The basic helix-loop-helix (bHLH) proteins are intimately associated with developmental events such as cell differentiation and lineage commitment. The HLH domain in the bHLH motif is responsible for dimerization, whereas the basic region mediates DNA binding. Based on sequence alignment and domain analysis, differentially expressed in chondrocytes/stimulated with retinoic acid/split and hairy-related proteins (DEC/STRA/SHARPs) represent a new class of bHLH proteins. The present study describes the functional characterization of DEC1. Subtractive experiments and blotting analyses demonstrated that DEC1 was highly expressed in colon carcinomas, but not in the adjacent normal tissues. Several cell cycle blockers markedly induced DEC1 expression. Stable transfectants with a tetracycline-inducible construct demonstrated that DEC1 caused proliferation inhibition, antagonized serum deprivation-induced apoptosis and selectively inhibited the activation of procaspases. These activities were highly correlated with the abundance of tetracycline-induced DEC1. Stable transfectants expressing a mutant DEC1 (lacking the DNA-binding domain) exhibited neither proliferation inhibition nor apoptotic antagonism, which suggests that DNA binding is required for these actions. Enzymic assays and immunoblotting analyses demonstrated that induction of DEC1 by tetracycline significantly decreased the activation of procaspases 3, 7 and 9 but not procaspase 8. The selective suppression on the activation of procaspases 3, 7 and 9 over procaspase 8 suggests that DEC1-mediated anti-apoptosis is achieved by blocking apoptotic pathways initiated via the mitochondria. The results functionally distinguish DEC1 from other bHLH proteins and directly link this factor to oncogenesis.
Recent evidence from this laboratory indicated that reduced expression of caveolin-1 accompanied the diminished expression of tight junction (TJ)-associated proteins occludin and zonula occludens-1 (ZO-1) following stimulation of brain microvascular endothelial cells (BMECs) with the chemokine CCL2 (formerly called MCP-1). Because attenuated caveolin-1 levels have also been correlated with heightened permeability of other endothelia, the objective of this study was to test the hypothesis that reduced caveolin-1 expression is causally linked to the action of CCL2 on BMEC junctional protein expression and barrier integrity. This was achieved using adenovirus to nondestructively deliver caveolin-1 siRNA (Ad-siCav-1) to BMEC monolayers, which model the blood-brain barrier (BBB). Treatment with siRNA reduced the caveolin-1 protein level as well as occludin and ZO-1. Additionally, occludin exhibited dissociation from the cytoskeletal framework. These changes were attended by comparable alterations in adherens junction (AJ)-associated proteins, VE-cadherin and -catenin, increased BMEC paracellular permeability, and facilitated the ability of CCL2 to stimulate monocytic transendo- IntroductionElevated permeability of the normally highly restrictive bloodbrain barrier (BBB) accompanies a variety of central nervous system (CNS) afflictions, including inflammation, infection, ischemia, seizures, and trauma. [1][2][3][4][5][6] Nevertheless, mechanisms regulating BBB permeability in physiological and pathophysiological situations remain poorly defined. Among the many factors affecting BBB permeability, this laboratory recently reported that the beta-chemokine CCL2 (formerly known as monocyte chemoattractant protein-1 [MCP-1]), which is elevated in the CNS during a variety of neuroinflammatory conditions, 7-10 plays an influential role. 11 Specifically, it effects dissociation of tight junction (TJ)-associated proteins occludin and zonula occludens-1 (ZO-1) from the cytoskeletal framework of brain microvascular endothelial cells (BMECs) comprising the BBB as well as diminished expression of these proteins. Given the proposed role(s) of TJs in restricting solute and cellular passage across endothelial and epithelial barriers, 12-14 such action could conceivably lie, in part, at the basis of the altered BBB permeability and accumulation of leukocytes in the CNS observed in certain neuroinflammatory episodes.Aside from the loss of occludin and ZO-1 following BMEC exposure to CCL2, expression of caveolin-1 was also significantly down-regulated. 11 This additional chemokine-associated loss may further contribute to BBB alteration, because caveolin-1 is the major structural protein of caveolae, membrane microdomains critically involved in various aspects of vesicular trafficking and cell signaling. [15][16][17] Of particular significance in this regard, Nusrat et al 18 reported that both occludin and ZO-1 might be organized within TJs by association with caveolin-1 in detergent-insoluble glycolipid rafts, membrane specializations...
Few terms in the biomedical lexicon are as widely recognized as the phrase blood-brain barrier (BBB). Indeed, it immediately conjures up a "barricade" between the blood and the brain, a feature often considered more obstacle than safeguard. In truth, the BBB performs in both capacities, and it is precisely this duality that imparts such a vital role to the BBB in influencing physiological and pathophysiological processes in the CNS. Although the concept is more than a century old, the BBB continues to remain enigmatic in both substance and idea, with seemingly resolved issues once again beckoning for clarification. In this regard, recent technological advancements, such as sequencing of the human genome and development of microarray analysis, have illuminated novel aspects of vascular gene expression and provoked reconsideration of the cellular and biochemical makeup of the BBB. In light of the critical impact of the BBB in the realms of science and medicine, this Mini-Review will revisit the topic of the composition of the BBB, specifically highlighting how recent developments in endothelial biology have prompted a reevaluation of its precise vascular location. We have intentionally avoided discussing generalized features of the BBB, as these have been skillfully described elsewhere as noted.
BackgroundThe mechanism of leukocyte transendothelial migration (TEM) across the highly restrictive blood-brain barrier (BBB) remains enigmatic, with paracellular TEM thought to require leukocytes to somehow navigate the obstructive endothelial tight junctions (TJs). Transient interactions between TJ proteins on the respective leukocyte and endothelial surfaces have been proposed as one mechanism for TEM. Given the expanding role of extracellular vesicles (EVs) in intercellular communication, we investigated whether EVs derived from brain microvascular endothelial cells (BMEC) of the BBB may play a role in transferring a major TJ protein, claudin-5 (CLN-5), to leukocytes as a possible basis for such a mechanism during neuroinflammation.MethodsHigh-resolution 3D confocal imaging was used to highlight CLN-5 immunoreactivity in the central nervous system (CNS) and on leukocytes of mice with the neuroinflammatory condition experimental autoimmune encephalomyelitis (EAE). Both Western blotting of circulating leukocytes from wild-type mice and fluorescence imaging of leukocyte-associated eGFP-CLN-5 in the blood and CNS of endothelial-targeted, Tie-2-eGFP-CLN-5 transgenic mice were used to confirm the presence of CLN-5 protein on these cells. EVs were isolated from TNF-α-stimulated BMEC cultures and blood plasma of Tie-2-eGFP-CLN-5 mice with EAE and evaluated for CLN-5 protein by Western blotting and fluorescence-activated cell sorting (FACS), respectively. Confocal imaging and FACS were used to detect binding of endothelial-derived EVs from these two sources to leukocytes in vitro. Serial electron microscopy (serial EM) and 3D contour-based surface reconstruction were employed to view EV-like structures at the leukocyte:BBB interface in situ in inflamed CNS microvessels.ResultsA subpopulation of leukocytes immunoreactive for CLN-5 on their surface was seen to infiltrate the CNS of mice with EAE and reside in close apposition to inflamed vessels. Confocal imaging of immunostained samples and Western blotting established the presence of CLN-5+ leukocytes in blood as well, implying these cells are present prior to TEM. Moreover, imaging of inflamed CNS vessels and the associated perivascular cell infiltrates from Tie-2-eGFP-CLN-5 mice with EAE revealed leukocytes bearing the eGFP label, further supporting the hypothesis CLN-5 is transferred from endothelial cells to circulating leukocytes in vivo. Western blotting of BMEC-derived EVs, corresponding in size to both exosomes and microvesicles, and FACS analysis of plasma-derived EVs from Tie-2-eGFP-CLN-5 mice with EAE validated expression of CLN-5 by EVs of endothelial origin. Confocal imaging and FACS further revealed both PKH-67-labeled EVs from cultured BMECs and eGFP-CLN-5+ EVs from plasma of Tie-2-eGFP-CLN-5 mice with EAE can bind to leukocytes. Lastly, serial EM and 3D contour-based surface reconstruction revealed a close association of EV-like structures between the marginating leukocytes and BMECs in situ during EAE.ConclusionsDuring neuroinflammation, CLN-5+ leukoc...
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