1. Biotic Communities Associated with Mangroves
1.1. Habitat for Local Communities
Mangrove ecosystems are habitats for local fauna and flora, providing breeding places, shelter, nesting, and nursing areas
[1] (
Table 1 and
Table 2). Mangrove canopies are home to several wild animals, such as monkeys, monitor lizards, snakes, and otters
[2]. The canopy also provides shade and shelter to aquatic-based animals, including amphibians and larger reptiles such as crocodiles
[3] and dugongs
[2]. Several birds inhabit mangroves, notably eagles, kingfishers, herons, plovers, terns, cormorants, egrets, and ibises
[4]. On tree trunks, the residing flora includes orchids, ferns, lilies, and vines
[5], which are home to invertebrates such as spiders and various insects
[6]. Other than that, mangrove roots are swarmed by arthropods (crabs, lobsters, and shrimp)
[7]; Molluscs (barnacles, oysters, mussels, and snails)
[8]; sponges
[9]; worms
[10]; jellyfish
[2]; and fish such as sea trout, snappers, jacks, tarpon, sea bass, red drums, and snook
[11]. Moreover, mangroves host diverse epibiont macroalgal communities on their prop roots, trunks, and mud surfaces
[12]. Mangrove habitats provide shallow water and, in many cases, high turbidity and fine sediment suitable for burrowing animals
[13]. These factors act to protect animals from their predators by reducing their visibility and lowering their encounter rate with potential predators
[14]. Mangrove plants, along with kelps, seagrasses, oysters, and corals, are key foundation species of coastal ecosystems
[15]. Foundation species are crucial for maintaining the structure and resilience of an ecosystem
[16].
Table 1. List of fauna associated with mangroves.
Group |
Common Name |
Genus/Species |
References |
Sponges |
Common Mangrove Sponge |
Tedania sp. Mycale sp. Dysidea sp. Haliclona sp. |
[17] |
Worms |
Segmented worms |
Sabellastarte sp. |
[18] |
Insects |
Ant |
Polyrachis bicolor sp. |
[19] |
Weevils |
Rhynchites sp. |
[20] |
Bettles |
Monolepta sp. |
[21] |
Crustaceans |
Crabs |
Ilyogynis microcheirum Portunus pelagicus Uca sp. Hippidea sp. |
[22][23] |
Prawns |
Penaeus monodon Exopalaemon styliferus Metapenaeus affinis Parapenaeopsis sculptilis |
[24][25] |
Barnacles |
Balanus sp. Euraphia sp. Tetraclita sp. |
[26][27] |
Mollusks |
Oyster |
Crassostrea sp. |
[28] |
Clam |
Tridacna derasa Tridacna maxima nodontia edentula |
[29][30][31] |
Sea slug/sea hares |
Dolobella sp. |
[32] |
Venus clam |
Bursa sp. Paphia amabilis Venus clam Paphia Haliotis asinina Tectus pyramis Echininus cumingii Terebralia sulcata Rhinoclavis sinensis Rhinoclavis vertegus Ficus gracilis Plicacularia pullus Fasciolaria trapezium Oliva reticulata Mitra mitra Trisodos tortuosa Anadara maculosa Chicoreus brunneus |
[33][34][35][36][37] |
Echinoderms |
Sea urchin |
Protoreaster sp. Archaster sp. Linckia sp. Clypeaster sp. Cerithium sp. Tripneustes sp. Holothuria sp. Oreaster albeolatus Ophiarachna incrasala Echinocardium cordatum Diadema setosum Laganum laganum Echinometra mathaei |
[33][38][39][40] |
Star fish |
Astropecten sp. Protoreaster nodosus Linkia laevigata |
[40][41] |
Feather star |
Comanthina bennetti Comanthina schlegeli |
[42] |
Sea star |
Luidia sp. Culcita novaeguineae |
[43] |
Tunicates |
Sea squirt |
Didemnum molle Atriolum robustum Polycarpa aurata Rhopalea sp. |
[44] |
Fishes |
Rabbitfish |
Siganid sp. |
[45] |
Mudskipper |
Periophthalmodon Periophthalmus |
[45] |
Spot-tail needlefish |
Strongylura strongylura |
[46] |
Amphibians |
Mangrove frog |
Fejervarya cancrivora Rana cancrivora |
[47] |
Reptiles |
Snake |
Cerberus rhybchos |
[33] |
Lizard |
Tupinambis indicus |
[48] |
Crocodiles |
Crocodylus porosus |
[49] |
Birds |
Eagles |
Haliastur indus Pitta megarhyncha |
[50][51] |
Kingfishers |
Halcyon senegaloides Todiramphus sordidus |
[52] |
|
Herons |
Nycticorax nycticorax Egretta gularis |
[53][54] |
Plovers |
Charadrius sp. Pluvialis sp. Thinornis sp. |
[55][56] |
Terns |
Sterna paradisaea |
[56] |
Crow |
Corvus splendens |
[57] |
Green pigeon |
Treron olax |
[57] |
Egrets |
Egretta garzetta Egretta immaculata Egretta nigripes |
[58][59] |
Mammals |
Bats |
Cynopterus brachyotis Acerodon jubatus |
[60][61] |
Monkey |
Nasalis larvatus |
[62] |
Dugong |
Dugong dugon |
[63] |
Otters |
Lutrinae sp. |
[64] |
Group |
Common Name |
Genus/Species |
References |
Angiosperm |
Seagrasses |
Cymodocea sp. Thalassia sp. Halodule sp. Halophila sp. Enhalus sp. |
[65][66] |
Orchids |
Acampe sp. Agrostophyllum sp. Apotasi sp. Ascocentrum sp. Bulbophyllum sp. Ceratostylis sp. Cleisostoma sp. Cymbidium sp. Dendrobium sp. Flickingeria sp. Grosourdya sp. Habenaria sp. Liparis sp. Malaxis sp. Podochilus sp. Pomatocalpa sp. Thelasis sp. |
[67][68][69][70][71] |
Lilies |
Crinum sp. Hymenocallis sp. Nymphaeaceae sp. Lycoris sp. |
[72][73] |
Vines |
Cryptostegia grandiflora |
[12] |
Bryophytes |
Ferns |
Acrostichum sp. Waterhousea sp. |
[74][75] |
Algae |
Marine algae |
Padina sp. Ulva sp. Ventricaria ventricosa |
[76][77] |
Mangrove ecosystems are partly linked with and support corals and seagrasses
[78]. Mangrove ecosystems have a positive impact on seagrass meadow traits such as shoot length, width, and height, shoot density, root length, number of leaves, leaf biomass, and population dynamics
[79]. Mangrove roots trap the fine sediments coming from terrestrial sources and intercept turbid water, preventing it from reaching coral and seagrass systems
[80]. On the other hand, coral reefs provide tranquil conditions that increase the deposition of fine sediments in adjusting areas, which supports the growth and development of seagrass beds and mangrove forests
[81]. Likewise, corals and seagrasses maintain the balance between organic and inorganic carbon contents in coastal areas, subsequently establishing carbon sinks and sources in the mangrove ecosystem
[82]. As mangrove forests, coral reefs, and seagrasses are interdependent ecosystems, to effectively store and export blue carbon in tropical coastal areas, it is essential to maintain the health of each of these coexisting ecosystems
[83].
1.3. Reservoir of Microbial Communities
Mangroves are reservoirs of diverse microbial communities that include bacteria and fungi
[84]. Organic sediments swept into mangroves by tides are inhabited by bacteria that decompose the organic debris and are primary contributors to carbon cycling
[85]. Diverse bacteria in these populations are involved in many other essential ecological functions such as nitrogen fixation
[86], photosynthesis
[87], phosphate solubilisation
[88], enzyme production
[89], sulfate reduction
[90], antibiotic production
[91], anoxygenesis
[92], and methanogenesis
[93] (
Table 3). Among fungi, the dominant fungal phyla are
Ascomycetes and
Basidiomycetes, which have been reported to be primarily associated with the survival of mangrove plants in waterlogged and nutrient-restricted environments
[94] (
Table 3). The microbial communities of mangroves improve nutrient availability, support the growth of vegetation, and provide protection from pathogenic bacteria, thereby positively impacting species diversity
[95].
Table 3. Major microbial groups inhabiting the mangrove forests.
Group |
Phyla |
Functions |
References |
Bacteria |
Actinobacteria |
-
Produce highly bioactive compounds such as antibiotics against pathogenic bacteria, anticancer, and antifungals, and protect mangroves from disease
|
[96] |
|
Chloroflexota |
-
Methanogenesis
-
Produce secondary metabolites from root exudates or soil organic matter that can be utilised by other anode-coupling microorganisms
-
Anaerobic degradation of organic compounds, e.g., sulfate reduction
|
[84][85] |
|
Asgardarchaeota |
|
[97] |
|
Bacteroidetes |
|
[16] |
|
Thermoproteota |
-
Oxidisation of ammonia
-
Sulfate reduction
-
Methanogenesis
|
[98] |
|
Calditrichota |
|
[99] |
|
Bacillota |
|
[100] |
|
Thermodesulfobacteriota |
-
Oxidation of the precipitated sulfide
-
Participate in the elimination of toxic metals
-
Regulate the sulfur cycle, oxidise reduced sulfide to sulfate, affecting the sulfur biogeochemistry
-
Converts many metal ions such as Cu, Pb, Cr, Zn, Hg, and As into low-solubility metal sulfides
|
[95] |
|
Euryarchaeota |
|
[84] |
|
Firmicutes |
-
Produce indole-3-acetic acid (IAA) and siderophores
-
Oxidize hydrogen cyanide and thiosulfate
-
Produce ammonia and cellulase
-
Solubilise potassium and zinc
|
[101][102] |
|
Halobacterota |
|
[103] |
|
Nitrososphaerota |
|
[98] |
|
Nitrospirota |
|
[93] |
|
Planctomycetota |
|
[104] |
|
Pseudomonadota |
|
[105][106] |
|
Thaumarchaeota |
|
[93] |
|
Zixibacteria |
|
[107] |
Cyanobacteria |
Cyanobacteriota |
-
Key role in carbon and nitrogen fixation
-
Helps in nitrogen fixation
-
Cells provide calcium, magnesium, and phosphorous storage in mangrove ecosystems
|
[108][109] |
Fungi |
Ascomycota |
-
Develops mycorrhizal associations with roots of mangroves and transports nutrients
-
Helps plants survive in waterlogged conditions
-
Acts as decomposers
-
Produces a variety of extracellular degradative enzymes, which include cellulase, xylanase, pectinase, and amylase
|
[94][110] |
|
Basidiomycota |
|
[111] |
There are several functions of mangrove forests other than as habitats for flora and fauna: They act as a carbon sink (blue carbon storage)
[112], maintain water quality
[113], protect coastal land from natural disasters
[114], and support coral and seagrass ecosystems
[115] (
Figure 1). In addition, mangroves provide livelihood opportunities for coastal communities through aquaculture, fodder, timber, and ecotourism
[116].
Figure 1. Functions and services of an intact mangrove ecosystem.
2.1. Carbon Sink
Mangroves play an important role in mitigating the effects of greenhouse gases generated by anthropogenic activities such as deforestation, agriculture, and industrial processes. This mitigation involves removing CO
2 from the atmosphere, after which mangrove flora sequester carbon in their above- and below-ground biomass
[112]. Mangroves, as a carbon sink, can hold an estimated 1023 Mg/hectare of carbon
[117]. Various studies have confirmed that mangroves have a faster carbon sequestering capacity than other ecosystems, such as grasslands or tropical rainforests
[118]. According to a report from the Global Mangrove Alliance (GMA) 2022
[119], the total organic carbon stored in mangrove forests at a global level is estimated at around 21,896.56 Mt CO
2e with 2817.23 Mt CO
2e stored in above-ground biomass and 19,079.32 Mt CO
2e stored in the upper 1 m of soil
[120]. It can be seen from
Figure 2 that the carbon storage capacity varies quite considerably for different countries, with Indonesia having a relatively strong capacity compared to the other countries. In mangroves, carbon-rich soils extend from 0.5 m to ~3 m in depth and accommodate 49%–98% of the carbon stored by the mangrove ecosystem
[121].
Figure 2 represents the organic carbon storage capacity of mangrove forests in various countries as above-ground biomass (data derived from GMW version 0.3, 2020)
[122]. As mangroves store a considerable amount of carbon, the destruction of this habitat disturbs the carbon sink and emits huge amounts of carbon back into the atmosphere, significantly contributing to climate change. Therefore, protecting and restoring mangrove habitats can reduce the impact of climate change
[123]. Although it would be great to consider many more countries in this discussion, due to the brevity of the paper, only 12 countries have been included that have the most robust data, as shown in
Figure 2.
Figure 2. Above-ground carbon storage capacity of mangrove forests in different countries in 2020. Each country has mangrove forests with different carbon storage capacities, which are presented in ranges of carbon storage measured in metric tons of equivalent carbon (Mt CO2e) with each range represented by a different colour. The x-axis is a scale bar of the percentages of the total forests in each country that fall into each carbon storage range. (Data sourced from GMW, 2022).
2.2. Natural Water Filters
Mangrove forests act as natural water filters for coastal areas, improving the water quality by trapping sediments and other solid impurities with their roots
[113]. This reduces the flow of sediments into offshore waters, thereby reducing erosion
[124], maintaining clean habitats for seagrass beds and coral reefs, and contributing to SDG 14, which talks about life below water
[125]. Mangroves can grow in saline water and filter 90% of sodium ions (Na
+) from the surrounding seawater
[126]. Their roots comprise a three-layered pore structure in the root epidermis, which facilitates Na
+ filtration
[127]. Additionally, mangrove roots, such as pneumatophores and prop roots, create a low-energy environment, allowing wastewater-containing contaminants to reside for an extended period
[128]. Mangrove plants also sequester other metals, including the heavy metals Zn, Mn, and Cu
[129]. The study of the mechanisms by which mangrove plants filter water has led to novel water treatment technology: Researchers at Virginia Tech (Virginia Polytechnic Institute and State University, USA)
[130] have developed a “synthetic tree” water purifier system inspired by the water filtration technique used in mangrove plants. Specifically, a synthetic tree is composed of a nano-porous “leaf” to produce suction via evaporation, a vertical column of glass tubes similar to the xylem vessels of the tree, and filters attached to the tube inlets, mimicking roots
[130]. In another recent study, a group of engineers from Yale University (New Haven, CT, USA) invented a water purification device that mimics the desalinisation ability of mangrove trees based on the principle of cohesion-tension theory in mangroves. In this technique, synthetic leaves can generate highly negative pressures that allow desalination through a reverse osmosis (RO) membrane
[131].
2.3. Barriers to Natural Disasters
Mangroves not only prevent soil and coastal erosion by retaining sediments in their aerial roots
[124] but also act as barriers against natural disasters. The canopy, trunk, and roots of mangrove plants restrain storm surges
[114] and waves
[132]. In the aftermath of the Asian tsunami on 26 December 2004
[133], Hurricane Katrina on 23 August 2005, on the US Gulf Coast
[134], and the Transoceanic tsunami on 23 January 2022
[135], persuasive evidence emerged from field studies in several countries justifying the role of mangroves as natural barriers protecting coastal habitats and communities. It is quite evident after the tsunami survey that the intact and dense mangroves with higher structural complexity near coastal areas offered fewer fatalities and minimal damage to assets as compared to the areas where mangroves had either been destroyed or transformed to alternate land uses
[136][137].
2.4. Livelihood Opportunities for Coastal Communities
About 90% of the global mangrove forests grow in economically less privileged countries
[138]. Approximately 100 million people live within a 10 km range of mangrove forests and directly benefit from this ecosystem as a source of livelihood opportunities
[139].
2.4.1. Aquaculture
Mangroves are considered hotspot locations for aquaculture
[140]. The species commonly reared include various fish, shrimp/prawns, crabs, molluscs, and other invertebrates
[141]. Approximately 80 million tonnes of fish were produced globally through aquaculture in 2022
[142]. Extensive mangrove-associated aquaculture has been observed in Indonesia, Malaysia, and the Philippines
[143]. Mangrove-associated aquaculture accounts for 21% (1.4 million tons annually) of the coastline fisheries of the ASEAN (Association of South East Asian Nations) region
[144]. Of the annual fish and seafood resources, fin fish alone contribute around 1.09 million tons
[145], while shrimp/prawn contribute around 0.4 million tons
[146]. In addition, fish products from these aquaculture activities are a principal source of food for coastal communities.
Large-scale aquaculture
[147], fish farming in cages or in ponds
[148], and integrated rice-fish farming
[149] have reduced pressure on overexploited fisheries by diversifying fish production other than wild stocks. Small-scale aquaculture, in particular, enables fish farmers to provide food for their families while generating income from the sale of surplus stock
[150]. Such activities also create employment opportunities through various enterprises ranging from the processing, distribution, and sale of fish linked to the aquaculture value chain
[151]. These livelihood opportunities facilitate the sustainable mangrove ecosystem’s ability to successfully contribute to the outcomes of various sustainable development goals set by the United Nations, such as SDG 1, SDG 2, SDG 8, SDG 11, SDG 13, SDG 14, and SDG 15. (The detailed agenda of these SDGs can be seen at
https://www.un.org/development/desa/disabilities/envision2030.html, accessed on 11 July 2023)
[152].
2.4.2. Fodder, Timber and Traditional Medicines
Mangroves also provide fodder, timber, and medicine resources for coastal indigenous communities (
Figure 1). Cattle, sheep, goats, and buffaloes are domestic animals that are generally fed on mangrove foliage
[153]. Mangrove foliage, particularly from
Avicennia marina, is considered healthy fodder for domestic animals (Mitra, 2020). Mangrove wood, being highly resistant to rot and insects, is frequently utilised as timber as well as for fuel wood
[154].
Rhizophora spp.,
Xylocarpus sp.,
Bruguiera sp., and
Sonneratia sp. are significantly important for timber due to the durability of their wood and their large trunk size
[155]. The timber of these species is used for small watercraft, shipbuilding, and for making utensil handles, furniture, poles, piles, and other building materials
[156]. Mangrove firewood has been widely used as an energy source by rural communities.
Mangrove services also include the provision of traditional medicine for treating skin ailments and stomach issues
[157]. Extracts from mangrove-associated species, for example,
Abonnema and
Nypa fruticans, have shown antimicrobial activity against some plant and animal pathogens
[158]. The bioactive compound ecteinascidin, extracted from the mangrove tunicate
Ecteinascidia turbinate, has been reported to show strong in vivo activity against various cancerous cells
[159]. Furthermore, the bark of
Ceriops sp. is a good source of tannin, and its decoction is used in Vedic medicine to stop haemorrhage and in the treatment of malignant ulcers
[160].
2.4.3. Ecotourism
Ecotourism refers to the form of tourism that focuses on responsible travel that minimises environmental impact and supports local communities
[161]. Ecotourism in mangrove regions places a strong emphasis on mangrove conservation, education of visitors about the mangrove forest, and providing economic benefit to local communities
[162]. Ecotourism syndicates three key aspects, viz., (i) ecology, which includes the existence of the elements upon which the mangrove ecosystem depends and also its conservation efforts
[163], (ii) financial revenue generated as a result of ecotourism activities in sustainable mangroves, a share of which is expended to maintain the ecosystem
[164], and (iii) empowerment and engagement of the local community in the ecotourism business
[165]. The species diversity of both fauna and flora and the unique characteristics of mangrove plants have been a great attraction for ecotourism
[166]. Mangrove areas offer several forms of ecotourism activities, such as sports and recreational activities such as fishing, boating, and camping
[167]; educational and research tourism in the form of field trips to mangroves to observe and study the mangrove vegetation and life inside the mangroves
[168]; and health tourism as sites for self-meditation and other therapy
[169]. Many mangrove forests have been established as tourist attractions by governmental or non-governmental organisations in different regions
[170]. For example, areas of mangrove forest in Bali, Indonesia, have been established by local communities for the purpose of ecotourism and to maintain the conservation of biodiversity, landscapes, and the ecosystem overall
[171]. Ecotourism activities carried out by these community groups are supported and fostered by the relevant stakeholders of the region and/or the state government and have been incorporated as a part of their CSR (corporate social responsibility) program
[172]. The use of mangroves for ecotourism is in accordance with the development directions of the Sustainable Development Goals (SDGs), 12, 13, 14, 15, and 17
[173].
This entry is adapted from the peer-reviewed paper 10.3390/f14091698