1. Introduction
Many reports have shown that natural compounds obtained from plants have potential for the human treatment of diseases [1]. From these secondary metabolites, the kaurane-type diterpenes have been associated with several important biological properties, including antiparasitic effect [2], antispasmodic and relaxant actions on the smooth muscle [3,4], among others [5].
Members of this class of diterpenes have also been reported to have cytotoxic effects [6,7], antiproliferative action on tumour cell cultures [8], and significant antibacterial and antifungal activities, including effect against phytopathogenic fungi [9,10].
According to Cotoras et al. [10], a kaurane-type diterpene, namely 3β-hydroxy-kaurenoic acid would produce changes in cell membrane permeability in the fungus Botrytis cinerea with induced efflux of phosphorus, mainly by affecting membrane permeabilization, suggesting by the interaction of the diterpene with some membrane constituents. It is known that a tip-high cytoplasmic calcium gradient is required for hyphal growth in most of fungi. The calcium concentration dependence of growth may relate directly to biochemical functions of calcium in hyphal extension, such as vesicle fusion and enzyme activation during cellular expansion [11]. Because KA was previously reported as an inhibitor of vascular contractility mainly by blocking extracellular Ca2+ influx [4] herein to learn more about the relation between kaurane diterpenes and fungi, a study was undertaken to analyze the effect of kaurenoic acid (Figure 1) on hyphal and growth in a fungus well characterized as Aspergillus nidulans. The effect of verapamil, a well known calcium channel blocker, was compared with KA.
2. Materials and Methods
2.1. Strains and Growth Conditions
Aspergillus nidulans strain FGSC A26 (biA1, veA1) was maintained according Vanzela and Said [12] and grown at 30˚C for seven days before inoculating them on the culture medium (MM) containing nitrate salts and trace elements prepared according to Käfer [13] supplemented
Figure 1. Chemical structure of KA (kaurenoic acid).
with 0.5% glucose and 0.02 µg/mL biotin; 1.8% agar was added and the pH was adjusted to 6.0.
2.2. Isolation of Kaurenoic Acid (KA)
Certified dried leaves of Mikania hirsutissima (1.0 kg) were purchased from “Nutri Comércio de Ervas LTDA”, São Paulo, SP, Brazil. The plant material was pulverized and then exhaustively extracted with dichloromethane (3.5 L) at room temperature, to give 42.0 g of crude extract, which was suspended in 300 mL of methanol-H2O (9:1) and filtered. The soluble fraction was partitioned using n-hexane (300 mL, four times), resulting 6.0 g of hexane-soluble fraction after solvent evaporation under reduced pressure. The n-hexane-soluble fraction was chromatographed over Si gel 60 (0.063 - 0.200 mm) using vaccum liquid chromatography [14] with n-hexane and increasing amounts of ethyl acetate as eluents (250 mL each fraction). The second fraction (1730.0 mg) was washed with cold methanol, to afford pure KA (ent-kaur- 16(17)-en-19-oic acid; 800.0 mg), which was identified by spectroscopic analysis and comparison with literature data [15].
2.3. Preparations of Extracts
KA was dissolved in dimethylsulfoxide (DMSO) to make a 6.6 mM stock solution and added to a final concentration of 0.3 mM. Verapamil (Ca2+ channel blocker) was dissolved in DMSO to make 50 mM stock solution and added to a final concentration of 1mM. All aqueous solutions were sterilized by filtration. EGTA, a Ca2+ chelator, was dissolved in distilled water.
2.4. Analysis of Hyphal Morphology
For all cultures conidia were inoculated (1 × 102 conidia) on dialysis membranes overlying MM in PETRI dishes and incubated at 30˚C ± 1˚C for 30 h (pre-incubation time). Afterwards, all the chemicals were applied directly onto the cultures at 30˚C ± 1˚C for 6, 8 and 24 h. The final concentration of solvents added to the cultures was adjust to less than 1 per cent and had no discernible effects on fungal growth. All treatments were performed at least two times with duplicates each. The hyphae were observed and photographed under an Olympus binocular stereomicroscope with transmitted light.
3. Results
Our results demonstrate that in presence of KA the hyphae lost the polarity and the addition of CaCl2 solution reverts this effect. Aspergillus nidulans showed alteration in the presence of 0.3 mM KA while at the same time 1 mM verapamil didn’t. KA affected hyphal morphology, inducing the lost of polarity after 6 and 8 h (Figures 2(D) and (E)). CaCl2 (500 mM) addition have reverted this morphological alteration (Figure 2(F)). However, abnormal hyphae and branching were decreased after 24 h (not shown).
4. Discussion
Plants have developed an arsenal of chemicals compounds in order to survive attacks by microbial invasion. Until now, many different antifungal compounds have been isolated from several plants. Since these compounds have relatively novel chemical structures and antifungal mechanisms, there has been a growing interest of antifungal compounds [16].
The establishment and maintenance of cell polarity in Aspergillus nidulans depend on the integration of many signaling networks including the calcium signaling and NDR (nuclear Dbf2-related) protein-kinase signaling pathway [17]. Many reports have shown also the importance of subfamily Rho of G proteins in governing the hyphal polarity establishment and maintenance. According to Kafer [18] in A. nidulans, microtubules and the Rho Cdc42 pathways regulate the formation of a stable axis of hyphal polarity. In A. niger RhoA GTPase is crucial for polarity establishment and polarity [19] and in mammalian the maintenance of arterial tone requires Ca2+ channel-dependent RhoA activation [20].
It is known that calcium is a vital intracellular second messenger involved in many other cellular functions as fungal growth, thus its influx and removal from cytoplasm have to be well regulated. In A. nidulans the levels of intracellular Ca2+ were higher in glucose than in pectin presence, demonstrating the Ca2+ importance when the fungi was growing fast [21]. The results presented here suggest that KA (0.3 mM) altered the intracellular calcium homeostasis which by different mechanisms damaged the polarity and morphology of hyphae. The potential of verapamil and KA is apparently not identical. The voltage-dependent Ca2+ channel blocker Verapamil (1 mM) promoted neither hiperbranching or abnormal hyphae nor lost polarity since 6 h until 24 h (Figures 2(G)- (I)).
However, neither the identity of the internal store system nor the regulatory mechanisms controlling Ca2+ re-
Figure 2. Effect of Kaurenoic acid and Verapamil in A. nidulans. Hyphae grown in medium supplemented with glucose 0.5% (w/v) and in absence KA were analyzed after 6 h (A) 8 h (B) and 24 h (C). KA (0.3 mM) was added after 30 h of incubation in (D) and (E) and analized after (6 h) and (8 h) respectively. CaCl2 (500 mM) was added in cultures (E) and analysed after 8 h (F). Verapamil (1 mM) was added and the cultures were analyzed after 6 (G), 8 (H) and 24 (I) hours. The preparations were viewed under stereomicroscope. Magnifications: ×56.
leased from these stores are well known. In the present work our results indicated that KA reduced the hyphal polarity probably for altering the intracellular Ca2+ levels that consequently decreased the fungal growth. This is the first report on the mechanism of action of KA involving calcium levels altering the elongation of fungi hyphae, indicating that KA and its closely related analogues could be used as fungistatic agent.
5. Acknowledgements
J. A. R. received a Doctoral Fellowship from Coordenação de Apoio de Pessoal de Nível Superio (CAPES) and N. S. A. would like to thank Universidade Estadual de Londrina and Fundação Araucária.
NOTES