The C-terminal extrahelical peptide of type I collagen and its role in fibrillogenesis in vitro

The formation in vitro of fibrils from type I acid-soluble calf skin collagen has been studied before and after removal of the extrahelical peptides with carboxypeptidase and with pepsin. Turbidimetric studies show that the mechanism of fibril growth in undigested collagen is similar to that in pepsin-digested collagen; following carboxypeptidase digestion, however, a different growth mechanism was apparent. The two mechanisms have been further characterized by electron microscopy. In the course of formation of fibrils from undigested collagen, “early fibrils” (short D-periodic fibrils that have both ends visible) occurred in the lag phase under the precipitating conditions employed here. After pepsin or carboxypeptidase digestion of the collagen no “early fibrils” were seen. In carboxypeptidase-digested collagen, lateral assembly was inhibited; after pepsin digestion, linear assembly was inhibited. Complete removal of the extrahelical peptides prevented fibril formation under the conditions used here. Electron-optical examination of segment-long-spacing (SLS) dimers established a more complete removal of the C-terminal peptide after carboxypeptidase digestion than after pepsin digestion. Analyses of staining patterns of SLS dimers and fibrils from undigested and digested samples showed that the C-terminal peptide in SLS crystallites and fibrils formed from undigested collagen is in a condensed conformation. A proposed conformation, in which condensation occurs predominantly in a hydrophobic region at the proximal end of the C-terminal peptide, is discussed in terms of a dual role for the C-terminal peptide in fibrillogenesis. One role, shared with the N-terminal peptide, is to participate in interactions between the 4D-staggered molecules leading to the formation of linear aggregates; the other is to participate in interactions between these linear aggregates giving rise to D-periodic aggregates and lateral (as well as linear) growth.     

Collagen fibril formation in the presence of sodium dodecyl sulphate.

Sodium dodecyl sulphate (SDS) was used to weaken both the electrostatic and the hydrophobic interactions during collagen fibrillogenesis in vitro. The rate and extent of fibril formation as well as fibril morphology were affected by SDS concentration. Both the formation of large fibrils at 0.3 mM-SDS and the complete cessation of fibril formation at 0.5 mM-SDS were considered to be the result of SDS-induced conformational changes in the non-helical telopeptides. A possible mechanism of SDS interaction with the N-terminal and the distal region of the C-terminal telopeptides is offered.     

A peptide study of the relationship between the collagen triple-helix and amyloid

Type XXV collagen, or collagen‐like amyloidogenic component, is a component of amyloid plaques, and recent studies suggest this collagen affects amyloid fibril elongation and has a genetic association with Alzheimer's disease. The relationship between the collagen triple helix and amyloid fibrils was investigated by studying peptide models, including a very stable triple helical peptide (Pro‐Hyp‐Gly)₁₀, an amyloidogenic peptide GNNQQNY, and a hybrid peptide where the GNNQQNY sequence was incorporated between (GPO)_n domains. Circular dichroism and nuclear magnetic resonance (NMR) spectroscopy showed the GNNQQNY peptide formed a random coil structure, whereas the hybrid peptide contained a central disordered GNNQQNY region transitioning to triple‐helical ends. Light scattering confirmed the GNNQQNY peptide had a high propensity to form amyloid fibrils, whereas amyloidogenesis was delayed in the hybrid peptide. NMR data suggested the triple‐helix constraints on the GNNQQNY sequence within the hybrid peptide may disfavor the conformational change necessary for aggregation. Independent addition of a triple‐helical peptide to the GNNQQNY peptide under aggregating conditions delayed nucleation and amyloid fibril growth. The inhibition of amyloid nucleation depended on the Gly‐Xaa‐Yaa sequence and required the triple‐helix conformation. The inhibitory effect of the collagen triple‐helix on an amyloidogenic sequence, when in the same molecule or when added separately, suggests Type XXV collagen, and possibly other collagens, may play a role in regulating amyloid fibril formation. © 2012 Wiley Periodicals, Inc. Biopolymers 97: 795–806, 2012.     

Collagen denaturation in spread monolayers at the air-water interface: Experiments and a possible model of the process

Spread monolayers of the fibril protein collagen were studied at the air-water interface in the presence of denaturants, urea and thiourea. The most prominent feature of spread collagen monolayers at the air-water interface is the ability to form supramolecular structures (fibrils), which themselves can form monolayers with collapse points of their own. The surface pressure isotherms of collagen monolayers have two “quasi-linear” centers, which are separated by a plateau and correspond to liquid-expanded and liquid-condensed states; this unique capability makes collagen different from other proteins. When in monolayer, collagen acquires the same level of structural organization as in the bulk. In the presence of denaturants, subphase characteristics of collagen monolayers change rapidly and irreversibly. Thiourea exerts more pronounced denaturing action on collagen monolayers than urea; this effect increases with exposure time and denaturant concentration. A hypothetical mechanism of thiourea-induced denaturation of fibril proteins is proposed according to which interactions between hydrophobic C=S groups of thiourea and nonpolar surface groups of the protein lead to reorientation of carbonyl groups to formation of intrinsic hydrogen bonds with NH₂-groups of thiourea eventually resulting in the rupture of intrinsic hydrogen bonds and denaturation of the protein.     

What Drives Amyloid Molecules To Assemble into Oligomers and Fibrils?

We develop a theory for three states of equilibrium of amyloid peptides: the monomer, oligomer, and fibril. We assume that the oligomeric state is a disordered micellelike collection of a few peptide chains held together loosely by hydrophobic interactions into a spherical hydrophobic core. We assume that fibrillar amyloid chains are aligned and further stabilized by steric zipper interactions—hydrogen bonding, steric packing, and specific hydrophobic side-chain contacts. The model makes a broad set of predictions that are consistent with experimental results: 1), Similar to surfactant micellization, amyloid oligomerization should increase with peptide concentration in solution. 2), The onset of fibrillization limits the concentration of oligomers in the solution. 3), The extent of Aβ fibrillization increases with peptide concentration. 4), The predicted average fibril length versus monomer concentration agrees with data on α-synuclein. 5), Full fibril length distributions agree with data on α-synuclein. 6), Denaturants should melt out fibrils. And finally, 7), added salt should stabilize fibrils by reducing repulsions between amyloid peptide chains. It is of interest that small changes in solvent conditions can tip the equilibrium balance between oligomer and fibril and cause large changes in rates through effects on the transition-state barrier. This model may provide useful insights into the physical processes underlying amyloid diseases.     

A study of the growth of normal and iodinated collagen fibrils in vitro using electron microscope autoradiography

Electron microscopic autoradiographic observations on collagen fibrils grown in vitro allow growth rates in the N- and C-terminal directions to be measured on individual fibrils. Such observations, made on normal and iodinated collagen, show that normal fibrils grow at both ends (although rather more rapidly at the N-terminal end), whereas fully-iodinated collagen fibrils grow only at the N-terminal end. Measurements of growth rates at different temperatures provide estimates of the activation enthalpy (ΔH^≠) and entropy (ΔS^≠) of precipitation for the two types of collagen. Solubility measurements have also yielded values for the thermodynamic enthalpy (ΔH) and entropy (ΔS) of precipitation. Results show that the activated (rate-limiting) state is characterized by a large positive ΔH^≠ and ΔS^≠ similar in magnitude to the ΔH and ΔS of transition from solution to fibril. It is also concluded that the different rates of precipitation of normal and iodinated collagen cannot be explained in terms of fibril formation requiring ionization of the tyrosine residues.     

Molecular Dynamics Simulations of Anti-Aggregation Effect of Ibuprofen

Using implicit solvent molecular dynamics and replica exchange simulations, we study the impact of ibuprofen on the growth of wild-type Aβ fibrils. We show that binding of ibuprofen to Aβ destabilizes the interactions between incoming peptides and the fibril. As a result, ibuprofen interference modifies the free energy landscape of fibril growth and reduces the free energy gain of Aβ peptide binding to the fibril by ≃2.5 RT at 360 K. Furthermore, ibuprofen interactions shift the thermodynamic equilibrium from fibril-like locked states to disordered docked states. Ibuprofen''s anti-aggregation effect is explained by its competition with incoming Aβ peptides for the same binding site located on the fibril edge. Although ibuprofen impedes fibril growth, it does not significantly change the mechanism of fibril elongation or the structure of Aβ peptides bound to the fibril.     

Investigation on interaction of tannic acid with type I collagen and its effect on thermal,enzymatic, and conformational stability for tissue engineering applications

Collagen is an essential component of tissues, which is the most abundant component in extracellular matrix and highly conserved across the animal kingdom. It can assemble into fiber and play an essential role in cell adhesion and growth and could be extremely useful in tissue engineering. In this study, the effect of tannic acid (TA) on the thermal, enzymatic and conformational stability of type I collagen has been investigated for the development of collagen‐based biomaterials. Interaction of TA with collagen demonstrates the role of hydrogen bonding and hydrophobic interaction in providing the thermal and enzymatic stability. Thermal analysis studies reveal that, hydrothermal stability of collagen increases as well as inhibits the breakdown of collagenase by formation of hydrogen bonds and hydrophobic interactions. TA binds to the collagen with high affinity because the structural flexibility of the collagen compensates for the structural rigidity of the phenolics. Increase in concentration of TA induces significant change in the conformation of triple helix. The free binding energy of TA with collagen‐like peptide was determined to be in the range of ?9.4 to ?11.2 kcal mol^?1, which was calculated by using Autodock Vina software and showed numerous hydrophobic and hydrogen bond interactions. We anticipate that these collagen‐based biomaterials hold great potential for biomedical applications. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 471–483, 2014.     

Structural Transitions and Interactions in the Early Stages of Human Glucagon Amyloid Fibrillation

A mechanistic understanding of the intermolecular interactions and structural changes during fibrillation is crucial for the design of safe and efficacious glucagon formulations. Amide hydrogen/deuterium exchange with mass spectrometric analysis was used to identify the interactions and amino acids involved in the initial stages of glucagon fibril formation at acidic pH. Kinetic measurements from intrinsic and thioflavin T fluorescence showed sigmoidal behavior. Secondary structural measurement of fibrillating glucagon using far-UV circular dichroism spectroscopy showed changes in structure from random coil → α-helix → β-sheet, with increase in α-helix content during the lag phase followed by increase in β-sheet content during the growth phase. Hydrogen/deuterium exchange with mass spectrometric analysis of fibrillating glucagon suggested that C-terminal residues 22–29 are involved in interactions during the lag phase, during which N-terminal residues 1–6 showed no changes. Molecular dynamics simulations of glucagon fragments showed C-terminal to C-terminal interactions with greater α-helix content for the 20–29 fragment, with hydrophobic and aromatic residues (Phe-22, Trp-25, Val-23, and Met-27) predominantly involved. Overall, the study shows that glucagon interactions during the early phase of fibrillation are mediated through C-terminal residues, which facilitate the formation of α-helix-rich oligomers, which further undergo structural rearrangement and elongation to form β-sheet-rich mature fibrils.     

Identification and characterization of a novel fibril forming peptide in fungal starch binding domain

Scanty information is available regarding the chemical basis for structural alterations of the carbohydrate-binding modules (CBMs). The N-terminal starch binding domain (SBD) of Rhizopus oryzae glucoamylase (GA) forms fibrils under thermal stress, presenting an unusual conformational change from immunoglobulin-like to β-sheet-rich structure. Site-directed mutagenesis revealed that the C-terminal Lys of SBD played a crucial role in the fibril formation. The synthetic peptide (DNNNSANYQVSTSK) representing the C-terminal 14 amino acid residues of SBD was further demonstrated to act as a fibril-forming segment, in which terminal charges and an internal NNNxxNYQ motif were key fibril-forming determinants. The formation of fibril structure in a fungal SBD, caused by its chemical and biophysical requirements, was demonstrated for the first time.     

The role of hydrophobic bonding in collagen fibril formation: a quantitative model

A model has been developed for approximating the free energy of collagen fibril formation (ΔF_f) and the equilibrium solubility of collagen under physiological conditions. The model utilizes an expression of Flory for rodlike polymers, with the modification that the “pure” anisotropic phase is defined as a collagen fibril containing about 0.3 g water/g collagen. The model also assumes that χ₁, the polymer–solvent interaction term, is entirely due to hydrophobic effects. χ₁ is estimated from hydrophobic bond energies of amino acid side chains, using the results of Némethy and Scheraga. The temperature dependence of χ₁ is utilized to calculate equilibrium solubilities and ΔF_f as a function of temperature.     

Characterization of nuclei in in vitro collagen fibril formation.

Heat precipitation fibril formation in collagen solutions depends upon the prior thermal history of the solution. Collagen solutions were heat precipitated to various extents at 30°C, cooled, and then brought to a second precipitation. Kinetic analysis of the secondary precipitation demonstrated that only the nucleation phase of the precipitation was affected, not the fibril growth phase. Thermal history, or memory, is thus related to the formation of low-temperature-stable nuclei. A range of nuclei sizes is evident, supporting the concept of a homogeneous nucleation process. Schiffs base formation and establishment of cross-linkages play no role in the in vitro nucleation: thiosemicarbazide treated collagen behaves identically to untreated collagen in kinetics of assembly to fibrils. Low-temperature-stable nuclei formed at neutral pH are dissociated in the cold in acetic acid at pH 4. Pronase and pepsin susceptible molecular end regions are important in establishing the low-temperature-stable nuclei. Pronase treatment completely abolishes the acquisition of memory of prior thermal history in collagen solutions. We speculate that biological control mechanisms for fibril formation in vivo relate to specific interactions between non-helical, enzyme susceptible regions on collagen molecules.     

Determining the critical nucleus and mechanism of fibril elongation of the Alzheimer's Abeta(1-40) peptide

We use a coarse-grained protein model to characterize the critical nucleus, structural stability, and fibril elongation propensity of Aβ_1-40 oligomers for the C_2x and C_2z quaternary forms proposed by solid-state NMR. By estimating equilibrium populations of structurally stable and unstable protofibrils, we determine the shift in the dominant population from free monomer to ordered fibril at a critical nucleus of ten chains for the C_2x and C_2z forms. We find that a minimum assembly of 16 monomer chains is necessary to mimic a mature fibril, and show that its structural stability correlates with a plateau in the hydrophobic residue density and a decrease in the likelihood of losing hydrophobic interactions by rotating the fibril subunits. While Aβ_1-40 protofibrils show similar structural stability for both C_2x and C_2z quaternary structures, we find that the fibril elongation propensity is greater for the C_2z form relative to the C_2x form. We attribute the increased propensity for elongation of the C_2z form as being due to a stagger in the interdigitation of the N-terminal and C-terminal β-strands, resulting in structural asymmetry in the presented fibril ends that decreases the amount of incorrect addition to the N terminus on one end. We show that because different combinations of stagger and quaternary structure affect the structural symmetry of the fibril end, we propose that differences in quaternary structures will affect directional growth patterns and possibly different morphologies in the mature fiber.     

Molecular Dynamics Simulations to Investigate the Structural Stability and Aggregation Behavior of the GGVVIA Oligomers Derived from Amyloid β Peptide

Abstract

Several neurodegenerative diseases, such as Alzheimer's, Parkinson's, and Huntington's dis-eases, are associated with amyloid fibrils formed by different polypeptides. Recently, the atomic structure of the amyloid-forming peptide GGVVIA from the C-terminal hydrophobic segment of amyloid-β (Aβ) peptide has been determined and revealed a dry, tightly self-com-plementing structure between two β-sheets, termed as “steric zipper”. In this study, several all-atom molecular dynamics simulations with explicit water were conducted to investigate the structural stability and aggregation behavior of the GGVVIA oligomers with various sizes. The results of our single-layer models suggested that the structural stability of the GGVVIA oligomers increases remarkably with increasing the numbers of β-strands. We fur-ther identified that SH2-ST2 may act as a stable seed in prompting amyloid fibril formations. Our results also demonstrated that hydrophobic interaction is the principle driving force to stabilize and associate the GGVVIA oligomers between β-strands; while the hydrophobic steric zipper formed via the side chains of V3, V4, and I5 plays a critical role in holding the two neighboring β-sheets together. Single glycine substitution at V3, V4, and I5 directly disrupted the hydrophobic steric zipper between these two β-sheets, resulting in the destabili-zation of the oligomers. Our simulation results provided detailed insights into understanding the aggregation behavior of the GGVVIA oligomers in the atomic level. It may also be help-ful for designing new inhibitors able to prevent the fibril formation of Aβ peptide.     

Amyloid fibril formation requires a chemically discriminating nucleation event: studies of an amyloidogenic sequence from the bacterial protein OsmB.

The sequence of the Escherichia coli OsmB protein was found to resemble that of the C-terminal region of the beta amyloid protein of Alzheimer's disease, which seems to be the major determinant of its unusual structural and solubility properties. A peptide corresponding to residues 28-44 of the OsmB protein was synthesized, and its conformational properties and aggregation behavior were analyzed. The peptide OsmB(28-44) was shown to form amyloid fibrils, as did two sequence analogs designed to test the sequence specificity of fibril formation. These fibrils bound Congo red, and two of the peptides showed birefringence. The peptide fibrils were analyzed by electron microscopy and Fourier transform infrared spectroscopy. Subtle differences were observed which were not interpretable at the molecular level. The rate of fibril formation by each peptide was followed by monitoring the turbidity of supersaturated aqueous solutions. The kinetics of aggregation were characterized by a delay period during which the solution remained clear, followed by a nucleation event which led to a growth phase, during which the solution became viscous and turbid due to the presence of insoluble fibrils. The observation of a kinetic barrier to aggregation is typical of a crystallization event. The delay period could be eliminated by seeding the supersaturated solution with previously formed fibrils. Each peptide could be nucleated by fibrils formed from that same peptide, but not by fibrils from closely related sequences, suggesting that fibril growth requires specific hydrophobic interactions. It appears likely that this repeated sequence motif, which comprises most of the OsmB protein sequence, dictates the structure and possibly the function of that protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding Modes of Phthalocyanines to Amyloid β Peptide and Their Effects on Amyloid Fibril Formation

The inherent tendency of proteins to convert from their native states into amyloid aggregates is associated with a range of human disorders, including Alzheimer’s and Parkinson’s diseases. In that sense, the use of small molecules as probes for the structural and toxic mechanism related to amyloid aggregation has become an active area of research. Compared with other compounds, the structural and molecular basis behind the inhibitory interaction of phthalocyanine tetrasulfonate (PcTS) with proteins such as αS and tau has been well established, contributing to a better understanding of the amyloid aggregation process in these proteins. We present here the structural characterization of the binding of PcTS and its Cu(II) and Zn(II)-loaded forms to the amyloid β-peptide (Aβ) and the impact of these interactions on the peptide amyloid fibril assembly. Elucidation of the PcTS binding modes to Aβ₄₀ revealed the involvement of specific aromatic and hydrophobic interactions in the formation of the Aβ₄₀-PcTS complex, ascribed to a binding mode in which the planarity and hydrophobicity of the aromatic ring system in the phthalocyanine act as main structural determinants for the interaction. Our results demonstrated that formation of the Aβ₄₀-PcTS complex does not interfere with the progression of the peptide toward the formation of amyloid fibrils. On the other hand, conjugation of Zn(II) but not Cu(II) at the center of the PcTS macrocyclic ring modified substantially the binding profile of this phthalocyanine to Aβ₄₀ and became crucial to reverse the effects of metal-free PcTS on the fibril assembly of the peptide. Overall, our results provide a firm basis to understand the structural rules directing phthalocyanine-protein interactions and their implications on the amyloid fibril assembly of the target proteins; in particular, our results contradict the hypothesis that PcTS might have similar mechanisms of action in slowing the formation of a variety of pathological aggregates.     

Mechanism of fiber assembly: treatment of Aβ peptide aggregation with a coarse-grained united-residue force field

The growth mechanism of β-amyloid (Aβ) peptide fibrils was studied by a physics-based coarse-grained united-residue model and molecular dynamics (MD) simulations. To identify the mechanism of monomer addition to an Aβ_1-40 fibril, we placed an unstructured monomer at a distance of 20 Å from a fibril template and allowed it to interact freely with the latter. The monomer was not biased towards fibril conformation by either the force field or the MD algorithm. With the use of a coarse-grained model with replica-exchange molecular dynamics, a longer timescale was accessible, making it possible to observe how the monomers probe different binding modes during their search for the fibril conformation. Although different assembly pathways were seen, they all follow a dock-lock mechanism with two distinct locking stages, consistent with experimental data on fibril elongation. Whereas these experiments have not been able to characterize the conformations populating the different stages, we have been able to describe these different stages explicitly by following free monomers as they dock onto a fibril template and to adopt the fibril conformation (i.e., we describe fibril elongation step by step at the molecular level). During the first stage of the assembly (“docking”), the monomer tries different conformations. After docking, the monomer is locked into the fibril through two different locking stages. In the first stage, the monomer forms hydrogen bonds with the fibril template along one of the strands in a two-stranded β-hairpin; in the second stage, hydrogen bonds are formed along the second strand, locking the monomer into the fibril structure. The data reveal a free-energy barrier separating the two locking stages. The importance of hydrophobic interactions and hydrogen bonds in the stability of the Aβ fibril structure was examined by carrying out additional canonical MD simulations of oligomers with different numbers of chains (4-16 chains), with the fibril structure as the initial conformation. The data confirm that the structures are stabilized largely by hydrophobic interactions and show that intermolecular hydrogen bonds are highly stable and contribute to the stability of the oligomers as well.     

Probing the importance of lateral hydrophobic association in self-assembling peptide hydrogelators

A class of peptides has been designed whose ability to self-assemble into hydrogel is dependent on their conformationally folded state. Under unfolding conditions aqueous peptide solutions are freely flowing having the viscosity of water. When folding is triggered by external stimuli, peptides adopt a β-hairpin conformation that self-assembles into a highly crosslinked network of fibrils affording mechanically rigid hydrogels. MAX 1, a 20 residue, amphiphilic hairpin self-assembles via a mechanism which entails both lateral and facial self-assembly events to form a network of fibrils whose local structure consists of a bilayer of hairpins hydrogen bonded in the direction of fibril growth. Lateral self-assembly along the long axis of the fibril is mainly facilitated by intermolecular hydrogen bonding between the strands of distinct hairpins and the formation of hydrophobic contacts between residue side chains of laterally associating hairpins. Facial assembly is driven by the hydrophobic collapse of the valine-rich faces of the amphiphilic hairpins affording a bilayer laminate. The importance of forming lateral hydrophobic contacts during hairpin self-assembly and the relative contribution these interactions have towards nano-scale morphology and material rigidity is probed via the study of: MAX1, a hairpin designed to exploit lateral hydrophobic interactions; MAX 4, a peptide with reduced ability to form these interactions; and MAX5, a control peptide. CD spectroscopy and rheological experiments suggest that the formation of lateral hydrophobic interactions aids the kinetics of assembly and contributes to the mechanical rigidity of the hydrogel. Transmission electron microscopy (TEM) shows that these interactions play an essential role in the self-assembly process leading to distinct nano-scale morphologies. Electronic Supplementary Material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

The potential inhibitory effect of β-casein on the aggregation and deposition of Aβ1-42 fibrils in Alzheimer’s disease: insight from in-vitro and in-silico studies

Aβ_1-40 and Aβ_1-42 have been shown to be the main components of the amyloid plaques found in the extracellular environment of neurons in Alzheimer’s disease. β-Casein, a milk protein, has been shown to display a remarkable chaperone ability in preventing the aggregation of proteins. In this study, the ability of β-casein to suppress the amyloid fibril formation of Aβ_1-42 has been examined through in vitro studies and molecular docking simulation. The results demonstrate the inhibitory effect of β-casein on fibril formation in Aβ_1-42, in a concentration dependent manner, suggesting that the chaperone binds to the Aβ_1-42 and prevents amyloid fibril formation. Molecular docking results show that the inhibitory effect of the β-casein may be due to binding of the chaperone with the aggregation-prone region of the Aβ_1-42 mainly via hydrophobic interactions. β-Casein probably binds to the CHC and C-terminal domain of the Aβ_1-42, and stabilizes proteins by inhibiting the conversion of monomeric Aβ_1-42 into fibrils. Thus our data suggests that the hydrophobic interactions between β-casein and Aβ_1-42 play an important role in the burial of the hydrophobic part of the Aβ_1-42. This means that β-casein maybe considered for use in preventing amyloid fibril formation in degenerative diseases such as Alzheimer.     

Amelogenin-Collagen Interactions Regulate Calcium Phosphate Mineralization in Vitro

Collagen and amelogenin are two major extracellular organic matrix proteins of dentin and enamel, the mineralized tissues comprising a tooth crown. They both are present at the dentin-enamel boundary (DEB), a remarkably robust interface holding dentin and enamel together. It is believed that interactions of dentin and enamel protein assemblies regulate growth and structural organization of mineral crystals at the DEB, leading to a continuum at the molecular level between dentin and enamel organic and mineral phases. To gain insight into the mechanisms of the DEB formation and structural basis of its mechanical resiliency we have studied the interactions between collagen fibrils, amelogenin assemblies, and forming mineral in vitro, using electron microscopy. Our data indicate that collagen fibrils guide assembly of amelogenin into elongated chain or filament-like structures oriented along the long axes of the fibrils. We also show that the interactions between collagen fibrils and amelogenin-calcium phosphate mineral complexes lead to oriented deposition of elongated amorphous mineral particles along the fibril axes, triggering mineralization of the bulk of collagen fibril. The resulting structure was similar to the mineralized collagen fibrils found at the DEB, with arrays of smaller well organized crystals inside the collagen fibrils and bundles of larger crystals on the outside of the fibrils. These data suggest that interactions between collagen and amelogenin might play an important role in the formation of the DEB providing structural continuity between dentin and enamel.