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Light Acquisition02:16

Light Acquisition

In order to produce glucose, plants need to capture sufficient light energy. Many modern plants have evolved leaves specialized for light acquisition. Leaves can be only millimeters in width or tens of meters wide, depending on the environment. Due to competition for sunlight, evolution has driven the evolution of increasingly larger leaves and taller plants, to avoid shading by their neighbors with contaminant elaboration of root architecture and mechanisms to transport water and nutrients.
Adaptations that Reduce Water Loss01:57

Adaptations that Reduce Water Loss

Though evaporation from plant leaves drives transpiration, it also results in loss of water. Because water is critical for photosynthetic reactions and other cellular processes, evolutionary pressures on plants in different environments have driven the acquisition of adaptations that reduce water loss.
Basic Plant Anatomy: Roots, Stems, and Leaves02:27

Basic Plant Anatomy: Roots, Stems, and Leaves

The primary organs of vascular plants are roots, stems, and leaves, but these structures can be highly variable, adapted for the specific needs and environment of different plant species.
Regulation of Transpiration by Stomata02:04

Regulation of Transpiration by Stomata

During photosynthesis, plants acquire the necessary carbon dioxide and release the produced oxygen back into the atmosphere. Openings in the epidermis of plant leaves is the site of this exchange of gasses. A single opening is called a stoma—derived from the Greek word for “mouth.” Stomata open and close in response to a variety of environmental cues.
Plant Tissues01:18

Plant Tissues

Plants are multicellular eukaryotes with tissue systems made of various cell types that carry out specific functions. Different tissues work together to perform a unique function and form an organ. Organs working together form organ systems. Vascular plants have two distinct organ systems: a shoot system and a root system. The shoot system consists of two portions: the vegetative (non-reproductive) parts of the plant, such as the leaves and the stems, and the reproductive parts of the plant,...
Primary and Secondary Growth in Roots and Shoots03:02

Primary and Secondary Growth in Roots and Shoots

Vascular plants, which account for over 90% of the Earth’s vegetation, all undergo primary growth—which lengthens roots and shoots. Many land plants, notably woody plants, also undergo secondary growth—which thickens roots and shoots.

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Related Experiment Video

Updated: May 27, 2026

Relating Stomatal Conductance to Leaf Functional Traits
11:09

Relating Stomatal Conductance to Leaf Functional Traits

Published on: October 12, 2015

Making leaves.

Mary E Byrne1

  • 1School of Biological Sciences, The University of Sydney 2006, New South Wales, Australia. mary.byrne@sydney.edu.au

Current Opinion in Plant Biology
|November 15, 2011
PubMed
Summary

Plant leaves develop from the shoot apical meristem through complex genetic regulation. Understanding these gene networks reveals how diverse leaf shapes evolve.

Area of Science:

  • Plant developmental biology
  • Genetics
  • Evolutionary biology

Background:

  • Leaves originate from the shoot apical meristem (SAM) via founder cell recruitment and axis establishment.
  • Balancing cell fate between pluripotency and differentiation is crucial for SAM maintenance and leaf production.
  • Hormonal signaling, alongside intrinsic and extrinsic factors, regulates SAM function and leaf initiation.

Purpose of the Study:

  • To explore the genetic basis of leaf development and shape variation.
  • To understand how conserved regulatory modules contribute to diverse leaf forms across species.
  • To investigate the role of gene networks in generating leaf complexity.

Main Methods:

  • Analysis of gene networks controlling leaf development and shape.

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Measurement of Leaf Hydraulic Conductance and Stomatal Conductance and Their Responses to Irradiance and Dehydration Using the Evaporative Flux Method (EFM)
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Measurement of Leaf Hydraulic Conductance and Stomatal Conductance and Their Responses to Irradiance and Dehydration Using the Evaporative Flux Method (EFM)

Published on: December 31, 2012

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Last Updated: May 27, 2026

Relating Stomatal Conductance to Leaf Functional Traits
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Published on: October 12, 2015

Reconstructing Terrestrial Paleoclimate and Paleoecology with Fossil Leaves Using Digital Leaf Physiognomy and Leaf Mass Per Area
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Reconstructing Terrestrial Paleoclimate and Paleoecology with Fossil Leaves Using Digital Leaf Physiognomy and Leaf Mass Per Area

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Measurement of Leaf Hydraulic Conductance and Stomatal Conductance and Their Responses to Irradiance and Dehydration Using the Evaporative Flux Method (EFM)
12:11

Measurement of Leaf Hydraulic Conductance and Stomatal Conductance and Their Responses to Irradiance and Dehydration Using the Evaporative Flux Method (EFM)

Published on: December 31, 2012

  • Comparative studies across species to identify interspecies differences in these networks.
  • Investigating the role of conserved regulatory modules in boundary establishment and growth zones.
  • Main Results:

    • Genes involved in initial leaf development within the SAM also regulate complex leaf shaping.
    • Common regulatory modules are fundamental for establishing boundaries and discrete growth zones.
    • Defining these gene networks provides insight into the genetic underpinnings of natural variation in leaf form.

    Conclusions:

    • Leaf development and shaping share common genetic regulatory modules.
    • Understanding these networks offers insights into the evolution of plant morphology.
    • Comparative genomics of leaf development pathways illuminates natural variation in leaf form.