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1. Collagen Fibril Abnormalities in Human and Mice Abdominal Aortic Aneurysm

   Jones, B.; Tonniges, J. R.; Debsk, A.i; Albert, B.; Yeung, D. A.; Gadde, N.; Mahajan, A.; Sharma, N.; Calomeni, E. P.; Go, M.; et al (August 2020, Biomedical Engineering Society 2020 Annual Meeting)

   null (Ed.)

   Introduction: Vascular diseases like abdominal aortic aneurysms (AAA) are characterized by a drastic remodeling of the vessel wall, accompanied with changes in the elastin and collagen content. At the macromolecular level, the elastin fibers in AAA have been reported to undergo significant structural alterations. While the undulations (waviness) of the collagen fibers is also reduced in AAA, very little is understood about changes in the collagen fibril at the sub-fiber level in AAA as well as in other vascular pathologies. Materials and Methods: In this study we investigated structural changes in collagen fibrils in human AAA tissue extracted at the time of vascular surgery and in aorta extracted from angiotensin II (AngII) infused ApoE−/− mouse model of AAA. Collagen fibril structure was examined using transmission electron microscopy and atomic force microscopy. Images were analyzed to ascertain length and depth of D-periodicity, fibril diameter and fibril curvature. Tissues were also stained using collagen hybridizing peptide (CHP) and analyzed using fluorescent microscopy and second harmonic generation (SHG) microscopy to locate regions of healthy and degraded collagen. Results: Abnormal collagen fibrils with compromised D-periodic banding were observed in the excised human tissue and in remodeled regions of AAA in AngII infused mice (Figure 1). These abnormal fibrils were characterized by statistically significant reduction in depths of D-periods and an increased curvature of collagen fibrils. These features were more pronounced in human AAA as compared to murine samples. Additionally, regions of abnormal collagen were located within the remodeled areas of AAA tissue and were distinct from healthy collagen regions as ascertained using CHP staining and SHG (Figure 1). Thoracic aorta from Ang II-infused mice, abdominal aorta from saline-infused mice, and abdominal aorta from non-AAA human controls did not contain abnormal collagen fibrils. Conclusions: The structural alterations in abnormal collagen fibrils appear similar to those reported for collagen fibrils subjected to mechanical overload or chronic inflammation in other tissues. Detection of abnormal collagen could be utilized to better understand the functional properties of the underlying extracellular matrix in vascular as well as other pathologies. 

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2. Mediation of Cartilage Matrix Degeneration and Fibrillation by Decorin in Post‐traumatic Osteoarthritis

   https://doi.org/10.1002/art.41254  

   Li, Qing; Han, Biao; Wang, Chao; Tong, Wei; Wei, Yulong; Tseng, Wei‐Ju; Han, Li‐Hsin; Liu, X_Sherry; Enomoto‐Iwamoto, Motomi; Mauck, Robert_L; et al (July 2020, Arthritis & Rheumatology)

   ObjectiveTo elucidate the role of decorin, a small leucine‐rich proteoglycan, in the degradation of cartilage matrix during the progression of post‐traumatic osteoarthritis (OA). MethodsThree‐month–old decorin‐null (Dcn^−/−) and inducible decorin‐knockout (Dcn^iKO) mice were subjected to surgical destabilization of the medial meniscus (DMM) to induce post‐traumaticOA. TheOAphenotype that resulted was evaluated by assessing joint morphology and sulfated glycosaminoglycan (sGAG) staining via histological analysis (n = 6 mice per group), surface collagen fibril nanostructure via scanning electron microscopy (n = 4 mice per group), tissue modulus via atomic force microscopy–nanoindentation (n = 5 or more mice per group) and subchondral bone structure via micro–computed tomography (n = 5 mice per group). Femoral head cartilage explants from wild‐type and Dcn^−/−mice were stimulated with the inflammatory cytokine interleukin‐1β (IL‐1β) in vitro (n = 6 mice per group). The resulting chondrocyte response toIL‐1β and release ofsGAGs were quantified. ResultsIn both Dcn^−/−and Dcn^iKOmice, the absence of decorin resulted in acceleratedsGAGloss and formation of highly aligned collagen fibrils on the cartilage surface relative to the control (P< 0.05). Also, Dcn^−/−mice developed more salient osteophytes, illustrating more severeOA. In cartilage explants treated withIL‐1β, loss of decorin did not alter the expression of either anabolic or catabolic genes. However, a greater proportion ofsGAGs was released to the media from Dcn^−/−mouse explants, in both live and devitalized conditions (P< 0.05). ConclusionIn post‐traumaticOA, decorin delays the loss of fragmented aggrecan and fibrillation of cartilage surface, and thus, plays a protective role in ameliorating cartilage degeneration. 

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3. Discoidin Domain Receptor 1 impacts bone microarchitecture with aging in female mice

   https://doi.org/10.1093/jbmrpl/ziae160  

   Denman, Kimberly; Blissett, Angela; Glisic, Stevan; Weiss, Brent; Zachariadou, Christina; Awad, Hani; Litsky, Alan; Cray, James; Lee, Beth S; Foster, Brian L; et al (January 2025, JBMR Plus)

   Discoidin Domain Receptor 1 (DDR1) is a receptor tyrosine kinase that binds to and is activated by collagen(s), including collagen type I. Ddr1 deletion in osteoblasts and chondrocytes has previously demonstrated the importance of this receptor in bone development. In this study, we examined the effect of DDR1 ablation on bone architecture and mechanics as a function of aging. Femurs were collected from female global Ddr1 knockout (KO) and wild-type (WT) mice at 2, 6, and 12 mo of age and analyzed by high-resolution micro-computed tomography (μCT), mechanical testing, and histology. Primary monocytes were collected for in vitro osteoclastogenesis assays. Our studies on younger (2 mo) mice revealed no significant differences between the two genotypes and the microarchitectural and mechanical features had a similar trend as those reported earlier for osteoblast or chondrocyte specific Ddr1 knockdown. At an advanced age (12 mo), significant differences were noted across the two genotypes. μCT analysis showed a decrease in medullary cavity area as well as increased trabeculation in cortical and trabecular bone in the Ddr1 KO vs. WT mice. In addition, Ddr1 KO mouse bones exhibited reduced mechanical properties (lower peak load, yield load, and energy to yield) at 12 mo. Histological analysis revealed reduced osteoclast count in Ddr1 KO femurs at 12 mo with no significant difference in osteocyte count between the genotypes. In vitro, osteoclastogenesis was impaired in Ddr1 KO bone marrow derived cells. These results suggest that DDR1 deficiency adversely impacts osteoclast differentiation and bone remodeling in an age-dependent manner. 

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4. Self-Assembly of Amyloid Fibrils into 3D Gel Clusters versus 2D Sheets

   https://doi.org/10.3390/biom13020230  

   Karunarathne, Kanchana; Bushra, Nabila; Williams, Olivia; Raza, Imad; Tirado, Laura; Fakhre, Diane; Fakhre, Fadia; Muschol, Martin (February 2023, Biomolecules)

   The deposition of dense fibril plaques represents the pathological hallmark for a multitude of human disorders, including many neurodegenerative diseases. Fibril plaques are predominately composed of amyloid fibrils, characterized by their underlying cross beta-sheet architecture. Research into the mechanisms of amyloid formation has mostly focused on characterizing and modeling the growth of individual fibrils and associated oligomers from their monomeric precursors. Much less is known about the mechanisms causing individual fibrils to assemble into ordered fibrillar suprastructures. Elucidating the mechanisms regulating this “secondary” self-assembly into distinct suprastructures is important for understanding how individual protein fibrils form the prominent macroscopic plaques observed in disease. Whether and how amyloid fibrils assemble into either 2D or 3D supramolecular structures also relates to ongoing efforts on using amyloid fibrils as substrates or scaffolds for self-assembling functional biomaterials. Here, we investigated the conditions under which preformed amyloid fibrils of a lysozyme assemble into larger superstructures as a function of charge screening or pH. Fibrils either assembled into three-dimensional gel clusters or two-dimensional fibril sheets. The latter displayed optical birefringence, diagnostic of amyloid plaques. We presume that pH and salt modulate fibril charge repulsion, which allows anisotropic fibril–fibril attraction to emerge and drive the transition from 3D to 2D fibril self-assembly. 

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5. Assembly of ordered DNA-curli fibril complexes during Salmonella biofilm formation correlates with strengths of the type I interferon and autoimmune responses

   https://doi.org/10.1371/journal.ppat.1010742  

   Nicastro, Lauren K.; de Anda, Jaime; Jain, Neha; Grando, Kaitlyn C.; Miller, Amanda L.; Bessho, Shingo; Gallucci, Stefania; Wong, Gerard C.; Tükel, Çagla (August 2022, PLOS Pathogens)

   Baumler, Andreas J. (Ed.)

   Deposition of human amyloids is associated with complex human diseases such as Alzheimer’s and Parkinson’s. Amyloid proteins are also produced by bacteria. The bacterial amyloid curli, found in the extracellular matrix of both commensal and pathogenic enteric bacterial biofilms, forms complexes with extracellular DNA, and recognition of these complexes by the host immune system may initiate an autoimmune response. Here, we isolated early intermediate, intermediate, and mature curli fibrils that form throughout the biofilm development and investigated the structural and pathogenic properties of each. Early intermediate aggregates were smaller than intermediate and mature curli fibrils, and circular dichroism, tryptophan, and thioflavin T analyses confirmed the establishment of a beta-sheet secondary structure as the curli conformations matured. Intermediate and mature curli fibrils were more immune stimulatory than early intermediate fibrils in vitro . The intermediate curli was cytotoxic to macrophages independent of Toll-like receptor 2. Mature curli fibrils had the highest DNA content and induced the highest levels of Isg15 expression and TNFα production in macrophages. In mice, mature curli fibrils induced the highest levels of anti-double-stranded DNA autoantibodies. The levels of autoantibodies were higher in autoimmune-prone NZBWxF/1 mice than wild-type C57BL/6 mice. Chronic exposure to all curli forms led to significant histopathological changes and synovial proliferation in the joints of autoimmune-prone mice; mature curli was the most detrimental. In conclusion, curli fibrils, generated during biofilm formation, cause pathogenic autoimmune responses that are stronger when curli complexes contain higher levels of DNA and in mice predisposed to autoimmunity. 

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