Frole, K. M. (2008) Drought responses of C3 and C4 (NADP-ME) Panicoid grasses. Masters thesis, Rhodes University.
The success of C[subscript 4] plants lies in their ability to concentrate CO[subscript 2] at the site of Rubisco thereby conferring greater efficiencies of light, water and nitrogen. Such characteristics should advantage C[subscript 4] plants in arid, hot environments. However, not all C[subscript 4] subtypes are drought tolerant. The relative abundance of NADP-ME species declines with increasing aridity. Furthermore, selected species have been demonstrated as being susceptible to severe drought showing metabolic limitations of photosynthesis. However there is a lack of phylogenetic control with many of these studies. The aims of this study were to determine whether the NADP-ME subtype was inherently susceptible to drought by comparing six closely related C[subscript 3] and C[subscript 4] (NADP-ME) Panicoid grasses. Gas exchange measurements were made during a natural rainless period and a controlled drought / rewatering event. Prior to water stress, the C[subscript 4] species had higher assimilation rates (A), and water use efficiencies (WUE[subscript leaf]) than the C[subscript 3] species, while transpiration rates (E) and stomatal conductances (g[subscript s]) were similar. At low soil water content, the C[subscript 3] species reduced gs by a greater extent than the C[subscript 4] species, which maintained higher E during the driest periods. The C[subscript 4] species showed proportionally greater reductions in A than the C[subscript 3] species and hence lost their WUE[subscript leaf] and photosynthetic advantage. CO[subscript 2] response curves showed that metabolic limitation was responsible for a greater decrease in A in the C[subscript 4] type than the C[subscript 3] type during progressive drought. Upon re-watering, photosynthetic recovery was quicker in the C[subscript 3] species than the C[subscript 4] species. Results from whole plant measurements showed that the C[subscript 4] type had a significant whole plant water use efficiency advantage over the C[subscript 3] type under well-watered conditions that was lost during severe drought due to a greater loss of leaf area through leaf mortality rather than reductions in plant level transpiration rates. The C[subscript 3] type had xylem characteristics that enhanced water-conducting efficiency, but made them vulnerable to drought. This is in contrast to the safer xylem qualities of the C[subscript 4] type, which permitted the endurance of more negative leaf water potentials than the C[subscript 3] type during low soil water content. Thus, the vulnerability of photosynthesis to severe drought in NADP-ME species potentially explains why NADP-ME species abundance around the world decreases with decreasing rainfall.
|Item Type:||Thesis (Masters)|
|Uncontrolled Keywords:||C[subscript 3]; C[subscript 4] photosynthesis; drought response; stomatal and metabolic limitations|
|Subjects:||Q Science > QK Botany|
|Divisions:||Faculty > Faculty of Science > Botany|
|Supervisors:||Ripley, B. (Prof.)|
|Deposited By:||Nicolene Mvinjelwa|
|Deposited On:||26 May 2010 12:40|
|Last Modified:||06 Jan 2012 16:21|
134 full-text download(s) in the past 12 months
Repository Staff Only: item control page