1.1.3 Cell Specialization

    Cards (48)

    • Cell specialization is crucial for multicellular organisms to carry out complex life processes.

      True
    • Cell specialization is the process by which cells develop specific structures and functions to perform tasks more effectively
    • Red blood cells carry oxygen and are adapted with no nucleus
    • The myelin sheath in nerve cells increases the speed of signal transmission.

      True
    • Cell specialization is crucial for multicellular organisms to carry out complex life processes
    • Red blood cells have a disc shape to maximize oxygen absorption.

      True
    • Cell specialization leads to a division of labor
    • What is the outcome of cell specialization in multicellular organisms?
      Efficient task execution
    • Cell specialization allows multicellular organisms to perform complex processes.

      True
    • Sperm cells have a flagellum for movement
    • Which specialized cells secrete hormones or enzymes?
      Gland cells
    • The myelin sheath in nerve cells increases the speed of signal transmission.

      True
    • Each specialized cell type has a unique structure and function
    • What is the key adaptation of nerve cells for transmitting electrical signals efficiently?
      Myelin sheath
    • Why is the division of labor among specialized cells important in multicellular organisms?
      Increased efficiency
    • Match the specialized cell type with its key adaptation:
      Nerve Cells ↔️ Myelin sheath
      Muscle Cells ↔️ Mitochondria
      Red Blood Cells ↔️ No nucleus
    • Cell specialization allows complex organs to work together seamlessly
    • What is the role of the myelin sheath in nerve cells?
      Transmit signals
    • What is the key adaptation of red blood cells for carrying oxygen?
      Disc shape
    • What are tight junctions in epithelial cells adapted for?
      Form protective barriers
    • The myelin sheath in nerve cells increases signal transmission
    • Specialization enables complex organs to work together seamlessly in multicellular organisms.

      True
    • Muscle cells use muscle fibers and mitochondria to produce movement
    • Match the real-world application with its example:
      Medicine ↔️ Cell-based therapies
      Agriculture ↔️ Crop improvement
      Biotechnology ↔️ Biomanufacturing
      Food Industry ↔️ Lab-grown meat
    • What is the process by which cells develop specific structures and functions to perform tasks more effectively?
      Cell specialization
    • Name an example of a specialized cell in the human body.
      Nerve cell
    • Nerve cells transmit electrical signals using long fibers and a myelin sheath.
      True
    • What is the role of cell specialization in multicellular organisms?
      Efficient task performance
    • What provides energy for muscle cell contraction?
      Mitochondria
    • Why does cell specialization increase efficiency in multicellular organisms?
      Cells perform specific tasks
    • Cell specialization enables complex organs to function together seamlessly.
      True
    • Each cell type in multicellular organisms has a unique structure and function
    • What are three key reasons why cell specialization is important in multicellular organisms?
      Increased efficiency, division of labor, complex organ function
    • Epithelial cells form protective barriers using tight junctions.

      True
    • Cell specialization determines cell structure and function
    • Why do red blood cells have a biconcave shape?
      Maximize oxygen absorption
    • Cell specialization reduces the burden on any single cell in multicellular organisms.

      True
    • Red blood cells have a disc shape and no nucleus to carry more oxygen.

      True
    • Cell specialization allows multicellular organisms to function more effectively due to increased efficiency and division of labor.

      True
    • Why is cell specialization important in multicellular organisms?
      Increased efficiency
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