نوع المستند : مقالات علمیة محکمة
المؤلفون
1 أستاذ علوم وتکنولوجيا الأغذية بکلية الزراعة– جامعة أسيوط وعضو أکاديمية العلوم الأمريکية
2 أستاذ التغذية بکلية التربية النوعية– جامعة عين شمس
3 أستاذ مساعد الکيمياء الحيوية الطبية بکلية الطب– جامعة أسيوط
4 مدرس مساعد بقسم الاقتصاد المنزلي– جامعة أسيوط
المستخلص
الموضوعات الرئيسية
1. Introduction
Cancer is increasing at an alarming rate in the world. Diet and dietary constituents had been found to play an important role in carcinogenesis. Several epidemiologic studies had also showed the importance of dietary habits in carcinogenesis and had shown a relationship between dietary intake and the incidence of cancer (Yamamoto, 2000). 1,2-Dimethylhydrazine (DMH), a potent and complete carcinogen, had been reliably used to induce initiation and promotion steps of colon carcinogenesis in rodents. DMH and related compounds induce neoplasm specifically in colon of rat even after a single dose (Ward, 1974). Experimental colon cancer induced by DMH in rats mimics human colon cancer (Halline et al., 1989) and is therefore an ideal model for cancer studies.
Angiogenesis, the formation of new blood vessels from pre-existing endothelium, had been shown to be critically involved in tumor development and progression and predictive for prognosis or clinical stage in most solid tumors that had been assessed (Folkman, 1990). Vascular endothelial growth factor (VEGF), a soluble angiogenic factor produced by many tumor and normal cells, plays a key role in regulating normal and abnormal angiogenesis (Inser & Asahara, 1999). VEGF is a potent mitogen and chemoattractant for endothelial cells and induces the release of MMP-2, MMP-9, and MT1-MMP by endothelial cells (Velasco, 2002). In addition, VEGF, also known as vascular permeability factor, induces vascular permeability, which allows leakage of plasma proteins, such as fibronectin and other clotting proteins (Dvorak, 2002). Tissue inhibitors of metalloproteinases (TIMPs) is one of the most major inhibitors of MMPs. TIMPs were originally found as collagenase inhibitors in serum and in the conditioned medium from fibroblast cultures (Welgus et al., 1979). There are four TIMPs in humans (TIMP-1 to -4) of 22–29 kDs. TIMP-1 and TIMP-3 are glycoproteins and TIMP-2 and TIMP-4 do not contain carbohydrates. They inhibit almost all MMPs tested so far (Baker et al., 2002).
Many of the common foods found in grocery stores or organic markets contain cancer-fighting properties, from the antioxidants that neutralize the damage caused by free radicals to the powerful phytochemicals. Many naturally occurring substances of plant origin such as spices in human diet exhibited anticarcinogenic and antimutagenic effects. Red chilli is a spice consumed as condiment with food, mostly in the south region of Egypt. Red chilli is the ripened fruit of pepper plant. It is a member of the family Solanecea and its Latin name is Capsicum annuum. Information about red chilli is available from ancient sources. Mayans and Aztecs used it for toothache and for treatment of some diseases. It was reported that 2 drops of red chilli extract cured toothache and sore throat (Boyunaga et al., 1995). In addition, red chilli has many valuable hygienic benefits concerning improvement the digestion of food. Red Chilli consists of 6%-7% glucose, 0.12%-35% carotenoids, nicotinic acid, iron, phosphorus, calcium, protein, water, volatile oils and vitamins A, C and E. The active material capsaicin (8-methyl-N-vanillyl-6-noneamide), causing the hotness, is an odorless white alkaloid soluble in hot water, alcohols and acetone (Rozin, 1990).
Menon, (1996) studied the effect of red chilli on intestinal B-glucuronidase and faecal mucinase activity in rats given DMH. Min et al., (2004) demonstrated the antiangiogenic activity of capsaicin using in vitro and in vivo assay systems. Capsaicin inhibited both VEGF-induced vessel sprouting in rat aortic ring assay and VEGF-induced vessel formation in the mouse Matrigel plug assay. Moreover, capsaicin was able to suppress tumor induced angiogenesis in chick chorioallantoic membrane assay. Nalini et al., (2006) investigated the effect of red chilli on colon cancer induced in rats by a colon-specific carcinogen, DMH. Colon cancer was induced by subcutaneous injection of DMH at a dosage of 20 mg/kg of body weight (15 doses, at 1-week intervals). After the total experimental period of 32 weeks (including 2 weeks of acclimatization) the incidence and number of tumors in the colon were observed to be significantly higher in the rats administered DMH and/or red chilli.
Protecting the safety of our food supply is of higher priority and a greater challenge than at any time in many years. Food sanitization is a process of exposing food to ionising radiation such as gamma rays emitted from the radioisotopes 60Co and 137Cs, or microwave produced by machine sources. Numerous studies dealt with detection methods for irradiated or microwaved spices and had also established that irradiation or microwave technology could be considered radiologically, microbiologically and toxicologically safe technology. Nevertheless, questions focusing on nutrient loss and changes of antioxidant (anticarcinogenic) properties after sanitization of spices are still being debated in the scientific field. Since diet had been correlated with incidence of the cancer disease, our aim was to evaluate the effect of administering raw red chilli and red chillis after treatment by gamma or microwave on the carcinogenicity in albino rats.
2. Materials and Methods
2.1. Source of samples
Nine kilograms of three samples (3.0 kg/sample) of red chilli were procured freshly from the Faculty of Agriculture, AssiutUniversity. The samples were cultivated in the same field in Assiut city and harvested in the same period (January/February 2008). The samples were kept at 5 °C in aroma-tight bags excluding light. The whole sample was homogenized and was grind in a mill type Lab. Mill-1 QC-114.
2.2. Treatment of red chilli sample
One sample of raw red chilli (about 3.0 kilograms) was irradiated at Egyptian Atomic Energy Authority using a 60Co gamma source at an average dose of 10 kGy, which is the average dose recommended by the Codex Alimentarius commission (1990), to reduce microbial load or to reduce the number of pathogenic microrganisms for spices and herbs. Another sample of raw red chilli (about 3.0 kilograms) was treated by microwave radiation. The treatment using microwave radiation (MS143SCE, Samsung Electronics, Korea) was performed by continues supply of red chilli in the pasteurization chamber at 50 W/Kg of red chilli for 15 min., where microwave oscillators allow the sanitization with drastic reduction of the microbic contamination (Less than 103 microorganisms per gram).
2.3. Preparation of solutions:
N,N\-Dimethylhydrazine Dihydrochloride (DMH, 30 mg/kg of body weight) was dissolved in 1 mM EDTA just prior to use, and the pH was adjusted to 6.5 with 0.9%NaCl.
2.4. Experimental animals
Fifty adult male white albino rats, weighing between 150 and 175 grams were obtained from the animal house of the Faculty of Medicine, AssiutUniversity. The animals were kept in wire cages under the normal laboratory conditions. The animals were fed standard diet containing 7 mg/body weight of the studied red chilli samples. This modified powdered diet was fed to rats throughout the experimental period of 18 weeks and 2 weeks prior to the experiment for acclimatization, and tap water was provided. Rats were randomized into 5 groups of 10 animals each. The animals were cared for incompliance with the principles and guidance of Ethical Committee for Animal Care of Assiut University in accordance with the Egyptian National Law on Animal Care and Use. The standard diet used consisted of corn oil, salt mixture, vitamin mixture and cornstarch as described elsewhere (El-Sayed, 2001, Ilwy, 2003 and Anon, 1980).
2.5. Design of the animal experiment
The rats were classified randomly according to the type of red chilli sample present in the given diet under investigation into (5) main groups of (10) rats each. Each rat was marked on the tail to differentiate between animals. Daily administrations were continued for (18) weeks. The groups were classified as the following:
Group I: Rats received the vehicle and act as negative control.
Group II: Rats were fed on diet alone for 4 weeks. Then rats injected DMH (30 mg/kg body weight) once a week subcutaneously for more 8 weeks. Rats continually fed with diet alone for other 6 weeks until the end of the program.
Group III: Rats were fed on diet with raw red chilli for 4 weeks. Then rats injected DMH (30 mg/kg body weight) once a week subcutaneously for more 8 weeks. Rats continually fed with diet combined with raw red chilli for other 6 weeks until the end of the program.
Group IV: Rats were fed on diet with gamma red chilli for 4 weeks. Then rats injected DMH (30 mg/kg body weight) once a week subcutaneously for more 8 weeks. Rats continually fed with diet combined with gamma red chilli for other 6 weeks until the end of the program.
Group V: Rats were fed on diet with microwave red chilli for 4 weeks. Then rats injected DMH (30 mg/kg body weight) once a week subcutaneously for more 8 weeks. Rats continually fed with diet combined with microwave red chilli for other 6 weeks until the end of the program.
2.6. Blood samples:
Five ml blood samples were obtained from each rat by vein puncture under complete aseptic conditions. Blood samples were taken into plain tubes, allowed to clot for 2 hours at room temperature before centrifuging for 20 minutes at approximately 1000 x g. Serum samples were stored into aliquots at -20° C till time of assay.
2.7. Determination of VEGF and TIMP-1 in rats sera:
Serum levels of rat VEGF were determined by monoclonal antibody-based enzyme-linked immunoassay (ELISA)designed to measure Rat VEGF-A165 levels (Quantikine, R&D SystemsInc, Catalog No. RRV00, USA) according to the manufacturer’sinstructions. Rat TIMP-1serum levels were determined by an ELISA kit (Quantikine, R&D SystemsInc, Catalog No.RTM100 USA) according to the manufacturer’sinstructions.
2.8. Statistical analysis
Data were tested for normality and were found to be normallydistributed. Accordingly, data are presented as the mean±SD. Statistical differences between groupswere assessed using paired and unpaired Student t test whereappropriate. Repeated measures analysis of variance (ANOVA)was used to compare differences in serial samples. A value of <0.05 was considered statisticallysignificant. Recovery was calculated by dividing the detector response of analyte in the sample to the response of analyte reference material. Correlation analysis between the different studied variables was performed using spearman’s rank correlation coefficient. All analyses were performed using Statistical Package for Social Sciences (SPSS) software(version 11.0).
3. Results and Discussion
To determine antiangiogenic activity of red chilli, its effects on VEGF-induced proliferation of endothelial cells and TIMP-1 were evaluated. Albino rats were pretreated with various types of red chilli before determination of VEGF or TIMP-1. Rats were fed with raw red chilli and by samples treated by microwave and gamma radiations at 7 mg/body weight for 18 weeks. The studied animals were initially fed with red chillis and were consequently injected with DMH starting from the 5th week till 12th week as a trial to investigate the effect of red chillis on the prevention of cancer.
3.1. Serum levels of Rat Vascular Endothelial Growth Factor (VEGF):
The results of the program concerned with the effect of red chillis on the prevention of cancer after 14 weeks are shown in Table (1). Results revealed that the mean serum levels of VEGF for rats treated with red chillis before DMH injection (5th to 12th weeks) were noticeably differed from control group I and DMH group II. There was a decreased levels of VEGF in gamma and microwave red chillis compared to raw red chilli but such difference did not reach the level of the significance.
The results of the program concerned with the effect of red chillis on the prevention of cancer after 18 weeks are shown in Table (2). Results elucidated that the mean serum levels of VEGF for rats treated with red chillis before DMH injection (5th to 12th weeks) were noticeably differed from control group I and DMH group II. Comparing the results, there was a decrease in the level of VEGF of groups IV and V in comparison to group III but the difference did not reach the level of the significance.
3.2. Serum levels of Rat tissue inhibitor of metalloproteinases 1 (TIMP-1):
The results of the program concerned with the effect of red chillis on the prevention of cancer after 14 weeks are shown in Table (1). Results revealed that the mean serum levels of TIMP-1 in group III for rats treated with raw red chilli was increased in comparison to control group I and DMH group II but the difference did not reach the significance. However, the mean serum levels of TIMP-1 in groups IV for rats treated with gamma red chilli was significantly increased in comparison to control group I and DMH group II (P < 0.001). Meanwhile, the mean serum levels of TIMP-1 in groups V for rats treated with microwave red chilli was significantly increased in comparison to control groups I and II (P < 0.05).
There was a significantly increased level of TIMP-1 in gamma red chilli compared to raw red chilli (P < 0.001). However, there was an increased level of TIMP-1 in microwave red chilli compared to raw red chilli but such difference did not reach the level of the significance. Meanwhile, there was a significantly increased level of TIMP-1 in gamma red chilli compared to microwave red chilli (P < 0.001).
The results of the program concerned with the effect of red chillis on the prevention of cancer after 18 weeks are shown in Table (2). Results elucidated that the mean serum levels of TIMP-1 for rats treated with red chillis before DMH injection (5th to 12th weeks) were noticeably increased from control groups I and II. In the case of gamma red chilli, the difference is significant at P < 0.001 but the difference did not reach the level of significance in the case of microwave and raw red chillis. Comparing the results, there was an increase in the level of TIMP-1 of groups IV and V in comparison to group III but the difference did not reach the level of the significance in the case of microwave red chilli but significant at P < 0.001 in the case of gamma red chilli.
There are significant negative correlations between levels of TIMP-1 (14 weeks) & VEGF (14 weeks), TIMP-1 (14 weeks) & VEGF (18 weeks), TIMP-1 (18 weeks) & VEGF (14 weeks) and TIMP-1 (18 weeks) & VEGF (18 weeks) in the studied groups as shown in Tables from 3 to 6 and figures from 1 to 10.
There are significant positive correlations between levels of VEGF (18 weeks) Vs VEGF (14 weeks) and TIMP-1 (18 weeks) Vs TIMP-1 (14 weeks) in the studied groups as shown in Tables from 3 to 6 and figures from 1 to 10.
The carcinogenic effect of DMH treatment was significantly modulated on red chilli supplementation as indicated by the observed significant changes of serum levels of VEGF and TIMP-1 particularly with gamma irradiated red chilli. The results of this study suggest that red chilli has a beneficial effect on chemically induced colonic cancer in rats.
It was well-known that capsaicin inhibits the arylhydrocarbon hydroxylase responsible for the metabolism of carcinogenic polycyclic aromatic hydrocarbons. Capsaicin was also found to suppress the metabolism and covalent DNA binding of polycyclic aromatic hydrocarbons in human and mouse keratinocytes (Modly et al., 1986). In addition, it has been demonstrated that capsaicin modulates the microsomal cytochrome P450 enzymes, thereby affecting the metabolism of carcinogens and other xenobiotics (Teel, 1991).
An early Italian case-control study revealed that chili consumption was protective against stomach cancer (Buiatti et al, 1989). However, an epidemiologic study showed that chilli pepper consumers have a greater risk to develop stomach cancer than non-consumers (Toth, and Gannett, 1992). A small number of studies have been conducted to assess the carcinogenic potency of chilli (Toth et al., 1984; Toth, and Gannett, 1992). The present study revealed that red chilli has an antiangiogenic activity as presented by significant decrease in VEGF level and significant increase in levels of TIMP-1 in red chilli treated groups. On the cellular level, capsaicin in red chillis almost completely suppressed the stimulatory effect of VEGF on endothelial cell proliferation, migration, and tube formation.
The cytotoxic capacity of the volatile oils based on prooxidant activity can make them excellent antiseptic and antimicrobial agents for personal use. A big advantage of volatile oils shows a very clear antimutagenic capacity which could well be linked to anticarcinogenic activity. Recent studies have demonstrated that the prooxidant activity of volatile oils or some of their constituents is very efficient in reducing local tumor volume or tumor cell proliferation by apoptotic and/or necrotic effects (Paik et al. 2005; Yoo et al., 2005; Kachadourian and Day, 2006). Salim and Fukushima (2003) have shown an antiproliferative activity and inhibition of 1,2-dimethylhydrazine-induced cancer in the rat by volatile oil. Therefore, the sanitization of red chilli by gamma irradiation is more beneficial from the human health point of view than that by microwave where the decreasing amount level of volatile oils is less.
These results could explain the finding that gamma red chilli treated rats showed significant lower levels of VEGF and higher levels of TIMP-1 than other red chilli treated groups.
Table 1: Serum levels of VEGF and TIMP-1 in DMH treated different red chilli groups and controls (14 weeks)
|
Parameter Groups (n =7) |
VEGF (pg/mL) |
TIMP-1 (pg/mL) |
||
|
Mean ± SD |
Range |
Mean ± SD |
Range |
|
|
Group I (Controls) |
30.00 ± 6.56 |
20.0 – 40.0 |
14.14 ± 4.06 |
9.0 – 20.0 |
|
Group II (Diet + DMH) |
442.86 ± 107.91 a*** |
300.0 – 600.0 |
15.71 ± 6.92 a≠ |
9.0 – 26.0 |
|
Group III (raw red chilli + DMH) |
330.71 ± 46.23 a*** b*** |
280.0 – 400.0 |
28.00 ± 8.72 a≠ b≠ |
15.0 – 38.0 |
|
Group IV (gamma red chilli + DMH) |
295.00 ± 37.31 a***b***c≠ |
230.0 – 340.0 |
103.57 ± 30.78 a*** b*** c*** |
65.00 – 160.0 |
|
Group V (microwave red chilli + DMH) |
305.00 ± 36.40 a*** b*** c≠ d≠ |
250.0 – 360.0 |
39.00 ± 9.42 a* b* c≠ d*** |
25.0 – 50.0 |
a: Groups X, XI, XII, XIII versus controls ***: P < 0.001 *: P < 0.05
b: Groups XI, XII, XIII versus Group X ≠: non-significant
c: Groups XII, XIII versus Group XI
d: Group XIII versus Group XII
Table 2: Serum levels of VEGF and TIMP-1 in DMH treated different red chilli groups and controls (18 weeks)
|
Parameter Groups (n =7) |
VEGF (pg/mL) |
TIMP-1 (pg/mL) |
||
|
Mean ± SD |
Range |
Mean ± SD |
Range |
|
|
Group I (Controls) |
30.00 ± 6.56 |
20.0 – 40.0 |
14.14 ± 4.06 |
9.0 – 20.0 |
|
Group II (Diet + DMH) |
480.00 ± 121.79 a*** |
350.0 – 700.0 |
17.00 ± 6.78 a≠ |
10.0 – 27.0 |
|
Group III (raw red chilli + DMH) |
335.00 ± 44.35 a*** b*** |
300.0 – 405.0 |
26.43 ± 7.48 a≠ b≠ |
15.0 – 35.0 |
|
Group IV (gamma red chilli + DMH) |
320.00 ± 57.37 a***b***c≠ |
210.0 – 380.0 |
90.00 ± 30.41 a*** b*** c*** |
55.00 – 150.0 |
|
Group V (microwave red chilli + DMH) |
325.00 ± 32.53 a*** b*** c≠ d≠ |
280.0 – 370.0 |
34.14 ± 8.97 a≠ b≠ c≠ d*** |
20.0 – 45.0 |
a: Groups X, XI, XII, XIII versus controls ***: P < 0.001 ≠: non-significant
b: Groups XI, XII, XIII versus Group X
c: Groups XII, XIII versus Group XI
d: Group XIII versus Group XII
Table 3: Correlation analysis between the different studied variables in group II
|
Variables |
VEGF (14 weeks) |
VEGF (18 weeks) |
TIMP-1 (14 weeks) |
|
VEGF (18 weeks) |
0.9677*** |
|
|
|
TIMP-1 (14 weeks) |
-0.8681* |
-0.8304* |
|
|
TIMP-1 (18 weeks) |
-0.8505* |
-0.8172* |
0.9870*** |
VEGF: vascular endothelial growth factor; TIMP-1: tissue inhibitor of metalloproteinases 1.
*: P < 0.05; ***: P < 0.001
Table 4: Correlation analysis between the different studied variables in group III
|
Variables |
VEGF (14 weeks) |
VEGF (18 weeks) |
TIMP-1 (14 weeks) |
|
VEGF (18 weeks) |
0.9858*** |
|
|
|
TIMP-1 (14 weeks) |
-0.9471*** |
-0.9441*** |
|
|
TIMP-1 (18 weeks) |
-0.8951** |
-0.9169** |
0.9840*** |
VEGF: vascular endothelial growth factor; TIMP-1: tissue inhibitor of metalloproteinases 1.
**: P < 0.01; ***: P < 0.001
Table 5:Correlation analysis between the different studied variables in group IV.
|
Variables |
VEGF (14 weeks) |
VEGF (18 weeks) |
TIMP-1 (14 weeks) |
|
VEGF (18 weeks) |
0.9695*** |
|
|
|
TIMP-1 (14 weeks) |
-0.9034** |
-0.9578*** |
|
|
TIMP-1 (18 weeks) |
-0.9401** |
-0.9838*** |
0.9880*** |
VEGF: vascular endothelial growth factor; TIMP-1: tissue inhibitor of metalloproteinases 1.
**: P < 0.01; ***: P < 0.001
Table 6: Correlation analysis between the different studied variables in group V.
|
Variables |
VEGF (14 weeks) |
VEGF (18 weeks) |
TIMP-1 (14 weeks) |
|
VEGF (18 weeks) |
0.9782*** |
|
|
|
TIMP-1 (14 weeks) |
-0.7464# |
-0.6719# |
|
|
TIMP-1 (18 weeks) |
-0.7630* |
-0.6710# |
0.9845*** |
VEGF: vascular endothelial growth factor; TIMP-1: tissue inhibitor of metalloproteinases 1.
*: P < 0.05; ***: P < 0.001; ≠: non-significant
Fig. 1. VEGF levels in different groups.
Fig. 2. TIMP-1 levels in different groups.
Fig. 3. Correlation between VEGF & TIMP-1
in diet + DMH group at 1 month.
Fig. 4. Correlation between VEGF & TIMP-1
in diet + DMH group at 2 months.
Fig. 5. Correlation between VEGF & TIMP-1
in raw red chilli + DMH group at 1 month.
Fig. 6. Correlation between VEGF & TIMP-1
in raw red chilli + DMH group at 2 months.
Fig. 7. Correlation between VEGF & TIMP-1
in gamma red chilli + DMH group at 1 month.
Fig. 8. Correlation between VEGF & TIMP-1
in gamma red chilli + DMH group at 2 months.
Fig. 9. Correlation between VEGF & TIMP-1
in microwave red chilli + DMH group at 1 month.
Fig. 10. Correlation between VEGF & TIMP-1
in microwave red chilli + DMH group at 2 months.
)
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