Abstract
It is believed that transferring the C4 engine into C3 crops will greatly increase the yields of major C3 crops. Many efforts have been made since the 1960s, but relatively little success has been achieved because C4plant traits, referred to collectively as C4 syndrome, are very complex, and little is known about the genetic mechanisms involved. Unfortunately, there exists no ideal genetic model system to study C4 syndrome. It was previously reported that the Haloxylon species have different photosynthetic pathways in different photosynthetic organs, cotyledons and assimilating shoots. Here, we took advantage of the developmental switch from the C3 to the C4 pathway to study the genetic mechanisms behind this natural transition. We compared the transcriptomes of cotyledons and assimilating shoots using mRNA-Seq to gain insight into the molecular and cellular events associated with C4 syndrome. A total of 2959 differentially expressed genes [FDR≤0.001 and abs (|log2(Fold change)|≥1)] were identified, revealing that the transcriptomes of cotyledons and assimilating shoots are considerably different. We further identified a set of putative regulators of C4 syndrome. This study expands our understanding of the development of C4 syndrome and provides a new model system for future studies on the C3-to- C4 switch mechanism.
Highlights
Photosynthetic CO2 fixation is a fundamental life process involving the conversion of solar energy into chemical energy that can be later released to fuel the activity of an organism
The results indicated that F1 hybrids of Atriplex rosea (C4, NAD-malic enzyme (NAD-ME) type) × Atriplex triangularis (C3) were more similar to their C3 parents in physiology and failed to form well-developed Kranz anatomy
Pyankov et al [29] discovered that two Haloxylon species, H. aphyllum and
Summary
Photosynthetic CO2 fixation is a fundamental life process involving the conversion of solar energy into chemical energy that can be later released to fuel the activity of an organism. The ancestral photosynthetic CO2-fixation process is C3 photosynthesis. The first organic product of CO2 fixation is a three-carbon compound. C3 photosynthesis and its key enzyme Rubisco (ribulose-1,5-bisphosphate carboxylase/oxygenase) evolved early in the history of life, when. The Developmental Genetics Mechanism of C4 Syndrome
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