Do molecular chaperones have to be proteins?

Intermolecular Interactions between a Membrane Protein and a Glycolipid Essential for Membrane Protein Integration

Inducing newly synthesized proteins to appropriate locations is an indispensable biological function in every organism. Integration of proteins into biomembranes in Escherichia coli is mediated by proteinaceous factors, such as Sec translocons and an insertase YidC. Additionally, a glycolipid named MPIase (membrane protein integrase), composed of a long sugar chain and pyrophospholipid, was proven essential for membrane protein integration. We reported that a synthesized minimal unit of MPIase possessing only one trisaccharide, mini-MPIase-3, involves an essential structure for the integration activity. Here, to elucidate integration mechanisms using MPIase, we analyzed intermolecular interactions of MPIase or its synthetic analogs with a model substrate, the Pf3 coat protein, using physicochemical methods. Surface plasmon resonance (SPR) analyses revealed the importance of a pyrophosphate for affinity to the Pf3 coat protein. Compared with mini-MPIase-3, natural MPIase showed faster association and dissociation due to its long sugar chain despite the slight difference in affinity. To focus on more detailed MPIase substructures, we performed docking simulations and saturation transfer difference-nuclear magnetic resonance. These experiments yielded that the 6-O-acetyl group on glucosamine and the phosphate of MPIase play important roles leading to interactions with the Pf3 coat protein. The high affinity of MPIase to the hydrophobic region and the basic amino acid residues of the protein was suggested by docking simulations and proven experimentally by SPR using protein mutants devoid of target regions. These results demonstrated the direct interactions of MPIase with a substrate protein and revealed detailed mechanisms of membrane protein integration.

Abnormal expression of HSP70 may contribute to PCOS pathology

Background

The mechanism of the pathological change of polycystic ovary syndrome (PCOS) is still unclear. Previous studies have shown that PCOS is a chronic nonspecific low-grade inflammatory condition, and that heat shock protein (HSP)70 has a potent anti-inflammatory property. So the aim of this study is to investigate the correlation between HSP70 and the hormones and inflammatory factors and to find out the role of HSP70 in the pathogenesis of PCOS.

Methods

Twenty female Sprague–Dawley (SD) rats (aged 23 days and weighted 80-90 g) were randomly divided into two groups (n = 10 per group), PCOS group and control group. PCOS group were subcutaneously injected with 6 mg/100 g dehydro-epiandrosterone (DHEA) for 20 consecutive days, the control group were subcutaneously injected with a solvent of equivalent amount. All the samples were collected in the morning fasting state, 12 h after the last administration. Histological examinations of ovarian tissues were analyzed. Hormone levels and inflammatory factors levels were measured by enzyme-linked immunosorbent assay (ELISA) kits.

Results

Serum concentrations of testosterone (T) and luteinizing hormone (LH) were significantly higher in the PCOS group than the control group (P < 0.001), but the concentrations of estradiol (E₂), follicle stimulating hormone (FSH) and insulin didn’t show significant difference between these two groups. All the concentrations of inflammatory factors including C-reactive protein (CRP), interleukin (IL)-6, IL-18, and tumor necrosis factor (TNF)-α. were significantly higher in PCOS group than the control group (P < 0.001). The expressions of HSP70 were significantly lower in serum but higher in ovarian tissues in the PCOS group than the control group. Spearman rank correlation analysis showed strong negative correlation of serum HSP70 levels with T, LH and all the detected inflammatory factors.

Conclusion

The abnormal expression of HSP70 correlated with testosterone and inflammatory factors, which indicates that HSP70 may play an important role in PCOS pathology.

Physiological mechanisms through which heat stress compromises reproduction in pigs

Seasonal variations in environmental temperatures impose added stress on domestic species bred for economically important production traits. These heat-mediated stressors vary on a seasonal, daily, or spatial scale, and negatively impact behavior and reduce feed intake and growth rate, which inevitably lead to reduced herd productivity. The seasonal infertility observed in domestic swine is primarily characterized by depressed reproductive performance, which manifests as delayed puberty onset, reduced farrowing rates, and extended weaning-to-estrus intervals. Understanding the effects of heat stress at the organismal, cellular, and molecular level is a prerequisite to identifying mitigation strategies that should reduce the economic burden of compromised reproduction. In this review, we discuss the effect of heat stress on an animal's ability to maintain homeostasis in multiple systems via several hypothalamic-pituitary-end organ axes. Additionally, we discuss our understanding of epigenetic programming and how hyperthermia experienced in utero influences industry-relevant postnatal phenotypes. Further, we highlight the recent recognized mechanisms by which distant tissues and organs may molecularly communicate via extracellular vesicles, a potentially novel mechanism contributing to the heat-stress response.

Protein disulfide-isomerase, a folding catalyst and a redox-regulated chaperone

Protein disulfide-isomerase (PDI) was the first protein-folding catalyst to be characterized, half a century ago. It plays critical roles in a variety of physiological events by displaying oxidoreductase and redox-regulated chaperone activities. This review provides a brief history of the identification of PDI as both an enzyme and a molecular chaperone and of the recent advances in studies on the structure and dynamics of PDI, the substrate binding and release, and the cooperation with its partners to catalyze oxidative protein folding and maintain ER redox homeostasis. In this review, we highlight the structural features of PDI, including the high interdomain flexibility, the multiple binding sites, the two synergic active sites, and the redox-dependent conformational changes.

Preventing α-synuclein aggregation: the role of the small heat-shock molecular chaperone proteins

Protein homeostasis, or proteostasis, is the process of maintaining the conformational and functional integrity of the proteome. The failure of proteostasis can result in the accumulation of non-native proteins leading to their aggregation and deposition in cells and in tissues. The amyloid fibrillar aggregation of the protein α-synuclein into Lewy bodies and Lewy neuritis is associated with neurodegenerative diseases classified as α-synucleinopathies, which include Parkinson's disease and dementia with Lewy bodies. The small heat-shock proteins (sHsps) are molecular chaperones that are one of the cell's first lines of defence against protein aggregation. They act to stabilise partially folded protein intermediates, in an ATP-independent manner, to maintain cellular proteostasis under stress conditions. Thus, the sHsps appear ideally suited to protect against α-synuclein aggregation, yet these fail to do so in the context of the α-synucleinopathies. This review discusses how sHsps interact with α-synuclein to prevent its aggregation and, in doing so, highlights the multi-faceted nature of the mechanisms used by sHsps to prevent the fibrillar aggregation of proteins. It also examines what factors may contribute to α-synuclein escaping the sHsp chaperones in the context of the α-synucleinopathies.

Identical RNA-protein interactions in vivo and in vitro and a scheme of folding the newly synthesized proteins by ribosomes

A distinct three-dimensional shape of rRNA inside the ribosome is required for the peptidyl transfer activity of its peptidyltransferase center (PTC). In contrast, even the in vitro transcribed PTC RNA interacts with unfolded protein(s) at about five sites to let them attain their native states. We found that the same set of conserved nucleotides in the PTC interact identically with nascent and chemically unfolded proteins in vivo and in vitro, respectively. The time course of this interaction, difficult to follow in vivo, was observed in vitro. It suggested nucleation of folding of cytosolic globular proteins vectorially from hydrophilic N to hydrophobic C termini, consistent with our discovery of a regular arrangement of cumulative hydrophobic indices of the peptide segments of cytosolic proteins from N to C termini. Based on this observation, we propose a model here for the nucleation of folding of the nascent protein chain by the PTC.

Heat shock proteins in porcine ovary: synthesis, accumulation and regulation by stress and hormones

The present studies aimed to understand the interrelationships between stress, hormones and heat shock proteins (HSPs) in the ovary. We examined (1) whether HSP70.2, HSP72 and HSP105/110 can be produced and accumulated in porcine ovarian tissue, (2) whether these HSPs could be indicators of stress, i.e. whether two kinds of stress (high temperatures and malnutrition/serum deprivation) can affect them, and (3) whether some hormonal regulators of ovarian functions (insulin-like growth factor (IGF)-I, leptin and follicle-stimulating hormone (FSH)) can affect these HSPs and response of ovaries to HSP-related stress. We analysed the expression of HSP70.2, HSP72 and HSP105/110 mRNA (by using real-time reverse transcriptase polymerase chain reaction) in porcine ovarian granulosa cells, as well as the accumulation of HSP70 protein (by using sodium dodecyl sulphate polyacrylamide gel electrophoresis-Western) in either whole ovarian follicles and granulose cells cultured at normal (37.5°C) or high (41.5°C) temperature, with and without serum and with and without IGF-I, leptin and FSH. Expression of mRNA for HSP70.2, HSP72 and HSP105/110 in ovarian granulosa cells and accumulation of HSP70 protein in whole ovarian follicles and granulosa cells were demonstrated. In all the groups, addition of either IGF-I, leptin and FSH reduced the expression of HSP70.2, HSP72 and HSP105/110 mRNA. Both high temperature, serum deprivation and their combination resulted in increase in mRNAs for all three analysed HSPs. Additions of either IGF-I, leptin and FSH prevented the stimulatory effect of both high temperature and serum deprivation on the transcription of HSP70.2, HSP72 and HSP105/110. In contrast, high temperature reduced accumulation of peptide HSP70 in both ovarian follicles and granulosa cell. Serum deprivation promoted accumulation of HSP70 in granulosa cells, but not in ovarian follicles. Addition of IGF-I, leptin and FSH was able to alter accumulation of HSP70 in both follicles and granulosa cells. The present observations suggest (1) that HSPs can be synthesised in ovarian follicular granulosa cells; (2) that hormones (IGF-I, leptin and FSH) can inhibit, whilst stressors (both high temperature and malnutrition/serum deprivation) can stimulate transcription of HSP70.2, HSP72 and HSP105/110 genes, whilst heat stress, but not malnutrition, can promote depletion of HSP70 in ovarian cells, and (3) that hormones (IGF-I, leptin and FSH) can prevent stress-related changes in HSPs. The application of HSPs as indicators and mediators of stress and hormones on ovarian functions, as well as use of hormones and HSPs as anti-stressor molecules, are discussed.

Sphingolipid/cholesterol regulation of neurotransmitter receptor conformation and function

Like all other monomeric or multimeric transmembrane proteins, receptors for neurotransmitters are surrounded by a shell of lipids which form an interfacial boundary between the protein and the bulk membrane. Among these lipids, cholesterol and sphingolipids have attracted much attention because of their well-known propensity to segregate into ordered platform domains commonly referred to as lipid rafts. In this review we present a critical analysis of the molecular mechanisms involved in the interaction of cholesterol/sphingolipids with neurotransmitter receptors, in particular acetylcholine and serotonin receptors, chosen as representative members of ligand-gated ion channels and G protein-coupled receptors. Cholesterol and sphingolipids interact with these receptors through typical binding sites located in both the transmembrane helices and the extracellular loops. By altering the conformation of the receptors ("chaperone-like" effect), these lipids can regulate neurotransmitter binding, signal transducing functions, and, in the case of multimeric receptors, subunit assembly and subsequent receptor trafficking to the cell surface. Several sphingolipids (especially gangliosides) also exhibit low/moderate affinity for neurotransmitters. We suggest that such lipids could facilitate (i) the attachment of neurotransmitters to the post-synaptic membrane and in some cases (ii) their subsequent delivery to specific protein receptors. Overall, various experimental approaches provide converging evidence that the biological functions of neurotransmitters and their receptors are highly dependent upon sphingolipids and cholesterol, which are active partners of synaptic transmission. Several decades of research have been necessary to untangle the skein of a complex network of molecular interactions between neurotransmitters, their receptors, cholesterol and sphingolipids. This sophisticated crosstalk between all four distinctive partners may allow a fine biochemical tuning of synaptic transmission.

Chaperones in control of protein disaggregation

The chaperone protein network controls both initial protein folding and subsequent maintenance of proteins in the cell. Although the native structure of a protein is principally encoded in its amino-acid sequence, the process of folding in vivo very often requires the assistance of molecular chaperones. Chaperones also play a role in a post-translational quality control system and thus are required to maintain the proper conformation of proteins under changing environmental conditions. Many factors leading to unfolding and misfolding of proteins eventually result in protein aggregation. Stress imposed by high temperature was one of the first aggregation-inducing factors studied and remains one of the main models in this field. With massive protein aggregation occurring in response to heat exposure, the cell needs chaperones to control and counteract the aggregation process. Elimination of aggregates can be achieved by solubilization of aggregates and either refolding of the liberated polypeptides or their proteolysis. Here, we focus on the molecular mechanisms by which heat-shock protein 70 (Hsp70), Hsp100 and small Hsp chaperones liberate and refold polypeptides trapped in protein aggregates.

Lipids in the assembly of membrane proteins and organization of protein supercomplexes: implications for lipid-linked disorders

Lipids play important roles in cellular dysfunction leading to disease. Although a major role for phospholipids is in defining the membrane permeability barrier, phospholipids play a central role in a diverse range of cellular processes and therefore are important factors in cellular dysfunction and disease. This review is focused on the role of phospholipids in normal assembly and organization of the membrane proteins, multimeric protein complexes, and higher order supercomplexes. Since lipids have no catalytic activity, it is difficult to determine their function at the molecular level. Lipid function has generally been defined by affects on protein function or cellular processes. Molecular details derived from genetic, biochemical, and structural approaches are presented for involvement of phosphatidylethanolamine and cardiolipin in protein organization. Experimental evidence is presented that changes in phosphatidylethanolamine levels results in misfolding and topological misorientation of membrane proteins leading to dysfunctional proteins. Examples are presented for diseases in which proper protein folding or topological organization is not attained due to either demonstrated or proposed involvement of a lipid. Similar changes in cardiolipin levels affects the structure and function of individual components of the mitochondrial electron transport chain and their organization into supercomplexes resulting in reduced mitochondrial oxidative phosphorylation efficiency and apoptosis. Diseases in which mitochondrial dysfunction has been linked to reduced cardiolipin levels are described. Therefore, understanding the principles governing lipid-dependent assembly and organization of membrane proteins and protein complexes will be useful in developing novel therapeutic approaches for disorders in which lipids play an important role.

Effect of thermal stress on protein expression in the mussel Mytilus galloprovincialis Lmk

The exposure of organisms to stressing agents may affect the level and pattern of protein expression. Certain proteins with an important role in protein homeostasis and in the tolerance to stress, known as stress proteins, are especially affected. Different tissues and cells show a range of sensitivities to stress, depending on the habitat to which organisms have adapted. The response of different tissues and cells from the mussel Mytilus galloprovincialis Lmk. to heat shock has been studied in this work using different exposure times and temperatures. During the assays, protein expression was observed to vary depending on the tissue studied, the temperature or the exposure time used. But maybe the most prominent thing is the different response obtained from the cultured haemocytes and those freshly obtained from stressed mussels, which makes us think that the extraction procedure is the main cause of the response of non-cultured cells, although the haemolymph may contain components that modulate haemocyte response.

Protein translocation through a tunnel induces changes in folding kinetics: a lattice model study

Compaction of a nascent polypeptide chain inside the ribosomal exit tunnel, before it leaves the ribosome, has been proposed to accelerate the folding of newly synthesized proteins following their release from the ribosome. Thus, we used Kinetic Monte Carlo simulations of a minimalist on-lattice model to explore the effect that polypeptide translocation through a variety of channels has on protein folding kinetics. Our results demonstrate that tunnel confinement promotes faster folding of a well-designed protein relative to its folding in free space by displacing the unfolded state towards more compact structures that are closer to the transition state. Since the tunnel only forbids rarely visited, extended configurations, it has little effect on a "poorly designed" protein whose unfolded state is largely composed of low-energy, compact, misfolded configurations. The beneficial effect of the tunnel depends on its width; for example, a too-narrow tunnel enforces unfolded states with limited or no access to the transition state, while a too-wide tunnel has no effect on the unfolded state entropy. We speculate that such effects are likely to play an important role in the folding of some proteins or protein domains in the cellular environment and might dictate whether a protein folds co-translationally or post-translationally.

Glutathione reductase from human cataract lenses can be revived by reducing agents and by a molecular chaperone, alpha-crystallin

PURPOSE

The aim of this study was to investigate how glutathione reductase (GR) loses its activity during cataract formation and whether it is possible to revive it back to the normal levels.

METHOD

In this study, endogenous as well as synthetic reducing systems (GSH, TTase, DTT, captopril) and alpha-crystallin at different concentrations were incubated with the soluble fraction of human cataract lens protein. The activity of glutathione reductase with or without the reducing agents and alpha-crystallin was tested, and the difference in activity gained was calculated.

RESULTS

Five agents (GSH, DTT, TTase, captopril, alpha-low crystallin) were able to revive the activity of GR from human cataract lenses to different extents.

CONCLUSION

This study shows that human lens GR activity was revived by different reducing agents as well as by a molecular chaperone (alpha-crystallin).

The unusual chaperonins of Mycobacterium tuberculosis

Heat shock proteins (Hsps), also known as molecular chaperones, are a diverse set of proteins that mediate the correct folding, assembly, transport and degradation of other proteins. In addition, Hsps have been shown to play a variety of important roles in immunity, thereby representing prominent antigens in the humoral and cellular immune response. Chaperonins form a sub-group of molecular chaperones that are found in all domains of life. Chaperonins in all bacteria are encoded by the essential groEL and groES genes, also called cpn60 and cpn10 arranged on the bicistronic groESL operon. Interestingly, Mycobacterium tuberculosis contains two copies of the cpn60 genes. The existence of a duplicate set of cpn60 genes in M. tuberculosis, however, has been perplexing. Cpn10 and Cpn60s of M. tuberculosis have been shown to be highly antigenic in nature, eliciting strong B- and T-cell immune responses. Recent work has shown intriguing structural, biochemical and signaling properties of the M. tuberculosis chaperonins. This review details the recent developments in the study of the M. tuberculosis chaperonins.

A cure for traffic jams: small molecule chaperones in the endoplasmic reticulum

Folding in the endoplasmic reticulum is the limiting step for the biogenesis of most secretory pathway cargo proteins; proteins which fail to fold are initially retained in the endoplasmic reticulum and subsequently often degraded. Mutations that affect secretory protein folding have profound phenotypes irrespective of their direct impact on protein function, because they prevent secretory proteins from reaching their final destination. When unicellular organisms are stressed by fluctuation of temperature or ionic strength, they synthesize high concentrations of small molecules such as trehalose or glycerol to prevent protein denaturation. These osmolytes can also stabilize mutant secretory proteins and allow them to pass secretory protein quality control in the endoplasmic reticulum. Specific ligands and cofactors such as ions, sugars, or peptides have similar effects on specific defective proteins and are beginning to be used as therapeutic agents for protein trafficking diseases.

Clusterin is an extracellular chaperone that specifically interacts with slowly aggregating proteins on their off-folding pathway

Clusterin is an extracellular mammalian chaperone protein which inhibits stress-induced precipitation of many different proteins. The conformational state(s) of proteins that interact with clusterin and the stage(s) along the folding and off-folding (precipitation-bound) pathways where this interaction occurs were previously unknown. We investigated this by examining the interactions of clusterin with different structural forms of alpha-lactalbumin, gamma-crystallin and lysozyme. When assessed by ELISA and native gel electrophoresis, clusterin did not bind to various stable, intermediately folded states of alpha-lactalbumin nor to the native form of this protein, but did bind to and inhibit the slow precipitation of reduced alpha-lactalbumin. Reduction-induced changes in the conformation of alpha-lactalbumin, in the absence and presence of clusterin, were monitored by real-time (1)H NMR spectroscopy. In the absence of clusterin, an intermediately folded form of alpha-lactalbumin, with some secondary structure but lacking tertiary structure, aggregated and precipitated. In the presence of clusterin, this form of alpha-lactalbumin was stabilised in a non-aggregated state, possibly via transient interactions with clusterin prior to complexation. Additional experiments demonstrated that clusterin potently inhibited the slow precipitation, but did not inhibit the rapid precipitation, of lysozyme and gamma-crystallin induced by different stresses. These results suggest that clusterin interacts with and stabilises slowly aggregating proteins but is unable to stabilise rapidly aggregating proteins. Collectively, our results suggest that during its chaperone action, clusterin preferentially recognises partly folded protein intermediates that are slowly aggregating whilst venturing along their irreversible off-folding pathway towards a precipitated protein.

Chaperone-like properties of lysophospholipids

Lysophospholipids are metabolic intermediates in phospholipid turnover, detergent molecules with membrane-modulating effects, and multifunctional cellular growth factors in eukaryotic cells. In bacterial cells, lysophospholipids are mostly found in the form of lysophosphatidylethanolamine. We show that a heat shock from 30 to 42 degrees C increases four-fold the Escherichia coli pool of lysophosphoethanolamine and that lysophospholipids display chaperone-like properties. Lysophosphatidylethanolamine, like molecular chaperones such as DnaK, promotes the functional folding of citrate synthase and alpha-glucosidase after urea denaturation. Like chaperones, lysophophatidylethanolamine, lysophosphatidylcholine, lysophosphatidylinositol and lysophosphatidic acid prevent the aggregation of citrate synthase at 42 degrees C. The renaturation and solubilisation of proteins by lysophospholipids occur at micromolar concentrations of these compounds, close to their critical micellar concentration. Furthermore, lysophosphatidylethanolamine is much more efficient than other detergents tested for the renaturation and solubilisation of citrate synthase. In contrast with lysophospholipids, phosphatidylethanolamine and phosphatidylcholine are not able to promote citrate synthase folding nor to prevent its aggregation at 42 degrees C. The chaperone-like properties of lysophospholipids suggest that, in addition to their known functions, they might affect the structure and function of hydrophilic proteins.

Thermodynamics of the folding of D-glyceraldehyde-3-phosphate dehydrogenase assisted by protein disulfide isomerase studied by microcalorimetry

Thermodynamics of the refolding of denatured D-glyceraldehyde 3-phosphate dehydrogenase (GAPDH) assisted by protein disulfide isomerase (PDI), a molecular chaperone, has been studied by isothermal microcalorimetry at different molar ratios of PDI/GAPDH and temperatures using two thermodynamic models proposed for chaperone-substrate binding and chaperone-assisted substrate folding, respectively. The binding of GAPDH folding intermediates to PDI is driven by a large favorable enthalpy decrease with a large unfavorable entropy reduction, and shows strong enthalpy-entropy compensation and weak temperature dependence of Gibbs free energy change. A large negative heat-capacity change of the binding, -156 kJ.mol(-1).K(-1), at all temperatures examined indicates that hydrophobic interaction is a major force for the binding. The binding stoichiometry shows one dimeric GAPDH intermediate per PDI monomer. The refolding of GAPDH assisted by PDI is a largely exothermic reaction at 15.0-25.0 degrees C. With increasing temperature from 15.0 to 37.0 degrees C, the PDI-assisted reactivation yield of denatured GAPDH upon dilution decreases. At 37.0 degrees C, the spontaneous reactivation, PDI-assisted reactivation and intrinsic molar enthalpy change during the PDI-assisted refolding of GAPDH are not detected.

The participation of 5S rRNA in the co-translational formation of a eukaryotic 5S ribonucleoprotein complex

The eukaryotic ribosomal 5S RNA-protein complex (5S rRNP) is formed by a co-translational event that requires 5S rRNA binding to the nascent peptide chain of eukaryotic ribosomal protein L5. Binding between 5S rRNA and the nascent chain is specific: neither the 5S rRNA nor the nascent chain of L5 protein can be substituted by other RNAs or other ribosomal proteins. The region responsible for binding 5S rRNA is located at positions 35-50 with amino acid sequence RLVIQDIKNKYNTPKYRM. Eukaryotic 5S rRNA binds a nascent chain having this sequence, but such binding is not substantive enough to form a 5S-associated RNP complex, suggesting that 5S rRNA binding to the nascent chain is amino acid sequence dependent and that formation of the 5S rRNP complex is L5 protein specific. Microinjection of 5S rRNP complex into the cytoplasm of Xenopus oocytes results in both an increase in the initial rate and also in the extent of net nuclear import of L5. This suggests that the 5S rRNP complex enhances nuclear transport of L5. We propose that 5S rRNA plays a chaperone-like role in folding of the nascent chain of L5 and directs L5 into a 5S rRNP complex for nuclear entry.

Sulfatide promotes the folding of proinsulin, preserves insulin crystals, and mediates its monomerization

Sulfatide is a glycolipid that has been associated with insulin-dependent diabetes mellitus. It is present in the islets of Langerhans and follows the same intracellular route as insulin. However, the role of sulfatide in the beta cell has been unclear. Here we present evidence suggesting that sulfatide promotes the folding of reduced proinsulin, indicating that sulfatide possesses molecular chaperone activity. Sulfatide associates with insulin by binding to the insulin domain A8--A10 and most likely by interacting with the hydrophobic side chains of the dimer-forming part of the insulin B-chain. Sulfatide has a dual effect on insulin. It substantially reduces deterioration of insulin hexamer crystals at pH 5.5, conferring stability comparable to those in beta cell granules. Sulfatide also mediates the conversion of insulin hexamers to the biological active monomers at neutral pH, the pH at the beta-cell surface. Finally, we report that inhibition of sulfatide synthesis with chloroquine and fumonisine B1 leads to inhibition of insulin granule formation in vivo. Our observations suggest that sulfatide plays a key role in the folding of proinsulin, in the maintenance of insulin structure, and in the monomerization process.

Exercise, heat shock proteins, and myocardial protection from I-R injury

Heat shock proteins (HSPs) play a critical role in maintaining cellular homeostasis and protecting cells during episodes of acute stress. Specifically, HSPs of the 70 kDa family (i.e., HSP72) are important in preventing ischemia-reperfusion induced apoptosis, necrosis, and oxidative injury in a variety of cell types including the cardiac myocyte. Evidence indicates that HSP72 may contribute to cellular protection against a variety of stresses by preventing protein aggregation, assisting in the refolding of damaged proteins, and chaperoning nascent polypeptides along ribosomes. Endurance exercise is a physiological stress that can be used to elevate myocardial levels of HSP72. It is now clear that endurance exercise training can elevate myocardial HSP72 by 400-500% in young adult animals. Importantly, an exercise-induced elevation in myocardial HSPs is associated with a reduction in ischemia-reperfusion (I-R) injury in the heart. Although it seems likely that exercise-induced elevations in myocardial levels of HSPs play an important role in this protection against an I-R insult, new evidence suggests that other factors may also be involved. This is an important area for future research.

Potential use of non-classical pathways for the transport of macromolecular drugs

Since an increasing number of drug delivery strategies utilising proteins and peptides exhibiting 'non-classical' transport activities have been proposed, studies have begun to establish underlying functional relationships between different vectors. These attempts to find common factors have been hampered by a lack of biophysical data for the various potential protein and peptide transporters, as well as by the structural and functional diversity of the group as a whole. We describe the various types of vectors being considered for use and the preliminary therapeutic successes that have been achieved. Additionally, the various models that have been proposed for non-classical import and export are outlined and discussed in relation to therapeutic delivery. Possible future developments are also discussed.

Binding and folding: in search of intramolecular chaperone-like building block fragments

We propose an intramolecular chaperone which catalyzes folding and neither dissociates nor is cleaved. This uncleaved foldase is an intramolecular chain-linked chaperone, which constitutes a critical building block of the structure. Macroscopically, all molecular chaperones facilitate folding reactions and manifest similar energy landscapes. However, microscopically they differ. While intermolecular chaperones catalyze folding by unfolding misfolded conformations or prevent misfolding, the chain-linked cleaved (proregion) and uncleaved intramolecular chaperone-like building blocks suggested here, catalyze folding by binding to, stabilizing and increasing the populations of native conformations of adjacent building block fragments. In both, the more stable the intramolecular chaperone fragment region, the faster is the folding rate. Hence, mechanistically, intramolecular chaperones and chaperone-like segments are similar. Both play a dual role, in folding and in protein function. However, while the functional role of the proregions is inhibitory, necessitating their cleavage, the function of the uncleaved intramolecular chaperone-like building blocks does not require their subsequent removal. On the contrary, it requires that they remain in the structure. This may lead to the difference in the type of control they are under: proteins folding with the assistance of the proregion have been shown to be under kinetic control. It has been suggested that kinetically controlled folding reactions, with the proregion catalyst removed, lend longevity under harsh conditions. On the other hand, proteins with uncleaved intramolecular chaperone-like building blocks, with their 'foldases' still attached, are largely under thermodynamic control, consistent with the control observed in most protein folding reactions. We propose that an uncleaved intramolecular chaperone-like fragment occurs frequently in proteins. We further propose that such proteins would be prone to changing conditions and in particular, to mutations in this critical building block region. We describe the features qualifying it for its proposed chaperone-like role, compare it with inter- and intramolecular chaperones and review current literature in this light. We further propose a mechanism showing how it lowers the barrier heights, leading to faster folding reaction rates. Since these fragments constitute an intergal part of the protein structure, we call these critical building blocks intramolecular, chaperone-like fragments, to clarify, distinguish and adhere to the definition of the transiently associating chaperones. The new mechanism presented here differs from the concept of 'folding nuclei'. While the concept of folding nuclei focuses on a non-sequential distribution of the folding information along the entire protein chain, the chaperone-like building block fragments proposition focuses on a segmental distribution of the folding information. This segmental distribution controls the distributions of the populations throughout the hierarchical folding processes.

The function of alpha-crystallin in vision

The alpha-crystallins account for approximately one-third of the total soluble protein in the lens, contributing to its refractive power. In addition, alpha-crystallin also has a chaperone-like function and thus can bind unfolding lens proteins. Alpha B-crystallin is also found outside the lens, having an extensive tissue distribution. It is over-expressed in response to stresses of all kinds, where it is thought to serve a general protective function. Recently, it has been shown in humans that naturally occurring point mutations in the alpha-crystallins result in a deficit in chaperone-like function, and cause cataracts as well as a desmin-related myopathy. This review summarizes much of the past and current knowledge concerning the structure and functions of alpha-crystallin.

Molecular chaperones: pathways and networks

Some proteins synthesized by growing eukaryotic cells are transferred along unidirectional pathways of molecular chaperones until the risk of aggregation has decreased and they can be released safely. Mature proteins denatured by stress may instead be handled by chaperones acting in branched, reversible networks.

DNA molecules can drive the assembly of other DNA molecules into specific four-stranded structures

Single-stranded DNA molecules containing clustered G-repeats can be assembled into various four-stranded structures linked by G-quartets. Here, we report that such molecules can also drive the assembly of other DNA molecules containing G-repeats into specific four-stranded structures. In these assays, the oligonucleotides 5'-CAGGCTGAGCAGGTACGGGGGAGCTGGGGTAGATTGGAATGTAG-3' (oligo D) and 5'-CGGGGGAGCTGGGGT-3' (oligo B), consisting of sequences found in immunoglobulin switch regions, were annealed in a buffer containing K+ and the annealing products were analyzed by polyacrylamide gel electrophoresis. This analysis revealed that whereas annealing of each oligo alone produced four-stranded structures designated D2 and B2, annealing of mixtures containing both oligos produced additional complexes designated D2* and B2*. D2* and B2* were found to contain only D molecules and only B molecules, respectively. The yield of D2* increased and the yield of B2* decreased, as the concentration ratio oligo B/oligo D was increased. These results indicated that B can drive the assembly of D into D2* and D can drive the assembly of B into B2*. Further studies revealed that while the assembly of D2 followed a second order kinetics, the B-driven assembly of D2* followed a first order kinetics. Dimethyl sulfate footprinting indicated that both D2 and D2* are four-stranded structures containing two parallel and two antiparallel chains. In addition, annealing of D mixed with various B mutants showed that only mutants containing two G-clusters can drive the assembly of D2*. Based on these data, we propose that in the process of D2* assembly, a four-stranded intermediate containing B and D is formed and then dissociates into D2* and B in a rate-limiting first order reaction. Driver mechanisms of this type may cause formation of specific four-stranded structures at G-rich chromosomal sites, thereby regulating processes such as recombination and telomere synthesis.

Origins of globular structure in proteins

Thermodynamic incompatibility of polymers in a common solvent is possibly a driving force for formation and evolution of globular protein structures. Folding of polypeptide chains leads to a decrease in both excluded volume of molecules and chemical differences between surfaces of globular molecules with chemical information hidden in the hydrophobic interior. Folding of polypeptide chains results in 'molecular or thermodynamic mimicry' of globular proteins and in at least more than 10-fold higher phase separation threshold values of mixed protein solutions compared to those of classical polymers. Unusually high co-solubility might be necessary for efficient biological functioning of proteins, e.g. enzymes, enzyme inhibitors, etc.

Principles of protein folding in the cellular environment

The ability of newly synthesised protein chains to fold into their functional conformations has evolved within the complex intracellular environment. Until recently, however, this ability has been studied largely as the refolding of denatured mature proteins in dilute simple solutions. Recent work aimed at understanding how proteins fold in vivo has allowed some general statements to be postulated.

Co-translational folding

Nascent proteins appear to fold co-translationally. The ribosome itself may function as a chaperone, providing a sheltered environment in which the nascent peptide is protected from aggregation and degradation, and in which folding into the tertiary structure is facilitated by interactions both with ribosomal proteins and with specific segments of the ribosomal RNA.

The Saccharomyces cerevisiae TCM62 gene encodes a chaperone necessary for the assembly of the mitochondrial succinate dehydrogenase (complex II)

The assembly of the mitochondrial respiratory chain is mediated by a large number of helper proteins. To better understand the biogenesis of the yeast succinate dehydrogenase (SDH), we searched for assembly-defective mutants. SDH is encoded by the SDH1, SDH2, SDH3, and SDH4 genes. The holoenzyme is composed of two domains. The membrane extrinsic domain, consisting of Sdh1p and Sdh2p, contains a covalent FAD cofactor and three iron-sulfur clusters. The membrane intrinsic domain, consisting of Sdh3p and Sdh4p, is proposed to bind two molecules of ubiquinone and one heme. We isolated one mutant that is respiration-deficient with a specific loss of SDH oxidase activity. SDH is not assembled in this mutant. The complementing gene, TCM62 (also known as SCYBR044C), does not encode an SDH subunit and is not essential for cell viability. It encodes a mitochondrial membrane protein of 64,211 Da. The Tcm62p sequence is 17.3% identical to yeast hsp60, a molecular chaperone. The Tcm62p amino terminus is in the mitochondrial matrix, whereas the carboxyl terminus is accessible from the intermembrane space. Tcm62p forms a complex containing at least three SDH subunits. We propose that Tcm62p functions as a chaperone in the assembly of yeast SDH.

Phospholipid-assisted protein folding: phosphatidylethanolamine is required at a late step of the conformational maturation of the polytopic membrane protein lactose permease

Previously we presented evidence that phosphatidylethanolamine (PE) acts as a molecular chaperone in the folding of the polytopic membrane protein lactose permease (LacY) of Escherichia coli. Here we provide more definitive evidence supporting the chaperone properties of PE. Membrane insertion of LacY prevents its irreversible aggregation, and PE participates in a late step of conformational maturation. The temporal requirement for PE was demonstrated in vitro using a coupled translation-membrane insertion assay that allowed the separation of membrane insertion from phospholipid-assisted folding. LacY was folded properly, as assessed by recognition with conformation-specific monoclonal antibodies, when synthesized in the presence of PE-containing inside-out membrane vesicles (IOVs) or in the presence of IOVs initially lacking PE but supplemented with PE synthesized in vitro either co- or post-translationally. The presence of IOVs lacking PE and containing anionic phospholipids or no addition of IOVs resulted in misfolded or aggregated LacY, respectively. Therefore, critical folding steps occur after membrane insertion dependent on the interaction of LacY with PE to prevent illicit interactions which lead to misfolding of LacY.

Origins of globular structure in proteins

Since natural proteins are the products of a long evolutionary process, the structural properties of present-day proteins should depend not only on physico-chemical constraints, but also on evolutionary constraints. Here we propose a model for protein evolution, in which membranes play a key role as a scaffold for supporting the gradual evolution from flexible polypeptides to well-folded proteins. We suggest that the folding process of present-day globular proteins is a relic of this putative evolutionary process. To test the hypothesis that membranes once acted as a cradle for the folding of globular proteins, extensive research on membrane proteins and the interactions of globular proteins with membranes will be required.