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Hyperinsulinemia-Induced Hypoglycemia Is Enhanced by Overexpression of Connexin 43¹

Department of Morphology, University of Geneva Medical School, CH-1211 Geneva 4, Switzerland

Address all correspondence and requests for reprints to: Paolo Meda, M.D., Department of Morphology, University of Geneva Medical School, 1 rue Michel-Servet, CH-1211 Geneva 4, Switzerland. E-mail: PAOLO.MEDA{at}MEDECINE.UNIGE.CH

	Abstract

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To assess whether cell to cell communications via connexins (Cx) participate to insulin secretion in vivo, we studied insulinoma cells (INS1) implanted in rats after stable transfection with connexin 43 (Cx43). We found that compared to wild-type and transfected cells, which in vivo express modest levels of Cx43 and junctional communication, cells overexpressing Cx43 communicated extensively, featured decreased growth, and induced a much higher hyperinsulinemia. As a result, rats with insulinomas made of these cells became more severely hypoglycemic than rats implanted with either wild-type, neomycin-transfected cells or cells transfected with a Cx43 antisense complementary DNA. Rats implanted with transfected cells that expressed modest level of Cx43 showed levels of circulating insulin similar to those in rats implanted with wild-type INS1 cells. The data show that overexpression of Cx43 influences the growth and secretion of the implanted insulinoma cells, providing evidence for a contribution of Cx-mediated cell to cell communication in the functioning of insulin-producing cells in vivo.

	Introduction

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ALMOST ALL differentiated cell types are connected by gap junctions, the membrane microdomains that concentrate connexin (Cx)-made channels for cell to cell exchanges of cytoplasmic ions and molecules (1, 2, 3). Experiments in adult systems have provided evidence that Cx-mediated communication may contribute to multiple functions, including electrical and mechanical synchronization of cells in excitable tissues, control of cell growth in both normal and tumoral systems, retention of differentiated characteristics, and secretion of various products (1, 2, 3, 4). Evidence for a secretory involvement of Cx channels has been derived from studies on the insulin-producing ß-cells of the endocrine pancreas, which have indicated that gap junctional communication significantly contributes to the control of insulin biosynthesis and release in vitro (5, 6).

Few studies have investigated whether this contribution is relevant to the in vivo functioning of insulin-producing cells, as it is also the case, in fact, for most of the functions that have been attributed to Cx channels in other systems (2, 7). Sustained exposure to drugs, hormones, and conditions that affect insulin secretion have been reported to modify in vivo the gap junctions of native ß-cells and the cell to cell communications these structures ensure within pancreatic islets (8, 9, 10, 11). As yet, however, we do not know whether a primary alteration in the Cx channels of islet cells actually results in changes in insulin secretion that would be relevant to the in vivo control of blood glucose levels. As a first approach to address this question, we have implanted normoglycemic rats with insulinoma cells expressing different levels of connexin 43 (Cx43), a gap junction protein that is expressed by native pancreatic ß-cells (12, 13) and have monitored the growth of tumoral cells and their effects on the circulating levels of glucose and insulin.

	Materials and Methods

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Cells
Cells of the INS1 line (14), which express no Cx and are uncoupled in vitro (6), were used. Stable transfection of the gene encoding Cx43 resulted in the selection of clones expressing different levels of this Cx and coupling, and showing a different secretion profile (6). Here, we have used three of these clones (e, i, and n) that, compared to wild-type INS1 cells and to cells transfected only for neomycin resistance, expressed high levels of Cx43, as judged at gene, transcript, and protein levels (Fig. 1). As additional controls, we used, in a separate set of experiments, two other clones (a and w) of transfected cells that in vitro expressed much lower levels of Cx43 (6), as well as a sixth clone of INS1 cells that had been transfected with a complementary DNA (cDNA) comprising the sequence coding for Cx43 in an antisense orientation and for resistance to phleomycin, which was used as the selection antibiotic (not shown).

View larger version (53K): [in this window] [in a new window]   Figure 1. a, A cDNA probe detected the endogenous gene coding for Cx43 in genomic DNA (6 ) of both wild-type (INS1) and Cx43-transfected clones (INS1Cx43-e, -i, and -n). In contrast, the transfected gene, which was identified by a mobility similar to that of the plasmid insert (VECTOR), was detected only in the latter clones. b, Analysis of total RNA revealed the presence of a native Cx43 transcript (Cx43-N) only in the heart extract that was used as control. In contrast, high levels of another transcript (Cx43-T), which had a slightly higher mobility due to the construction of the transfected insert, were detected in the three clones of Cx43-transfected cells (INS1Cx43-e, -i, and -n). No transcript was detected in samples of liver, which was used as negative control, or in wild-type cells (INS1). Lanes were loaded with 5 µg (heart) or 10 µg total RNA (all other lanes). c, Antibodies to Cx43 revealed this protein in membranes of heart and of the three Cx43-transfected clones. The two immunoreactive bands detected in Cx43-transfected cells did not have the same mobility as those in heart, presumably indicating different levels of phosphorylation of the gap junction protein in the two systems. In contrast, no Cx43 was detected in samples of liver and wild-type cells. All lanes were loaded with 50 µg protein.

For identification of Cx43 transcript, cell cultures were homogenized in 2.5 ml 0.1 M Tris-HCl, pH 7.4, containing 2 M ß-mercaptoethanol and 4 M guanidium thiocyanate. After the addition of solid CsCl (0.4 g/ml), the homogenate was layered on a 2-ml 5.7 M CsCl-0.1 M EDTA (pH 7.4) cushion and centrifuged for 20 h at 20 C at 150,000 x g, using a SW55 rotor and a Beckman L8–70M ultracentrifuge (Beckman, Fullerton, CA). Pelleted RNA was resuspended in 300 µl 10 mM Tris-HCl, pH 8.1, supplemented with 5 mM EDTA and 0.1% SDS, extracted twice with phenol-chloroform, precipitated in ethanol, and resuspended in water. Probes for Cx43 were constructed and used as previously described (13). For Northern blots, total cellular RNA was denatured with glyoxal, electrophoresed in a 1% agarose gel (5–10 µg total cellular RNA/lane) and transferred overnight onto nylon membranes (Hybond N, Amersham International, Aylesbury, UK). Filters were baked under vacuum at 80 C for 2 h, exposed for 30 sec to 302 nm light, stained with methylene blue, and prehybridized for 30 min at 65 C in 5 x SSC (standard saline citrate) containing 0.1% SDS, 5 x Denhardt’s solution, and 250 mg/ml salmon sperm DNA. Filters were then hybridized for 18 h at 65 C with 10⁵ cpm/cm^{2 32}P-labeled probe and washed twice at room temperature in 2 x SSC containing 0.1% SDS, followed by two washings at 65 C in 0.5 x SSC and 0.1% SDS. Filters were then exposed to film (XAR-5, Eastman Kodak Co.) between intensifying screens at -80 C. Samples of total cellular RNA were similarly extracted from heart and liver, and used as internal controls in all blots.

For Western blotting, cell cultures were lysed and homogenized by sonication in 0.02 M Tris-HCl, pH 8.0, supplemented with 20 mM EDTA, 1 µg/ml pepstatin A, 1 µg/ml antipain, 1 mM benzamidine, 200 kallikrein inhibitor units/ml aprotinin, 2 mM phenylmethylsulfonylfluoride, and 1 mM diisoprophyl fluorophosphate. After a 10-min centrifugation of the sonicate at 3,000 x g and 4 C, the supernatant was collected and centrifuged for 60 min at 100,000 x g and 4 C. Pelleted material was resuspended in a 0.1 M Tris buffer, pH 7.0, containing 20% SDS, 10 mM EDTA, and 2.5% ß-mercaptoethanol and stored at -80 C. The protein content was measured by a detergent-compatible protein assay kit (500–0-116, Bio-Rad Laboratories, Glattbrugg, Switzerland). Samples of crude membrane preparations (50 µg protein/lane) were fractionated by electrophoresis in a 12.5% polyacrylamide gel and immunoblotted as previously described (12). To this end, electrophoresed samples were transferred onto Immobilon membranes (Millipore, Wolketswil, Switzerland) for 18 h at a constant voltage of 25 V in the presence of 0.02% SDS. After checking for efficient transfer by Ponceau S staining, the nitrocellulose membranes were saturated at room temperature in BLOTTO solution (40 mM Tris-HCl, 0.1% Tween-20, and 4% dry milk) and then incubated for 60 min with a mouse monoclonal antibody against heart Cx43 (Zymed Laboratories, San Francisco, CA), diluted 1:500. After repeated rinsing in BLOTTO, the nitrocellulose immmunoblots were incubated for 60 min at room temperature with a biotinylated serum (Jackson ImmunoResearch Laboratories, West Grove, PA) against mouse Ig (diluted 1:500). Filters were incubated for 45 min at room temperature with alkaline phosphatase-labeled streptavidin (Amersham International, Little Chalfont, UK) diluted 1:5,000, rinsed repeatedly in 40 mM Tris-HCl supplemented with 0.5 M NaCl and 0.1% Tween-20, and eventually processed for detection of alkaline phosphatase activity using bromochloroindolyl phosphate-nitro blue tetrazolium as substrate. Heart and liver samples were processed in a similar way and used as controls.

Animals
Rats (200–300 g BW) of the inbred NEDH strain were used because they are immunologically adequate recipients for implantation of the RIN-derived INS cells (15). The animals were briefly anesthetized by inhalation of 5% Ethrane (Abbott Laboratories, Cham, Switzerland) and injected sc in one thigh with 10⁶ INS1 cells that had been freshly trypsinized from 1-week-old cultures. In all experiments, one or two rats were injected with each of the six different types of INS1 cells tested (control, neomycin-transfected, Cx43 antisense-transfected, and three different clones of Cx43-transfected cells). The animals were then returned to standard housing conditions with free access to water and food. All animal manipulations were conducted according to the rules of our institutional committee on animal experiments.

Blood measurement
Samples of venous blood were obtained from the tail of each rat just before cell implantation and thereafter at regular intervals up to the time of tumor removal. Small aliquots of blood were analyzed for glucose concentrations using an Accutrend glucometer (Boehringer Mannheim, Mannheim, Germany). The remaining blood was collected in heparinized tubes and centrifuged at 4 C to prepare plasma, for measurement of insulin concentrations. To this end, we used a RIA with a charcoal separation step and rat insulin as standard (16).

Tumor sampling
Macroscopically detectable tumors developed exclusively at the site of injection. All tumors were surgically removed 5 weeks after cell injection. After measurement of tumor weight and volume, fragments of each tumor were sampled for light and electron microscopy, immunoidentification of Cx, total RNA extraction, and evaluation of dye coupling.

Histology
Fragments of the tumors were fixed in Bouin’s solution and processed according to standard histological methods. The volume density of endocrine cells was assessed on sections by computerized planimetry, using a Leica Quantimet 500 (Leica, Cambridge, UK). Sections were also processed for insulin and glucagon immunostaining, as previously described (17).

Analysis of Cx43 expression and coupling in tumors
Northern blots of insulinoma RNA were performed as detailed for INS cell cultures. Immunofluorescence labeling of cryostat sections of unfixed tumor fragments was carried out using monoclonal antibodies against Cx43 (Zymed Laboratories, San Francisco, CA), diluted 1/50. Sections of rat heart were similarly processed and used as positive controls. Negative controls were provided by omitting the anti-Cx antibodies during the first incubation.

For assessment of junctional coupling, fragments of the tumors were incubated for 30 min at 37 C with 0.8 mg/ml Collagenase 1 (Serva, Heidelberg, Germany) under continuous shaking. The resulting cell suspension was diluted in ice-cold Hanks’ solution supplemented with 0.3% BSA and passed through two nylon filters. After repeated rinsing, 2 x 10⁶ cells/ml RPMI 1640 medium were plated in culture dishes. Immediately after attachment, individual cells were microinjected with 4% Lucifer Yellow CH (Sigma Chemical Co., St. Louis, MO), as described previously (12). The incidence of coupling was determined by scoring whether each injection resulted in cell to cell transfer of Lucifer Yellow. The extent of coupling was determined by scoring the number of cells labeled by Lucifer Yellow (including the injected cells) on photographs taken immediately at the end of each injection.

	Results

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When studied in vitro, wild-type INS1 cells and cells transfected with a neomycin resistance gene did not express Cx43 (Fig. 1), Cx26, or Cx32 and were essentially uncoupled, as judged both by Lucifer Yellow injections and dual patch-clamp electrophysiology (not shown). Stable transfection of the gene encoding Cx43 resulted in the selection of clones expressing different levels of this Cx (6). Here, we studied the in vivo behavior of three independent clones of INS1 cells (clones i, n, and e) that stably expressed high levels of Cx43, as judged at gene, transcript, and protein levels (Fig. 1). This behavior was compared to that of INS1 cells that expressed levels of Cx43, which were either undetectable in vitro (wild-type cells and cells transfected only with a neomycin resistance gene; Fig. 1) or were much lower than those expressed by clones i, n, and e [Cx43-transfected clones a and w (6) and cells transfected with a Cx43 cDNA in an antisense orientation].

For 2 weeks after the sc injection of these INS1 cell types in the thigh of control rats, no change was detectable at the site of injection or in the circulating levels of glucose and insulin (Fig. 2). In contrast, from the third week onward, a tumor was detectable at the site of injection, and the animals showed persistent hyperinsulinemia, which caused a progressive drop in their circulating glucose levels (Fig. 2). From this time on, rats bearing tumors made of Cx43-transfected cells of clones i, n, and e had higher plasma insulin and lower blood glucose levels than the rats injected with all other types of INS1 cells tested (Fig. 2) and displayed smaller tumors.

View larger version (20K): [in this window] [in a new window]   Figure 2. a, Five weeks after cell injection, all insulinoma-bearing rats (T-CONT, T-NEO, T-e, T-i, and T-n) had lower blood glucose levels than nonimplanted rats (CONT). In addition, the insulinomas made by Cx43-transfected cells (T-e, T-i, and T-n) induced greater hypoglycemia than those formed by either wild-type (T-CONT) or neomycin-transfected (T-NEO) cells. Values are the mean ± SEM for the number of rats indicated. b, Corresponding insulin levels were significantly higher in the rats injected with Cx43-transfected cells (T-e, T-i, and T-n). Values are the mean ± SEM for the number of rats indicated. c, Up to 2 weeks after cell injection, all rats featured normal circulating levels of glucose and insulin. Thereafter, the level of glucose decreased with time, whereas that of insulin increased. Also, rats injected with Cx43-transfected cells (open squares show the mean ± SEM for T-e, T-i, and T-n cells, four rats per cell type) became more hypoglycemic and hyperinsulinemic than rats injected with other INS1 cells (solid squares show the mean ± SEM for T-CONT and T-NEO cells, four rats per cell type).

Tumors generated by clones i, n, and e were consistently half as large as those made of either wild-type or neomycin-transfected cells (Fig. 3). Histology revealed that all tumors comprised cords of endocrine cells, surrounded by abundant vessels and contained within a thick connective capsule (Figs. 4 and 5). Morphometric measurements revealed that the endocrine cells had similar volume densities and contained comparable amounts of immunolabeled insulin in all tumors (Fig. 4). However, tumors generated by Cx43-transfected cells expressed significantly higher levels of this Cx, as judged at both transcript and protein levels, than tumors formed by either wild-type or neomycin-transfected cells (Fig. 5).

View larger version (56K): [in this window] [in a new window]   Figure 3. a, All insulinomas removed 5 weeks after cell injection were solid tumors enclosed by a capsule of connective tissue. Tumors formed by wild-type (first from left) and neomycin-transfected cells (second from left) were similar in size and consistently larger than tumors formed by Cx43-transfected cells (T-n, T-i, and T-e tumors are first, second and third from right, respectively). b, On the average, insulinomas formed by Cx43-transfected cells (T-e, T-i, and T-n) were half the volume of those formed by either wild-type (T-CONT) or neomycin-transfected (T-NEO) cells. c, In contrast, the volume density (Vv) of endocrine cells was comparable in all tumors. Values are the mean ± SEM for the number of insulinomas indicated. The bar represents 1 cm.

View larger version (120K): [in this window] [in a new window]   Figure 4. Immunostaining for insulin revealed the cytoplasmic accumulation of the hormone in the endocrine cells of all insulinomas (A and C), but not in their connective capsule (c). No obvious difference in insulin content was observed between tumors made of wild-type (A) and Cx43-transfected (C) cells. B and D are phase contrast views of A and C, respectively. The bar represents 20 µm.

View larger version (101K): [in this window] [in a new window]   Figure 5. Upper panel, Northern blot analysis of all insulinomas (T-CONT, -NEO, -e, -i, and -n) revealed the presence of a single transcript for endogenous Cx43 (Cx43-N), that was much less abundant than in the heart extract used as a control. In addition, insulinomas made of Cx43-transfected cells (T-e, T-i, and T-n) also expressed high levels of a second, transfection-induced transcript of slightly higher mobility (Cx43-T). Lower panel, Immunolabeling with antibodies to Cx43 resulted in a punctuate labeling of cells in the connective capsule (arrows) of all insulinomas (A and C). In addition, the endocrine cell cords that formed the bulk of the tumors were immunolabeled in the tumors formed by Cx43-transfected cells (C), but were not detectable in those formed by wild-type or neomycin-transfected cells (A). B and D are phase contrast views of A and C, respectively. The barrepresents 12 µm.

In agreement with these findings, endocrine cells freshly dispersed from tumors generated by clones i, e, and n showed a significantly higher incidence and extent of junctional communications than these dispersed from tumors made of wild-type and neomycin-transfected cells, as assessed by microinjection of Lucifer Yellow (Fig. 6). The overall extent of coupling, evaluated by multiplying coupling incidence by coupling extent, was 6–7 times higher in the tumors made of Cx43-transfected cells (329.5, 308.3, and 373.8 arbitrary units in tumors made by cells e, i, and n, respectively) than in those made of either wild-type or neomycin-transfected cells (56.7 and 51.8 arbitrary units, respectively).

View larger version (20K): [in this window] [in a new window]   Figure 6. Upper panel, Junctional coupling was detected in 25% of the injections performed in either wild-type (T-CONT) or neomycin-transfected (T-NEO) insulinoma cells and in 90% of the injections performed in cells overexpressing Cx43 (T-e, T-i, and T-n). This difference was highly significant (P < 0.001). Lower panel, After the injections that revealed junctional coupling, Lucifer Yellow was found transferred between an average of 2.2 cells in T-CONT and T-NEO tumors and between 3–4 cells in T-e, T-i, and T-n tumors. The difference reached statistical significance (P < 0.02–0.03). Shown are the mean ± SEM of 20 injections for each cell type. *, P < 0.001; , P < 0.03 (T-i); P < 0.02 (T-e and T-n).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Previous observations have documented that junctional communication of pancreatic ß-cells affects the biosynthesis, storage, and release of insulin in vitro and have indicated that an enlargement of this communication is required for the up-regulation of insulin release (4, 5, 6, 12, 16, 17, 18, 19). The present findings provide evidence that junctional communication is also operative and influential under the pathophysiological conditions encountered in vivo as a result of the development of an insulinoma. However, this study has also documented marked differences in the communication and secretory behavior of tumoral cells in vitro and in vivo. Thus, INS1 cells do not express detectable levels of Cx43 (or, in fact, of two other Cx that are prominent in secretory cells), are essentially uncoupled, and synthesize and secrete insulin rather poorly in two-dimensional cultures (6, 14). In contrast, under in vivo conditions, these cells rapidly acquire the ability to express Cx43, but not Cx32 or Cx26 (6, 12, 13), and to establish sizable levels of junctional communication (6, 12). Noticeably, these changes are also associated with a marked increase in the cell’s ability to biosynthesize and release insulin (14, 15). Even though the cause of this parallel differentiation has not yet been elucidated, the data suggest that junctional coupling is necessary, if not obligatory, for the proper control of insulin output in vivo.

In this perspective, it remains to be established by which mechanism a 6- to 7-fold increase in Cx-mediated communications between INS1 cells results in an enhancement of insulin release, which is large enough to dramatically perturb the regulation of blood glucose levels in the intact animal. Conceivably, such a sizable increase in Cx channels could result in a faster or more widespread cell to cell exchange of second messengers that are critical for insulin secretion (4, 5, 20, 21, 22, 23). It is also possible that a greater abundance of Cx channels could significantly favor the coupling of insulin-producing cells exhibiting markedly different sensitivities to secretagogue stimulation (19). In this case, coupling could favor the recruitment of larger numbers of actively secreting cells and/or decrease their threshold level of stimulation (4, 5, 24, 25). Also unclear at this time is how the cell to cell exchanges of current-carrying ions and low mol wt tracers via Cx channels are integrated with the other mechanisms that depend on signaling via components of the extracellular matrix, neurotransmitters, and hormones to help coordinate insulin release from multicellular assemblies (5). The animal model we describe here should facilitate further investigations of these matters.

Another central question obviously concerns the relevance of these findings for the physiological control of insulin secretion by pancreatic ß-cells. Previous observations have documented that different physiological, pathological, and pharmacological conditions that affect insulin secretion in vivo are associated with changes in the expression of gap junctions, Cx43, and/or junctional coupling of native ß-cells (8, 9, 10, 11, 12). The present findings for tumoral cells extend these data by showing that a primary alteration in the level of Cx-mediated communication is sufficient in vivo to induce major changes in insulin secretion. Together, the available data suggest that Cx channels are required to ensure a proper response of the endocrine pancreas to a sustained increase in the demand for insulin. Direct experimental testing of this hypothesis awaits the development of transgenic animals in which the pattern of ß-cell Cx could be selectively (26) and conditionally modified. Analogous experiments are needed in other systems, as the consistent expression of Cx43 in all endocrine glands investigated to date (13) raises the possibility that specific characteristics of junctional communication, made possible through channels formed by Cx43, may represent a widespread mechanism to regulate the in vivo output of several hormones (4).

	Acknowledgments

 
We thank L. Burkhardt, K. Casada, F. Cogne, J.-P. Gerber, and E. Sutter for excellent technical assistance.

	Footnotes

 
¹ This work was supported by grants from the Swiss National Science Foundation (32–34086.95), the Juvenile Diabetes Foundation International (195077), and the European Union (BMH4-CT96–1427).

Received December 20, 1996.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

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This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Copyright Permission Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Vozzi, C. Articles by Meda, P. Search for Related Content PubMed PubMed Citation Articles by Vozzi, C. Articles by Meda, P.