Question

Water transport from roots to leaves occurs by __________ a. a pressure gradient inside sieve tubes b. different solutes at source and sink regions c. the pumping force of xylem vessels d. transpiration, tension, and cohesion of water

Short answer

Water transport occurs by transpiration, tension, and cohesion of water.

Step-by-step solution

Understanding the Question

The question is asking about the mechanism by which water is transported from the roots to the leaves in plants. We need to explore concepts related to plant physiology, particularly focusing on water transport mechanisms.

Evaluating Each Option

Let's look at each answer choice: - **Option a**: "a pressure gradient inside sieve tubes" is related to phloem transport, not xylem. - **Option b**: "different solutes at source and sink regions" describes phloem transport (source and sink relate to sugar movement), not water transport by xylem. - **Option c**: "the pumping force of xylem vessels" is incorrect as xylem vessels do not pump; they use passive transport. - **Option d**: "transpiration, tension, and cohesion of water" aligns with the cohesion-tension theory for water movement in xylem.

Selecting the Correct Option

Based on our evaluation, Option d ('transpiration, tension, and cohesion of water') is the correct choice as it describes the cohesion-tension theory. This theory states that water is pulled up the plant through the xylem as water evaporates (transpiration) from the leaves, creating tension that pulls more water from the roots.

Conclusion

The answer to the initial question is Option d: water transport from roots to leaves occurs by the process of transpiration, tension, and cohesion.

Key concepts

Water Transport

In plants, water transport is a crucial process that ensures essential nutrients and minerals are delivered from the roots to the leaves and other parts of the plant. This flow of water is mainly facilitated by the plant's vascular system, specifically through the xylem vessels.
Water uptake begins at the roots, where root hairs absorb it from the soil. From there, water travels upward through the plant, mostly via passive transport methods such as evaporation and capillary action. This system does not require energy input from the plant, unlike active transport mechanisms.

The continuous upward transport of water is primarily driven by a combination of factors:

• Transpiration: The loss of water vapor from the plant leaves creates a negative pressure that pulls water upwards.
• Cohesion and Adhesion: Water molecules stick together (cohesion) and to the walls of xylem vessels (adhesion), facilitating uninterrupted water movement.

Without efficient water transport, plants would struggle to perform photosynthesis and maintain overall cellular function.

Xylem

The xylem is a specialized tissue in vascular plants responsible for the transport of water and some nutrients from the roots to the leaves. Unlike its counterpart, the phloem, which transports organic nutrients like sugars, xylem deals primarily with water movement.

Xylem vessels are composed of dead cells that form long tubes through which water can flow freely. These cells are lined up end to end, forming a continuous column that extends throughout the plant. The walls of xylem vessels are thickened with lignin, providing structural support and preventing collapse under pressure.

Essential functions of xylem include:

• Structural Support: Lignified walls add rigidity to the plant, enabling it to stand upright.
• Water Transport: Facilitates the upward movement of water from the roots.
• Mineral Distribution: Conducts essential minerals absorbed from the soil to various plant parts.

In essence, the xylem is vital for maintaining plant health and facilitating water transport across different plant sections.

Cohesion-Tension Theory

The cohesion-tension theory is a well-accepted explanation of how water moves from the roots to the leaves of plants through the xylem. It describes the mechanism that generates the force needed for water transport, relying on the physical properties of water and plant physiology.

Here's how the theory works:

• Transpiration: Water evaporates from the leaf surfaces, particularly through tiny openings called stomata.
• Tension Creation: This evaporation results in a lower pressure inside the leaves, generating a "tension" that pulls water upward from the roots.
• Cohesion and Adhesion: The cohesive property of water helps form a continuous water column inside the xylem. Meanwhile, adhesion between water molecules and xylem walls aids in sustaining the upward pull.

These principles ensure that even in tall trees, water can be efficiently transported over significant heights. This theory highlights the impressive adaptabilities plant systems have evolved to ensure survival and growth in various environments.