DSpace at VNU: The Function of Saffron and its Constituent in Gastroenterological Tissues

Saffron crude extracts, which contain approximately 40% of crocin, significantly inhibited the growth of colorectal cancer cell lines HCT-116, HT-29 and SW-480, although crocin did not

E-ISSN: 2308-6483/15 © 2015 Synergy Publishers

5 Faculty of Pharmaceutical Science, Fukuoka University, Fukuoka 871-6631, Japan

6 School of Medicine and Pharmacy, Vietnam National University, Hanoi, 144Xuan Thuy St Cau Giay, Hanoi,

Vietnam

7 Faculty of Pharmaceutical Science, Nagasaki International University, Nagasaki 859-3298, Japan

Abstract: Japan has been moving towards a super aging society, resulting in a rapidly increasing prevalence of lifestyle

diseases, including colon cancer Japanese patients survey by the Ministry of Health, Labour and Welfare reported

235,000 colon cancer patients in 2015, and this number is quickly increasing due to the change of dietary life style from

the typical Japanese food to the westernized style food Although the cancer chemotherapy has been widely developing

recently, some natural product support, having wide spectra of bioactivity, however mild, are required Saffron finds use

as folk medicines as well as a flavoring and a coloring agent Saffron consists of three main chemical components; red

color, crocetin glycosides; a bitter taste, picrocrocin; and spicy aroma, safranal In this chapter, we evaluate the activities

of saffron extracts and a major crocetin glycoside, crocin against colorectal cancer in in vitro and in vivo trials Saffron

crude extracts, which contain approximately 40% of crocin, significantly inhibited the growth of colorectal cancer cell

lines HCT-116, HT-29 and SW-480, although crocin did not affect for non-cancer cells Crocin significantly inhibited the

development of colonic adenocarcinomas induced by azoxymethane and dextran sodium sulfate in mice during 18

weeks feeding The crocin feeding experiment for 4 weeks evidently inhibits the dextran sodium sulfate induced colitis

and, then, the clear suppression for the mRNA expression of tumor necrosis factor
, interleukin- (IL-) 1,IL-6, interferon

, NF-B, cyclooxygenase-2, and inducible nitric oxide synthase, and the increase of Nrf2 mRNA expression in the

colorectal mucosa occurred From these results we suggest that crocin can suppress chemically induced colitis and

colitis-related colon carcinogenesis in mice mainly through the inhibition of inflammation related cytokines, indicating that

saffron and crocin are suitable candidates for the prevention of colitis and inflammation-associated colon carcinogenesis

We further review the supporting phenomena like strong anti-oxidant and anti-inflammation activities of crocin using our

previous publications

Keywords: Crocus sativus, saffron, crocin, colorectal cancer cell line, colon carcinogenesis, anti-inflammation

activity

1 INTRODUCTION

Japan has been moving towards a super aging

society, resulting in a rapidly increasing prevalence in

lifestyle diseases, including colon cancer Japaneses

patient survey by the Ministry of Health, Labour and

Welfare reported 235,000 colon cancer patients in

2015, and this number is quickly increasing due to the

change of dietary life style from the typical Japanese

food to the westernized style food Although the cancer

chemotherapy has been widely developing recently,

some natural product support, having wide spectra of

bioactivity, however mild, are required This is the

reason why natural products having preventive

activities for cancers are particularly desirable in Japan

*Address correspondence to this author at the Faculty of Pharmaceutical

Science, Nagasaki International University, Nagasaki 859-3298, Japan;

Tel/Fax: +81-956-20-5653; E-mail: shoyama@niu.ac.jp

Considering such recent health circumstances in Japan, we select saffron for preventing and increasing quality of life against cancers, and its function will be reviewed in this chapter because we have been clarified the multifunctional activity of saffron and its constituent, crocin [1], although saffron was not listed in the NCI report indicating the 40 foods having anti-cancer activity [2]

Crocus sativus L (Iridaceae) is a perennialherb that

is widely cultivated mainly in Iran, which produces 90%

of saffron, and in other countries like Greece, Spain and Morocco for its red stigmatic lobes that constitute saffron from 3500 years ago This plant blooms only once a year and the manual harvest of stigmas should

be performed within a very short time [3]

The manual cultivation methods practiced with

saffron crocus contribute greatly to its high price About

100,000 flowers give about 1,000 g of the dried saffron

The stigmas can be collected from full blooming C

sativus (Figure 1 Left) We confirmed that the

concentration of crocin increases until full blooming and

then decreases Therefore, stigmas can be collected in

full blooming season in order to keep the higher

concentration of crocin [4]

Saffron finds use as folk medicines and traditional

Chinese medicine (TCM) as well as a flavoring and a

coloring agent Saffron has three main chemical

components: the bright yellow coloring carotenoids, a

bitter tastingpicrocrocin, and spicy aroma, safranal The

carotenoid pigments consist of crocetin-diglucoside,

crocin-2, crocin-3, crocin-4 and

crocetin-di-(
-D-digentiobiosyl)-ester (crocin) (Figure 2) More recently

we succeeded to isolate a novel crocetin glycoside,

trans-crocetin-1-al 1-O-
-gentiobiosyl ester (Figure 2)

[5] We confirmed that drying is important because an

endogenous
-glucosidase is still active when moisture

remains [4] Therefore, drying is completed in about

30-45min, after which the drug is cooled and stored under

dry condition [4]

Saffron can be used as an antispasmodic,

anticatarrhal, and nerve sedative ingredient, and is

reported to be useful in treating various human

disorders such as heart and blood disorders [6] Crocin

has a wide range of activities including antioxidant

[7,8], hypolipidemic [9,10,11] like lowering of

cholesterol and triglyceride levels in serum by crocin

and crocetin [12], an inhibitory effect on the increase of

bilirubin in blood [13] and anti-inflammatory effects

[14-16] The neuroprotective activities of crocin have also

been demonstrated in various experimental animal

models of brain disorders, such as cerebral ischemia [17], Alzheimer disease [18], depression [19], memory impairment [20-22] and neuroprotective activity [7,17,23,24]

Figure 2: Structures of saffron constituents

Since it becomes clear that saffron and its constituent, crocin have the wide pharmacological activities as described above, we focus to confirm the incorporation of crocin into cells first and the

anti-colorectal cancer activities of saffron and crocin in vitro and in vivo in this chapter

Figure 1: Blooming of Crocus sativus L (left) and saffron (right)

conjugated with BSA to give crocin-hemisuccinate BSA

conjugate as indicated in Figure 3 The molecular

weight of prepared schiff base was analyzed by

MALDI-tof-mass spectrometry to determine the hapten

number in the conjugate for suitability of immunization

Since the hapten number in crocin-hemisuccinate BSA

conjugate was determined to be 8.6, which was

suitably enough for immunization rather than that of

crocin-BSA conjugate prepared by NaIO4 treatment,

the former was used as an antigen Hybridoma

producing MAb reactive to crocin was obtained by

general procedure, and classified into IgG2a, which

after the addition of crocin in the medium was not

enough after 15 min (Figure 4B) After 30 min, the clear staining occurred (Figure 4C and D) From this

evidence we confirmed that crocin can be incorporated into the cell and be functioned

3 ANTI-PROLIFERATION ACTIVITIES OF SAFFRON EXTRACT AND CROCIN AGAINST HUMAN COLORECTAL CELL LINES

Anti-tumour activity of saffron on mice transplanted with sarcoma-180, Ehrlich as cites carcinoma and Dalton’s lymphoma as cites tumours [26], inhibitory effects of saffron on chemical carcinogenesis in mice using two-stage assay system [27,28,29] and the effect

of crocetin on skin papillomas and rous sarcoma [30]

Escribano et al (1996) reported crocin inhibits the

growth of Hela cells and suggested apoptosis induction [31] Effects of saffron extracts and crocin on the proliferation of colorectal cancer cell lines, we investigated HCT-116, SW-480 and HT-29 [32]

Figure 5A shows the relationship between saffron

extract concentration and the inhibition of proliferation for the three cell lines At 0.25 and 0.5 mg/ml levels of saffron extract no inhibition occurred in three cell lines When 1.0 mg/ml of saffron extract was added, the decrease of proliferation ratio was observed resulting in 45.5, 91.0 and 79.2 %, in HCT-116, SW-480 and

HT-29 cells, respectively In the case of 3.5 mg/ml of saffron extract, strong inhibition appeared in all cells as

6.8, 17.6 and 12.9 %, respectively (Figure 5A) From

these results HCT-116 cells were the most sensitive to saffron extract, suggesting the major constituent of saffron, crocin, might be strongly affective for three cell lines

The same tendency was observed with the addition

of crocin (Figure 5B) At a 1.0 mM concentration of

crocin, HCT-116, SW-480 and HT-29 cells proliferation was significantly reduced to 2.8, 52 and 16.8%

Figure 3: Synthetic pathway of hapten for preparation of

monoclonal antibody against crocin

proliferation, respectively (P < 0.01), although at 0.03,

0.1 and 0.3 mM the affect was not strong Consistent

with the saffron data, crocin has the most significant

anti-proliferative effect on HCT-116 cells Since the

concentration of crocin in the saffron crude extract is

approximately 40 % [4], 3 mg of saffron extract and 1

mM of crocin are nearly equivalent Therefore, the

above two results (Figure 5A and B) are satisfactory

although the other minor crocetin-glycosides are contained in saffron extract as previously documented [4]

Figure 4: Immunostaining of crocin in PC-12 cells using anti-crocin monoclonal antibody

A Control cells

B Culturing for 15 min C Culturing for 30 min D Culturing for 1h

Figure 5: Effects of saffron extract (A) and crocin (B) on proliferation of human colorectal cancer cells, HCT-116, SW-480 and

HT-29

was compared to that of the HCT-116 cells At the

tested concentration range, saffron extract did not

show any significant inhibition of the YAMC cells, while

cell growth was significantly inhibited in HCT-116 cells

at 1.0 mg/ml (P < 0.01)

4 ANTI-COLORECTAL CANCER ACTIVITY OF

CROCIN IN VIVO

Previous in vitro investigation clearly showed that

the real constituent having anti-cancer activity in

saffron was crocin First of all, we confirmed that no

observable clinical toxicity was found in the mice by

histopathological survey of liver and kidneys, by

weights of the whole body and liver, and by the colon

length after feeding of crocin for 8 weeks This is in

good agreement with the previous data that the oral

LD50 of saffron was approximately 20 g/kg [33],

meaning it is a very safe food

Following the in vitro data of crocin using three

colorectal cell lines we started the in vivo experiments

using mice with the feeding of azoxymethan (AOM) and

dexran sodium sulfate (DSS),which were applied as the

promotional agent for the induction of colorectal lesions

[34] The feeding of AOM and/or DSS in mice was

investigated The AOM and/or DSS treatment indicated

the occurrence of several colorectal lesions, such as

colitis with mucosal ulcers, dysplastic crypts, tubular

adenoma and tubular adenocarcinoma resulting in the

clear incidences and multiplicity of colorectal

inflammation with mucosal ulcers and the presence of

dysplasia after 18 weeks

The incidence of inflammation with mucosal ulcers

significantly decreased after feeding of all three

concentrations of crocin (50, 100 and 200 ppm)

compared to AOM + DSS group Similarly, the

inflammation score decreased after crocin treatment at

the higher concentrations (100 and 200 ppm) The

Figure 6: Histopathological survey of colonic proliferative

lesions (tubular adenocarcinoma) induced by azoxymethane (AOM) and dextran sodium sulfate (DSS)

The incidence and multiplicity of colonic tumors after 18 weeks of feeding were observed The AOM + DSS group clearly indicated colonic adenocarcinoma

with an incidence of 90% and a multiplicity of 3.15 ± 1.87 On the other hand the treatment with three

concentrations of crocin significantly reduced the incidence and multiplicity of adenocarcinoma Crocin also significantly decreased the incidence of adenomas and the multiplicities of colonic adenoma

The expression of minichromosome maintenance protein 2 (MCM2) related to the DNA replication in colonic adenocarcinoma areas was surveyed by the immunohistochemical analysis using anti- MCM2 rabbit MAb in order to determine the effects of crocin on the proliferation of cancer cells From this analysis, a clear decrease of staining in adenocarcinoma was observed

in the treatment with crocin compared to that of AOM + DSS group, indicating that crocin evidently decreased

the cancer cell proliferation (Figure 7)

To make sure the expression of NF-kB and Nrf2 by the treatment with or without crocin, the immunohistochemical analysis in the adenocarcinomas that will be developed into the colons was investigated When compared with the AOM + DSS group, the treatment of crocin at 100 ppm and200 ppm significantly suppressed the immunohistochemical

score for NF-
B, while significantly enhancing the

expression of Nrf2 at 200 ppm crocin In the crocin

alone group (200 ppm) and the untreated group, the

immunohistochemical expressions of NF-B and Nrf2

in the colonic mucosa were very weak

The colonic mucosa of mice treated with 200 ppm of

crocin alone showed almost normal histology On the

other hand the DSS treatment induced severe colitis

with mucosal ulcers The induction of colitis in the mice

treated with DSS and crocin at 100 ppm or 200 ppm

decreased, and regenerative crypt cells covered and

healed the mucosal ulcers as shown in Figure 8

Figure 8: Histopathological survey of colorectal mucosa

Treated with DSS and 200 ppm of crocin

The inflammation scores of the DSS + 50 ppm

crocin (P <0.05), DSS + 100 ppm crocin (P <0.01), and

DSS + 200 ppm crocin (P <0.001) groups were

significantly decreased dose-dependently than those of

the DSS alone group as indicated in Figure 9

The relative mRNA expression levels of COX-2,

iNOS, IFN-, TNF-
, IL-1, IL-6, NF-B and Nrf2 were

surveyed comparing with the DSS alone group by an RT-PCR analysis The expression levels of all genes except iNOS and Nrf2 in the mice treated with DSS were dose-dependently decreased by the combination with crocin On the other hand the expression levels of Nrf2 and iNOS were increased by the treatment with crocin

Figure 9: Inflammation score in colorectum with DSS and/or

crocin

5 CONCLUSION

In cancer chemotherapy, the induction of cancer cell apoptosis has been emphasized, and the cell apoptosis

is mediated by many factors Among them, p53 gene is

a transcription factor placed at the nexus of a number

of pathways that mediate apoptosis in response to a wide range of cellular stresses [35] HCT-116 cells are

p53 gene wild-type, while SW-480 and HT-29 cells are

mutant in the p53 tumor suppressor gene Since the

effects of saffron extract and crocin on HCT-116 are stronger than that of HT-29 and SW480, it suggests

that some activity of p53 gene may be linked to the

saffron extract and crocin to express the anti-cancer effects [36] Furthermore, crocin has anti-tumor effects

Figure 7: Immunohistochemical staining for minichromosome maintenance protein 2 (MCM2) by anti-MCM2 monoclonal

antibody

Left colorectal tissues treated with azoxymethane (AOM) and dextran sodium sulfate (DSS)

Right Treatment with AOM/DSS and crocin 200 ppm

in the activation of NF-B and are associated with a

number of chronic inflammatory diseases, including

inflammatory bowel disease (IBD) and IBD-related

colorectal carcinogenesis [41-45] We observed

decreases in the mRNA expression levels of NF-B,

COX-2, TNF-
, IL-1, and IL-6 in the mice treated with

DSS and crocin compared to the mice with DSS alone

These evidences suggest that crocin suppressed the

mouse colonic inflammation induced by DSS by

modulating the NF-B signaling pathway The NF-B

signaling pathway also has a major role in

inflammation-associated carcinogenesis [46]

Therefore, NF-B is a target for cancer

chemoprevention [47,48], and natural compounds that

suppress NF-B expression may be useful for cancer

chemoprevention [49] As previously documented

crocin has the anti-inflammatory effects [14-16], these

evidences might be related to a range of inflammation

gene expression Since rocin did not produce any

chromosome damage in mammalian cells in culture

[50], the clinical trials of crocin may be possible

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