Targeted methylation of CMV and E1A viral promoters

Recombinant thermosomes from the Acidianus tengchongensis strain S5^T were purified to homogeneity and assembled in vitro into homo-oligomers (rATcpnα or rATcpnβ) and hetero-oligomers (rATcpnαβ). The symmetries of these complexes were determined by electron microscopy and image analysis. The rATcpnα homo-oligomer was shown to possess 8-fold symmetry while both rATcpnβ and rATcpnαβ oligomers adopted 9-fold symmetry. rATcpnαβ oligomers were shown to contain the α and β subunits in a 1:2 ratio. All of the complexes prevented the irreversible inactivation of yeast alcohol dehydrogenase at 55 °C and completely prevented the formation of aggregates during thermal inactivation of citrate synthase at 45 °C. All rATcpn complexes showed trace ATP hydrolysis activity. Furthermore, rATcpnβ sequestered fully chemically denatured substrates (GFP and thermophilic malic dehydrogenase) in vitro without refolding them in an ATP-dependent manner. This property is similar to previously reported properties of chaperonins from Sulfolobus tokodaii and Sulfolobus acidocaldarius. These features are consistent with the slow growth rates of these species of archaea in their native environment.     

Crystal structure of group II chaperonin in the open state

Thermosomes are group II chaperonins responsible for protein refolding in an ATP-dependent manner. Little is known regarding the conformational changes of thermosomes during their functional cycle due to a lack of high-resolution structure in the open state. Here, we report the first complete crystal structure of thermosome (rATcpnβ) in the open state from Acidianus tengchongensis. There is a ～30° rotation of the apical and lid domains compared with the previous closed structure. Besides, the structure reveals a conspicuous hydrophobic patch in the lid domain, and residues locating in this patch are conserved across species. Both the closed and open forms of rATcpnβ were also reconstructed by electron microscopy (EM). Structural fitting revealed the detailed conformational change from the open to the closed state. Structural comparison as well as protease K digestion indicated only ATP binding without hydrolysis does not induce chamber closure of thermosome.     

ATPase cycle of an archaeal chaperonin

Recent structural data imply differences in allosteric behavior of the group I chaperonins, typified by GroEL from Escherichia coli, and the group II chaperonins, which comprise archaeal thermosome and eukaryotic TRiC/CCT. Therefore, this study addresses the mechanism of interaction of adenine nucleotides with recombinant alpha-only and native alphabeta-thermosomes from Thermoplasma acidophilum, which also enables us to analyze the role of the heterooligomeric composition of the natural thermosome. Although all subunits of the alpha-only thermosome seem to bind nucleotides tightly and independently, the native chaperonin has two different classes of ATP-binding sites. Furthermore, for the alpha-only thermosome, the steady-state ATPase rate is determined by the cleavage reaction itself, whereas, for the alphabeta-thermosome, the rate-limiting step is associated with a post-hydrolysis isomerisation into a non-covalent ADP*P(i) species prior to the release of the gamma-phosphate group. After half-saturation with ATP, a negative cooperativity in hydrolysis is observed for both thermosomes. The effect of Mg(2+) and K(+) nucleotide cycling is documented. We conclude that archaeal chaperonins have unique allosteric properties and discuss them in the light of the mechanism established for the group I chaperonins.     

Conformational rearrangements of an archaeal chaperonin upon ATPase cycling

Chaperonins are double-ring protein assemblies with a central cavity that provides a sequestered environment for in vivo protein folding. Their reaction cycle is thought to consist of a nucleotide-regulated alternation between an open substrate-acceptor state and a closed folding-active state. The cavity of ATP-charged group I chaperonins, typified by Escherichia coli GroEL [1], is sealed off by a co-chaperonin, whereas group II chaperonins--the archaeal thermosome and eukaryotic TRiC/CCT [2]--possess a built-in lid [3-5]. The mechanism of the lid's rearrangements requires clarification, as even in the absence of nucleotides, thermosomes of Thermoplama acidophilum appear open in vitrified ice [6] and closed in crystals [4]. Here we analyze the conformation of the thermosome at each step of the ATPase cycle by small-angle neutron scattering. The apo-chaperonin is open in solution, and ATP binding induces its further expansion. Closure seems to occur during ATP hydrolysis and before phosphate release, and represents the rate-limiting step of the cycle. The same closure can be triggered by the crystallization buffer. Thus, the allosteric regulation of group II chaperonins appears different from that of their group I counterparts.     

Coexistence of group I and group II chaperonins in the archaeon Methanosarcina mazei

Two distantly related classes of cylindrical chaperonin complexes assist in the folding of newly synthesized and stress-denatured proteins in an ATP-dependent manner. Group I chaperonins are thought to be restricted to the cytosol of bacteria and to mitochondria and chloroplasts, whereas the group II chaperonins are found in the archaeal and eukaryotic cytosol. Here we show that members of the archaeal genus Methanosarcina co-express both the complete group I (GroEL/GroES) and group II (thermosome/prefoldin) chaperonin systems in their cytosol. These mesophilic archaea have acquired between 20 and 35% of their genes by lateral gene transfer from bacteria. In Methanosarcina mazei G?1, both chaperonins are similarly abundant and are moderately induced under heat stress. The M. mazei GroEL/GroES proteins have the structural features of their bacterial counterparts. The thermosome contains three paralogous subunits, alpha, beta, and gamma, which assemble preferentially at a molar ratio of 2:1:1. As shown in vitro, the assembly reaction is dependent on ATP/Mg2+ or ADP/Mg2+ and the regulatory role of the beta subunit. The co-existence of both chaperonin systems in the same cellular compartment suggests the Methanosarcina species as useful model systems in studying the differential substrate specificity of the group I and II chaperonins and in elucidating how newly synthesized proteins are sorted from the ribosome to the proper chaperonin for folding.     

The Dynamic Conformational Cycle of the Group I Chaperonin C-Termini Revealed via Molecular Dynamics Simulation

Chaperonins are large ring shaped oligomers that facilitate protein folding by encapsulation within a central cavity. All chaperonins possess flexible C-termini which protrude from the equatorial domain of each subunit into the central cavity. Biochemical evidence suggests that the termini play an important role in the allosteric regulation of the ATPase cycle, in substrate folding and in complex assembly and stability. Despite the tremendous wealth of structural data available for numerous orthologous chaperonins, little structural information is available regarding the residues within the C-terminus. Herein, molecular dynamics simulations are presented which localize the termini throughout the nucleotide cycle of the group I chaperonin, GroE, from Escherichia coli. The simulation results predict that the termini undergo a heretofore unappreciated conformational cycle which is coupled to the nucleotide state of the enzyme. As such, these results have profound implications for the mechanism by which GroE utilizes nucleotide and folds client proteins.     

Assembly of chaperonin complexes

Chaperonins are a subclass of molecular chaperones that assist both the folding of newly synthesized proteins and the maintenance of proteins in a folded state during periods of stress. The best studied members of this family are the type I chaperonins, occurring in bacteria and evolutionarily derived organelles. Type II chaperonins occur in archaea and the eukaryotic cytosol. An intriguing question pertains to the mechanism by which chaperonins themselves are folded and assembled into functional oligomers. The available evidence for the assembly/disassembly of type I and II chaperonins points to a process that is highly cooperative and suggests a prominent role for nucleotides. Interestingly, the intracellular assembly of type I chaperonins appears to be a chaperone-dependent process itself and requires functional preformed chaperonin complexes.     

Assessment of plant chaperonin-60 gene function in Escherichia coli.

Brassica napus chaperonin-60 alpha and chaperonin-60 beta genes expressed separately and in combination produce three novel Escherichia coli strains: alpha, beta, and alpha beta. In beta and alpha beta cells, the plant gene products assemble efficiently into tetradecameric cpn60(14) species, including novel hybrids containing both bacterial and plant gene products. The levels of authentic groEL14 are reduced in these cells (Cloney, L. P., Wu, H. B., and Hemmingsen, S. M. (1992) J. Biol. Chem. 267, 23327-23332). The assembly of cyanobacterial ribulose-P2 carboxylase (rubisco) in E. coli requires the activities of the endogenous chaperonin proteins. Furthermore, the extent to which assembly occurs is limited by the normal levels of expression of the groE operon (Goloubinoff, P., Gatenby, A. A., and Lorimer, G. H. (1989) Nature 337, 44-47). We have now monitored the accumulation of cyanobacterial rubisco in E. coli alpha, beta, and alpha beta cells to assess the activity of the plant cpn60 gene products and effects on endogenous chaperonin functions. Expression of cpn-60 alpha alone did not enhance rubisco assembly, which is consistent with our previous observation that p60cpn-60 alpha required the presence of p60cpn-60 beta for assembly into cpn60(14) species. In contrast, expression of cpn-60 beta alone resulted in markedly enhanced rubisco assembly in cells that accumulated normal levels of both endogenous chaperonin polypeptides (groEL and groES). This demonstrates that assembled p60cpn-60 beta is functional as a chaperonin in E. coli. Co-expression of cpn-60 alpha and cpn-60 beta in cells with normal levels of expression of groES and groEL suppressed rubisco assembly. Increased expression of groES in cells in which cpn-60 alpha and cpn-60 beta were co-expressed relieved this suppression and resulted in enhanced rubisco assembly. Implications with respect to dependence of chloroplast cpn60 function on cpn10 are discussed.     

Insights into chaperonin function from studies on archaeal thermosomes

It is now well understood that, although proteins fold spontaneously (in a thermodynamic sense), many nevertheless require the assistance of helpers called molecular chaperones to reach their correct and active folded state in living cells. This is because the pathways of protein folding are full of traps for the unwary: the forces that drive proteins into their folded states can also drive them into insoluble aggregates, and, particularly when cells are stressed, this can lead, without prevention or correction, to cell death. The chaperonins are a family of molecular chaperones, practically ubiquitous in all living organisms, which possess a remarkable structure and mechanism of action. They act as nanoboxes in which proteins can fold, isolated from their environment and from other partners with which they might, with potentially deleterious consequences, interact. The opening and closing of these boxes is timed by the binding and hydrolysis of ATP. The chaperonins which are found in bacteria are extremely well characterized, and, although those found in archaea (also known as thermosomes) and eukaryotes have received less attention, our understanding of these proteins is constantly improving. This short review will summarize what we know about chaperonin function in the cell from studies on the archaeal chaperonins, and show how recent work is improving our understanding of this essential class of molecular chaperones.     

Metal ions modulate the plastic nature of Mycobacterium tuberculosis chaperonin-10

Chaperonin-10s possess a highly flexible segment of approximately 10 residues that covers their dome-like structure and closes the central cavity of the chaperonin assembly. The dome loop is believed to contribute to the plasticity of their oligomeric structure. We have exploited the presence of a single tryptophan residue occurring in the dome loop of Mycobacterium tuberculosis chaperonin-10 (cpn-10), and through intrinsic fluorescence measurements show that in the absence of metal ions, the tryptophan is almost fully solvent exposed at neutral pH. The dome loop, however, assumes a closed conformation in the presence of metal ions, or at low pH. These changes are fully reversed in the presence of chelating agents such as EDTA, confirming the role of cations in modulating the metastable states of cpn-10.     

NMR studies on the substrate-binding domains of the thermosome: structural plasticity in the protrusion region

Group II chaperonins close their cavity with the help of conserved, helical extensions, the so-called protrusions, which emanate from the apical or substrate-binding domains. A comparison of previously solved crystal structures of the apical domains of the thermosome from Thermoplasma acidophilum showed structural plasticity in the protrusion parts induced by extensive packing interactions. In order to assess the influence of the crystal contacts we investigated both the alpha and beta-apical domains (alpha-ADT and beta-ADT) in solution by NMR spectroscopy. Secondary structure assignments and 15N backbone relaxation measurements showed mostly rigid structural elements in the globular parts of the domains, but revealed intrinsic structural disorder and partial helix fraying in the protrusion regions. On the other hand, a beta-turn-motif conserved in archaeal group II chaperonins might facilitate substrate recognition. Our results help us to specify the idea of the open, substrate-accepting state of the thermosome and may provide an additional jigsaw piece in understanding the mode of substrate binding of group II chaperonins.     

Group II chaperonins: new TRiC(k)s and turns of a protein folding machine.

In the past decade, the eubacterial group I chaperonin GroEL became the paradigm of a protein folding machine. More recently, electron microscopy and X-ray crystallography offered insights into the structure of the thermosome, the archetype of the group II chaperonins which also comprise the chaperonin from the eukaryotic cytosol TRiC. Some structural differences from GroEL were revealed, namely the existence of a built-in lid provided by the helical protrusions of the apical domains instead of a GroES-like co-chaperonin. These structural studies provide a framework for understanding the differences in the mode of action between the group II and the group I chaperonins. In vitro analyses of the folding of non-native substrates coupled to ATP binding and hydrolysis are progressing towards establishing a functional cycle for group II chaperonins. A protein complex called GimC/prefoldin has recently been found to cooperate with TRiC in vivo, and its characterization is under way.     

Chaperonins: two rings for folding

Chaperonins are ubiquitous chaperones found in Eubacteria, eukaryotic organelles (group I), Archaea and the eukaryotic cytosol (group II). They all share a common structure and a basic functional mechanism. Although a large amount of information has been gathered for the simpler group I, much less is known about group II chaperonins. Recent crystallographic and electron microscopy structures have provided new insights into the mechanism of these chaperonins and revealed important differences between group I and II chaperonins, mainly in the molecular rearrangements that take place during the functional cycle. These differences are evident for the most complex chaperonin, the eukaryotic cytosolic CCT, which highlights the uniqueness of this important molecular machine.     

Expression of plant chaperonin-60 genes in Escherichia coli.

We have examined the expression in Escherichia coli of genes encoding a plant chloroplast molecular chaperone, chaperonin-60. Purified plant chaperonin-60 is distinct in that it contains two polypeptides, p60cpn-60 alpha and p60cpn-60 beta, which have divergent amino acid sequences (Hemmingsen, S. M., and Ellis, R. J. (1986) Plant Physiol. 80, 269-276; Martel, R., Cloney, L. P., Pelcher, L. E., and Hemmingsen, S. M. (1990) Gene (Amst.) 94, 181-187). The precise polypeptide composition(s) of the active tetradecameric specie(s) (cpn60(14)) has not been determined. Genes encoding the mature forms of the Brassica napus chaperonin polypeptides have been expressed separately and in combination in E. coli to produce three novel strains: alpha, beta, and alpha beta. The plant cpn60 polypeptides accumulated in soluble forms and to similar high levels in each. There was no conclusive evidence that p60cpn-60 alpha assembled into cpn60(14) species in alpha cells. In beta and alpha beta cells, the plant gene products assembled efficiently into cpn60(14) species. Thus, the assembly of p60cpn-60 alpha required the presence of p60cpn-60 beta, whereas the assembly of p60cpn-60 beta could occur in the absence of p60cpn-60 alpha. Significant proportions of the endogenous groEL polypeptides were not assembled into tetradecameric groEL14 in beta and alpha beta cells. Analysis of the tetradecameric species that did form indicated the presence of novel hybrid cpn6014 species that contained both plant and bacterial cpn60 polypeptides.     

All three chaperonin genes in the archaeon Haloferax volcanii are individually dispensable

The Hsp60 or chaperonin class of molecular chaperones is divided into two phylogenetic groups: group I, found in bacteria, mitochondria and chloroplasts, and group II, found in eukaryotic cytosol and archaea. Group I chaperonins are generally essential in bacteria, although when multiple copies are found one or more of these are dispensable. Eukaryotes contain eight genes for group II chaperonins, all of which are essential, and it has been shown that these proteins assemble into double-ring complexes with eightfold symmetry where all proteins occupy specific positions in the ring. In archaea, there are one, two or three genes for the group II chaperonins, but whether they are essential for growth is unknown. Here we describe a detailed genetic, structural and biochemical analysis of these proteins in the halophilic archaeon, Haloferax volcanii. This organism contains three genes for group II chaperonins, and we show that all are individually dispensable but at least one must be present for growth. Two of the three possible double mutants can be constructed, but only one of the three genes is capable of fully complementing the stress-dependent phenotypes that these double mutants show. The chaperonin complexes are made up of hetero-oligomers with eightfold symmetry, and the properties of the different combinations of subunits derived from the mutants are distinct. We conclude that, although they are more homologous to eukaryotic than prokaryotic chaperonins, archaeal chaperonins have some redundancy of function.     

The chaperonins of Synechocystis PCC 6803 differ in heat inducibility and chaperone activity.

The chaperonins GroEL and Cpn60 were isolated from the cyanobacterium Synechocystis PCC 6803 and characterized. In cells grown under optimal conditions their ratio was about one to one. However, the amount of GroEL increased considerably more than that of Cpn60 in response to heat stress. The labile chaperonin oligomer required stabilization by MgATP or glycerol during isolation. Use of the E. coli mutant strain, groEL44 revealed that the functional properties of the two cyanobacterial chaperonins are strikingly different. Overexpression of cyanobacterial GroEL in the E. coli mutant strain allowed growth at elevated temperature, the formation of mature bacteriophage T4, and active Rubisco enzyme assembly. In contrast, Cpn60 partially complemented the temperature-sensitive phenotype, the Rubisco assembly defect and did not promote the growth of the bacteriophage T4. The difference in chaperone activity of the two cyanobacterial chaperonins very probably reflects the unique chaperonin properties required during the life of Synechocystis PCC 6803.     

Differential substrate specificity of group I and group II chaperonins in the archaeon Methanosarcina mazei

Chaperonins are macromolecular machines that assist in protein folding. The archaeon Methanosarcina mazei has acquired numerous bacterial genes by horizontal gene transfer. As a result, both the bacterial group I chaperonin, GroEL, and the archaeal group II chaperonin, thermosome, coexist. A proteome‐wide analysis of chaperonin interactors was performed to determine the differential substrate specificity of GroEL and thermosome. At least 13% of soluble M. mazei proteins interact with chaperonins, with the two systems having partially overlapping substrate sets. Remarkably, chaperonin selectivity is independent of phylogenetic origin and is determined by distinct structural and biochemical features of proteins. GroEL prefers well‐conserved proteins with complex α/β domains. In contrast, thermosome substrates comprise a group of faster‐evolving proteins and contain a much wider range of different domain folds, including small all‐α and all‐β modules, and a greater number of large multidomain proteins. Thus, the group II chaperonins may have facilitated the evolution of the highly complex proteomes characteristic of eukaryotic cells.     

Role of B regulatory subunits of protein phosphatase type 2A in myosin II assembly control in Dictyostelium discoideum

In Dictyostelium discoideum, myosin II resides predominantly in a soluble pool as the result of phosphorylation of the myosin heavy chain (MHC), and dephosphorylation of the MHC is required for myosin II filament assembly, recruitment to the cytoskeleton, and force production. Protein phosphatase type 2A (PP2A) was identified in earlier studies in Dictyostelium as a key biochemical activity that can drive MHC dephosphorylation. We report here gene targeting and cell biological studies addressing the roles of candidate PP2A B regulatory subunits (phr2aBα and phr2aBβ) in myosin II assembly control in vivo. Dictyostelium phr2aBα- and phr2aBβ-null cells show delayed development, reduction in the assembly of myosin II in cytoskeletal ghost assays, and defects in cytokinesis when grown in suspension compared to parental cell lines. These results demonstrate that the PP2A B subunits phr2aBα and phr2aBβ contribute to myosin II assembly control in vivo, with phr2aBα having the predominant role facilitating MHC dephosphorylation to facilitate filament assembly.     

小胶质细胞在脂多糖引起的热高敏中的作用

目的探讨小胶质细胞在脂多糖引起的热高敏中的作用。方法清洁级雄性昆明小鼠,随机分成两组,每组5只,腹腔注射LPS组和注射PBS组,在注射前及后30、60、120、240 min测量小鼠足底的热痛阈;每组于注射前及后4h各处死5只取脑组织检测IL-1β、TNF-α;每组于腹腔注射4h时处死动物,免疫荧光确定脑组织中小胶质细胞的激活情况。然后分为四组,米诺环素+PBS组,米诺环素+LPS组,PBS+PBS组,PBS+LPS组,每组5只,连续三天腹腔注射米诺环素或PBS,第三天注射LPS或PBS,在注射前及后30、60、120、240 min测量小鼠足底的热痛阈;每组于注射前及后4h各处死5只取脑组织检测IL-1β、TNF-α。结果与注射PBS相比,注射LPS导致IL-1β、TNF-α分泌增加,注射60、120、240 min小鼠的热痛阈降低;与米诺环素+PBS组、米诺环素+LPS组、PBS+PBS组相比,PBS+LPS组导致IL-1β、TNF-α分泌增加,注射60、120、240 min小鼠的热痛阈降低。结论LPS激活小胶质细胞分泌促炎细胞因子导致热高敏。     

Ubiquitin-like protein MNSFβ/endophilin II complex regulates Dectin-1-mediated phagocytosis and inflammatory responses in macrophages

Post-translational modification by monoclonal nonspecific suppressor factor β (MNSFβ) has been implicated in the regulation of a variety of cellular events. Previous studies have demonstrated that MNSFβ covalently binds to the intracellular pro-apoptotic protein Bcl-G in a macrophage cell line, Raw264.7, suggesting involvement of this ubiquitin-like protein in apoptosis. Most recently, we found that MNSFβ covalently conjugates to endophilin II, a member of the endophilin A family, and inhibits phagocytosis by macrophages. In this study, we further examined the mechanism of action of MNSFβ/endophilin II complex in the phagocytosis of zymosan. MNSFβ/endophilin II I mediated inhibition of phagocytosis in Raw264.7 cells was neutralized by anti-Decti-1, β-glucan receptor, mAb, indicating that MNSFβ/endophilin II is a mediator of Dectin-1 signaling in regulating phagocytosis. The β-glucan-dependent TNFα response to zymosan was significantly increased by the treatment with endophilin II siRNA and/or MNSFβ siRNA. Conversely, cotransfection of endophilin II and MNSFβ cDNAs inhibited the enhancement of zymosan-induced TNFα production. Interestingly, endophilin II siRNA did not affect Pam₃CSK₄ (TLR2 specific ligand)-induced TNFα production. Endophilin II and/or MNSFβ siRNA enhanced zymosan-induced IκBα degradation. Together, these results demonstrate that MNSFβ/endophilin II inhibits the signal pathway upstream of IKK activation, but not downstream of TLR2 signaling.