Epidermal growth factor (EGF) binding to its receptor causes rapid phosphorylation of the clathrin heavy chain at tyrosine 1477, which lies in a domain controlling clathrin assembly. EGF-mediated clathrin phosphorylation is followed by clathrin redistribution to the cell periphery and is the product of downstream activation of SRC kinase by EGF receptor (EGFR) signaling. In cells lacking SRC kinase, or cells treated with a specific SRC family kinase inhibitor, EGF stimulation of clathrin phosphorylation and redistribution does not occur, and EGF endocytosis is delayed. These observations demonstrate a role for SRC kinase in modification and recruitment of clathrin during ligand-induced EGFR endocytosis and thereby define a novel effector mechanism for regulation of endocytosis by receptor signaling.
Many pathogens have co-evolved with their human hosts to develop strategies for immune evasion that involve disruption of the intracellular pathways by which antigens are bound by class I and class II molecules of the major histocompatibility complex (MHC) for presentation to T cells. Here the molecular events in these pathways are reviewed and pathogen interference is documented for viruses, extracellular and intracellular bacteria and intracellular parasites. In addition to a general review, data from our studies of adenovirus, Chlamydia trachomatis and Coxiella burnetii are summarized. Adenovirus E19 is the first viral gene product described that affects class I MHC molecule expression by two separate mechanisms, intracellular retention of the class I heavy chain by direct binding and by binding to the TAP transporter involved in class I peptide loading. Coxiella and Chlamydia both affect peptide presentation by class II MHC molecules as a result of their residence in endocytic compartments, although the properties of the parasitophorous vacuoles they form are quite different. These examples of active interference with antigen presentation by viral gene products and passive interference by rickettsiae and bacteria are typical of the strategies used by these different classes of pathogens, which need to evade different types of immune responses. Pathogen-host co-evolution is evident in these subversion tactics for which the pathogen crime seems tailored to fit the immune system punishment.
Following biosynthesis, class II MHC molecules are transported through a lysosome-like compartment, where they acquire antigenic peptides for presentation to T cells at the cell surface. This compartment is characterized by the presence of HLA-DM, which catalyzes the peptide loading process. Here we report that the morphology and function of the class II loading compartment is affected in diseases with a phenotypic change in lysosome morphology. Swollen lysosomes are observed in cells from patients with the hereditary immunodeficiency Chediak-Higashi syndrome and in cells infected with Coxiella burnetii, the rickettsial organism that causes Q fever. In both disease states, we observed that HLA-DR and HLA-DM accumulate in enlarged intracellular compartments, which label with the lysosomal marker LAMP-1. The distribution of class I MHC molecules was not affected, localizing disease effects to the endocytic pathway. Thus, cellular mechanisms controlling lysosome biogenesis also affect formation of the class II loading compartment. Analysis of cell surface class II molecules revealed that their steady-state levels were not reduced on diseased cells. However, in both disease states, enhanced interaction between HLA-DR and HLA-DM was detected. In the Chediak-Higashi syndrome cells, this correlated with more efficient removal of the CLIP peptide. These findings suggest a mechanism for perturbation of Ag presentation by class II molecules and consequent immune deficiencies in both diseases.
Brain-based discussion of language has classically centered around models focused on Broca's and Wernicke's areas. Recent neurobiological research indicates that such models may be oversimplified. The present paper attempts to propose a model in which afar greater number of brain structures are involved in language functions. To demonstrate this model, three areas of the brain rarely associated with language, the anterior cingulate gyrus, the prefrontal cortex, and the basal temporal language area (fusiform gyrus) are examined. Recent neurobiological research linking these areas to language function will be reviewed to illustrate that a whole-brain view of language is both more feasible and better supported by data than the idea of a languagespecific brain system, such as the Wernicke-Geschwind model.
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