Textbook Question
You have isolated a motile, gram-positive cell with no visible nucleus. You can assume this cell has
a. Ribosomes.
b. Mitochondria.
c. An endoplasmic reticulum.
d. A Golgi complex.
e. All of the above
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Ch. 4 - Functional Anatomy of Prokaryotic and Eukaryotic Cells
Tortora14th EditionMicrobiology: An IntroductionISBN: 9780138200398
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Table of contents
- Ch. 1 - The Microbial World and You18
- Ch. 2 - Chemical Principles20
- Ch. 3 - Observing Microorganisms Through a Microscope18
- Ch. 4 - Functional Anatomy of Prokaryotic and Eukaryotic Cells21
- Ch. 5 - Microbial Metabolism20
- Ch. 6 - Microbial Growth20
- Ch. 7 - The Control of Microbial Growth20
- Ch. 8 - Microbial Genetics19
- Ch. 9 - Biotechnology & DNA Technology20
- Ch. 10 - Classification of Microorganisms15
- Ch. 11 - The Prokaryotes: Domains Bacteria and Archaea14
- Ch. 12 - The Eukaryotes: Fungi, Algae, Protozoa, and Helminths17
- Ch. 13 - Viruses, Viroids, and Prions20
- Ch. 14 - Principles of Disease and Epidemiology21
- Ch. 15 - Microbial Mechanisms of Pathogenicity19
- Ch. 16 - Innate Immunity: Nonspecific Defenses of the Host20
- Ch. 17 - Adaptive Immunity: Specific Defenses of the Host20
- Ch. 18 - Practical Applications of Immunology20
- Ch. 19 - Disorders Associated with the Immune System19
- Ch. 20 - Antimicrobial Drugs19
- Ch. 21 - Microbial Diseases of the Skin and Eyes21
- Ch. 22 - Microbial Diseases of the Nervous System19
- Ch. 23 - Microbial Diseases of the Cardiovascular and Lymphatic Systems20
- Ch. 24 - Microbial Diseases of the Respiratory System20
- Ch. 25 - Microbial Diseases of the Digestive System20
- Ch. 26 - Microbial Diseases of the Urinary and Reproductive Systems19
- Ch. 27 - Environmental Microbiology20
- Ch. 28 - Applied and Industrial Microbiology19
Tortora14th EditionMicrobiology: An IntroductionISBN: 9780138200398Not the one you use?Change textbook
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Tortora 14th EditionCh. 4 - Functional Anatomy of Prokaryotic and Eukaryotic CellsProblem 8
Tortora 14th EditionCh. 4 - Functional Anatomy of Prokaryotic and Eukaryotic CellsProblem 8Chapter 4, Problem 8
Starch is readily metabolized by many cells, but a starch molecule is too large to cross the plasma membrane. How does a cell obtain the glucose molecules from a starch polymer? How does the cell transport these glucose molecules across the plasma membrane?
Verified step by step guidance1
Understand that starch is a polysaccharide composed of many glucose units linked together, making it too large to pass through the plasma membrane directly.
Recognize that cells secrete enzymes called amylases which break down starch into smaller sugar units such as maltose and glucose outside the cell.
Identify that the enzymatic hydrolysis of starch involves breaking the glycosidic bonds, converting the polymer into smaller, transportable molecules like glucose.
Learn that once starch is broken down into glucose molecules, these smaller sugars can be transported across the plasma membrane using specific transport proteins such as glucose transporters.
Note that glucose transport across the membrane can occur via facilitated diffusion or active transport, depending on the cell type and environmental conditions.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Extracellular Enzymatic Breakdown of Starch
Cells secrete enzymes called amylases that break down large starch polymers into smaller glucose units outside the cell. This extracellular digestion is necessary because starch molecules are too large to pass through the plasma membrane directly.
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Formation & Breakdown of Polysaccharides
Glucose Transport Across the Plasma Membrane
Once starch is broken down into glucose, cells transport glucose molecules across the plasma membrane using specific transport proteins, such as facilitated diffusion carriers or active transporters, depending on the cell type and glucose concentration.
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02:47Introduction to Membrane Transport
Selective Permeability of the Plasma Membrane
The plasma membrane is selectively permeable, allowing only certain molecules to pass through. Large molecules like starch cannot cross, so cells rely on enzymatic breakdown and transport proteins to import smaller, usable nutrients like glucose.
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Related Practice
Textbook Question
Answer the following questions using the diagrams provided, which represent cross sections of bacterial cell walls.
a. Which diagram represents a gram-positive bacterium? How can you tell?
b. Explain how the Gram stain works to distinguish these two types of cell walls.
c. Why does penicillin have no effect on most gram-negative cells?
d. How do essential molecules enter cells through each wall?
e. Which cell wall is toxic to humans?
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Textbook Question
The antibiotic amphotericin B disrupts plasma membranes by combining with sterols; it will affect all of the following cells except
a. Animal cells.
b. Gram-negative bacterial cells.
c. Fungal cells.
d. Mycoplasma cells.
e. Plant cells.
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Textbook Question
Match the characteristics of eukaryotic cells in column A with their functions in column B.
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Textbook Question
Which of the following pairs is mismatched?
a. Metachromatic granules—stored phosphates
b. Polysaccharide granules—stored starch
c. Lipid inclusions—poly-β-hydroxybutyric acid
d. Sulfur granules—energy reserve
e. Ribosomes—protein storage
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Textbook Question
Which of the following pairs is mismatched?
a. Glycocalyx—adherence
b. Pili—reproduction
c. Cell wall—toxin
d. Cell wall—protection
e. Plasma membrane—transport
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