from Amer-sham Pharmacia Biotech (Piscataway, NJ, USA) Using Un-Scan-It Image Digitizing Software (Silk Scientific; Orem,

UT, USA), the bands of interest were compared with those

of b-actin, and the relative intensity ratios were calculated

SW480 cells were plated on coverslips and allowed to

adhere for 24 h before treatment with IxoA or vehicle for

appropriate time points The cells were washed with

NaCl⁄ Pi, and then fixed with 10% buffered formalin and

cold methanol Staining was then conducted using a BIM⁄

BOD rabbit polyclonal antibody or a mucin 3 mouse

monoclonal antibody The immunoperoxidase reaction was

performed using the Dako LSAB2 System kit (Dako

Cor-poration, Carpinteria, CA, USA) Briefly, the biotinylated

link IgG was applied for 10 min, followed by incubation of

horseradish peroxidase-linked streptavidin After the

sec-tions had been washed with NaCl⁄ Pi,

3-amino-9-ethyl-carbazole (AEC) substrate⁄ chromogen solution was

applied The cells were then counterstained with

hematoxy-lin and examined for antibody localization

Oil Red O staining

Levels of lipid accumulation, a classic differentiation

mar-ker, were measured in IxoA-treated SW480 cells by

histo-chemical analysis using Oil Red O staining Briefly, SW480

cells were plated, treated, and fixed as previously described

for immunocytochemistry studies The samples were then

placed in propylene glycol for 2 min, followed by 1 h

incu-bation in Oil Red O at room temperature Counterstaining

was performed with hematoxylin

Acknowledgements

The studies were supported in part by Public Health

Grants P01 CA48112 and CA103861 from the National

Cancer Institute, National Institutes of Health, and

Department of Health and Human Services

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