The delta(13)C values of several seagrasses were considerably less negative than those of terrestrial C(3) plants and tended toward those of terrestrial C(4) plants. However, for Thalassia hemprichii (Ehrenb.) Aschers and Halophila spinulosa (R. Br.) Aschers, phosphoglycerate and other C(3) cycle intermediates predominated among the early labeled products of photosynthesis in (14)C-labeled seawater (more than 90% at the earliest times) and the labeling pattern at longer times was brought about by the operation of the C(3) pathway. Malate and aspartate together accounted for only a minor fraction of the total fixed label at all times and the kinetic data of this labeling were not at all consistent with these compounds being early intermediates in seagrass photosynthesis. Pulse-chase (14)C-labeling studies further substantiated these conclusions. Significant labeling of photorespiratory intermediates was observed in all experiments. The kinetics of total fixation of label during some steady-state and pulse-chase experiments suggested that there may be an intermediate pool of inorganic carbon of variable size closely associated with the leaves, either externally or internally. Such a pool may be one cause for the C(4)-like carbon isotope ratios of seagrasses.
The efficiency with which crop plants use their resources of light, water, and fertilizer nitrogen could be enhanced by replacing their CO 2 -fixing enzyme, d -ribulose-1,5-bisphosphate carboxylase-oxygenase (RubisCO), with more efficient forms, such as those found in some algae, for example. This important challenge has been frustrated by failure of all previous attempts to substitute a fully functional, foreign RubisCO (efficient or inefficient) into higher plants. This failure could be caused by incompatibility between the plastid-encoded large subunits and the nucleus-encoded small subunits or by inability of the foreign RubisCO subunits to fold or assemble efficiently in the plastid. Mismatch between the regulatory requirements of the foreign RubisCO and conditions in the chloroplast also might render the substituted enzyme inactive but, previously, it has not been possible to test this. To answer the general question of whether a foreign RubisCO can support photosynthesis in a plant, we used plastid transformation to replace RubisCO in tobacco with the simple homodimeric form of the enzyme from the α-proteobacterium, Rhodospirillum rubrum , which has no small subunits and no special assembly requirements. The transplastomic plants so obtained are fully autotrophic and reproductive but require CO 2 supplementation, consistent with the kinetic properties of the bacterial RubisCO. This establishes that the activity of a RubisCO from a very different phylogeny can be integrated into chloroplast photosynthetic metabolism without prohibitive problems.
The carboxylterminal octapeptide of ribulosebisphosphate carboxylase from Rhodospirillum rubrum , which lacks small subunits, shows homology to a highly conserved region near the amino terminus of the small subunits of hexadecameric ribulosebisphosphate carboxylases, which are composed of large and small subunits. Truncations of the R. rubrum enzyme, which partially or completely deleted the region of homology, demonstrated that the region is not an important determinant of the catalytic efficiency of the enzyme. A further truncation, which replaced the carboxylterminal 19 amino acid residues with a single terminal leucyl residue, yielded a Rubisco whose substrate‐saturated catalytic rate resembled that of the wild‐type enzyme but which had weaker affinities for ribulose‐P 2 and CO 2 .
Abstract Transgenic tobacco (Nicotiana tabacum L. cv W38) plants with an antisense gene directed against the mRNA of ribulose-1,5-biphosphate carboxylase/oxygenase (Rubisco) activase grew more slowly than wild-type plants in a CO2-enriched atmosphere, but eventually attained the same height and number of leaves. Compared with the wild type, the anti-activase plants had reduced CO2 assimilation rates, normal contents of chlorophyll and soluble leaf protein, and much higher Rubisco contents, particularly in older leaves. Activase deficiency greatly delayed the usual developmental decline in Rubisco content seen in wild-type leaves. This effect was much less obvious in another transgenic tobacco with an antisense gene directed against chloroplast-located glyceraldehyde-3-phosphate dehydrogenase, which also had reduced photosynthetic rates and delayed development. Although Rubisco carbamylation was reduced in the anti-activase plants, the reduction was not sufficient to explain the reduced photosynthetic rate of older anti-activase leaves. Instead, up to a 10-fold reduction in the catalytic turnover rate of carbamylated Rubisco in vivo appeared to be the main cause. Slower catalytic turnover by carbamylated Rubisco was particularly obvious in high-CO2-grown leaves but was also detectable in air-grown leaves. Rubisco activity measured immediately after rapid extraction of anti-activase leaves was not much less than that predicted from its degree of carbamylation, ruling out slow release of an inhibitor from carbamylated sites as a major cause of the phenomenon. Nor could substrate scarcity or product inhibition account for the impairment. We conclude that activase must have a role in vivo, direct or indirect, in promoting the activity of carbamylated Rubisco in addition to its role in promoting carbamylation.
The side chain of residue threonine 65 within the active site of ribulosebisphosphate carboxylase participates in a network of hydrogen bonds and ionic interactions involving the phosphate moiety attached to C-1 of the substrate. This residue was replaced with serine, alanine, and valine in the enzyme from Synechococcus PCC 6301. The mutant enzymes were stable, expressed abundantly by Escherichia coli, and retained the ability to form gel-filterable complexes with the reaction-intermediate analog, 2'-carboxyarabinitol-1,5-bisphosphate. The substitutions reduced the kcat/Km(CO2) (where kcat is the substrate-saturated turnover rate) of the enzyme from 17- to 340-fold with the more radical substitutions causing more severe reductions. The CO2/O2 specificity also deteriorated progressively, the valine replacement causing a 2.3-fold reduction. In concert with these changes, a compound tentatively identified as 1-deoxy-D-glycero-2,3-pentodiulose-5-phosphate, the product of beta elimination of the 2,3-enediol(ate) intermediate of the catalytic reaction, appeared among the reaction products in progressively increasing amounts. In the case of the valine substitution, it comprised 13% of the ribulose bisphosphate consumed. The mutant enzymes also partitioned more of their reaction flux to pentulose bisphosphate isomers of ribulose bisphosphate. By contrast, the diversion of carboxylated product to pyruvate, as a result of beta elimination of the three-carbon aci-carbanion intermediate of the carboxylation reaction, was ameliorated by the replacements, the valine mutant showing a 5-fold improvement in this parameter. These observations focus attention on a geometric conflict which exists between the requirements for stabilization of the 5-carbon enediol(ate) and 3-carbon aci-carbanion intermediates. This conflict must be resolved by a change in the angle of the C-1/bridge oxygen bond during each catalytic cycle. The network of hydrogen bonds involving the side chain of threonine 65 must play a crucial role in facilitating reaction of the enediol(ate) with the gaseous substrate and in shepherding this subsequent movement.
The large subunit core of ribulose-bisphosphate carboxylase from Synechococcus PCC 6301 expressed in Escherichia coli in the absence of its small subunits retains a trace of carboxylase activity (about 1% of the kcat of the holoenzyme) (Andrews, T. J (1988) J. Biol. Chem. 263, 12213-12219). During steady-state catalysis at substrate saturation, this residual activity diverted approximately 10% of the reaction flux to 1-deoxy-D-glycero-2,3-pentodiulose-5-phosphate as a result of β elimination of inorganic phosphate from the first reaction intermediate, the 2,3-enediol form of ribulose bisphosphate. This indicates that the active site's ability to stabilize and/or retain this intermediate is compromised by the absence of small subunits. Epimerization and isomerization of the substrate resulting from misprotonation of the enediol intermediate were not significantly exacerbated by lack of small subunits. The residual carboxylating activity partitioned product between pyruvate and 3-phosphoglycerate in a ratio similar to that of the holoenzyme, indicating that stablization of the penultimate three-carbon aci-acid intermediate is not perturbed by lack of small subunits. The underlying instability of the five-carbon enediol intermediate was revealed, even with the holoenzyme, under conditions designed to lead to exhaustion of substrate CO2 (and O2). When carboxylation (and oxygenation) stalled upon exhaustion of gaseous substrate, both spinach and Synechococcus holoenzymes continued slowly to β eliminate inorganic phosphate from and to misprotonate the enediol intermediate. With carboxylation and oxygenation blocked, the products of these side reactions of the enediol intermediate accumulated to readily detectable levels, illustrating the difficulties attendant upon ribulose-P2 carboxylase's use of this reactive species as a catalytic intermediate.
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