Agricultural and Marine Sciences, 14:49-53 (2009)
©2009 Sultan Qaboos University

49
__________________________________________
*Corresponding author. E-mail: sergey@squ.edu.om

Bioactive Compounds from Omani 
Sea Cucumbers

Sergey Dobretsov1*, Iman Mohammed Al-Mammari1
and Bassam Soussi2, 3

1Department of Marine Science and Fisheries, College of Agricultural and Marine Sciences, 

Sultan Qaboos University, PO Box 34, Al-Khod 123, Sultanate of Oman 

2
 UNESCO Chair in Marine Biotechnology, Sultan Qaboos University, Sultanate of Oman

3
Department of Clinical Sciences, Sahlgrenska Academy, 

University of Gothenburg, Sweden

ABSTRACT:  Antimicrobial, anti-diatom and anti-larval activities of both water soluble (water extracts) and non-water soluble metabolites 
(methanol: chlorophorm, 1:1 extracts) of the sea cucumbers Holothuria atra and Holothuria edulis from Bander AL-Khiran region, Oman 
were tested in this study. There was no significant effect of the extracts from sea cucumbers on bacterial (3 reference bacteria from seawater 
and pathogens Escherichia coli, Staphylococcus aureus, Klebsiella pneumoniae, Pseudomonas aeruginosa, Streptococcus pneumoniae, 
Streptococcus pyogenes, Staphylococcus epidermidis) and the diatom Chaetoceros sp. growth. Both water extracts and methanol: 
chlorophorm extracts caused significant mortality of Artemia salina nauplia. This study suggests that Omani sea cucumbers might be a 
good source of toxic anti-larval compounds. 

Keywords: Sea cucumber, biofouling, antifouling, secondary metabolites, Sea of Oman.

Introduction
Any natural and man-made substrates in the marine 
environment are quickly colonized by micro- (bacteria, 
diatoms and protozoa) and macroorganisms (algae and 
invertebrates) in a process known as “biofouling” (Railkin, 
2004). The adverse effects of biofouling on ships and boats 
are high frictional resistance, speed reduction, increase of 
corrosion and high fuel consumption (Yebra et al., 2004). 
Biofouling can also clog water intake lines in power plants 
and membranes in desalination plants (Flemming and 
Ridgway, 2009). So far, the most effective methods of 
biofouling control are based on the application of highly 
toxic substances like tributyl tin (TBT), copper or organic 
compounds (e.g. Sea-Nine, Isothiazolone) (Thomas, 2001; 
Yebra et al., 2004). All these antifouling compounds kill 
marine organisms and pollute the marine environment (see 
reviews of Evans, 1999; Yebra et al., 2004). Therefore, novel 
antifouling compounds are urgently needed (Dobretsov et al., 
2006). 

Class Holothuroidea includes approximately 1200 known 
species of sea cucumbers, which are found throughout the 
world’s oceans and in great ranges of latitudes and depths, 
but their greatest abundance occurs in the Indo-Pacific 
region (Conand, 2004). While sea cucumbers have a massive 
exoskeleton, they are less susceptible to predation and 
biofouling compare to other marine organisms. This suggests 
that sea cucumbers might have a chemical defense mechanism 
(Fusetani, 2004). Therefore, chemical compounds from 
sea cucumbers could be used for antifouling defense and 
biomedical applications.

Sea cucumbers contain numerous polar and non-polar 
secondary metabolites that can be used for drug discovery 
(Paul et al., 2008). These compounds are commonly utilized 
for treating weakness, impotence, constipation and frequent 
urination (Hamel and Mercier, 2004). Recently, antitumour, 
antiviral, anticoagulant and antimicrobial compounds have 
been isolated from sea cucumbers (Kelly, 2005). These 

البحر العماني لدي خیار المركبات البیولوجیة النشطة

وبسام سوسي المعمري محمد وإیمان سیرجي دوبریتسوف
من والمستخلصة (١:١ (مستخلص المیثانول:كلوروفورم بنسبة الذائبة وغیر البحر) میاه (مستخلصات الذائبة، المواد األیضیة بعض قدرة إختبار إلى الدراسة ھدفت ھذه الخالصة:
عدم وجود الدراسة بینت وقد والیرقات. والدایاتوم المیكروبات نشاط على منع عمان، في بندر الخیران منطقة من (,Holothuria atra Holothuria edulis) البحر حیوان خیار
Escherichia coli, Staphylococcus aureus, Klebsiella pneumoniae, Pseudomonas میاه البحر و بكتریا (٣ من البكتیریا نمو على المستخلصات من تأثیر أي
كل أدت بینما ،.Chaetoceros sp نوع أوالدایاتوم من (aeruginosa, Streptococcus pneumoniae, Streptococcus puogenes, Staphylococcus epidermidis

للیرقات. على سموم مضادة العماني البحر خیار حیوان من مركبات إحتواء بعضا إمكانیة إلى ھذه الدراسة تشیر فإن وعلیھ .Artemia salina یرقات وفاة إلى المستخلصات

بحر عمان ثانویة، أیضیة مواد الترسبات، مضادات الحیویة، الترسبات البحر، خیار كلمات مفتاحیة:



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Dobretsov, Al-Mammari and Soussi

51

Bioactive compounds from Omani sea cucumbers

organisms are also remarkably rich in vitamins, trace 
elements, and polysaccharides (condroitin sulfate), which 
reduce arthritis pain and inhibit viral activities (Hamel 
and Mercier, 2004). Saponins, such as holothurins, are 
one of the major natural products isolated from sea 
cucumbers (Bhakuni and Rawat, 2005). These water 
soluble glycosides showed haemolytic and cytotoxic 
activity in vivo and in vitro (Kelly, 2005) and can be used 
for treatment of cancer and fungal infections. Antifouling 
compounds have not been isolated from sea cucumbers so 
far (Fusetani, 2004). 

The main aim of this study was to investigate the anti-
microbial, anti-diatom and anti-larval potential of water 
soluble and non-soluble extracts from the sea cucumbers 
Holothuria atra and H. edulis in laboratory experiments 
in vitro.

Material and Methods

Preparation of the Extracts

Several specimens of the sea cucumbers Holothuria atra 
and H. edulis were collected 24.09.07 from Bandar Al-
Khiran area (23o31’13.9”N 58o43’58.68”E) at the depth 4 
m. These sea cucumbers were kept on ice and frozen at 
-20oC in the laboratory. After 2 weeks, the sea cucumbers 
Holothuria atra and H. edulis were defrosted and cut into 
small pieces and separated into 2 approximately equal 
portions. The first portion of the sea cucumbers was 
extracted with distilled sterile water. For this, 500ml of 
water was added to 649g (wet weight) of the black sea 
cucumber H. atra or 663g (wet weight) of the red sea 
cucumber H. edulis and incubated at 40C in the fridge for 2 
days. The second portion the sea cucumbers was extracted 
with 1:1 methanol:chloroform solution. For this, 500 ml of 
1:1 methanol:chloroform solution was added to 660g (wet 
weight) of the sea cucumbers H. atra and H. edulis. These 
samples were extracted for 2 weeks at room temperature 
(23oC). After that, the samples containing water soluble 
metabolites were filtered and preserved in the freezer for 
the bioassays (see below), while the methanol:chloroform 
extracts were filtered and concentrated under vacuum 
using a rotary evaporator. The water bath temperature 
was +40-50°C. After evaporation the remaining sample 
was mixed with new 1:1 methanol:chloroform solution 
and transferred into small labelled containers. Finally, all  
extracts were dried at room temperature. 

Bioassays

Preparation of the bacterial media

Bacteria were growing either in liquid marine broth 
(Difco) or on the surface of nutrient agar (Oxoid). 
Broth were prepared on distilled water according to 
the manufacturer’s protocols. Flasks with media were 
autoclaved at 121oC in order to sterilize them. 

Anti-bacterial assay

Three strains of unidentified marine bacteria (Reference1, 
Reference2, and Reference5) isolated from Bandar Al-
Khiran water column (23o31’13.9”N 58o43’58.68”E) 

and bacterial pathogens Escherichia coli, Staphylococcus 
aureus, Klebsiella pneumoniae, Pseudomonas aeruginosa, 
Streptococcus pneumoniae, Streptococcus pyogenes, 
Staphylococcus epidermidis obtained from SQU Hospital 
were used in this bioassay. 

Before the assay, all strains were sub-cultured in the 
marine broth for 24h at + 30oC. Two hundred μl of the 
bacterial culture was spread on each Petri dish. Water 
extracts of sea cucumbers were pipetted and loaded on 
paper disks (1 mm2 in diameter). There were 3 disks 
containing 50 μl (WB50) and 20 ml (WB20) of the water 
soluble extracts of Holothuria atra, as well as with 20 μl 
(WR20) and 50 μl of H. edulis (WR50). For the controls, 
3 disks containing 20 and 50  μl of sterile water were 
used. Twenty  μl of chloroform: methanol extracts of H. 
atra (B20) and H. edulis (R20) were added to 3 disks. 
All disks were dried at room temperature (23oC) and 
placed into Petri dishes containing bacterial strains under 
investigation. The experiment was run with 3 replicates. 
Petri dishes were kept at room temperature (23oC) for 2 
days. The observed zones of growth inhibition between 
the disc and the bacterial film were measured to the 
nearest 0.2 mm.

Anti-diatom assay 

Prior to the experiment, the diatom Chaetoceros sp. 
(provided by Prof. U. Riebesell, IFM-GEOMAR) was 
cultivated in the F2 media for 2 weeks at room temperature 
(23oC). When a visible film developed in the culture flask, 
diatom suspensions were prepared by brushing the culture 
flask with a sterile paint brush. This algal suspension was 
then used in the following experiments. 

Anti-diatom activity of the sponge extracts was 
tested according to a protocol developed by Dobretsov 
and Qian (2002). Five hundred μl of the water extracts 
of H. edulis or H. atra were added to Petri dishes in 3 
replicates containing 5 ml of diatom suspension (about 
12 x 104 cells ml-1). Methanol: chloroform extracts of H. 
atra and H. edulis were evaporated and re-dissolved in 
dimethylsulfoxide (DMSO). Then, 100 μl extracts were 
added to Petri dishes in 3 replicates containing 5 ml of 
diatom suspension. Five hundred  μl of sea water or 100 
μl of DMSO were used as the controls. The Petri dishes 
were incubated for 4 days with continuous light at 23oC. 
After that, the unattached diatoms and water were poured 
out. Then, 15ml of 90% acetone was added to each Petri 
dish to extract chlorophyll a. The amount of chlorophyll a 
in each sample was measured using a spectrophotometer 
following Lorenzen (1967). 

Anti-larval assay

Prior to the experiment, the brain shrimp Artemia salina 
nauplia were cultivated. For this, we added 2g of the 
A. salina eggs into 1L of sterile seawater. Eggs with 
seawater were kept in a covered container (volume 1L) 
with aeration at room temperature (23oC). After two days, 
the larvae hatched. Photopositive nauplia were collected 
and used in the bioassay. Fifty mμl of A. salina culture 



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Dobretsov, Al-Mammari and Soussi

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Bioactive compounds from Omani sea cucumbers

containing 10-20 larvae was added to each cell of multi-
well dishes containing 500 mμl of sterile sea water. Then, 
500 μl or 50 μl of the water extracts from H. edulis and 
H. atra were added to the cells. Additionally, 50 μl of 
methanol: chloroform extracts of these sea cucumbers 
evaporated and re-dissolved in DMSO was applied to 
other cells. Five hundred μl of seawater or 100 μl of 
DMSO were used as the controls. Each treatment was 
repeated 4 times. After 24h, the amounts of swimming 
and dead larvae were counted using a microscope. 

Statistical Analysis

Chlorophyll a concentrations were log transformed to 
ensure normality and homogeneity of variance (Zar, 
1996). The percent values of larval survival were arcsine-
transformed. To improve the arcsine-transformation, 
those replicates with zero survival were given the value 
of 1/(4n) (n = number of larvae in a single replicate) 
(Zar, 1996). In all cases, the normality assumption was 
verified by the Shapiro-Wilk test (Shapiro and Wilk, 
1965). The differences between the experimental and 
control treatments were determined by one-way ANOVA 
followed by an LSD post-hoc test (Zar, 1996). In all cases, 
the threshold for significance was 5%.

Results

Anti-bacterial Assay

None of the tested extracts (water extracts and chloroform: 
methanol extracts) of H. atra and H. edulis inhibited 
growth of reference bacteria and pathogens. At the same 
time, we observed halos (reduction of bacterial growth) in 

the case of reference bacteria 1 in the presence of water 
extracts from H. edulis (WR20) and from H. atra (WB20 
and WB50).

Anti-diatom Assay

The results of the diatom test showed that there were no 
significant changes (P>0.05, ANOVA) in diatom growth 
after 4d of experiment (Fig.1). None of the extracts caused 
reduction of chlorophyll a concentration.

Anti-larval Assay

All tested extracts changed mortality of Artemia salina 
larvae (Fig. 2). In all cases, water and methanol:
chloroform extracts of H. edulis and H. atra caused 
significantly high (ANOVA, P<0.05) mortality of larvae 
compared to the controls. All larvae died in the presence 
of methanol: chloroform extracts of H. atra and H. edulis. 
Water extracts of both species at 50 μl and 500 μl caused 
moderate mortality of A. salina larvae. 

Discussion and Conclusions
In this study, we have investigated anti-microbial, anti-
diatom and anti-larval activities of both water-soluble 
and non-water soluble metabolites from two species of 
sea cucumber specimens from the Sea of Oman. Our 
findings suggest that polar and non-polar metabolites of 
the sea cucumbers H. atra and H. edulis can kill larvae of 
invertebrates and cannot be  used as non-toxic antifouling 
compounds. 

Our results show that neither chloroform: methanol 
(non-polar) nor water (polar) extracts of the sea cucumber 

Figure 1. The effect of water and chloroform: methanol extracts (1:1) of the sea cucumbers H. atra and H. edulis on growth of 
the diatom Chaetoceros sp. The data are the mean chlorophyll a concentration (mg m-3) ± SE (standard error) measured after 4d 
experiments with 500 μl of the water extracts of H. edulis (500WR) and H.atra (500WB), as well as 100 μl methanol:chloroform 
extracts of H. edulis (100MCR) and H.atra (100MCB) re-dissolved in dimethylsulfoxide (DMSO). Five hundred μl of seawater (SW) 
and 100 μl of DMSO (DMSO) were used as the controls.

Treatments



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Bioactive compounds from Omani sea cucumbers

H. edulis and H. atra affected the growth of tested 
pathogens. This can be explained by the fact that the 
investigated sea cucumbers most likely have never been 
exposed to the human pathogens tested in this study and, 
therefore, may lack such a defense. Furthermore, the 
tested extracts did not demonstrate antimicrobial activity 
against naturally occurring bacterial strains. This suggests 
that H. edulis and H. atra lack antimicrobial defense in the 
present experiment set up. This result contradicts findings 
of Stonik et al. (1979) suggesting that sea cucumbers 
produce different antimicrobial water-soluble glycosides. 
Additionally, tested reference bacteria might not be 
harmful to these sea cucumbers and, therefore, the sea 
cucumbers have not evolved any antimicrobial defense 
against them. 

None of the tested compounds affected the growth of 
the diatom Chaetoceros sp. This result suggests that the sea 
cucumbers H. atra and H. edulis have no or very low anti-
diatom activity.  To our knowledge, anti-diatom activity of 
sea cucumbers has not been reported previously. 

We found that the methanol: chloroform and water 
extracts from H. atra and H. edulis caused high mortality 
and low survival of Artemia salina larvae compared to the 
controls. These results suggest that some toxic secondary 

metabolites are present in the extracts of sea cucumbers. 
These metabolites potentially can be used as cytotoxic 
compounds for cancer treatments. Previously, holothurins 
and asterosaponins that are toxic to the larvae of marine 
invertebrates have been isolated from sea cucumbers 
(Fusetani, 2004). Similarly, several triterpene glycosides 
isolated from Psolus patagonicus (Dendrochirotida: 
Psolidae) showed a high level of mortality against the 
brine shrimp Artemia salina and revealed antifungal 
activity against the fungi Cladosporium fulvum, Fusarium 
oxysporum and Monilia sp. (Muniain et al., 2008). Thus, 
in line with these findings, our data suggest that secondary 
metabolites from sea cucumbers have promising potential 
for biomedicine applications.

Overall, very little information is available about 
the biology, ecology and biotechnological potential of 
Holothuroids along the Arabian Sea coast of Oman (Rashdi 
et al., 2007). The present study is the first investigation of 
anti-microbial, anti-diatom and anti-larval activity of both 
water-soluble and non-water soluble metabolites from two 
species of sea cucumbers from the Sea of Oman coast. 
Further studies of sea cucumber metabolites are needed in 
order to elucidate the structure of possible novel secondary 
metabolites useful in biomedical applications. 

Figure 2. The effect of water and chloroform: methanol extracts (1:1) of the sea cucumbers H. atra and H. edulis on mortality of 
Artemia salina nauplia. The data are the mean percentage of mortality ± SE (standard error) in experiments with 500 μl (500) and 50 
μl (50) of the water extracts of H. edulis (WR) and H. atra (WB), as well as 50 μl (50) of methanol: chloroform extracts (MCB and 
MCR) of sea cucumbers re-dissolved in dimethylsulfoxide (DMSO). Five hundred μl of seawater (SW) or 100 μl of DMSO (DMSO) 
were used as the controls. Different letters above the bars indicate data that are significantly different in the LSD test (P < 0.05, one-
way ANOVA).

Treatments



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Bioactive compounds from Omani sea cucumbers

Acknowledgements
This investigation was supported by the SQU grant (IG/
AGR/FISH/09/03) to SD and the HM Fund for Strategic 
Research (SR/AGR/FOOD/05/01) and University of 
Gothenburg Sahlgrenska Academy to BS. We thank 
Dr. Michel Claereboudt for his help in collecting sea 
cucumbers and Dr. Hussain Al-Massroori for Arabic 
translation of the manuscript. We acknowledge help of 
Prof. Ulf Riebesell who kindly provided diatoms for this 
experiment. 

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Received:  March 2009
Accepted:  May 2009