Molecular evolution of ribulose-1,5-biphosphate carboxylase/oxygenase (RuBisCO)

The biological deep sea hydrothermal vent as a model to study carbon dioxide capturing enzymes

Deep sea hydrothermal vents are located along the mid-ocean ridge system, near volcanically active areas, where tectonic plates are moving away from each other. Sea water penetrates the fissures of the volcanic bed and is heated by magma. This heated sea water rises to the surface dissolving large amounts of minerals which provide a source of energy and nutrients to chemoautotrophic organisms. Although this environment is characterized by extreme conditions (high temperature, high pressure, chemical toxicity, acidic pH and absence of photosynthesis) a diversity of microorganisms and many animal species are specially adapted to this hostile environment. These organisms have developed a very efficient metabolism for the assimilation of inorganic CO₂ from the external environment. In order to develop technology for the capture of carbon dioxide to reduce greenhouse gases in the atmosphere, enzymes involved in CO₂ fixation and assimilation might be very useful. This review describes some current research concerning CO₂ fixation and assimilation in the deep sea environment and possible biotechnological application of enzymes for carbon dioxide capture.

Reminiscences, collaborations and reflections

This is a personal account by a semi old-timer who completed his official term as a professor of plant biochemistry at Nagoya University in Japan in 1992. My university student life began soon after the World War II (1948). I shared the hardships of many in my age group, in that life was difficult during my college years. I was fortunate to have the opportunity of studying in the USA on a Fulbright scholarship first at Purdue University (1955-1956), and then at the University of California, Berkeley (1956-1957). My graduate study and postdoctoral training in the new world were vitally refreshing and stimulating, which gave me the impetus for becoming a natural scientist associated with academic institutions. Consciously and subconsciously I was impressed by the friendly and liberal atmosphere surrounding young students as well as senior scholars in the United States. But more importantly, I was inspired by the critical and competitive minds prevailing among these people.The appointment as a biochemist at the International Rice Research Institute (IRRI) in the Philippines (1962-1964) was the real start of my professional career. The work was continued upon my return to Nagoya to become a staff member of the Research Institute for Biochemical Regulation (1964-1992). Throughout the years, my major research interest has covered photosynthesis as a whole, involving photosynthetic CO2-fixation (RuBisCO), carbohydrate metabolism, e.g. starch biosynthesis and breakdown (α-amylase), and metabolic regulation, which are interrelated in the basic metabolism of plant cells.I shall briefly describe in this article highlights from my studies and discoveries made and I shall also discuss their possible significance in plant metabolism, with the hope that it does not contradict my sense of humility: They are (a) discovery of ADPG in plants and its role in starch biosynthesis; (b) structure-function relationship of RuBisCO proteins, in particular on heterologous recombination of their subunits of plant-type enzyme molecules derived from the prokaryotic photosynthetic bacteria; (c) molecular evolution of RuBisCO genes; (d) mode of actions (formation, intracellular transport and secretion) of rice seed α-amylase and its structural characteristics (distinctive glycosylation), and (e) DNA methylation and regulatory mechanism of photosynthesis gene expression in plastids (amyloplasts). In each step of my research, I shared joy, excitement, disappointment, and agony with my colleagues, an experience that may be common to all researchers. Although it is now becoming well recognized among the scientific community in Japan, I want to point out that interaction of multinational scientific minds in the laboratory produces a vital and creative atmosphere for performance of successful research. I experienced and realized this important fact in my earlier days in the USA and the Philippines. Inasmuch as I believe that this is the most crucial element for any research laboratory to possess, I fondly remember the friendships gained with numerous overseas visitors and collaborators who have contributed immensely to our work.

Principles of functional and structural organization in the bacterial cell: 'compartments' and their enzymes

Most bacteria lack obvious compartmentation, i.e., structural partition of the cell into functional entities (organelles) formed by a closed biological membrane. Nevertheless, these organisms exhibit sophisticated regulation and interactions of their catabolic and anabolic pathways; they are able to exploit a great variety of carbon and energy sources, and they conserve and transform energy in an efficient manner. In a less stringent sense, 'compartments' are also present in bacteria if one accepts that bacterial 'compartments' are not necessarily surrounded by a membrane, but are rather defined as mere functional entities characterized by their structural components, their enzymes and other functional proteins such as binding proteins. This view would mean that the bacterial cell can be described as a highly organized structured system comprised of these functional entities. Regulated transport processes within 'compartments' and across boundaries involving low and high molecular mass compounds, solutes, and ions take place within the 'framework' constituted by this structured system. Special emphasis is given to the fact that many of the transport processes take place involving the functional entity 'energized membrane'. This 'framework', the structural basis for the functional potential of a bacterial cell, can be studied by electron microscopy. Advanced sample preparation techniques and imaging modes are available which keep the danger of artefact formation low; they can be applied at cellular and macromolecular levels. Recent developments in immunoelectron microscopy and affinity labelling techniques provide tools which allow to unequivocally locate enzymes and other antigens in the cell and to identify polypeptide chains in enzyme complexes. Application of these approaches in studies on cellular and macromolecular organization of bacteria and their enzyme systems confirmed some old views but also extended our knowledge. This is exemplified by a description of selected enzyme complexes located in the bacterial cytoplasm, in the cytoplasmic membrane or attached to it, in the periplasmic space, and attached to the cell wall or set free into the surrounding medium.

Ribulose bisphosphate carboxylase in algae: synthesis, enzymology and evolution

Studies demonstrating differences in chloroplast structure and biochemistry have been used to formulate hypotheses concerning the origin of algal plastids. Genetic and biochemical experiments indicate that significant variation occurs in ribulose-1,5-bisphosphate carboxylase (Rubisco) when supertaxa of eukaryotic algae are compared. These differences include variations in the organelle location of the genes and their arrangement, mechanism of Rubisco synthesis, polypeptide immunological reactivity and sequence, as well as efficacy of substrate (ribulose bisphosphate and CO2) binding and inhibitor (6-phosphogluconate) action. The structure-function relationships observed among chromophytic, rhodophytic, chlorophytic and prokaryotic Rubisco demonstrate that: (a) similarities among chromophytic and rhodophytic Rubisco exist in substrate/inhibitor binding and polypeptide sequence, (b) characteristic differences in enzyme kinetics and subunit polypeptide structure occur among chlorophytes, prokaryotes and chromophytes/rhodophytes, and (c) there is structural variability among chlorophytic plant small subunit polypeptides, in contrast to the conservation of this polypeptide in chromophytes and rhodophytes. Taxa-specific differences among algal Rubisco enzymes most likely reflect the evolutionary history of the plastid, the functional requirements of each polypeptide, and the consequences of encoding the large and small subunit genes in the same or different organelles.

Expressed genes for plant-type ribulose 1,5-bisphosphate carboxylase/oxygenase in the photosynthetic bacterium Chromatium vinosum, which possesses two complete sets of the genes

Two sets of genes for the large and small subunits of ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCO) were detected in the photosynthetic purple sulfur bacterium Chromatium vinosum by hybridization analysis with RuBisCO gene probes, cloned by using the lambda Fix vector, and designated rbcL-rbcS and rbcA-rbcB. rbcL and rbcA encode the large subunits, and rbcS and rbcB encode the small subunits. rbcL-rbcS was the same as that reported previously (A. M. Viale, H. Kobayashi, T. Takabe, and T. Akazawa, FEBS Lett. 192:283-288, 1985). A DNA fragment bearing rbcA-rbcB was subcloned in plasmid vectors and sequenced. We found that rbcB was located 177 base pairs downstream of the rbcA coding region, and both genes were preceded by plausible procaryotic ribosome-binding sites. rbcA and rbcD encoded polypeptides of 472 and 118 amino acids, respectively. Edman degradation analysis of the subunits of RuBisCO isolated from C. vinosum showed that rbcA-rbcB encoded the enzyme present in this bacterium. The large- and small-subunit polypeptides were posttranslationally processed to remove 2 and 1 amino acid residues from their N-termini, respectively. Among hetero-oligomeric RuBisCOs, the C. vinosum large subunit exhibited higher homology to that from cyanobacteria, eucaryotic algae, and higher plants (71.6 to 74.2%) than to that from the chemolithotrophic bacterium Alcaligenes eutrophus (56.6%). A similar situation has been observed for the C. vinosum small subunit, although the homology among small subunits from different organisms was lower than that among the large subunits.

D-ribulose-1,5-bisphosphate carboxylase/oxygenase: function-dependent structural changes

The key carboxylating enzyme of the reductive pentose phosphate cycle, D-ribulose-1,5-bisphosphate carboxylase/oxygenase [RuBisCO] isolated from the chemolithoautotrophic, H2-oxidizing bacterium Alcaligenes eutrophus H16 has been analyzed by several different techniques that allow conclusions about structure and function-dependent structural changes. The techniques include a novel approach in which the enzyme was induced to form 2D-crystals suitable for electron microscopy in each of its three stable functional states: as active enzyme [Ea] (in the presence of Mg2+ and HCO3-); as inactivated enzyme [Eia] (in the absence of Mg2+ and HCO3-) and as enzyme locked in an in vitro transition state [CABP-E] (Ea fully saturated with the transition state analogue 2-carboxy-D-arabinitol-1,5-bisphosphate [CABP-E]). In conjunction with X-ray crystallography, X-ray small angle scattering and other biophysical and biochemical data, the results obtained by electron microscopy support the idea that drastic configurational changes occur. Upon transition from Ea to the CABP-E the upper and lower L4S4 halves of the molecule consisting of eight large and eight small subunits (L8S8; MW = 536,000 Da) are assumed to be laterally shifted by as much as 3.6 nm relative to one another while the location of the small subunits on top of the large subunits, and relative to them, remains the same. For the Eia a similar sliding-layer configurational change in the range of 2-2.5 nm is proposed and in addition it is suggested that other configurational/conformational changes take place. The proposed structural changes are discussed with respect to the current model for the tobacco enzyme and correlated with data obtained for various other plant and (cyano) bacterial L8S8 RuBisCOs leading to speculations about structure-function relationships.

Sequence analysis of the Alcaligenes eutrophus chromosomally encoded ribulose bisphosphate carboxylase large and small subunit genes and their gene products

The nucleotide sequence of the chromosomally encoded ribulose bisphosphate carboxylase/oxygenase (RuBPCase) large (rbcL) and small (rbcS) subunit genes of the hydrogen bacterium Alcaligenes eutrophus ATCC 17707 was determined. We found that the two coding regions are separated by a 47-base-pair intergenic region, and both genes are preceded by plausible ribosome-binding sites. Cotranscription of the rbcL and rbcS genes has been demonstrated previously. The rbcL and rbcS genes encode polypeptides of 487 and 135 amino acids, respectively. Both genes exhibited similar codon usage which was highly biased and different from that of other organisms. The N-terminal amino acid sequence of both subunit proteins was determined by Edman degradation. No processing of the rbcS protein was detected, while the rbcL protein underwent a posttranslational loss of formylmethionyl. The A. eutrophus rbcL and rbcS proteins exhibited 56.8 to 58.3% and 35.6 to 38.5% amino acid sequence homology, respectively, with the corresponding proteins from cyanobacteria, eucaryotic algae, and plants. The A. eutrophus and Rhodospirillum rubrum rbcL proteins were only about 32% homologous. The N- and C-terminal sequences of both the rbcL and the rbcS proteins were among the most divergent regions. Known or proposed active site residues in other rbcL proteins, including Lys, His, Arg, and Asp residues, were conserved in the A. eutrophus enzyme. The A. eutrophus rbcS protein, like those of cyanobacteria, lacks a 12-residue internal sequence that is found in plant RuBPCase. Comparison of hydropathy profiles and secondary structure predictions by the method described by Chou and Fasman (P. Y. Chou and G. D. Fasman, Adv. Enzymol. 47:45-148, 1978) revealed striking similarities between A. eutrophus RuBPCase and other hexadecameric enzymes. This suggests that folding of the polypeptide chains is similar. The observed sequence homologies were consistent with the notion that both the rbcL and rbcS genes of the chemoautotroph A. eutrophus and the thus far characterized rbc genes of photosynthetic organisms have a common origin. This suggests that both subunit genes have a very ancient origin. The role of quaternary structure as a determinant of the rate of accepted amino acid substitution was examined. It is proposed that the sequence of the dimeric R. rubrum RuBPCase may be less conserved because there are fewer structural constraints for this RuBPCase than there are for hexadecameric enzymes.

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.

Activity expressed from cloned Anacystis nidulans large and small subunit ribulose bisphosphate carboxylase genes

The ribulose bisphosphate carboxylase/oxygenase (EC4.1.1.39) (RubisCO) large and small subunit genes from Anacystis nidulans have been cloned as a single fragment into M 13mp10 and pEMBL8 and expressed in Escherichia coli. From M 13mp10 a low yield of enzyme with high specific activity was obtained. The molecular weight of the active enzyme was 260 000 Da and of the inactive enzyme approximately 730 000 Da. The small and large subunits cloned separately did not express activity. The RubisCO gene cloned into pEMBL8 expressed activity up to 22 times that from the M 13 cloned RubisCO DNA. The RubisCO protein produced by the pEMBL cloned gene had a normal MW (550 000). Immunoprecipitation and polyacrylamide gel electrophoresis showed the presence of both large and small subunits.

Factors affecting the dissociation and reconstitution of ribulose-1,5-bisphosphate carboxylase/oxygenase from Aphanothece halophytica

Factors affecting the mutual interaction between the catalytic core [octamer of large subunit (A)] and the small subunit (B) comprising ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) from the superhalophilic cyanobacterium, Aphanothece halophytica, were investigated. The enzyme molecule dissociated into the catalytic core highly depleted of subunit B and the monomeric form of subunit B during density gradient centrifugation (15 h, 4 degrees C) in a sucrose solution of low ionic strength ([I] less than or equal to 50 mM), whereas dissociation was effectively prevented in the presence of 0.3 M KCl. Under the latter condition, dissociation of the enzyme molecule was almost completely prevented by raising the temperature to 20 degrees C, suggesting hydrophobic interaction between catalytic core and subunit B. The addition of RuBP to the sucrose gradient was shown to effectively reduce the molecular dissociation, suggesting a close interaction between the catalytic site and the binding site of subunit B with the catalytic core directly or indirectly. The dissociation was accelerated at alkaline pH higher than 8.5. Reconstitution of the enzymatically active molecular form from the separated components, catalytic core highly depleted of subunit B and B1, was done under various conditions. Both carboxylase and oxygenase activities increased proportionately with the amount of subunit B and then became saturated. From the reconstitution kinetics of RuBP carboxylase, the binding constant of subunit B (KD) was estimated to be about 30 nM in the presence of bovine serum albumin under the usual assay conditions at pH 7.5 and 25 degrees C, but decreased to about 1 nM by the further addition of 0.3 M KCl. Alkaline pH (8.5 or 9) could increase KD by one order of magnitude. High KD was also observed as a result of lowering the temperature; however, the presence of 0.3 M KCl or 0.4 M sucrose or glycerol could effectively decrease the KD at low temperature from 900 nM to less than 50 nM. All these data indicate that the enzyme dissociation at low temperature can be prevented in vivo by cellular components such as salts, polyols, and substrate RuBP besides a factor of enzyme concentration.

The prokaryote-eukaryote interface

Over the past 30 years the study of the sequences of proteins and nucleic acids has produced almost incredible amounts of information, new concepts, and new avenues of research. The beginning was slow: the first peptide hormones sequenced in the early 1950's, the first cytochrome c (horse) in 1961, the first bacterial ferredoxin in 1964, and the first transfer RNA (yeast alanine tRNA) in 1965. In the past 6 years, the rate of data accumulation has accelerated tremendously, primarily due to technological advances in nucleic acid sequencing techniques. For investigators of biological evolution, the sequence data and the new information on genetic mechanisms would prove to be the best evidence for elucidating relationships among the genomes of living organisms and for deducing phylogenetic history. In particular, they needed evidence to decide between the two hypotheses for the origin of eukaryotic cells. Now, less than 20 years since Margulis renewed the investigation of this problem, comparisons of protein and nucleic acid sequences, especially of the small subunit ribosomal RNAs, have answered this question in favor of the endosymbiotic origin of eukaryotic cells. After briefly discussing some of the concepts that helped resolve this controversy and the problems involved in using sequence data for evolutionary studies, we describe a few examples of useful evolutionary trees.