Glucose-dependent Functional Heterogeneity In β-TC-6 Murine Insulinoma
To determine if the murine insulinoma, β-TC-6, is a
suitable substitute for primary pancreatic β-cells in the study of β-
cell functional heterogeneity, we used three distinct functional assays
to ascertain the cell line-s response to glucose or a glucose analog.
These assays include: (i) a 2-NBDG uptake assay; (ii) a calcium
influx assay, and; (iii) a quinacrine secretion assay. We show that a
population of β-TC-6 cells endocytoses the glucose analog, 2-
NBDG, at different rates, has non-uniform intracellular calcium ion
concentrations and releases quinacrine at different rates when
challenged with glucose. We also measured the Km for β-TC-6
glucose uptake to be 46.9 mM and the Vm to be 8.36 x 10-5
mmole/million cells/min. These data suggest that β-TC-6 might be
used as an alternative to primary pancreatic β-cells for the study of
glucose-dependent β-cell functional heterogeneity.
[1] D. E. Ingber, The Pancreas: Biology, Pathobiology, and Disease, 1993,
pp. 369-380.
[2] P. E. MacDonald, J. W. Joseph and P. Rorsman, "Glucose-sensing
mechanisms in pancreatic beta-cells," Philos Trans R Soc Lond B Biol
Sci, vol. 360, 2005, pp. 2211-2225.
[3] F. Matschinsky, Y. Liang, P. Kesavan, L. Wang, P. Froguel, G. Velho,
D. Cohen, M. A. Permutt, Y. Tanizawa, T. L. Jetton and et al.,
"Glucokinase as pancreatic beta cell glucose sensor and diabetes gene,"
J Clin Invest, vol. 92, 1993, pp. 2092-2098.
[4] T. Aizawa, T. Kaneko, K. Yamauchi, H. Yajima, T. Nishizawa, T. Yada,
H. Matsukawa, M. Nagai, S. Yamada, Y. Sato, M. Komatsu, N. Itoh, H.
Hidaka, Y. Kajimoto and K. Hashizume, "Size-related and size-unrelated
functional heterogeneity among pancreatic islets," Life Sci, vol. 69,
2001, pp. 2627-2639.
[5] H. Heimberg, A. De Vos, A. Vandercammen, E. Van Schaftingen, D.
Pipeleers and F. Schuit, "Heterogeneity in glucose sensitivity among
pancreatic beta-cells is correlated to differences in glucose
phosphorylation rather than glucose transport," EMBO J, vol. 12, 1993,
pp. 2873-2879.
[6] D. G. Pipeleers, "Heterogeneity in pancreatic beta-cell population,"
Diabetes, vol. 41, 1992, pp. 777-781.
[7] W. F. Pralong, C. Bartley and C. B. Wollheim, "Single islet beta-cell
stimulation by nutrients: relationship between pyridine nucleotides,
cytosolic Ca2+ and secretion," EMBO J, vol. 9, 1990, pp. 53-60.
[8] D. Salomon and P. Meda, "Heterogeneity and contact-dependent
regulation of hormone secretion by individual B cells," Exp Cell Res,
vol. 162, 1986, pp. 507-520.
[9] P. Smolen, J. Rinzel and A. Sherman, "Why pancreatic islet burst but
single beta cells do not: The heterogeneity hypothesis," Biophys J, vol.
64, 1993, pp. 1668-1680.
[10] S. S. Andrali, M. L. Sampley, N. L. Vanderford and S. Ozcan, "Glucose
regulation of insulin gene expression in pancreatic beta-cells," Biochem
J, vol. 415, 2008, pp. 1-10.
[11] N. Inagaki, K. Yasuda, G. Inoue, Y. Okamoto, H. Yano, Y. Someya, Y.
Ohmoto, K. Deguchi, K. Imagawa, H. Imura and et al., "Glucose as
regulator of glucose transport activity and glucose-transporter mRNA in
hamster beta-cell line," Diabetes, vol. 41, 1992, pp. 592-597.
[12] F. C. Jonkers and J. C. Henquin, "Measurements of cytoplasmic Ca2+ in
islet cell clusters show that glucose rapidly recruits beta-cells and
gradually increases the individual cell response," Diabetes, vol. 50,
2001, pp. 540-550.
[13] A. Jorns, M. Tiedge and S. Lenzen, "Nutrient-dependent distribution of
insulin and glucokinase immunoreactivities in rat pancreatic beta cells,"
Virchows Arch, vol. 434, 1999, pp. 75-82.
[14] N. Pakhtusova, L. Zaostrovskaya, P. Lindstrom and G. Larsson-Nyren,
"Cell-specific Ca(2+) responses in glucose-stimulated single and
aggregated beta-cells," Cell Calcium, vol. 34, 2003, pp. 121-129.
[15] K. Yasuda, Y. Yamada, N. Inagaki, H. Yano, Y. Okamoto, K. Tsuji, H.
Fukumoto, H. Imura, S. Seino, and Y. Seino, "Expression of GLUT1
and GLUT2 glucose transporter isoforms in rat islets of Langerhans and
their regulation by glucose," Diabetes, vol. 41, 1992, pp. 76-81.
[16] V. Poitout, L. E. Stout, M. B. Armstrong, T. F. Walseth, R. L. Sorenson
and R. P. Robertson, "Morphological and functional characterization of
beta TC-6 cells--an insulin-secreting cell line derived from transgenic
mice," Diabetes, vol. 44, 1995, pp. 306-313.
[17] F. Leira, M. C. Louzao, J. M. Vieites, L. M. Botana and M. R. Vieytes,
"Fluorescent microplate cell assay to measure uptake and metabolism of
glucose in normal human lung fibroblasts," Toxicol In Vitro, vol. 16,
2002, pp. 267-273.
[18] K. Yamada, M. Nakata, N. Horimoto, M. Saito, H. Matsuoka and N.
Inagaki, "Measurement of glucose uptake and intracellular calcium
concentration in single, living pancreatic beta-cells," J Biol Chem, vol.
275, 2000, pp. 22278-22283.
[19] K. Yoshioka, K. B. Oh, M. Saito, Y. Nemoto and H. Matsuoka,
"Evaluation of 2-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]-2-
deoxy-D-glucose, a new fluorescent derivative of glucose, for viability
assessment of yeast Candida albicans," Appl Microbiol Biotechnol, vol.
46, 1996, pp. 400-404.
[20] C. Zou, Y. Wang and Z. Shen, "2-NBDG as a fluorescent indicator for
direct glucose uptake measurement," J Biochem Biophys Methods, vol.
64, 2005, pp. 207-215.
[21] G. G. Holz IV, C. A. Leech, and J. F. Habener, "Actication of a cAMPregulated
Ca2+-signaling pathway in pancreatic beta-cells by the
insulinotropic hormone glucagon-like peptide-1," J Bio Chem, vol. 270,
1995, pp. 17749-17757.
[1] D. E. Ingber, The Pancreas: Biology, Pathobiology, and Disease, 1993,
pp. 369-380.
[2] P. E. MacDonald, J. W. Joseph and P. Rorsman, "Glucose-sensing
mechanisms in pancreatic beta-cells," Philos Trans R Soc Lond B Biol
Sci, vol. 360, 2005, pp. 2211-2225.
[3] F. Matschinsky, Y. Liang, P. Kesavan, L. Wang, P. Froguel, G. Velho,
D. Cohen, M. A. Permutt, Y. Tanizawa, T. L. Jetton and et al.,
"Glucokinase as pancreatic beta cell glucose sensor and diabetes gene,"
J Clin Invest, vol. 92, 1993, pp. 2092-2098.
[4] T. Aizawa, T. Kaneko, K. Yamauchi, H. Yajima, T. Nishizawa, T. Yada,
H. Matsukawa, M. Nagai, S. Yamada, Y. Sato, M. Komatsu, N. Itoh, H.
Hidaka, Y. Kajimoto and K. Hashizume, "Size-related and size-unrelated
functional heterogeneity among pancreatic islets," Life Sci, vol. 69,
2001, pp. 2627-2639.
[5] H. Heimberg, A. De Vos, A. Vandercammen, E. Van Schaftingen, D.
Pipeleers and F. Schuit, "Heterogeneity in glucose sensitivity among
pancreatic beta-cells is correlated to differences in glucose
phosphorylation rather than glucose transport," EMBO J, vol. 12, 1993,
pp. 2873-2879.
[6] D. G. Pipeleers, "Heterogeneity in pancreatic beta-cell population,"
Diabetes, vol. 41, 1992, pp. 777-781.
[7] W. F. Pralong, C. Bartley and C. B. Wollheim, "Single islet beta-cell
stimulation by nutrients: relationship between pyridine nucleotides,
cytosolic Ca2+ and secretion," EMBO J, vol. 9, 1990, pp. 53-60.
[8] D. Salomon and P. Meda, "Heterogeneity and contact-dependent
regulation of hormone secretion by individual B cells," Exp Cell Res,
vol. 162, 1986, pp. 507-520.
[9] P. Smolen, J. Rinzel and A. Sherman, "Why pancreatic islet burst but
single beta cells do not: The heterogeneity hypothesis," Biophys J, vol.
64, 1993, pp. 1668-1680.
[10] S. S. Andrali, M. L. Sampley, N. L. Vanderford and S. Ozcan, "Glucose
regulation of insulin gene expression in pancreatic beta-cells," Biochem
J, vol. 415, 2008, pp. 1-10.
[11] N. Inagaki, K. Yasuda, G. Inoue, Y. Okamoto, H. Yano, Y. Someya, Y.
Ohmoto, K. Deguchi, K. Imagawa, H. Imura and et al., "Glucose as
regulator of glucose transport activity and glucose-transporter mRNA in
hamster beta-cell line," Diabetes, vol. 41, 1992, pp. 592-597.
[12] F. C. Jonkers and J. C. Henquin, "Measurements of cytoplasmic Ca2+ in
islet cell clusters show that glucose rapidly recruits beta-cells and
gradually increases the individual cell response," Diabetes, vol. 50,
2001, pp. 540-550.
[13] A. Jorns, M. Tiedge and S. Lenzen, "Nutrient-dependent distribution of
insulin and glucokinase immunoreactivities in rat pancreatic beta cells,"
Virchows Arch, vol. 434, 1999, pp. 75-82.
[14] N. Pakhtusova, L. Zaostrovskaya, P. Lindstrom and G. Larsson-Nyren,
"Cell-specific Ca(2+) responses in glucose-stimulated single and
aggregated beta-cells," Cell Calcium, vol. 34, 2003, pp. 121-129.
[15] K. Yasuda, Y. Yamada, N. Inagaki, H. Yano, Y. Okamoto, K. Tsuji, H.
Fukumoto, H. Imura, S. Seino, and Y. Seino, "Expression of GLUT1
and GLUT2 glucose transporter isoforms in rat islets of Langerhans and
their regulation by glucose," Diabetes, vol. 41, 1992, pp. 76-81.
[16] V. Poitout, L. E. Stout, M. B. Armstrong, T. F. Walseth, R. L. Sorenson
and R. P. Robertson, "Morphological and functional characterization of
beta TC-6 cells--an insulin-secreting cell line derived from transgenic
mice," Diabetes, vol. 44, 1995, pp. 306-313.
[17] F. Leira, M. C. Louzao, J. M. Vieites, L. M. Botana and M. R. Vieytes,
"Fluorescent microplate cell assay to measure uptake and metabolism of
glucose in normal human lung fibroblasts," Toxicol In Vitro, vol. 16,
2002, pp. 267-273.
[18] K. Yamada, M. Nakata, N. Horimoto, M. Saito, H. Matsuoka and N.
Inagaki, "Measurement of glucose uptake and intracellular calcium
concentration in single, living pancreatic beta-cells," J Biol Chem, vol.
275, 2000, pp. 22278-22283.
[19] K. Yoshioka, K. B. Oh, M. Saito, Y. Nemoto and H. Matsuoka,
"Evaluation of 2-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]-2-
deoxy-D-glucose, a new fluorescent derivative of glucose, for viability
assessment of yeast Candida albicans," Appl Microbiol Biotechnol, vol.
46, 1996, pp. 400-404.
[20] C. Zou, Y. Wang and Z. Shen, "2-NBDG as a fluorescent indicator for
direct glucose uptake measurement," J Biochem Biophys Methods, vol.
64, 2005, pp. 207-215.
[21] G. G. Holz IV, C. A. Leech, and J. F. Habener, "Actication of a cAMPregulated
Ca2+-signaling pathway in pancreatic beta-cells by the
insulinotropic hormone glucagon-like peptide-1," J Bio Chem, vol. 270,
1995, pp. 17749-17757.
@article{"International Journal of Biological, Life and Agricultural Sciences:60131", author = "Darren C-W. Tan and Partha Roy", title = "Glucose-dependent Functional Heterogeneity In β-TC-6 Murine Insulinoma", abstract = "To determine if the murine insulinoma, β-TC-6, is a
suitable substitute for primary pancreatic β-cells in the study of β-
cell functional heterogeneity, we used three distinct functional assays
to ascertain the cell line-s response to glucose or a glucose analog.
These assays include: (i) a 2-NBDG uptake assay; (ii) a calcium
influx assay, and; (iii) a quinacrine secretion assay. We show that a
population of β-TC-6 cells endocytoses the glucose analog, 2-
NBDG, at different rates, has non-uniform intracellular calcium ion
concentrations and releases quinacrine at different rates when
challenged with glucose. We also measured the Km for β-TC-6
glucose uptake to be 46.9 mM and the Vm to be 8.36 x 10-5
mmole/million cells/min. These data suggest that β-TC-6 might be
used as an alternative to primary pancreatic β-cells for the study of
glucose-dependent β-cell functional heterogeneity.", keywords = "2-NBDG, Fura-2/AM, functional heterogeneity,
quinacrine.", volume = "3", number = "5", pages = "259-4", }
