Oktavianus 83 *Department of Parasitology, Medical School, Atma Jaya Catholic University of Indonesia **Medical student of Medical School, Atma Jaya Catholic University of Indonesia ***Department of Chemistry, Medical School, Atma Jaya Catholic University of Indonesia Correspondence dr. Hanna Yolanda, M.Kes. Department of Parasitology Medical School, Atma Jaya Catholic University of Indonesia Pluit Raya 2 Jakarta 14440 Phone: +6221 6693168; +62813 222 85483 Email : hanna.yolanda@atmajaya.ac.id Univ Med 2014;33:83-90 ABSTRACT UNIVERSA MEDICINA May-August, 2014May-August, 2014May-August, 2014May-August, 2014May-August, 2014 Vol.33- No.2 Vol.33- No.2 Vol.33- No.2 Vol.33- No.2 Vol.33- No.2 BACKGROUND To develop new effective antifungals, it is essential to search for antifungal compounds from plants such as Nepenthes spp., which have their greatest diversity in Indonesia. Since chitin-induced liquid (CIL) from Nepenthes khasiana pitchers has antifungal activity, due to their naphthoquinone content, this study aimed to evaluate antifungal activity of Nepenthes rafflesiana pitcher liquids on Candida spp. METHODS Collected pitcher liquids were of 3 types: non-induced liquid (NIL), prey-induced liquid (PIL), and chitin-induced liquid (CIL). Non-induced liquid (NIL) was collected from fresh naturally opened pitchers, PIL from opened pitchers after 3 hours of induction with Zophobas morio larvae, and CIL from closed pitchers after 5 days of chitin solution injection. The antifungal activity of the liquids against C. albicans, C. glabrata, C. krusei, and C. tropicalis were detected by disc diffusion and macrodilution methods. RESULTS Inhibition zone diameters of NIL, PIL, and CIL against C. albicans were 35.00 (35.00 – 39.33) mm, 26.33 (23.00 – 40.00) mm, and 30.00 ( 28.00 – 32.00) mm, respectively, while for C. glabrata the zone diameters were 22.22 ± 3.66 mm, 29.89 ± 2.79 mm, and 28.89 ± 1.17 mm, respectively. No inhibition zones were found for NIL, PIL, and CIL against C. krusei and C. tropicalis. At concentrations of 80%, almost all samples showed visually apparent inhibition of fungal growth. CONCLUSION The pitcher liquid of N. rafflesiana has antifungal properties, presumably due to the presence of many potentially active substances, such as naphthoquinones, as has been proven in other studies. Key words : Antifungal, chitin-induced, disc diffusion, Nepenthes, Candida Nepenthes rafflesiana pitcher liquid has antifungal activity against Candida spp. Hanna Yolanda*, Ingrid M. Makahinda**, Maureen Aprilia**, Nikki Sanjaya**, Harry Gunawan**, and Rita Dewi*** 84 Yolanda, Makahinda, Aprillia, et al Nepenthes rafflesiana against Candida spp. Aktivitas antijamur cairan kantong Nepenthes rafflesiana terhadap Candida spp. PENDAHULUAN Untuk mengembangkan obat antijamur baru yang efektif, adalah sangat penting untuk mencari senyawa antijamur dari sumber alamiah, seperti Nepenthes spp., yang paling aneka ragam di Indonesia. Karena cairan kantong Nepenthes khasiana yang telah diinduksi kitin memiliki aktivitas antijamur akibat kandungan naftokuinon, penelitian ini bertujuan untuk menilai aktivitas antijamur Nepenthes rafflesiana terhadap Candida spp. METODE Cairan kantong yang dikumpulkan ada 3 jenis yaitu: cairan yang tidak diinduksi (T), cairan yang diinduksi mangsa (M), dan cairan yang diinduksi kitin (K). T diambil dari kantong yang baru terbuka secara alami, M diambil dari kantong terbuka yang telah diinduksi larva Zophobas morio selama 3 jam, dan K diambil dari kantong tertutup yang telah disuntikkan larutan kitin selama 5 hari. Aktivitas antijamur ketiga jenis cairan tersebut terhadap C. albicans, C. glabrata, C. krusei, dan C. tropicalis dideteksi dengan menggunakan metode difusi diskus dan makrodilusi. HASIL Diameter zona inhibisi tampak pada uji T, M, dan K terhadap C. albicans [35,00 (35,00 – 39,33) mm, 26,33 (23,00 – 40,00) mm, dan 30,00 ( 28,00 – 32,00) mm] dan C. glabrata (22.22 ± 3.66 mm, 29.89 ± 2.79 mm, dan 28.89 ± 1.17 mm). Pada uji T, M, dan K terhadap C. krusei dan C. tropicalis tidak tampak adanya zona inhibisi. Pada konsentrasi 80% didapatkan berkurangnya pertumbuhan jamur secara visual pada hampir semua sampel uji. KESIMPULAN Cairan kantong N. rafflesiana memiliki aktivitas antijamur, karena mengandung beberapa zat potensial, antara lain adalah naftokuinon. Kata kunci : Antijamur, diinduksi kitin, difusi diskus, Nepenthes, Candida ABSTRAK INTRODUCTION T h e e m e r g e n c e o f t h e h u m a n immunodeficiency virus infection, modern patient-management technologies and therapy, s u c h a s b o n e m a r r o w a n d s o l i d - o r g a n transplants, and the use of more aggressive chemotherapy have resulted in a rapidly expanding number of immunocompromised patients highly susceptible to fungal infections,(1) the most common being candidiasis. Because of increasing use of antifungals and the limited types of antifungals, the development of resistence is an important issue. In addition, adverse effects, drug-drug interactions, and toxixity, are also factors that influence the use of antifungals. Therefore, exploration to find new a n d e f f e c t i v e c o m p o u n d s f o r a n t i f u n g a l chemotherapy is of pivotal importance.(2) Exploration of natural products that may have antifungal properties has been increasing. Naphthoquinones are a group of secondary metabolites with antifungal properties occurring in a number of plant families, such as the Nepenthaceae.(5) Nepenthes are carnivorous plants that have developed insect capturing- traps, evolved by specific modification of the leaf tips, and capable of utilizing digested insects. Nepenthes khasiana, commonly found i n I n d i a , h a s b e e n f o u n d t o c o n t a i n naphthoquinones, especially droserone and 5- O-methyldroserone.(3,4) 85 Indonesia, as a tropical country, has many species of Nepenthes, such as Nepenthes rafflesiana, since the distribution of Nepenthes is predominantly in Indonesia, especially Borneo. The liquid inside the pitchers is traditionally used for relieving eye disorders, cough, stomach ache, burn injuries, and skin diseases.(6) Several studies have been conducted to detect antifungal activity in Nepenthes, but none of them have explored antifungal activity in pitcher fluid of N. rafflesiana.(3,7,8) A study by Eilenberg et al.(3) on the antifungal effects of chitin-induced liquid (CIL) from N. khasiana to Candida spp. concluded that only CIL efficiently inhibited fungal pathogens.(3) It has been suggested that either chitin itself or its breakdown products induce the synthesis of antifungal agent/s, that are not produced under natural conditions either in closed or opened pitchers. However, subsequently many enzymes, such as endochitinases, were detected inside closed pitchers.(9) Since chitin is one of the major components of fungal cell walls,(10) these results suggested that closed pitchers may have antifungal effects as a result of compounds other than naphthoquinones, e.g. chitinases. In this study, we used 3 types of pitcher liquid of N. rafflesiana, i.e. non-induced liquid (NIL), prey-induced liquid (PIL), and CIL. The objective of this research was to determine if pitcher liquids of N. rafflesiana have antifungal activity on tested Candida spp. and have significant differences in activity. N. rafflesiana is a lowland pitcher plant and thus easy to cultivate in Jakarta. The pitcher liquid of N. rafflesiana has the unique characteristic of being the most viscoelastic. A 95%-dilution in water still retains enough viscoelasticity to capture all insects dropped into the pitcher.(11) METHODS Research design T h e d e s i g n o f t h i s r e s e a r c h w a s experimental laboratory. This research was done i n M e d i c a l S c h o o l , A t m a J a y a C a t h o l i c University of Indonesia, from March 2013 to November 2013. The first six months were used to collect the 3 types of pitcher liquid until we had enough stock. The next months were used to conduct the antifungal activity tests. Plant materials N. rafflesiana plants were obtained from Borneo island and looked after in the garden of the Medical School of Atma Jaya Catholic University of Indonesia. We used pitcher liquid from the lower pitchers of N. rafflesiana that were more than 7 cm in height, measured from the base to the spur of the pitcher. We used larvae of Zophobas morio as prey for induction. The chitin solution was made from dried prawn exoskeletons. For fungal preparation and disc diffusion test, we used Sabouraud dextrose agar (Difco, France), Mueller Hinton agar (Difco, France) with the addition of 2% glucose and 0.5 mg/L methylene blue.(12) The discs were 5 mm in diameter, cut out of Whatman filter paper No. 42. For the macrodilution method, we used Sabouroud dextrose broth (Difco, France). As test fungi we used four Candida species, viz. C a n d i d a a l b i c a n s , C a n d i d a g l a b r a t a , Candida kr usei, and Candida tropicalis, obtained from the fungal collection of the Parasitology Department, Medical Faculty, University of Indonesia. Chitin extraction The chitin solution was prepared from ground dried prawn exoskeletons, which were washed by boiling with distilled water for 1 hour. The mixture was centrifuged to precipitate the solid phase, which was separated by filtration through filter paper. The solid phase was stirred in an ethanol : ether : HCl mix (38:38:0.8, v:v:v) for 15 minutes, then the mixture was filtered through filter paper. Thereafter, the solid phase was solubilized in 0.2 M NaClO for 1 hour at 75oC. After an additional filtering, the solid phase was solubilized in acetone and 32% HCl (1:150, v:v) at 4oC. After centrifugation, the supernatant (solubilized chitin) was collected and the chitin Univ Med Vol. 33 No.2 86 Yolanda, Makahinda, Aprillia, et al Nepenthes rafflesiana against Candida spp. was precipitated by adding ice-cold water and incubating at 4oC overnight. The acid was removed by subsequent washes with cold water until the pH of the supernatant reached 2.5. The prepared chitin was allowed to dry on a filter paper, then 80 mg of the chitin was homogenized with 10 mL distilled water, and the pH of the colloidal chitin adjusted to 5 by addition of 1 N NaOH.(3,4,13) Collection of pitcher liquid The NIL, PIL, and CIL were collected as follows.We wrapped target-pitchers with sealed plastic. NIL was collected from fresh naturally opened pitchers (opened less than 24 hours). PIL was collected from opened pitchers after 3 hours of Z. morio induction. CIL was collected from closed pitchers after 5 days of 2 ml chitin injection (8 mg/mL chitin solution).(3,4) All of the liquids were stored in dark bottles at 4oC.(14) Before being used for the disc diffusion tests, the samples were incubated in a water bath at 50oC for an hour. We collected the liquid from 20 plants of N. rafflesiana. Fungal preparation All Candida species were subcultured into Sabouraud dextrose agar at 37 oC for 24 hours.(15,16) The inocula were prepared from 24- hour old cultures of Candida spp. The colonies were suspended in sterile saline, then the turbidity of the homogenous suspension was a d j u s t e d b y s p e c t r o p h o t o m e t r y t o ~ 0 . 5 McFarland standard at 530 nm. This stock suspension was used for the disc diffusion method. For macrodilution, this stock suspension was diluted 1:2000 in Sabouroud dextrose broth.(12,15,16) Disc diffusion test The 24-hour cultures of Candida spp. were cultured onto Mueller Hinton agar with the addition of 2% glucose and 0.5mg/L methylene blue, by dropping 10 µL fungal suspension onto the agar and spreading it over the entire surface by sterile swab to obtain a confluent growth.(12) The sterile discs were soaked in NIL, PIL, or CIL and placed on the seeded surface.(17) A sterile disc soaked in aquabidest and similarly placed on the seeded medium was used as a control. The plates were incubated at 37oC for 24 hours, then examined for inhibition zones around the paper discs, indicating antifungal activity. The inhibition zone diameters (in millimeters) were measured in triplicate at the point at which there was a prominent reduction in growth, repeating the measurements in different diagonals, and calculating their mean value. All disc diffusion tests were performed in triplicate. Macrodilution We used pitcher liquid in concentrations of 20%, 50%, and 80%. A volume of 1000 µL fungal suspension was used as control. The mixtures were incubated at 37oC for 24 hours, then their turbidities were compared with that of the control. These tests were also performed in triplicate. Statistical analysis Inhibition zone diameters of pitcher liquids were compared using one-way Anova test or Kruskal-Wallis test. For all Candida spp. except C. glabrata, the test results are shown as median (minimum – maximum) because they were non-normally distributed and were tested by Kruskal-Wallis test. The normally distributed C. glabrata data were tested by one-way Anova, with the results shown as mean (± standard deviation). Results were considered significant if p<0.05. RESULTS The color of NIL and PIL was a cloudy white, with PIL being more cloudy than NIL. On chitin induction, the color of the pitcher liquid changed to orange red (Figure 1). The pH values of NIL, PIL and CIL were 3.1, 3.0, and 2.6, respectively. All samples were slimy. The tested pitcher liquids exhibited different degrees of antifungal activity against Candida 87 spp. NIL, PIL, and CIL inhibited the growth of C. albicans and C. glabrata. The diameters of the inhibition zones found on testing of NIL, PIL, and CIL against C. albicans were 35.00 (35.00 – 39.33) mm, 26.33 (23.00 – 40.00) mm, and 30.00 (28.00 – 32.00) mm, respectively. For tests against C. glabrata , the inhibition zone diameters of NIL, PIL, and CIL were 22.22 ± 3.66 mm, 29.89 ± 2.79 mm, and 28.89 ± 1.17 mm, respectively. No inhibition zones were found in NIL, PIL, and CIL tests against C. krusei and C. tropicalis. (Table 1 and Figure 2). By Kruskal-Wallis test, there were no significant differences in inhibition zones among the 3 types of pitcher liquid against C. albicans (p=0.298) (Table 1). In contrast, for tests against C. glabrata, using one-way Anova, significant differences were found between 2 types of pitcher liquid (p=0.027) (Table 1). By post-hoc LSD test, there were significant differences in inhibition zones between NIL and PIL (p=0.014), and between NIL and CIL (p=0.025), but no significant differences between PIL and CIL (p=0.671). The concentrations of NIL and PIL that showed decreased growth of C. albicans, C. glabrata, C. krusei, and C. tropicalis, were observed visually to be 80%, 50%, 80%, and 50%, respectively. On the other hand, the CIL concentrations showing decreased growth of C. albicans , C. glabrata, C. krusei, and C . tropicalis were observed visually to be 80%, 20%, 80%, and 80%, respectively (Table 2). Figure 1. Pitcher liquid of N. rafflesiana: non-induced liquid (NIL) (A), prey-induced liquid (PIL) (B), and chitin-induced liquid (CIL) (C) A B C CA B D FE Figure 2. Results of disc diffusion test of non-induced liquid (NIL), prey-induced liquid (PIL), and chitin- induced liquid (CIL) to C. albicans and C. glabrata. Inhibition zone of NIL to C. albicans (A), PIL to C. albicans (B), CIL to C. albicans (C), NIL to C. glabrata (D), PIL to C. glabrata (E), CIL to C. glabrata (F) Univ Med Vol. 33 No.2 88 Yolanda, Makahinda, Aprillia, et al Nepenthes rafflesiana against Candida spp. Fungi Pitcher liquid Diameter of inhibition zone (mm) p value C. albicans NIL 35.00 ( 35.00 – 39.3 3)† 0.298* PIL 26.33 (23.00 – 40.00) † CIL 30.00 ( 28.00 – 32.00) † C. glabrata NIL 22.22 ± 3.66‡ 0.027** PIL 29.89 ± 2.79‡ CIL 28.89 ± 1.17‡ C. krusei NIL n o zone PIL n o zone CIL n o zone C. tropicalis NIL n o zone PIL n o zone CIL n o zone Control n o zone Table 1. Inhibition zone of NIL, PIL, and CIL against Candida spp. growth in vitro NIL : non-induced liquid; PIL : prey-induced liquid;CIL : chitin-induced liquid; † Data are shown as median (minimum – maximum) because data distribution was not normal; ‡ Data are shown as mean ± standar deviation because data distribution was normal; * Kruskal-Wallis test; ** One-way Anova. Post-hoc LSD test : NIL vs PIL p=0.014; NIL vs CIL p = 0.025; PIL vs CIL p = 0.671 DISCUSSION The CIL color change into orange red was similar to that found by Eilenberg et al. in CIL of Nepenthes khasiana.(3) According to these investigators, the color change was associated with the presence of droserone (3,5-dihydroxy- 2-methyl-1,4-naphthoquinone), which has antifungal properties. The pH of NIL, PIL, and CIL was acidic, as has also been determined by several studies, which found that the pH of most pitcher fluid is acidic, rarely neutral.(18,19) N. rafflesiana has the unique characteristic of its highly viscoelastic fluid, differing in this respect from other Nepenthes species. A c c o r d i n g t o a C l i n i c a l L a b o r a t o r y Standard Institute document, the sensitivity to fluconazole, one of the standard treatments of candidiasis, is defined as an inhibition zone of more than 19 mm.(12,15) Since the inhibition zones of NIL, PIL, and CIL towards C. albicans and C. glabrata were more than 19 mm, these r e s u l t s i n d i c a t e t h a t C . a l b i c a n s a n d C . glabrata were susceptible to N. rafflesiana pitcher liquid. In our study, PIL and CIL showed better inhibition than NIL against C. glabrata. Types of pitcher liquid C oncentration (%) C. a lbicans C. glabrata C. krusei C. tropicalis + ± - + ± - + ± - + ± - NIL 20 100 0 0 100 0 0 100 0 0 66.67 33.33 0 50 100 0 0 0 100 0 100 0 0 0 1 00 0 80 0 33.33 66.67 0 100 0 0 100 0 0 1 00 0 PIL 20 100 0 0 100 0 0 100 0 0 33.33 66.67 0 50 100 0 0 0 100 0 66.67 33.33 0 0 1 00 0 80 0 100 0 66.67 33.33 0 100 0 0 1 00 0 CIL 20 100 0 0 0 100 0 100 0 0 66.67 33.33 0 50 100 0 0 0 100 0 100 0 0 33.33 66.67 0 80 0 100 0 0 0 10 0 0 100 0 0 0 100 NIL : non-induced liquid; PIL : prey-induced liquid;CIL : chitin-induced liquid; + : turbidity equal to control; ± : turbidity less than control; - : no turbidity Table 2. Macrodilution test NIL, PIL, and CIL against Candida spp. (in % sample) 89 Eilenberg et al.(3) and Raj et al.(4) stated that naphthoquinones, which have antifungal properties, are only detected in red-colored C I L . N a p h t h o q u i n o n e s a r e a p p a r e n t l y chromatic pigments.(5) However, in the present study, we found that NIL and PIL, which are not red in color, also have an antifungal effect. I t i s p o s s i b l e t h a t N I L a n d P I L o f N . rafflesiana contain other substances with antifungal properties, which do not give a red color to pitcher liquid. No inhibition zones were produced in disc diffusion tests of NIL, PIL, and CIL against C. krusei and C. tropicalis, which agrees with the fact that C. kr usei and C. tropicalis are c o m m o n l y m o r e r e s i s t a n t t o a n t i f u n g a l treatment. ( 2 0 ) According to the European Committee on Antimicrobial Susceptibility Testing, the drug dosages for MIC50 and MIC90 of both of fungi, especially C. krusei, are higher than those for the other Candida species.(21) The CIL concentration that inhibited C. albicans was about 3-fold and 6-fold lower than that required for growth inhibition of C. krusei and C. glabrata, respectively.(3) In this study, we used crude liquids that contain many substances, therefore the concentrations of the active compounds were presumably lower than necessary to obtain inhibition zones against C. krusei and C. tropicalis. However, this may have also been caused by the intrinsic resistance of the fungi. In the macrodilution test, we observed the turbidity of the test samples, compared to control. Most of them showed inhibition to tested fungi at 80% pitcher liquid concentration. Decreased growth of C. glabrata was shown at 20% CIL, compared with 50% NIL and PIL (Table 2). Pitcher liquids showed growth inhibition against C. krusei and C. tropicalis at 80%, except for inhibition of NIL and PIL against C. tropicalis, which were at 50%. These results support the idea of fungal activity of pitcher liquids towards C. krusei and C. tropicalis, although no inhibition zones were detected in disc diffusion test. Chitin injection into closed pitchers triggers t h e s y n t h e s i s o f a n t i f u n g a l s a n d c e r t a i n chitinases.(3) As yet, the mechanism underlying the pitcher response to chitin in Nepenthes is not clear and may include both the induced synthesis of new compounds and/or the release of existing compounds from the pitcher gland cells to the trap liquid. The presence of naphthoquinones in the pitcher of Nepenthes is important for chemical defense.(3) In addition, chitinases hydrolyze chitin which is a major component of fungal cell walls.(7,10,22) Chitinase was also identified in the digestion fluid of closed pitchers, not only in chitin-induced pitchers.(9) Therefore it may be assumed that chitinase is also potentially antifungal. The difficulties of this study were how to predict the right time to do chitin induction before opening the pitcher and the phenomenon of non- producing pitchers after several times of taking pitcher liquids. Obtaining pitcher liquid at precisely the right time is important to get as much as liquid we can. Taking liquids was only done once, and no repetition was performed because of the contamination risk. Using special treatments to plants may have to be done to promote the production of pitcher liquid. Exploration about potentially active substances in the pitcher liquid of Nepenthes should be encouraged. Naphthoquinones and chitinase are potential future antifungals. Many species of Nepenthes in Indonesia have not been explored, although most of Nepenthes species originate from Indonesia. CONCLUSION The pitcher liquid of N. rafflesiana has antifungal properties due to the presence of many potentially active substances, especially against C. albicans and C. glabrata. ACKNOWLEDGMENTS We thank Mr. Edwin Dwianto from the “Pitcher of Paradise” nursery and Mr. Anton Univ Med Vol. 33 No.2 90 Yolanda, Makahinda, Aprillia, et al Nepenthes rafflesiana against Candida spp. Halim for their contribution as providers of Nepenthes. We also thank Siska Tri Hapsari, A g u s S i s w a n t o , a n d I d a A f i a h f o r t h e i r contribution in laboratory experimentation. REFERENCES 1. Michallet M, Ito JL. Approaches to the management of invasive fungal infections in hematologic malignancy and hematopoietic cell transplantation. J Clin Oncol 2009;27:3398-409. 2. Akins RA. 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