Future Research into C₄ Biology [Editorial]
Date
2016-05
Authors
Taniguchi, Mitsutaka
Weber, Andreas P M
von Caemmerer, Susanne
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Publisher
Oxford University Press
Abstract
The year 2016 marks the 50th anniversary of putting forward
the idea of C₄ photosynthesis (Hatch and Slack 1966). During
the early investigative years, considerable emphasis was placed
on studying the biochemistry of C₄ photosynthesis (Hatch
1999), which revealed how the C₄ photosynthetic pathway
functions as a CO₂ pump to concentrate CO₂ to the Calvin–
Benson cycle. The high CO₂ concentration around ribulose-1, 5-
bisphosphate carboxylase/oxygenase (Rubisco) causes suppression
of the oxygenation reaction of Rubisco, which results in a
lowering of photorespiration. In most C₄ plants, the C₄ cycle is
distributed between two types of photosynthetic cells: the
mesophyll (M) cells and bundle sheath (BS) cells. BS cells surround
the vascular tissues and M cells encircle the cylinders of
the BS cells. Both of these distinct photosynthetic cell types
contain numerous well-developed chloroplasts, and the leaf
anatomy, which is characterized by two concentric rings of
photosynthetic cells surrounding a vascular bundle, is termed
Kranz anatomy. Most of today’s crops are C₃ plants which do
not possess the C₄ pathway. In these crops, photorespiration
decreases the net CO₂ assimilation. Despite recent progress
stimulated by technological innovations in molecular biology,
such as next-generation sequencing, the C₄ Rice Project, which
aims at establishing a C₄ cycle in rice plants, further serves as the
driving force to advance knowledge of C₄ plant biology (von
Caemmerer et al. 2012). In this Special Focus Issue, the current
leading ideas and future prospects of C₄ photosynthetic research
are discussed.
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Source
Plant & cell physiology
Type
Journal article