Tyrosine phosphorylation of a gap junction protein correlates with inhibition of cell-to-cell communication.

Cell-to-cell communication is achieved by passage of small molecules through gap junction membrane channels. The expression of the transforming gene from Rous sarcoma virus, v-src, induces a rapid and dramatic reduction in cell-to-cell communication in cultured cells. To determine whether connexin43, a major gap junction protein expressed in fibroblasts, is a target for the v-src protein tyrosine kinase activity, we examined the phosphorylation state of connexin43 in cells expressing variants of src. Using an antipeptide serum that recognizes connexin43, we demonstrate that this protein is phosphorylated on serine and tyrosine residues in avian and mammalian cells expressing activated src proteins. Connexin43 from control cells and cells expressing nonactivated variants of the src protein was phosphorylated solely on serine residues. In lysates from v-src-transformed cells, all phosphorylated connexin43 molecules were cleared from the lysate by sequential immunoprecipitations using the phosphotyrosine antibodies, suggesting that each molecule of phosphorylated connexin43 contains both phosphoserine and phosphotyrosine. We have also examined junctional permeability in cells expressing src variants and find that loss of cell-to-cell communication correlates with tyrosine phosphorylation of connexin43.

Junctional intercellular communication is cooperatively inhibited by oncogenes in transformation.

We examined the actions of the cellular src (c-src) and adenovirus E1A genes on junctional cell-to-cell communication. Neither gene causes complete transformation of NIH3T3 cells on its own, but the two do so in conjunction with one another. This cooperation goes hand in hand with summation of the actions of the two genes on junctional communication: junctional permeability is reduced when the cells are transfected with either gene; it is reduced significantly more when they are transfected with both. This cooperative loss of communication approaches the noncooperative loss induced by the viral src gene (v-src), chimeric c-src/v-src, or Tyr527-mutant c-src--genes that cause transformation on their own. This provides a rationale for the hitherto unexplained complementation of the two oncogenes in carcinogenesis; it is the expected behavior if the loss of communication is causal in the decontrol of growth in transformation.

The cellular src gene product regulates junctional cell-to-cell communication.

Overexpression of the cellular src gene in NIH 3T3 cells causes reduction of cell-to-cell transmission of molecules in the 400- to 700-dalton range. This down-regulation of gap junctional communication correlates with the activity of the gene product, the protein tyrosine kinase pp60c-src. The down-regulation was enhanced by point mutation of Tyr527 (a site that is phosphorylated in pp60c-src and that inhibits kinase activity) or by substitution of the viral-src for the cellular-src carboxyl-terminal coding region. Mutation of Tyr416 (a site phosphorylated upon Tyr527 mutation) suppresses both the down-regulation of communication by Tyr527 mutation and that by gene overexpression. The regulation of communication by src may be important in the control of embryonic development and cellular growth.

Polyomavirus middle T antigen downregulates junctional cell-to-cell communication.

We examined the effect of polyomavirus middle T antigen on cell-to-cell communication in rat F cells transfected with an inducible middle T recombinant DNA or infected with a conditional mutant virus. Junctional permeability fell (reversibly) when middle T transcription was induced or when middle T was switched to the transformation+ form. The effect correlates with the rise of protein tyrosine kinase activity.

Tropomyosin in peripheral ruffles of cultured rat kidney cells.

Tropomyosin distribution has been studied in two normal lines and one transformed line of rat kidney cells during the early phases of substrate attachment and growth. One non-motile normal line, which spreads rapidly after attachment, immediately begins to assemble prominent stress fibers that contain tropomyosin. It displays small peripheral ruffles that are not noticeably stained with anti-tropomyosin. The other normal line is motile and produces large ruffles that are brightly stained with anti-tropomyosin. Large numbers of tropomyosin-positive stress fibers assemble only after the cells stop moving and lose the peripheral ruffles. The transformed line does not assemble stress fibers but does contain large numbers of actin filament bundles in ruffles on the cell surface that are stained with anti-tropomyosin. These observations indicate that cytoskeletal tropomyosin is not restricted in distribution to stress fibers, and may undergo re-organization along with actin during the transition from motile to non-motile behavior.

Cyclic AMP effects on cell-to-cell junctional membrane permeability during adipocyte differentiation of 3T3-L1 fibroblasts.

Mouse 3T3-L1 fibroblast cells, also know as preadipocytes, differentiate in vitro into adipocytes when treated with promoting agents and acquire numerous properties characteristic of mature fat cells. We studied junctional cell-to-cell communication by measuring the incidence of electrical coupling and transfer of carboxy-fluorescein among these cells. When 3T3-L1 cells were induced to differentiate into adipocytes, they lost virtually all cell-cell communication. Preadipocytes that remained nondifferentiated after the treatment maintained normal communication. Loss of communication in the adipocytes invariably coincided with appearance of lipid droplets and not with other phenotypic changes. In the differentiating cells, loss of cell-to-cell communication and lipid accumulation was prevented if dibutyryl cyclic AMP and caffeine were present in the culture medium. Addition of dibutyryl cyclic AMP and caffeine to already differentiated adipocytes resulted in loss of lipid and simultaneously improved junctional permeability. The results demonstrate that in the in vitro 3T3-L1 cell system, (a) cell-to-cell communication and lipid synthesis are intimately related during the adipose conversion and (b) cAMP affects the expression of the two phenotypes.

Translation and functional expression of cell-cell channel mRNA in Xenopus oocytes.

mRNA from estrogen-stimulated rat myometrium, a tissue known to upregulate cell-cell channels in response to this hormone, was microinjected into Xenopus laevis oocytes. The oocytes had been freed from covering layers of follicle cells and vitelline to allow direct cell membrane interactions when paired. About 4 hours after the mRNA injection, paired oocytes become electrically coupled. This coupling was due to the presence of typical cell-cell channels characterized by size-limited intercellular tracer flux, the presence of gap junctions at the oocyte-oocyte interface, and the reversible uncoupling that occurred in the presence of carbon dioxide. The induction of new cell-cell channels in the oocyte membrane was observed against a zero background or a low level of endogenous coupling, depending on the maturation stage of the oocytes. The time course of development of cell-cell coupling after the microinjection of mRNA was determined. The mRNA capable of inducing cell-cell coupling was confined to an intermediate size class when fractionated on a sucrose gradient.

Intercellular communication and the control of growth: X. Alteration of junctional permeability by the src gene. A study with temperature-sensitive mutant Rous sarcoma virus.

To study changes of junctional membrane permeability associated with transformation, the junctions and the nonjunctional membranes of quail embryo-, chick embryo- and mouse-3T3 cell cultures, infected with temperature-sensitive mutant Rous sarcoma virus, were probed with fluorescent-labelled glutamate. Junctional permeability fell in the transformed state. In the quail cells, the fall was detectable within 25 min of shifting the temperature down to the level (permissive) at which tyrosine-phosphorylation by the viral src gene product is expressed. This reduction of junctional permeability is one of the earliest manifestations of viral transformation. Normal permeability was restored within 30 min of raising the temperature to the nonpermissive level, a reversibility that could be displayed several times during the span of a cell generation. The reversal seems to reflect a reopening of cell-to-cell channels rather than a synthesis of new ones; it is not blocked by protein-synthesis inhibition. Treatments with cyclic AMP and phosphodiesterase inhibitor or with forskolin, which stimulate serine and threonine phosphorylation--the type of phosphorylation on which normal junctional permeability depends (Wiener & Loewenstein, 1983, Nature 305:433)--did not abolish, in general, the junctional effect of the virus; src tyrosine-phosphorylation apparently overrides the junctional upregulation mediated by cyclic AMP. Nonjunctional membrane permeability was not sensibly affected by the virus. It was affected, however, by temperature: lowering the temperature from the nonpermissive to the permissive level caused the nonjunctional permeability to fall, and vice versa. This change was unrelated to transformation. Its secondary effect on junctional transfer is in the opposite direction to that produced by the temperature-activated viral transformation.

Intercellular communication and the control of growth: XI. Alteration of junctional permeability by the src gene in a revertant cell with normal cytoskeleton.

To learn whether the reduction of cell-to-cell communication in transformation is a possible primary effect of pp60src phosphorylation or secondary to a cytoskeletal alteration, we examined the junctional permeability in transformed cells with normal cytoskeleton. The permeability to fluorescent-labelled mono- and diglutamate was compared in clones of Faras' vole cells--clones transformed by Rous sarcoma virus and reverted from that transformation. One revertant clone (partial revertant), had the high level of pp60src kinase activity and tumorigenicity of the fully transformed parent clone, but had lost the cytoskeletal alterations of that clone. Another revertant clone (full revertant) had lost the tumorigenicity and most of the pp60src kinase activity, in addition (J.F. Nawrocki et al., 1984, Mol. Cell Biol. 4:212). The junctional permeability of the partial revertant with normal cytoskeleton was similar to that of the fully transformed parent clone with abnormal cytoskeleton. The permeabilities of both were lower than those of the full revertant and the normal uninfected cell, demonstrating that the junctional change by the src gene is independent of the cytoskeletal one.

Intercellular communication and the control of growth: XII. Alteration of junctional permeability by simian virus 40. Roles of the large and small T antigens.

We studied the action of temperature-sensitive mutant simian virus 40--a transformation-inducing DNA virus--on the junctional permeability to mono-, di- and triglutamate in rat embryo-, pancreas islet (epithelial)-, and 10T1/2 cell cultures. Junctional permeability was reduced (reversibly) in the transformed state. To dissect the genetics of this alteration, we used two kinds of mutant virus DNA. One kind had a temperature-sensitive mutation on the A gene, rendering the large T antigen (the gene product) thermolabile (T+ in equilibrium T-). The other had a deletion on the F gene, in addition, abolishing (permanently) the expression of the little t addition (t-). The junctional alteration occurred in the condition T+ t+, but not in the conditions T- t+, T+ t- or T- t-. Both antigens, thus, are necessary for this junctional alteration--a genetic requirement identical to that for decontrol of growth (but distinct from that of the cytoskeletal alteration).

Induction of cell--cell channel formation by mRNA.

Intercellular junctional communication is very common in normal organized tissue. It provides a pathway for transmission of electrical signals, especially in heart muscle, and may be important in differentiation and growth control. The hydrophilic channels which enable cell--cell communication have been well characterized by biophysical methods, and there is now good evidence that they are contained in the nexus (gap junctions). Little, however, is known about the molecular mechanism of biosynthesis of junctional channels. Knowledge in this area has been obtained almost exclusively from experiments with reaggregated cells, a system complicated by the fact that de novo synthesis of channel proteins is obscured by reassembly of pre-existing subunits or utilization of precirsors. To avoid these problems, we have now isolated mRNA from cells that are in the process of making new intercellular nexus with high efficiency, incorporated it via liposomes into communication-defective cells and have shown that the recipient cells established junctional communication.

Cell junction and cycle AMP: III. Promotion of junctional membrane permeability and junctional membrane particles in a junction-deficient cell type.

The cyclic nucleotide effect on junction was studied in C1-1D cells, a mouse cancer cell type that fails to make permeable junctions in ordinary confluent culture. Upon administration of cyclic AMP, dibutyryl cyclic AMP, dibutyryl cyclic AMP plus caffeine (db-cAMP-caffeine), or cholera toxin (an adenylate cyclase activator), the cells acquired permeable junctions; they became electrically coupled and transferred fluorescent tracer molecules among each other - a transfer exhibiting the molecular size limit of permeation of normal cell-to-cell channels. The effect took several hours to develop. With the db-cAMP-caffeine treatment, junctional permeability emerged within two hours in one-fifth of the cell population, and within the next few hours in the entire population. This development was not prevented by the cytokinesis inhibitor cytochalasin B. Permeable junctions formed also in two other conditions where the cell-endogenous cyclic AMP level may be expected to increase: serum starvation and low cell density. After three weeks of starving, the cells of serum, a junctional permeability arose in confluent cultures, which on feeding with serum disappeared within two to three days. At low cell density, namely below confluency, the cells made permeable junctions, unstarved. In cultures of rather uniform density, the frequency of permeable junctions was inversely related to the average density, over the subconfluent range; at densities of about 1 X 10(4) cells/cm2, where the cells had few mutual contacts, 80% of the pairs presumed to be in contact were electrically coupled. In cultures with adjoining territories of high (confluent) and low cell density, there was coupling only in the last, and in this low-density state the cells were also capable of coupling with other mammalian cell types (mouse 3T3-BalbC and human Lesch-Nyhan cells).

De novo construction of cell-to-cell channels.

Nexus (gap junctions), which are considered to contain cell-to-cell channels, are newly formed in uterine smooth muscle during parturition or in response to estrogen treatment of virginal animals. A mRNA preparation was isolated from estrogen-dominated rat myometria and was encapsulated into liposomes. Subsequently the liposomes were fused with cultured cells of a mouse cell line CL-1D. It is established that these tumor cells normally are neither electrically coupled nor do they contain nexus. The cells, however, become electrically coupled a few hours after being loaded with the mRNA preparation. This de novo expression of cell coupling persisted for a litte more than 24 hr after a single loading procedure. Freeze-fracture electron microscopy revealed small nexus-like particle aggregates at the time coupling was present. In control experiments the cells remained noncoupling when the RNA preparation was pretreated with ribonuclease, when cycloheximide was applied to the cells, or when liposomes filled with buffer solution only were used. These data suggest that the de novo expression of cell-to-cell coupling is accomplished by mRNA-induced protein biosynthesis resulting in the formation of cell-to-cell channels.

Intercellular communication and tissue growth: IX. Junctional membrane structure of hybrids between communication-competent and communication-incompetent cells.

The structure of the membrane junctions of the hybrid cell system, examined in the companion paper in respect to competence for communication through cell-to-cell membrane channels, is here examined by freeze-fracture electron microscopy. The junctions of the channel-competent parent cell and of the channel-competent hybrid cells present aggregates of intramembranous particles typical of "gap junction"; those of the channel-incompetent parent cell and channel-incompetent segregant hybrid cells do not. Competence for junctional communication and for gap junction formation are genetically related. The junctions of the intermediate hybrid cells with incomplete channel-competence (characterized by cell-to-cell transfer of small inorganic ions but not of fluorescein), present special intramembranous fibrillar structures instead of discrete gap-junctional particles. The possibility that these structures may constitute coupling elements with subnormal permeability is discussed in terms of incomplete dominance of the genetic determinants of gap junction.

Intercellular communication and tissue growth: VII. A cancer cell strain with retarded formation of permeable membrane junction and reduced exchange of a 330-dalton molecule.

A cancer (hepatoma) cell strain is described in which the formation of junctional membrane channels is abnormally slow. The development of electrical junctional coupling following the establishment of contact between these (reaggregated) cells is at least 15 times slower than that between their normal counterparts; and junctional transfer of fluorescein eventually develops, but only in about 5 per cent of the contacts (as against 100 per cent normally). This deviant membrane behavior is interpreted as a retardation in the process of accretion of junctional membrane channels. Its possible etiological role in defective growth regulation is discussed.

The role of divalent cations in activation of the sea urchin egg. I. Effect of fertilization on divalent cation content.

The Ca and Mg content of unfertilized sea urchin eggs (3 and 21 mumole/ml eggs) remains remarkably constant over periods of hours, even when the eggs are suspended in Ca- or Mg-free sea water. After fertilization the Ca content of eggs in regular sea water increases sharply by about 20%, followed by a decrease to the unfertilized level by 40 minutes. However, if the fertilized eggs are washed three minutes in Ca-free sea water a sharp decrease in the Ca content occurs amounting to 30% of the total in the first 40 minutes, with little change thereafter. Suspension of the eggs in Ca-free sea water results in an even greater loss of Ca amounting to about 43% of the total in the same time interval, followed by a continuing slow loss. It is concluded that fertilization initiates the intracellular release of Ca, which is then extruded. For unwashed eggs this change is masked by the simultaneous generation of new extra-cellular coats with high affinity for Ca. Changes in the Mg content of fertilized eggs follow the same general pattern except that absorption of this divalent cation to the extracellular coats is minimal.

Autotransplantation of retinal pigment epithelium in intravitreal diffusion chamber.

Retinal pigment epithelial (RPE) cells were autotransplanted intravitreally in diffusion chambers in rabbit eyes. The RPE cells underwent transformation; first into macrophages, later into spindle-shaped cells with collagen production having epithelial cell characteristics. DNA replication, shown by autoradiography, and loss of pigment granules indicated proliferation of these cells. These results support the hypothesis that RPE proliferation and transformation play a major role in the formation of collagen containing membranes, such as are found in massive periretinal proliferation.