Subunit Structure of Human Fibrinogen, Soluble Fibrin, and Cross-Linked Insoluble Fibrin

The three unique polypeptide chains of human fibrinogen differ significantly in molecular weight. Cross-linkage of fibrin by fibrin-stabilizing factor results in the rapid formation of cross-links between gamma-chains and a slower formation of cross-links between alpha-chains. beta-Chains are not involved directly in the cross-linking of fibrin. Reduced, cross-linked fibrin contains uncross-linked beta-chains, dimers of gamma-chain, and higher polymers of alpha-chain. Although it is uncertain whether the gamma-gamma dimers are formed by chains in different molecules of fibrin, the polymers of alpha-chain in fibrin can only be accounted for by cross-linkage of alpha-chains in different molecules. The nature of cross-linkage among the subunits in fibrin can account well for the three-dimensional, covalent structure of cross-linked, insoluble fibrin.     

Increased Osteopontin Contributes to Inhibition of Bone Mineralization in FGF23‐Deficient Mice

Excessive FGF23 has been identified as a pivotal phosphaturic factor leading to renal phosphate‐wasting and the subsequent development of rickets and osteomalacia. In contrast, loss of FGF23 in mice (Fgf23^?/?) leads to high serum phosphate, calcium, and 1,25‐vitamin D levels, resulting in early lethality attributable to severe ectopic soft‐tissue calcifications and organ failure. Paradoxically, Fgf23^?/? mice exhibit a severe defect in skeletal mineralization despite high levels of systemic mineral ions and abundant ectopic mineralization, an abnormality that remains largely unexplained. Through use of in situ hybridization, immunohistochemistry, and immunogold labeling coupled with electron microscopy of bone samples, we discovered that expression and accumulation of osteopontin (Opn/OPN) was markedly increased in Fgf23^?/? mice. These results were confirmed by qPCR analyses of Fgf23^?/? bones and ELISA measurements of serum OPN. To investigate whether elevated OPN levels were contributing to the bone mineralization defect in Fgf23^?/? mice, we generated Fgf23^?/?/Opn^?/? double‐knockout mice (DKO). Biochemical analyses showed that the hypercalcemia and hyperphosphatemia observed in Fgf23^?/? mice remained unchanged in DKO mice; however, micro‐computed tomography (µCT) and histomorphometric analyses showed a significant improvement in total mineralized bone volume. The severe osteoidosis was markedly reduced and a normal mineral apposition rate was present in DKO mice, indicating that increased OPN levels in Fgf23^?/? mice are at least in part responsible for the osteomalacia. Moreover, the increased OPN levels were significantly decreased upon lowering serum phosphate by feeding a low‐phosphate diet or after deletion of NaPi2a, indicating that phosphate levels contribute in part to the high OPN levels in Fgf23^?/? mice. In summary, our results suggest that increased OPN is an important pathogenic factor mediating the mineralization defect and the alterations in bone metabolism observed in Fgf23^?/? bones. © 2014 American Society for Bone and Mineral Research.     

Evolution of neuronal and glial tau isoforms in chronic traumatic encephalopathy

Chronic traumatic encephalopathy (CTE) is a neurodegenerative tauopathy characterized by accumulation of hyperphosphorylated tau (p‐tau) in perivascular aggregates in neurons and glia at the depths of neocortical sulci and progresses to diffuse neocortical, allocortical and brainstem structures. The strongest risk factor is exposure to repetitive head impacts acquired most commonly through contact sports and military service. Given that CTE can only be definitively diagnosed after death, a better understanding of the cellular and molecular changes in CTE brains may lead to identification of mechanisms that could be used for novel biomarkers, monitoring progression or therapeutic development. Disruption of alternative pre‐mRNA splicing of tau mRNA plays a pathogenic role in tauopathy, with multiple characteristic patterns of isoform accumulation varying among tauopathies. Limited data are available on CTE, particularly at early stages. Using biochemical and histological approaches, we performed a detailed characterization of tau isoform signatures in post‐mortem human brain tissue from individuals with a range of CTE stages (n = 99). In immunoblot analyses, severity was associated with decreased total monomeric tau and increased total oligomeric tau. Immunoblot with isoform‐specific antisera revealed that oligomeric tau with three and four microtubule binding domain repeats (3R and 4R) also increased with CTE severity. Similarly, immunohistochemical studies revealed p‐tau accumulation consisting of both 3R and 4R in perivascular lesions. When the ratio of 4R:3R was analyzed, there was mixed expression throughout CTE stages, although 4R predominated in early CTE stages (I‐II), a 3R shift was observed in later stages (III‐IV). While neurons were found to contain both 3R and 4R, astrocytes only contained 4R. These 4R‐positive cells were exclusively neuronal at early stages. Overall, these findings demonstrate that CTE is a mixed 4R/3R tauopathy. Furthermore, histologic analysis reveals a progressive shift in tau isoforms that correlates with CTE stage and extent of neuronal pathology.     

Secretion of osteopontin by macrophages and its accumulation at tissue surfaces during wound healing in mineralized tissues: A potential requirement for macrophage adhesion and phagocytosis

Osteopontin (OPN), a noncollagenous, extracellular matrix sialoprotein found at relatively high levels in both normal and pathological mineralized tissues, is expressed by tissue-specific cells in bone, calcified cartilage, and teeth. On the other hand, a hallmark of OPN expression in pathologically mineralizing tissues, and in other soft tissues experiencing a more generalized type of necrotic injury, is the production of OPN by macrophages at the lesion site. In the present study, we have localized OPN and other noncollagenous proteins by ultrastructural colloidal-gold immunocytochemistry using a rat model in which mineralized tissue defects are surgically created in mandibular bone and teeth. The healing response was examined by immunocytochemistry and transmission electron microscopy at 10 min, 3 days and 7 days post-surgery using antibodies against OPN, bone sialoprotein, osteocalcin, bone acidic glycoprotein-75, fibronectin, and amelogenin. Whereas most of these proteins were characteristically distributed within their respective extracellular matrices as described previously, OPN was additionally observed to accumulate as a lamina limitans at surgically exposed bone and tooth surfaces, as well as at the surface of particulate, mineralized tissue debris. Intracellular labeling of the Golgi apparatus and secretory granules of macrophages at the lesion site demonstrated that OPN production by macrophages was a prominent secretory event of the inflammatory response during wound healing in mineralized tissues. Pseudopodal and lamellipodal cytoplasmic extensions of macrophages were observed in direct contact with the OPN-containing lamina limitans at these surfaces. Particulate, calcified debris internalized by macrophages also displayed a prominent surface “coating” of OPN. In conclusion, our interpretation of the present data is that OPN secreted by macrophages may serve as a macrophage adhesion protein, and where concentrated at the surface of small particulate, mineralized tissue debris, may act as an opsonin, thereby facilitating cell adhesion and phagocytosis by macrophages, a process likely mediated by integrin-binding, signal transduction, and cytoskeletal restructuring. © 1996 Wiley-Liss, Inc.