Molecular mechanisms of lymphocyte extravasation. II. Studies of in vitro lymphocyte adherence to high endothelial venules

Lymphocyte migration from the blood into the lymph nodes in most species occurs across post-capillary high endothelial venules (HEV). In a previous study, we proposed that lymphocyte extravasation involves receptor-mediated binding followed by adenylate cyclase-dependent activation of lymphocyte motility. This hypothesis was, in part, based on observations of in vitro lymphocyte adherence to HEV by employing pertussigen, which is a known inhibitor of lymphocyte recirculation. In vitro lymphocyte-HEV binding requires a cold (6 degrees C) incubation step and binding is poor to nil if the assay is attempted at room (23 degrees C) or physiologic temperature. We decided to investigate why this assay is temperature restricted, because of the possibility that pertussigen or fucoidin -treated lymphocytes might interact with HEV differently at higher temperatures. We now report that O.C.T. compound (OCT), the embedding matrix generally used to cut frozen lymph node sections, is toxic to lymphocytes at temperatures above 6 degrees C. Exclusion of OCT from the assay system will allow lymphocyte-HEV binding to occur at 23 degrees C and to a lesser extent at 37 degrees C. With this modified protocol, lymphocytes treated with either pertussigen, fucoidin , or neuraminidase were tested for adherence to HEV at 23 degrees C. No essential difference in binding properties was observed from what had been reported at 6 degrees C. In contrast, trypsin-treated lymphocytes that did not bind to HEV with the standard technique at 6 degrees C did adhere to a minimal extent to HEV at 23 degrees C using the modified procedure. We also report some preliminary work, using the modified assay, on in vitro lymphocyte-HEV binding of rat, rabbit, and guinea pig lymphocytes to sections of lymph nodes from the respective species.     

Molecular mechanisms of lymphocyte extravasation. III. The loss of lymphocyte extravasation potential induced by pertussis toxin is not mediated via the activation of protein kinase C

The present study evaluated whether protein kinase C (PKC) activation was involved in the lymphocytosis promoting properties of pertussis toxin (Ptx). The exposure of mouse lymphocytes to phorbol esters (as a means to selectively activate PKC) caused a depression in their subsequent capacity to localize into lymph nodes and Peyer's patches in vivo. This pattern of inhibition was quite similar to that observed with lymphocytes treated with Ptx. The mechanisms responsible for the observed decreases in localization to lymphoid organs caused by these two agents, however, appeared to be distinct. Exposure of lymphocytes to PMA was followed by a time and dosage-dependent decrease in the surface density of MEL-14 defined homing receptors. Ptx-treated lymphocytes retained normal density of this homing receptor. Consequently, PMA-treated lymphocytes lost their capacity to bind to high-endothelial venules in in vitro lymph node binding assays while Ptx-treated cells retained normal high-endothelial venule binding potential. We conclude from this study that: 1) the activation of PKC in lymphocytes by PMA can alter their recirculation properties via mechanisms that diminish their expression of surface receptors which support extravasation into lymph node and mucosal lymphoid tissues, and 2) even though Ptx has been reported to elevate the rate of inositol phosphate turnover in lymphocytes, the loss of extravasation potential of Ptx-treated lymphocytes is not mediated via the modification of surface homing receptors as observed in cells exposed to the known PKC activator, PMA.     

Molecular mechanisms of band 3 inhibitors. 3. Translocation inhibitors

During the translocation of the band 3 transport site between the inward- and outward-facing orientations, the Cl- transport site complex passes through a transition state lying on the reaction pathway between the two extreme orientations. Niflumic acid, 2-[(7-nitrobenzofurazan-4-yl)amino]ethanesulfonate, and 2,4,6-trichlorobenzenesulfonate each are translocation blockers that can bind to both the inward- and outward-facing conformations of band 3. The principal mechanism of these inhibitors is a reduction in the translocation rate, since they have essentially no effect on the apparent KD for Cl- binding to the transport site and the migration of Cl- between the transport site and solution. Instead, these inhibitors raise the free energy of formation of the transition state during translocation and thereby can lock the transport site into either the inward- or outward-facing orientation. In contrast, 2,4-dinitrofluorobenzene (DNFB) appears to restrict the accessibility of the transport site to solution Cl-; also, the DNFB reaction rate is increased by Cl-, suggesting that DNFB modification may occur during translocation. Thus DNFB is proposed to trap the Cl--transport site complex site during translocation to yield a conformation intermediate to the inward- and outward-facing orientations. A model is presented for the molecular mechanism of transport across biological membranes. The transport machinery is proposed to contain greater than or equal to 6 transmembrane helices that surround a central channel containing a sliding hydrophobic barrier. The transport site lies between two of the channel-forming helices and remains stationary while the hydrophobic barrier slides from one end of the channel to the other, thereby exposing the transport site to the opposite solution compartment.     

Molecular mechanisms of band 3 inhibitors. 1. Transport site inhibitors

The band 3 protein of red cells is a transmembrane ion transport protein that catalyzes the one-for-one exchange of anions across the cell membrane. 35Cl NMR studies of Cl- binding to the transport sites of band 3 show that inhibitors of anion transport can be grouped into three classes: (1) transport site inhibitors (examined in this paper), (2) channel-blocking inhibitors (examined in the second of three papers in this issue), and (3) translocation inhibitors (examined in the third of three papers in this issue). Transport site inhibitors fully or partially reduce the affinity of Cl- for the transport site. The dianion 4,4'-di-nitrostilbene-2,2'-disulfonate (DNDS) and the arginine-specific reagent phenylglyoxal (PG) each completely eliminate the transport site 35Cl NMR line broadening, and each compete with Cl- for binding. These results indicate that DNDS and PG share a common inhibitory mechanism involving occupation of the transport site: one of the DNDS negative charges occupies the site, while PG covalently modifies one or more essential positive charges in the site. In contrast, 35Cl NMR line broadening experiments suggest that 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) leaves the transport site partially intact so that the affinity of Cl- for the site is reduced but not destroyed. This result is consistent with a picture in which DIDS binds near the transport site and partially occupies the site.     

Molecular mechanisms of band 3 inhibitors. 2. Channel blockers

Band 3 is proposed to contain substrate channels that lead from the aqueous medium to a transport site buried within the membrane, and which can be blocked by inhibitors. The inhibitors 1,2-cyclohexanedione (CHD) and dipyridamole (DP) each inhibit the transport site 35Cl NMR line broadening, but neither competes with Cl- for binding. Thus these inhibitors do not occupy the transport site; instead they slow the migration of Cl- between the transport site and the medium. The simplest explanation for this behavior is that CHD and DP block one or more substrate channels. CHD is an arginine-specific covalent modification reagent, and its effectiveness as a channel blocker indicates that the channel contains arginine positive charges to facilitate the migration of anions through the channel. DP is a noncovalent channel blocker that binds with a stoichiometry of 1 molecule per band 3 dimer. DP binding is unaffected by CHD but is prevented by phenylglyoxal (PG), 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS), or niflumic acid. Thus the DP and CHD binding sites are distinct, with DP binding sufficiently close to the transport site to interact with PG and DNDS. It is proposed that substrate channels may be a general feature of transport proteins.     

Molecular mechanisms of viral inhibitors of RIG-I-like receptors

Activation of innate immune signaling pathways through cytosolic RIG-I-like receptors (RLR) is a crucial response that is antagonized by many viruses. A variety of RNA-related pathogen-associated molecular patterns (PAMPS) have been identified and their role in RLR activation has been examined. Recent studies suggest that several virus-encoded components that antagonize RLR signaling interact with and inhibit the interferon (IFN)-α/β activation pathway using both RNA-dependent and RNA-independent mechanisms. The structural basis for these RLR inhibitory mechanisms, as well as the multifunctional nature of viral RLR antagonists, is reviewed in the context of recent biochemical and structural studies.     

Molecular mechanisms of selective dopaminergic neuronal death in Parkinson's disease

Parkinson's disease (PD) is a progressive neurological disease caused by selective degeneration of dopaminergic neurons in the substantia nigra pars compacta (SNc). Although PD has been heavily researched, the precise etiology of nigral cell loss is still unknown and, consequently, treatment is largely symptomatic rather than preventive. There are conflicting data regarding the mode of dopaminergic cell death in PD and, hence, this remains controversial. Several mutations in specific genes have recently been linked with hereditary forms of PD. Although none of these mutations are seen in idiopathic disease cases, the elucidation of these genetic defects sheds light on the nature of idiopathic PD. It is possible that dopaminergic neurogenesis also contributes to the etiology of idiopathic PD. In addition, intracellular as well as extracellular substances found in the SNc are believed to function as damaging pathogenetic factors. These factors, and the interactions among them, might hold the secret to the underlying causes of the selective death of dopaminergic neurons in PD.     

Two distinct mechanisms for redistribution of lymphocyte surface macromolecules. I. Relationship to cytoplasmic myosin

A detailed kinetic analysis of the distribution of cytoplasmic myosin during the capping of various lymphocytic surface molecules revealed two distinct capping mechanisms. (a) Some cell surface molecules, including immunoglobulin, Fc receptor, and thymus leukemia antigen, all cap spontaneously in a small fraction of lymphocytes during locomotion. Cytoplasmic myosin becomes concentrated in the cytoplasm underlying these spontaneous caps. Exposure to specific antibodies causes all three of these surface molecules to cap rapidly with a concomitant redistribution of cytoplasmic myosin to the area of the cap. These antibodies also stimulate cell locomotion. (b) Other lymphocyte surface molecules, including H2 and Thy.1, do not cap spontaneously. Moreover, exposure to antibodies to these molecules causes them to cap slowly without a redistribution of cytoplasmic myosin or stimulation of cell locomotion. Exposure to concanavalin A gives a response intermediate between these two extremes. We believe that the first type of capping is active and may involve a direct link between the surface molecules and the cytoplasmic contractile apparatus. The second type of capping appears to result simply from aggregation of cross-linked molecules in the plane of the membrane.     

The predominant role of the spleen in lymphocyte recirculation. I. Homing of lymphocytes to and release from the isolated perfused pig spleen.

Lymphocyte recirculation through the isolated pig spleen was studied by means of a perfusion system which kept the organ alive for a prolonged period of time. By changing the perfusate to a leucocyte-enriched or cell-free perfusate and taking serial arterial and venous samples, the numbers of lymphocytes which homed to or were released from the spleen were measured. In all experiments more lymphocytes homed than were released per minute. There was no apparent difference when autologous or allogeneic cells were used. The number of lymphocytes released depended on the number of lymphocytes homed previously. During the phase of constant release up to 3-3 X 10(6) lymphocytes were released per gram spleen per minute. From these values it can be extrapolated that up to 270 X 19(9) lymphocytes recirculate through the isolated pig spleen per day. Based on kinetic data from other species it is estimated that in the entire pig a total number of 300-400 X 10(9) lymphocytes recirculate per day. Thus, it can be concluded that the spleen is the most important organ for lymphocyte recirculation in the pig.     

Small molecule inhibitors induce conformational changes in the I domain and the I-like domain of lymphocyte function-associated antigen-1. Molecular insights into integrin inhibition.

The beta(2) integrin lymphocyte function-associated antigen-1 (LFA-1) is a conformationally flexible alpha/beta heterodimeric receptor, which is expressed on the surface of all leukocytes. LFA-1 mediates cell adhesion crucial for normal immune and inflammatory responses. Intracellular signals or cations are required to convert LFA-1 from a nonligand binding to a ligand binding state. Here we investigated the effect of small molecule inhibitors on LFA-1 by monitoring the binding of monoclonal antibodies mapped to different receptor domains. The inhibitors were found to not only induce epitope changes in the I domain of the alpha(L) chain but also in the I-like domain of the beta(2) chain depending on the individual chemical structure of the inhibitor and its binding site. For the first time, we provide strong evidence that the I-like domain represents a target for allosteric LFA-1 inhibition similar to the well established regulatory L-site on the I domain of LFA-1. Moreover, the antibody binding patterns observed in the presence of the various inhibitors establish a conformational interaction between the LFA-1 I domain and the I-like domain in the native receptor that is formed upon activation. Differentially targeting the binding sites of the inhibitors, the L-site and the I-like domain, may open new avenues for highly specific therapeutic intervention in diseases where integrins play a pathophysiological role.     

Molecular mechanisms of hormonal activity. I. receptors. neuromediators. systems with second messengers

Hormone signal transfer along all of the cell compartments including nucleus is powered by signal transduction systems. Characteristics and importance of hormone receptors, principal components, functional mechanisms, and biological role of different systems with second messengers are described. Considerable examples of the importance of these systems for medicine are adduced. The drugs modifying these systems comprise more than 65% of contemporary medicines.Translated from Biokhimiya, Vol. 70, No. 1, 2005, pp. 33–50.Original Russian Text Copyright © 2005 by Kulinsky, Kolesnichenko.