Objective:
Study the anatomical features of plants that are involved in photosynthesis.
Tissue which is composed of parenchyma cells containing abundant chloroplasts is called chlorenchyma. Chlorenchyma is typically located in leaves and primary stems and is the primary light harvesting tissue of plants. Analysis of photosynthesis reveals that tissues performing this function must: a) Intercept adequate light energy to drive the light reaction, b) have an adequate supply of water for donation of electrons to the Z scheme, c) have an adequate supply of CO2 to complete the dark reaction, d) export fixed carbon to the phloem for translocation to carbon sinks within the plant. In addition to these fundamental requirements for photosynthesis, various plants have evolved different photosynthetic mechanisms which make inhabitation of arid environments possible.
I. C3 Photosynthesis
A. Compare transverse sections of Populus (5.18), Triticum or Poa (9.02) and Pinus (3.09,3.095) leaves. Pay particular attention to: a) The geometry of the outermost cell walls of epidermal cells. Could these act as lenses to focus light to the interior of the leaf? b) The relative location of xylem and chlorenchyma tissue. Keep in mind that suberized, lignified and cutinized cell walls are relatively impervious to water. c) The relative location of stomata and chlorenchyma. What role does intercellular air space play here? Are the chloroplasts optimally located for CO2 uptake? H2O uptake? light inception? How would your answers change if chlorenchyma cells had parietal vacuoles and centralized cytoplasm? d) Relative location of phloem and chlorenchyma. Visualize the general pathway that fixed carbon must take in these various plant species. Are there intervening non-photosynthetic cells in this pathway? Apply terms such as spongy and palisade mesophyll, transfusion tissue, endodermis where appropriate. Record your observations in the lab exercise sheet.
B. Many plant species exhibit the ability to regulate the characteristics of their photosynthetic systems in response to the intensity of light to which their developing leaves are exposed. Compare transverse sections of sun and shade leaves of Lactuca (9.04), Acer (9.05) and Quercus (9.06). What general inferences can be made about the effects of light intensity on the differentiation of the photosynthetic system? Record your observations in the lab exercise sheet.
II. C4 Photosynthesis
Many species of plants have evolved C4 photosynthesis in which the oxygen sensitive ribulose bisphosphate carboxylase (RUBPCase) is spatially separated from oxygen insensitive phosphoenolpyruvate carboxylase (PEPCase). C4 plants typically, but not absolutely, exhibit Kranz leaf anatomy in which leaf veins are surrounded by bundle sheath cells, characterized by the presence of thick cell walls, numerous chloroplasts which may be agranal, accumulated starch grains, in which RUPBCase and other enzymes are localized. The bundle sheath cells are in turn surrounded by mesophyll cells which resemble chlorenchyma of C3 plants with numerous granal plastids in which high concentrations of PEPCase and other enzymes are found. C4 photosynthesis appears to be more efficient than C3 photosynthesis under conditions of high temperatures and light intensity.
A. Study transverse
sections of Zea mays (3.07) and
Bouteloua (9.08) leaves. Identify the typical features of
Kranz leaf anatomy in these C4 species. Record
your observations in the lab exercise sheet.
Material
Prepared Slides Fresh
Populus
(5.18)
Crassula argenta
Triticum or Poa
(9.02)
(some stems covered
Pinus
(3.09,3.095)
with aluminum foil
for 3 days)
Lactuca (9.04)
Acer (9.05)
Quercus (9.06)
Zea (3.07)
Bouteloua (9.08)