Biology, Medicine, & Natural Product Chemistry  ISSN 2089-6514 (paper) 
Volume 10, Number 2, October 2021 | Pages: 117-121 | DOI: 10.14421/biomedich.2021.102.117-121 ISSN 2540-9328 (online) 
 

 

 

 

Antibacterial Activity of Mangrove Root Extracts from 

Ngurah Rai Mangrove Forest, Denpasar-Bali 

 
Made Dharmesti Wijaya1*, Anak Agung Gede Indraningrat2 

1Pharmacology and Pharmacy Department; 2Microbiology and Parasitology Department, Faculty of Medicine and Health Sciences, Warmadewa University 

Jl. Terompong No 24 Denpasar 80235, Tel. +62 361 240727, Indonesia. 

 

Corresponding author* 
dharmestiwijaya@gmail.com 

 

 
Manuscript received: 08 October 2021. Revision accepted: 15 October, 2021. Published: 21 October, 2021. 

 

 

Abstract 

 

The increasing rate of antimicrobial resistance in the past decades has motivated the search for novel antibacterial compounds to 

overcome infectious diseases. Among diverse natural sources, mangrove ecosystems offer untapped sources of biological active 

compounds for future antibacterial medicine. This research was aimed to evaluate antibacterial activities of crude extracts of four 

dominant mangrove plants from the Ngurah Rai Mangrove Forest namely Rhizophora mucronata, Avicennia marina, Rhizophora 

apiculata, and Sonneratia alba. Roots of these four plants were extracted using methanol, chloroform, and n-hexane. These crude extracts 

were tested against two Gram positive bacteria (Staphylococcus aureus and Streptococcus mutans) and two Gram negative bacteria 

(Escherichia coli dan Klebsiella pneumoniae) by disc difussion assay. We found that 3 mg/mL of N-hexane crude extracts from R. 

apiculata yielded the highest zone of inhibition of 8.64 mm against S. aureus. While, 3 mg/mL of chloroform crude extract of R. 

apiculata yielded the highest inhibition of 19.83 mm against S. mutans. Unfortunately, no zone of inhibition was observed when crude 

extracts were tested against Gram negative indicator strains. Our results indicate that the root crude extracts of R. apiculata yielded the 

highest zone of inhibition against Gram positive indicator strains compared to root crude extracts of R. mucronata, S. alba, and A. marina. 

Further research is required to determine the antibacterial activities of the mangrove crude extracts against other bacterial indicator strains 

to determine their spectrum of activities. 

 

Keywords: mangrove; roots, antibacterial; Rhizopora apiculata. 

 

 

INTRODUCTION 
 

Antimicrobial substances play a crucial role during 

prevention and medication of infectious diseases, post-

operation infections, infections after chemotherapy or 

infections for diabetic patients, late stage of kidney 

diseases and patients with rheumatoid arthritis (Ventola, 

2015). However, incidence rate of antimicrobial 

resistance has increased dramatically in the past decades 

(Ventola, 2015), which cause difficulty to treat 

infectious diseases, increase cost for medication, and 

lead to higher mortality rate (World Health 

Organization, 2020). World Health Organization 

reported approximately 700,000 mortality every year 

until 2014 due to antimicrobial resistance and it is 

predicted the casualties of antimicrobial resistance 

reached 10 million in 2050 (Departemen Kesehatan 

Republik Indonesia, 2016). 

Immediate actions are required to overcome the 

increasing rate of antimicrobial resistance such as a 

better diagnose and prescription of antibiotics, 

optimization of therapy regimen, and prevention of 

infectious diseases (Ventola, 2015). In addition, the 

search for novel antimicrobial compounds are urgently 

needed since many antibiotics on the market are no 

longer effective to eradicate bacterial infections 

(Ventola, 2015). Among natural resources, mangrove 

ecosystems are the ideal habitat to search for novel 

antimicrobial activities. Mangrove refers to ecosystem 

where seawater and fresh water dissolve, which 

characterize by plants that can tolerate high salinity and 

limited oxygen (Friess, 2016). A number of studies 

showed that mangrove plants are rich of various of 

active compounds such as alkaloid, steroid, terpenoid, 

saponin, tannin, flavonoid dan poliphenol (Dahibhate et 

al., 2018; Gouda et al., 2015; Patra & Mohanta, 2014). 

Furthermore, diversity of these secondary metabolites 

led to broad biological activities such as antibacterial, 

antifungal, antioxidant, antiviral, and anticancer, which 

overall could potentially be developed as the source of 

new drugs (Patra & Thatoi, 2011; Saranraj, 2015).  

A study conducted in Kalimantan showed 

antibacterial activities of root of mangrove plant of 

Rhizophora apiculata (Usman, 2018). However, a 

similar study from mangrove plants found in Bali have 

not been conducted. The Ngurah Rai Mangrove Forest is 

the biggest mangrove ecosystem in Bali which has more 

than 16 different mangrove spesies and the four 

https://doi.org/10.14421/biomedich.2021.102.117-121


 

 

 

118 Biology, Medicine, & Natural Product Chemistry 10 (2), 2021: 117-121 
 

 

dominant species are Rhizophora mucronata, Avicennia 
marina, Rhizophora apiculata and Sonneratia alba 

(Lugina et al., 2017). To date, antibacterial properties of 

these four dominant mangrove species are rather 

unexplored. Therefore, we aimed to screen for 

antibacterial activities of crude extract of the root of 

these four mangrove species by using three different 

solvents: methanol, chloroform and n-hexane against 

Gram negative and positive indicator strains. It is 

expected antibacterial activities of these crude extracts 

will shed light to explore antibacterial active compounds 

from root of mangrove plants. 
 
 

MATERIALS AND METHODS 
 

Materials 
Roots of the four dominant mangrove plants: 

Rhizophora mucronata, Avicennia marina, Rhizophora 
apiculata and Sonneratia alba were collected from the 

Ngurah Rai Mangrove Forest (8o43’40.4886” S, 

115o11’42.80313” E), Bali, Indonesia, on August 2019 

during the low tide. The species determination was 

carried out in Eka Karya Botanical Garden, Bedugul, 

Tabanan, Bali, Indonesia. The solvents (methanol, 

chloroform, and n-hexane) were purchased from Merck, 

Germany. 
 

Methods 

Sample extraction 

For each of mangrove species, 50 g of each dry powder 

of mangrove root were macerated twice using 250 mL of 

individual solvent (methanol, chloroform, or n-hexane) 

at room temperature for 24 hours and filtered using 

Whatmann filter paper No. 1. The extracts were then 

evaporated using rotary evaporator (IKA®, RV8) at 

50°C, 90 rpm and stored in closed and air tight vial at 

4°C until further used. 
 

Antibacterial screening 

From each mangrove root extract, three level of 

concentrations were prepared: 1 mg/mL, 3 mg/mL and 5 

mg/mL. Subsequently, each crude extract was exposed 

against bacterial indicator strains Gram positive 

(Staphylococcus aureus dan Streptococcus mutans) and 
Gram negative (Escherichia coli dan Klebsiella 

pneumoniae) by disc diffusion assay. One hundred 

microlitre of bacterial indicator strains were spotted on 

Luria Bertani agar and spread using a sterile spreader. 

Thirty microlitre of crude extracts were spotted on a 6 

mm paper disc and air dried for 30 minutes. Paper discs 

in triplicates containing crude extracts were placed on 

agar media containing bacterial indicator strains. 

Ampicillin and Streptomycin were used as positive 

controls, while the solvents, methanol, chloroform, and 

n-hexane were used as negative controls. Antibacterial 

activities were calculated based on average zone of 

inhibition (ZOI) that were formed from triplicate disc. 
 
 

RESULTS AND DISCUSSION 
 

The results showed that antibacterial activities were 

displayed by some extracts against Gram positive 

strains, S. aureus and S. Mutans (Table 1), but none 

against Gram negative strains, E. coli dan K. 

pneumoniae. Among the four mangrove species, only R. 
apiculata exhibited antibacterial properties against both 

Gram positive indicator strains. The concentration of 3 

mg/ml N-hexane extract showed the highest ZOI of 8.64 

± 0.13 mm against S. aureus while 3 mg/ml chloroform 

extract yielded the highest ZOI of 19.83 ± 0.63 mm 

against S. mutans. A study by Seepana and co-workers 

(2016) also showed that methanol, ethanol, and hexane 

extract of R. apiculata roots is active against Salmonela 
typhi and S. aureus. Their study also showed that 

methanol, hexane, and ethanol R. apiculata root extracts 
have no activity against E. coli. However, there are 

activities against other Gram-negative bacteria 

Salmonella typhi, shown by methanol, hexane, and 
ethanol extracts of R. apiculata root. Ethanolic extract of 

R. apiculata root also displays activity against K. 
pneumonia (Seepana et al. 2016). 

 
 

     
 

Figure 1. Antimicrobial activity of R. apiculata N-hexane extracts in triplicates against S. aureus. The concentration of 3 mg/ml N-hexane extract showed 
the highest ZOI (8.64 ± 0.13 mm). 

5 mg/ml 

5 mg/ml 

5 mg/ml 

3 mg/ml 

3 mg/ml 

1 mg/ml 

1 mg/ml 

3 mg/ml 

1 mg/ml 



 

 

 

 Wijaya & Indraningrat – Antibacterial Activity of Mangrove Root  119 
 

 

     
 
Figure 2. Antimicrobial activity of R. apiculata chloroform extracts in triplicates against S. mutans. The concentration of 3 mg/ml chloroform extract 

yielded the highest ZOI of 19.83 ± 0.63 mm against S. mutans. 

 

 

 

Table 1. Antibacterial activities of mangrove root extracts. 
 

Bacterial Strains Samples Solvents Concentration ZOI (mm) 

Staphylococcus aureus Rhizopora apiculata Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml 8.05 ± 0.64 

 3 mg/ml 8.64 ± 0.13 

 5 mg/ml 7.84 ± 0.61 

Rhizopora mucronata Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Sonneratia alba Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Avicennia marina Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Positive controls Ampicillin 10 μg 19.20 ± 0.98 

Streptomycin 10 μg 15.54 ± 0.22 

Negative controls Methanol - - 

Chloroform - - 

N-hexane - - 

3 mg/ml 

3 mg/ml 

3 mg/ml 

1 mg/ml 

1 mg/ml 

5 mg/ml 

1 mg/ml 

5 mg/ml 

5 mg/ml 



 

 

 

120 Biology, Medicine, & Natural Product Chemistry 10 (2), 2021: 117-121 
 

 

Bacterial Strains Samples Solvents Concentration ZOI (mm) 

Streptococcus mutans Rhizopora apiculata Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml 13.98 ± 1.49 

 3 mg/ml 19.83 ± 0.63 

 5 mg/ml 15.92 ± 0.68 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Rhizopora mucronata Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml 7.32 ± 0.43 

Sonneratia alba Methanol 1 mg/ml - 

 3 mg/ml - 

   5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml 7.39 ± 0.21 

 5 mg/ml 7.96 ± 0.25 

Avicennia marina Methanol 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Chloroform 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

N-hexane 1 mg/ml - 

 3 mg/ml - 

 5 mg/ml - 

Positive controls Ampicillin 10 μg 31.72 ± 3.03 

Streptomycin 10 μg 20.76 ± 1.49 

Negative controls Methanol - - 

Chloroform - - 

N-hexane - - 

 
 

 

In addition, other Rhizopora species namely R. 
mucronata also displayed antibacterial activity in which 

5 mg/ml n-hexane extract showed ZOI of 7.32 ± 0.43 

mm against S. mutans. Rhizopora species including R. 

apiculata and R. mucronata contain many medically 

important secondary metabolites such as essential oils, 

glycosides, alkaloids, phenolic compounds, and tannins 

(Habib et al., 2018). Tannins is known to have 

antimicrobial properties against both Gram-positive and 

Gram-negative bacteria. This compound passes the 

bacterial cell wall and intrudes the cell metabolism, 

resulted in bacterial death (Kaczmarek, 2020).  

Furthermore, N-hexane extract of S. alba root 

showed activity against S. mutans in which the 
concentration of 3 mg/ml and 5 mg/ml yielded ZOI of 

7.39 ± 0.21 and 7.96 ± 0.25 mm respectively. Although 

study on S. alba root extract is still limited, there are a 

number of studies focusing on leaves and bark of this 

plant. A study by Saad and co-workers (2012) showed 

that methanolic extract of S. alba leaves antibacterial 
activities were observed against Gram-negative bacteria 

E. coli (17,5 mm), as well as Gram-positive bacteria 

namely S. aureus (12.5 mm) and Bacillus cereus (12.5 
mm) (Saad et al., 2012). 

Our result indicate that overall, crude extract of 

mangrove root displayed much lower antibacterial 

activities compared to positive control ampicillin (10 

μg) dan streptomycin (10 μg). However, zone of 

inhibition R. apiculata crude extracts using n-hexane (3 

mg/L) were comparable to that of streptomycin. 

Therefore, R. apiculata could potentially contain novel 
antibacterial compounds. However, composition of 

active compounds in the crude extracts need to be 

confirmed. It is expected that once this active compound 



 

 

 

 Wijaya & Indraningrat – Antibacterial Activity of Mangrove Root  121 
 

 

has been identified, it can be isolated and further 

developed as new antibiotics drugs. 

 

 

CONCLUSION 
 

In conclusion, crude extracts of root R. apiculata 
displayed the highest antibacterial activities compared to 

other crude extracts of different mangrove plants. We 

found that extraction using n-hexane yielded the highest 

inhibition zones compared to methanol and chloroform. 

Further research is required to elucidate the active 

compounds in n-hexane. 

 

Acknowledgements: We would like to acknowledged 

financial support from UP2M of Faculty of Medicines 

and Health Sciences under grant no. 

417/Unwar/FKIK/UP2M/KP-02/VII/2019. 

 

Conflicts of Interest: The authors declare that there are 

no conflicts of interest. 

 

 

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