Amyloid-associated nucleic acid hybridisation

Nucleic acids promote amyloid formation in diseases including Alzheimer's and Creutzfeldt-Jakob disease. However, it remains unclear whether the close interactions between amyloid and nucleic acid allow nucleic acid secondary structure to play a role in modulating amyloid structure and function. Here we have used a simplified system of short basic peptides with alternating hydrophobic and hydrophilic amino acid residues to study nucleic acid - amyloid interactions. Employing biophysical techniques including X-ray fibre diffraction, circular dichroism spectroscopy and electron microscopy we show that the polymerized charges of nucleic acids concentrate and enhance the formation of amyloid from short basic peptides, many of which would not otherwise form fibres. In turn, the amyloid component binds nucleic acids and promotes their hybridisation at concentrations below their solution K(d), as shown by time-resolved FRET studies. The self-reinforcing interactions between peptides and nucleic acids lead to the formation of amyloid nucleic acid (ANA) fibres whose properties are distinct from their component polymers. In addition to their importance in disease and potential in engineering, ANA fibres formed from prebiotically-produced peptides and nucleic acids may have played a role in early evolution, constituting the first entities subject to Darwinian evolution.     

DNA-induced partial unfolding of prion protein leads to its polymerisation to amyloid

The full-length mouse recombinant prion protein (23-231 amino acid residues) contains all of its structural elements viz. three alpha-helices and a short two-stranded antiparallel beta-sheet in its C-terminal fragment comprising 121-231 amino acid residues. The incubated mixture of this prion protein fragment and nucleic acid results in the formation of amyloid fibres evidenced from electron microscopy, birefringence and fluorescence of the fibre bound Congo Red and Thioflavin T dyes, respectively. The secondary structure of the amyloid formed in nucleic acid solution is similar to the in vivo isolated prion protein 27-30 amyloid but unlike in it, a hydrophobic milieu is absent in the 121-231 amyloid. Thermal denaturation study demonstrates a partial unfolding of the protein fragment in nucleic acid solution. We propose that nucleic acid catalyses unfolding of prion protein helix 1 followed by a nucleation-dependent polymerisation of the protein to amyloid.     

8 Using pseudorotation as a reaction coordinate in free energy simulations of nucleic acids

Backbone sugar groups are central components of nucleic acids. The conformations of the ribose/deoxyribose can be elegantly described using the concept of pseudorotation (Altona and Sundaralingam, 1972), and are dominated by the C2′- and C3′-endo conformers. The free energy barrier of the transition between these two major puckering modes can be probed by NMR relaxation experiments (Johnson and Hoogstraten, 2008), but an atomic picture of the transition path per se is only available for several truncated nucleoside analogues (Brameld & Goddard III, 1999). Here, we implemented a new free energy simulation method for Molecular Dynamics simulations using pseudorotation as the reaction coordinate (Cremer and Pople, 1975). This allowed us to compute the free energy landscape of a complete pseudorotation cycle. The free energy landscape revealed not only the relative stability of C2′- and C3′-endo conformers, but also the main transition path and its free energy barrier. As a validation of our new approach, we calculated free energy surface of the pseudorotation of guanosine monophosphate. The free energy surface revealed that the C2′-endo conformation is ?1?kcal/mol that is more stable and the free energy barrier for the transition is 4.5–5?kcal/mol. These are in excellent agreement with previous NMR measurements (Zhang et al., 2012; Röder et al., 1975). We have further applied this method to other systems that are important in pre-biotic chemistry, including an RNA duplex with unique 2′, 5′-phosphodiester linkages.     

Influence of lipid membranes on the conformational transitions of nucleic acids

The conformational transitions of nucleic acids which were enclosed in reverse phase evaporation vesicles (REV) were studied by thermal denaturation with optical recording. Cloned fragments of double-stranded DNA containing 179 base pairs and 187 base pairs, respectively, and polyA.polyU were enclosed in REV with a yield up to every vesicle containing 50 nucleic acid molecules. With the 179 base pairs DNA enclosed in the vesicle from egg lecithin two well resolved helix-coil transitions could be measured; one is very similar in the midpoint-temperature Tm and halfwidth delta T1/2 to the transition of the free nucleic acid, and the other transition occurs stabilized at a 3.5 degrees C higher Tm-value and with a broader delta T1/2, 2.7 degrees C instead of 0.6 degree C. Both transitions are from nucleic acids inside the vesicles. Varying the surface charge of the lipid membrane by adding the negatively charged phosphatidylserine or phosphatidylglycerol, an optimum in the yield of enclosure and a maximum in the increase in Tm (4.5 degrees C) and delta T1/2 (5.5 degrees C instead of 1.0 degrees C) was obtained at 20% phosphatidylserine or phosphatidylglycerol. In vesicles from pure negatively charged lipids no second population of nucleic acids was observed. Qualitatively, similar effects were observed with polyA.polyU. Stabilization and broadening of the second transition is higher for nucleic acids inside vesicles from lipids with unsaturated fatty acids, as dioleoyl-phosphatidylcholine, than with saturated fatty acids, dipalmitoyl-phosphatidylcholine. Stabilization and broadening decrease with increasing ionic strength, whereas the relative contributions of both transitions to the total hypochromicity remain unchanged; the second transition coincides with the first at 90 mM Na+. From the experimental results it was concluded that the interaction of nucleic acids and lipid membranes is mainly of electrostatic nature. The nucleic acids exist inside the vesicles in two populations, one behaving like nucleic acid free in solution and one influenced by the contact with the membrane. All results are in accordance with a model in which the interaction between the nucleic acid and the membrane is in competition with the dipole-dipole interaction inside the membrane surface.     

Binding with nucleic acids or glycosaminoglycans converts soluble protein oligomers to amyloid

Ample evidence suggests that almost all polypeptides can either adopt a native structure (folded or intrinsically disordered) or form misfolded amyloid fibrils. Soluble protein oligomers exist as an intermediate between these two states, and their cytotoxicity has been implicated in the pathology of multiple human diseases. However, the mechanism by which soluble protein oligomers develop into insoluble amyloid fibrils is not clear, and investigation of this important issue is hindered by the unavailability of stable protein oligomers. Here, we have obtained stabilized protein oligomers generated from common native proteins. These oligomers exert strong cytotoxicity and display a common conformational structure shared with known protein oligomers. They are soluble and remain stable in solution. Intriguingly, the stabilized protein oligomers interact preferentially with both nucleic acids and glycosaminoglycans (GAG), which facilitates their rapid conversion into insoluble amyloid. Concomitantly, binding with nucleic acids or GAG strongly diminished the cytotoxicity of the protein oligomers. EGCG, a small molecule that was previously shown to directly bind to protein oligomers, effectively inhibits the conversion to amyloid. These results indicate that stabilized oligomers of common proteins display characteristics similar to those of disease-associated protein oligomers and represent immediate precursors of less toxic amyloid fibrils. Amyloid conversion is potently expedited by certain physiological factors, such as nucleic acids and GAGs. These findings concur with reports of cofactor involvement with disease-associated amyloid and shed light on potential means to interfere with the pathogenic properties of misfolded proteins.     

Oxidative damage in brain from human mutant APP/PS-1 double knock-in mice as a function of age

Oxidative stress is strongly implicated in the progressive decline of cognition associated with aging and neurodegenerative disorders. In the brain, free radical-mediated oxidative stress plays a critical role in the age-related decline of cellular function as a result of the oxidation of proteins, lipids, and nucleic acids. A number of studies indicate that an increase in protein oxidation and lipid peroxidation is associated with age-related neurodegenerative diseases and cellular dysfunction observed in aging brains. Oxidative stress is one of the important factors contributing to Alzheimer's disease (AD), one of whose major hallmarks includes brain depositions of amyloid beta-peptide (Abeta) derived from amyloid precursor protein (APP). Mutation in APP and PS-1 genes, which increases production of the highly amyloidogenic amyloid beta-peptide (Abeta42), is the major cause of familial AD. In the present study, protein oxidation and lipid peroxidation in the brain from knock-in mice expressing human mutant APP and PS-1 were compared with brain from wild type, as a function of age. The results suggest that there is an increased oxidative stress in the brain of wild-type mice as a function of age. In APP/PS-1 mouse brain, there is a basal increase (at 1 month) in oxidative stress compared to the wild type (1 month), as measured by protein oxidation and lipid peroxidation. In addition, age-related elevation of oxidative damage was observed in APP/PS-1 mice brain compared to that of wild-type mice brain. These results are discussed with reference to the importance of Abeta42-associated oxidative stress in the pathogenesis of AD.     

Protein misfolding and amyloid formation for the peptide GNNQQNY from yeast prion protein Sup35: simulation by reaction path annealing

We study the early steps of amyloid formation of the seven residue peptide GNNQQNY from yeast prion-like protein Sup35 by simulating the random coil to beta-sheet and alpha-helix to beta-sheet transition both in the absence and presence of a cross-beta amyloid nucleus. The simulation method at atomic resolution employs a new implementation of a Langevin dynamics "reaction path annealing" algorithm. The results indicate that the presence of amyloid-like cross-beta-sheet strands both facilitates the transition into the cross-beta conformation and substantially lowers the free energy barrier for this transition. This model systems allows us to investigate the energetic and kinetic details of this transition, which is consistent with an auto-catalyzed, nucleation-like mechanism for the formation of beta-amyloid. In particular, we find that electrostatic interactions of peptide backbone dipoles contribute significantly to the stability of the beta-amyloid state. Furthermore, we find water exclusion and interactions of polar side-chains to be driving forces of amyloid formation: the cross-beta conformation is stabilized by burial of polar side-chains and inter-residue hydrogen bonds in the presence of an amyloid-like "seed". These findings are in support of a "dry, polar zipper model" of amyloid formation.     

Protein design at the interface of the pre-biotic and biotic worlds

"Proteogenesis" (the origin of proteins) is a likely key event in the unsolved problem of biogenesis (the origin of life). The raw material for the very first proteins comprised the available amino acids produced and accumulated upon the early earth via abiotic chemical and physical processes. A broad consensus is emerging that this pre-biotic set likely comprised Ala, Asp, Glu, Gly, Ile, Leu, Pro, Ser, Thr, and Val. A key question in proteogenesis is whether such abiotically-produced amino acids comprise a "foldable" set. Current knowledge of protein folding identifies properties of complexity, secondary structure propensity, hydrophobic-hydrophilic patterning, core-packing potential, among others, as necessary elements of foldability. None of these requirements excludes the pre-biotic set of amino acids from being a foldable set. Moreover, nucleophile and metal ion/mineral binding capabilities also appear present in the pre-biotic set. Properties of the pre-biotic set, however, likely restrict foldability to the acidophilic/halophilic environment.     

Shuffling of amino acid sequence: an important control in synthetic peptide studies of nucleic acid-binding domains. Binding properties of fragments of a conserved eukaryotic RNA binding motif.

We have used synthetic peptides to study a conserved RNA binding motif in yeast poly(A)-binding protein. Two peptides, 45 and 44 amino acids in length, corresponding to amino and carboxyl halves of a 90-amino acid RNA-binding domain in the protein were synthesized. While the amino-terminal peptide had no significant affinity for nucleic acids, the carboxyl-terminal peptide-bound nucleic acids with similar characteristics to that for the entire 577 residue yeast poly(A)-binding protein. In 100 mM NaCl, the latter peptide retained over 50% of the intrinsic binding free energy of the protein, as well as, similar RNA versus DNA binding specificity. However, shuffling of the sequence of this 44 residue peptide had surprisingly little effect on its nucleic acid binding properties suggesting the overriding importance of amino acid composition as opposed to primary sequence. Deletion studies on the 44 residue peptide with the "correct" sequence succeeded in identifying amino acids important for conferring RNA specificity and for increasing our understanding of the molecular basis for nucleic acid binding by synthetic peptides. The shuffled peptide study, however, clearly indicates that considerable caution must be exercised before extrapolating results of structure/function studies on synthetic peptide analogues to the parent protein.     

Targeting BACE with small inhibitory nucleic acids - a future for Alzheimer's disease therapy?

beta-Secretase, a beta-site amyloid precursor protein (APP) cleaving enzyme (BACE), participates in the secretion of beta-amyloid peptides (Abeta), the major components of the toxic amyloid plaques found in the brains of patients with Alzheimer's disease (AD). According to the amyloid hypothesis, accumulation of Abeta is the primary influence driving AD pathogenesis. Lowering of Abeta secretion can be achieved by decreasing BACE activity rather than by down-regulation of the APP substrate protein. Therefore, beta-secretase is a primary target for anti-amyloid therapeutic drug design. Several approaches have been undertaken to find an effective inhibitor of human beta-secretase activity, mostly in the field of peptidomimetic, non-cleavable substrate analogues. This review describes strategies targeting BACE mRNA recognition and its down-regulation based on the antisense action of small inhibitory nucleic acids (siNAs). These include antisense oligonucleotides, catalytic nucleic acids - ribozymes and deoxyribozymes - as well as small interfering RNAs (siRNAs). While antisense oligonucleotides were first used to identify an aspartyl protease with beta-secretase activity, all the strategies now demonstrate that siNAs are able to inhibit BACE gene expression in a sequence-specific manner, measured both at the level of its mRNA and at the level of protein. Moreover, knock-down of BACE reduces the intra- and extracellular population of Abeta40 and Abeta42 peptides. An anti-amyloid effect of siNAs is observed in a wide spectrum of cell lines as well as in primary cortical neurons. Thus targeting BACE with small inhibitory nucleic acids may be beneficial for the treatment of Alzheimer's disease and for future drug design.     

Modeling protein–nucleic acid complexes with extremely large conformational changes using Flex-LZerD

Proteins and nucleic acids are key components in many processes in living cells, and interactions between proteins and nucleic acids are often crucial pathway components. In many cases, large flexibility of proteins as they interact with nucleic acids is key to their function. To understand the mechanisms of these processes, it is necessary to consider the 3D atomic structures of such protein–nucleic acid complexes. When such structures are not yet experimentally determined, protein docking can be used to computationally generate useful structure models. However, such docking has long had the limitation that the consideration of flexibility is usually limited to small movements or to small structures. We previously developed a method of flexible protein docking which could model ordered proteins which undergo large-scale conformational changes, which we also showed was compatible with nucleic acids. Here, we elaborate on the ability of that pipeline, Flex-LZerD, to model specifically interactions between proteins and nucleic acids, and demonstrate that Flex-LZerD can model more interactions and types of conformational change than previously shown.     

The phi29 DNA polymerase:protein-primer structure suggests a model for the initiation to elongation transition

The absolute requirement for primers in the initiation of DNA synthesis poses a problem for replicating the ends of linear chromosomes. The DNA polymerase of bacteriophage phi29 solves this problem by using a serine hydroxyl of terminal protein to prime replication. The 3.0 A resolution structure shows one domain of terminal protein making no interactions, a second binding the polymerase and a third domain containing the priming serine occupying the same binding cleft in the polymerase as duplex DNA does during elongation. Thus, the progressively elongating DNA duplex product must displace this priming domain. Further, this heterodimer of polymerase and terminal protein cannot accommodate upstream template DNA, thereby explaining its specificity for initiating DNA synthesis only at the ends of the bacteriophage genome. We propose a model for the transition from the initiation to the elongation phases in which the priming domain of terminal protein moves out of the active site as polymerase elongates the primer strand. The model indicates that terminal protein should dissociate from polymerase after the incorporation of approximately six nucleotides.     

Model for the irreversible dissociation kinetics of cooperatively bound protein–nucleic acid complexes

We present a quantitative model for the irreversible dissociation kinetics of cooperatively bound nonspecific protein–nucleic acid complexes. The model assumes that the major pathway of dissociation is via singly contiguously bound protein that “peels” off the ends of clusters of bound protein. It should therefore be most applicable for proteins that bind nucleic acids with high cooperativity (w > 10³). Furthermore, the model assumes that no redistribution of bound protein occurs during the time course of the dissociation. Solutions to the rate equations are presented for the entire time course of the dissociation. Under initial conditions such that the nucleic acid is less than fully saturated with protein, a single-exponential decay is predicted (if w is large). However, when the nucleic acid lattice is initially fully saturated, zero-order kinetics, corresponding to a constant rate of protein dissociation, is predicted. The experimental observation of zero-order dissociation kinetics in a cooperative protein–nucleic acid system is a good qualitative indicator for the dissociation mechanism discussed here. A discussion of the analysis of experimental data that enables one to extract molecular rate constants is presented. Furthermore, comparisons are made between the nonredistributing model presented here and Epstein's model [Epstein, I. R. (1979) Biopolymers 18 , 2037–2050] in which protein can translocate infinitely quickly while bound to the nucleic acid, and hence protein clusters redistribute during dissociation and maintain an equilibrium distribution on the nucleic acid at all times.     

Nucleic acid induced unfolding of recombinant prion protein globular fragment is pH dependent

Nucleic acid can catalyze the conversion of α‐helical cellular prion protein to β‐sheet rich Proteinase K resistant prion protein oligomers and amyloid polymers in vitro and in solution. Because unfolding of a protein molecule from its ordered α‐helical structure is considered to be a necessary step for the structural conversion to its β‐sheet rich isoform, we have studied the unfolding of the α‐helical globular 121–231 fragment of mouse recombinant prion protein in the presence of different nucleic acids at neutral and acid pH. Nucleic acids, either single or double stranded, do not have any significant effect on the secondary structure of the protein fragment at neutral pH; however the protein secondary structure is modified by the nucleic acids at pH 5. Nucleic acids do not show any significant effect on the temperature induced unfolding of the globular prion protein domain at neutral pH which, however, undergoes a gross conformational change at pH 5 as evidenced from the lowering of the midpoint of thermal denaturation temperatures, Tm, of the protein. The extent of Tm decrease shows a dependence on the nature of nucleic acid. The interaction of nucleic acid with the nonpolar groups exposed from the protein interior at pH 5 probably contributes substantially to the unfolding process of the protein.     

Coarse-grained free energy functions for studying protein conformational changes: a double-well network model

In this work, a double-well network model (DWNM) is presented for generating a coarse-grained free energy function that can be used to study the transition between reference conformational states of a protein molecule. Compared to earlier work that uses a single, multidimensional double-well potential to connect two conformational states, the DWNM uses a set of interconnected double-well potentials for this purpose. The DWNM free energy function has multiple intermediate states and saddle points, and is hence a “rough” free energy landscape. In this implementation of the DWNM, the free energy function is reduced to an elastic-network model representation near the two reference states. The effects of free energy function roughness on the reaction pathways of protein conformational change is demonstrated by applying the DWNM to the conformational changes of two protein systems: the coil-to-helix transition of the DB-loop in G-actin and the open-to-closed transition of adenylate kinase. In both systems, the rough free energy function of the DWNM leads to the identification of distinct minimum free energy paths connecting two conformational states. These results indicate that while the elastic-network model captures the low-frequency vibrational motions of a protein, the roughness in the free energy function introduced by the DWNM can be used to characterize the transition mechanism between protein conformations.     

Abundant mRNAs specific to the developing cotton fibre

 Five fibre-specific cDNA clones were isolated by differential screening of a cDNA library from cotton fibres, a developmentally synchronous population of non-dividing cells. The genes corresponding to these cDNAs were expressed preferentially in fibre cells and exhibited differing patterns of temporal expression during fibre development. One cDNA encoded a lipid transfer protein (LTP), and a second encoded a member of a group of well-characterised proline-rich proteins (PRP) from plants. The presence of signal peptide-encoding sequences suggests that both the LTP and the PRP are targeted to the extracellular matrix of the fibre, and a role is envisaged for each in cell elongation. Sequence analysis showed that a third clone was similar to a previously reported fibre-specific sequence of unknown function, whilst the remaining two cDNA clones showed no sequence similarity to previously reported plant nucleic acids. Received: 24 September 1996 / Accepted: 18 October 1996     

Conformational transition occurring upon amyloid aggregation of the HET-s prion protein of Podospora anserina analyzed by hydrogen/deuterium exchange and mass spectrometry

The [Het-s] infectious element of the filamentous fungus Podospora anserina corresponds to the prion form of the HET-s protein. HET-s (289 amino acids in length) aggregates into amyloid fibers in vitro. Such fibers obtained in vitro are infectious, indicating that the [Het-s] prion can propagate as a self-perpetuating amyloid aggregate of the HET-s protein. Previous analyses have suggested that only a limited region of the HET-s protein is involved in amyloid formation and prion propagation. To document the conformational transition occurring upon amyloid aggregation of HET-s, we have developed a method involving hydrogen/deuterium exchange monitored by MALDI-MS. In a first step, a peptide mass fingerprint of the protein was obtained, leading to 87% coverage of the HET-s primary structure. Amyloid aggregates of HET-s were obtained, and H/D exchange was monitored on the soluble and on the amyloid form of HET-s. This study revealed that in the soluble form of HET-s, the C-terminal region (spanning from residues 240-289) displays a high solvent accessibility. In sharp contrast, solvent accessibility is drastically reduced in that region in the amyloid form. H/D exchange rates and levels in the N-terminal part of the protein (residues 1-220) are comparable in the soluble and the aggregated state. These results indicate that amyloid aggregation of HET-s involves a conformational transition of the C-terminal part of the protein from a mainly disordered to an aggregated state in which this region is highly protected from hydrogen exchange.     

The origin of the RNA world: co-evolution of genes and metabolism

Discoveries demonstrating that RNA can serve genetic, catalytic, structural, and regulatory roles have provided strong support for the existence of an RNA World that preceded the origin of life as we know it. Despite the appeal of this idea, it has been difficult to explain how macromolecular RNAs emerged from small molecules available on the early Earth. We propose here a mechanism by which mutual catalysis in a pre-biotic network initiated a progression of stages characterized by ever larger and more effective catalysts supporting a proto-metabolic network, and the emergence of RNA as the dominant macromolecule due to its ability to both catalyze chemical reactions and to be copied in a template-directed manner. This model suggests that many features of modern life, including the biosynthetic pathways leading to simple metabolites, the structures of organic and metal ion cofactors, homochirality, and template-directed replication of nucleic acids, arose long before the RNA World and were retained as pre-biotic systems became more sophisticated.     

Selenium Derivatization of Nucleic Acids for X‐Ray Crystal‐Structure and Function Studies

It is estimated that over two thirds of all new crystal structures of proteins are determined via the protein selenium derivatization (selenomethionine (Se‐Met) strategy). This selenium derivatization strategy via MAD (multi‐wavelength anomalous dispersion) phasing has revolutionized protein X‐ray crystallography. Through our pioneer research, similarly, Se has also been successfully incorporated into nucleic acids to facilitate the X‐ray crystal‐structure and function studies of nucleic acids. Currently, Se has been stably introduced into nucleic acids by replacing nucleotide O‐atom at the positions 2′, 4′, 5′, and in nucleobases and non‐bridging phosphates. The Se derivatization of nucleic acids can be achieved through solid‐phase chemical synthesis and enzymatic methods, and the Se‐derivatized nucleic acids (SeNA) can be easily purified by HPLC, FPLC, and gel electrophoresis to obtain high purity. It has also been demonstrated that the Se derivatization of nucleic acids facilitates the phase determination via MAD phasing without significant perturbation. A growing number of structures of DNAs, RNAs, and protein–nucleic acid complexes have been determined by the Se derivatization and MAD phasing. Furthermore, it was observed that the Se derivatization can facilitate crystallization, especially when it is introduced to the 2′‐position. In addition, this novel derivatization strategy has many advantages over the conventional halogen derivatization, such as more choices of the modification sites via the atom‐specific substitution of the nucleotide O‐atom, better stability under X‐ray radiation, and structure isomorphism. Therefore, our Se‐derivatization strategy has great potentials to provide rational solutions for both phase determination and high‐quality crystal growth in nucleic‐acid crystallography. Moreover, the Se derivatization generates the nucleic acids with many new properties and creates a new paradigm of nucleic acids. This review summarizes the recent developments of the atomic site‐specific Se derivatization of nucleic acids for structure determination and function study. Several applications of this Se‐derivatization strategy in nucleic acid and protein research are also described in this review.