12 (Yaya Rukayadi) Catatan penelitian (94-96).pmd


SHORT COMMUNICATION

The Effects of Xanthorrhizol on the Morphology of Candida Cells

Examined by Scanning Electron Microscopy

YAYA  RUKAYADI∗  AND  JAE-KWAN  HWANG

Department of Biotechnology, Yonsei University, 134-Sinchon-dong, Seodaemun-gu, Seoul 120-749, Korea

The effects of xanthorrhizol, a natural anticandidal agent isolated from the rhizome of temulawak or java

turmeric (Curcuma xanthorrhiza Roxb.) on the morphology of four human pathogenic Candida species, i.e., C. albicans,

C. glabrata, C. guilliermondii, and C. parapsilosis was examined by scanning electron microscopy (SEM). The SEM

analysis showed that, unlike control cells representing normal oval to spherical with smooth surface, treatment

of Candida strains with xanthorrhizol at 1 x MICs (minimum inhibitory concentration) significantly affected the

external morphology, exhibiting deformation, and protrusions on the cell surface. The potent anticandidal activity of

xanthorrhizol may support the use of medicinal plants for the treatment of candidal infections.

Key words: anticandidal, Candida sp., scanning electron microscopy, xanthorrhizol

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∗
Corresponding author, Phone: +82-2-2123-4097,

Fax: +82-2-362-7265, E-mail: yr32@yahoo.com

The incidence of invasive fungal infections, particularly

those caused by Candida sp., has increased over the past

few decades (Hsueh et al. 2005). Recently, strains of Candida

sp., such as C. albicans, C. glabrata, C. guilliermondii,

and C. parapsilosis are showing increased resistance to

traditional antifungal agents (Hawser and Dauglas 1995;

Nguyen et al. 1996; Barchiesi et al. 1999; Dauglas 2003).

This demonstrates the great importance of identifying novel

antifungal agents (Ficker et al. 2003). Recent years have

seen a growing interest in the use of natural antifungal agents

isolated from the medicinal plants.

Xanthorrhizol, a novel bioactive compound isolated from

the rhizome of an indigenous Indonesian medicinal plant,

temulawak or java turmeric (Curcuma xanthorrhiza Roxb.)

has been previously reported to possess an antibacterial

activity against several oral pathogens (Hwang et al. 2000a,

2000b) and has the ability to prevent and remove

Streptococcus mutans biofilm formation (Rukayadi and

Hwang 2006a, 2006b, 2006c). Xanthorrhizol also has

anticandidal activity (Rukayadi et al. 2006), anti-Malassezia

activity (Rukayadi and Hwang 2007a) and antimycotic activity

against opportunistic filamentous fungi (Rukayadi and

Hwang 2007b). This short communication reports the effect

of xanthorrhizol on the morphology of Candida cells

examined using the scanning electron microscopy (SEM).

The Candida strains (C. albicans ATCC 10231, C.

glabrata ATCC 50044, C. guillerimondii ATCC 9058, and C.

parapsilosis ATCC 22019), used in this study, were obtained

from the American Type Culture Collection (Rockville, MD,

USA). The strains were cultured on Sabouraud dextrose broth

(SDB) or Sabouraud dextrose agar (SDA) (Difco, Becton

Dickinson and Company, USA) for 48 h at 35 oC. The

standardized inoculum (a McFarland standard) for each

isolate used was 5 x 106 cfu ml-1 (NCCLS 2002).

Xanthorrhizol (Fig 1) (Hwang et al. 2000a) was isolated

from the ethyl acetate fraction of the methanol extract from

Curcuma xanthorrhiza according to the method of Hwang

et al. (2000a). Briefly, the rhizomes of C. xanthorrhiza (100 g)

were ground and extracted with 75% MeOH (v/v; 400 ml),

and further fractioned consecutively with ethyl acetate

(4.8 g), n-butanol (1.7 g), and water (1.1 g). Xanthorrhizol

was isolated from the ethyl acetate fraction using silica-gel-

column chromatography (Merk; 70-230 mesh; 5 x 43 cm; n-

hexane/ethyl acetate, 10:1) yielding 0.2 g. Xanthorrhizol was

dissolved in 10% (vol/vol) dimethylsulfoxide (DMSO) to

obtain 1 mg ml-1 stock solutions. DMSO at 10% (vol/vol)

was found not to kill Candida.

Samples for scanning electron microscopy were provided

as follows: 10 ml of cultures of C. albicans, C. glabrata, C.

guilliermondii, and C. parapsilosis were exposed to 1 x

MICs of xanthorrhizol (15, 10, 8, and 25 µg ml-1, respectively)

(Rukayadi et al. 2006). After 1 hour of incubation at 35 oC,

1  ml of each culture, and a negative control of a

corresponding culture were aliquoted and centrifuged at

3,900 x g for 10 min. Cell pellets were resuspended in 10 ml of

sterile water and fixed overnight in 4% (vol/vol)

glutaraldehyde. The samples were washed twice with 2-ml

portions of sterile water and centrifuged at 3,900 x g for 10

 1 4

4
OH

3

2

1

7

1 5

6

5

8

9

1 0

1 2

1 1

1 3

Fig 1 Structure of xanthorrhizol (Hwang et al. 2000a).

MICROBIOLOGY INDONESIA, August 2007, p 98-100                                                Volume 1, Number 2

ISSN 1978-3477



min. The final pellets were then resuspended in sterile water.

A drop of each suspension was transferred onto glass cover

slips and fixed onto aluminium SEM stubs (Agar Science

Ltd, Standstead, UK). The drop was spread thinly on the

slip and dried in the air for 2 hour at room temperature. Graded

concentrations of ethanol (70, 80, 90, and 95%, vol/vol), were

applied, 2-5 min each, to ensure complete dehydration of

specimens. The specimens were coated with gold in a low-

pressure argon atmosphere employing a model E5000 Polaron

Sputter Coating Unit (Polaron Equipment Ltd, New Haven,

West Sussex, UK). A JEOL JSM-840 scanning electron

microscope (Jeol Technics Ltd, Tokyo, Japan) was used to

evaluate samples, operating at accelerating voltages of 20-

25 kV (Helal et al. 2006).

SEM analysis showed that, unlike control cells

(antifungal-agent free) showing normal oval to spherical

shapes with smooth surfaces, treatment of Candida species

with MIC of xanthorrhizol affected the external morphology

of these yeasts (Fig 2). Control cells displayed well-formed

cells with smooth unadulterated surface (Fig 2a, c, e, g). In

contrast, cells incubated in the presence of xanthorrhizol

demonstrated a greater tendency to clump compared with

the control cultures (e.g., C. albicans - Fig 2b). Xanthorrhizol-

treated C. glabrata cells showed minor abnormalities without

a smooth or a slightly awkward surface (Fig 2d).

Xanthorrhizol-treated Candida cells exhibited deformation

and protrusions on the cell surface, which was more clearly

demonstrated with C. guilliermondii and C. parapsilosis

(Fig 2f, h).

Electron micrographs revealed the existence of a

recognizable affected external morphology of Candida cells

caused by xanthorrhizol. Visible deformation, protrusion, or

clumping was noted for each species at concentration MICs

for 1 h treatment. In general, Candida exposed to

xanthorrhizol at concentrations 1 x MICs exhibited

substantial ultrastructural abnormalities such as shape

deformation, protrusion, rugged cells surface, and clumping.

Although, we were not able to identify the underlying

molecular changes caused by the compounds by scanning

electron microscope after 1 h  treatment, we were able to

show that the observable cell wall changes were generally

obtained following exposure of the isolates to concentrations

of xanthorrhizol equal to 1 x MICs. Analysis of electron

micrograph at the appropriate exposure time and higher

concentrations (2 x MICs or 4 x MICs) may result in more

detailed analyses of the activities and effects of antifungal

agents (Klepser et al. 1998). Further studies have been

conducted examining the effect of xanthorrhizol on the

morphology Candida cells at 2 x MICs and  4 x MICs for 2

and 4 h of incubation.

In summary, the potent anticandidal action of

xanthorrhizol against strains of four human pathogenic

Candida species was demonstrated by scanning electron

microscopy analysis. The results showed the usefulness of

xanthorrhizol, a promising new antifungal agent for the topical

treatment of candidiasis.

Fig 2  SEM of Candida albicans (a and b), C. glabrata (c and d), C. guilliermondii (e and f), and C. parapsilosis (g and h) after treating by

xanthorrhizol at 1 x MIC for 1 h of incubation.

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100     Short  Communication                                                                                Microbiol Indones