Delayed Osmotic Effect on in Vitro Assembly of RuBisCO : Relationship to Large Subunit-Binding Protein Complex Dissociation

Higher plant ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) cannot reassociate after dissociation, and its subunits do not assemble into active RuBisCO when synthesized in Escherichia coli. Newly synthesized subunits of RuBisCO are associated with a high molecular weight binding protein complex in pea chloroplasts. The immediate donor for large subunits which assemble into RuBisCO is a low molecular weight complex which may be derived from the high molecular weight binding protein complex. When the high molecular weight binding protein complex is diluted, it tends to dissociate, forming low molecular weight complexes. When the large subunit-binding protein complexes were examined after in organello protein synthesis, it was found that the low molecular weight complexes were more abundant when protein synthesis was carried out under hypotonic conditions. This increase in the assembly competent population of low molecular weight large subunit complexes can account for the increased amount of in vitro RuBisCO assembly which occurs under these conditions. The data indicate that the assembly of large subunits into RuBisCO is a function of the aggregation state of the large subunit binding protein complex during protein synthesis. This implies that the binding protein exerts its effects during or shortly after large subunit synthesis.     

The Saccharomyces cerevisiae mitochondrial succinate:ubiquinone oxidoreductase

The Saccharomyces cerevisiae succinate dehydrogenase (SDH) provides an excellent model system for studying the assembly, structure, and function of a mitochondrial succinate:quinone oxidoreductase. The powerful combination of genetic and biochemical approaches is better developed in yeast than in other eukaryotes. The yeast protein is strikingly similar to other family members in the structural and catalytic properties of its subunits. However, the membrane domain and particularly the role of the single heme in combination with two ubiquinone-binding sites need further investigation. The assembly of subunits and cofactors that occurs to produce new holoenzyme molecules is a complex process that relies on molecular chaperones. The yeast SDH provides the best opportunity for understanding the biogenesis of this family of iron–sulfur flavoproteins.     

Issue Information

Complex II [succinate dehydrogenase (succinate‐ubiquinone oxidoreductase); EC 1.3.5.1; SDH] is the only enzyme shared by both the electron transport chain and the tricarboxylic acid (TCA) cycle in mitochondria. Complex II in plants is considered unusual because of its accessory subunits (SDH5–SDH8), in addition to the catalytic subunits of SDH found in all eukaryotes (SDH1–SDH4). Here, we review compositional and phylogenetic analysis and biochemical dissection studies to both clarify the presence and propose a role for these subunits. We also consider the wider functional and phylogenetic evidence for SDH assembly factors and the reports from plants on the control of SDH1 flavination and SDH1–SDH2 interaction. Plant complex II has been shown to influence stomatal opening, the plant defense response and reactive oxygen species‐dependent stress responses. Signaling molecules such as salicyclic acid (SA) and nitric oxide (NO) are also reported to interact with the ubiquinone (UQ) binding site of SDH, influencing signaling transduction in plants. Future directions for SDH research in plants and the specific roles of its different subunits and assembly factors are suggested, including the potential for reverse electron transport to explain the succinate‐dependent production of reactive oxygen species in plants and new avenues to explore the evolution of plant mitochondrial complex II and its utility.     

Assembly of the cytochrome bo3 complex

An understanding of the mechanisms that govern the assembly of macromolecular protein complexes is fundamental for studying their function and regulation. With this in mind, we have determined the assembly pathway for the membrane-embedded cytochrome bo(3) of Escherichia coli. We show that there is a preferred order of assembly, where subunits III and IV assemble first, followed by subunit I and finally subunit II. We also show that cofactor insertion catalyses assembly. These findings provide novel insights into the biogenesis of this model membrane protein complex.     

Incorporation of Large Subunits into Ribulose Bisphosphate Carboxylase in Chloroplast Extracts : Influence of Added Small Subunits and of Conditions during Synthesis

The incorporation of newly synthesized large subunits into ribulose bisphosphate carboxylase/oxygenase (RuBisCO) in pea chloroplast extracts occurs at the expense of intermediate forms of the large subunit which are complexed with a binding protein. Most subunits of this binding protein are found in dodecameric complexes in chloroplast extracts. Addition of small subunits to these extracts results in approximately 40 to 60% increased incorporation of newly made large subunits into RuBisCO at low or zero concentrations of ATP, but is without significant effect at high concentrations of ATP, a condition in which the dodecameric binding protein complex is dissociated into subunits. Overall, these data support the assumption that the incorporation of large subunits into RuBisCO in chloroplast extracts reflects de novo assembly rather than `mere' exchange of subunits. The in vitro assembly of large subunits into RuBisCO is a function of the conditions under which the large subunits are synthesized in organello. When the large subunits are made in chloroplasts suspended in 188 millimolar sorbitol, they are approximately 2- to 3-fold better able to assemble into RuBisCO when subsequently incubated in vitro than when they are synthesized in chloroplasts suspended in 375 millimolar sorbitol. This observation indicates that mere synthesis of large subunits is not sufficient to confer maximal assembly competence on large subunits.     

Synthesis and assembly of the cytochrome b-f complex in higher plants

The cytochrome b-f complex is composed of four polypeptide subunits, three of which, cytochrome f, cytochrome b-563 and subunit IV, are encoded in chloroplast DNA and synthesised within the chloroplast, and the fourth, the Rieske FeS protein, is encoded in nuclear DNA and synthesised in the cytoplasm. The assembly of the cytochrome b-f complex therefore requires the interaction of subunits encoded by different genomes. A key role for the nuclear-encoded Rieske FeS protein in the assembly of the complex is suggested by a study of cytochrome b-f complex mutants. The assembly of individual subunits of the complex may be regulated by the availability of prosthetic groups. The genes for the chloroplast-encoded subunits and cDNA clones for the Rieske FeS protein have been isolated and characterised. Cytochrome f and the Rieske FeS protein are synthesised initially with N-terminal presequences required for their correct assembly within the chloroplast. The deduced amino acid sequences of the four subunits have been used to suggest models for the arrangement of the polypeptides in the thylakoid membrane.     

Molecular pathogenesis of tumorigenesis caused by succinate dehydrogenase defect

Succinate dehydrogenase (SDH), also named as complex II or succinate:quinone oxidoreductases (SQR) is a critical enzyme in bioenergetics and metabolism. This is because the enzyme is located at the intersection of oxidative phosphorylation and tricarboxylic acid cycle (TCA); the two major pathways involved in generating energy within cells. SDH is composed of 4 subunits and is assembled through a multi-step process with the aid of assembly factors. Not surprisingly malfunction of this enzyme has marked repercussions in metabolism leading to devastating tumors such as paraganglioma and pheochromocytoma. It is already known that mutations in the genes encoding subunits lead to tumorigenesis, but recent discoveries have indicated that mutations in the genes encoding the assembly factors also contribute to tumorigenesis. The mechanisms of pathogenesis of tumorigenesis have not been fully understood. However, a multitude of signaling pathways including succinate signaling was determined. We, here discuss how defective SDH may lead to tumor development at the molecular level and describe how yeast, as a model system, has contributed to understanding the molecular pathogenesis of tumorigenesis resulting from defective SDH.     

Five Entry Points of the Mitochondrially Encoded Subunits in Mammalian Complex I Assembly

Complex I (CI) is the largest enzyme of the mammalian mitochondrial respiratory chain. The biogenesis of the complex is a very complex process due to its large size and number of subunits (45 subunits). The situation is further complicated due to the fact that its subunits have a double genomic origin, as seven of them are encoded by the mitochondrial DNA. Understanding of the assembly process and characterization of the involved factors has advanced very much in the last years. However, until now, a key part of the process, that is, how and at which step the mitochondrially encoded CI subunits (ND subunits) are incorporated in the CI assembly process, was not known. Analyses of several mouse cell lines mutated for three ND subunits allowed us to determine the importance of each one for complex assembly/stability and that there are five different steps within the assembly pathway in which some mitochondrially encoded CI subunit is incorporated.Complex I (CI) (NADH-ubiquinone oxidoreductase; EC 1.6.5.3) is one of the main electron entry points in the mitochondrial respiratory electron transport chain catalyzing the oxidation of NADH to reduce ubiquinone to ubiquinol (31, 39, 40), contributing to the proton motive force to synthesize ATP by the process called oxidative phosphorylation (OXPHOS).CI assembly is a difficult problem to address due to the large size of the complex and its dual genomic nature, as 7 out of its 45 subunits are encoded by the mitochondrial DNA (mtDNA) (10, 11). Until very recently, mammalian CI assembly was explained using two different and apparently contradictory models. One model was proposed by following the time course of formation of CI intermediates in human cells in culture once mitochondrial protein synthesis had recovered after its inhibition by doxycycline (36). Based on these observations, human CI was proposed to be assembled through two different modules corresponding to the membrane and peripheral arms. The other model was proposed after analysis of a cohort of four CI-deficient patients in which seven putative assembly intermediates containing a combination of both peripheral- and membrane arm subunits were identified. Thus, an assembly pathway in which the peripheral- and membrane arm subassemblies came together before the completion of each of the arms was proposed (4). However, the most recent studies have refined the previous models and propose an overlapping view of the process. One study, by green fluorescent protein (GFP) tagging of the NDUFS3 subunit, identified six peripheral-arm intermediates. The second and third smaller NDUFS3-containing subassemblies were accumulated and could not advance into higher-molecular-mass species when mitochondrial protein synthesis was inhibited, thus determining the entry point of the mitochondrially encoded subunits in the CI assembly pathway (37). The most recent study analyzed the incorporation of the mitochondrial subunits in a time course to the fully assembled CI and, on the other hand, the incorporation of the nuclear subunits by importing them into isolated mitochondria (24). Although these two models differ in the order in which some subunits are incorporated, they agree on the general human CI assembly pathway, which takes place via evolutionarily conserved modular subassemblies (14, 25, 28, 37).However, the specific entry points of all the mtDNA-encoded CI subunits (ND subunits) in the CI assembly pathway and their roles in the stability of the complex remained to be clarified. Structural studies related to mutations in the ND subunits in pathological cases have given some hints as to the importance of each of them for CI assembly/stability. In this case, defects in specific ND subunits do not have the same effect: ND1, ND4, and ND6 seem to be fundamental to CI assembly, while ND3 and ND5 are important for its activity but not for assembly. On the other hand, mutations in ND2 alter CI assembly, with abnormal intermediate accumulation (19).In this article, we present new insights into the roles of the ND subunits by using mouse cells deficient for ND4, ND6, and a combination of ND6 and ND5. This study has allowed us to propose the five different entry points by which the mtDNA-encoded subunits are sequentially incorporated into the CI assembly pathway, completing the current view of the process. We conclude that ND4 and ND6 are required for the proper function and assembly of CI, although at different degrees due to their different entry points and roles in the CI assembly pathway.     

The four subunits of mitochondrial respiratory complex II are encoded by multiple nuclear genes and targeted to mitochondria in Arabidopsis thaliana

Mitochondrial respiratory complex II contains four subunits: a flavoprotein (SDH1), an iron-sulphur subunit (SDH2) and two membrane anchor subunits (SDH3 and SDH4). We have found that in Arabidopsis thaliana SDH1 and SDH3 are encoded by two, and SDH4 by one nuclear genes, respectively. All these encoded polypeptides are found to be imported into isolated plant mitochondria. While both SDH1 proteins are highly conserved when compared to their counterparts in other organisms, SDH3 and SDH4 share little similarity with non-plant homologues. Expression of SDH1-1, SDH3 and SDH4 genes was detected in all tissues analysed, with the highest steady-state mRNA levels found in flowers and inflorescences. In contrast, the second SDH1 gene (SDH1-2) is expressed at a low level.     

重组细菌多药外排泵AcrAB-TolC的转运功能和动态组装

【背景】多药外排泵多以膜蛋白复合体形式存在,是导致细菌耐药性的重要原因。外排泵的转运功能和组装过程对于细菌耐药性和药物研发具有重要意义。【目的】以多药外排泵耐药结节细胞分化家族(resistance-nodulation-division family, RND)的重要成员AcrAB-TolC复合体为对象,研究其转运活性和体外组装特性。【方法】基于大肠杆菌AcrAB-TolC复合体基因序列,分别构建含有acrA、acrB、tolC基因的重组质粒,表达和纯化复合体各亚基,利用荧光光谱、等温滴定量热法(isothermal titration calorimetry,ITC)等技术分析复合体及亚基的转运功能、亚基与底物的相互作用,以及亚基间的相互作用和动态装配。【结果】实现了AcrAB-TolC复合体各组分的表达和纯化(纯度>98%),证实表达有各组分的活细胞提高了对于溴化乙锭(ethidium bromide,EB)的转运活性,并发现群体感应效应信号分子N-hexanoyl-L-homoserine lactone (C6-HSL)能够抑制AcrB、TolC对于EB的转运活性。ITC结果进一步证实了C6-HSL与AcrB、TolC的相互作用。ITC结果还显示AcrA分别与AcrB、TolC之间存在明显的相互作用,而AcrB与TolC之间无明显的相互作用。在体外装配实验中观测到AcrAB-TolC亚基的单分子荧光强度随时间增加,证实了复合体亚基在膜上的动态组装过程。【结论】实现了AcrAB-TolC外排泵及亚基的表达和纯化,证实了AcrAB-TolC对底物的转运活性及与底物的相互作用,观察到AcrAB-TolC的动态组装过程。以上结果为研究多药外排泵导致的细菌耐药性及抗菌策略具有重要意义。     

Analysis of mitochondrial subunit assembly into respiratory chain complexes using Blue Native polyacrylamide gel electrophoresis

The mitochondrial respiratory chain consists of multi-subunit protein complexes embedded in the inner membrane. Although the majority of subunits are encoded by nuclear genes and are imported into mitochondria, 13 subunits in humans are encoded by mitochondrial DNA. The coordinated assembly of subunits encoded from two genomes is a poorly understood process, with assembly pathway defects being a major determinant in mitochondrial disease. In this study, we monitored the assembly of human respiratory complexes using radiolabeled, mitochondrially encoded subunits in conjunction with Blue Native polyacrylamide gel electrophoresis. The efficiency of assembly was found to differ markedly between complexes, and intermediate complexes containing newly synthesized mitochondrial DNA-encoded subunits could be observed for complexes I, III, and IV. In particular, we detected human cytochrome b as a monomer and as a component of a novel approximately 120 kDa intermediate complex at early chase times before being totally assembled into mature complex III. Furthermore, we show that this approach is highly suited for the rapid detection of respiratory complex assembly defects in fibroblasts from patients with mitochondrial disease and, thus, has potential diagnostic applications.     

Translation Initiation Requires Cell Division Cycle 123 (Cdc123) to Facilitate Biogenesis of the Eukaryotic Initiation Factor 2 (eIF2)

The eukaryotic translation initiation factor 2 (eIF2) is central to the onset of protein synthesis and its modulation in response to physiological demands. eIF2, a heterotrimeric G-protein, is activated by guanine nucleotide exchange to deliver the initiator methionyl-tRNA to the ribosome. Here we report that assembly of the eIF2 complex in vivo depends on Cdc123, a cell proliferation protein conserved among eukaryotes. Mutations of CDC123 in budding yeast reduced the association of eIF2 subunits, diminished polysome levels, and increased GCN4 expression indicating that Cdc123 is critical for eIF2 activity. Cdc123 bound the unassembled eIF2γ subunit, but not the eIF2 complex, and the C-terminal domain III region of eIF2γ was both necessary and sufficient for Cdc123 binding. Alterations of the binding site revealed a strict correlation between Cdc123 binding, the biological function of eIF2γ, and its ability to assemble with eIF2α and eIF2β. Interestingly, high levels of Cdc123 neutralized the assembly defect and restored the biological function of an eIF2γ mutant. Moreover, the combined overexpression of eIF2 subunits rescued an otherwise inviable cdc123 deletion mutant. Thus, Cdc123 is a specific eIF2 assembly factor indispensable for the onset of protein synthesis. Human Cdc123 is encoded by a disease risk locus, and, therefore, eIF2 biogenesis control by Cdc123 may prove relevant for normal cell physiology and human health. This work identifies a novel step in the eukaryotic translation initiation pathway and assigns a biochemical function to a protein that is essential for growth and viability of eukaryotic cells.     

Biogenesis of the cytochrome bc1 complex and role of assembly factors

The cytochrome bc₁ complex is an essential component of the electron transport chain in most prokaryotes and in eukaryotic mitochondria. The catalytic subunits of the complex that are responsible for its redox functions are largely conserved across kingdoms. In eukarya, the bc₁ complex contains supernumerary subunits in addition to the catalytic core, and the biogenesis of the functional bc₁ complex occurs as a modular assembly pathway. Individual steps of this biogenesis have been recently investigated and are discussed in this review with an emphasis on the assembly of the bc₁ complex in the model eukaryote Saccharomyces cerevisiae. Additionally, a number of assembly factors have been recently identified. Their roles in bc₁ complex biogenesis are described, with special emphasis on the maturation and topogenesis of the yeast Rieske iron–sulfur protein and its role in completing the assembly of functional bc₁ complex. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

Reprint of: Biogenesis of the cytochrome bc1 complex and role of assembly factors

The cytochrome bc₁ complex is an essential component of the electron transport chain in most prokaryotes and in eukaryotic mitochondria. The catalytic subunits of the complex that are responsible for its redox functions are largely conserved across kingdoms. In eukarya, the bc₁ complex contains supernumerary subunits in addition to the catalytic core, and the biogenesis of the functional bc₁ complex occurs as a modular assembly pathway. Individual steps of this biogenesis have been recently investigated and are discussed in this review with an emphasis on the assembly of the bc₁ complex in the model eukaryote Saccharomyces cerevisiae. Additionally, a number of assembly factors have been recently identified. Their roles in bc₁ complex biogenesis are described, with special emphasis on the maturation and topogenesis of the yeast Rieske iron–sulfur protein and its role in completing the assembly of functional bc₁ complex. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

Flavinylation and Assembly of Succinate Dehydrogenase Are Dependent on the C-terminal Tail of the Flavoprotein Subunit

The enzymatic function of succinate dehydrogenase (SDH) is dependent on covalent attachment of FAD on the ∼70-kDa flavoprotein subunit Sdh1. We show presently that flavinylation of the Sdh1 subunit of succinate dehydrogenase is dependent on a set of two spatially close C-terminal arginine residues that are distant from the FAD binding site. Mutation of Arg⁵⁸² in yeast Sdh1 precludes flavinylation as well as assembly of the tetrameric enzyme complex. Mutation of Arg⁶³⁸ compromises SDH function only when present in combination with a Cys⁶³⁰ substitution. Mutations of either Arg⁵⁸² or Arg⁶³⁸/Cys⁶³⁰ do not markedly destabilize the Sdh1 polypeptide; however, the steady-state level of Sdh5 is markedly attenuated in the Sdh1 mutant cells. With each mutant Sdh1, second-site Sdh1 suppressor mutations were recovered in Sdh1 permitting flavinylation, stabilization of Sdh5 and SDH tetramer assembly. SDH assembly appears to require FAD binding but not necessarily covalent FAD attachment. The Arg residues may be important not only for Sdh5 association but also in the recruitment and/or guidance of FAD and or succinate to the substrate site for the flavinylation reaction. The impaired assembly of SDH with the C-terminal Sdh1 mutants suggests that FAD binding is important to stabilize the Sdh1 conformation enabling association with Sdh2 and the membrane anchor subunits.     

Crystal structure of a new benzoic acid inhibitor of influenza neuraminidase bound with a new tilt induced by overpacking subsite C6

Background

The quaternary structure of eukaryotic NADH:ubiquinone oxidoreductase (complex I), the largest complex of the oxidative phosphorylation, is still mostly unresolved. Furthermore, it is unknown where transiently bound assembly factors interact with complex I. We therefore asked whether the evolution of complex I contains information about its 3D topology and the binding positions of its assembly factors. We approached these questions by correlating the evolutionary rates of eukaryotic complex I subunits using the mirror-tree method and mapping the results into a 3D representation by multidimensional scaling.

Results

More than 60% of the evolutionary correlation among the conserved seven subunits of the complex I matrix arm can be explained by the physical distance between the subunits. The three-dimensional evolutionary model of the eukaryotic conserved matrix arm has a striking similarity to the matrix arm quaternary structure in the bacterium Thermus thermophilus (rmsd=19 ?) and supports the previous finding that in eukaryotes the N-module is turned relative to the Q-module when compared to bacteria. By contrast, the evolutionary rates contained little information about the structure of the membrane arm. A large evolutionary model of 45 subunits and assembly factors allows to predict subunit positions and interactions (rmsd = 52.6 ?). The model supports an interaction of NDUFAF3, C8orf38 and C2orf56 during the assembly of the proximal matrix arm and the membrane arm. The model further suggests a tight relationship between the assembly factor NUBPL and NDUFA2, which both have been linked to iron-sulfur cluster assembly, as well as between NDUFA12 and its paralog, the assembly factor NDUFAF2.

Conclusions

The physical distance between subunits of complex I is a major correlate of the rate of protein evolution in the complex I matrix arm and is sufficient to infer parts of the complex??s structure with high accuracy. The resulting evolutionary model predicts the positions of a number of subunits and assembly factors.     

Assembly of complex organelles: pilus biogenesis in gram-negative bacteria as a model system

Pathogenic bacteria assemble a variety of adhesive structures on their surface for attachment to host cells. Some of these structures are quite complex. For example, the hair-like organelles known as pili or fimbriae are generally composed of several components and often exhibit composite morphologies. In gram-negative bacteria assembly of pili requires that the subunits cross the cytoplasmic membrane, fold correctly in the periplasm, target to the outer membrane, assemble into an ordered structure, and cross the outer membrane to the cell surface. Thus, pilus biogenesis provides a model for a number of basic biological problems including protein folding, trafficking, secretion, and the ordered assembly of proteins into complex structures. P pilus biogenesis represents one of the best-understood pilus systems. P pili are produced by 80-90% of all pyelonephritic Escherichia coli and are a major virulence determinant for urinary tract infections. Two specialized assembly factors known as the periplasmic chaperone and outer membrane usher are required for P pilus assembly. A chaperone/usher pathway is now known to be required for the biogenesis of more than 30 different adhesive structures in diverse gram-negative pathogenic bacteria. Elucidation of the chaperone/usher pathway was brought about through a powerful combination of molecular, biochemical, and biophysical techniques. This review discusses these approaches as they relate to pilus assembly, with an emphasis on newer techniques.     

ATP-released large subunits participate in the assembly of RuBP carboxylase

Preincubation of 35S-methionine-labeled chloroplast extracts with ATP at 0 degree C potentiates the subsequent assembly of labeled large subunits into RuBPCase . This is correlated with the dissociation of newly synthesized large subunits from the 29S large subunit binding protein complex. These released large subunits then assemble into RuBPCase in a second, nucleotide-stimulated reaction. The data demonstrate that the 29S complex can play an active role in the assembly of RuBPCase .     

Human CIA30 is involved in the early assembly of mitochondrial complex I and mutations in its gene cause disease

In humans, complex I of the respiratory chain is composed of seven mitochondrial DNA (mtDNA)-encoded and 38 nuclear-encoded subunits that assemble together in a process that is poorly defined. To date, only two complex I assembly factors have been identified and how each functions is not clear. Here, we show that the human complex I assembly factor CIA30 (complex I intermediate associated protein) associates with newly translated mtDNA-encoded complex I subunits at early stages in their assembly before dissociating at a later stage. Using antibodies we identified a CIA30-deficient patient who presented with cardioencephalomyopathy and reduced levels and activity of complex I. Genetic analysis revealed the patient had mutations in both alleles of the NDUFAF1 gene that encodes CIA30. Complex I assembly in patient cells was defective at early stages with subunits being degraded. Complementing the deficiency in patient fibroblasts with normal CIA30 using a novel lentiviral system restored steady-state complex I levels. Our results indicate that CIA30 is a crucial component in the early assembly of complex I and mutations in its gene can cause mitochondrial disease.