145-148 (shirly kumala)..pmd


Infectious disease is one of the main health problems in

the developing countries including Indonesia. According

to Household Health Survey 1997, the main cause of death

are as follows: 28.1% are caused by infectious and parasitic

diseases, 18.9% are due to vascular diseases, and 15.7% are

caused by respiratory diseases (Depkes 1997). This evidence

demonstrates that the prevalence of infectious disease in

Indonesia is still high, and to solve this problem new anti-

infection drugs that are potent and affordable must be

available especially for  those in  the low to middle economic

society classes. This encourages research  to find new natural

low cost medicinal sources with potent anti-microbial activity.

The microbes existing in plants are called endophytic

microbes. These microbes spent part or their entire lifetime

in the living tissue of the host plant without causing any

harm (Petrini et al. 1992). Microbes such as fungi, yeast, and

bacteria associated with the host plant assist in the

metabolism of the host plant, and produce secondary

metabolites with potent medicinal activity such as anti-tumor,

anti-bacterial, and anti-fungal compounds as decomposing

enzymes, and also plant growth hormones (Petrini et al. 1992;

Strobel et al. 1996;  Strobel  2002).

Mengkudu is a tropical plant that has been used to treat

a variety of diseases since thousands of years ago. Studies

showed that parts of the mengkudu plant (Morinda citrifolia)

such as the fruit, leaf, root, and bark apparently have a

therapeutic effect. Some of these effects are the lowering of

high blood pressure. Improving body resistance, pain relief,

anti-tumor and anti-cancer, anti-inflammatory and anti-

bacterial activity.

MICROBIOLOGY INDONESIA, December 2007, p 145-148                              Volume 1, Number 3

ISSN 1978-3477

SHORT COMMUNICATION

Isolation and Screening of Endophytic Microbes from Morinda

citrifolia and their Ability to Produce  Anti-Microbial Substances

SHIRLY  KUMALA*  AND ENDRO BUDI  SISWANTO

Faculty of Pharmacy, Universitas Pancasila, Jalan Srengseng Sawah, Jagakarsa, Jakarta 12460, Indonesia

Assaying for, and isolation and screening of endophytic microbes from the Morinda citrifolia plant and their ability to

produce anti-microbial substances was carried out. Endophytic microbes are microorganisms that live asymptomatically within

the living tissue of host plants. Microorganisms such as bacteria, fungi, and yeast can be associated with the host and produce

secondary metabolites. These secondary metabolites may be enzymes and other bioactive substances with medicinal activity

such as anti-arthritic, anti-cancer, and anti-microbial compounds. The aims of these experiments was to investigate the ability

of endophytic microbes isolated from M. citrifolia to produce secondary metabolites which can act as anti-microbial agents. A

direct seed inoculating technique was used by planting the plant sample onto the surface of Nutrient Agar and Potato-Dextrose

Agar. Assessment of their ability to produce anti-microbial substances was conducted by growing the endophyte isolates in

Muller Hinton Broth for bacterial isolates, and in Potato-Dextrose Yeast Broth for fungal isolates. The agar diffusion method

using paper disk was applied to assay the anti-microbial activity of each substance. The results of the endophyte isolation in

these experiments gave five bacterial isolates and eleven fungal isolates. All of the bacterial isolates showed a broad anti-

microbial spectrum while ten of the fungal isolate demonstrated broad anti-microbial activity and four out of the ten fungal

isolates had activity towards Candida albicans.

Key words: anti-microbial, endophytic microbe, Morinda citrifolia (mengkudu), secondary metabolite

_____________________________________________

________________________

*
Corresponding author, Phone: +62-21-6902104,

Fax: +62-21-7864727, E-mail: fskumala@yahoo.com

Up to now there have been few studies, which focus  on

the medicinal activity of endophytic microbes as anti-

microbial substances. The objective of this study is to

identify the endophytic microbes in the mengkudu plant

and their capacity to produce secondary metabolites that

have anti-microbial effect.

The twig of the mengkudu plant which was used in this

study had been identified at the Herbarium Bogoriense,

Balitbang Botani, Puslitbang Biologi LIPI, Bogor (The Bogor

Herbarium, Botanical Research and Development Agency).

The test microbes used in this assay were Staphylococcus

aureus, Escherichia coli, Bacillus subtilis, Salmonella

typhimurium, and Candida albicans. These microorganisms

were derivates of  ATCC and were obtained  from laboratory

of microbiology, medical faculty, University of Indonesia.

Twigs from the second and the third branches of the

mengkudu plant (diameter of 0.3-0.6 cm) were selected for

use in this study. Leaves were removed and the twigs were

cut into lengths of 2 cm and washed with under running

water (tap water) for about 10 min. The sections of the twigs

were sterilized by soaking in 75% v/v ethanol for 1 min in the

Laminar Air Flow Cabinet (Gelman Sciences, Australia), and

then in a 5.3% w/v solution of NaOCl for 5 min. Following

the sterilization step, samples were air-dried on sterile tissue

paper for 1 min. After drying, they were placed on a sterile

glass slide and cut longitudinally with a scalpel into two

equal parts. One part was placed on an nutrient agar (NA)

medium that had been treated with Nystatin (0.01% w/v) as

an antifungal agent and the other part was on Potato Dextrose

Agar that had been treated with Chloramphenicol (0.005%

w/v) as antibiotic. Each sample was positioned longitudinally

such that the surface of the cut was placed in contact with

the medium. Samples were then placed in an incubator for

5-7 days at 27-29 °C (Bacon 1988).



146   Short Communication                                                                                                 Microbiol Indones

Second branching

First branching

Second branching

Second branching

Second branching

NATgPc 5A

NATgPc 3B

NATgPc 2A

NATgPc 1B

NATgPc 1C

Cocco bacil

Cocco bacil

Cocco bacil

Cocco bacil

Cocco bacil

Gram negative

Gram positive

Gram positive

Gram positive

Gram negative

Table  1  Data of endophytic bacteria

Part of plant               Isolate code          Shape           Gram stain

First branching

First branching

Second brancing

Second brancing

First branching

Second brancing

First branching

Second brancing

First branching

First branching

Second brancing

PDAPgPc 5A1-1

PDAPgPc 4A1-A2

PDATgPc 3A2

PDATgPc 3A

PDAPgPc 1C

PDATgPc 5A

PDAPgPc 1D

PDAPgPc 4-C2

PDATgPc 2

PDAPgPc 4A1

PDATgPc 5A1-2

white undulate, reverse white, aerial concentric

green to black velvety, reverse black

brown to withish,, reverse white, aerial concentric

white hyphae, reverse white, with aerial concentric

black at center, reverse white milk

white undulate, reverse white, aerial concentric white milk

grey velvety, edge of colony entire, reverse white

black velvety, reverse grey

yellow, reverse white milk, aerial concentric

white, reverse white

white edge of colony undulate, reverse white

Table 2  Macroscopic morphology of endophytic fungi

Part of plant                                            Isolate code                                    Morphology and color of colony on PDA medium at 27-29 °C

Bacterial colony identification was through observation

and was carried out based on the following criteria: color,

surface, the margin of the colony as well as Gram staining.

Fungal colony identification was through observation based

on the color of colonies and color contrast. Sample that

matched with this observation criteria were considered to be

the same isolate while those that did not match with the

criteria were considered  as a different isolate. Furthermore,

individual colonies with different morphology were separated

and considered  as individual  isolates. Observation of the

morphology was again conducted after 5-7 days of incubation

and each isolate was transferred into two different types of

culture media (stock and working culture). Each stock culture

was kept in paraffin lig, while each working culture was kept

in slant agar.

The 24 h bacterial sample in the NA slant was suspended

by adding 5 ml of muller hinton broth (MHB). The opacity of

bacteria is made equal to the opacity of 0.5 McFarland

standard. Then, 1 ml of bacterial suspension was put into a

50 ml Erlenmeyer flask containing 9 ml of MHB medium. The

fermentation process was done using a shaking incubator

for 48 h with a speed of 120 rpm. The secondary metabolites,

as product of fermentation, were centrifuged with a speed of

3 000 rpm for 20 min. The supernatant was used for anti-

microbial assay (Rosana  et al. 2001).

A section of the fungal isolate that had sporulated (aged

7-10 days) was taken out using a sharp forceps, (dimension

of 1 x 1 cm) and was placed  into 10 ml liquid fermentation

medium of Potato Dextrose Yeast Extract Broth in a 50 ml

Erlenmeyer flask. The fermentation process was conducted

by using a shaker for 7 days with a speed of 170 rpm. The

product of  fermentation was centrifuged with a speed of

3 000 rpm for 20 min, and the supernatant was used for anti-

microbial assay (Rosana et al. 2001).

The assay was performed using a paper disk for the fungi

and using stainless cylindrical tubes for the bacteria (Kumala

et al. 2006). The Gram positive test bacterial were S. aureus

and B. subtilis, the Gram negative  test bacterial were E. coli

and S. typhimurium, and the yeast test microbe was C.

albicans. Nutrient Agar was used as the medium for S.

aureus, B. subtilis, E. coli, and S. typhimurium bacterial test

and PDA was used as the medium for C. albicans yeast test

microbe. Disks were dipped into the suspension until it was

saturated, and then placed on the agar medium that had been

inoculated with test microbes. The test microbe was adjusted

with 0.5 McFarland standard. For the bacteria, 100 ml of

suspension of the product of fermentation was put into the

stainless cylinder that had been placed on the agar medium

that had been inoculated with the test microbe. Then, it was

incubated at a temperature of 37 °C and assayed for two

days. Assay was by observation which was carried out to

determine a clear zone around the disk and stainless

cylindrical tubes.

The endophytic bacteria isolated from the piece of twig

were grown in NA medium that had been added with Nystatin

as an anti-fungal agent. Three Gram positive endophytic

bacteria and two Gram negative endophytic bacteria were

obtained (Table 1).

Endophytic fungi isolated from the piece of twig were

grown in PDA medium that had been added with

chloramphenicol as an anti-bacterial agent to grow the fungi.

Eleven endophytic fungi were obtained (Table 2).

In this study, we screen endophytic microbes that can

produce secondary metabolite that has potential anti-

microbial substances. The in vitro testing showed that the

secondary metabolite of the endophytic microbes produced

a zone of inhibition of the test microbes.

Of the 5 bacteria, all of them (100%) had activity against

the test bacteria (S. aureus, E. coli, S. typhimurium, B.

subtilis) and on the yeast (C. albicans). The diameter of the

zone of inhibition and the illustration of the zone of inhibition

can be seen in Table 3 and Fig 1. Table 4 shows the inhibition

zone of the endophytic fungi.

This study is a preliminary study to find a source of anti-

microbial compounds from endophytic microbes. The

isolates obtained were fungal and bacterial endophytic

microbes.

From the isolations carried out, we obtained five

endophytic bacterial isolates and eleven endophytic fungal

isolates. Of the five endophytic bacterial isolates obtained,

all of them had the same cell shape, that is rod-shaped, in

which 3 isolates were Gram positive and 2 isolates were Gram

negative. Identification of endophytic bacterial and fungal

isolates from the mengkudu plant was only carried out based

on observed morphology and grouping by Gram staining.

These results showed that endophytic microbes living in

the mengkudu plant contained more Gram positive than Gram

negative. The products of bacterial fermentation were tested

for anti-microbial activity. The test microbes used were



Volume 1, 2007                                       Microbiol Indones   147

Table 3  Data for anti-microbial assay of endophytic bacteria using a 1.0 cm cylindrical tube

                                                                                                       Diameter of zone inhibition (cm)

                                   Staphylococcus aureus          Bacillus subtilis        Escherichia coli        Salmonella typhimurium         Candida albicans
Isolate code

NATgPc 5A

NAPgPc 3B

NATgPc 2A

NATgPc 1B

NATgPc 1C

++

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+

+: < 1.2, ++: > 1.2.

Fig 1  Anti-microbial assay of endophytic fungi towards

Staphylococcus aureus. èNo. 9 shows inhibition zone.

PDAPg Pc 5A1-1

PDAPg Pc 4-A2

PDATg Pc 3A2

PDATg Pc 3A

PDAPg Pc 1C

PDATg Pc 5A

PDAPg Pc 1D

PDAPg Pc 4-C2

PDATg Pc 2

PDA Pg Pc 4A1

PDATg Pc 5A1-2

+

+

++

+

-

+

+

++

++++

+

+

+

+

+

+

-

+

+

+

++

+

+

+

+

++

+

-

+

+

+

+++

+

+

+

+

+

+

-

++

+

++

+++

+

+

-

-

-

-

-

-

-

++

++

+++

+

Table 4  Data for anti-microbial assay of endophytic fungi using 0.6 cm paper disk

                                                                                                       Diameter of zone inhibition (cm)

                                   Staphylococcus aureus          Bacillus subtilis        Escherichia coli        Salmonella typhimurium         Candida albicans
Isolate code

-: no inhibition, +: < 0.80, ++: > 0.80 - < 1.00, +++: > 1.00 - < 1.20, ++++: > 1.20.

S. aureus, B. subtilis, E. coli, and one yeast C. albicans.

The results of the anti-microbial activity test showed that

the five endophytic bacterial isolates of the mengkudu plant

produced anti-microbial substances. This was demonstrated

by the formation of a clear zone surrounding the  paper disk,

indicating that there was a zone of inhibition of growth of

the test microbe. Of the five test microbes, S. aureus was the

most sensitive to the anti-microbial substances produced

by the endophytic bacteria. Shaking was used in this assay

as Kumala et al. (2005) stated that isolated fungal or bacterial

endophytes produced more secondary metabolites than if

still fermentation methods were used.

The product of fungal fermentation in the PDY medium

showed that ten endophytic fungal isolates from the

mengkudu  produced anti-microbial substances. This was

demonstrated by the formation of a clear zone surrounding

the cylindrical tube, indicating that there was a zone of

inhibition of the growth of the test microbe.

The four types of test bacteria used, which were S.

aureus, B. subtilis, E. coli, S. typhimurium, and the test

yeast used, which was C. albicans, were sensitive to the

anti-microbial compounds produced by the endophytic fungi.

Of the five test microbes, S. aureus was the most sensitive

to the anti-microbial substance produced by the endophytic

fungi. There was one endophytic fungal isolate that was not

capable of producing anti-microbial substances. This showed

that no zone inhibition of growth of the test microbes.

Using cylindrical tubes not paper disks, the bacteria

isolate needs to obtain a clear zone. For the smalles quantities

of anti-microbial agent it is easier to assay using cylindrical

tubes rather than paper disks (Kumala et al. 2006).

The result of this anti-microbial assay showed that the

anti-microbial substances produced by the endophytic

bacteria and fungi had a broad spectrum because it was

capable of inhibiting the growth of  Gram positive bacteria,

Gram negative bacteria, and a yeast. Furthermore, the number

of isolated fungi which were obtained in this study were

more than for the bacteria endophytes. These results agree

with a previous investigation (Kumala et al. 2006).

ACKNOWLEDGEMENTS

We would like to thank the Microbiology Laboratory of

the Medical Faculty of the Universitas Indonesia for the test

microbes used in this study.

REFERENCES

Bacon CW. 1988. Procedure for isolating the endophytes from fall

rescue and screening isolates for ergot alkaloid. Appl Environ

Microbiol 54:2615-2618.

[Depkes] Departemen kesehatan. 1997. Survei Kesehatan Rumah

Tangga. Jakarta: Badan Penelitian dan Pengembangan Kesehatan,

Depkes.

Kumala S, Mangunwardoyo W, Budiarti P. 2005. Fermentasi diam

dan goyang isolat kapang endofit dari Brucea javanica L. Merr

dan uji aktivitas anti-mikroba. J Ilmu Kefarmasian Indones 3:12-

1 5 .



148   KUMALA ET AL.                                                                                                Microbiol Indones

Kumala S, Syarmalina, Handayani AR. 2006. Isolasi mikroba endofit

ranting tanaman Johar (Cassia siamea Lamk) serta uji aktivitas

anti-mikroba substansi bioaktif mikroba endofit. J Ilmu

Kefarmasian Indonesia 4:15-24.

Petrini O, Sieber TN, Toti L, Viret O. 1992. Ecology, metabolite

production, and substrate utilization in endophytic fungi. Nat

Toxin 1:185-196.

Rosana Y, Ibrahim F, Susilo J, Sukara E. 2001. Isolasi dan seleksi

jamur endofit dari tanaman belimbing wuluh (Averhoa blith Linn)

yang menghasilkan bahan anti-mikotik. J Mikol Ked Indones

2:134-139.

Strobel GA. 2002. Microbial gifts from rain forest: Symposium

contribution. Can J Plant Pathol 24:14-20.

Strobel GA, Hess WM, Ford E, Sidhu RS, Yang X. 1996. Taxol from

fungal endophytic and the issue of biodiversity. J Indust Microbiol

17:417-423.