34.12
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Q1: What are the three main pathways plants use to transport resources between cells?
Plants transport solutes through three pathways: the apoplastic pathway moves substances through extracellular spaces and cell walls, the symplastic pathway transports materials through plasmodesmata that connect neighboring cell cytoplasm, and the transmembrane pathway moves substances across the plasma membrane. Each pathway serves different transport needs depending on distance and substance type.
Q2: How do plants move ions and large molecules across cell membranes?
Ions and large molecules cannot diffuse passively across the plasma membrane due to their charge or size. Instead, cells use specific membrane proteins like ion channels and transporter proteins to actively move these solutes. Proton pumps use ATP energy to create an electrochemical gradient that powers many transporters, such as nitrate transporters that move nutrients against their concentration gradient.
Q3: Why is transmembrane transport effective only over short distances?
Repeatedly moving substances across the plasma membrane through transmembrane transport is sufficiently fast over 2 or 3 cells but becomes much slower over longer distances. This limitation occurs because each crossing requires energy and specific transport proteins, making the process inefficient for transporting resources across many cells. Longer-distance transport requires different mechanisms like xylem and phloem.
Q4: What role does the central vacuole play in short-distance transport?
The central vacuole stores resources and regulates turgor pressure through active and passive transport across the tonoplast membrane. Transport proteins in the tonoplast control movement of solutes, ions, and protons into the vacuole, creating an acidic environment for breaking down unwanted substances. Water moves passively across the tonoplast through aquaporins, water channels that respond to cellular signals and regulate vacuole size.
Q5: How does turgor pressure affect plant structure and drought response?
Turgor pressure is generated when the vacuole pushes the plasma membrane against the cell wall, contributing to plant rigidity and structure. During drought, water loss causes the vacuole to shrink, reducing turgor pressure in individual cells. On a macroscopic level, plants appear wilted when turgor pressure drops, as cells lose their structural support and the plant loses rigidity.
Q6: Which small molecules can diffuse passively across the plasma membrane without transport proteins?
Small uncharged molecules such as oxygen, carbon dioxide, and water can diffuse passively across the plasma membrane, moving along their concentration gradients from high to low concentration. This passive diffusion does not require energy or transport proteins. In contrast, charged ions and larger molecules like sugars cannot cross the membrane without assistance from specific transport proteins.
Q7: How do proton pumps enable nutrient uptake in plant roots?
Proton pumps use chemical energy from ATP to create an electrochemical gradient of hydrogen ions across the cell membrane. Many plant transporters harness this hydrogen gradient to move resources into cells. For example, the nitrate transporter in roots moves one nitrate ion along with one hydrogen ion, allowing nutrient uptake even against the nitrate concentration gradient.
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