[Seminar] The genus Neurachne: Key to Understanding the Evolution of C4 Photosynthesis
Prof. Martha Ludwig
When |
06 Jun, 2023
from
12:00 pm to 01:00 pm |
---|---|
Where | ITQB NOVA Auditorium |
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Title: The genus Neurachne: Key to Understanding the Evolution of C4 Photosynthesis
Speaker: Prof Martha Ludwig (School of Molecular Sciences, University Western Australia)
Abstract: The Australian grass tribe Neurachninae is the only known monocot group with distinct, closely related species using C3, C4 or C2 photosynthesis. C2 photosynthesis is recognised as the evolutionary bridge from the ancestral C3 pathway to the more derived C4 pathway. To gain insights into the evolution of C4 photosynthesis in the monocots, we examined gas exchange, leaf anatomy and cellular location of glycine decarboxylase subunit P (GDC-P) in Neurachne species previously described as C3 (N. alopecuroidea, N. annularis, N. lanigera), C2 (N. minor), and C4 (N. munroi, N. muelleri). Our results demonstrate that progressive changes occurred in organelle numbers and GDC-P location as C2 metabolism became engaged in the Neurachne, with scavenging of photorespiratory CO2 within a vascular sheath tissue being a critical early stage in the evolution of the C4 pathway.
An important enzyme in the CO2 concentrating mechanism of C4 plants is carbonic anhydrase (CA), which catalyses the first reaction in the C4 pathway. We have used the photosynthetic diversity in the Neurachne to identify the C4-associated CA and the sequence changes in the C3 orthologue that enabled the evolution of the C4 form of the enzyme. Different splice variants of the ca1 gene encode the C4-associated CA in the two C4 Neurachne species, supporting phylogenetic information for two independent C4 origins in the genus. Remarkably, the evolutionary mechanism used by one of the C4 species is homoplastic with the evolution of the C4-associated CA in a dicot genus, suggesting that there may be molecular limitations / constraints on the evolutionary path to C4.