Caveolin-1 Expression Determines the Route of Neutrophil Extravasation through Skin Microvasculature

Interleukin-8 plays a key role in the acute inflammatory response by mediating recruitment of neutrophils through vessel walls into affected tissues. During this process, molecular signals guide circulating blood neutrophils to target specific vessels for extravasation and to migrate through such vessels via particular routes. Our results show that levels of endothelial caveolin-1, the protein responsible for the induction of the membrane domains known as caveolae, are critical to each of these processes. We demonstrate that, in response to the intradermal injection of interleukin-8, neutrophils are preferentially recruited to a unique subset of venules that express high levels of intercellular adhesion molecule-1 and low levels of caveolin-1. Our results show that neutrophils traverse human dermal microvascular endothelial cells using one of two pathways: a transcellular route directly through the cell or a paracellular route through cellular junctions. Caveolin-1 expression appears to favor the transcellular path while down-regulation of caveolin-1 promotes the paracellular route.Wounding of the epithelium and entry of a foreign body elicit a series of responses from the innate immune system. One of the main hallmarks of acute inflammation is neutrophil infiltration at the affected site.^1,2 In response to injury or infection, resident phagocytic cells become activated and release inflammatory cytokines such as tumor necrosis factor (TNF)-α and interleukin (IL)-8. TNF-α activates the vascular endothelium causing vasodilation and cellular infiltration.³ IL-8 functions as a critical chemotactic factor attracting neutrophils from the blood to the affected area.^1,4It is currently thought that leukocyte recruitment and migration through the vasculature is an active process not only for migrating blood cells but also for endothelial cells lining the vessels. Initially, inflammatory cytokines or bacterial endotoxins induce expression of P- and E-selectin on the surface of microvascular endothelial cells.^5,6 These molecules recognize carbohydrate counterligands on the surface of circulating leukocytes and mediate the tethering and rolling of these cells along vessel walls.^5,6,7 Firm adhesion is then initiated through the upregulation of endothelial adhesion molecules such as intercellular adhesion molecule (ICAM)-1 and vascular adhesion molecule (VCAM)-1, which bind to integrins expressed on the leukocyte surface.^5,7,8 Finally, the leukocyte is induced to migrate through the vessel in a process known as diapedesis.^5,6,7Among the many proteins implicated in the process of diapedesis, the adhesion molecule ICAM-1, which is up-regulated on activated endothelium, and caveolin-1, which is expressed on most terminally differentiated cell types but is largely undetectable in white blood cells, have been most closely associated with the route of transendothelial migration in in vitro systems.^7,9,10 A recent study by Millan et al clearly demonstrates that ICAM-1 and caveolin-1 are involved in directing the path of T lymphoblast migration through human umbilical vein endothelial cells (HUVECs).⁷Although both caveolin-1 and ICAM-1 have been associated with leukocyte transendothelial migration in vitro, the distribution of these proteins in vessels used by migrating leukocytes in vivo remain unclear. While all endothelial cells (ECs) share common features, the vascular tree is known to be extremely heterogeneous. As a result, the precise molecular profile of selectins and adhesion molecules defining vessels targeted for extravasation by circulating leukocytes is unknown. Furthermore, since the phenotype of vessel ECs is determined in large part by their unique in vivo microenvironment, site specific and regional differences in the expression of molecules contributing to the regulation of leukocyte transmigration have yet to be thoroughly characterized.^11,12 In this study, we have examined the in vivo molecular profile of vessels targeted by circulating neutrophils in response to IL-8 in the skin and have determined the effect of the expression of these factors on the route of neutrophil transmigration in vitro.     

Heat shock protein 70 associations with myelin basic protein and proteolipid protein in multiple sclerosis brains

Heat shock proteins (hsp) are known to facilitate the generation of specific immune responses by chaperoning proteins and peptides involved in T cell activation. Hsp have been shown to be strikingly elevated in multiple sclerosis (MS) lesions. The unique chaperonin properties of hsp70 have allowed identification of immunogenic proteins bound to it by the ex vivo demonstration of hsp associations with proteins implicated in the immune response. We have investigated the association of hsp70 with myelin basic protein (MBP), myelin proteolipid protein (PLP) and myelin oligodendrocyte protein (MOG) in MS and control brain tissue. In co-immunoprecipitation experiments, in all samples of MS brains examined (n = 3), but not control brain tissue (n = 3), direct association of MBP with hsp70, but not with hsp90, was found. In some MS brain samples, association between PLP and hsp70 was also seen. In similar co-immunoprecipitation experiments on brain tissue obtained from mice with experimental autoimmune encephalomyelitis (n = 5) induced by immunization with PLP peptide, specific association of hsp70 with PLP and MBP was found. Using surface plasmon resonance we demonstrated specific binding of hsp70 with MBP in vitro. Analysis of the amounts of MBP bound to hsp70 yielded a molecular ratio of MBP binding to hsp70 at 6.5:1. MBP complexed with hsp70 was taken up at significantly higher rates by antigen-presenting cells than MBP alone and enhanced MBP-specific immune responses. These results indicate that hsp70 specifically associates with MBP in MS brain tissue. This association might be relevant to the enhanced immune recognition of MBP in MS.     

Upregulation of group 1 CD1 antigen presenting molecules in guinea pigs with experimental autoimmune encephalomyelitis: an immunohistochemical study

In humans, group 1 CD1 glycoproteins present foreign and self lipid and glycolipid antigens to T-cells. Homologues of these molecules are not found in mice or rats but are present in guinea pigs (GPs). We examined CD1 and MHC class II expression in the central nervous system (CNS) of GPs sensitized for experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis. In normal GPs and the uninflamed CNS, low-level MHC class II (MHC II) immunoreactivity occurred on vascular elements, meningeal macrophages and parenchymal microglial cells, whereas immunoreactivity for CD1 was absent. In the inflamed CNS, the majority of infiltrating cells were MHC II+ and microglia showed increased expression. CD1 immunoreactivity was detected on astrocytes and subsets of inflammatory cells Including B cells and macrophages. Minimal CD1 and MHC II co-expression was noted on inflammatory cells or glia. We conclude that group 1 CD1 molecules are strongly upregulated in the inflamed CNS on subsets of cells distinct from the majority of MHC II bearing cells. The expression of CD1 proteins in such lesions broadens the potential repertoire of antigens recognized at these sites and highlights the value of the GP as a model for studies of the relevance of CD1 molecules in host defense and autoimmune diseases.     

An optimal algorithm for configuring delivery options of a one-dimensional intensity-modulated beam

The problem of generating delivery options for one-dimensional intensity-modulated beams (1D IMBs) arises in intensity-modulated radiation therapy. In this paper, we present an algorithm with the optimal running time, based on the 'rightmost-preference' method, for generating all distinct delivery options for an arbitrary 1D IMB. The previously best known method for generating delivery options for a 1D IMB with N left leaf positions and N right leaf positions is a 'brute-force' solution, which first generates all N! possible combinations of the left and right leaf positions and then removes combinations that are not physically allowed delivery options. Compared with the brute-force method, our algorithm has several advantages: (1) our algorithm runs in an optimal time that is linearly proportional to the total number of distinct delivery options that it actually produces. Note that for a 1D IMB with multiple peaks, the total number of distinct delivery options in general tends to be considerably smaller than the worst case N!. (2) Our algorithm can be adapted to generating delivery options subject to additional constraints such as the 'minimum leaf separation' constraint. (3) Our algorithm can also be used to generate random subsets of delivery options; this feature is especially useful when the 1D IMBs in question have too many delivery options for a computer to store and process. The key idea of our method is that we impose an order on how left leaf positions should be paired with right leaf positions. Experiments indicated that our rightmost-preference algorithm runs dramatically faster than the brute-force algorithm. This implies that our algorithm can handle 1D IMBs whose sizes are substantially larger than those handled by the brute-force method. Applications of our algorithm in therapeutic techniques such as intensity-modulated arc therapy and 2D modulations are also discussed.     

Gated CT imaging using a free-breathing respiration signal from flow-volume spirometry

Respiration-induced tumor motion is known to cause artifacts on free-breathing spiral CT images used in treatment planning. This leads to inaccurate delineation of target volumes on planning CT images. Flow-volume spirometry has been used previously for breath-holds during CT scans and radiation treatments using the active breathing control (ABC) system. We have developed a prototype by extending the flow-volume spirometer device to obtain gated CT scans using a PQ 5000 single-slice CT scanner. To test our prototype, we designed motion phantoms to compare image quality obtained with and without gated CT scan acquisition. Spiral and axial (nongated and gated) CT scans were obtained of phantoms with motion periods of 3-5 s and amplitudes of 0.5-2 cm. Errors observed in the volume estimate of these structures were as much as 30% with moving phantoms during CT simulation. Application of motion-gated CT with active breathing control reduced these errors to within 5%. Motion-gated CT was then implemented in patients and the results are presented for two clinical cases: lung and abdomen. In each case, gated scans were acquired at end-inhalation, end-exhalation in addition to a conventional free-breathing (nongated) scan. The gated CT scans revealed reduced artifacts compared with the conventional free-breathing scan. Differences of up to 20% in the volume of the structures were observed between gated and free-breathing scans. A comparison of the overlap of structures between the gated and free-breathing scans revealed misalignment of the structures. These results demonstrate the ability of flow-volume spirometry to reduce errors in target volumes via gating during CT imaging.