Your search keyword '"Baldock, Clair"' showing total 215 results

201. Structural and compositional diversity of fibrillin microfibrils in human tissues.

Author

Eckersley A, Mellody KT, Pilkington S, Griffiths CEM, Watson REB, O'Cualain R, Baldock C, Knight D, and Sherratt MJ

Subjects

Aged, Cells, Cultured, Collagen Type VI analysis, Eye chemistry, Female, Fibrillin-1 ultrastructure, Humans, Male, Microfibrils ultrastructure, Microscopy, Atomic Force, Protein Conformation, Skin chemistry, Fibrillin-1 analysis, Microfibrils chemistry

Abstract

Elastic fibers comprising fibrillin microfibrils and elastin are present in many tissues, including the skin, lungs, and arteries, where they confer elasticity and resilience. Although fibrillin microfibrils play distinct and tissue-specific functional roles, it is unclear whether their ultrastructure and composition differ between elastin-rich (skin) and elastin-poor (ciliary body and zonule) organs or after in vitro synthesis by cultured cells. Here, we used atomic force microscopy, which revealed that the bead morphology of fibrillin microfibrils isolated from the human eye differs from those isolated from the skin. Using newly developed pre-MS preparation methods and LC-MS/MS, we detected tissue-specific regions of the fibrillin-1 primary structure that were differentially susceptible to proteolytic extraction. Comparing tissue- and culture-derived microfibrils, we found that dermis- and dermal fibroblast-derived fibrillin microfibrils differ in both bead morphology and periodicity and also exhibit regional differences in fibrillin-1 proteolytic susceptibility. In contrast, collagen VI microfibrils from the same dermal or fibroblast samples were invariant in ultrastructure (periodicity) and protease susceptibility. Finally, we observed that skin- and eye-derived microfibril suspensions were enriched in elastic fiber- and basement membrane-associated proteins, respectively. LC-MS/MS also identified proteins (such as calreticulin and protein-disulfide isomerase) that are potentially fundamental to fibrillin microfibril biology, regardless of their tissue source. Fibrillin microfibrils synthesized in cell culture lacked some of these key proteins (MFAP2 and -4 and fibrillin-2). These results showcase the structural diversity of these key extracellular matrix assemblies, which may relate to their distinct roles in the tissues where they reside., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

202. Targeted Modulation of Tropoelastin Structure and Assembly.

Author

Yeo GC, Baldock C, Wise SG, and Weiss AS

Abstract

Tropoelastin, as the monomer unit of elastin, assembles into elastic fibers that impart strength and resilience to elastic tissues. Tropoelastin is also widely used to manufacture versatile materials with specific mechanical and biological properties. The assembly of tropoelastin into elastic fibers or biomaterials is crucially influenced by key submolecular regions and specific residues within these domains. In this work, we identify the functional contributions of two rarely occurring negatively charged residues, glutamate 345 in domain 19 and glutamate 414 in domain 21, in jointly maintaining the native conformation of the tropoelastin hinge, bridge and foot regions. Alanine substitution of E345 and/or E414 variably alters the positioning and interactive accessibility of these regions, as illustrated by nanostructural studies and detected by antibody and cell probes. These structural changes are associated with a lower propensity for monomer coacervation, cross-linking into morphologically and functionally atypical hydrogels, and markedly impaired and abnormal elastic fiber formation. Our work indicates the crucial significance of both E345 and E414 residues in modulating specific local structure and higher-order assembly of human tropoelastin.

Published

2017

203. The herpes viral transcription factor ICP4 forms a novel DNA recognition complex.

Author

Tunnicliffe RB, Lockhart-Cairns MP, Levy C, Mould AP, Jowitt TA, Sito H, Baldock C, Sandri-Goldin RM, and Golovanov AP

Subjects

Amino Acid Sequence, Binding Sites genetics, Crystallography, X-Ray, DNA chemistry, DNA genetics, DNA metabolism, Herpesvirus 1, Human genetics, Herpesvirus 1, Human pathogenicity, Humans, Immediate-Early Proteins genetics, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins genetics, Intrinsically Disordered Proteins metabolism, Models, Biological, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Domains, Protein Folding, Protein Multimerization, Scattering, Small Angle, Surface Plasmon Resonance, X-Ray Diffraction, Herpesvirus 1, Human metabolism, Immediate-Early Proteins chemistry, Immediate-Early Proteins metabolism

Abstract

The transcription factor ICP4 from herpes simplex virus has a central role in regulating the gene expression cascade which controls viral infection. Here we present the crystal structure of the functionally essential ICP4 DNA binding domain in complex with a segment from its own promoter, revealing a novel homo-dimeric fold. We also studied the complex in solution by small angle X-Ray scattering, nuclear magnetic resonance and surface-plasmon resonance which indicated that, in addition to the globular domain, a flanking intrinsically disordered region also recognizes DNA. Together the data provides a rationale for the bi-partite nature of the ICP4 DNA recognition consensus sequence as the globular and disordered regions bind synergistically to adjacent DNA motifs. Therefore in common with its eukaryotic host, the viral transcription factor ICP4 utilizes disordered regions to enhance the affinity and tune the specificity of DNA interactions in tandem with a globular domain., (© The Author(s) 2017. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2017

204. Defining the hierarchical organisation of collagen VI microfibrils at nanometre to micrometre length scales.

Author

Godwin ARF, Starborg T, Sherratt MJ, Roseman AM, and Baldock C

Subjects

Computer Simulation, Extracellular Matrix Proteins chemistry, Extracellular Matrix Proteins ultrastructure, Protein Conformation, Collagen Type IV chemistry, Collagen Type IV ultrastructure, Microfibrils chemistry, Microfibrils ultrastructure, Models, Chemical, Models, Molecular

Abstract

Extracellular matrix microfibrils are critical components of connective tissues with a wide range of mechanical and cellular signalling functions. Collagen VI is a heteromeric network-forming collagen which is expressed in tissues such as skin, lung, blood vessels and articular cartilage where it anchors cells into the matrix allowing for transduction of biochemical and mechanical signals. It is not understood how collagen VI is arranged into microfibrils or how these microfibrils are arranged into tissues. Therefore we have characterised the hierarchical organisation of collagen VI across multiple length scales. The frozen hydrated nanostructure of purified collagen VI microfibrils was reconstructed using cryo-TEM. The bead region has a compact hollow head and flexible tail regions linked by the collagenous interbead region. Serial block face SEM imaging coupled with electron tomography of the pericellular matrix (PCM) of murine articular cartilage revealed that the PCM has a meshwork-like organisation formed from globular densities ∼30nm in diameter. These approaches can characterise structures spanning nanometer to millimeter length scales to define the nanostructure of individual collagen VI microfibrils and the micro-structural organisation of these fibrils within tissues to help in the future design of better mimetics for tissue engineering., Statement of Significance: Cartilage is a connective tissue rich in extracellular matrix molecules and is tough and compressive to cushion the bones of joints. However, in adults cartilage is poorly repaired after injury and so this is an important target for tissue engineering. Many connective tissues contain collagen VI, which forms microfibrils and networks but we understand very little about these assemblies or the tissue structures they form. Therefore, we have use complementary imaging techniques to image collagen VI microfibrils from the nano-scale to the micro-scale in order to understand the structure and the assemblies it forms. These findings will help to inform the future design of scaffolds to mimic connective tissues in regenerative medicine applications., (Copyright © 2016 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2017

205. Structural analysis of X-linked retinoschisis mutations reveals distinct classes which differentially effect retinoschisin function.

Author

Ramsay EP, Collins RF, Owens TW, Siebert CA, Jones RPO, Wang T, Roseman AM, and Baldock C

Subjects

Animals, COS Cells, Chlorocebus aethiops, Cryoelectron Microscopy, Eye Proteins ultrastructure, Humans, Mutation genetics, Protein Conformation, Protein Multimerization, Retina chemistry, Retina pathology, Retinoschisis pathology, Eye Proteins chemistry, Eye Proteins genetics, Retinoschisis genetics, Structure-Activity Relationship

Abstract

Retinoschisin, an octameric retinal-specific protein, is essential for retinal architecture with mutations causing X-linked retinoschisis (XLRS), a monogenic form of macular degeneration. Most XLRS-associated mutations cause intracellular retention, however a subset are secreted as octamers and the cause of their pathology is ill-defined. Therefore, here we investigated the solution structure of the retinoschisin monomer and the impact of two XLRS-causing mutants using a combinatorial approach of biophysics and cryo-EM. The retinoschisin monomer has an elongated structure which persists in the octameric assembly. Retinoschisin forms a dimer of octamers with each octameric ring adopting a planar propeller structure. Comparison of the octamer with the hexadecamer structure indicated little conformational change in the retinoschisin octamer upon dimerization, suggesting that the octamer provides a stable interface for the construction of the hexadecamer. The H207Q XLRS-associated mutation was found in the interface between octamers and destabilized both monomeric and octameric retinoschisin. Octamer dimerization is consistent with the adhesive function of retinoschisin supporting interactions between retinal cell layers, so disassembly would prevent structural coupling between opposing membranes. In contrast, cryo-EM structural analysis of the R141H mutation at ∼4.2Å resolution was found to only cause a subtle conformational change in the propeller tips, potentially perturbing an interaction site. Together, these findings support distinct mechanisms of pathology for two classes of XLRS-associated mutations in the retinoschisin assembly., (© The Author 2016. Published by Oxford University Press.)

Published

2016

206. Cadherin flexibility provides a key difference between desmosomes and adherens junctions.

Author

Tariq H, Bella J, Jowitt TA, Holmes DF, Rouhi M, Nie Z, Baldock C, Garrod D, and Tabernero L

Subjects

Adherens Junctions genetics, Adherens Junctions metabolism, Animals, CHO Cells, Cricetinae, Cricetulus, Crystallography, X-Ray, Desmoglein 2 genetics, Desmoglein 2 metabolism, Desmosomes genetics, Desmosomes metabolism, Humans, Protein Structure, Tertiary, Adherens Junctions chemistry, Desmoglein 2 chemistry, Desmosomes chemistry

Abstract

Desmosomes and adherens junctions are intercellular adhesive structures essential for the development and integrity of vertebrate tissue, including the epidermis and heart. Their cell adhesion molecules are cadherins: type 1 cadherins in adherens junctions and desmosomal cadherins in desmosomes. A fundamental difference is that desmosomes have a highly ordered structure in their extracellular region and exhibit calcium-independent hyperadhesion, whereas adherens junctions appear to lack such ordered arrays, and their adhesion is always calcium-dependent. We present here the structure of the entire ectodomain of desmosomal cadherin desmoglein 2 (Dsg2), using a combination of small-angle X-ray scattering, electron microscopy, and solution-based biophysical techniques. This structure reveals that the ectodomain of Dsg2 is flexible even in the calcium-bound state and, on average, is shorter than the type 1 cadherin crystal structures. The Dsg2 structure has an excellent fit with the electron tomography reconstructions of human desmosomes. This fit suggests an arrangement in which desmosomal cadherins form trans interactions but are too far apart to interact in cis, in agreement with previously reported observations. Cadherin flexibility may be key to explaining the plasticity of desmosomes that maintain tissue integrity in their hyperadhesive form, but can adopt a weaker, calcium-dependent adhesion during wound healing and early development.

Published

2015

207. Nanoscale structure of the BMP antagonist chordin supports cooperative BMP binding.

Author

Troilo H, Zuk AV, Tunnicliffe RB, Wohl AP, Berry R, Collins RF, Jowitt TA, Sengle G, and Baldock C

Subjects

Animals, Bone Morphogenetic Proteins chemistry, Glycoproteins ultrastructure, HEK293 Cells, Humans, Hydrodynamics, Imaging, Three-Dimensional, Mice, Models, Molecular, Mutant Proteins chemistry, Nanoparticles ultrastructure, Protein Binding, Protein Structure, Tertiary, Scattering, Small Angle, Solutions, Surface Plasmon Resonance, X-Ray Diffraction, Bone Morphogenetic Proteins antagonists & inhibitors, Glycoproteins chemistry, Intercellular Signaling Peptides and Proteins chemistry, Nanoparticles chemistry

Abstract

Bone morphogenetic proteins (BMPs) orchestrate key cellular events, such as proliferation and differentiation, in development and homeostasis. Extracellular antagonists, such as chordin, are essential regulators of BMP signaling. Chordin binds to BMPs blocking interaction with receptors, and cleavage by tolloid proteinases is thought to relieve this inhibition. A model has been previously proposed where chordin adopts a horseshoe-like arrangement enabling BMP binding cooperatively by terminal domains (1). Here, we present the nanoscale structure of human chordin using electron microscopy, small angle X-ray scattering, and solution-based biophysical techniques, which together show that chordin indeed has a compact horseshoe-shaped structure. Chordin variants were used to map domain locations within the chordin molecule. The terminal BMP-binding domains protrude as prongs from the main body of the chordin structure, where they are well positioned to interact with the growth factor. The spacing provided by the chordin domains supports the principle of a cooperative BMP-binding arrangement that the original model implied in which growth factors bind to both an N- and C-terminal von Willebrand factor C domain of chordin. Using binding and bioactivity assays, we compared full-length chordin with two truncated chordin variants, such as those produced by partial tolloid cleavage. Cleavage of either terminal domain has little effect on the affinity of chordin for BMP-4 and BMP-7 but C-terminal cleavage increases the efficacy of chordin as a BMP-4 inhibitor. Together these data suggest that partial tolloid cleavage is insufficient to ablate BMP inhibition and the C-terminal chordin domains play an important role in BMP regulation.

Published

2014

208. Shape of tropoelastin, the highly extensible protein that controls human tissue elasticity.

Author

Baldock C, Oberhauser AF, Ma L, Lammie D, Siegler V, Mithieux SM, Tu Y, Chow JY, Suleman F, Malfois M, Rogers S, Guo L, Irving TC, Wess TJ, and Weiss AS

Subjects

Animals, Entropy, Humans, Models, Molecular, Neutron Diffraction, Protein Conformation, Scattering, Small Angle, Solutions, Vertebrates metabolism, X-Ray Diffraction, Elasticity, Organ Specificity, Tropoelastin chemistry

Abstract

Elastin enables the reversible deformation of elastic tissues and can withstand decades of repetitive forces. Tropoelastin is the soluble precursor to elastin, the main elastic protein found in mammals. Little is known of the shape and mechanism of assembly of tropoelastin as its unique composition and propensity to self-associate has hampered structural studies. In this study, we solve the nanostructure of full-length and corresponding overlapping fragments of tropoelastin using small angle X-ray and neutron scattering, allowing us to identify discrete regions of the molecule. Tropoelastin is an asymmetric coil, with a protruding foot that encompasses the C-terminal cell interaction motif. We show that individual tropoelastin molecules are highly extensible yet elastic without hysteresis to perform as highly efficient molecular nanosprings. Our findings shed light on how biology uses this single protein to build durable elastic structures that allow for cell attachment to an appended foot. We present a unique model for head-to-tail assembly which allows for the propagation of the molecule's asymmetric coil through a stacked spring design.

Published

2011

209. Collagen VI microfibril formation is abolished by an {alpha}2(VI) von Willebrand factor type A domain mutation in a patient with Ullrich congenital muscular dystrophy.

Author

Tooley LD, Zamurs LK, Beecher N, Baker NL, Peat RA, Adams NE, Bateman JF, North KN, Baldock C, and Lamandé SR

Subjects

Cell Line, Collagen Type VI genetics, Exons genetics, Extracellular Matrix genetics, Extracellular Matrix metabolism, Humans, Muscular Dystrophies genetics, Protein Structure, Quaternary, Protein Structure, Tertiary, RNA, Messenger genetics, RNA, Messenger metabolism, von Willebrand Factor genetics, Collagen Type VI metabolism, Muscular Dystrophies metabolism, Mutation, Protein Folding, Protein Multimerization, von Willebrand Factor metabolism

Abstract

Collagen VI is an extracellular protein that most often contains the three genetically distinct polypeptide chains, α1(VI), α2(VI), and α3(VI), although three recently identified chains, α4(VI), α5(VI), and α6(VI), may replace α3(VI) in some situations. Each chain has a triple helix flanked by N- and C-terminal globular domains that share homology with the von Willebrand factor type A (VWA) domains. During biosynthesis, the three chains come together to form triple helical monomers, which then assemble into dimers and tetramers. Tetramers are secreted from the cell and align end-to-end to form microfibrils. The precise molecular mechanisms responsible for assembly are unclear. Mutations in the three collagen VI genes can disrupt collagen VI biosynthesis and matrix organization and are the cause of the inherited disorders Bethlem myopathy and Ullrich congenital muscular dystrophy. We have identified a Ullrich congenital muscular dystrophy patient with compound heterozygous mutations in α2(VI). The first mutation causes skipping of exon 24, and the mRNA is degraded by nonsense-mediated decay. The second mutation is a two-amino acid deletion in the C1 VWA domain. Recombinant C1 domains containing the deletion are insoluble and retained intracellularly, indicating that the mutation has detrimental effects on domain folding and structure. Despite this, mutant α2(VI) chains retain the ability to associate into monomers, dimers, and tetramers. However, we show that secreted mutant tetramers containing structurally abnormal C1 VWA domains are unable to associate further into microfibrils, directly demonstrating the critical importance of a correctly folded α2(VI) C1 domain in microfibril formation.

Published

2010

210. Role of dimerization and substrate exclusion in the regulation of bone morphogenetic protein-1 and mammalian tolloid.

Author

Berry R, Jowitt TA, Ferrand J, Roessle M, Grossmann JG, Canty-Laird EG, Kammerer RA, Kadler KE, and Baldock C

Subjects

Animals, Calcium metabolism, Cell Line, Computer Simulation, Humans, Microscopy, Electron, Transmission, Models, Molecular, Protein Structure, Quaternary, Protein Structure, Tertiary, Structural Homology, Protein, Substrate Specificity, Tolloid-Like Metalloproteinases genetics, Tolloid-Like Metalloproteinases ultrastructure, Protein Multimerization, Tolloid-Like Metalloproteinases chemistry, Tolloid-Like Metalloproteinases metabolism

Abstract

The bone morphogenetic protein (BMP)-1/tolloid metalloproteinases are evolutionarily conserved enzymes that are fundamental to dorsal-ventral patterning and tissue morphogenesis. The lack of knowledge regarding how these proteinases recognize and cleave their substrates represents a major hurdle to understanding tissue assembly and embryonic patterning. Although BMP-1 and mammalian tolloid (mTLD) are splice variants, it is puzzling why BMP-1, which lacks 3 of the 7 noncatalytic domains present in all other family members, is the most effective proteinase. Using a combination of single-particle electron microscopy, small-angle X-ray scattering, and other biophysical measurements in solution, we show that mTLD, but not BMP-1, forms a calcium-ion-dependent dimer under physiological conditions. Using a domain deletion approach, we provide evidence that EGF2, which is absent in BMP-1, is critical to the formation of the dimer. Based on a combination of structural and functional data, we propose that mTLD activity is regulated by a substrate exclusion mechanism. These results provide a mechanistic insight into how alternative splicing of the Bmp1 gene produces 2 proteinases with differing biological activities and have broad implications for regulation of BMP-1/mTLD and related proteinases during BMP signaling and tissue assembly.

Published

2009

211. Missense mutations that cause Van der Woude syndrome and popliteal pterygium syndrome affect the DNA-binding and transcriptional activation functions of IRF6.

Author

Little HJ, Rorick NK, Su LI, Baldock C, Malhotra S, Jowitt T, Gakhar L, Subramanian R, Schutte BC, Dixon MJ, and Shore P

Subjects

Amino Acid Sequence, Animals, COS Cells, Chlorocebus aethiops, Cleft Lip metabolism, Cleft Palate metabolism, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, Humans, Interferon Regulatory Factors chemistry, Interferon Regulatory Factors genetics, Mice, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Structure, Tertiary, Cleft Lip genetics, Cleft Palate genetics, DNA-Binding Proteins metabolism, Interferon Regulatory Factors metabolism, Mutation, Missense, Transcriptional Activation

Abstract

Cleft lip and cleft palate (CLP) are common disorders that occur either as part of a syndrome, where structures other than the lip and palate are affected, or in the absence of other anomalies. Van der Woude syndrome (VWS) and popliteal pterygium syndrome (PPS) are autosomal dominant disorders characterized by combinations of cleft lip, CLP, lip pits, skin-folds, syndactyly and oral adhesions which arise as the result of mutations in interferon regulatory factor 6 (IRF6). IRF6 belongs to a family of transcription factors that share a highly conserved N-terminal, DNA-binding domain and a less well-conserved protein-binding domain. To date, mutation analyses have suggested a broad genotype-phenotype correlation in which missense and nonsense mutations occurring throughout IRF6 may cause VWS; in contrast, PPS-causing mutations are highly associated with the DNA-binding domain, and appear to preferentially affect residues that are predicted to interact directly with the DNA. Nevertheless, this genotype-phenotype correlation is based on the analysis of structural models rather than on the investigation of the DNA-binding properties of IRF6. Moreover, the effects of mutations in the protein interaction domain have not been analysed. In the current investigation, we have determined the sequence to which IRF6 binds and used this sequence to analyse the effect of VWS- and PPS-associated mutations in the DNA-binding domain of IRF6. In addition, we have demonstrated that IRF6 functions as a co-operative transcriptional activator and that mutations in the protein interaction domain of IRF6 disrupt this activity.

Published

2009

212. Nanostructure of fibrillin-1 reveals compact conformation of EGF arrays and mechanism for extensibility.

Author

Baldock C, Siegler V, Bax DV, Cain SA, Mellody KT, Marson A, Haston JL, Berry R, Wang MC, Grossmann JG, Roessle M, Kielty CM, and Wess TJ

Subjects

Epidermal Growth Factor chemistry, Extracellular Matrix metabolism, Fibrillin-1, Fibrillins, Heparitin Sulfate chemistry, Humans, Image Processing, Computer-Assisted, Kinetics, Microscopy, Electron, Models, Chemical, Models, Molecular, Molecular Conformation, Protein Structure, Tertiary, Microfilament Proteins chemistry, Nanostructures

Abstract

Fibrillin-1 is a 330-kDa multidomain extracellular matrix protein that polymerizes to form 57-nm periodic microfibrils, which are essential for all tissue elasticity. Fibrillin-1 is a member of the calcium-binding EGF repeat family and has served as a prototype for structural analyses. Nevertheless, both the detailed structure of fibrillin-1 and its organization within microfibrils are poorly understood because of the complexity of the molecule and the resistance of EGF arrays to crystallization. Here, we have used small-angle x-ray scattering and light scattering to analyze the solution structure of human fibrillin-1 and to produce ab initio structures of overlapping fragments covering 90% of the molecule. Rather than exhibiting a uniform rod shape as current models predict, the scattering data revealed a nonlinear conformation of calcium-binding EGF arrays in solution. This finding has major implications for the structures of the many other EGF-containing extracellular matrix and membrane proteins. The scattering data also highlighted a very compact, globular region of the fibrillin-1 molecule, which contains the integrin and heparan sulfate-binding sites. This finding was confirmed by calculating a 3D reconstruction of this region using electron microscopy and single-particle image analysis. Together, these data have enabled the generation of an improved model for microfibril organization and a previously undescribed mechanism for microfibril extensibility.

Published

2006

213. Homotypic fibrillin-1 interactions in microfibril assembly.

Author

Marson A, Rock MJ, Cain SA, Freeman LJ, Morgan A, Mellody K, Shuttleworth CA, Baldock C, and Kielty CM

Subjects

Amino Acid Motifs, Binding Sites, Calcium metabolism, Contractile Proteins chemistry, Dose-Response Relationship, Drug, Ethylmaleimide chemistry, Extracellular Matrix Proteins chemistry, Fibrillin-1, Fibrillins, Furin chemistry, Humans, Kinetics, Ligands, Linear Models, Microfilament Proteins metabolism, Protein Binding, Protein Structure, Tertiary, RNA Splicing Factors, Recombinant Proteins chemistry, Microfibrils metabolism, Microfilament Proteins chemistry

Abstract

We have defined the homotypic interactions of fibrillin-1 to obtain new insights into microfibril assembly. Dose-dependent saturable high affinity binding was demonstrated between N-terminal fragments, between furin processed C-terminal fragments, and between these N- and C-terminal fragments. The N terminus also interacted with a downstream fragment. A post-furin cleavage site C-terminal sequence also interacted with the N terminus, with itself and with the furin-processed fragment. No other homotypic fibrillin-1 interactions were detected. Some terminal homotypic interactions were inhibited by other terminal sequences, and were strongly calcium-dependent. Treatment of an N-terminal fragment with N-ethylmaleimide reduced homotypic binding. Microfibril-associated glycoprotein-1 inhibited N- to C-terminal interactions but not homotypic N-terminal interactions. These fibrillin-1 interactions are likely to regulate pericellular fibrillin-1 microfibril assembly.

Published

2005

214. Fibrillin microfibrils.

Author

Kielty CM, Sherratt MJ, Marson A, and Baldock C

Subjects

Aging physiology, Animals, Elasticity, Fibrillin-1, Fibrillins, Genetic Diseases, Inborn genetics, Genetic Diseases, Inborn metabolism, Humans, Microfibrils genetics, Microfibrils physiology, Microfilament Proteins biosynthesis, Microfilament Proteins genetics, Microfilament Proteins physiology, Microfibrils chemistry, Microfilament Proteins chemistry

Abstract

Fibrillin microfibrils are widely distributed extracellular matrix assemblies that endow elastic and nonelastic connective tissues with long-range elasticity. They direct tropoelastin deposition during elastic fibrillogenesis and form an outer mantle for mature elastic fibers. Microfibril arrays are also abundant in dynamic tissues that do not express elastin, such as the ciliary zonules of the eye. Mutations in fibrillin-1-the principal structural component of microfibrils-cause Marfan syndrome, a heritable disease with severe aortic, ocular, and skeletal defects. Isolated fibrillin-rich microfibrils have a complex 56 nm "beads-on-a-string" appearance; the molecular basis of their assembly and elastic properties, and their role in higher-order elastic fiber formation, remain incompletely understood.

Published

2005

215. Fibrillin: from microfibril assembly to biomechanical function.

Author

Kielty CM, Baldock C, Lee D, Rock MJ, Ashworth JL, and Shuttleworth CA

Subjects

Animals, Elasticity, Fibrillins, Humans, Marfan Syndrome genetics, Microfibrils ultrastructure, Microfilament Proteins genetics, Microfilament Proteins ultrastructure, Models, Molecular, Protein Structure, Quaternary, Biomechanical Phenomena, Microfibrils chemistry, Microfibrils metabolism, Microfilament Proteins chemistry, Microfilament Proteins metabolism

Abstract

Fibrillins form the structural framework of a unique and essential class of extracellular microfibrils that endow dynamic connective tissues with long-range elasticity. Their biological importance is emphasized by the linkage of fibrillin mutations to Marfan syndrome and related connective tissue disorders, which are associated with severe cardiovascular, ocular and skeletal defects. These microfibrils have a complex ultrastructure and it has proved a major challenge both to define their structural organization and to relate it to their biological function. However, new approaches have at last begun to reveal important insights into their molecular assembly, structural organization and biomechanical properties. This paper describes the current understanding of the molecular assembly of fibrillin molecules, the alignment of fibrillin molecules within microfibrils and the unique elastomeric properties of microfibrils.

Published

2002