María C. Brañes

TNF-α Plus IFN-γ Induce Connexin43 Expression and Formation of Gap Junctions Between Human Monocytes/Macrophages That Enhance Physiological Responses

In this work, the effects of bacterial LPS, TNF-α, and IFN-γ on gap junctional communication (dye coupling) and on the expression of connexin43 (immunofluorescence, immunoblotting, and RT-PCR) in monocytes/macrophages were studied. Freshly isolated human monocytes plated at high density and treated either with LPS plus IFN-γ or TNF-α plus IFN-γ became transiently dye coupled (Lucifer yellow) within 24 h. Cells treated with LPS, TNF-α, or IFN-γ alone remained dye uncoupled. In dye-coupled cells, the spread of Lucifer yellow to neighboring cells was reversibly blocked with 18 α-glycyrrhetinic acid, a gap junction blocker, but it was unaffected by oxidized ATP or probenecid, which block ionotropic ATP-activated channels and organic anion transporters, respectively. Abs against TNF-α significantly reduced the LPS plus IFN-γ-induced increase in dye coupling. In dye-coupled monocytes/macrophages, but not in control cells, both connexin43 protein and mRNA were detected, and their levels were higher in cells with an elevated incidence of dye coupling. In dye-coupled cells, the localization of connexin43 immunoreactivity was diffuse at perinuclear regions and thin cell processes. The addition of 18-α-glycyrrhetinic acid induced a profound reduction of monocyte/macrophage transmigration across a blood brain barrier model. It also induced a significant reduction in the secretion of metalloproteinase-2 in cells treated with TNF-α plus IFN-γ. We propose that some monocyte/macrophage responses are coordinated by connexin-formed membrane channels expressed transiently at inflammatory sites in which these cells form aggregates.

Structural Determinants of the Alzheimer's Amyloid β-Peptide†

Abstract: The hallmark event of Alzheimers disease (AD) is the deposition of amyloid as insoluble fiber masses in extracellular neuritic plaques and around the walls of cerebral blood vessels. The main component of amyloid is a hydrophobic peptide, named amyloid β‐peptide (βA4), which results from the processing of a much longer membrane amyloid precursor protein (APP). This review focuses on the structural features of βA4 and the factors that determine βA4 insolubilization. Theoretical and experimental studies of the primary structure of βA4 have shown that it is composed of a completely hydrophobic C‐terminal domain, which adopts β‐strand structure, and an N‐terminal region, whose sequence permits different secondary structures. In fact, this region can exist as an α‐helical or β‐strand conformation depending on the environmental condition (pH and hydrophobicity surrounding the molecule). The effects of pH and hydrophobicity on βA4 structure may elucidate the mechanisms determining its aggregation and amyloid deposition in AD.

Regulation of gap junctions by protein phosphorylation

Gap junctions are constituted by intercellular channels and provide a pathway for transfer of ions and small molecules between adjacent cells of most tissues. The degree of intercellular coupling mediated by gap junctions depends on the number of gap junction channels and their activity may be a function of the state of phosphorylation of connexins, the structural subunit of gap junction channels. Protein phosphorylation has been proposed to control intercellular gap junctional communication at several steps from gene expression to protein degradation, including translational and post-translational modification of connexins (i.e., phosphorylation of the assembled channel acting as a gating mechanism) and assembly into and removal from the plasma membrane. Several connexins contain sites for phosphorylation for more than one protein kinase. These consensus sites vary between connexins and have been preferentially identified in the C-terminus. Changes in intercellular communication mediated by protein phosphorylation are believed to control various physiological tissue and cell functions as well as to be altered under pathological conditions.

Identification of second messengers that induce expression of functional gap junctions in microglia cultured from newborn rats.

The effect of several second messengers on the functional expression of gap junctions was investigated in primary cultures of newborn rat microglia. As previously reported, microglia cultured under resting conditions expressed low levels of the gap junction protein connexin 43, and exhibited little dye coupling. After treatment with 4bromo-A23187, a Ca(2+) ionophore, the incidence of dye coupling between microglia increased progressively over a 12-h period. Dye coupling was markedly reduced by gap junction blockers. Induction of dye coupling by 4bromo-A23187 was prevented by the addition of a synthetic peptide with the same sequence as a region of the extracellular loop 1 of connexin 43 (residues 53-66). The increase in dye coupling induced by 4bromo-A23187 was associated with increased connexin 43 mRNA and protein levels. Treatment of microglia with phorbol 12-myristate 13-acetate, an activator of protein kinase C, did not promote gap junctional communication in untreated microglia and reversed 4bromo-A23187-induced dye coupling. Thus, gap junctional communication between microglia can be regulated oppositely by calcium- and protein kinase C-dependent pathways. Activators of cGMP-dependent protein kinase (8bromo-cGMP) or protein kinase A (8bromo-cAMP) had no effect on untreated microglia or on 4bromo-A23187-induced dye coupling. Differential regulation of gap junctions by intracellular calcium concentration and protein kinase C activity may help to explain how various stimuli evoke differences in microglia responses, such as synthesis and secretion of cytokines and proteases.

Injury of skeletal muscle and specific cytokines induce the expression of gap junction channels in mouse dendritic cells

Dendritic cells (DCs) in culture express at least connexin43, a protein subunit of gap junctions, and form gap junction channels, which could be important for T‐cells activation. Here, we evaluated whether DCs express connexins in vivo and also to identify components of their microenvironment that regulate the functional expression of gap junctions. In vivo studies were performed in lymph nodes of mice under control conditions or after skeletal muscle damage. In double immunolabeling studies, connexin45 was frequently detected in DEC205+ DCs in lymph nodes of control animals, whereas connexin43 was rarely found in DCs. However, connexin43 was upregulated in DCs after skeletal muscle damage. Upregulation of connexin43 gene expression by tissue damage was also confirmed in mice carrying a β‐galactosidase reporter gene in a connexin43 allele. The effect of several cytokines on the expression of functional gap junctions between cultured DCs was also tested. Under control conditions, cultured DCs did not communicate via gap junctions. However, after treatment with keratinocyte‐conditioned medium or cytokine mixtures containing at least TNF‐α and IL‐1β, they became transiently coupled through a pathway sensitive to octanol, a gap junction blocker. Cellular coupling induced by effective cytokine mixtures was prevented by IL‐6. Single cytokines (TNF‐α, IL‐1β, IFN‐γ, or IL‐6) or other mixtures than the described above did not induce coupling via gap junctions. Increased levels of connexin43 and connexin45 protein and mRNA accompanied the appearance of cellular coupling. These studies provide demonstration of connexin expression and regulation by specific danger signals in DCs. J. Cell. Physiol. 211: 649–660, 2007.

Modulation of gap junction channels and hemichannels by growth factors

Gap junction hemichannels and cell-cell channels have roles in coordinating numerous cellular processes, due to their permeability to extra and intracellular signaling molecules. Another mechanism of cellular coordination is provided by a vast array of growth factors that interact with relatively selective cell membrane receptors. These receptors can affect cellular transduction pathways, including alteration of intracellular concentration of free Ca(2+) and free radicals and activation of protein kinases or phosphatases. Connexin and pannexin based channels constitute recently described targets of growth factor signal transduction pathways, but little is known regarding the effects of growth factor signaling on pannexin based channels. The effects of growth factors on these two channel types seem to depend on the cell type, cell stage and connexin and pannexin isoform expressed. The functional state of hemichannels and gap junction channels are affected in opposite directions by FGF-1 via protein kinase-dependent mechanisms. These changes are largely explained by channels insertion in or withdrawal from the cell membrane, but changes in open probability might also occur due to changes in phosphorylation and redox state of channel subunits. The functional consequence of variation in cell-cell communication via these membrane channels is implicated in disease as well as normal cellular responses.

Chapter 25: Gap Junctions in Inflammatory Responses: Connexins, Regulation and Possible Functional Roles

Publisher Summary The properties of the inflammatory response depend on the quality, intensity, and duration of the insult (e.g., microorganism, foreign molecule, trauma, burn, and infarct), as well as on the individual and the affected tissue. Moreover, an inflammatory process could be acute or chronic and it is mediated chiefly by the innate or the specific immune system. The main components of innate immunity are physical and chemical barriers (e.g., epithelia and antimicrobial substances), blood proteins (e.g., complement factors), phagocytic cells (e.g., neutrophils and macrophages), and other leukocytes (e.g., natural killer cells). On the other hand, the principal components of the specific immunity are humoral (antibodies) and cellular (CD4+T cells). The specific immune response amplifies the mechanism of innate immunity and enhances their function, particularly upon repeated exposures to the same foreign antigen. Inflammation is a progressive process that shows overlapping phases. Whereas the acute unspecific response is characterized by hernodynamic, metabolic, and cellular changes, the specific response begins with the recognition of the antigen by specific lymphocytes, followed by their proliferation and differentiation into effector cells.