Activated leukocyte cell adhesion molecule (ALCAM, CD166) is a cell adhesion molecule of the immunoglobulin superfamily and has been implicated in diverse pathophysiological processes including T cell activation, leukocyte trafficking, and (lymph)angiogenesis. However, exploring the therapeutic potential of ALCAM blockade in immune-mediated inflammatory disorders has been difficult due to the lack of antibodies with blocking activity toward murine ALCAM. In this study, we identified and characterized a monoclonal antibody with high affinity and specificity for murine ALCAM. This antibody reduced in vitro T cell activation induced by antigen-presenting dendritic cells (DCs) as well as (trans)migration of murine DCs across lymphatic endothelial monolayers. Moreover, it reduced emigration of DCs from in vitro -cultured human skin biopsies. Similarly, antibody-based blockade of ALCAM reduced (lymph)angiogenic processes in vitro and decreased developmental lymphangiogenesis in vivo to levels observed in ALCAM-deficient mice. Since corneal allograft rejection is an important medical condition that also involves (lymph)angiogenesis, DC migration and T cell activation, we investigated the therapeutic potential of ALCAM blockade in murine corneal disease. Blocking ALCAM lead to DC retention in corneas and effectively prevented corneal allograft rejection. Considering that we also detected ALCAM expression in human corneal DCs and lymphatics, our findings identify ALCAM as a potential novel therapeutic target in human corneal allograft rejection.
In this observational study, 13 patients with severe COVID‐19 and 10 healthy controls were enrolled. The data concerning the analysis of circulating T cells show that, in severe COVID‐19 patients, the expansion of these cell compartments is prone to induce antibody response, inflammation (CCR4+ and CCR6+ TFH) and regulation (CD8+ Treg). This pathogenic mechanism could lead us to envision a possible new form of biological target therapy.
The efficacy of taxanes on human leukemia cells is the object of intensive in vitro investigation concerning the influence of cell‐type‐specific characteristics on cytotoxic response to drugs. The present study dissects the response to taxanes of HL60 acute myelomonocytic leukemia and of K562 chronic myelogenous leukemia, in parallel over a 72‐hr time‐span. The kinetics of cytotoxicity following pulsed and continuous exposure to either taxol or taxotere showed a delayed response of K562 cells independently of dose and type of exposure. In K562 cells, apoptosis became evident at 48 hr and prominent at 72 hr of treatment. These events were mirrored by delayed kinetics of caspase‐3 activation. Comparable microtubule targeting was demonstrated in HL60 and in K562 cell lines, as bcl‐2 and raf‐1 were phosphorylated following treatment with taxanes. These observations indicate that early activation processes were responsible for apoptosis, but that the delay was determined by other factors. In addition, cell‐free‐system experiments excluded the presence of excess nuclear and/or cytoplasmic inhibitory factors and demonstrated that K562 cells possess a fully competent caspase system which can be readily activated. Processing of caspase‐3 pro‐enzyme was in fact increased by addition of cytochrome c. These results extend to taxol and taxotere the notion that drug‐induced apoptosis is delayed upstream of caspase‐3 activation in K562 cells, that such kinetics is independent of drug concentration and exposure time, and that it is linked to intrinsic cellular characteristics mapping between bcl‐2 phosphorylation and cytochrome c release. Int. J. Cancer 85:527–533, 2000. © 2000 Wiley‐Liss, Inc.
Squamous cell carcinoma (SCC) derives from dysplastic or metaplastic stratified epithelia. The process of squamous cell carcinogenesis has been investigated for the potential role of the adhesion molecule CD44, whose standard form (CD44s) and isoforms generated by alternative splicing of variant exons are known to display altered expression during tumorigenesis in other systems. We have utilized an in vitro correlate of squamous cell carcinogenesis, in which progression stages from normal squamous epithelium to dysplastic lesions and to SCC are represented by primary cultures of normal keratinocytes, by human papilloma virus-immortalized keratinocytes (UP) and by HPVimmortalized/v-Ha-ras transfected tumorigenic keratinocytes (UPR). We investigated expression of CD44 and of variant isoforms, from mRNA to intracellular and surface protein levels, and found no relationship between expression of CD44 and stages of squamous cell carcinogenesis. However, when the function of CD44 was analyzed as Ca(2+) mobilization ability upon monoclonal antibody binding and crosslinking, signal transduction via CD44 was found only for the neoplastic stage (UPR cells). Ca(2+) mobilization was completely independent of density of surface CD44. We have performed similar analyses in an in vitro model of SCC in which four squamous tumor cell lines and UPR cells were sorted according to increasing resistance to external cytotoxic stimuli, i.e. starving conditions, treatment with the retinoid N-(4-hydroxyphenyl)retinamide and cytolytic activity of effector lymphokine-activated killer cells. No relationship between expression of CD44 and level of cell resistance against external cell death-inducing stimuli was found, while CD44-mediated Ca(2+) mobilization ability was restricted to the highly resistant tumor cell lines. Our results indicate that the role(s) of CD44 in squamous cell proliferative disorders can be evinced from the functional features of the molecule, rather than from its phenotypic repertoire.
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