Comparative analysis of the major polypeptides from liver gap junctions and lens fiber junctions

Gap junctions from rat liver and fiber junctions from bovine lens have similar septilaminar profiles when examined by thin-section electron microscopy and differ only slightly with respect to the packing of intramembrane particles in freeze-fracture images. These similarities have often led to lens fiber junctions being referred to as gap junctions. Junctions from both sources were isolated as enriched subcellular fractions and their major polypeptide components compared biochemically and immunochemically. The major liver gap junction polypeptide has an apparent molecular weight of 27,000, while a 25,000-dalton polypeptide is the major component of lens fiber junctions. The two polypeptides are not homologous when compared by partial peptide mapping in SDS. In addition, there is not detectable antigenic similarity between the two polypeptides by immunochemical criteria using antibodies to the 25,000-dalton lens fiber junction polypeptide. Thus, in spite of the ultrastructural similarities, the gap junction and the lens fiber junction are comprised of distinctly different polypeptides, suggesting that the lens fiber junction contains a unique gene product and potentially different physiological properties.     

Biochemical and immunological approaches to the study of gap junctional communication

Studies on gap junctions isolated from rat liver by a procedure that avoids exogenous proteolysis (Hertzberg, E. L.; Gilula. N. B.; J. Biol. Chem. 254: 2138-2147; 1979) are described. The original isolation procedure was modified to increase the yield and has been extended to the preparation of gap junctions from mouse and bovine liver. Peptide map studies showed that the 27,000-dalton polypeptides present in liver gap junction preparations from all three sources are homologous and are not derived from other polypeptides of higher molecular weight that are observed in cruder preparations. Similar studies with lens fiber junctions demonstrated no homology between liver and lens junction polypeptides. Antibodies to the lens junction polypeptides did not cross-react with the liver gap junction polypeptide, further supporting this conclusion.     

Antisera directed against connexin43 peptides react with a 43-kD protein localized to gap junctions in myocardium and other tissues

Rat heart and other organs contain mRNA coding for connexin43, a polypeptide homologous to a gap junction protein from liver (connexin32). To provide direct evidence that connexin43 is a cardiac gap junction protein, we raised rabbit antisera directed against synthetic oligopeptides corresponding to two unique regions of its sequence, amino acids 119-142 and 252-271. Both antisera stained the intercalated disc in myocardium by immunofluorescence but did not react with frozen sections of liver. Immunocytochemistry showed anti-connexin43 staining of the cytoplasmic surface of gap junctions in isolated rat heart membranes but no reactivity with isolated liver gap junctions. Both antisera reacted with a 43-kD polypeptide in isolated rat heart membranes but did not react with rat liver gap junctions by Western blot analysis. In contrast, an antiserum to the conserved, possibly extracellular, sequence of amino acids 164-189 in connexin32 reacted with both liver and heart gap junction proteins on Western blots. These findings support a topological model of connexins with unique cytoplasmic domains but conserved transmembrane and extracellular regions. The connexin43-specific antisera were used by Western blots and immunofluorescence to examine the distribution of connexin43. They demonstrated reactivity consistent with gap junctions between ovarian granulosa cells, smooth muscle cells in uterus and other tissues, fibroblasts in cornea and other tissues, lens and corneal epithelial cells, and renal tubular epithelial cells. Staining with the anti-connexin43 antisera was never observed to colocalize with antibodies to other gap junctional proteins (connexin32 or MP70) in the same junctional plaques. Because of limitations in the resolution of the immunofluorescence, however, we were not able to determine whether individual cells ever simultaneously express more than one connexin type.     

Analysis of the rat liver gap junction protein: clarification of anomalies in its molecular size

The major gap junction polypeptide in most tissues has an apparent molecular mass of 27 kDa with a 47 kDa dimer present in junction-enriched fractions. However, a 54 kDa protein recognized by gap junction-specific antibodies has been reported and a complementary DNA (cDNA) sequence for both human and rat liver gap junctions codes for a 32 kDa protein. In this paper we show that these are all forms of the same gap junction protein that can be observed on SDS-polyacrylamide gels simply by varying the concentration of acrylamide in the gels. A 64 kDa dimer is also obtainable. Antibodies to the gap junction protein or to a synthetic peptide constructed to match the rat liver gap junction amino-terminal sequence recognize all of these forms. Under some conditions a 54 kDa dimer is 'preferred', explaining the presence of this species in whole tissue homogenate Western blots. These results clarify several controversies and indicate that the protein forming the gap junction channel probably undergoes no major post-translational modification as the cDNA sequence codes for a protein of molecular mass 32 kDa and this protein species and its 64 kDa dimer are demonstrable on SDS-polyacrylamide gels under appropriate conditions.     

Preparation of a gap junction fraction from uteri of pregnant rats: the 28-kD polypeptides of uterus, liver, and heart gap junctions are homologous

A procedure for the preparation of a gap junction fraction from the uteri of pregnant rats is described. The uterine gap junctions, when examined by electron microscopy of thin sections and in negatively stained preparations, were similar to gap junctions isolated from heart and liver. Major proteins of similar apparent molecular weight (Mr 28,000) were found in gap junction fractions isolated from the uterus, heart, and liver, and were shown to have highly homologous structures by two-dimensional mapping of their tryptic peptides. An Mr 10,000 polypeptide, previously deduced to be a proteolytic product of the Mr 28,000 polypeptide of rat liver (Nicholson, B. J., L. J. Takemoto, M. W. Hunkapiller, L. E. Hood, and J.-P. Revel, 1983, Cell, 32:967-978), was also studied and shown by chymotryptic mapping to be homologous in the uterine, heart, and liver gap junction fractions. An antibody raised in rabbits to a synthetic peptide corresponding to an amino-terminal sequence of the liver gap junction protein recognized Mr 28,000 proteins in the three tissues studied, showing that the proteins shared common antigenic determinants. These results indicate that gap junctions are biochemically conserved plasma membrane specializations. The view that gap junctions are tissue-specific plasma membrane organelles based on previous comparisons of Mr 26,000-30,000 polypeptides is not sustained by the present results.     

Biochemical and immunological approaches to the study of gap junctional communication

Summary Studies on gap junctions isolated from rat liver by a procedure that avoids exogenous proteolysis (Hertzberg, E. L.; Gilula, N. B.; J. Biol. Chem. 254: 2138–2147; 1979) are described. The original isolation procedure was modified to increase the yield and has been extended to the preparation of gap junctions from mouse and bovine liver. Peptide map studies showed that the 27,000-dalton polypeptides present in liver gap junction preparations from all three sources are homologous and are not derived from other polypeptides of higher molecular weight that are observed in cruder preparations. Similar studies with lens fiber junctions demonstrated no homology between liver and lens junction polypeptides. Antibodies to the lens junction polypeptide did not cross-react with the liver gap junction polypeptide, further supporting this conclusion. Presented in the symposium on Molecular and Morphological Aspects of Cell-Cell Communication at the 31st Annual Meeting of the Tissue Culture Association, St. Louis, Missouri, June 1–5, 1980. This symposium was supported in part by Contract 263-MD-025754 from the National Cancer Institute and the Fogarty International Center. Research in the laboratory was supported by grants to Dr. Gilula from the National Institute of Health (HL 16507 and GM 24753).     

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

Summary 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 20 mM NaOH or 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 16Kd, 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 detergentalkali solubility, equilibrium density on sucrose gradients, and protein content (antigenic properties).     

Topological analysis of the major protein in isolated intact rat liver gap junctions and gap junction-derived single membrane structures

The topological organization of the major rat liver gap junction protein has been examined in intact gap junctions and gap junction-derived single membrane structures. Two methods, low pH and urea at alkaline pH, were used to "transform" or "split" double membrane gap junctions into single membrane structures. Low pH treatment "transforms" rat liver gap junctions into small single membrane vesicles which have an altered sodium dodecyl sulfate-polyacrylamide gel electrophoresis profile after digestion with L-1-to-sylamido-2-phenylethylchloromethyl ketone-trypsin. Alkaline pH treatment in the presence of 8 M urea can split isolated rat liver gap junctions into single membrane sheets which have no detectable structural alteration or altered sodium dodecyl sulfate-polyacrylamide gel electrophoresis profile after proteolytic digestion, suggesting that these single membrane sheets may be useful for topological studies of the gap junction protein. Proteolytic digestion studies have been used to localize the carboxyl terminus of the molecule on the cytoplasmic surface of the intact gap junction. However, the amino terminus does not appear to be accessible to proteases or to interaction with an antibody that is specific for the amino-terminal region of the molecule in intact or split gap junctions. Binding of antibodies, that block junctional channel conductance, can be eliminated by proteolytic digestion of intact gap junctions, suggesting that all antigenic sites for these antibodies are located on the cytoplasmic surface of the intact gap junction. In addition, calmodulin gel overlays indicate that at least two calmodulin binding sites exist on the cytoplasmic surface of the junctional protein. The information generated from these studies has been used to develop a low resolution two-dimensional model for the organization of the major rat liver gap junctional protein in the junctional membrane.     

Biochemical and genetic investigations on gap junctions from mammalian cells

Gap junction protein (26K) in mouse or rat liver has been studied using a rabbit antiserum directed against the sodium dodecylsulfate denatured 26K protein from mouse liver. The liver 26K protein has been localized in gap junction plaques of hepatic plasma membranes by immuno electron microscopy. Affinity purified anti-26K antiserum showed weak cross reactivity with mouse or bovine lens gap junction protein (MIP26). This result suggests some structural homology between the different gap junction proteins in liver and lens. After partial hepatectomy of young rats the liver 26K protein appears to be degraded and later resynthesized. A variant of established Chinese hamster fibroblastoid cells has been isolated and shown to be defective in metabolic cooperation via gap junctions.     

A protein homologous to the 27,000 dalton liver gap junction protein is present in a wide variety of species and tissues

The species and tissue specificities of gap junction polypeptides were investigated with antibodies raised against the 27,000 dalton rat liver gap junction protein. Cross-reacting 27,000 dalton polypeptides were detected in liver from mammalian, fish, and avian species by immunoreplica analyses and were localized to punctate regions of the plasma membrane by indirect immunofluorescence. They were also found in homogenates of other rat tissues, including pancreas, heart, brain, kidney, stomach, and adrenal gland, but not in lens fiber material. Localization of antibody binding in pancreas was similar to that of liver, while in heart ventricle the immunofluorescence pattern was consistent with binding to the intercalated disc. These findings indicate that homologous gap junction polypeptides may be widely distributed among vertebrate tissues.     

Gap junctions in several tissues share antigenic determinants with liver gap junctions.

Using affinity-purified antibodies against mouse liver gap junction protein (26 K), discrete fluorescent spots were seen by indirect immunofluorescence labelling on apposed membranes of contiguous cells in several mouse and rat tissues: pancreas (exocrine part), kidney, small intestine (epithelium and circular smooth muscle), Fallopian tube, endometrium, and myometrium of delivering rats. No reaction was seen on sections of myocardium, ovaries and lens. Specific labelling of gap junction plaques was demonstrated by immunoelectron microscopy on ultrathin frozen sections through liver and the exocrine part of pancreas after treatment with gold protein A. Weak immunoreactivity was found on the endocrine part of the pancreas (i.e., Langerhans islets) after glibenclamide treatment of mice and rats, which causes an increase of insulin secretion and of the size as well as the number of gap junction plaques in cells of Langerhans islets. Furthermore, the affinity purified anti-liver 26 K antibodies were shown by immunoblot to react with proteins of similar mol. wt. in pancreas and kidney membranes. Taken together these results suggest that gap junctions from several, morphogenetically different tissues have specific antigenic sites in common. The different extent of specific immunoreactivity of anti-liver 26 K antibodies with different tissues is likely due to differences in size and number of gap junctions although structural differences cannot be excluded.     

Simultaneous light and electron microscopic observation of immunolabeled liver 27 KD gap junction protein on ultra-thin cryosections

We report on immunolabeling of gap junction protein in rat liver. Simultaneous light and electron microscopic immunolabeling of ultra-thin frozen sections was performed to confirm that the antigenic targets of polyclonal antibodies and a monoclonal 27 KD antibody (12/1 C5) are the gap junctions. Our results clearly demonstrate that the immunoreactive sites determined by indirect immunofluorescence correspond to immunogold-labeled gap junctions identified in the same section according to electron microscopic criteria. Our results also support the concept that the 27 KD protein is a major constituent of gap junctions.     

Topology of the Mr 27,000 liver gap junction protein. Cytoplasmic localization of amino- and carboxyl termini and a hydrophilic domain which is protease-hypersensitive

Hydropathy analysis of the Mr 27,000 rat liver gap junction protein sequence deduced from a cDNA clone has suggested the presence of four transmembrane segments (Paul, D. L. (1986) J. Cell Biol. 103, 123-134). In the present report, several features of the molecular topology of the protein were investigated by microsequence analysis of peptides generated by treatment of isolated gap junctions with a variety of proteases. Under the experimental conditions used, the proteases had access only to the portion of the Mr 27,000 protein that was originally (in vivo) the cytoplasmic surface of the gap junction. Microsequencing of the peptides resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the amino terminus of the protein is disposed at or near the cytoplasmic surface of the gap junction, and that this surface also contains a protease-hypersensitive hydrophilic sequence between residues 109 and 123, presumably connecting the second and third transmembrane segments. Immunocytological localization of binding of monoclonal antipeptide antibodies demonstrates that the carboxyl terminus of the protein is also localized to the cytoplasmic surface of the gap junction. No protease sensitivity was found in the hydrophilic sequences thought to connect either the first and second transmembrane segments or the third and fourth segments, supporting the model's prediction that these sequences face the narrow intercellular gap which cannot be penetrated by proteases.     

Immunological evidence for gap junction polypeptide in plant cells

A whole cell homogenate prepared from soybean (Glycine max (L.) Merr. cv. Mandarin) root cells (SB-1 cell line) was electrophoresed on a sodium dodecyl sulfate-polyacrylamide gel and transferred to nitrocellulose paper. The nitrocellulose was probed with a monospecific antibody capable of recognizing the Mr 27,000 polypeptide of rat liver gap junctions; this antibody was prepared from immune serum raised against gap junctions purified from V79 cells (Chinese lung fibroblasts). The immunoblots afforded two polypeptides migrating at Mr 29,000 and 48,000. This pattern of blotting was also observed when homogenates of soybean or poinsettia leaves excised from whole plants were probed with anti-V79 gap junction antiserum. Gap junction purification schemes, developed for rat liver (Hertzberg, E. L. (1984) J. Biol. Chem. 259, 9936-9943), were employed on soybean protoplast homogenates yielding a significant enrichment for the Mr 29,000 and 48,000 polypeptides as judged by Coomassie Blue staining and immunoblotting with anti-V79 gap junction antiserum. These immunological results provide the first reported evidence for a homologous gap junction polypeptide in plant cells.     

Immunocytochemical localization of the gap junction 26 K protein in mouse liver plasma membranes

Specific binding sites for anti-26 K antibodies directed against the liver gap junction protein (26 K) were localized by immunoelectron microscopy in gap junction plaques purified from hepatic plasma membranes. Using immunofluorescence microscopy we found discrete fluorescent spots on plasma membranes in cross sections of liver tissues after incubation with anti-26 K antibodies. This is consistent with the notion of specific binding to gap junction plaques. Quantitative binding of anti-26 K antibodies was indirectly measured by the protein A-gold technique. We found that urea/detergent-treated, purified gap junction plaques bind 30-fold more anti-26 K antibodies than preimmune serum. Anti-26 K antibodies also bind specifically to native gap junction plaques within hepatic plasma membranes although only about one fifth as efficiently as to purified plaques. Possibly the anti-26 K antibodies raised after injection of SDS-denatured 26 K protein into rabbits recognize the cytoplasmic face of urea/detergent-treated plaques better than that of native plaques. Some, if not most, of the vesicular structures in preparations of purified plaques appear to be derived from split gap junction plaques and are probably sheets of gap junction hemichannels. In some vesicles the former cytoplasmic face of the hemichannels is turned outside, other vesicles have the former cell surface turned outside. The anti-26 K antibodies do not recognize any 26 K protein on the sheets of partially split gap junction plaques, on the heterogeneous vesicular structures, or on non-junctional areas of hepatic plasma membranes. These results suggest that the conformation of the 26 K protein in plaques must be different from that of the 26 K protein in earlier biosynthetic steps of plaque assembly.     

Functional assembly of gap junction conductance in lipid bilayers: demonstration that the major 27 kd protein forms the junctional channel

Gap junctions isolated from rat liver were incorporated into planar lipid bilayers. A channel activity that was directly dependent on voltage was recorded. Changes of pH and (Ca2+) had no direct effect on channel activity; however, they modulated the voltage-dependent gating of the gap junction channels differently. Single-channel fluctuations showed large scatter with peak amplitudes of 140 and 280 picoSiemmens in 0.1 M NaCl. The major protein of gap junctions (Mr of 27 kd) was also reconstituted into bilayers, giving channel properties similar to those of intact gap junctions. Polyclonal antibodies specific for this protein caused inhibition of the junctional conductance in bilayers. These data provide direct evidence that the 27 kd protein is the molecular species responsible for gap junction communication between cells.     

Immunolocalization of an extracellular domain of connexin43 in rat heart gap junctions.

Antipeptide antibodies directed to residues 55 to 66 (NTQQPGCENVCY) of connexin43 (cx43) specifically recognize this protein on Western blots of intact and urea-split gap junctions isolated from rat heart. These antibodies detect a single protein of 43 kDa, corresponding to cx43, on Western blots of whole fractions of various vertebrate hearts. Immunogold labeling by electron microscopy shows that the epitopes recognized by these antibodies are not localized on the cytoplasmic surfaces of intact gap junctions but only at the edges of these junctions. In urea-split gap junctions the gold particles are seen in the junctional space, associated with the extracellular faces of junctional membranes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analyses of rat heart gap junctions treated with trypsin show that they are constituted with either two polypeptides of Mr 12,000 and 14,000 or a single polypeptide of Mr 22,000 according to whether the analyses are performed under reducing or non-reducing conditions, respectively. The antibodies directed to residues 55 to 66 of cx43 cross-react with both the 12 and 22 kDa polypeptides. These results suggest that the two protected domains of 12 and 14 kDa which contain the first extracellular loop and a putative second extracellular loop, respectively, are linked by disulfide bonds. In adult rat heart sections analyzed by indirect immunofluorescence the intercalated discs are labeled with antibodies directed to a cytoplasmic carboxy-terminal domain of cx43 (El Aoumari et al., J. Membr. Biol. 115, 229-240 (1990)). The same intercalated discs are also labeled in adjacent sections incubated with the antibodies directed to residues 55 to 66. Two hypotheses might explain these results: either the antibodies have access to the extracellular domain of cx43 molecules localized at the edges of the gap junctions, or cx43 molecules are present in the non-junctional membranes of the intercalated discs.     

Comparative characterization of the 21-kD and 26-kD gap junction proteins in murine liver and cultured hepatocytes

Affinity-purified antibodies to mouse liver 26- and 21-kD gap junction proteins have been used to characterize gap junctions in liver and cultured hepatocytes. Both proteins are colocalized in the same gap junction plaques as shown by double immunofluorescence and immunoelectron microscopy. In the lobules of rat liver, the 21-kD immunoreactivity is detected as a gradient of fluorescent spots on apposing plasma membranes, the maximum being in the periportal zone and a faint reaction in the perivenous zone. In contrast, the 26-kD immunoreactivity is evenly distributed in fluorescent spots on apposing plasma membranes throughout the rat liver lobule. Immunoreactive sites with anti-21 kD shown by immunofluorescence are also present in exocrine pancreas, proximal tubules of the kidney, and the epithelium of small intestine. The 21-kD immunoreactivity was not found in thin sections of myocardium and adult brain cortex. Subsequent to partial rat hepatectomy, both the 26- and 21-kD proteins first decrease and after approximately 2 d increase again. By comparison of the 26- and 21-kD immunoreactivity in cultured embryonic mouse hepatocytes, we found (a) the same pattern of immunoreactivity on apposing plasma membranes and colocalization within the same plaque, (b) a similar decrease after 1 d and subsequent increase after 3 d of both proteins, (c) cAMP-dependent in vitro phosphorylation of the 26-kD but not of the 21-kD protein, and (d) complete inhibition of intercellular transfer of Lucifer Yellow in all hepatocytes microinjected with anti-26 kD and, in most cases, partial inhibition of dye transfer after injection of anti-21 kD. Our results indicate that both the 26-kD and the 21-kD proteins are functional gap junction proteins.     

Structure and biochemistry of mouse hepatic gap junctions

A new method for the isolation of gap junctions from mouse liver is described. Particular attention has been directed to minimising the effects of proteolysis during isolation. The purified membrane fragments retain the typical morphological features found in junctions of the intact liver.The junctions show two major polypeptides upon polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. The apparent molecular weights are 26,000 for the more abundant species and 21,000 for the minor component. Preliminary protein chemical characterisation by fingerprint analysis suggests that the two polypeptides are structurally related. While an in vivo origin of the 21,000 molecular weight species cannot be excluded, the sensitivity of the junction proteins to proteolytic degradation in vitro suggests that the 21,000 molecular weight molecule may be a breakdown product of the major component.Image reconstruction methods applied to micrographs of negatively stained isolated junctions show that the membrane contains a close-packed hexagonal lattice of components having marked 6-fold symmetry. It is suggested that these represent hexamers of the 26,000 molecular weight protein.Lipid analysis performed on gap junctions isolated by different procedures shows that the lipid composition is strongly affected by the detergents employed during the isolation. A large amount of phopholipid, but not cholesterol, can be extracted from the structure without affecting its gross morphology. This result suggests that cholesterol is tightly bound to the junction protein and may play a role in determining the structure of the gap junction.     

On the structure of isolated junctions between communicating cells

Summary Gap junctions are specialized regions of contact between apposed plasma membranes of communicating cells. They are composed of hexagonally arranged units (connexons) embedded in plasma membranes and linked together in the extracellular space. The three-dimensional structure of the connexon, was obtained by Fourier analysis on specimens of isolated rat liver gap junctions. The connexon is an annular oligomer, composed of six subunits, that protrudes from both sides of the plasma membrane. The subunits are tangentially displaced about the connexon axis. A narrow channel is located along the connexon, axis spanning the thickness of the junction, but it is greatly reduced in the hydrophobic zones of the membranes. Two closely related forms of isolated gap junctions which have different connexon subunit structures but the same hexagonal lattice, were obtained. The transition between the two forms of communicating junctions seen in isolation is produced by radial inward motion of the connexon subunits near their cytoplasmic surfaces and a reduction of their inclination tangential to the 6-fold axis. Similar rearrangement of essentially rigid subunits embedded in the membrane could provide a mechanism for modulation of the junction permeability. Presented in the symposium on Molecular and Morphological Aspects of Cell-Cell Communication at the 31st Annual Meeting of the Tissue Culture Association, St. Louis, Missouri, June 1–5, 1980. This symposium was supported in part by Contract 263-MD-025754 from the National Cancer Institute and the Fogarty International Center. This work was supported by NH Grants 5P1GM23911-07 and 5T32-6M07403-04.