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Related Concept Videos

Cell Diversity01:13

Cell Diversity

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The concept of a cell started with microscopic observations of dead cork tissue by Robert Hooke in 1665. Hooke coined the term "cell" based on the resemblance of the small subdivisions in the cork to the rooms that monks inhabited, called cells. About ten years later, Antonie van Leeuwenhoek became the first person to observe the living and moving cells under a microscope. In the century that followed, the theory that cells represented the basic unit of life developed.
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What are Cells?01:15

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Cells are the smallest and basic units of life, whether it is a single cell that forms the entire organism, e.g., in a bacterium, or trillions of them, e.g., in humans. No matter what organism a cell is a part of, they share specific characteristics.
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What are Cells?01:07

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Cells are the smallest and basic units of life, whether it is a single cell that forms the entire organism, e.g., in a bacterium or trillions of them, e.g., in humans. No matter what organism a cell is a part of, they share specific characteristics.
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Structural Organization of the Human Body: An Overview01:18

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It is convenient to consider the body's structures in terms of fundamental levels of organization that increase in complexity: subatomic particles, atoms, molecules, organelles, cells, tissues, organs, organ systems, and organisms.
To study the chemical level of organization, scientists consider the simplest building blocks of matter: subatomic particles, atoms, and molecules. All matter in the universe is composed of one or more unique pure substances called elements, familiar examples of...
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Cellular Differentiation00:57

Cellular Differentiation

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How does a complex organism such as a human develop from a single cell? It all starts from a single fertilized egg which gives rise to a vast array of cell types, such as nerve cells, muscle cells, and epithelial cells that characterize the adult? Throughout development and adulthood, cellular differentiation leads cells to assume their final morphology and physiology. Differentiation is the process by which unspecialized cells become specialized to carry out distinct functions.
A zygote is a...
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Prokaryotic vs. Eukaryotic Cells01:28

Prokaryotic vs. Eukaryotic Cells

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Prokaryotic and eukaryotic cells represent two fundamental types of cellular organization, differing significantly in structure, complexity, and function. These distinctions underpin the biological diversity seen across domains of life.Prokaryotic Cell CharacteristicsProkaryotic cells, exemplified by bacteria and archaea, are structurally simple and lack membrane-bound organelles, including a nucleus. Their genetic material consists of a single, circular DNA molecule in the nucleoid region,...
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Updated: Oct 31, 2025

Cell-cell Fusion of Genome Edited Cell Lines for Perturbation of Cellular Structure and Function
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Cell-cell Fusion of Genome Edited Cell Lines for Perturbation of Cellular Structure and Function

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Pars Pro Toto: Every Single Cell Matters.

Fien Christiaens1,2, Balkan Canher1,2, Fien Lanssens1,2

  • 1Department of Plant Biotechnology and Bioinformatics, Ghent University, Ghent, Belgium.

Frontiers in Plant Science
|July 1, 2021
PubMed
Summary
This summary is machine-generated.

Plants possess remarkable self-repair abilities, regenerating damaged cells and tissues. This review explores plant regeneration mechanisms, molecular players, and agricultural applications.

Keywords:
calluscropsregenerationsingle cellwounding

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Area of Science:

  • Plant biology
  • Developmental biology
  • Regenerative medicine

Background:

  • Plants exhibit exceptional self-repair capacities, unlike most other species.
  • Damage response and regeneration vary based on the extent of injury and affected organ.
  • Recent research highlights diverse tissue damage responses initiating plant regeneration.

Purpose of the Study:

  • To review plant regeneration following single-cell to whole-organ loss.
  • To emphasize key molecular players and hormonal cues in *Arabidopsis thaliana* regeneration.
  • To highlight agricultural applications of plant regenerative responses in crops and trees.

Main Methods:

  • Literature review of recent publications on plant regeneration.
  • Focus on molecular and hormonal mechanisms.
  • Inclusion of case studies on *Arabidopsis thaliana* and crop species.

Main Results:

  • Regeneration processes differ based on damage type and scale.
  • Specific molecular players and hormonal signals orchestrate regeneration.
  • Understanding regeneration informs agricultural practices.

Conclusions:

  • Plant regeneration is a complex process influenced by damage context.
  • Key molecular and hormonal factors are crucial for successful regeneration.
  • Harnessing plant regeneration offers significant agricultural potential for crop improvement and propagation.