Activated fibroblasts are key players in the injury response, tumorigenesis, fibrosis, and inflammation. Dichotomous outcomes in response to varied stroma-targeted therapies in cancer emphasize the need to disentangle the roles of heterogeneous fibroblast subsets in physiological and pathophysiological settings. In wound healing, fibrosis, and myriad tumor types, fibroblast activation protein (FAP) and alpha-smooth muscle actin (αSMA) identify distinct, yet overlapping, activated fibroblast subsets. Prior studies established that FAP reactive fibroblasts and αSMA myofibroblasts can exert opposing influences in tumorigenesis. However, the factors that drive this phenotypic heterogeneity and the unique functional roles of these subsets have not been defined. We demonstrate that a convergence of ECM composition, elasticity, and transforming growth factor beta (TGF-β) signaling governs activated fibroblast phenotypic heterogeneity. Furthermore, FAP reactive fibroblasts and αSMA myofibroblasts exhibited distinct gene expression signatures and functionality in vitro, illuminating potentially unique roles of activated fibroblast subsets in tissue remodeling. These insights into activated fibroblast heterogeneity will inform the rational design of stroma-targeted therapies for cancer and fibrosis.
Monoclonal antibodies raised against purified acetylcholine receptor from muscle and electric organ were tested for cross-reaction with surface components on chicken ciliary ganglion neurons. Indirect immunofluorescence indicated that antibodies to a determinant in the "main immunogenic region" of the receptor bind to the neurons in culture. Ultrastructural studies on 16-day embryonic ganglia, using horseradish peroxidase-conjugated monoclonal antibody, revealed that most of the conjugate labeling was associated with synaptic membrane on the neurons. A lesser amount of labeling was associated with the short processes extending from the neuronal somata in the region of preganglionic innervation. The labeling was blocked by coincubation with unlabeled antibodies of appropriate specificity and not by nonimmune serum. The pattern of labeling was clearly different from that previously found for a horseradish peroxidase conjugate of a-bungarotoxin: the toxin conjugate bound extensively to the short processes but not to synaptic membrane on the neurons. The synaptic antigen identified here by the crossreacting antibodies is a candidate for the synaptic acetylcholine receptor on chicken ciliary ganglion neurons.Chicken ciliary ganglion neurons have nicotinic acetylcholine (AcCho) receptors that mediate chemical synaptic transmission through the ganglion (1, 2). Efforts to study the regulation and distribution of such receptors on neurons have been limited by the absence of suitable probes. a-Bungarotoxin has been a very useful probe for studying nicotinic AcCho receptors in vertebrate skeletal muscle and electric organ, where the toxin binds tightly and specifically to the receptor and blocks its function (3). Ciliary ganglion neurons also have high-affinity binding sites for a-bungarotoxin, but in this case the binding sites appear to be distinct from synaptic AcCho receptors. Ultrastructural studies demonstrate that toxin binding sites on the neurons are located in the immediate vicinity of presynaptic terminals but are not present in the postsynaptic membrane (4), as would be expected for synaptic receptors. Moreover, a-bungarotoxin does not block AcCho receptor function on the neurons (5, 6), and, when the levels of AcCho sensitivity and toxin binding are compared for the neurons grown under various conditions in cell culture, no simple correlation is found between the two properties (7), as would be expected if they represented the same membrane component.An alternative approach is to use antibodies against the AcCho receptor as probes. Monoclonal antibodies (mAbs) against AcCho receptors from skeletal muscle and electric organ have been useful in studying the structure and synthesis of these receptors (8)(9)(10)(11)(12). Recent studies have shown that mAbs specific for each of the four subunits of AcCho receptors from muscle and electric organ bind to neurons in the lateral spiriform nucleus of chicken brain (13). These neurons do not bind a-bungarotoxin. Best cross-reaction was obtained with mAbs to the "...
ResultsUsing PCR, we constructed chimeric subunits in which the α7 cytoplasmic loop immediately after TM3 and before TM4 was replaced with the homologous region of the α3 or α5 sequence (Fig. 1a). The N-terminus up to TM2 regulates intersubunit assembly into receptor complexes, and α7 subunits do not coassemble with nAChR subunits, as demonstrated for endogenous subunits in CG neurons and for chimeric α7 subunits expressed in Xenopus laevis oocytes 4,5,12,13 . In particular, we have observed that coexpression of chimeric α7 subunits containing the α3 cytoplasmic loop together with wild-type α3 and β4 subunits in Xenopus oocytes results in the formation of two distinct receptor types that have the pharmacological properties of Bgt-nAChRs and nAChRs, respectively (data not shown). Thus, a difference in the distribution of chimeric α7 as compared to wild-type α7 on the infected CG neuron surface would result from the added α3 or α5 cytoplasmic loop. It cannot be explained by assembly with an endogenous nAChR subunit that can target to the synapse. Different types of neurotransmitter receptors coexist within single neurons and must be targeted to discrete synaptic regions for proper function. In chick ciliary ganglion neurons, nicotinic acetylcholine receptors (nAChRs) containing α3 and α5 subunits are concentrated in the postsynaptic membrane, whereas α-bungarotoxin receptors composed of α7 subunits are localized perisynaptically and excluded from the synapse. Using retroviral vector-mediated gene transfer in vivo, we show that the long cytoplasmic loop of α3 targets chimeric α7 subunits to the synapse and reduces endogenous nAChR surface levels, whereas the α5 loop does neither. These results show that a particular domain of one subunit targets specific receptor subtypes to the interneuronal synapse in vivo. Moreover, our findings suggest a difference in the mechanisms that govern assembly of interneuronal synapses as compared to the neuromuscular junction in vertebrates.1998 Nature America Inc.• http://neurosci.nature.com 1998 Nature America Inc.• http://neurosci.nature.com
Tissue remodeling is critical during development and wound healing. It also characterizes a number of pathologic conditions, including chronic inflammation, fibrosis and cancer. It is well appreciated that reactive stromal cells play critical roles in these settings. However, understanding of the mechanisms involved in the differentiation of reactive stromal cells and their biologic activities has been hampered by the fact that they are generated from diverse progenitors, and by their phenotypic and function heterogeneity. Furthermore, molecular markers that are expressed by all reactive stromal cells and that distinguish them from all other cell types have been lacking. Fibroblast activation protein (FAP) is a serine protease that was originally discovered as a cell surface protein expressed on astrocytomas and sarcomas. Over the last two decades, FAP has attracted increasing attention as a selective marker of carcinoma-associated fibroblasts (CAFs) and more broadly, of activated fibroblasts in tissues undergoing remodeling of their extracellular matrix (ECM) due to chronic inflammation, fibrosis or wound healing. Herein we review the evidence that FAP is indeed a robust and selective marker for reactive mesenchymal stromal cells associated with pathophysiologic tissue remodeling. We also review recent insights obtained using FAP as a tool to define the relationship between subpopulations of reactive stromal cells in various settings of tissue remodeling. Furthermore, we review recent genetic and pharmacologic data indicating that FAP and FAP-expressing cells play important roles in such conditions. Finally, we discuss the potential risks and therapeutic benefits of targeting FAP and FAP-expressing cells, as well as approaches to do so.
Abstract. Chick ciliary ganglion neurons have a membrane component that shares an antigenic determinant with the main immunogenic region (MIR) of nicotinic acetylcholine receptors from skeletal muscle and electric organ. Previous studies have shown that the component has many of the properties expected for a ganglionic nicotinic acetylcholine receptor, and that its distribution on the neuron surface in vivo is restricted predominantly to synaptic membrane. Here we report the presence of a large intracellular pool of the putative receptor in embryonic neurons and demonstrate that it is associated with organelles known to comprise the biosynthetic and regulatory pathways of integral plasma membrane proteins. Embryonic chick ciliary ganglia were lightly fixed, saponinpermeabilized, incubated with an anti-MIR monoclonal antibody (mAb) followed by horseradish peroxidase-conjugated secondary antibody, reacted for peroxidase activity, and examined by electron microscopy. Deposits of reaction product were associated with synaptic membrane, small portions of the pseudodendrite surface membrane, most of the rough endoplasmic reticulum, small portions of the nuclear envelope, some Golgi complexes, and a few coated pits, coated vesicles, multivesicular bodies, and smooth-membraned vacuoles. No other labeling was present in the neurons. The labeling was specific in that it was not present when the anti-MIR mAb was replaced with either nonimmune serum or mAbs of different specificity. Chick dorsal root ganglion neurons thought to lack nicotinic acetylcholine receptors were not labeled by the anti-MIR mAb. Substantial intracellular populations have also been reported for the muscle acetylcholine receptor and brain voltagedependent sodium channel ct-subunit. This may represent a general pattern for multisubunit membrane proteins during development.ITTLE is known about the distribution and regulation of nicotinic acetylcholine receptors (AChRs) 1 on neurons because methods have not been available for unambiguously identifying the receptor protein. Chick ciliary ganglion neurons have nicotinic AChRs that mediate chemical synaptic transmission through the ganglion (Martin and Pilar, 1963a, b). Recently monoclonal antibodies (mAbs) to the main immunogenic region (MIR) of AChR ¢t-subunit from muscle and electric organ have been used to identify a membrane component on chick ciliary ganglion neurons that has many of the properties expected for a neuronal nicotinic AChR. On the neuron surface, the cross-reacting component is located predominantly in synaptic membrane (Jacob et al., 1984). It is an integral membrane component that in detergent extracts has a sedimentation coefficient similar to AChR from muscle and electric organ; it binds to concanavalin A, a lectin known to block AChR function on 1. Abbreviations used in this paper: AChR, acetylcholine receptor; HRP, horseradish peroxidase; mAb, monoclonal antibody; MIR, main immunogenic region; PBS-glycine, phosphate-buffered saline containing 0.75 % glycine; PG, phosphate-buffered...
CD44 contributes to inflammation and fibrosis in response to injury. As fibroblast recruitment is critical to wound healing, we compared cytoskeletal architecture and migration of wild-type (CD44WT) and CD44-deficient (CD44KO) fibroblasts. CD44KO fibroblasts exhibited fewer stress fibers and focal adhesion complexes, and their migration was characterized by increased velocity but loss of directionality, compared with CD44WT fibroblasts. Mechanistically, we demonstrate that CD44WT cells generated more active TGFβ than CD44KO cells and that CD44 promotes the activation of TGFβ via an MMP-dependent mechanism. Reconstitution of CD44 expression completely rescued the phenotype of CD44KO cells whereas exposure of CD44KO cells to exogenous active TGFβ rescued the defect in stress fibers and migrational velocity, but was not sufficient to restore directionality of migration. These results resolve the TGFβ-mediated and TGFβ-independent effects of CD44 on fibroblast migration and suggest that CD44 may be critical for the recruitment of fibroblasts to sites of injury and the function of fibroblasts in tissue remodeling and fibrosis.
Normal cognitive and autonomic functions require nicotinic synaptic signaling. Despite the physiological importance of these synapses, little is known about molecular mechanisms that direct their assembly during development. We show here that the tumor-suppressor protein adenomatous polyposis coli (APC) functions in localizing ␣3-nicotinic acetylcholine receptors (nAChRs) to neuronal postsynaptic sites. Our quantitative confocal microscopy studies indicate that APC is selectively enriched at cholinergic synapses; APC surface clusters are juxtaposed to synaptic vesicle clusters and colocalize with ␣3-nAChRs but not with the neighboring synaptic glycine receptors or perisynaptic ␣7-nAChRs on chick ciliary ganglion (CG) neurons. We identify PSD (postsynaptic density)-93, -catenin, and microtubule end binding protein EB1 as APC binding partners. PSD-93 and -catenin are also enriched at ␣3-nAChR postsynaptic sites. EB1 shows close proximity to and partial overlap with ␣3-nAChR and APC surface clusters. We tested the role of APC in neuronal nicotinic synapse assembly by using retroviral-mediated in vivo overexpression of an APC dominant-negative (APC-dn) peptide to block the interaction of endogenous APC with both EB1 and PSD-93 during synapse formation in CG neurons. The overexpressed APC-dn led to dramatic decreases in ␣3-nAChR surface levels and clusters. Effects were specific to ␣3-nAChR postsynaptic sites; synaptic glycine receptor and perisynaptic ␣7-nAChR clusters were not altered. In addition, APC-dn also reduced surface membrane-associated clusters of PSD-93 and EB1. The results show that APC plays a key role in organizing excitatory cholinergic postsynaptic specializations in CG neurons. We identify APC as the first nonreceptor protein to function in localizing nAChRs to neuronal synapses in vivo.
Neurons engage in two distinct types of cell-cell interactions: they receive innervation and establish synapses on target tissues. Regulatory events that influence synapse formation and function on developing neurons are largely undefined. We show here that nicotinic acetylcholine receptor (AChR) subunit transcript levels are differentially regulated by innervation and target tissue interactions in developing chick ciliary ganglion neurons in situ. Using ganglia that have developed in the absence of pre- or postganglionic tissues and quantitative RT-PCR, we demonstrate that alpha 3 and beta 4 transcript levels are increased by innervation and target tissue interactions. In contrast, alpha 5 transcript levels are increased by innervation, but target tissues have little effect. Whole-cell ACh-induced currents, used to estimate the number of functional AChRs, change in correlation with alpha 3 and beta 4, but not alpha 5, transcript levels. A model is proposed in which the changes in AChR subunit expression regulate levels of synaptic activity, which is a critical determinant of synapse stabilization and elimination, and neuronal cell death.
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