The Correlation between the Intrinsic and Extrinsic Molecular Markers in the Inhibition of the Lungs Carcinogenesis Growth by Mahkota Dewa Polyphenols on Balb/c Mouse

Phytochemical analysis shows that mahkota dewa fruit contains polyphenols. Mahkota dewa polyphenols have the ability to disrupt or reverse the stages of cancer or a carcinogenesis process by affecting the intracellular signaling tissue molecules involved in an initiation and/or promotion. This chemopreventive potential is highly anticipating. The use, effectiveness, and benefits of the polyphenol have been empirically and pre-clinically proved without side effects. A multivariate analysis using Spearman’s test was conducted to examine the correlation between variables. Meanwhile, to determine which dependent variables played the strong role, a discriminant function analysis was performed with a significance level of p < 0.05 and a reliability level of 95%. The results showed that the mahkota dewa polyphenols acted as the suppressor agent by inducing apoptosis. This finding proved that polyphenols addition might result in death signal transduction through an apoptosis pathway which is either mediated by death receptor or mitochondria. The results of this study indicate that there is a relationship between apoptotic cell death mediated by death receptor and mitochondria through the administration of mahkota dewa polyphenols, it can be argued that mahkota dewa polyphenols can function in lung cancer chemoprevention in mice strain Balb/c. Correlation between the Intrinsic and Extrinsic Molecular Markers the


Introduction
The mechanism of apoptosis through the mitochondrial (intrinsic) pathway is initiated by the activation of tumor protein compressor 53, an important regulator mediated by mitochondria in response to cellular stress (Breuer et al. [1]).
While the mechanism of cell death through the death receptor pathway (extrinsic) is triggered through death activators that bind to the receptors on the cell surface concerned such as Tumor Necrosis Factor (TNF) and Ligand Fas (FasL) (Hanahan and Weinberg [2]). The Fas ligand pulls the Fas-associated death domain (FADD) in the intracellular direction which then captures procaspase-8 (Pop et al. [7], Viktorsson and Lewensohn [8]). Procaspase-8 transactivation will break down and active caspase-8 then activate procaspase-3 directly and activate active caspase-3 so that apoptosis occurs or enlarge the signal through splitting Bids (Garrido et al. [9]. According to Owen-Schaub, et al. [10], in addition to protein 53 it can activate the mitochondrial pathway, it can also activate the receptor death pathway so that it can activate caspase-8. The process of apoptosis is important in eliminating cells that have damaged DNA that cannot be repaired and if the ability of apoptosis is decreased (Sreedhar and Csermely [11]) or the dysregulation of apoptosis results in cells surviving with DNA damage which in turn results in mutations 4 and is an important process in carcinogenesis (Crighton and Ryan [12], Rousselot and Garnero [13]).
Apoptosis is an important event in the regulation of carcinogenesis and an appropriate balance between cell proliferation and cell death (apoptosis) determines the emergence of malignant neoplasia, hence both cellular processes are targets for chemopreventive intervention (Banerjee et al. [14]). For this reason, testing of medicinal plants as a chemopreventive agent capable of programmatically inducing cancer cell death by providing minimum side effects is indispensable in chemopreventive (Kintono and Pihie [15]).
Chemopreventive strategies aim at cancer intervention by administering natural ingredients that can inhibit, delay, and block or restore the process of carcinogenesis, which can be used to protect against carcinogenic exposure and reduce the risk of lung cancer (Banerjee et al. [16]). Many potential chemopreventive polyphenols can disrupt or reverse the carcinogenesis process by acting on intracellular signaling tissue molecules involved in initiation and/or promotion, but phenolic compounds can also stop or reverse the stage of cancer development (Manson [17], Surh [18]). Its use, effectiveness and utilization have been proven without side effects both empirically and pre-clinical testing (Soeksmanto [19], Soeksmanto [20]). Polyphenols are a very large general chemical class with >8000 known components (Finley [21]; Ross and Kasum [22]). Although the hidrophobic nature is found in most phenolic groups, glycoliation by sugars such as glucose, rhamnosa, galactose and arabinosa makes it soluble in water (Scalbert et al. [23]; Giovannelli et al. [24]). Based on phytochemical analysis, polyphenols are one of the compounds found in mahkota dewa plant (Lisdawati [25], Watuguly [26], Watuguly [27], Faried et al. [28], Sutiono et al. [29], Shahrzad and Bitsch [30]).
In vitro test results conducted by Budijitno et al. [31] by looking at the anticancer effects of breast on C3H mice, were able to increase perforin expression and apoptotic index. Mahkota dewa polyphenols also appeared to have significant efficacy in increasing the apoptosis index.
Experimental studies conducted by Faried et al. [28] in vitro and in vivo on mahkota dewa extracts by looking at anticancer activity in human esophageal squamous cell carcinoma, are able to induce apoptosis in human esophageal cell tissue. In addition, the in vitro test of anticancer activity in C3H mice was able to increase apoptosis by using ethanol extracts mahkota dewa flesh 80 times the human dose induced by transplantation (Rahmawati et al. [32]). The results of other experiments carried out, showed that the mahkota dewa fruit of young and old had hypoglycemic activity with in vitro experiments with increased enzymes of alfaglucosidation and in vivo in mice (Sugiwati et al. [33]).
Mahkota dewa polyphenols are natural phenolics which are expected to have antioxidant properties and can potentially inhibit the growth of lung cancer cells. Studies by Frei and Higdon [34] show that polyphenols act as antioxidants and play a role in preventing cancer. As an antioxidant and anticancer, mahkota dewa polyphenols are expected to induce apoptosis in both the mitochondrial pathway and the death receptor pathway (Giovannini et al. [35]). The purpose of this study is to prove that mahkota dewa polyphenols can inhibit pulmonary carcinogenesis through molecular marker interactions in the intrinsic pathway and extrinsic pathway in Balb/c strain mice.

Study Area
The study began in While the manufacture of paraffin blocks to immunohytochemistry and the reading of preparations were carried out at the Anatomical Pathology Laboratory of the Faculty of Medicine, Diponegoro University, Semarang, the Anatomical Pathology Laboratory, Yogyakarta Yogyakarta and the Anatomical Pathology Laboratory Dr. Sardjito Yogjakarta.

Design and Study Variables
This study is a pure in-laboratory experimental research with posttest control group design, using experimental animal mice Balb/c strains as research objects (Portney et al. [36], Gross and Mary [37], Campbell [38]

Research Samples
The number of samples used in the current research was determined based on the minimal number of samples used in a common experimental study which was (t − 1) (n − 1) ≥ 15. The result of the calculation using the formula suggested five mice as the minimum number to be used in each treatment. One treatment group consisted of three terminated periods. Every terminated period employed 5 mice. This research, therefore, used 45 Balb/c mice in total. This figure had exceeded the criteria set by WHO for mutagenicity (5 animals).

IHC Staining
IHC painting uses antibodies labeled by the enzyme horseradish peroxidase.
These antibodies will be bound to specific proteins. In cells that express proteins positively, the enzymes labeled in antibodies react with chromogen DAB to become a brown substrate, whereas cells with negative expressions will appear purple.
Immunohistochemical staining is scored according to the number of positively colored cells per 100 counted cells. Protein immunoreactivity 53, bax, Bcl-2, caspase-3, caspase-8 and caspase-9 are considered negative (0) when there is no staining; weak (1) when coloring is focal and rather intense; moderate/moderate (2) when about two-thirds of the cells are sufficiently colored; strong (3) when the majority of cells (>two thirds) are stained intensely. This inspection procedure is in accordance with that carried out by Mohan, et al. [39], Letchoumy et al. [40].

Statistical Analysis
Data on the expression of p53, protein Bax, protein Bcl-2, caspase-8, caspase-9 and caspase-3 proteins was collected in the form of ratio scales. Spearman's test was performed to test the correlation of the research variables. Meanwhile, to analyze which dependent variables played a strong role, a discriminant function analysis was conducted with a significance level of p < 0.05 and a reliability interval of 95%. Data collected statistically was analyzed using SPSS vers. 19.

Histopathology of Lungs Carcinogenesis
Findings of this research confirmed that the administration of polyphenols extracted from the mahkota dewa plants could induce apoptosis during lungs carcinogenesis. Therefore, next step to be taken was to determine the effects of the polyphenols on genes expression related to apoptosis. Studies have suggested that pro and anti-apoptosis proteins play a significant role in an apoptotic process; thus, the current study aimed to investigate the effects of the mahkota dewa polyphenols on the expression of p53, pro-apoptosis Bax and anti-apoptosis Bcl-2, Caspase-3, -8 and -9 proteins in Balb/c mice. Observations were con- There was an increase reported by expressions of p53, Bax, Bcl-2, caspase-8, caspase-9, caspase-3 proteins as well for both the control and experimental group on week 8, week, 17, and week 26. In the experimental group in particular, p53, Bax, caspase-8, caspase-9, and caspase-3 proteins expressions experienced an increase meanwhile Bcl-2 protein expression declined significantly (Table 1).

Multivariate Analysis Using Spearman's Correlation Test to Testing the Relationship between the Research Variables
Findings of the research suggested that the mahkota dewa polyphenols could inhibit lungs carcinogenesis on the experimental animals. This phenomenon could be a result of the dependency of the research variables tested in this research which were related to either cell proliferation or apoptosis. Therefore, Spearman's correlation test was conducted to examine the relationship between all dependent variables observed in the current research.

Discriminant Factors of the Research Variables
Multivariate and discriminant analysis could be performed on data which distributed normally. Otherwise, a normality test should be conducted. The initial analysis indicated 2 outlier variables; therefore, data transformation was necessary. The result of the data transformation analysis suggested that all variables were homogeneous and distributed normally. As a result, a discriminant function analysis could be conducted. This analysis was preceded by an equality test to ensure that all independent variables and covariance groups were equal.
The discriminant function analysis was conducted to investigate the interaction roles and contribution of dependent variables observed in both groups (control and experimental groups). The present research employed stepwise discriminant analysis where the variables were inserted one by one into the discriminant model. Meanwhile, the final analysis showed that six variables (p53, Bax, Bcl-2, caspase-8, and -3) could be processed for further analysis, the Fisher's linear discriminant functions analysis (see Table 3). Table 3 and Figure 2 presented values of each variable in the control and experimental groups which had been selected to proceed in the final analysis. To test, the accuracy of the discriminant functions classification, a cross-validated group test was conducted as shown in Table 4.
The results of the discriminant functions analysis indicated two cases, original group (5/5 × 100% = 100%) and cross validated group (5/5 × 100% = 100%). It can be concluded that both groups had the same functions. Output data in Table  5.14 presented that the accuracy of the model was 100.0% which suggested the Open Journal of Applied Sciences inhibition of the lungs carcinogenesis. To anticipate bias, leave-one-out-cross validation was performed and the result was 100.0%. It was then proved that the discriminant functions were very accurate. The original group variables included p53, Bax, Bcl-2, caspase-8, 9, and 3, meanwhile the cross validated group consisted of p53, Bax, Bcl-2, Cas-8 and -3. The results of the analysis, thus, indicated that caspase-9 could be excluded from the analysis because this variable had the most less intense interaction with p53, Bax, Bcl-2 and caspase-8 and -3 both in the control and experimental groups.

Discussion
The chemopreventive properties of the mahkota dewa polyphenols are assumed to be able to cause an apoptotic process indicated by cell's blebbing and shrinkage, increased permeability and decreased mitochondrial potential. An apoptotic cell will experience DNA damage which can be detected with TUNEL staining. According to Bonner et al. [46], the use of this method can result in high specificity to detect cells that undergo an apoptotic process.    It has been reported that EGCG can boost apoptotic index in human's epidermal carcinoma cells A431 (Kelly et al. [47]). According to Ahmad, et al. [48], apoptosis in human's colon adenocarcinoma HT-29 could be induced by EGCG.
Apoptosis can also be triggered by theaflavin and in vivo EGCG. Either theaflavin or EGCG can inhibit cell proliferation and as a result improve apoptosis.
This inhibition process significantly affects lungs carcinogenesis induced by BP in strain A mice (Banerjee et al. [14]). The current research suggest that an increase in the apoptotic index in the experimental group can be a result of the administration of the mahkota dewa polyphenols.
The results of the statistical analyses performed in this research indicated that polyphenols extracted from the mahkota dewa plants could inhibit lungs carcinogenesis in mice through cell proliferation and apoptotic mechanisms. Similarly, the correlation between Bax, Bcl-2, Cas-3 was also significant (p = 0.000) and strong (r = 0.624; 0.754; 0.605). These figures, therefore, the increase of Bax protein as well as the decrease of Bcl-2 which in turn activates caspase-3 in the apoptotic mechanism.
There was also a strong and significant relationship found between p53 and Bax, Cas-8, 9 and 3 proteins (p = 0.001; 0.000). Theories suggest that the activation of Bax protein by p53 will result in releasing c-cytochrome from caspase-9 and end up activating caspase-3 and caspase-8 on the death receptor. Mahkota dewa polyphenols extracted from the have been proved able to activate p53 protein so that caspase-8 is boosted and caspase-3 is triggered. The correlation between Bax and Bcl-2 was significant (p = 0.000) and strong (r = 0.000). This finding suggest that the decreased Bcl-2 expression as an anti-apoptosis and the increased Bax expression as a pro-apoptosis lead to the release of c-cytochrome which initiates an assembly of Apaf-1 (Apoptotis protease-activating factor) and pro-caspase 9 to form an apoptosome. ATP is needed by Apaf-1 to recruit procaspase 9 through the so-called CARD (caspase recruiting domain). Then, procaspase-9 is autolitically broken down into active caspase 9 which can activate pro-caspase 3 and disintegrate substrates and apoptosis. This finding indicate that apoptosis induction by the mahkota dewa polyphenols is not determined by the level of Bcl-2 and Bax expressions only, but by the ratio of both (Chao and Korsmeyer [49]).
The correlation between caspase-8, caspase-9 and caspase-3 was significant (p = 0.000) and strong (r = 0.744). These findings suggest that caspase-8, caspase-9 and caspase-3 play a significant role in inhibiting cell proliferation and inducing apoptosis. Therefore, the administration of the mahkota dewa polyphenols is effective to inhibit lungs carcinogenesis. Overall, the results of this research suggest that polyphenols extracted from the mahkota dewa plants could act as a suppressor agent by inducing apoptosis.
In addition, the administration of the polyphenols can transduce death signal either through death receptor or mitochondrial pathways. Even though it has not been proved which pathway is dominant, it can be assumed that there is a crosstalk relationship between those two pathways at different levels. The interaction between the two pathways, therefore, can activate caspase-3 and induce apoptosis (Mohan et al. [39], Gupta [50]). In short, it can be said that the mahkota dewa polyphenols can perform an anti-cancer activity to inhibit lungs carcinogenesis the increase of p53, Bax, Bcl-2, caspase-8, caspase-9, and caspase-3. Thus, it can be said that the mahkota dewa polyphenols have anti-cancer activity that can play a role in the process of inhibition of pulmonary carcinogenesis in experimental animals through the mechanism of inhibition of pulmonary carcinogenesis, increased protein 53, Bax protein and Bcl-2 and increased caspase-8, caspase-9 and caspase-3.

Conclusion
The results of this study indicate that there is a relationship between apoptotic cell death mediated by death receptor (extrinsic) and mitochondria (intrinsic) through the administration of mahkota dewa polyphenols, it can be argued that mahkota dewa polyphenols can function in lung cancer chemoprevention in mice strain Balb/c.