Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1 -- 1676 2023-11-06 14:03:42 |
2 format correct Meta information modification 1676 2023-11-07 01:39:11 |

Video Upload Options

We provide professional Video Production Services to translate complex research into visually appealing presentations. Would you like to try it?

Confirm

Are you sure to Delete?
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Osman, M.E.H.; Abo-Shady, A.M.; Elshobary, M.E.; Abd El-Ghafar, M.O.; Hanelt, D.; Abomohra, A. Seagrass. Encyclopedia. Available online: https://encyclopedia.pub/entry/51190 (accessed on 16 November 2024).
Osman MEH, Abo-Shady AM, Elshobary ME, Abd El-Ghafar MO, Hanelt D, Abomohra A. Seagrass. Encyclopedia. Available at: https://encyclopedia.pub/entry/51190. Accessed November 16, 2024.
Osman, Mohamed E. H., Atef M. Abo-Shady, Mostafa E. Elshobary, Mahasen O. Abd El-Ghafar, Dieter Hanelt, Abdelfatah Abomohra. "Seagrass" Encyclopedia, https://encyclopedia.pub/entry/51190 (accessed November 16, 2024).
Osman, M.E.H., Abo-Shady, A.M., Elshobary, M.E., Abd El-Ghafar, M.O., Hanelt, D., & Abomohra, A. (2023, November 06). Seagrass. In Encyclopedia. https://encyclopedia.pub/entry/51190
Osman, Mohamed E. H., et al. "Seagrass." Encyclopedia. Web. 06 November, 2023.
Seagrass
Edit

ٍSeagrass is a type of aquatic plants that grow in a wide variety of marine habitats. Seagrasses are specifically adapted to thrive in shallow and transparent seawater environments to access ample sunlight for their photosynthetic processes. This unique botanical group plays a crucial ecological role in coastal ecosystems and is distinguishable from macroalgae due to its vascular plant characteristics and its capacity to form underwater meadows in coastal waters.

biorefinery green energy pretreatment seagrass marine biomass

1. Introduction

Seagrass plays a crucial role in coastal marine ecosystems globally, serving as a foundational element. It provides sustenance for marine creatures such as dugongs and turtles and functions as an essential nursery for various fish and prawn species. It serves as a habitat for a wide range of small marine organisms. Thus, the presence and health of seagrass beds are vital for maintaining the overall ecological balance and biodiversity of coastal marine environments. These meadows are essential to shoreline communities, supporting diverse marine life that sustains local livelihoods. In recent decades, human-induced factors such as diminished water quality, rising temperatures, amplified sedimentation, and intensified grazing pressure have resulted in a worldwide decrease in seagrass populations and the expanse of seagrass beds [1][2]. On the other hand, the overgrowth of seagrass can have negative impacts on the coastal marine ecosystems and the surrounding environment. For instance, the non-native salt marsh plant Spartina alterniflora expanded its range deeper into the intertidal zone within China’s Yellow River Delta, which posed a threat to the natural habitat of the native seagrass Zostera japonica [3]. Thick and overgrown seagrass beds can impede water circulation and flow, leading to stagnant areas with reduced oxygen levels, which can harm aquatic life. In addition, the excessive seagrass growth can alter the physical structure of coastal habitats. It may create overly dense and monotonous underwater landscapes, reducing the availability of open spaces needed by various species for feeding, reproduction, and movement. While seagrass beds are known for their biodiversity, an overgrowth can lead to a decline in species diversity, as some species may thrive in the dense seagrass while others that require more open habitat may suffer. Moreover, the overgrown seagrass can trap sediments and organic matter, leading to increased turbidity (cloudiness) in the water, negatively affecting light penetration and hindering the growth of other marine plants, such as macroalgae or even corals. Furthermore, it may provide excessive shelter for herbivores like sea urchins and parrotfish, making it difficult for them to graze and control algal growth. This can lead to simultaneous algal overgrowth, negatively impacting the coastal area. In order to maintain a healthy balance, it is important to monitor and manage seagrass ecosystems carefully. Proper management practices may involve seagrass restoration, selective thinning, and maintaining water quality to prevent excessive growth while ensuring the continued ecological benefits of these vital coastal habitats. Simultaneous management of seaweeds has the potential to help maintain the equilibrium of seagrass ecosystems, particularly in temperate and tropical regions where seagrass decline has been linked to the proliferation of macroalgal bloom [4].
Tropical seagrass meadows have gained recent research focus due to declines in iconic marine species like the dugong. Initiatives like neighborhood watch programs and extensive research efforts are vital for managing the uncertain future of coastal marine life. The seagrass habitats in tropical systems can be categorized into river estuary, coastal, deep water, and reef. These categories vary based on water depth and seabed type, influencing factors such as light availability crucial for photosynthesis. Deepwater coastal ecosystems, found between 10 and 70 m deep, contain sand-covered seafloors, while reef environments are formed by coral-derived calcium carbonate rock. Shallow water habitats, exposed during low tide, pose challenges to seagrass growth due to air exposure and intense light. The ongoing research in these diverse habitats contributes crucial knowledge for the conservation of coastal marine ecosystems [5][6].

2. Species Diversity

Seagrasses represent a polyphyletic group of marine angiosperms comprising approximately 60 species distributed across five families: Zosteraceae, Hydrocharitaceae, Posidoniaceae, Cymodoceaceae, and Ruppiaceae [7]. These seagrasses are classified within the order Alismatales, following the Angiosperm Phylogeny Group IV proposed system. Important coastal habitats are formed by seagrasses [8]. These species have different morphological, physiological, and ecological characteristics that allow them to adapt to various environmental conditions. Seagrasses can be found in a variety of habitats, such as sandy/muddy or rocky shores, kelp forests, coral reefs, estuaries, lagoons, and deep waters. Many factors, such as climate, light, nutrients, salinity, sedimentation, herbivory, and human activities, influence seagrass diversity. Seagrass diversity is important for maintaining the resilience and functioning of seagrass ecosystems and the services they provide. Seagrasses were recorded and found in 159 countries across six continents [9]. According to Short et al. [10], seagrasses exhibit five primary centers of high global diversity, all of which are situated in the eastern hemisphere. Among these centers, four are in the Tropical Indo-Pacific region, while the fifth is in southwestern Australia, falling within the adjacent Temperate Southern Oceans bioregion. The study reported that the largest and foremost center of seagrass diversity, boasting the highest number of seagrass species of 19, is situated across insular Southeast Asia and extends through north tropical Australia, including the Great Barrier Reef. A second, comparatively smaller center of diversity is identified in southeastern India, encompassing 13 exclusively tropical species. The remaining three high-diversity global centers are located in eastern Africa, southern Japan, and southwestern Australia. In East Africa, there are 12 seagrass species, with only one, Z. capensis, being of temperate origin, resulting in a predominantly tropical species mix. Southern Japan also boasts 12 seagrass species, with Z. japonica being the sole temperate species contributing to the diversity of this otherwise tropical region. Within the temperate Southern Oceans bioregion, southwestern Australia is home to 13 seagrass species, four of which are tropical in origin and contribute to its high diversity. A deeper insight into these diversity patterns and the specific distribution ranges of individual seagrass species has been discussed by Green and Short [11].

3. Cell Wall Structure

Genome data has revealed that significant alterations in cell wall composition are essential for organisms to adapt successfully to diverse marine environments [12][13]. However, the composition and characteristics of seagrass cell walls remain relatively enigmatic. Beyond the ancestral traits inherited from land plants, seagrasses are expected to have undergone a habitat-driven adaptation process to their unique environment. This environment is marked by various abiotic factors, such as high salinity, as well as biotic factors, like diverse seagrass grazers and bacterial colonization, all of which contribute to the stressors faced by these plants. Seagrass cell walls are composed of polysaccharides that are familiar from angiosperm land plants, i.e., cellulose, despite the lack of current information [14]. However, sulfated polysaccharides (SP) are characteristic of the macroalgae. They are also present in the cell walls of certain seagrasses [15][16][17]. Another distinctive characteristic is the presence of peculiar pectic polysaccharides known as apiogalacturonans in seagrass cell walls. The peculiar monosaccharide apiose (Apif) is substituted with significant numbers of low-methyl esterified galacturonic acid (GalAp) units [18][19]. Seagrasses feature highly glycosylated arabinogalactan-proteins (AGPs) that are of particular interest due to their dual role in wall architecture and cellular regulatory processes [20][21]. These AGPs are characterized by their complex structure, featuring extensive polysaccharide components consisting of arabinogalactans (AGs). AGPs were recently isolated from seagrasses and structurally described for the first time [22]. In seagrasses, phenolic polymers (i.e., lignin) responsible for the mechanical strengthening of the wall have also been detected, even though in much lower amounts than angiosperm land plants [23][24][25][26]. As a result, the cell walls of seagrasses appear to be intriguing fusions of traits from marine macroalgae and angiosperm land plants with novel structural components. More details about the cell wall structure of seagrasses have been previously discussed [22]. However, it is imperative to deepen the comprehension of seagrass cell walls, especially from a technical perspective, given their potential utility in various applications, such as biofuel production, biodegradable materials, and as a source of valuable compounds for pharmaceutical and industrial purposes.

4. Seagrass Cultivation

Seagrass cultivation can be performed in different ways, depending on the species, the environmental conditions, and the project’s objectives. Some common methods of seagrass cultivation include seed collection and sowing [27]. This method involves collecting seagrass seeds from natural populations or the lab, then sowing them directly into the seabed or into biodegradable mats or bags that can be transplanted later. This method can produce large numbers of plants with high genetic diversity, but it requires careful timing, handling, and monitoring of the seeds and seedlings. Vegetative propagation is another cultivation method [28]. It involves cutting seagrass shoots or rhizomes from donor plants and planting them into the seabed or into pots or trays that can be transplanted later. This method can produce fast-growing plants with high survival rates, but it requires sufficient donor material and may reduce the genetic diversity of the plants. In addition to the aforementioned methods, tissue culture is another promising cultivation technique [29]. This method involves growing seagrass cells or tissues in a sterile laboratory environment and then transferring them to a greenhouse or a nursery for further growth and acclimation. This method can produce disease-free plants with high genetic diversity, but it requires advanced equipment/skills and is costly and time-consuming.
Overall, seagrass cultivation is a promising technique to enhance the conservation and restoration of seagrass ecosystems, which are threatened by global and local stressors such as climate change, pollution, coastal development, and overfishing. In addition, seagrass land-based co-cultivation with seaweeds can also provide benefits for human well-being, such as food security, shoreline protection, carbon sequestration, water filtration, and fisheries production [30]. The existing literature reveals a scarcity of studies focusing on cultivating seagrass for biomass production. In contrast to macroalgae, most research concerning seagrass biomass relies on natural cultivation systems. However, macroalgae have been relatively more extensively investigated for their potential biomass production through cultivation. The emphasis has been placed on understanding seagrass ecosystems within their natural habitats rather than developing dedicated cultivation strategies for biomass production. In that context, the co-cultivation of seagrass and macroalgae could be of significant ecological, environmental, and economic importance for carbon sequestration, wastewater treatment, enhanced biodiversity, food security, and biofuel production.

References

  1. de los Santos, C.B.; Krause-Jensen, D.; Alcoverro, T.; Marbà, N.; Duarte, C.M.; van Katwijk, M.M.; Pérez, M.; Romero, J.; Sánchez-Lizaso, J.L.; Roca, G.; et al. Recent Trend Reversal for Declining European Seagrass Meadows. Nat. Commun. 2019, 10, 3356.
  2. Papenbrock, J.; Teichberg, M. Editorial: Current Advances in Seagrass Research. Front. Plant Sci. 2023, 14, 1196437.
  3. Yue, S.; Zhou, Y.; Xu, S.; Zhang, X.; Liu, M.; Qiao, Y.; Gu, R.; Xu, S.; Zhang, Y. Can the Non-Native Salt Marsh Halophyte Spartina Alterniflora Threaten Native Seagrass (Zostera japonica) Habitats? A Case Study in the Yellow River Delta, China. Front. Plant Sci. 2021, 12, 643425.
  4. Han, Q.; Liu, D. Macroalgae Blooms and Their Effects on Seagrass Ecosystems. J. Ocean Univ. China 2014, 13, 791–798.
  5. El-Shaffai, A.A.; Hanafy, M.H.; Gab-Alla, A.A. Distribution, Abundance and Species Composition of Seagrasses in Wadi El-Gemal National Park, Red Sea, Egypt. Indian J. Appl. Sci. 2011, 4, 1–8.
  6. Waycott, M.; McMahon, K.; Mellors, J.; Calladine, A.; Kleine, D. A Guide to Tropical Seagrasses of the Indo-West Pacific; James Cook University: Townsville, Australia, 2004.
  7. Group, A.P.; Chase, M.W.; Christenhusz, M.J.M.; Fay, M.F.; Byng, J.W.; Judd, W.S.; Soltis, D.E.; Mabberley, D.J.; Sennikov, A.N.; Soltis, P.S. An Update of the Angiosperm Phylogeny Group Classification for the Orders and Families of Flowering Plants: APG IV. Bot. J. Linn. Soc. 2016, 181, 1–20.
  8. Hemminga, M.A.; Duarte, C.M. Seagrass Ecology; Cambridge University Press: Cambridge, UK, 2000; ISBN 0521661846.
  9. Reynolds, P.L.; Duffy, E.; Knowlton, N. Seagrass and Seagrass Beds. Ocean Portal. 2018. Available online: https://www.dcbd.nl/sites/default/files/documents/SeagrassAndSeagrass%20Beds%20_%20SmithsonianOceanPortal.pdf (accessed on 26 September 2023).
  10. Short, F.; Carruthers, T.; Dennison, W.; Waycott, M. Global Seagrass Distribution and Diversity: A Bioregional Model. J. Exp. Mar. Bio. Ecol. 2007, 350, 3–20.
  11. Green, E.P.; Edmund, P.; Short, F.T. World Atlas of Seagrasses; University of California Press: Oakland, CA, USA, 2003; p. 298.
  12. Lee, H.; Golicz, A.A.; Bayer, P.E.; Jiao, Y.; Tang, H.; Paterson, A.H.; Sablok, G.; Krishnaraj, R.R.; Chan, C.-K.K.; Batley, J. The Genome of a Southern Hemisphere Seagrass Species (Zostera muelleri). Plant Physiol. 2016, 172, 272–283.
  13. Olsen, J.L.; Rouzé, P.; Verhelst, B.; Lin, Y.-C.; Bayer, T.; Collen, J.; Dattolo, E.; De Paoli, E.; Dittami, S.; Maumus, F. The Genome of the Seagrass Zostera marina Reveals Angiosperm Adaptation to the Sea. Nature 2016, 530, 331–335.
  14. Syed, N.F.N.; Zakaria, M.H.; Bujang, J.S. Fiber Characteristics and Papermaking of Seagrass Using Hand-Beaten and Blended Pulp. BioResources 2016, 11, 5358–5380.
  15. Silva, J.; Dantas-Santos, N.; Gomes, D.L.; Costa, L.S.; Cordeiro, S.L.; Costa, M.S.S.P.; Silva, N.B.; Freitas, M.L.; Scortecci, K.C.; Leite, E.L. Biological Activities of the Sulfated Polysaccharide from the Vascular Plant Halodule wrightii. Rev. Bras. Farmacogn. 2012, 22, 94–101.
  16. Kolsi, R.B.A.; Fakhfakh, J.; Krichen, F.; Jribi, I.; Chiarore, A.; Patti, F.P.; Blecker, C.; Allouche, N.; Belghith, H.; Belghith, K. Structural Characterization and Functional Properties of Antihypertensive Cymodocea nodosa Sulfated Polysaccharide. Carbohydr. Polym. 2016, 151, 511–522.
  17. Aquino, R.S.; Landeira-Fernandez, A.M.; Valente, A.P.; Andrade, L.R.; Mourao, P.A.S. Occurrence of Sulfated Galactans in Marine Angiosperms: Evolutionary Implications. Glycobiology 2005, 15, 11–20.
  18. Gloaguen, V.; Brudieux, V.; Closs, B.; Barbat, A.; Krausz, P.; Sainte-Catherine, O.; Kraemer, M.; Maes, E.; Guerardel, Y. Structural Characterization and Cytotoxic Properties of an Apiose-Rich Pectic Polysaccharide Obtained from the Cell Wall of the Marine Phanerogam Zostera marina. J. Nat. Prod. 2010, 73, 1087–1092.
  19. Lv, Y.; Shan, X.; Zhao, X.; Cai, C.; Zhao, X.; Lang, Y.; Zhu, H.; Yu, G. Extraction, Isolation, Structural Characterization and Anti-Tumor Properties of an Apigalacturonan-Rich Polysaccharide from the Sea Grass Zostera caespitosa Miki. Mar. Drugs 2015, 13, 3710–3731.
  20. Ellis, M.; Egelund, J.; Schultz, C.J.; Bacic, A. Arabinogalactan-Proteins: Key Regulators at the Cell Surface? Plant Physiol. 2010, 153, 403–419.
  21. Ma, Y.; Zeng, W.; Bacic, A.; Johnson, K. AGPs through Time and Space. Annu. Plant Rev. Online 2018, 1, 767–804.
  22. Pfeifer, L.; Classen, B. The Cell Wall of Seagrasses: Fascinating, Peculiar and a Blank Canvas for Future Research. Front. Plant Sci. 2020, 11, 588754.
  23. Opsahl, S.; Benner, R. Decomposition of Senescent Blades of the Seagrass Halodule wrightii in a Subtropical Lagoon. Mar. Ecol. Prog. Ser. 1993, 94, 191.
  24. Klap, V.A.; Hemminga, M.A.; Boon, J.J. Retention of Lignin in Seagrasses: Angiosperms That Returned to the Sea. Mar. Ecol. Prog. Ser. 2000, 194, 1–11.
  25. Martone, P.T.; Estevez, J.M.; Lu, F.; Ruel, K.; Denny, M.W.; Somerville, C.; Ralph, J. Discovery of Lignin in Seaweed Reveals Convergent Evolution of Cell-Wall Architecture. Curr. Biol. 2009, 19, 169–175.
  26. Kaal, J.; Serrano, O.; del Río, J.C.; Rencoret, J. Radically Different Lignin Composition in Posidonia Species May Link to Differences in Organic Carbon Sequestration Capacity. Org. Geochem. 2018, 124, 247–256.
  27. ReMEDIES Seagrass Cultivation Lab—Save Our Seabed. Available online: https://saveourseabed.co.uk/seagrass-cultivation-lab/ (accessed on 4 September 2023).
  28. Yue, S.; Zhang, X.; Xu, S.; Zhang, Y.; Zhao, P.; Wang, X.; Zhou, Y. Reproductive Strategies of the Seagrass Zostera japonica under Different Geographic Conditions in Northern China. Front. Mar. Sci. 2020, 7, 574790.
  29. Subhashini, P.; Raja, S.; Thangaradjou, T. Establishment of Cell Suspension Culture Protocol for a Seagrass (Halodule pinifolia): Growth Kinetics and Histomorphological Characterization. Aquat. Bot. 2014, 117, 33–40.
  30. Potouroglou, M.; Pedder, K.; Wood, K.; Scalenghe, D. What to Know About Seagrass, the Ocean’s Overlooked Powerhouse 2022. Available online: https://www.wri.org/insights/understanding-seagrass?utm_campaign=wridigest&utm_source=wridigest-2022-08-09&utm_medium=email&utm_content=image (accessed on 1 October 2023).
More
Information
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register : , , , , ,
View Times: 365
Revisions: 2 times (View History)
Update Date: 07 Nov 2023
1000/1000
ScholarVision Creations