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Red Algae01:23

Red Algae

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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...
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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...
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Other Algae01:19

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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...
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Eukaryotic RNA Polymerases00:58

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RNA Polymerase (RNAP) is conserved in all animals, with bacterial, archaeal, and eukaryotic RNAPs sharing significant sequence, structural, and functional similarities. Among the three eukaryotic RNAPs, RNA Polymerase II is most similar to bacterial RNAP in terms of both structural organization and folding topologies of the enzyme subunits. However, these similarities are not reflected in their mechanism of action.
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The eukaryotic promoter region is a segment of DNA located upstream of a gene. It contains an RNA polymerase binding site, a transcription start site, and several cis-regulatory sequences.  The proximal promoter region is located in the vicinity of the gene and has cis-regulatory sequences and the core promoter. The core promoter is the binding site for RNA polymerase and is usually located between -35 and +35 nucleotides from the transcription start site. The distal promoter regions are...
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Updated: Feb 6, 2026

Establishment of a Clonal Culture of Unicellular Conjugating Algae
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Establishment of a Clonal Culture of Unicellular Conjugating Algae

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Phytochrome diversification in cyanobacteria and eukaryotic algae.

Nathan C Rockwell1, J Clark Lagarias1

  • 1Department of Molecular and Cellular Biology, 31 Briggs Hall, One Shields Avenue, University of California, Davis, CA 95616, United States of America.

Current Opinion in Plant Biology
|April 27, 2017
PubMed
Summary
This summary is machine-generated.

Phytochromes are light-sensing proteins crucial for plant development. Recent studies reveal their structure and evolutionary history, offering potential for crop improvement.

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Area of Science:

  • Plant biology
  • Photoreceptor research
  • Evolutionary genomics

Background:

  • Phytochromes regulate key plant processes like germination, growth, development, and flowering in response to red and far-red light.
  • Understanding phytochrome mechanisms is vital for agricultural applications, such as engineering crop light responses.
  • Recent advancements in structural, genomic, and transcriptomic research are enhancing our knowledge of these photoreceptors.

Purpose of the Study:

  • To summarize recent breakthroughs in understanding phytochrome structure and function.
  • To explore the evolutionary history of phytochromes through genomic and transcriptomic analyses.
  • To investigate the role of phytochromes in diverse organisms, including cyanobacteria and algae.

Main Methods:

  • Structural biology techniques to elucidate phytochrome architecture.
  • Genomic and transcriptomic analyses to study phytochrome evolution and diversification.
  • Comparative studies across various species, including algae and cyanobacteria.

Main Results:

  • New insights into the molecular mechanisms of phytochrome action derived from structural studies.
  • Detailed understanding of phytochrome gene loss, retention, and diversification across evolutionary lineages.
  • Emerging data on phytochrome functions in non-plant organisms like cyanobacteria and eukaryotic algae.

Conclusions:

  • Phytochromes are fundamental regulators of plant life with significant potential for crop engineering.
  • Structural and evolutionary research is rapidly advancing our comprehension of phytochrome biology.
  • Phytochrome research is expanding beyond plants to include other photosynthetic organisms.