ⓘ Aquatic plant

Aquatic plant

ⓘ Aquatic plant

Aquatic plants are plants that have adapted to living in aquatic environments. They are also referred to as hydrophytes or macrophytes to distinguish them from algae and other microphytes. A macrophyte is a plant that grows in or near water and is either emergent, submergent, or floating. In lakes and rivers macrophytes provide cover for fish, substrate for aquatic invertebrates, produce oxygen, and act as food for some fish and wildlife.

Macrophytes are primary producers and are the basis of the food web for many organisms. They have a significant effect on soil chemistry and light levels as they slow down the flow of water and capture pollutants and trap sediments. Excess sediment will settle into the benthos aided by the reduction of flow rates caused by the presence of plant stems, leaves and roots. Some plants have the capability of absorbing pollutants into their tissue. Seaweeds are multicellular marine algae and, although their ecological impact is similar to other larger water plants, they are not typically referred to as macrophytes.

Aquatic plants require special adaptations for living submerged in water, or at the waters surface. The most common adaptation is the presence of lightweight internal packing cells, aerenchyma, but floating leaves and finely dissected leaves are also common. Aquatic plants can only grow in water or in soil that is frequently saturated with water. They are therefore a common component of wetlands.One of the largest aquatic plants in the world is the Amazon water lily; one of the smallest is the minute duckweed. Many small aquatic animals use plants such as duckweed for a home, for protection from predators. Some other familiar examples of aquatic plants might include floating heart, water lily, lotus, and water hyacinth.


1. Distribution

The principal factor controlling the distribution of aquatic plants is the depth and duration of flooding. However, other factors may also control their distribution, abundance, and growth form, including nutrients, disturbance from waves, grazing, and salinity. A few aquatic plants are able to survive in brackish, saline, and salt water.


2. Evolution

Aquatic plants have adapted to live in either freshwater or saltwater. Aquatic vascular plants have originated on multiple occasions in different plant families; they can be ferns or angiosperms including both monocots and dicots. The only angiosperms capable of growing completely submerged in seawater are the seagrasses. Examples are found in genera such as Thalassia and Zostera. An aquatic origin of angiosperms is supported by the evidence that several of the earliest known fossil angiosperms were aquatic. Aquatic plants are phylogenetically well dispersed across the angiosperms, with at least 50 independent origins, although they comprise less than 2% of the angiosperm species. Archefructus represents one of the oldest, most complete angiosperm fossils which is around 125 million years old. These plants require special adaptations for living submerged in water or floating at the surface.

Although most aquatic plants can reproduce by flowering and setting seeds, many have also evolved to have extensive asexual reproduction by means of rhizomes, turions, and fragments in general.


3. Classification of Macrophytes

Based on growth form, macrophytes can be charecterised as:

  • Rooted: rooted to the substrate
  • Submerged
  • Unrooted: free-floating in the water column
  • Attached: attached to substrate but not by roots
  • Emergent
  • Floating-leaved
  • Free-floating

3.1. Classification of Macrophytes Emergent

An emergent plant is one which grows in water but pierces the surface so that it is partially in air. Collectively, such plants are emergent vegetation.

This habit may have developed because the leaves can photosynthesis more efficiently in air and competition from submerged plants but often, the main aerial feature is the flower and the related reproductive process. The emergent habit permits pollination by wind or by flying insects.

There are many species of emergent plants, among them, the reed Phragmites, Cyperus papyrus, Typha species, flowering rush and wild rice species. Some species, such as purple loosestrife, may grow in water as emergent plants but they are capable of flourishing in fens or simply in damp ground.


3.2. Classification of Macrophytes Submerged

Submerged macrophytes completely grow under water with roots attached to the substrate e.g. Myriophyllum spicatum or without any root system e.g. Ceratophyllum demersum. Helophytes are plants that grows in a marsh, partly submerged in water, so that it regrows from buds below the water surface. Fringing stands of tall vegetation by water basins and rivers may include helophytes. Examples include stands of Equisetum fluviatile, Glyceria maxima, Hippuris vulgaris, Sagittaria, Carex, Schoenoplectus, Sparganium, Acorus, yellow flag Iris pseudacorus, Typha and Phragmites australis.


3.3. Classification of Macrophytes Floating-leaved

Floating-leaved macrophytes have root systems attached to the substrate or bottom of the body of water and with leaves that float on the water surface. Common floating leaved macrophytes are water lilies family Nymphaeaceae, pondweeds family Potamogetonaceae.


3.4. Classification of Macrophytes Free-floating

Free-floating macrophytes are aquatic plants that are found suspended on water surface with their root not attached to substrate, sediment, or bottom of the water body. They are easily blown by air and provide breeding ground for mosquitoes. Example include Pistia spp commonly called water lettuce, water cabbage or Nile cabbage.


4. Morphological classification

The many possible classifications of aquatic plants are based upon morphology. One example has six groups as follows:

  • Pleuston: vascular plants that float freely in the water
  • Nymphaeids: plants rooted in the bottom, but with leaves floating on the water surface
  • Amphiphytes: plants that are adapted to live either submerged or on land
  • Elodeids: stem plants that complete their entire lifecycle submerged, or with only their flowers above the waterline
  • Helophytes: plants rooted in the bottom, but with leaves above the waterline
  • Isoetids: rosette plants that complete their entire lifecycle submerged

5. Functions of macrophytes in aquatic system

Macrophytes perform many ecosystem functions in aquatic ecosystems and provide services to human society. One of the important functions performed by macrophyte is uptake of dissolve nutrients N and P from water. Macrophytes are widely used in constructed wetlands around the world to remove excess N and P from polluted water. Beside direct nutrient uptake, macrophytes indirectly influence nutrient cycling, especially N cycling through influencing the denitrifying bacterial functional groups that are inhabiting on roots and shoots of macrophytes. Macrophytes promote the sedimentation of suspended solids by reducing the current velocities, impede erosion by stabilising soil surfaces. Macrophytes also provide spatial heterogeneity in otherwise unstructured water column. Habitat complexity provided by macrophytes like to increase the richness of taxonomy and density of both fish and invertebrates.


6.1. Uses and importance to humans Food crops

Some aquatic plants are used by humans as a food source. Examples include wild rice Zizania, water caltrop Trapa natans, Chinese water chestnut Eleocharis dulcis, Indian lotus Nelumbo nucifera, water spinach Ipomoea aquatica, and watercress Rorippa nasturtium-aquaticum.


6.2. Uses and importance to humans Bioassessment

A decline in a macrophyte community may indicate water quality problems and changes in the ecological status of the water body. Such problems may be the result of excessive turbidity, herbicides, or saliniation. Conversely, overly high nutrient levels may create an overabundance of macrophytes, which may in turn interfere with lake processing. Macrophyte levels are easy to sample, do not require laboratory analysis, and are easily used for calculating simple abundance metrics.


6.3. Uses and importance to humans Potential sources of therapeutic agents

Phytochemical and pharmacological researches suggest that freshwater macrophytes, such as Centella asiatica, Nelumbo nucifera, Nasturtium officinale, Ipomoea aquatica and Ludwigia adscendens, are promising sources of anticancer and antioxidative natural products.

Hot water extracts of the stem and root of Ludwigia adscendens, as well as those of the fruit, leaf and stem of Monochoria hastata were found to have lipoxygenase inhibitory activity. Hot water extract prepared from the leaf of Ludwigia adscendens exhibits alpha-glucosidase inhibitory activity more potent than that of acarbose.

  • charged. The garden opened in 1969 and features a wide assortment of aquatic plants It is best known for its iris and lotus collections, comprising about
  • phyton meaning plant Epiphytic plants are sometimes called air plants because they do not root in soil. However, there are many aquatic species of algae
  • sword plant although other plants are also known under this common name. The aquatic plant is cultivated for and used in ponds and artificial aquatic habitats
  • live plants Hobby aquarists use aquatic plants for aquascaping. Brackish plants are known to occur in brackish water. The taxonomy of most plant genera
  • waterwheel plant is the sole extant species in the flowering plant genus Aldrovanda of the family Droseraceae. The plant captures small aquatic invertebrates
  • Marine botany is the study of aquatic plants and algae that live in seawater of the open ocean and the littoral zone, along shorelines of the intertidal
  • Aponogeton natans is a species of aquatic plant in the family Aponogetonaceae. Aponogeton natans grows as a submerged aquatic plant Aponogeton natans is native

Users also searched:

5 aquatic plants, aquatic plant identification key, fixed aquatic plants names, floating aquatic plants,