Escherichia coli F1 ATPase is reversibly inhibited by intra- and intersubunit crosslinking: an approach to assess rotational catalysis

Reaction of the multisubunit F1 ATPase from Escherichia coli (EF1) with a bifunctional cleavable crosslinker, 3,3'-dithiobis(succinimidylpropionate) (DSP), has been used to explore the possibility that during catalysis a rotational movement of catalytic subunits relative to noncatalytic subunits occurs. The premise is that such rotational catalysis is tenable if intersubunit crosslinking of a major subunit with one of the minor subunits inhibits the enzyme activity and if upon cleavage of the crosslinks, the enzyme regains activity. The results presented in this paper show that crosslinking of about 5-6 reactive groups on EF1 with DSP is accompanied by a loss of 2/3 of the enzyme activity. Both intra- and intersubunit crosslinks are formed. The most prominent intersubunit crosslinks are those of gamma and delta subunits with the alpha subunit. Nearly complete recovery of activity can be attained by cleaving the disulfide bond in the crosslinker with dithiothreitol. Because the chemical modification of enzyme groups remains after the crosslinker is cleaved, the loss in activity before cleavage can be ascribed to conformational restraints. The results show that catalysis by the EF1 ATPase is highly sensitive to the restrictions of crosslinking, and are consistent with the view that catalysis is accompanied by appreciable movements of the major subunits with respect to the minor subunits, as suggested for rotational catalysis.     

Role of arginine residues in ovine lutropin: Reversible modification by 1,2-cyclohexanedione

The modification of arginine residues of ovine pituitary lutropin by 1,2-cyclohexanedione has been studied. This alteration did not disrupt the quaternary structure of the hormone. Modification of the first set of about five reactive arginines resulted in 50% loss of hormonal activity. Further alteration in which seven to eight residues of arginine were modified led to 85% loss in activity. Hydroxylamine treatment of the derivative restored a significant amount (70%) of biological activity. Modification of isolated subunits did not appear to affect recombination. Recombinants in which either the α or β subunit was modified showed approximately 30% of the activity of the native hormone. The recombinant in which both of the subunits were derivatized had about 10% hormonal activity.     

Modification of myosin subfragment 1 tryptophans by dimethyl(2-hydroxy-5-nitrobenzyl)sulfonium bromide

Modification of tryptophanyl residues (Trps) of myosin subfragments 1 (S-1) was performed with dimethyl(2-hydroxy-5-nitrobenzyl)sulfonium bromide (DHNBS). Under controlled conditions, pH 6 at 0 degrees C and 10-min reaction with 10-100-fold molar excess, K+(EDTA) activity was reduced down to less than half, whereas Ca2+-ATPase activity increased and acto-S-1-ATPase was not affected. The number of modified Trps (up to 2.5) agreed well with the number of 2-hydroxy-5-nitrobenzyl moieties incorporated in S-1. The thiol groups of S-1 were not affected up to 50-fold molar excess of DHNBS, thus indicating that the modification was selective for Trps. The modification of as few as one Trp caused a blue shift of the emission spectrum, accompanied by a reduction in the fluorescence quantum yield. The accessibility of Trps to the fluorescence quencher acrylamide is drastically reduced upon modification, indicating that DHNBS-reactive Trps are more "exposed" than the DHNBS-refractive ones. DHNBS modification did not seem to affect the ATP-induced tryptophan fluorescence enhancement of S-1. The effect of DHNBS modification of the intrinsic fluorescence of S-1 indicates that the modified Trps are located in a polar environment and that they may be identical with the long-lifetime Trps of Torgerson [Torgerson, P. (1984) Biochemistry 23, 3002-3007]. The most reactive Trp is located in the N-terminal 27-kDa fragment of the S-1 heavy chain. It might also be inferred from the above data that the nonexposed and ATP-perturbed Trp(s) is (are) located in the 50-kDa fragment.     

Identification of a domain in the V0 subunit d that is critical for coupling of the yeast vacuolar proton-translocating ATPase

Vacuolar proton-translocating ATPase pumps consist of two domains, V(1) and V(o). Subunit d is a component of V(o) located in a central stalk that rotates during catalysis. By generating mutations, we showed that subunit d couples ATP hydrolysis and proton transport. The mutation F94A strongly uncoupled the enzyme, preventing proton transport but not ATPase activity. C-terminal mutations changed coupling as well; ATPase activity was decreased by 59-72%, whereas proton transport was not measurable (E328A) or was moderately reduced (E317A and C329A). Except for W325A, which had low levels of V(1)V(o), mutations allowed wild-type assembly regardless of the fact that subunits E and d were reduced at the membrane. N- and C-terminal deletions of various lengths were inhibitory and gradually destabilized subunit d, limiting V(1)V(o) formation. Both N and C terminus were required for V(o) assembly. The N-terminal truncation 2-19Delta prevented V(1)V(o) formation, although subunit d was available. The C terminus was required for retention of subunits E and d at the membrane. In addition, the C terminus of its bacterial homolog (subunit C from T. thermophilus) stabilized the yeast subunit d mutant 310-345Delta and allowed assembly of the rotor structure with subunits A and B. Structural features conserved between bacterial and eukaryotic subunit d and the significance of domain 3 for vacuolar proton-translocating ATPase function are discussed.     

Characterization of the subunit structure of the catalytically active type I iodothyronine deiodinase

Type I iodothyronine deiodinase is a approximately 50-kDa, integral membrane protein that catalyzes the outer ring deiodination of thyroxine. Despite the identification and cloning of a 27-kDa selenoprotein with the catalytic properties of the type I enzyme, the composition and the physical nature of the active deiodinase are unknown. In this report, we use a molecular approach to determine holoenzyme composition, the role of the membrane anchor on enzyme assembly, and the contribution of individual 27-kDa subunits to catalysis. Overexpression of an immunologically unique rat 27-kDa protein in LLC-PK1 cells that contain abundant catalytically active 27-kDa selenoprotein decreased deiodination by approximately 50%, and > 95% of the LLC-PK1 derived 27-kDa selenoprotein was specifically immune precipitated by the anti-rat enzyme antibody. The hybrid enzyme had a molecular mass of 54 kDa and an s(20,w) of approximately 3.5 S indicating that every native 27-kDa selenoprotein partnered with an inert rat 27-kDa subunit in a homodimer. Enzyme assembly did not depend on the presence of the N-terminal membrane anchor of the 27-kDa subunit. Direct visualization of the deiodinase dimer showed that the holoenzyme was sorted to the basolateral plasma membrane of the renal epithelial cell.     

Influence of chemical modification of cysteine and histidine side chains upon subunit reassembly of alpha crystallin

Alpha crystallin, the important multimeric structural protein of mammalian eye lens, is an assembly composed of 30 alpha-A and 10 alpha-B subunits. The influence of either partial or complete chemical modification of two important amino acid side chains, cysteine and histidine, upon the integrity of native alpha crystallin assembly and also upon the mode of subunit reassembly has been investigated. It has been found that chemical modification of surface-exposed cysteine and histidine side chains does not affect the subunit-subunit interactions stabilizing the native aggregate. Cysteine modifications, either partial or complete, unlike histidine modifications, do not seem to affect the backbone conformation of the subunits refolded after denaturation. Both cysteine and histidine modifications, however, affect the packing of the refolded structural elements forming the tertiary structure of the subunits and also the mode of oligomeric reorganization. The most striking effect of histidine modification is the considerable increase in size of the aggregates upon reassociation of the modified subunits. The chaperone activity, however, has been found to remain almost unaffected in spite of these chemical modifications.     

Influence of chemical modification of cysteine and histidine side chains upon subunit reassembly of alpha crystallin

Alpha crystallin, the important multimeric structural protein of mammalian eye lens, is an assembly composed of 30 alpha-A and 10 alpha-B subunits. The influence of either partial or complete chemical modification of two important amino acid side chains, cysteine and histidine, upon the integrity of native alpha crystallin assembly and also upon the mode of subunit reassembly has been investigated. It has been found that chemical modification of surface-exposed cysteine and histidine side chains does not affect the subunit-subunit interactions stabilizing the native aggregate. Cysteine modifications, either partial or complete, unlike histidine modifications, do not seem to affect the backbone conformation of the subunits refolded after denaturation. Both cysteine and histidine modifications, however, affect the packing of the refolded structural elements forming the tertiary structure of the subunits and also the mode of oligomeric reorganization. The most striking effect of histidine modification is the considerable increase in size of the aggregates upon reassociation of the modified subunits. The chaperone activity, however, has been found to remain almost unaffected in spite of these chemical modifications.     

Identification and localization of a cysteinyl residue critical for the trypsin-like catalytic activity of the proteasome.

Chemical modification of the proteasome with N-ethylmaleimide (NEM) was performed for the purpose of identifying amino acid residues that play a role in the enzyme's proteolytic function. Modification of the proteasome with NEM specifically and irreversibly suppressed one of the three peptidase activities of the enzyme, viz., the "trypsin-like" activity. Leupeptin, a reversible competitive inhibitor of this activity, protected the activity from NEM inactivation, suggesting that NEM modifies a residue in the leupeptin binding site. Comparisons of enzyme samples labeled with [14C]NEM either in the presence or in the absence of leupeptin allowed the identification of a proteasome subunit containing an NEM-modified, leupeptin-protected cysteinyl residue. The leupeptin protection experiments suggest that residues of this subunit contribute to the active site responsible for the proteasome's trypsin-like activity. This subunit was purified by reverse-phase high-performance liquid chromatography. Peptide mapping and N-terminal amino acid sequencing were employed to acquire information about the primary structure of the subunit, including the sequence surrounding the leupeptin-protected cysteinyl residue. The sequencing data suggest that this proteasome subunit is evolutionarily related to other proteasome subunits that have been sequenced, which show no homology to other known proteases. The assignment of a catalytic function to a member of the proteasome family supports the hypothesis that proteasome subunits represent a structurally and possibly mechanistically novel group of proteases.     

The anatomy of transcarboxylase and the role of its subunits.

Biotin enzymes in general catalyze the fixation of CO2 and in a few instances decarboxylations yielding CO2. Transcarboxylase is an exception; it catalyzes the transfer of a carboxyl group from one compound to another and CO2 is not involved. This enzyme plays an essential role in the formation of propionic acid by propionibacteria and its structure and catalytic mechanism have been extensively investigated including studies of the quaternary structure by electron microscopy. The structure is complex, consisting of three types of subunits: (1) a central hexameric subunit, (2) six dimeric outside subunits, and (3) twelve biotinyl subunits which bind the outside subunits to the central subunit. There are 12 substrate sites on the central subunit (2 per polypeptide) and 2 substrate sites on each of the dimeric outside subunits. The carboxyl is transferred between these sites via the biotin of the biotinyl subunit. The biotinyl subunit (approximately 123 residues) has been completely sequenced and it has been shown that the first 42 residues serve in binding the outside subunits to the central subunit and the remainder of the sequence is involved in placing the biotin between the subunits so that it may serve as the carboxyl carrier between the substrate sites on the central and outside subunits. It is proposed that the dual sites on the polypeptides of the central subunit have arisen as a consequence of gene duplication and fusion. An intriguing question is why such a complicated structure is required for catalysis of a rather simple reaction.     

Identification of bovine heart cytochrome c oxidase subunits modified by the lipid peroxidation product 4-hydroxy-2-nonenal

Bovine heart cytochrome c oxidase (CcO) was inactivated by the lipid peroxidation product 4-hydroxy-2-nonenal (HNE) in a time- and concentration-dependent manner with pseudo-first-order kinetics. Cytochrome c oxidase electron transport activity decreased by as much as 50% when the enzyme was incubated for 2 h at room temperature with excess HNE (300-500 microM). HNE-modified CcO subunits were identified by two mass spectrometric methods: electrospray ionization mass spectrometry (ESI/MS) and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF/MS). All of the experimentally determined molecular masses were in excellent agreement with published sequence values with an accuracy of approximately 1 part per 10000 mass units for subunits smaller than 20 kDa and approximately 1 part per 1000 mass units for the three subunits larger than 20 kDa. Both MS methods detected six CcO subunits with an increased mass of 156 Da after reaction with HNE (subunits II, IV, Vb, VIIa, VIIc, and VIII); this result indicates a single Michael-type reaction site on either a lysine or histidine residue within each subunit. Reaction of HNE with either subunit VIIc or subunit VIII (modified approximately 30% and 50-75%, respectively) must be responsible for CcO inhibition. None of the other subunits were modified more than 5% and could not account for the observed loss of activity. Reaction of HNE with His-36 of subunit VIII is most consistent with the approximately 50% inhibition of CcO: (1) subunit VIII is modified more than any other subunit by HNE; (2) the time dependence of subunit VIII modification is consistent with the percent inhibition of CcO; (3) His-36 was identified as the HNE-modified amino acid residue within subunit VIII by tandem MS analysis.     

The role of dissimilar subunits of NAD-specific isocitrate dehydrogenase from pig heart. Evaluation using affinity labeling

NAD-specific isocitrate dehydrogenase from pig heart is composed of three dissimilar subunits present in the native enzyme as 2 alpha:1 beta: 1 gamma, with a tetramer being the smallest form of complete enzyme. The role of these subunits has been explored using affinity labeling. Specifically labeled subunits are separated and then recombined with unmodified subunits to form dimers. Recombination of beta or gamma subunits modified by the isocitrate analogues, 3-bromo-2-ketoglutarate and 3,4-didehydro-2-ketoglutarate, with unmodified alpha subunit led to the same activity in the dimer as when unmodified beta or gamma was combined with alpha. Contrastingly, modification of alpha with these isocitrate analogues led to loss in activity either alone or when recombined with beta or gamma. Hence, the isocitrate site on alpha is required for catalytic activity but the isocitrate sites on beta or gamma are not necessary for the activity of the functional dimer. Reaction of isolated subunits with 3-bromo-2-ketoglutarate shows that alpha and the alpha beta dimer are modified at about the same rate as holoenzyme, suggestive of similarity of the isocitrate site in native enzyme and in isolated active entities containing alpha subunit; in contrast, beta and gamma subunits react more slowly. Modification by the 2',3'-dialdehyde derivative of the allosteric effector, ADP, led to loss of activity in reconstituted dimers, independent of which subunit was modified. Reaction of isolated subunits with the dialdehyde derivative of ADP is slow compared to the initial reaction with native enzyme, indicating differences in the effects of ADP on intact enzyme and subunits. The ADP sites on all subunits may thus be important in intersubunit interactions, which in turn modulate catalytic activity.     

Synthesis and assembly of bacterial and higher plant Rubisco subunits in Escherichia coli

The synthesis in Escherichia coli of both the large and small subunits of cereal ribulose bisphosphate carboxylase/oxygenase has been obtained using expression plasmids and bacteriophages. The level and order of synthesis of the large and small subunits were regulated using different promoters, resulting in different subunit pool sizes and ratios that could be controlled in attempts to optimize the conditions for assembly. Neither assembly nor enzyme activity were observed for the higher plant enzyme. In contrast, cyanobacterial large and small subunits can assemble to give an active holoenzyme in Escherichia coli. By the use of deletion plasmids, followed by infection with appropriate phages, it can be demonstrated that the small subunit is essential for catalysis. However, the small subunit is not required for the assembly of a large subunit octomer core in the case of the Synechococcus enzyme; self-assembly of the octomer will occur in an rbcS deletion strain. The cyanobacterial small subunits can be replaced by wheat small subunits to give an active enzyme in Escherichia coli. The hybrid cyanobacterial large/wheat small subunit enzyme has only about 10% of the level of activity of the wild-type enzyme, reflecting the incomplete saturation of the small subunit binding sites on the large subunit octomer, and possibly a mismatch in the subunit interactions of those small subunits that do bind, giving rise to a lower rate of turnover at the active sites.Abbreviations IPTG isopropyl--D-thiogalactopyranoside - L large subunit - Rubisco ribulose bisphosphate carboxylase/oxygenase - S small subunit     

N-terminal deletion of the gamma subunit affects the stabilization and activity of chloroplast ATP synthase

Five truncation mutants of chloroplast ATP synthase gamma subunit from spinach (Spinacia oleracea) lacking 8, 12, 16, 20 or 60 N-terminal amino acids were generated by PCR by a mutagenesis method. The recombinant gamma genes were overexpressed in Escherichia coli and assembled with alphabeta subunits into a native complex. The wild-type (WT) alphabetagamma assembly i.e. alphabetagammaWT exhibited high (Mg2+)-dependent and (Ca2+)-dependent ATP hydrolytic activity. Deletions of eight residues of the gamma subunit N-terminus caused a decrease in rates of ATP hydrolysis to 30% of that of the alphabetaWT assembly. Furthermore, only approximately 6% of ATP hydrolytic activity was retained with the sequential deletions of gamma subunit up to 20 residues compared with the activity of the alphabetaWT assembly. The inhibitory effect of the epsilon subunit on ATP hydrolysis of these alphabetagamma assemblies varied to a large extent. These observations indicate that the N-terminus of the gamma subunit is very important, together with other regions of the gamma subunit, in stabilization of the enzyme complex or during cooperative catalysis. In addition, the in vitro binding assay showed that the gamma subunit N-terminus is not a crucial region in binding of the epsilon subunit.     

Distribution of Nuclease O Inhibitor among Aspergillus Species

Leucine dehydrogenase was inhibited by p-chioromercuribenzoate and HgCl₂, but not by 5,5′-dithiobis(2-nitrobenzoic acid), 4,4′-dithiopyridine and N-ethylmaleimide. Modification of sulfhydryl groups of the enzyme with p-chloromercuribenzoate and HgCl₂ was accompanied with a loss of the enzyme activity. The 6 reactive sulfhydryl groups per enzyme molecule play an essential role for catalysis. Approximately 12 sulfhydryl groups were titrated per molecule in the presence of 8 m urea: the enzyme contains 2 sulfhydryl groups per subunit, and one of them participates in the catalytic action. Fluorometric and gel filtration studies on binding of NADH to the enzyme revealed that the enzyme contains 6 coenzyme binding sites per molecule.

These results are compatible with the hexameric structure of leucine dehydrogenase composed of identical subunits, showing that each subunit has one catalytic site and one indispensable sulfhydryl group.     

Implication of arginyl residues in mRNA binding to ribosomes

Modification of Escherichia coli robosomes with phenylglyoxal and butanedione, protein reagents specific for arginyl residues, inactivates polypeptide polymerization, assayed as poly(U)-dependent polyphenylalanine synthesis, and the binding of poly(U). Inactivation is produced by modification of the 30-S subunit. Both the RNA and the protein moieties of 30-S subunits are modified by phenylglyoxal, and modification of either of them is accompanied by inactivation of polypeptide synthesis. Modification of only the split proteins released from 30-S subunits by prolonged dialysis against a low-ionic-strength buffer, which contain mainly protein S1, produces inhibition of poly(U) binding and inactivation of polypeptide synthesis. Amino acid analysis of the modified split proteins showed a significant modifications of arginyl residues. These results indicate that the arginyl residues of a few 30-S proteins might be important in the interaction between mRNA and the 30-S subunit, which agrees with the general role assigned to the arginyl residues of proteins as the positively charged recognition site for anionic ligands.     

The reactivity of sulfhydryl groups of yeast DNA dependent RNA polymerase I

The number of reactive cysteine residues of yeast RNA polymerase I was determined and their function was studied using parachloromercury benzoate (pCMB), dithiobisnitrobenzoate (DTNB) and N-ethyl-maleimide (NEM) as modifying agents. By treatment with DTNB about 45 sulfhydryl groups react in the presence of 8M urea. Under non-denaturing conditions only 20 sulfhydryl groups are reactive with pCMB and DTNB. Both reagents completely inactivate the enzyme and this effect can be reversed by reducing agents. The sedimentation coefficient and the subunit composition are not affected when the enzyme is inactivated. Two of the most reactive sulfhydryl groups are necessary for activity. The modification of these groups is partially protected by substrates and DNA, suggesting that they are involved either in catalysis or in the maintenance of the conformation of the active site. Experiments with 14C-NEM indicate that the most reactive groups are located in subunits of 185,000, 137,000 and 41,000 daltons.     

蚕豆β－半乳糖苷酶活性必需氨基酸残基分析

 蚕豆β－半乳糖苷酶活性必需氨基酸残基分析龚笑海,孙册（中国科学院上海生物化学研究所,上海２０００３１）化学修饰作为一种研究酶活性基团的方法,对研究糖苷酶的催化机理有其独到的优点,并已有这方面的报道．从蚕豆纯化的β－半乳糖苷酶,分子量为７０ｋＤ,由两个...     

Binding of the delta subunit to rod phosphodiesterase catalytic subunits requires methylated, prenylated C-termini of the catalytic subunits

PDE6 (type 6 phosphodiesterase) from rod outer segments consists of two types of catalytic subunits, alpha and beta; two inhibitory gamma subunits; and one or more delta subunits found only on the soluble form of the enzyme. About 70% of the phosphodiesterase activity found in rod outer segments is membrane-bound, and is thought to be anchored to the membrane through C-terminal prenyl groups. The recombinant delta subunit has been shown to solubilize the membrane-bound form of the enzyme. This paper describes the site and mechanism of this interaction in more detail. In isolated rod outer segments, the delta subunit was found exclusively in the soluble fraction, and about 30% of it did not coimmunoprecipitate with the catalytic subunits. The delta subunit that was bound to the catalytic subunits dissociated slowly, with a half-life of about 3.5 h. To determine whether the site of this strong binding was the C-termini of the phosphodiesterase catalytic subunits, peptides corresponding to the C-terminal ends of the alpha and beta subunits were synthesized. Micromolar concentrations of these peptides blocked the phosphodiesterase/delta subunit interaction. Interestingly, this blockade only occurred if the peptides were both prenylated and methylated. These results suggested that a major site of interaction of the delta subunit is the methylated, prenylated C-terminus of the phosphodiesterase catalytic subunits. To determine whether the catalytic subunits of the full-length enzyme are methylated in situ when bound to the delta subunit, we labeled rod outer segments with a tritiated methyl donor. Soluble phosphodiesterase from these rod outer segments was more highly methylated (4.5 +/- 0.3-fold) than the membrane-bound phosphodiesterase, suggesting that the delta subunit bound preferentially to the methylated enzyme in the outer segment. Together these results suggest that the delta subunit/phosphodiesterase catalytic subunit interaction may be regulated by the C-terminal methylation of the catalytic subunits.     

ADP-glucose pyrophosphorylase from potato tuber: site-directed mutagenesis of homologous aspartic acid residues in the small and large subunits

Asp142 in the homotetrameric ADP-glucose pyrophosphorylase (ADP-Glc PPase) enzyme from Escherichia coli was demonstrated to be involved in catalysis of this enzyme [Frueauf, J.B., Ballicora, M.A. and Preiss J. (2001) J. Biol. Chem., 276, 46319-46325]. The residue is highly conserved throughout the family of ADP-Glc PPases, as well as throughout the super-family of sugar-nucleotide pyrophosphorylases. In the heterotetrameric ADP-Glc PPase from potato (Solanum tuberosum L.) tuber, the homologous residue is present in both the small (Asp145) and the large (Asp160) subunits. It has been proposed that the small subunit of plant ADP-Glc PPases is catalytic, while the large subunit is modulatory; however, no catalytic residues have been identified. To investigate the function of these conserved Asp residues in the ADP-Glc PPase from potato tuber, we used site-directed mutagenesis to introduce either an Asn or a Glu. Kinetic analysis in the direction of synthesis or pyrophosphorolysis of ADP-Glc showed a significant decrease (more than four orders of magnitude) in the specific activity of the SD145NLwt, SD145NLD160N, and SD145NLD160E mutants, while the effect was smaller (approximately two orders of magnitude) with the SD145ELwt, SD145ELD160N, and SD145ELD160E mutants. By contrast, mutation of the large subunit alone did not affect the specific activity but did alter the apparent affinity for the activator 3-phosphoglycerate, showing two types of apparent roles for this residue in the different subunits. These results show that mutation of Asp160 of the large subunit does not affect catalysis, thus the large subunit is not catalytic, and that the negative charge of Asp145 in the small subunit is necessary for enzyme catalysis.     

Ribulose 1,5-bisphosphate carboxylase-oxygenase. I. Structural, immunochemical and catalytic properties

Some structural, immunochemical and catalytic properties are examined for ribulose 1,5-bisphosphate carboxylase-oxygenase from various cellular organisms including bacteria, cyanobacteria, algae and higher plants. The native enzyme molecular masses and the subunit polypeptide compositions vary according to enzyme sources. The molecular masses of the large and small subunits from different cellular organisms, on the other hand, show a relatively high homology due to their well-conserved primary amino acid sequence, especially that of the large subunit. In higher plants, the native enzyme and the large subunit are recognized by the antibodies raised against either the native or large subunit, whereas the small subunit apparently cross-reacts only with the antibodies directed against itself. A wide diversity exists, however, in the serological response of the native enzyme and its subunits with antibodies directed against the native enzyme or its subunits from different cellular organisms. According to numerous kinetic studies, the carboxylase and oxygenase reactions of the enzyme with ribulose 1,5-bisphosphate and carbon dioxide or oxygen require activation by carbon dioxide and magnesium prior to catalysis with ribulose 1,5-bisphosphate and carbon dioxide or oxygen. The activation and catalysis are also under the regulation of other metal ions and a number of chloroplastic metabolites. Recent double-labeling experiments using radioactive ribulose 1,5-bisphosphate and 14CO2 have elucidated the carboxylase/oxygenase ratios of the enzymes from different organisms. Another approach, i.e., genetic experiments, has also been used to examine the modification of the carboxylase/oxygenase ratio.