Retention of misfolded mutant transthyretin by the chaperone BiP/GRP78 mitigates amyloidogenesis

Carriers of the D18G transthyretin (TTR) mutation display an unusual central nervous system (CNS) phenotype with late onset of disease. D18G TTR is monomeric and highly prone to misfold and aggregate even at physiological conditions. Extremely low levels of mutant protein circulate both in human serum and cerebrospinal fluid, indicating impaired secretion of D18G TTR. Recent data show efficient selective ER-associated degradation (ERAD) of D18G TTR. One essential component of the ER-assisted folding machinery is the molecular chaperone BiP. Co-expression of BiP and D18G TTR, or BiP and wild-type (wt) TTR, or mutants A25T TTR and L55P TTR in Escherichia coli showed that only D18G TTR was significantly captured by BiP. Negligible capture of wt TTR and L55P TTR was seen and a sixfold smaller amount of A25T TTR bound to BiP compared to D18G TTR. These data correlate very well with thermodynamic and kinetic stability of the TTR variants, indicating that folding efficiency is inversely correlated to BiP capture. The complexes between BiP and D18G TTR were stable and could be isolated through affinity chromatography. Analytical ultracentrifugation and size-exclusion chromatography revealed that D18G TTR and BiP formed a mixture of 1:1 complexes and large soluble oligomers. The stoichiometry of captured D18G TTR versus BiP increased with increasing size of the oligomers. This indicates that BiP either worked as a molecular shepherd collecting the aggregation-prone mutant into stable oligomers or that BiP could bind to oligomers formed from misfolded mutant protein. Sequence analysis of bound TTR peptides to BiP revealed a bound sequence corresponding to residues 88-103 of TTR, comprising beta-strand F in the folded TTR monomer constituting part of the hydrogen bonding tetramer interface in native TTR. The F-strand has also been suggested as a possible elongation region of amyloid fibrils, implicating how substoichiomeric amounts of BiP could sequester prefibrillar amyloidogenic oligomers through binding to this part of TTR. BiP binding to D18G TTR was abolished by addition of ATP. The released D18G TTR completely misfolded into amyloid aggregates as shown by ThT fluorescence and Congo red binding.     

Sulfated glycosaminoglycans accelerate transthyretin amyloidogenesis by quaternary structural conversion

Glycosaminoglycans (GAGs), which are found in association with all extracellular amyloid deposits in humans, are known to accelerate the aggregation of various amyloidogenic proteins in vitro. However, the precise molecular mechanism(s) by which GAGs accelerate amyloidogenesis remains elusive. Herein, we show that sulfated GAGs, especially heparin, accelerate transthyretin (TTR) amyloidogenesis by quaternary structural conversion. The clustering of sulfate groups on heparin and its polymeric nature are essential features for accelerating TTR amyloidogenesis. Heparin does not influence TTR tetramer stability or TTR dissociation kinetics, nor does it alter the folded monomer-misfolded monomer equilibrium directly. Instead, heparin accelerates the conversion of preformed TTR oligomers into larger aggregates. The more rapid disappearance of monomeric TTR in the presence of heparin likely reflects the fact that the monomer-misfolded amyloidogenic monomer-oligomer-TTR fibril equilibria are all linked, a hypothesis that is strongly supported by the light scattering data. TTR aggregates prepared in the presence of heparin exhibit a higher resistance to trypsin and proteinase K proteolysis and a lower exposure of hydrophobic side chains comprising hydrophobic clusters, suggesting an active role for heparin in amyloidogenesis. Our data suggest that heparin accelerates TTR aggregation by a scaffold-based mechanism, in which the sulfate groups comprising GAGs interact primarily with TTR oligomers through electrostatic interactions, concentrating and orienting the oligomers, facilitating the formation of higher molecular weight aggregates. This model raises the possibility that GAGs may play a protective role in human amyloid diseases by interacting with proteotoxic oligomers and promoting their association into less toxic amyloid fibrils.     

Novel Zn2+-binding Sites in Human Transthyretin: IMPLICATIONS FOR AMYLOIDOGENESIS AND RETINOL-BINDING PROTEIN RECOGNITION*

Human transthyretin (TTR) is a homotetrameric protein involved in several amyloidoses. Zn²⁺ enhances TTR aggregation in vitro, and is a component of ex vivo TTR amyloid fibrils. We report the first crystal structure of human TTR in complex with Zn²⁺ at pH 4.6–7.5. All four structures reveal three tetra-coordinated Zn²⁺-binding sites (ZBS 1–3) per monomer, plus a fourth site (ZBS 4) involving amino acid residues from a symmetry-related tetramer that is not visible in solution by NMR. Zn²⁺ binding perturbs loop E-α-helix-loop F, the region involved in holo-retinol-binding protein (holo-RBP) recognition, mainly at acidic pH; TTR affinity for holo-RBP decreases ∼5-fold in the presence of Zn²⁺. Interestingly, this same region is disrupted in the crystal structure of the amyloidogenic intermediate of TTR formed at acidic pH in the absence of Zn²⁺. HNCO and HNCA experiments performed in solution at pH 7.5 revealed that upon Zn²⁺ binding, although the α-helix persists, there are perturbations in the resonances of the residues that flank this region, suggesting an increase in structural flexibility. While stability of the monomer of TTR decreases in the presence of Zn²⁺, which is consistent with the tertiary structural perturbation provoked by Zn²⁺ binding, tetramer stability is only marginally affected by Zn²⁺. These data highlight structural and functional roles of Zn²⁺ in TTR-related amyloidoses, as well as in holo-RBP recognition and vitamin A homeostasis.     

Characterization of Oligomeric Species on the Aggregation Pathway of Human Lysozyme

The aggregation process of wild-type human lysozyme at pH 3.0 and 60 °C has been analyzed by characterizing a series of distinct species formed on the aggregation pathway, specifically the amyloidogenic monomeric precursor protein, the oligomeric soluble prefibrillar aggregates, and the mature fibrils. Particular attention has been focused on the analysis of the structural properties of the oligomeric species, since recent studies have shown that the oligomers formed by lysozyme prior to the appearance of mature amyloid fibrils are toxic to cells. Here, soluble oligomers of human lysozyme have been analyzed by a range of techniques including binding to fluorescent probes such as thioflavin T and 1-anilino-naphthalene-8-sulfonate, Fourier transform infrared spectroscopy, and controlled proteolysis. Oligomers were isolated after 5 days of incubation of the protein and appear as spherical particles with a diameter of 8-17 nm when observed by transmission electron microscopy. Unlike the monomeric protein, oligomers have solvent-exposed hydrophobic patches able to bind the fluorescent probe 1-anilino-naphthalene-8-sulfonate. Fourier transform infrared spectroscopy spectra of oligomers are indicative of misfolded species when compared to monomeric lysozyme, with a prevalence of random structure but with significant elements of the β-sheet structure that is characteristic of the mature fibrils. Moreover, the oligomeric lysozyme aggregates were found to be more susceptible to proteolysis with pepsin than both the monomeric protein and the mature fibrils, indicating further their less organized structure. In summary, this study shows that the soluble lysozyme oligomers are locally unfolded species that are present at low concentration during the initial phases of aggregation. The nonnative conformational features of the lysozyme molecules of which they are composed are likely to be the factors that confer on them the ability to interact inappropriately with a variety of cellular components including membranes.     

Transthyretin chemical chaperoning by flavonoids: Structure–activity insights towards the design of potent amyloidosis inhibitors

BackgroundMany polyphenols have been proposed as broad-spectrum inhibitors of amyloid formation. To investigate structure–activity relationships relevant for the interaction of flavonoids with transthyretin (TTR), the protein associated with familial amyloid polyneuropathy (FAP), we compared the effects of major tea catechins and their larger polymers theaflavins, side-by-side, on TTR amyloid formation process.MethodsInteraction of flavonoids with TTR and effect on TTR stability were assessed through binding assays and isoelectric focusing in polyacrylamide gel. TTR aggregation was studied, in vitro, by dynamic light scattering (DLS), transmission electron microscopy (TEM) and in cell culture, through cytotoxicity assays.ResultsTested flavonoids bound to TTR and stabilized the TTR tetramer, with different potencies. The flavonoids also inhibited in vitro formation of TTR small oligomeric species and in cell culture inhibited pathways involving caspase-3 activation and ER stress that are induced by TTR oligomers. In all assays performed the galloyl esters presented higher potency to inhibit aggregation than the non-gallated flavonoids tested.ConclusionsOur results highlight the presence of gallate ester moiety as key structural feature of flavonoids in chemical chaperoning of TTR aggregation. Upon binding to the native tetramer, gallated flavonoids redirect the TTR amyloidogenic pathway into unstructured nontoxic aggregation assemblies more efficiently than their non-gallated forms.General significanceOur findings suggest that galloyl moieties greatly enhance flavonoid anti-amyloid chaperone activity and this should be taken into consideration in therapeutic candidate drug discovery.     

Actin dynamics studied by solid-state NMR spectroscopy

Solid-state nuclear magnetic resonance spectroscopy was used to study the motion of ²H and ¹⁹F probes attached to the skeletal muscle actin residues Cys-10, Lys-61 and Cys-374. The probe resonances were observed in dried and hydrated G-actin, F-actin and F-actin-myosin subfragment-1 complexes. Restricted motion was exhibited by ¹⁹F probes attached to Cys-10 and Cys-374 on actin. The dynamics of probes attached to dry cysteine powder or F-actin were very similar and the binding of myosin had little effect indicating that the local probe environment imposes the major influence on motion in the solid state. Correlation times determined for the solid state probes indicated that they were undergoing some rapid internal motion in both G-actin and F-actin such as domain twisting. The probe size influenced the motion in G-actin and appeared to sense monomer rotation but not in F-actin where segmental mobility and intramonomer co-ordination appeared to dominate.     

Tetramer dissociation and monomer partial unfolding precedes protofibril formation in amyloidogenic transthyretin variants

Amyloid fibril formation and deposition is a common feature of a wide range of fatal diseases including spongiform encephalopathies, Alzheimer's disease, and familial amyloidotic polyneuropathies (FAP), among many others. In certain forms of FAP, the amyloid fibrils are mostly constituted by variants of transthyretin (TTR), a homotetrameric plasma protein. Recently, we showed that transthyretin in solution may undergo dissociation to a non-native monomer, even under close to physiological conditions of temperature, pH, ionic strength, and protein concentration. We also showed that this non-native monomer is a compact structure, does not behave as a molten globule, and may lead to the formation of partially unfolded monomeric species and high molecular mass soluble aggregates (Quintas, A., Saraiva, M. J. M., and Brito, R. M. M. (1999) J. Biol. Chem. 274, 32943-32949). Here, based on aging experiments of tetrameric TTR and chemically induced protein unfolding experiments of the non-native monomeric forms, we show that tetramer dissociation and partial unfolding of the monomer precedes amyloid fibril formation. We also show that TTR variants with the least thermodynamically stable non-native monomer produce the largest amount of partially unfolded monomeric species and soluble aggregates under conditions that are close to physiological. Additionally, the soluble aggregates formed by the amyloidogenic TTR variants showed morphological and thioflavin-T fluorescence properties characteristic of amyloid. These results allowed us to conclude that amyloid fibril formation by some TTR variants might be triggered by tetramer dissociation to a compact non-native monomer with low conformational stability, which originates partially unfolded monomeric species with a high tendency for ordered aggregation into amyloid fibrils. Thus, partial unfolding and conformational fluctuations of molecular species with marginal thermodynamic stability may play a crucial role on amyloid formation in vivo.     

Characterization of intermediate species during the molecular assembly of aspartase

Molecular assembly of aspartase (L-aspartate ammonia-lyase, EC 4.3.1.1) from Escherichia coli was studied during the reversible denaturation. Although previous studies [Tokushige, M., Eguchi, G., and Hirata, F. (1977) Biochem. Biophys. Acta 480, 479-488] were unable to identify intermediate species during the course of reversible denaturation of aspartase, temperature-controlled HPLC and cross-linking with dimethyl suberimidate of the renaturation products showed that monomeric, dimeric and trimeric species occupied over 80% of the total oligomeric molecules below 13 degrees C; unlike the tetramer, these intermediates were without the activity. The degree of active tetramer formation was a linear function of the restoration of the activity below 18 degrees C, while above 23 degrees C, the activity regain was less than 70% restoration of tetrameric molecules. Upon examination by fluorescence spectroscopy, structural changes during reconstitution exhibited such complex kinetics that the rapid formation of structured oligomers proceeds first with a half-time of less than 10 sec, followed by slow subunit association. These results strongly suggest that the tetramer formation is an essential prerequisite, though not sufficient for the active enzyme.     

Signal turn-on probe for nucleic acid detection based on (19)F nuclear magnetic resonance

To image gene expression in vivo, we designed and synthesized a novel signal turn-on probe for ¹⁹F nuclear magnetic resonance (MR) imaging based on paramagnetic relaxation enhancement. The stem-loop structured oligodeoxyribonucleotide (ODN) having a molecular beacon sequence for point mutated K-ras mRNA was doubly labeled with bis(trifluoromethyl)benzene moiety and Gd-1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid chelate moiety at the each termini of the ODN probe, respectively. We found that the ¹⁹F MR signal of the bis(trifluoromethyl)benzene moiety tethered at the 5′ termini of the probe turned on by the addition of complementary ODN. The probe has the potential to image gene expressions in vivo.     

Dissecting the structure, thermodynamic stability, and aggregation properties of the A25T transthyretin (A25T-TTR) variant involved in leptomeningeal amyloidosis: identifying protein partners that co-aggregate during A25T-TTR fibrillogenesis in cerebrospinal fluid

Deposition of amorphous aggregates and fibrils of transthyretin (TTR) in leptomeninges and subarachnoid vessels is a characteristic of leptomeningeal amyloidosis (LA), a currently untreatable cerebral angiopathy. Herein, we report the X-ray structure of the A25T homotetramer of TTR, a natural mutant described in a patient with LA. The structure of A25T-TTR is indistinguishable from that of wild-type TTR (wt-TTR), indicating that the difference in amyloidogenicity between A25T-TTR and wt-TTR cannot be ascribed to gross structural differences. Using pressure-induced dissociation of the tetramer, we show that A25T-TTR is 3 kcal/mol less stable than L55P-TTR, the most aggressive mutant of TTR described to date. After incubation for 15 days at 37 °C (pH 7.3), A25T-TTR forms mature amyloid fibrils. To mimic the environment in which TTR aggregates, we investigated aggregation in cerebrospinal fluid (CSF). Unlike L55P-TTR, A25T-TTR rapidly forms amyloid aggregates in CSF that incorporated several protein partners. Utilizing a proteomics methodology, we identified 19 proteins that copurified with A25T-TTR amyloid fibrils. We confirmed the presence of proteins previously identified to be associated with TTR aggregates in biopsies of TTR amyloidosis patients, such as clusterin, apolipoprotein E, and complement proteins. Moreover, we identified novel proteins, such as blood coagulation proteins. Overall, our results revealed the in vitro characterization of TTR aggregation in a biologically relevant environment, opening new avenues of investigation into the molecular mechanisms of LA.     

Aggregation-induced conformation changes dictate islet amyloid polypeptide (IAPP) membrane affinity

Islet amyloid polypeptide (IAPP) is a 37 residue intrinsically disordered protein whose aggregation is associated with Type II diabetes. Like most amyloids, it appears that the intermediate aggregates (“oligomers”) of IAPP are more toxic than the mature fibrils, and interaction with the cell membrane is likely to be an integral component of the toxicity. Here we probe the membrane affinity and the conformation of the peptide as a function of its aggregation state. We find that the affinity of the peptide for artificial lipid bilayers is more than 15 times higher in the small oligomeric state (hydrodynamic radius ~ 1.6 nm) compared to the monomeric state (hydrodynamic radius ~ 0.7 nm). Binding with RIN-m5F cell membranes also shows qualitatively similar behavior. The monomeric state, as determined by Forster Resonance Energy Transfer, has a much larger end to end distance than the oligomeric state, suggesting conformational change between the monomers and the oligomers. Raman and Infrared spectroscopic measurements show the presence of considerable alpha helical content in the oligomers, whereas the larger aggregates have largely beta sheet character. Therefore, the conformation of the small oligomers is distinct from both the smaller monomers and the larger oligomers, and this is associated with an enhanced membrane affinity. This provides a possible structural basis for the enhanced toxicity of amyloid oligomers. Such change is also reminiscent of amyloid beta, another aggregation prone amyloidogenic peptide, though the nature of the conformational change is quite different in the two cases. We infer that conformational change underlying oligomer formation is a key factor in determining the enhanced membrane affinity of disease causing oligomers, but the toxic “oligomer fold” may not be universal.     

Tetramerization of the S100B Chaperone Spawns a Ca2+ Independent Regulatory Surface that Enhances Anti-aggregation Activity and Client Specificity

Alzheimer’s disease (AD) hallmarks include the aggregation of amyloid-β (Aβ), tau and neuroinflammation promoted by several alarmins. Among these is S100B, a small astrocytic homodimeric protein, upregulated in AD, whose multiple biological activities depend on localization, concentration, and assembly state. S100B was reported to inhibit the aggregation and toxicity of Aβ42 and tau similarly to a holdase-type chaperone. This activity is dependent of Ca²⁺-binding, which triggers the exposure of a regulatory binding cleft at the S100B dimer interface with which amyloidogenic clients dynamically interact. Although the dimer prevails, a significant portion of secreted S100B in the human brain occurs as higher order multimers, whose protective functions remain uncharacterized and which we here investigate. Resorting to ThT-monitored aggregation kinetics, we determined that unlike the dimer, tetrameric S100B inhibits Aβ42 aggregation at sub/equimolar ratios, an effect that persists in the absence of Ca²⁺ binding. Structural analysis revealed that S100B tetramerization spawns a novel extended cleft accommodating an aggregation-prone surface that mediates interactions with monomeric Aβ client via hydrophobic interactions, as corroborated by Bis-ANS fluorescence and docking analysis. Correspondingly, at high ionic strength that reduces solvation and favours hydrophobic contacts, the inhibition of Aβ42 aggregation by tetrameric S100B is 3-fold increased. Interestingly, this extended Ca²⁺-independent surface favours Aβ42 as substrate, as tau K18 aggregation is not inhibited by the apo tetramer. Overall, results illustrate a mechanism through which oligomerization of the S100B chaperone fine-tunes anti-aggregation activity and client specificity, highlighting the potential functional relevance of S100B multimers in the regulation of AD proteotoxicity.     

The most pathogenic transthyretin variant, L55P, forms amyloid fibrils under acidic conditions and protofilaments under physiological conditions.

The L55P transthyretin (TTR) familial amyloid polyneuropathy-associated variant is distinct from the other TTR variants studied to date and the wild-type protein in that the L55P tetramer can dissociate to the monomeric amyloidogenic intermediate and form fibril precursors under physiological conditions (pH 7.0, 37 degrees C). The activation barrier associated with L55P-TTR tetramer dissociation is lower than the barrier for wild-type transthyretin dissociation, which does not form fibrils under physiological conditions. The L55P-TTR tetramer is also very sensitive to acidic conditions, readily dissociating to form the monomeric amyloidogenic intermediate between pH 5.5-5.0 where the wild-type TTR adopts a nonamyloidogenic tetrameric structure. The formation of the L55P monomeric amyloidogenic intermediate involves subtle tertiary structural changes within the beta-sheet rich subunit as discerned from Trp fluorescence, circular dichroism analysis, and ANS binding studies. The assembly of the L55P-TTR amyloidogenic intermediate at physiological pH (pH 7.5) affords protofilaments that elongate with time. TEM studies suggest that the entropic barrier associated with filament assembly (amyloid fibril formation) is high in vitro, amyloid being defined by the laterally assembled four filament structure observed by Blake upon isolation of "fibrils" from the eye of a FAP patient. The L55P-TTR protofilaments formed in vitro bind Congo red and thioflavin T (albeit more weakly than the fibrils produced at acidic pH), suggesting that the structure observed probably represents an amyloid precursor. The structural continuum from misfolded monomer through protofilaments, filaments, and ultimately fibrils must be considered as a possible source of pathology associated with these diseases.     

Transthyretin aggregation under partially denaturing conditions is a downhill polymerization

The deposition of fibrils and amorphous aggregates of transthyretin (TTR) in patient tissues is a hallmark of TTR amyloid disease, but the molecular details of amyloidogenesis are poorly understood. Tetramer dissociation is typically rate-limiting for TTR amyloid fibril formation, so we have used a monomeric variant of TTR (M-TTR) to study the mechanism of aggregation. Amyloid formation is often considered to be a nucleation-dependent process, where fibril growth requires the formation of an oligomeric nucleus that is the highest energy species on the pathway. According to this model, the rate of fibril formation should be accelerated by the addition of preformed aggregates or "seeds", which effectively bypasses the nucleation step. Herein, we demonstrate that M-TTR amyloidogenesis at low pH is a complex, multistep reaction whose kinetic behavior is incompatible with the expectations for a nucleation-dependent polymerization. M-TTR aggregation is not accelerated by seeding, and the dependence of the reaction timecourse is first-order on the M-TTR concentration, consistent either with a dimeric nucleus or with a nonnucleated process where each step is bimolecular and essentially irreversible. These studies suggest that amyloid formation by M-TTR under partially denaturing conditions is a downhill polymerization, in which the highest energy species is the native monomer. Our results emphasize the importance of therapeutic strategies that stabilize the TTR tetramer and may help to explain why more than eighty TTR variants are disease-associated. The differences between amyloid formation by M-TTR and other amyloidogenic peptides (such as amyloid beta-peptide and islet amyloid polypeptide) demonstrate that these polypeptides do not share a common aggregation mechanism, at least under the conditions examined thus far.     

Transthyretin suppresses the toxicity of oligomers formed by misfolded proteins in vitro

Although human transthyretin (TTR) is associated with systemic amyloidoses, an anti-amyloidogenic effect that prevents Aβ fibril formation in vitro and in animal models has been observed. Here we studied the ability of three different types of TTR, namely human tetramers (hTTR), mouse tetramers (muTTR) and an engineered monomer of the human protein (M-TTR), to suppress the toxicity of oligomers formed by two different amyloidogenic peptides/proteins (HypF-N and Aβ₄₂). muTTR is the most stable homotetramer, hTTR can dissociate into partially unfolded monomers, whereas M-TTR maintains a monomeric state. Preformed toxic HypF-N and Aβ₄₂ oligomers were incubated in the presence of each TTR then added to cell culture media. hTTR, and to a greater extent M-TTR, were found to protect human neuroblastoma cells and rat primary neurons against oligomer-induced toxicity, whereas muTTR had no protective effect. The thioflavin T assay and site-directed labeling experiments using pyrene ruled out disaggregation and structural reorganization within the discrete oligomers following incubation with TTRs, while confocal microscopy, SDS-PAGE, and intrinsic fluorescence measurements indicated tight binding between oligomers and hTTR, particularly M-TTR. Moreover, atomic force microscopy (AFM), light scattering and turbidimetry analyses indicated that larger assemblies of oligomers are formed in the presence of M-TTR and, to a lesser extent, with hTTR. Overall, the data suggest a generic capacity of TTR to efficiently neutralize the toxicity of oligomers formed by misfolded proteins and reveal that such neutralization occurs through a mechanism of TTR-mediated assembly of protein oligomers into larger species, with an efficiency that correlates inversely with TTR tetramer stability.     

Characterization of the formation of amyloid protofibrils from barstar by mapping residue-specific fluorescence dynamics

The small protein barstar aggregates at low pH to form soluble oligomers, which can be transformed into fibrillar aggregates at an elevated temperature. To characterize structurally, with residue-specific resolution, the process of amyloid formation of barstar, as well as to monitor the increase in size that accompanies the aggregation process, time-resolved fluorescence anisotropy decay measurements have been introduced as a valuable probe. Seven different single-cysteine-containing mutant forms of barstar were made, to each of which a fluorophore was attached at the thiol group. The rotational dynamics of these seven fluorophores, as well as of the sole intrinsic tryptophan residue in the protein, were determined in the amyloid protofibrils formed, as well as in the soluble oligomers from which the protofibrils arise upon heating. Mapping of the fast rotational dynamics onto the sequence of the protein yields dynamic amplitude maps that allowed identification of the segments of the chain that possess local structure in the soluble oligomer and amyloid protofibrils. The patterns of these maps of the soluble oligomer and protofibrils are seen to be similar; and protofibrils display more local structure than do the soluble oligomers, at all residue positions studied. The observation that transformation from soluble oligomers to protofibrils does not perturb local structure significantly at eight different residue positions, suggests that the soluble oligomers transform directly into protofibrils, without undergoing drastic structural rearrangements.     

Snap-to-it probes: chelate-constrained nucleobase oligomers with enhanced binding specificity

We describe snap-to-it probes, a novel probe technology to enhance the hybridization specificity of natural and unnatural nucleic acid oligomers using a simple and readily introduced structural motif. Snap-to-it probes were prepared from peptide nucleic acid (PNA) oligomers by modifying each terminus with a coordinating ligand. The two coordinating ligands constrain the probe into a macrocyclic configuration through formation of an intramolecular chelate with a divalent transition metal ion. On hybridization with a DNA target, the intramolecular chelate in the snap-to-it probe dissociates, resulting in the probe ‘snapping-to’ and binding the target nucleic acid. Thermal transition analysis of snap-to-it probes with complementary and single-mismatch DNA targets revealed that the transition between free and target-bound probe conformations was a reversible equilibrium, and the intramolecular chelate provided a thermodynamic barrier to target binding that resulted in a significant increase in mismatch discrimination. A 4–6°C increase in specificity (ΔT_m) was observed from snap-to-it probes bearing either terminal iminodiacetic acid ligands coordinated with Ni²⁺, or terminal dihistidine and nitrilotriacetic acid ligands coordinated with Cu²⁺. The difference in specificity of the PNA oligomer relative to DNA was more than doubled in snap-to-it probes. Snap-to-it probes labeled with a fluorophore-quencher pair exhibited target-dependent fluorescence enhancement upon binding with target DNA.     

Capture of monomeric refolding intermediate of human muscle creatine kinase

Human muscle creatine kinase (CK) is an enzyme that plays an important physiological role in the energy metabolism of humans. It also serves as a typical model for studying refolding of proteins. A study of the refolding and reactivation process of guanidine chloride-denatured human muscle CK is described in the present article. The results show that the refolding process can be divided into fast and slow folding phases and that an aggregation process competes with the proper refolding process at high enzyme concentration and high temperature. An intermediate in the early stage of refolding was captured by specific protein molecules: the molecular chaperonin GroEL and alpha(s)-casein. This intermediate was found to be a monomer, which resembles the "molten globule" state in the CK folding pathway. To our knowledge, this is the first monomeric intermediate captured during refolding of CK. We propose that aggregation is caused by interaction between such monomeric intermediates. Binding of GroEL with this intermediate prevents formation of aggregates by decreasing the concentration of free monomeric intermediates, whereas binding of alpha(s)-casein with this intermediate induces more aggregation.     

Kinetic stabilization of an oligomeric protein under physiological conditions demonstrated by a lack of subunit exchange: implications for transthyretin amyloidosis

Kinetic stabilization of transthyretin (TTR) is established to prevent human neurodegeneration. Therefore, small molecule-mediated kinetic stabilization of the native state is an attractive strategy to prevent the misfolding and misassembly associated with TTR amyloid disease. Since the physiological microenvironment resulting in human TTR amyloidogenesis remains unclear, the conservative approach is to identify inhibitors that function under a variety of conditions. Small molecule kinetic stabilization of TTR has been established by concentration-dependent inhibition of acid-mediated amyloidogenesis and urea-induced tetramer dissociation. Since denaturing conditions reduce the binding affinity of inhibitors making it difficult to predict inhibitor efficacy under physiological conditions, we introduce a method for quantifying kinetic stabilization under physiological conditions. The rate of subunit exchange between wild-type TTR homotetramers and wild-type TTR homotetramers tagged with an N-terminal acidic flag tag is dictated by the rate of tetramer dissociation to its monomeric subunits prior to reassembly, rendering this method ideally suited for assessing the kinetic stabilization of TTR imparted by small molecule binding and evaluating small molecule binding constants. Addition of amyloidogenesis inhibitors to this exchange reaction slows tetramer dissociation in a concentration-dependent manner, stopping dissociation at concentrations where at least one inhibitor is bound to each tetramer in solution. Subunit exchange enables the rate of tetramer dissociation and the kinetic stabilization imparted by small molecule binding to be evaluated under physiological conditions in which the TTR concentration is not reduced by aggregation or irreversible dissociation.     

An engineered transthyretin monomer that is nonamyloidogenic, unless it is partially denatured

Transthyretin (TTR) is a soluble human plasma protein that can be converted into amyloid by acid-mediated dissociation of the homotetramer into monomers. The pH required for disassembly also results in tertiary structural changes within the monomeric subunits. To understand whether these tertiary structural changes are required for amyloidogenicity, we created the Phe87Met/Leu110Met TTR variant (M-TTR) that is monomeric according to analytical ultracentrifugation and gel filtration analyses and nonamyloidogenic at neutral pH. Results from far- and near-UV circular dichroism spectroscopy, one-dimensional proton NMR spectroscopy, and X-ray crystallography, as well as the ability of M-TTR to form a complex with retinol binding protein, indicate that M-TTR forms a tertiary structure at pH 7 that is very similar if not identical to that found within the tetramer. Reducing the pH results in tertiary structural changes within the M-TTR monomer, rendering it amyloidogenic, demonstrating the requirement for partial denaturation. M-TTR exhibits stability toward acid and urea denaturation that is nearly identical to that characterizing wild-type (WT) TTR at low concentrations (0.01-0.1 mg/mL), where monomeric WT TTR is significantly populated at intermediate urea concentrations prior to the tertiary structural transition. However, the kinetics of denaturation and fibril formation are much faster for M-TTR than for tetrameric WT TTR, particularly at near-physiological concentrations, because of the barrier associated with the tetramer to folded monomer preequilibrium. These results demonstrate that the tetramer to folded monomer transition is insufficient for fibril formation; further tertiary structural changes within the monomer are required.