Abstract
Rubisco limits photosynthetic CO(2) fixation because of its low catalytic turnover rate (k(cat)) and competing oxygenase reaction. Previous attempts to improve the catalytic efficiency of Rubisco by genetic engineering have gained little progress. Here we demonstrate that the introduction of the small subunit (RbcS) of high k(cat) Rubisco from the C(4) plant sorghum (Sorghum bicolor) significantly enhances k(cat) of Rubisco in transgenic rice (Oryza sativa). Three independent transgenic lines expressed sorghum RbcS at a high level, accounting for 30%, 44%, and 79% of the total RbcS. Rubisco was likely present as a chimera of sorghum and rice RbcS, and showed 1.32- to 1.50-fold higher k(cat) than in nontransgenic rice. Rubisco from transgenic lines showed a higher K(m) for CO(2) and slightly lower specificity for CO(2) than nontransgenic controls. These results suggest that Rubisco in rice transformed with sorghum RbcS partially acquires the catalytic properties of sorghum Rubisco. Rubisco content in transgenic lines was significantly increased over wild-type levels but Rubisco activation was slightly decreased. The expression of sorghum RbcS did not affect CO(2) assimilation rates under a range of CO(2) partial pressures. The J(max)/V(cmax) ratio was significantly lower in transgenic line compared to the nontransgenic plants. These observations suggest that the capacity of electron transport is not sufficient to support the increased Rubisco capacity in transgenic rice. Although the photosynthetic rate was not enhanced, the strategy presented here opens the way to engineering Rubisco for improvement of photosynthesis and productivity in the future.
Highlights
Rubisco limits photosynthetic CO2 fixation because of its low catalytic turnover rate and competing oxygenase reaction
Our results clearly show that the introduction of sorghum RbcS increases the kcat of Rubisco in rice, suggesting that RbcS could be an important determinant of the kinetic properties of Rubisco and a useful target for genetic engineering to improve photosynthesis
This study shows that the chimeric incorporation of sorghum RbcS significantly increases the kcat of Rubisco in transgenic rice (Table I)
Summary
Rubisco limits photosynthetic CO2 fixation because of its low catalytic turnover rate (kcat) and competing oxygenase reaction. Many agriculturally important crops, including cereals such as rice (Oryza sativa) and most woody perennials, are classified as C3 plants Their photosynthetic rate at present atmospheric CO2 level is limited by the activity of Rubisco because of its extremely low catalytic turnover rate (kcat) and competing oxygenase reaction, which initiates wasteful photorespiration (von Caemmerer and Quick, 2000; Parry et al, 2003). To compensate for these detrimental enzymatic properties, C3 plants invest 15% to 35% of total leaf nitrogen in this single enzyme (Evans, 1989; Makino et al, 1992). Our results clearly show that the introduction of sorghum RbcS increases the kcat of Rubisco in rice, suggesting that RbcS could be an important determinant of the kinetic properties of Rubisco and a useful target for genetic engineering to improve photosynthesis
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