Investigating the origins of nanostructural variations in differential ethnic hair types using X-ray scattering techniques.

OBJECTIVE: Human hair is a major determinant of visual ethnic differentiation. Although hair types are celebrated as part of our ethnic diversity, the approach to hair care has made the assumption that hair types are structurally and chemically similar. Although this is clearly not the case at the macroscopic level, the intervention of many hair treatments is at the nanoscopic and molecular levels. The purpose of the work presented here is to identify the main nanoscopic and molecular hierarchical differences across five different ethnic hair types from hair fibres taken exclusively from the scalp. These are Afro (subdivided into elastic 'rubber' and softer non-elastic 'soft'), Chinese, European and Mullato (mixed race). METHODS: Small angle X-Ray scattering (SAXS) is a technique capable of resolving nanostructural variations in complex materials. Individual hair fibres from different ethnic hair types were used to investigate structural features found in common and also specific to each type. Simultaneous wide angle X-Ray scattering (WAXS) was used to analyse the submolecular level structure of the fibrous keratin present. The data sets from both techniques were analysed with principal component analysis (PCA) to identify underlying variables. RESULTS: Principal component analysis of both SAXS and WAXS data was shown to discriminate the scattering signal between different hair types. The X-ray scattering results show a common underlying keratin intermediate filament (KIF) structure. However, distinct differences were observed in the preferential orientation and intensity signal from the lipid component of the hair. In addition, differences were observed in the intensity distribution of the very low-angle sample-dependent diffuse scatter surrounding the 'beamstop.' CONCLUSION: The results indicate that the fibrous keratin scaffold remains consistent between ethnic hair types. The hierarchies made by these may be modulated by variation in the content of keratin-associated proteins (KAPs) and lipids that alter the interfacial structures and lead to macroscopic differences in hair morphology.

Protein and mineral characterisation of rendered meat and bone meal.

We report the characterisation of meat and bone meal (MBM) standards (Set B-EFPRA) derived from cattle, sheep, pig and chicken, each rendered at four different temperatures (133, 137, 141 and 145 °C). The standards, prepared for an EU programme STRATFEED (to develop new methodologies for the detection and quantification of illegal addition of mammalian tissues in feeding stuffs), have been widely circulated and used to assess a range of methods for identification of the species composition of MBM. The overall state of mineral alteration and protein preservation as a function of temperature was monitored using small angle X-ray diffraction (SAXS), amino acid composition and racemization analyses. Progressive increases in protein damage and mineral alteration in chicken and cattle standards was observed. In the case of sheep and pig, there was greater damage to the proteins and alteration of the minerals at the lowest treatment temperature (133 °C), suggesting that the thermal treatments must have been compromised in some way. This problem has probably impacted upon the numerous studies which tested methods against these heat treatments. We use protein mass spectrometric methods to explore if thermostable proteins could be used to identify rendered MBM. In more thermally altered samples, so-called 'thermostable' proteins such as osteocalcin which has been proposed as a ideal target to speciate MBM were no longer detectable, but the structural protein type I collagen could be used to differentiate all four species, even in the most thermally altered samples.

Calcium determines the supramolecular organization of fibrillin-rich microfibrils.

Microfibrils are ubiquitous fibrillin-rich polymers that are thought to provide long-range elasticity to extracellular matrices, including the zonular filaments of mammalian eyes. X-ray diffraction of hydrated bovine zonular filaments demonstrated meridional diffraction peaks indexing on a fundamental axial periodicity (D) of approximately 56 nm. A Ca2+-induced reversible change in the intensities of the meridional Bragg peaks indicated that supramolecular rearrangements occurred in response to altered concentrations of free Ca2+. In the presence of Ca2+, the dominant diffracting subspecies were microfibrils aligned in an axial 0.33-D stagger. The removal of Ca2+ caused an enhanced regularity in molecular spacing of individual microfibrils, and the contribution from microfibrils not involved in staggered arrays became more dominant. Scanning transmission electron microscopy of isolated microfibrils revealed that Ca2+ removal or addition caused significant, reversible changes in microfibril mass distribution and periodicity. These results were consistent with evidence from x-ray diffraction. Simulated meridional x-ray diffraction profiles and analyses of isolated Ca2+-containing, staggered microfibrillar arrays were used to interpret the effects of Ca2+. These observations highlight the importance of Ca2+ to microfibrils and microfibrillar arrays in vivo.

The variability in type I collagen helical pitch is reflected in the D periodic fibrillar structure.

The variability in amino acid axial rise per residue of the collagen helix is a potentially important parameter that is missing in many structural models of fibrillar collagen to date. The significance of this variability has been supported by evidence from collagen axial structures determined by electron microscopy and X-ray diffraction, as well as studies of the local sequence-dependent conformation of the collagen helix. Here, sequence-dependent variation of the axial rise per residue was used to improve the fit between simulated diffraction patterns derived from model structures of the axially projected microfibrillar structure and the observed X-ray diffraction pattern from hydrated rat tail tendon. Structural models were adjusted using a genetic algorithm that allowed a wide range of structures to be tested efficiently. The results show that variation of the axial rise per residue could reduce the difference metric between model and observed data by up to 50%, indicating that such a variable is a necessary part of fibril model structure building. The variation in amino acid translation was also found to be influenced by the number of proline and hydroxyproline residues in the triple helix structure.

Domains 17-27 of tropoelastin contain key regions of contact for coacervation and contain an unusual turn-containing crosslinking domain.

The central region of tropoelastin including domains 19-25 of human tropoelastin forms a hot-spot for contacts during the inter-molecular association of tropoelastin by coacervation [Wise, S.G., Mithieux, S.M., Raftery, M.J. and Weiss, A.S (2005). "Specificity in the coacervation of tropoelastin: solvent exposed lysines." Journal of Structural Biology 149: 273-81.]. We explored the physical properties of this central region using a sub-fragment bordered by domains 17-27 of human tropoelastin (SHEL 17-27) and identified the intra- and inter-molecular contacts it forms during coacervation. A homobifunctional amine reactive crosslinker (with a maximum reach of 11 A, corresponding to approximately 7 residues in an extended polypeptide chain) was used to capture these contacts and crosslinked regions were identified after protease cleavage and mass spectrometry (MS) with MS/MS verification. An intermolecular crosslink formed between the lysines at positions 353 of each strand of tropoelastin at the lowest of crosslinker concentrations and was observed in all samples tested, suggesting that this residue forms an important initial contact during coacervation. At higher crosslinker concentrations, residues K425 and K437 showed the highest levels of involvement in crosslinks. An intramolecular crosslink between these K425 and K437, separated by 11 residues, indicated that a structural bend must serve to bring these residues into close proximity. These studies were complemented by small angle X-ray scattering studies that confirmed a bend in this important subfragment of the tropoelastin molecule.

Collagen fibril form and function.

The majority of collagen in the extracellular matrix is found in a fibrillar form, with long slender filaments each displaying a characteristic approximately 67?nm D-repeat. Here they provide the stiff resilient part of many tissues, where the inherent strength of the collagen triple helix is translated through a number of hierarchical levels to endow that tissue with its specific mechanical properties. A number of collagen types have important structural roles, either comprising the core of the fibril or decorating the fibril surface to give enhanced functionality. The architecture of subfibrillar and suprafibrillar structures (such as microfibrils), lateral crystalline and liquid crystal ordering, interfibrillar interactions, and fibril bundles is described. The fibril surface is recognized as an area that contains a number of intimate interactions between different collagen types and other molecular species, especially the proteoglycans. The interplay between molecular forms at the fibril surface is discussed in terms of their contribution to the regulation of fibril diameter and their role in interfibrillar interactions.

The in situ conformation and axial location of the intermolecular cross-linked non-helical telopeptides of type I collagen.

BACKGROUND: Type I collagen contains specific lysine and hydroxylysine residues that are critical in the formation of intermolecular cross-links crucial for the normal configuration and stability of the 67 nm axial repeat of collagen fibrils in the extracellular matrix. The major cross-linkage sites are believed to occur between the non-helical terminal regions (telopeptides) and helical segments of adjacent collagen molecules. In this X-ray fibre diffraction study the tissue has been maintained in the hydrated fibrillar state, whilst detailed structural information was obtained using highly collimated synchrotron radiation. RESULTS: The axial component of the X-ray diffraction patterns extends more than twice as far in reciprocal space than that of any already published. The structure-factor phases were calculated using the multiple isomorphous addition method, avoiding model-based approaches, and produced an electron-density profile of the molecular arrangement projected on to the fibre axis to 0.54 nm resolution. This corresponds to the phasing of 124 orders of the meridional diffraction pattern. CONCLUSIONS: The axially projected electron-density profile and the electron-density difference maps showed that both the N- and C-terminal telopeptides are contracted structures. This profile puts narrow constraints on the possible conformations of the C-terminal telopeptide; the best fit to the electron-density profile is when the alpha1 chains adopt a folded conformation with a sharp hairpin turn around residues 13 and 14 of the 25-residue telopeptide. Our results reveal for the first time the location, parallel to the fibril axis, of the intermolecular cross-links in normal hydrated tissue. These cross-links are essential for the biological function of the tissue.

The in situ supermolecular structure of type I collagen.

BACKGROUND: The proteins belonging to the collagen family are ubiquitous throughout the animal kingdom. The most abundant collagen, type I, readily forms fibrils that convey the principal mechanical support and structural organization in the extracellular matrix of connective tissues such as bone, skin, tendon, and vasculature. An understanding of the molecular arrangement of collagen in fibrils is essential since it relates molecular interactions to the mechanical strength of fibrous tissues and may reveal the underlying molecular pathology of numerous connective tissue diseases. RESULTS: Using synchrotron radiation, we have conducted a study of the native fibril structure at anisotropic resolution (5.4 A axial and 10 A lateral). The intensities of the tendon X-ray diffraction pattern that arise from the lateral packing (three-dimensional arrangement) of collagen molecules were measured by using a method analogous to Rietveld methods in powder crystallography and to the separation of closely spaced peaks in Laue diffraction patterns. These were then used to determine the packing structure of collagen by MIR. CONCLUSIONS: Our electron density map is the first obtained from a natural fiber using these techniques (more commonly applied to single crystal crystallography). It reveals the three-dimensional molecular packing arrangement of type I collagen and conclusively proves that the molecules are arranged on a quasihexagonal lattice. The molecular segments that contain the telopeptides (central to the function of collagen fibrils in health and disease) have been identified, revealing that they form a corrugated arrangement of crosslinked molecules that strengthen and stabilize the native fibril.

Cross-linkage sites in type I collagen fibrils studied by neutron diffraction.

Cross-links in tendon collagen are essential for the biomechanical strength of healthy tissue. The nature and position of these cross-links has long been a subject for conjecture. We have approached this problem in a non-destructive manner, by studying neutron diffraction from collagen fibrils that have been specifically deuterated by reduction at keto-amine and Schiff base groups with sodium borodeuteride (NaB2H4). The intensities of the first 23 meridional reflections were recorded for both native and reduced tendons. These data were used to calculate the neutron-scattering density profile of the 67 nm (D) repeat of type I collagen fibrils in rat tail tendon. This approach not only succeeds in determining the location of the cross-linkage sites with respect to the fibril structure, as projected onto the fibre axis, but also presents a novel form of the isomorphous derivative solution to the phase problem.

Phasing the meridional diffraction pattern of type I collagen using isomorphous derivatives.

The meridional X-ray diffraction pattern of wet rat tail tendon contains information about the one-dimensional structure, or axial projection of electron density distribution of the type I collagen fibril. Using synchrotron radiation we have determined the intensities of the first 50 meridional X-ray diffraction reflections. The approach of isomorphous addition with reagents, selected using criteria of chemical reactivity, which label at fewer sites than the stains used in previous studies was applied to phase these 50 reflections to produce a one-dimensional electron density distribution map of a single D-repeat of the collagen fibril. This method is not model-dependent and thus constitutes the first unambiguous determination of the meridional phases of type I collagen.

Type I collagen packing, conformation of the triclinic unit cell.

The X-ray diffraction pattern of tendon collagen can contain a number of sharp Bragg peaks indicating three-dimensional crystallinity of the sample. Optimal diffraction images have been obtained with a high flux synchrotron X-ray source and a carefully maintained sample environment and staining techniques. The Bragg peaks are always superimposed on a diffuse background. This makes interpretation of data difficult and a number of conflicting models of collagen packing have been proposed. The removal of the diffuse scatter from the images allows the Bragg peaks to be seen on a relatively flat background. This was conducted by modelling the background points as a series of two-dimensional polynomial functions. The resultant set of observed Bragg reflections serves as an excellent basis to test the validity of two contradictory packing modes; (1) the triclinic model, Fraser et al., (2) the microfibril model, Kajava. From this it can easily be seen that the model proposed by Kajava is inappropriate, since there is limited agreement between predicted positions of reflections and the positions of observable reflections on film. The packing of collagen molecules on a triclinic lattice is favoured by this criterion.

Molecular packing of type I collagen in tendon.

X-ray diffraction of rat tail tendon shows that type I collagen fibrils contain regions of three-dimensional crystalline arrays; where molecular packing is speculated to be by a staggered sheet or microfibril arrangement. The X-ray diffraction pattern also contains a significant amount of diffuse scatter indicative of static and thermal disorder in fibrils. Removal of the diffuse scatter from the equatorial region of X-ray diffraction patterns obtained using synchrotron radiation allowed the Bragg intensities to be viewed on a flat background. Indexing of Bragg peak intensity on the 10, -10, 0 -1, 01, -11 and 1-1 row-lines of the triclinic unit cell have been used here to test possible sheet and microfibril packing arrangements. The relative translation of molecular segments in the gap and overlap regions as well as the telopeptide orientation have been investigated. A global search through combinations of molecular packing and molecular translation revealed that the sheet-type conformations cannot account for the observed low-angle off-meridional Bragg peak intensity distribution. A superior fit is obtained with D-staggered left-handed microfibril structures. The orientation of the telopeptides may indicate that there are interconnections between microfibrils that may explain the difficulty in isolating individual microfibrillar structures.

The in vivo glycation of diabetic tendon collagen studied by neutron diffraction.

Glycation (non-enzymatic glycosylation) sites in the axial unit cell of diabetic tendon collagen were investigated by neutron diffraction. Samples of diabetic and control tendon were reacted with sodium borodeuteride and sodium cyanoborodeuteride. This facilitated deuteration at aldimine, aldol or ketoimine groups in the molecule. These are natural collagen cross-links and sites where non-enzymatic glycation had occurred. The introduction of a deuteron at specific locations allowed the diabetic glycation collagen to be treated as multiple isomorphous derivatives for neutron fibre diffraction. Neutron diffraction was conducted at the Institut Laue Langevin, Grenoble. Standard crystallographic refinement techniques (modified for axial projections) were used to determine the structure of the control (non-diabetic) and diabetic samples. The results are shown as difference maps, these indicate that glycation takes place at different rates within the collagen axial unit cell. The position of glycation correlates well with the position of hydroxylysine residues. The reactions of periodate with enzymatically attached sugars, proteoglycan, natural cross-links and glycation products lead to complications in map interpretation.

A preliminary study of breast cancer diagnosis using laboratory based small angle x-ray scattering.

Breast tissue collected from tumour samples and normal tissue from bi-lateral mastectomy procedures were examined using small angle x-ray scattering. Previous work has indicated that breast tissue disease diagnosis could be performed using small angle x-ray scattering (SAXS) from a synchrotron radiation source. The technique would be more useful to health services if it could be made to work using a conventional x-ray source. Consistent and reliable differences in x-ray scatter distributions were observed between samples from normal and tumour tissue samples using the laboratory based 'SAXSess' system. Albeit from a small number of samples, a sensitivity of 100% was obtained. This result encourages us to pursue the implementation of SAXS as a laboratory based diagnosis technique.

An analysis of the lamellar structure of sea urchin egg cortical granules using X-ray scattering.

Cortical granules (CGs) are secretory vesicles associated with egg and oocyte plasma membranes that undergo exocytosis at fertilisation. In the sea urchin Strongylocentrotus purpuratus, the internal organisation of these CGs exhibits a lamellar-type morphology. The different lamellar layers correspond to proteoglycans, structural proteins and enzymes required for fertilisation envelope assembly and modification of the post-fertilisation egg surface. We have studied the lamellar structure of CGs using X-ray scattering and reveal the contrast density variation of the lamellae in the native state. The structure of functionally competent CGs in situ differs significantly from that determined by electron microscopic studies. We observed a strong periodicity of the lamellar structure of 280 A as opposed to the 590 A repeat observed previously. Fusion of the CGs produced a loss of the lamellar repeat and the development of a broad peak corresponding to a 20 A periodicity that may be indicative of the molecular packing in the resulting hydrated gel structure.

Fibrillin-rich microfibrils: an X-ray diffraction study of the fundamental axial periodicity.

Microfibrils are ubiquitous matrix polymers which are thought to provide elastic properties in all extracellular matrix structures. The major component of the elastic microfibrils is the protein fibrillin; its molecular structure is unknown. In electron microscopy, microfibrils appear as beaded structures exhibiting a variable periodicity, indicating that they may be elastomeric. The X-ray diffraction of fibrillin-rich microfibrils in the form of zonular filaments from bovine eyes exhibits meridional diffraction peaks indexing on a fundamental periodicity of 55 nm in the relaxed state. The application of a 40% extension produced a lengthening of the periodicity by 3% as judged by alteration of the D spacing of the principal peaks. This effect was shown to be reversible. Changes in the periodicity of the meridional reflections indicate changes in the fundamental structure of the microfilaments, but cannot account for all long range elastomeric properties of fibrillin-containing microfibrils.

Bone mineral change during experimental heating: an X-ray scattering investigation.

The effects of heating and burning on bone mineral have previously been studied using techniques such as X-ray diffraction (XRD) with the aim of discerning a characteristic signature of crystal change. This would enable a better understanding of alteration to bone mineral during heating, which would in turn impact on the preparation and use of natural bone hydroxyapatite as a biomaterial resource. In addition, this knowledge could prove invaluable in the investigation of burned human remains from forensic and archaeological contexts in cremation and funerary practice. Here we describe a complementary method, small-angle X-ray scattering (SAXS), to determine more accurately the changes to bone crystallite size and shape during an experimental heating regimen. Samples were subjected to controlled heating at 500 degrees C, 700 degrees C, or 900 degrees C for 15 or 45 min. Our results show bone crystallites begin to alter in the first 15 min of heating to 500 degrees C or above. They then appear to stabilise to a temperature-specific thickness and shape with prolonged heating. While the samples heated to lower temperatures or for shorter periods produce XRD traces showing little alteration to the apatite, corresponding information obtained from SAXS shows an early, subtle change in crystal parameters.

Molecular interactions in collagen and chitosan blends.

Molecular interactions between collagen and chitosan (CC) have the potential to produce biocomposites with novel properties. We have characterised the molecular interactions in CC complexes by viscometry, wide angle X-ray scattering and Fourier transform infrared spectroscopy. It was found that CC are miscible at the molecular level and exhibit interactions between the components; X-ray diffraction of CC blends indicate that the collagen helix structure is lost in CC films with increasing chitosan content. Non-linear viscometic behaviour with decreasing chitosan content is interpreted as evidence of a third structural phase formed as a complex of CC. The blending of collagen with chitosan gives the possibility of producing new bespoke materials for potential biomedical applications.

Fibrillin-rich microfibrils of the extracellular matrix: ultrastructure and assembly.

Fibrillin-rich microfibrils are a unique class of extensible connective tissue macromolecules. Their critical contribution to the establishment and maintenance of diverse extracellular matrices was underlined by the linkage of their principal structural component fibrillin to Marfan syndrome, a heritable connective tissue disorder with pleiotropic manifestations. Microscopy and preparative techniques have contributed substantially to the understanding of microfibril structure and function. The supramolecular organisation of microfibrillar assemblies in tissues has been examined by tissue sectioning and X-ray diffraction methods. Published findings are discussed and new information reported on the organisation of microfibrils in the ciliary zonular fibrils by environmental scanning electron microscopy. This review summarises microscopy and X-ray diffraction studies that are informing current understanding of the ultrastructure of fibrillin-rich microfibrils.

Effect of chemical modifications on the susceptibility of collagen to proteolysis. II. Dehydrothermal crosslinking.

Collagen was dehydrothermally treated (heat cured) by heating dry under vacuum at 60, 80, 100 and 120 degrees C. The change in stability was determined by subjecting to measurement of gross crosslinking, content of lysino-alanine and naturally occurring collagen crosslinks, shrinkage temperature (TM), susceptibility to digestion by lysosomal thiol proteases, and susceptibility to pepsin and trypsin. Morphological changes were examined by electron microscopy. The in vivo biodegradation of dehydrothermally treated collagen sponges was investigated using a rat lumbar muscle implantation model for up to 28 days. For all heat-cured collagens, the data strongly indicated that both crosslinking and denaturation/degradation was present in increasing quantities with increasing temperature of treatment, its level was too low (maximum 179 pmol mg-1) to account for the decreased solubility and increased molecular weight gross changes observed. Increasing resistance of treated collagen to both lysosomal cathepsins and pepsin correlated well with increased crosslinking and increasing temperature of the heat-curing process. However, increased denaturation/degradation of the collagen at higher temperatures was revealed by electrophoretic analysis, trypsin hydrolysis data and by electron microscopy. Differential scanning calorimetry (d.s.c.) correlated well with these results showing an increased level of denaturation in heated samples. The in vivo study showed little difference between control and heat-cured samples except for the material treated at 120 degrees C which was biodegraded in vivo at a significantly faster rate. The data shows, therefore, that crosslinking induced by the dehydrothermal treatment of collagen decreases its rate of proteolysis at acid pH in vitro. However, the simultaneous denaturation/degradation of the protein during the heat-cure process appears to be a more important factor in determining the fate of the material implanted into rat muscle.