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Other Algae01:19

Other Algae

The group Stramenopiles include some phototrophic microorganisms. Members of this group possess flagella covered in numerous short, hairlike extensions, a feature that inspired the group's name, derived from the Latin words for "straw" and "hair." Some of the main categories of Stramenopiles include diatoms, golden algae, and brown algae.Diatoms are unicellular, photosynthetic eukaryotes, with over 200 known genera. They play a key role in the planktonic communities of both marine and...
Green Algae01:21

Green Algae

Green algae, also referred to as chlorophytes, are different from red algae in having the chloroplasts containing chlorophylls a and b, which give them their distinct green hue. However, they lack phycobiliproteins, preventing them from developing the red or blue-green pigmentation seen in red algae. In terms of photosynthetic pigment composition, green algae closely resemble plants and share a close evolutionary relationship with them. Taxonomically Green algae belong to Phylum Chlorophyta in...
Overview of Algae01:28

Overview of Algae

The kingdom Archaeplastida encompasses red and green algae, along with land plants. Unlike other protists with chloroplasts that arose through secondary endosymbiosis, only red and green algae originated from primary endosymbiotic events. This diverse group of eukaryotic organisms contains chlorophyll and performs oxygenic photosynthesis.Algae exist in various forms, from large brown kelp in coastal waters to green scum in puddles and stains on rocks or soil. Some species are responsible for...
Red Algae01:23

Red Algae

Red algae, also known as rhodophytes, are primarily found in marine environments, though some species inhabit freshwater and terrestrial ecosystems. These organisms exist in both unicellular and multicellular forms, with some multicellular varieties reaching macroscopic sizes.As phototrophic organisms, red algae contain chlorophyll a; however, their chloroplasts lack chlorophyll b. Instead, they possess phycobiliproteins, which serve as major light-harvesting pigments, similar to those found in...
Adaptations that Reduce Water Loss01:57

Adaptations that Reduce Water Loss

Though evaporation from plant leaves drives transpiration, it also results in loss of water. Because water is critical for photosynthetic reactions and other cellular processes, evolutionary pressures on plants in different environments have driven the acquisition of adaptations that reduce water loss.
C4 Pathway and CAM01:27

C4 Pathway and CAM

Most plants use the C3 pathway for carbon fixation. However, some plants, such as sugar cane, corn, and cacti that grow in hot conditions, use alternative pathways to fix carbon and conserve energy loss due to photorespiration. Photorespiration is the process that occurs when the oxygen concentration is high. Under such conditions, the rubisco enzyme in the Calvin cycle binds O2 instead of CO2, which halts photosynthesis and consumes energy.
C4 Pathway
The C4 pathway is used by plants such as...

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Updated: May 25, 2026

The Barnacle Balanus improvisus as a Marine Model - Culturing and Gene Expression
07:47

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Published on: August 8, 2018

Ectocarpus: a model organism for the brown algae.

Susana M Coelho1, Delphine Scornet, Sylvie Rousvoal

  • 1UPMC Université Paris 06, The Marine Plants and Biomolecules Laboratory, UMR 7139, Station Biologique de Roscoff, BP74, 29682 Roscoff Cedex, France.

Cold Spring Harbor Protocols
|February 4, 2012
PubMed
Summary
This summary is machine-generated.

Brown algae are ecologically vital and evolutionarily unique organisms. The filamentous brown alga Ectocarpus is emerging as a powerful model for studying their complex biology.

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Area of Science:

  • Marine Biology
  • Evolutionary Biology
  • Phycology

Background:

  • Brown algae are dominant in coastal ecosystems, forming underwater forests.
  • They possess a unique evolutionary history within the stramenopiles, distantly related to plants and animals.
  • Brown algae exhibit novel cell biology and metabolic pathways, and independently evolved complex multicellularity.

Purpose of the Study:

  • To highlight the significance of brown algae in marine ecosystems.
  • To underscore their unique evolutionary trajectory and biological features.
  • To introduce Ectocarpus as a model organism for advanced research.

Main Methods:

  • Genomic approaches
  • Genetic approaches
  • Comparative biology

Main Results:

  • Ectocarpus is amenable to genomic and genetic studies.
  • This model system facilitates research into brown algal biology.
  • It enables comparison with classical model organisms.

Conclusions:

  • Brown algae, particularly Ectocarpus, are increasingly accessible to modern biological research.
  • The study of Ectocarpus promises significant insights into algal biology, evolution, and ecology.
  • This model system bridges the gap between classical models and the unique biology of brown algae.