Drugs that block calmoduLin activity inhibit cell-to-cell coupling in the epidermis of Tenebrio molitor

Role of Tunneling Nanotubes in Viral Infection, Neurodegenerative Disease, and Cancer

The network of tunneling nanotubes (TNTs) represents the filamentous (F)-actin rich tubular structure which is connected to the cytoplasm of the adjacent and or distant cells to mediate efficient cell-to-cell communication. They are long cytoplasmic bridges with an extraordinary ability to perform diverse array of function ranging from maintaining cellular physiology and cell survival to promoting immune surveillance. Ironically, TNTs are now widely documented to promote the spread of various pathogens including viruses either during early or late phase of their lifecycle. In addition, TNTs have also been associated with multiple pathologies in a complex multicellular environment. While the recent work from multiple laboratories has elucidated the role of TNTs in cellular communication and maintenance of homeostasis, this review focuses on their exploitation by the diverse group of viruses such as retroviruses, herpesviruses, influenza A, human metapneumovirus and SARS CoV-2 to promote viral entry, virus trafficking and cell-to-cell spread. The later process may aggravate disease severity and the associated complications due to widespread dissemination of the viruses to multiple organ system as observed in current coronavirus disease 2019 (COVID-19) patients. In addition, the TNT-mediated intracellular spread can be protective to the viruses from the circulating immune surveillance and possible neutralization activity present in the extracellular matrix. This review further highlights the relevance of TNTs in ocular and cardiac tissues including neurodegenerative diseases, chemotherapeutic resistance, and cancer pathogenesis. Taken together, we suggest that effective therapies should consider precise targeting of TNTs in several diseases including virus infections.

Calmodulin-mediated gating of lens gap junction channels in vesicles

The fiber cells of eye lens communicate directly with each other by exchanging ions, dyes and metabolites. In most tissues this type of communication (cell coupling) is mediated by gap junctions. In the lens, the fiber cells are extensively interconnected by junctions. However, lens junctions, although morphologically similar to gap junctions, differ from them in a number of structural, biochemical and immunological features. Like gap junctions, lens junctions are regions of close cell-to-cell apposition. Unlike gap junctions, however, the extracellular gap is apparently absent in lens junctions, such that their thickness is approximately 2 nm smaller than that of typical gap junctions (Fig. 1,c). In freeze-fracture replicas, the particles of control lens junctions are more loosely packed than those of typical gap junctions (Fig. 1,a) and crystallize, when exposed to uncoupling agents such as Ca++, or H+, into pseudo-hexagonal, rhombic (Fig. 1,b) and orthogonal arrays with a particle-to-particle spacing of 6.5 nm. Because of these differences, questions have been raised about the interpretation of the lens junctions as communicating junctions, in spite of the fact that they are the only junctions interlinking lens fiber cells.

Calmodulin-Mediated Regulation of Gap Junction Channels

Evidence that neighboring cells uncouple from each other as one dies surfaced in the late 19th century, but it took almost a century for scientists to start understanding the uncoupling mechanism (chemical gating). The role of cytosolic free calcium (Ca2+i) in cell-cell channel gating was first reported in the mid-sixties. In these studies, only micromolar [Ca2+]i were believed to affect gating-concentrations reachable only in cell death, which would discard Ca2+i as a fine modulator of cell coupling. More recently, however, numerous researchers, including us, have reported the effectiveness of nanomolar [Ca2+]i. Since connexins do not have high-affinity calcium sites, the effectiveness of nanomolar [Ca2+]i suggests the role of Ca-modulated proteins, with calmodulin (CaM) being most obvious. Indeed, in 1981 we first reported that a CaM-inhibitor prevents chemical gating. Since then, the CaM role in gating has been confirmed by studies that tested it with a variety of approaches such as treatments with CaM-inhibitors, inhibition of CaM expression, expression of CaM mutants, immunofluorescent co-localization of CaM and gap junctions, and binding of CaM to peptides mimicking connexin domains identified as CaM targets. Our gating model envisions Ca2+-CaM to directly gate the channels by acting as a plug ("Cork" gating model), and probably also by affecting connexin conformation.

Chlorpromazine reduces the intercellular communication via gap junctions in mammalian cells

In the work presented herein, we evaluated the effect of chlorpromazine (CPZ) on gap junctions expressed by two mammalian cell types; Gn-11 cells (cell line derived from mouse LHRH neurons) and rat cortical astrocytes maintained in culture. We also attempted to elucidate possible mechanisms of action of CPZ effects on gap junctions. CPZ, in concentrations comparable with doses used to treat human diseases, was found to reduce the intercellular communication via gap junctions as evaluated with measurements of dye coupling (Lucifer yellow). In both cell types, maximal inhibition of functional gap junctions was reached within about 1 h of treatment with CPZ, an recovery was almost complete at about 5 h after CPZ wash out. In both cell types, CPZ treatment increased the phosphorylation state of connexin43 (Cx43), a gap junction protein subunit. Moreover, CPZ reduced the reactivity of Cx43 (immunofluorescence) at cell interfaces and concomitantly increased its reactivity in intracellular vesicles, suggesting an increased retrieval from and/or reduced insertion into the plasma membrane. CPZ also caused cellular retraction reducing cell-cell contacts in a reversible manner. The reduction in contact area might destabilize existing gap junctions and abrogate formation of new ones. Moreover, the CPZ-induced reduction in gap junctional communication may depend on the connexins (Cxs) forming the junctions. If Cx43 were the only connexin expressed, MAPK-dependent phosphorylation of this connexin would induce closure of gap junction channels.

Chemical gating of gap junction channels; roles of calcium, pH and calmodulin

Both Ca(2+) and H(+) play a role in chemical gating of gap junction channels, but, with the possible exception of Cx46 hemichannels, neither of them is likely to induce gating by a direct interaction with connexins. Some evidence suggests that low pH(i) affects gating via an increase in [Ca(2+)](i); in turn, Ca(2+) is likely to induce gating by activation of CaM, which may act directly as a gating particle. The effective concentrations of both Ca(2+) and H(+) vary depending on cell type, type of connexin expressed and procedure employed to increase their cytosolic concentrations; however, pH(i) as high as 7.2 and [Ca(2+)](i) as low as 150 nM or lower have been reported to be effective in some cells. Some data suggest that Ca(2+) and H(+) affect gating by acting synergistically, but other data do not support synergism. Chemical gating follows the activation of a slow gate distinct from the fast V(j)-sensitive gate, and there is evidence that the chemical/slow gate is V(j)-sensitive. At the single channel level, the chemical/slow gate closes the channels slowly and completely, whereas the fast V(j) gate closes the channels rapidly and incompletely. At least three molecular models of channel gating have been proposed, but all of them are mostly based on circumstantial evidence.

Localization of a centrin-like protein to higher plant plasmodesmata

Antibodies against centrin, the ubiquitous calcium-binding contractile protein, recognized a 17 kDa protein in extracts of onion root tips and cauliflower florets. Using immunofluorescence microscopy, anti-centrin antibodies were localized to the developing cell plate of onion and cauliflower root tip cells. In cauliflower florets, these antibodies localized to the walls in a punctate manner, consistent with the distribution of plasmodesmata as shown by colocalization with callose. Anti-centrin antibodies were localized to plasmodesmata of onion root tips and cauliflower florets with immunogold electron microscopy. Furthermore, this label was concentrated around the necks of plasmodesmata. In contrast, an antibody against calmodulin, which is a closely related calcium-binding protein, did not label plasmodesmata. We propose that centrin is a component of calcium-sensitive contractile nanofilaments in the neck region of plasmodesmata and facilitates the calcium-induced regulation of intercellular transport.

Connexin 32 of gap junctions contains two cytoplasmic calmodulin-binding domains

A fluorescent calmodulin derivative, 2-chloro-[4-(epsilon-amino-Lys75)]-[6-(4- diethylaminophenyl)-1,3,5-triazin-4-yl]-calmodulin (TA-calmodulin) [Török and Trentham (1994) Biochemistry 33, 12807-12820], and equilibrium fluorescence methods were used to identify calmodulin-binding domains of connexin subunits of gap junctions. Synthetic peptides corresponding to six extramembrane regions of connexin 32, a major component of rat liver gap junctions, and peptides derived from connexin 43 and 26, were tested. Two cytoplasmically oriented peptides that correspond to an N-terminal 21-amino-acid sequence and a 15-amino-acid sequence at the C-terminal tail of connexin 32 bound TA-calmodulin in a Ca2+-dependent manner. The dissociation constants (Kd) of TA-calmodulin binding to GAP 10 (MNWTGLYTLLSGVNRHSTAIG, residues 1-21) and GAP 8M (ACARRAQRRSNPPSR, residues 216-230) were 27 nM and 1.2 microM respectively at 150 mM ionic strength, 2 mM MgCl2, 100 microM CaCl2, pH 7.0 and 21 degrees C. Both halves of each peptide were required for calmodulin binding. Substitution of Trp3 present in all connexins by Tyr increased Kd for TA-calmodulin by 40-fold. Liver gap junctions (whose connexons contain mainly connexin 32) and recombinant connexons constructed of connexin 26 expressed by baculovirus-infected insect cells exhibited weaker binding of TA-calmodulin with variable Ca2+-dependence. These studies identify two calmodulin-binding amino-acid sequences in connexin 32, and provide independent evidence that calmodulin may function as an intracellular ligand, regulating Ca2+-dependent intercellular communication across gap junctions.

Mammalian lens inter-fiber resistance is modulated by calcium and calmodulin

The relationship between Ca2+ and lens fiber cell communication was investigated in the isolated intact rat lens by using radiotracer and electrophysiological techniques. The lens internal calcium was increased by adding the SH oxidant diamide (1 mM), by incubating in a sodium-free (n-methylglucamine) solution or by increasing external calcium from 1 to 10 mM. A 12 hours incubation in diamide produced a ten-fold increase in 45Ca uptake into the lens which was accompanied by a ten-fold increase in internal resistance. Incubation in Na-free solution or in 10 mM Ca2+ both produced a 5-fold increase in 45Ca content, while the increase in internal resistance was five and six fold respectively. This uncoupling was prevented in the diamide and Na-free treated lenses by omitting Ca2+ from the incubation medium. Fiber cell uncoupling was noticed in each of these experimental conditions after approximately 5 hours incubation, and good recovery was obtained in the high calcium solution if the stress was removed. The calmodulin antagonists calmidazolium (3 microM) and W7 (100 microM) both prevented uncoupling in the high calcium solution, provided there was a 2 hours preincubation period in calcium-free solution containing antagonist before the stress was applied. These data indicate that lens fiber cell communication is required by Ca2+ and calmodulin.

The arthropod gap junction and pseudo-gap junction: isolation and preliminary biochemical analysis

The hepatopancreas of the crayfish, Procambarus clarkii, contains an unusual abundance of gap junctions, suggesting that this tissue might provide an ideal source from which to isolate the arthropod-type of gap junction. A membrane fraction obtained by subcellular fractionation of this organ contained smooth septate junctions, zonulae adhaerentes, gap junctions and pentalaminar membrane structures (pseudo-gap junctions) as determined by electron microscopy. A further enrichment of plasma membranes and gap junctions was achieved by the use of linear sucrose gradients and extraction with 5 mM NaOH. The enrichment of gap junctions correlated with the enrichment of a 31 Kd protein band on polyacrylamide gels. Extraction with greater than or equal to 20 mM NaOH or greater than or equal to 0.5% (w/v) Sarkosyl NL97 resulted in the disruption and/or solubilization of gap junctions. Negative staining revealed a uniform population of 9.6 nm diameter subunits within the gap junctions with an apparent sixfold symmetry. Using antisera to the major gap junctional protein of rat liver (32 Kd) and to the lens membrane protein (MP 26), we failed to detect any homologous antigenic components in the arthropod material by immunoblotting-enriched gap junction fractions or by immunofluorescence on tissue sections. The enrichment of another membrane structure (pseudo-gap junctions), closely resembling a gap junction, correlated with the enrichment of two protein bands, 17 and 16 Kd, on polyacrylamide gels. These structures appeared to have originated from intracellular myelin-like figures in phagolysosomal structures. They could be distinguished from gap junctions on the basis of their thickness, detergent-alkali insolubility, and lack of association with other plasma membrane structures, such as the septate junction. Pseudo-gap junctions may be related to a class of pentalaminar contacts among membranes involved in intracellular fusion in many eukaryotic cell types. We conclude that pseudo-gap junctions and gap junctions are different cellular structures, and that gap junctions from this arthropod tissue are uniquely different from mammalian gap junctions of rat liver in their detergent-alkali solubility, equilibrium density on sucrose gradients, and protein content (antigenic properties).

Calmodulin-like proteins and communicating junctions. Electrical uncoupling of crayfish septate axons is inhibited by the calmodulin inhibitor W7 and is not affected by cyclic nucleotides

The effects of W7, a calmodulin (CaM)-inhibitor, and cyclic nucleotides on electrical coupling and uncoupling are studied in crayfish lateral giant axons (septate axons). The septate axons provide a relatively simple two cell system in which both surface membrane and junctional resistance can be measured independently. Four microelectrodes are inserted into a septate axon, two on each side of the septum. Hyperpolarizing current pulses (150 nA) are injected alternatively in the caudal and rostral axon segment and the resulting electrotonic potentials are recorded. The axons are uncoupled at regular intervals by superfusing them with acetate-containing saline solution (pH 6.3) in the presence or absence of W7 (50-100 microM) or, as a control, its nonchlorinated form (W5). W7 strongly inhibits the acetate-induced increased in junctional resistance, while W5 is ineffective. The uncoupling inhibition does not appear to be caused by an increase in cyclic nucleotide concentration, because in preliminary experiments exposure to db-cAMP or db-cGMP (up to 1 mM) does not seem to influence either the basic values of Rj or their changes with acetate. The data confirm previous evidence for a participation of CaM-like proteins in cell-to-cell channel gating.

Metabolic cooperation in vitro: differential ability of ouabain to uncouple normal, preneoplastic, and neoplastic mouse mammary cells

We utilized two assays for metabolic cooperation in vitro, one in which cells were grown in monolayer and one in which the cells formed three-dimensional structures in a collagen gel matrix. Both assays required one of the test cell pair to be resistant both to ouabain and to thioguanine (deficient in hypoxanthine-guanine phosphoribosyltransferase). Normal mammary gland cells, cells from preneoplastic mouse hyperplastic alveolar nodules, and mouse mammary tumor cells were metabolically linked in vitro to the drug-resistant tumor cells. Ouabain abrogated communication between tumor cells and normal mammary gland cells and between tumor cells and preneoplastic cells but had no effect on communication between tumor cells.

Lens junctions are communicating junctions

Lens fibers are electrically coupled with each other and directly exchange dyes and metabolites. In most cells, this form of communication is mediated by gap junctions. Lens fibers lack typical gap junctions. The lens junctions, although morphologically similar to gap junctions, differ from them structurally, chemically and immunologically. Nevertheless, recent evidence suggests that indeed lens junctions are communicating junctions. The lens junction protein, MIP26, displays structural characteristics similar to other channel proteins. Once incorporated into liposomes it forms channels permeable to molecules as heavy as 1.5 kDa. Like other communicating junctions, lens junctions assume crystalline arrays and uncouple with Ca++. The liposome incorporated channels close with Ca++ and H+ in the presence of calmodulin (CaM). Partial loss of gating competency occurs after proteolytic cleavage of the C-terminal arm of MIP26. The need for a unique type of communicating junction in lens is unclear. A possibility is that this tissue has some special cell-to-cell transport requirements, in terms of size and/or charge of permeants, not shared by coupled cells of other tissues.

Permeability and gating of lens gap junction channels incorporated into liposomes

The lens junction protein (MIP26), and its trypsin cleavage product (MIP21), isolated from calf fiber cells, are incorporated into liposomes and the permeability and gating of the resulting channels are studied spectrophotometrically by an osmotic swelling assay. Liposomes incorporated with either protein and loaded with Dextran T-10 swell when placed in isotonic or hypertonic KCl, sucrose or polyethyleneglycol (PEG), indicating the presence of channels permeable to molecules as large as MW 1500. In the absence of calmodulin (CaM), the permeability of either MIP26 or MIP21 channels is not altered by Ca++. On the contrary, MIP26-CaM channels reversibly close in the presence of Ca++ (10(-5)M). Preliminary experiments show channel closure with lowered pH (5.5) as well. While MIP26-CaM channels close to all the permeants tested, MIP21-CaM channels close only partially with Ca++, becoming impermeable to large probes (PEG) while remaining permeable to sucrose and KCl. This indicates that the trypsin-cleaved C-terminal arm of MIP26 is the channel gate. Evidence from spectrophotofluorometry and circular dichroism spectroscopy indicates that activated CaM changes the conformation of isolated MIP26, suggesting that channel occlusion could result from a change in protein configuration.

Rates of diffusion of fluorescent molecules via cell-to-cell membrane channels in a developing tissue

Diffusion coefficients for the intercellular movement of fluorescent tracers have been measured in the epidermis of a larval beetle. Fluorescent tracer was injected into a cell and the spread of tracer from cell to cell in this monolayer was recorded by a TV camera. Fluorescence intensities were digitized from the TV images at successive times after the start of injection at various distances from the source by a microcomputer interfaced with a video analyzer. From the relationship between concentration (measured as light intensity), time and distance, an effective diffusion coefficient (De) is calculated for the tracer in the tissue. In newly ecdysed epidermis, De for carboxyfluorescein (CF) is 2.7 X 10(-7) cm2/s, and De for lissamine rhodamine B (LRB) is 1.2 X 10(-7) cm2/s, whereas in intermolt epidermis the De's for CF and LRB are 3.7 X 10(-7) and 1.2 X 10(-7) cm2/s, respectively. These diffusion coefficients are only an order of magnitude lower than their values in water. The ratio of De for the two tracers at these two stages of development differs from the ratio predicted in cytoplasm alone, with the movement of the slightly larger molecule (LRB) being impeded relative to that of the smaller molecule (CF). This suggests that the properties of the membrane channels amplify differences in the rates of movement of molecules of similar size. This may be important during cell patterning in development. De for CF was also monitored as junctional resistance was increased in the epidermis. During 30 min of exposure to 0.25 mM chlorpromazine, De dropped to 20% of its initial value of 5 X 10(-7) cm2/s, implying that the junctional membrane, rather than cytoplasm, is the major barrier to molecular diffusion among the cells.

Interaction of calmodulin and other calcium-modulated proteins with mammalian and arthropod junctional membrane proteins

Calmodulin and other calcium-modulated proteins bind in vitro to purified junctional polypeptides from rat liver gap junctions, bovine lens fiber junctions, a chymotryptic fragment from bovine lens junctions, and crayfish hepatopancreas gap junctions. The potential biological relevance of the interaction of calmodulin with junctional proteins is suggested by immunocytochemical localization of endogenous calmodulin in cortical regions of the cell where gap junctions exist. These observations provide a molecular basis for understanding the potential regulatory role of calmodulin on cell-cell communication channels in vivo. In addition, the calmodulin binding represents the first molecular homology that has been found for junctional channel proteins from mammalian and arthropod tissues.

Filipin-cholesterol complexes in plasma membranes and cell junctions of Tenebrio molitor epidermis

The polyene antibiotic filipin combines with cholesterol in membranes to form complexes that are readily identifiable in the electron microscope. The distribution of filipin-cholesterol (FC) complexes is most easily studied by freeze-fracture. Larval epidermis of Tenebrio molitor (Insecta, Coleoptera) was maintained in vitro for 48 hr, since the electrophysiological properties of the cells are best characterized under these conditions. The cells were fixed in buffered 3.0% glutaraldehyde at RT for 15 min, transferred to fresh fixative containing 1% DMSO and filipin (final concentration; 0.5 mg/ml) for 3 hr RT. Control cells were treated in fixative containing 1% DMSO only. In freeze fracture replicas, FC complexes appear on the plasma membrane as large circular protrusions measuring 26.5 +/- 6.8 nm (x +/- s.d.) n = 50, in diameter and 17.1 +/- 2.8 nm, n = 50, in height and 11.7 +/- 2.6 nm, n = 25, in depth. Protrusions are about two times more frequent on the E face while pits are several times more frequent on the P face. FC complexes are most abundant (greater than 50/mu m2) on the basal membrane surface of the cells but are excluded from regions of hemidesmosomal plaques that anchor the cells to the basal lamina. FC complexes are also abundant on the apical surfaces of the cells where cuticle secretion occurs. In the lateral regions below the junctional belt, FC complexes are less numerous but often appear to increase in frequency in a graded fashion away from the junctional region. The septate junctions are relatively free of FC complexes except in regions where they open to form islands. These islands often contain gap junctions but the FC complexes rarely invade the particle domains of the gap junctions. Single FC complexes were seen in three out of a total of 97 gap junctions. Exposure of the epidermis to 20-hydroxyecdysone for 24 hr in vitro did not induce the appearance of FC complexes within the cell junctions.

Effects of the calmodulin inhibitor, trifluoperazine, on membrane potentials and slow action potentials of cultured heart cells

The effects of an inhibitor of calmodulin, trifluoperazine (TFP), were determined on the electrical activity of cultured cell reaggregates derived from chick embryonic hearts (15-day-old). The cells exhibited naturally occurring slowly rising action potentials (APs) having a maximum rate of rise (+Vmax) of less than 35 V/s. After superfusion with 100 microM TFP, the maximal diastolic potential (MDP) decreased, within 30 min, from -66.0 to -55.5 mV. The frequency of discharge decreased, and there was also a decrease in AP amplitude and in +Vmax (from 10.0 to 4.9 V/s). By 90 min, all spontaneous activity had stopped, and the resting potential was about -10 mV. Input resistance increased, consistent with a decrease in K+ conductance. Hyperpolarization by current pulses did not allow the production of APs upon electrical stimulation, suggesting that the TFP blocks slow inward current (Isi). No recovery occurred upon washout (up to 48 h). Higher concentrations of TFP (200-500 microM), or injection of the inhibitor intracellularly be means of phosphatidylcholine liposomes, accelerated the time course of the blockade (e.g. within 15 min). In fresh (non-cultured) chick ventricle with fast-rising APs, TFP (400 microM) caused excitation-contraction uncoupling within 10 min, presumably by blocking the slow Ca2+ channels; the the fast APs were depressed (+Vmax) within 45 min, before any depolarization occurred. The cells became completely depolarized (Em congruent to -4 mV) by 195 min; hyperpolarization by current pulses did not allow the production of APs, suggesting that the fast Na+ channels were blocked.(ABSTRACT TRUNCATED AT 250 WORDS)

Communicating junctions and calmodulin: inhibition of electrical uncoupling in Xenopus embryo by calmidazolium

This paper reports the inhibitory effects of calmidazolium (CDZ), a calmodulin inhibitor, on electrical uncoupling by CO2. Membrane potential and coupling ratio (V2/V1) are measured in two neighboring cells of Xenopus embryos (16 to 64 cell stage) for periods as long as 5.5 hr. Upon exposure to 100% CO2, control cells consistently uncouple even if the CO2 treatments are repeated every 15 min for 2.5 hr. CDZ (5 X 10(-8) - 1 X 10(-7) M) strongly inhibits uncoupling. The inhibition starts after 30, 50 and 60 min of treatment with 1 X 10(-7), 7 X 10(-8) and 5 X 10(-8) M CDZ, respectively, is concentration-dependent and partially reversible. In the absence of CO2, CDZ also improves electrical coupling. CDZ has no significant effect on membrane potential and nonjunctional membrane resistance. These data suggest that calmodulin or a calmodulin-like protein participates in the uncoupling mechanism.