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Interphase00:54

Interphase

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The cell cycle occurs over approximately 24 hours (in a typical human cell) and in two distinct stages: interphase, which includes three phases of the cell cycle (G1, S, and G2), and mitosis (M). During interphase, which takes up about 95 percent of the duration of the eukaryotic cell cycle, cells grow and replicate their DNA in preparation for mitosis.
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Interphase00:56

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The cell cycle occurs over approximately 24 hours (in a typical human cell) and in two distinct stages: interphase, which includes three phases of the cell cycle (G1, S, and G2), and mitosis (M). During interphase, which takes up about 95 percent of the duration of the eukaryotic cell cycle, cells grow and replicate their DNA in preparation for mitosis.
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Following each period of mitosis and cytokinesis, eukaryotic cells enter interphase, during which they grow and replicate...
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Cell Diagrams and IUPAC Conventions01:21

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Electrochemical cell notation is a standardized symbolic representation that communicates the structure and reaction pathway of galvanic and electrolytic cells. This notation plays a critical role in describing redox reactions and electrochemical cell configurations without the need for detailed diagrams.In electrochemical cell notation, a single vertical line “|” denotes a phase boundary, such as between a solid electrode and an aqueous solution. A double vertical line...
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Proteins targeted to the inner chloroplast membrane, or plastid proteins, are transported by two general pathways: the stop-transfer and the re-insertion or post-import pathways. Most plastid proteins carry N-terminal transit sequences and internal import sequences targeting it to the specific chloroplast subcompartment. Proteins targeted by the stop-transfer pathway have internal hydrophobic sequences that inhibit their translocation into the stroma. As a result, these precursors are arrested...
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Updated: May 4, 2026

Analysis of LINE-1 Retrotransposition at the Single Nucleus Level
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Cell intercalation from top to bottom.

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  • 1Graduate Program in Genetics and Department of Zoology, University of Wisconsin-Madison, 250 N Mills Street, Madison, Wisconsin 53706, USA.

Nature Reviews. Molecular Cell Biology
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Summary
This summary is machine-generated.

Cell intercalation is a fundamental process in animal development, involving coordinated cell movements to shape tissues. Recent studies clarify key steps in cell polarization during intercalation, revealing distinct molecular mechanisms.

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Area of Science:

  • Developmental Biology
  • Cell Biology
  • Morphogenesis

Background:

  • Animal body plan formation relies on precise cell movements and fate specification.
  • Cell intercalation, a key morphogenetic process, reshapes tissues by altering cell arrangements.
  • Understanding the molecular mechanisms of cell intercalation is crucial for developmental biology.

Purpose of the Study:

  • To elucidate the critical cellular behaviors and molecular mechanisms underlying cell intercalation.
  • To clarify the distinct steps in cell polarization during both mediolateral and radial intercalation.
  • To identify the interplay of adhesion, cytoskeletal dynamics, and planar cell polarity in driving cell rearrangement.

Main Methods:

  • Analysis of cell behaviors during tissue elongation and spreading.
  • Investigation of cell polarization events in different intercalation contexts.
  • Examination of the roles of cell adhesion, cytoskeletal forces, and planar cell polarity signaling.

Main Results:

  • Key steps in the polarization of mediolaterally and radially intercalating cells have been identified.
  • Cell intercalation requires specific combinations of adhesive changes and cytoskeletal rearrangements.
  • Planar cell polarity signaling regulates intercalation processes in certain contexts.

Conclusions:

  • Cell intercalation employs a conserved set of cellular behaviors with context-specific molecular underpinnings.
  • Distinct mechanisms involving cell adhesion, cytoskeletal dynamics, and planar cell polarity orchestrate tissue shaping.
  • These findings advance our understanding of morphogenesis and developmental processes.