Advancing Our Understanding and Capacity to Engineer Nature’s CO2-Sequestering Enzyme, Rubisco

Whitney, Spencer M.; Houtz, Robert L.; Alonso, Hernán

doi:10.1104/pp.110.164814

Cited by 398 publications

(380 citation statements)

References 52 publications

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“…36 and 37), the link between Rubisco molecular structure, aggregation, and pyrenoid function had not previously been proven. In evolutionary terms, there is an inverse relationship between Rubisco specificity and the activity of a CCM in cyanobacteria, chlorophyte algae, and higher plants (38). C 3 plants, and green algae without a CCM (39) or reliant on CO 2 diffusion, have a Rubisco with high specificity for CO 2 (Ω ∼ 80-100).…”

Section: Discussionmentioning

confidence: 99%

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Meyer

Genkov

Skepper

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

110

118

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The pyrenoid is a subcellular microcompartment in which algae sequester the primary carboxylase, ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco). The pyrenoid is associated with a CO 2 -concentrating mechanism (CCM), which improves the operating efficiency of carbon assimilation and overcomes diffusive limitations in aquatic photosynthesis. Using the model alga Chlamydomonas reinhardtii, we show that pyrenoid formation, Rubisco aggregation, and CCM activity relate to discrete regions of the Rubisco small subunit (SSU). Specifically, pyrenoid occurrence was shown to be conditioned by the amino acid composition of two surface-exposed α-helices of the SSU: higher plant-like helices knock out the pyrenoid, whereas native algal helices establish a pyrenoid. We have also established that pyrenoid integrity was essential for the operation of an active CCM. With the algal CCM being functionally analogous to the terrestrial C 4 pathway in higher plants, such insights may offer a route toward transforming algal and higher plant productivity for the future.algal photosynthesis | carbon fixation | chloroplast | protein engineering

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Section: Discussionmentioning

confidence: 99%

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Meyer

Genkov

Skepper

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

110

118

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“…Many attempts to improve photosynthetic efficiency by engineering Rubisco have gained little progress (Andrews and Whitney, 2003;Whitney et al, 2011). Most of these efforts were focused on altering the CO 2 /O 2 specificity of Rubisco to suppress photorespiration.…”

mentioning

confidence: 99%

Functional Incorporation of Sorghum Small Subunit Increases the Catalytic Turnover Rate of Rubisco in Transgenic Rice

et al. 2011

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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.

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“…These approaches include elevating the CO 2 concentration within chloroplasts using recombinant CO 2 /HCO 3 − transporters from cyanobacteria or engineering alternative pathways to bypass photorespiration and release CO 2 within the stroma (13,14). Although each strategy faces continuous challenges in its fine tuning and integration into crops, further improvements in yield and in the efficiency of water and nitrogen use are likely by concurrently "speeding up" rubisco (9).…”

mentioning

confidence: 99%

Isoleucine 309 acts as a C ₄ catalytic switch that increases ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) carboxylation rate in Flaveria

Whitney

Sharwood

Orr

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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132

138

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Improving global yields of important agricultural crops is a complex challenge. Enhancing yield and resource use by engineering improvements to photosynthetic carbon assimilation is one potential solution. During the last 40 million years C 4 photosynthesis has evolved multiple times, enabling plants to evade the catalytic inadequacies of the CO 2 -fixing enzyme, ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco). Compared with their C 3 ancestors, C 4 plants combine a faster rubisco with a biochemical CO 2 -concentrating mechanism, enabling more efficient use of water and nitrogen and enhanced yield. Here we show the versatility of plastome manipulation in tobacco for identifying sequences in C 4 -rubisco that can be transplanted into C 3 -rubisco to improve carboxylation rate (V C ). Using transplastomic tobacco lines expressing native and mutated rubisco large subunits (L-subunits) from Flaveria pringlei (C 3 ), Flaveria floridana (C 3 -C 4 ), and Flaveria bidentis (C 4 ), we reveal that Met-309-Ile substitutions in the L-subunit act as a catalytic switch between C 4 ( 309 Ile; faster V C , lower CO 2 affinity) and C 3 ( 309 Met; slower V C , higher CO 2 affinity) catalysis. Application of this transplastomic system permits further identification of other structural solutions selected by nature that can increase rubisco V C in C 3 crops. Coengineering a catalytically faster C 3 rubisco and a CO 2 -concentrating mechanism within C 3 crop species could enhance their efficiency in resource use and yield.CO 2 assimilation | rbcL mutagenesis | gas exchange | chloroplast transformation T he future uncertainties of global climate change and estimates of unsustainable population growth have increased the urgency of improving crop yields (1). One possible solution is to "supercharge" photosynthesis by improving the C 3 cycle (2, 3). Although a simple idea, this is a complex challenge that involves several possible alternatives. Many of these alternatives focus on enhancing the performance of the CO 2 -fixing enzyme ribulose-1,5-bisphosphate (RuBP) carboxylase/oxygenase (rubisco), which catalyses the first step in the synthesis of carbohydrates. Despite its pivotal role, rubisco is a slow catalyst, completing only one to four carboxylation reactions per catalytic site per second in plants (4, 5). Moreover CO 2 not only is fixed through a complex catalytic process but also must compete with O 2 . The oxygenation of RuBP produces 2-phosphoglycolate, whose recycling by photorespiration requires energy and results in the futile loss of fixed carbon [∼30% of fixed CO 2 in many C 3 plants (6)].To compensate for rubisco's catalytic limitations, plants invest as much as 25% of their leaf nitrogen in rubisco (7). This value is much lower in C 4 plants, where a biochemical CO 2 -concentrating mechanism (CCM) elevates CO 2 around rubisco. This optimized microenvironment allows rubisco to operate close to its maximal activity, reducing O 2 competition. This CCM has enabled C 4 plants to evolve rubiscos with substantially im...

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Advancing Our Understanding and Capacity to Engineer Nature’s CO2-Sequestering Enzyme, Rubisco

Cited by 398 publications

References 52 publications

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Functional Incorporation of Sorghum Small Subunit Increases the Catalytic Turnover Rate of Rubisco in Transgenic Rice

Isoleucine 309 acts as a C ₄ catalytic switch that increases ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) carboxylation rate in Flaveria

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Advancing Our Understanding and Capacity to Engineer Nature’s CO2-Sequestering Enzyme, Rubisco

Cited by 398 publications

References 52 publications

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Rubisco small-subunit α-helices control pyrenoid formation inChlamydomonas

Functional Incorporation of Sorghum Small Subunit Increases the Catalytic Turnover Rate of Rubisco in Transgenic Rice

Isoleucine 309 acts as a C 4 catalytic switch that increases ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) carboxylation rate in Flaveria

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Isoleucine 309 acts as a C ₄ catalytic switch that increases ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) carboxylation rate in Flaveria