烟草核酮糖-1,5-二磷酸羧化酶/加氧酶四级结构的研究(英文)

本文提出三种证据证明烟草核酮糖-1,5-二磷酸羧化酶/加氧酶(Rubisco)的大亚基伸展在小亚基的外面,小亚基排列在大亚基中间的概念。证据是:1.固定化胰蛋白酶在一定条件下可水解RubisCO的大亚基但不水解小亚基,而天然胰蛋白酶水解大亚基,也水解小亚基。2.固定化抗小亚基IgG-Sepharose可与游离的小亚基相结合,但不能与全酶结合。3.低浓度尿素处理可使固定化的RubisCO-Sepharose上的小亚基解离下来,而大亚基仍结合在载体上,这说明RubisCO是通过定位在分子表面上的大亚基的ε-氨基与Sepharose共价偶联的。当RubisCO中的小亚基全部被解离后,大亚基之间的结合进一步增强,这时解离大亚基所需的尿素浓度要比小亚基存在时高。任何RubisCO的四级结构模型都应将小亚基置于大亚基中间受保护的位置,一部份小亚基可暴露于全酶分子表面。     

Co-translocation of a periplasmic enzyme complex by a hitchhiker mechanism through the bacterial tat pathway

Bacterial periplasmic nickel-containing hydrogenases are composed of a small subunit containing a twin-arginine signal sequence and a large subunit devoid of an export signal. To understand how the large subunit is translocated into the periplasm, we cloned the hyb operon encoding the hydrogenase 2 of Escherichia coli, constructed a deletion mutant, and studied the mechanism of translocation of hydrogenase 2. The small subunit (HybO) or the large subunit (HybC) accumulated in the cytoplasm as a precursor when either of them was expressed in the absence of the other subunit. Therefore, contrary to most classical secretory proteins, the signal sequence of the small subunit itself is not sufficient for membrane targeting and translocation if the large subunit is missing. On the other hand, the small subunit was required not only for membrane targeting of the large subunit, but also for the acquisition of nickel by the large subunit. Most interestingly, the signal sequence of the small subunit determines whether the large subunit follows the Sec or the twin-arginine translocation pathway. Taken together, these results provide for the first time compelling evidence for a naturally occurring hitchhiker co-translocation mechanism in bacteria.     

Identification, characterization, and functional analysis of heart-specific myosin light chain phosphatase small subunit

Myosin light chain phosphatase consists of three subunits, a 38-kDa catalytic subunit, a large 110-130-kDa myosin binding subunit, and a small subunit of 20-21 kDa. The catalytic subunit and the large subunit have been well characterized. The small subunit has been cloned and studied from smooth muscle, but little is known about its function and specificity in the other muscles such as cardiac muscle. In this study, cDNAs for heart-specific small subunit isoforms, hHS-M(21), were isolated and characterized. Evidence was obtained from an analysis of genome to suggest that the small subunit was the product of the same gene as the large subunit. Using permeabilized renal artery preparation and permeabilized cardiac myocytes, it was shown that the small subunit increased sensitivity to Ca(2+) in muscle contraction. It was also shown using an overlay assay that hHS-M(21) bound the large subunit. Mapping experiments demonstrated that the binding domain and the domain involved in the increasing Ca(2+) sensitivity mapped to the same N-terminal region of hHS-M(21). These observations suggest that the heart-specific small subunit hHS-M(21) plays a regulatory role in cardiac muscle contraction by its binding to the large subunit.     

Subunit dissociation and reconstitution of ribulose-1,5-bisphosphate carboxylase from Chromatium vinosum

The large and small subunits of ribulose bisphosphate carboxylase from Chromatium vinosum were dissociated and separated at pH 9.6 by sucrose density gradient centrifugation. After further purification by gel filtration, the small subunit fraction contained no carboxylase activity. The large subunit fraction was highly depleted of small subunit based on analysis by denaturing polyacrylamide gel electrophoresis. Carboxylase activity of the large subunit fraction was approximately 1% of the untreated native enzyme. Addition of purified small subunit to the large subunit fraction yielded increases of up to 67-fold in carboxylase activity, further indicating that both subunit types are required for catalysis by this enzyme. The isolated large subunit was fully capable of high-affinity activator 14CO2 binding in the presence of Mg2+ and 2-carboxyarabinitol bisphosphate, indicating that the activator and catalytic sites were not grossly denatured by the depletion of small subunit. Kinetic constants of the native C. vinosum enzyme defined a new class of ribulose bisphosphate carboxylase, which permits the detection of possible kinetic differences if the large and small subunits can be favorably reassembled with those of another kinetic class. From experiments with the enzymes from tobacco and spinach leaves it is concluded that the enzyme from higher plant sources is not suitable for such dissociation/reconstitution-type experiments.     

In vivo synthesis of carbamyl phosphate from NH3 by the large subunit of Escherichia coli carbamyl phosphate synthetase

The cloned carAB operon of Escherichia coli coding for the small and large subunits of carbamyl phosphate synthetase has been used to construct a recombinant plasmid with a 4.16 kilobase ClaI fragment of the car operon that lacks the major promoters, P1 and P2. The plasmid, pHN12, carries a functional carB gene. A mutant E. coli strain lacking both subunits of carbamyl phosphate synthetase when transformed with pHN12 overproduces the large subunit by 200-fold (8-10% of the cellular protein). The elevated levels of the large subunit enable the transformed cells to utilize NH3 but not glutamine as nitrogen donor for carbamyl phosphate synthesis. The large subunit has been purified from the overexpressing strain. The purified native large subunit is capable of synthesizing carbamyl phosphate from ammonia, HCO-3, and ATP. The kinetic properties of the large subunit compared with the holoenzyme indicate that the Michaelis constants of the large subunit for HCO-3 and ATP are modulated by its association with the small glutamine binding subunit.     

The two AGPase subunits evolve at different rates in angiosperms, yet they are equally sensitive to activity-altering amino acid changes when expressed in bacteria

The rate of protein evolution is generally thought to reflect, at least in part, the proportion of amino acids within the protein that are needed for proper function. In the case of ADP-glucose pyrophosphorylase (AGPase), this premise led to the hypothesis that, because the AGPase small subunit is more conserved compared with the large subunit, a higher proportion of the amino acids of the small subunit are required for enzyme activity compared with the large subunit. Evolutionary analysis indicates that the AGPase small subunit has been subject to more intense purifying selection than the large subunit in the angiosperms. However, random mutagenesis and expression of the maize (Zea mays) endosperm AGPase in bacteria show that the two AGPase subunits are equally predisposed to enzyme activity-altering amino acid changes when expressed in one environment with a single complementary subunit. As an alternative hypothesis, we suggest that the small subunit exhibits more evolutionary constraints in planta than does the large subunit because it is less tissue specific and thus must form functional enzyme complexes with different large subunits. Independent approaches provide data consistent with this alternative hypothesis.     

The large subunit of (sodium + potassium)-activated adenosine triphosphatase from the electroplax of Electrophorus electricus is a glycoprotein.

The large subunit of Na,K-ATPase purified from eel electroplax was found to contain amino sugars, neutral sugars and sialic acid. The concentration of these carbohydrates in the large subunit was 5–10% of that found in the smaller subunit and in total accounts for 2.6% of the mass of the large subunit. The periodic acid-Schiff's stain for glycoproteins on polyacrylamide gels is apparently not sufficiently sensitive to detect glycoproteins with these low levels of carbohydrates.     

The biosynthesis of ribulose bisphosphate carboxylase. Uncoupling of the synthesis of the large and small subunits in isolated soybean leaf cells

Isolated leaf cells from soybean (Glycine max) incorporate [35S]methionine into protein at a linear rate for at least 5h. Analysis of the products of incorporation by one-dimensional and two-dimensional polyacrylamide gel electrophoresis shows that major products are the large and small subunits of the chloroplast enzyme, ribulose bisphosphate carboxylase. The large subunit is synthesized by chloroplast ribosomes and the small subunit by cytoplasmic ribosomes. Addition of chloramphenicol to the cells reduces incorporation into the large subunit without affecting incorporation into the products of cytoplasmic ribosomes. Addition of cycloheximide or 2-(4-methyl-2,6-dinitroanilino)-N-methylpropionamide stops incorporation into the small subunit, but large subunit continues to be made for at least 4 h. For accurate estimates of incorporation into the large subunit, it is essential to use two-dimensional gel electrophoresis, because the large subunit region on one-dimensional gels is contaminated with the products of cytoplasmic ribosomes. Newly synthesized large subunits continue to enter complete molecules of ribulose bisphosphate carboxylase in the absence of small subunit synthesis. These results suggest that, in contrast to the situation in algal cells, the synthesis of the two subunits of ribulose bisphosphate carboxylase in the different subcellular compartments of higher plant cells is not tightly coupled over short time periods, and that a pool of small subunits exists in these cells. The results are disucssed in relation to possible mechanisms for the integration of the synthesis of the large and small subunits of ribulose bisphosphate carboxylase.     

A mitochondrial presequence can transport a chloroplast-encoded protein into yeast mitochondria

Ribulose-1,5-bisphosphate carboxylase/oxygenase of chloroplasts contains eight large and eight small subunits. The small subunit is encoded by nuclear DNA, synthesized in the cytoplasm, and imported into chloroplasts. The large subunit is encoded by chloroplast DNA and synthesized within chloroplasts. We show in this communication that the large subunit of Chlamydomonas chloroplasts could be efficiently imported into isolated yeast mitochondria if it was attached to the presequence of a protein transported into the yeast mitochondrial matrix. Thus, synthesis of the large subunit within chloroplasts does not reflect the inability of this subunit to cross membranes. The same mitochondrial presequence could also transport the nuclear-encoded small subunit into yeast mitochondria. However, when the two types of subunits were coimported into mitochondria, they did not assemble with each other inside the heterologous organelle.     

Identification and Precipitation of the Polyribosomes in Chlamydomonas reinhardi Involved in the Synthesis of the Large Subunit of d-ribulose-1,5-bisphosphate Carboxylase

The size classes of polyribosomes involved in the synthesis of ribulose-1,5-bisphosphate carboxylase large subunit were determined by binding radioiodinated specific antibodies to polyribosomal preparations from Chlamydomonas reinhardi. Antibodies specific to the denatured large subunit and to the native enzyme bound primarily to small polyribosomes (N = two to five ribosomes). The binding of antibodies to small polyribosomes was unexpected since the large subunit is a large polypeptide (molecular weight 55,000) coded for by a corresponding large mRNA (12-14S). Control experiments showed that this unexpected pattern of antibody binding was not a result of messenger RNA degradation, "run-off" of ribosomes from polyribosomes, or adventitious binding of the completed enzyme to a selected class of polyribosomes. In addition, polyribosomes bearing nascent large subunit chains have been immunoprecipitated from small polyribosome fractions. A large RNA species that can direct the synthesis of large subunit in vitro was extracted from small polyribosomes.     

Cytoplasmic ribosomal proteins from Chlamydomonas reinhardtii: characterization and immunological comparisons

Summary Experiments were undertaken to characterize the cytoplasmic ribosomal proteins (r-proteins) in Chlamydomonas reinhardtii and to compare immunologically several cytoplasmic r-proteins with those of chloroplast ribosomes of this alga, Escherichia coli, and yeast. The large and small subunits of the C. reinhardtii cytoplasmic ribosomes were shown to contain, respectively, 48 and 45 r-proteins, with apparent molecular weights of 12,000–59,000. No cross-reactivity was seen between antisera made against cytoplasmic r-proteins of Chlamydomonas and chloroplast r-proteins, except in one case where an antiserum made against a large subunit r-protein cross-reacted with an r-protein of the small subunit of the chloroplast ribosome. Antisera made against one out of five small subunit r-proteins and three large subunit r-proteins recognized r-proteins from the yeast large subunit. Each of the yeast r-proteins has been previously identified as an rRNA binding protein. The antiserum to one large subunit r-protein cross-reacted with specific large subunit r-proteins from yeast and E. coli.     

Topology of cytochrome b558 in neutrophil membrane analyzed by anti-peptide antibodies and proteolysis.

Cytochrome b558 is an important constituent of the superoxide-generating system in neutrophils and B lymphocytes. In this paper, the topology of the cytochrome in human neutrophil membrane was studied using antibodies raised in rabbits against synthetic peptides corresponding to various regions in the large and small subunits of the cytochrome. The antibodies recognized the cytochrome subunits in immunoblots and the cytochrome in situ. An antibody raised against residues 150-172 in the large subunit (anti-L123) bound to intact neutrophils, indicating that this region is exposed to the outside of the cells. In contrast, antibodies raised against any of the carboxyl-terminal regions of the large and small subunits (anti-LC and anti-SC, respectively) or the amino-terminal region of the small subunit (anti-SN), bound to neutrophils only after the cells were made permeable by freezing and thawing. The region close to the carboxyl terminus of the large subunit was digested by extracellularly added papain and, as a result, an 18-kDa carboxyl-terminal fragment was detected. Thus the carboxyl-terminal region of the large subunit is cytoplasmic and/or buried in the membrane, and the region around residues 369-398 is exposed on the cell surface. In contrast to the large subunits, the small subunit in neutrophils was resistant to any of the proteinases tested, although the subunit in membrane or Triton-solubilized preparation was digestible with papain. These results indicate that the large subunit of cytochrome b558 is a transmembrane protein with at least two regions exposed on the cell surface and that the carboxyl terminus of this subunit and both termini of the small subunit are exposed to the cytoplasmic side.     

A polymorphic motif in the small subunit of ADP-glucose pyrophosphorylase modulates interactions between the small and large subunits

The heterotetrameric, allosterically regulated enzyme, adenosine-5'-diphosphoglucose pyrophosphorylase (AGPase) catalyzes the rate-limiting step in starch synthesis. Despite vast differences in allosteric properties and a long evolutionary separation, heterotetramers of potato small subunit and maize large subunit have activity comparable to either parent in an Escherichia coli expression system. In contrast, co-expression of maize small subunit with the potato large subunit produces little activity as judged by in vivo activity stain. To pinpoint the region responsible for differential activity, we expressed chimeric maize/potato small subunits in E. coli. This identified a 55-amino acid motif of the potato small subunit that is critical for glycogen production when expressed with the potato large subunit. Potato and maize small subunit sequences differ at five amino acids in this motif. Replacement experiments revealed that at least four amino acids of maize origin were required to reduce staining. An AGPase composed of a chimeric potato small subunit containing the 55-amino acid maize motif with the potato large subunit exhibited substantially less affinity for the substrates, glucose-1-phosphate and ATP and an increased Ka for the activator, 3-phosphoglyceric acid. Placement of the potato motif into the maize small subunit restored glycogen synthesis with the potato large subunit. Hence, a small polymorphic motif within the small subunit influences both catalytic and allosteric properties by modulating subunit interactions.     

Cover Picture

Freeze‐etch images of ribosome‐translocon complex in chicken retinal pigment epithelial cells, where the ribosomal small subunit, large subunit, small translocon and large translocon are colored in yellow, blue, red and green respectively. The ribosomal small subunit is aligned over small translocon, and the ribosomal large subunit is over the large translocon as well. Reproduced from Miyaguchi and Reese (1996) with permission of Elsevier.     

Carboxyl-terminal truncation and site-directed mutagenesis of the EF hand structure-domain of the small subunit of rabbit calcium-dependent protease

A mutant of the small subunit of rabbit calcium-dependent protease lacking the amino-terminal one-fourth produced in Escherichia coli could associate with the native large subunit to exert protease activity. Deletion of a few carboxyl-terminal residues of this variant small subunit caused a significant decrease in the protease activity after reconstitution with the native large subunit. Loss of the fourth EF hand loop region by further truncation of the variant small subunit made interaction with the large subunit impossible. The calcium binding assay revealed that the fourth EF hand structure of the rabbit small subunit, which has been previously demonstrated to possess two calcium-binding sites, can bind calcium ions. Furthermore it was established by site-directed mutagenesis that the first EF hand structure, in addition to the fourth one, is capable of binding calcium ions. Replacement of amino acids in the EF hand structure affected interaction with the native large subunit or the calcium sensitivity of the reconstituted product. These findings indicate that the EF hand structure-domain of the small subunit is essential for the full protease activity.     

Limited autolysis of calcium-activated neutral protease (CANP): reduction of the Ca2+-requirement is due to the NH2-terminal processing of the large subunit

Calcium-activated neutral protease (rabbit mCANP), composed of large and small subunits, was converted to a lower-Ca2+-requiring form (derived microCANP) by limited autolysis in the presence of Ca2+. The NH2-terminal regions of the two subunits of mCANP were cleaved by autolysis, but the COOH-termini remained intact after autolysis. When native mCANP or derived microCANP was dissociated into subunits, the proteolytic activity of the large subunit was reduced to 2-5% of that of the native dimeric enzyme. The Ca2+-sensitivity of one hybrid CANP reconstituted from the large subunit of derived microCANP and the small subunit of native mCANP was similar to that of derived microCANP. However, the other hybrid molecule composed of the large subunit of native mCANP and the small subunit of derived microCANP required a high concentration of Ca2+ for activity, like native mCANP. These results indicate that the Ca2+-sensitivity of derived microCANP is determined by the structural change of the large subunit resulting from loss of its NH2-terminal region. The autolysis of the small subunit apparently has no effect on the reduction of the Ca2+-requirement.     

Methyltransferase and subunit association domains of vaccinia virus mRNA capping enzyme.

RNA triphosphatase, RNA guanylyltransferase, and RNA (guanine-N7-)-methyltransferase activities are associated with the vaccinia virus mRNA capping enzyme, a heterodimeric protein containing polypeptides of M(r) 95,000 and 31,000. Although the RNA triphosphatase and RNA guanylyltransferase domains have been localized to a M(r) 59,000 fragment of the capping enzyme large subunit, the location of the methyltransferase domain within the protein and the catalytic role of individual subunits in methyl group transfer remain unclear. In the present work, through the study of methyltransferase activity of truncated forms of capping enzyme translated in vitro in a rabbit reticulocyte lysate, we have localized the methyltransferase domain to a complex consisting of the small subunit and the carboxyl-terminal portion of the large subunit. The M(r) 31,000 subunit translated alone was not sufficient for methyltransferase activity. This requirement for both subunits may explain the tight physical association of the two polypeptides in vivo. We have recreated the association of the large and small enzyme subunits in vitro through the translation of synthetic mRNAs encoding the two polypeptides. Study of the ability of deleted versions of the large subunit to bind the small subunit, as detected by co-immunoprecipitation, defined a 347-amino acid carboxyl-terminal region of the large subunit that was sufficient for heterodimerization. Colocalization within the large subunit of the methyltransferase and subunit association domains suggests that dimerization of the subunits may be required for methyltransferase activity.     

The first complete monogenean ribosomal RNA gene operon: sequence and secondary structure of the Gyrodactylus salaris Malmberg, 1957, large subunit ribosomal RNA gene

The sequence of the Gyrodactylus salaris Malmberg, 1957, large subunit, or 28S, ribosomal RNA (rRNA) gene has been determined. This gene is the final portion of the Gyrodactylus rRNA gene operon to be sequenced and results in the first complete sequence of all rRNA genes and spacers from a monogenean. The nucleotide sequence was used to predict the secondary structure of the large subunit rRNA, and regions of conserved and variable sequence and structure were identified. The site where the 5' terminus of the 5.8S rRNA binds to a region within the large subunit rRNA was predicted and complements the anticipated interaction of the 3' terminus of the 5.8S with the 5' terminus of the large subunit rRNA. The large subunit gene may be useful in phylogenetic analysis of the Monogenea or Platyhelminthes and comparisons with other eukaryotes. The variable domains C and H may be most suitable for this purpose.     

Membrane targeting and translocation of bacterial hydrogenases

Periplasmic or membrane-bound bacterial hydrogenases are generally composed of a small subunit and a large subunit. The small subunit contains a peculiar N-terminal twin-arginine signal peptide, whereas the large subunit lacks any known targeting signal for export. Genetic and biochemistry data support the assumption that the large subunit is cotranslocated with the small subunit across the cytoplasmic membrane. Indeed, the signal peptide carried by the small subunit directs both the small and the large subunits to the recently identified Mtt/Tat pathway, independently of the Sec machinery. In addition, the twin-arginine signal peptide of hydrogenase is capable of directing protein import into the thylakoidal lumen of chloroplasts via the homologous deltapH-driven pathway, which is independent of the Sec machinery. Therefore, the translocation of hydrogenase shares characteristics with the deltapH-driven import pathway in terms of Sec-independence and requirement for the twin-arginine signal peptide, and with protein import into peroxisomes in a "piggyback" fashion.     

A model for the spatial arrangement of the proteins in the large subunit of the Escherichia coli ribosome.

A three-dimensional model for the arrangement of 29 of the 33 proteins from the Escherichia coli large ribosomal subunit has been generated by interactive computer graphics. The topographical information that served as input in the model building process was obtained by combining the immunoelectron microscopically determined network of epitope-epitope distances on the surface of the large ribosomal subunit with in situ protein-protein cross-linking data. These two independent sets of data were shown to be compatible by geometric analysis, thus allowing the construction of an inherently consistent model. The model shows (i) that the lower third of the large subunit is protein-poor, (ii) that proteins known to be functionally involved in peptide bond formation and translocation are clustered in two separate regions, (iii) that proteins functionally interdependent during the self-assembly of the large subunit are close neighbours in the mature subunit and (iv) that proteins forming the early assembly nucleus are grouped together in a distinct region at the 'back' of the subunit.