Углеводы и термогенез у пчел Apis mellifera
(Carbohydrates and thermogenesis of honeybee Apis mellifera)
Выдержки из работы: Маршаков В.Г. «Биоэнергетика пчелиной семьи и проблемы практического пчеловодства» (готовится к печати)
6. Литература
- Матвеев В.В. (2010). Революция в физиологии клетки? (статья размещена на сайте: http://www.bioparadigma.spb.ru/revolution.htm) (еще: Химия и жизнь, 1994, 8, 42-47)
- Al-Lawati H., Kamp G., Bienefeld K. (2009). Characteristics of the spermathecal contents of old and young honeybee queens. - Journal of Insect Physiology, 55, 2, 117-122.
- Allen M. D. (1959). Respiration rates of worker honeybees of different ages and at different temperatures. - The Journal of Experimental Biology, 36, 92-101.
- Askew G.N., Tregear R.T., Ellington Ch.P. (2010). The scaling of myofibrillar actomyosin ATPase activity in apid bee flight muscle in relation to hovering flight energetics. - The Journal of Experimental Biology 213, 1195-1206.
- Beenakkers A.M.T, Van der Horst D.J, Van Marrewijk J.A. (1984) Insect flight muscle metabolism. - Insect Biochemistry, 14, 243–60.
- Becker A., Schlöder P., Steele J.E., Wegener G. (1996). The regulation of trehalose metabolism in insects. – Experientia (Cellular and Molecular Life Sciences), 52, 5, 433-439.
- Beis I., Newsholme E.A. (1975). The contents of adenine nucleotides, phosphagens and some glycolytic intermediates in resting muscles from vertebrates and invertebrates. - Biochemical Journal, 152, 23-32.
- Blatt J., Roces F. (2001). Haemolymph sugar levels in foraging honeybees (Apis mellifera carnica): dependence on metabolic rate and in vivo measurement of maximal rates of trehalose synthesis. – The Journal of Experimental Biology, 204, 2709-2716.
- Bloxham D.P., Clark M.G., Holland P.C., Lardy H.A. (1973). A model study of the fructose diphosphatase-phosphofructokinase substrate cycle. - Biochemical Journal, 134, 581-586.
- Bosca L., Challiss R.A., Newsholme E.A. (1985). The effect of fructose 2,6-bisphosphate on muscle fructose-1,6-bisphosphatase activity. – Biochim. Biophys. Acta, 828, 2, 151-154.
- Bounias M., Morgan M. R. J. (1984). Induction of honeybee haemolymph sucrase activity by high levels of dietary sucrose. - Comp.Biochem. Physiol., 79B, 75–80.
- Bozic J., Woodring J. (1997). Effect of activity on the haemolymph sugar titres in honey bees. - J. Apic. Res., 36, 33–39.
- Brandt N.R., Huber R.E. (1979). Carbohydrate utilisation in the thoraces of honey bee (Apis mellifera) during early times of flight. - Journal of Insect Physiology, 25, 6, 483-486.
- Brandt N.R., Huber R.E. (1979a). The localization of honey bee thorax trehalose. - Canadian Journal of Biochemistry, 57, 2, 145-154.
- Brandt N.R., Hurlburt K.L., Huber R.E. (1979). The kinetic parameters of trehalase in whole and disrupted mitochondrial preparations from two insects with asynchronous muscle. - Canadian Journal of Biochemistry, 57, 10, 1210-5.
- Chamberlin M.E. (1997). Mitochondrial arginine kinase in the midgut of the tobacco hornworm (Manduca sexta). – The Journal of Experimental Biology, 200, 2789-2796.
- Clark M.G., Bloxham D.P., Holland P.C., Lardy H.A. (1973). Estimation of the fructose diphosphatase-phosphofructokinase substrate cycle in the flight muscle of Bombus affinis. – Biochemical Journal, 134, 2, 589-597.
- Clegg J.S., Evans D.R. (1961). The physiology of blood trehalose and its function during flight in the blowfly. - The Journal of Experimental Biology, 38, 771-792.
- Crabtree B., Newsholme E. A. (1972). The activities of phosphorylase, hexokinase, phosphofructokinase, lactate dehydrogenase and the glycerol 3-phosphate dehydrogenase in muscle from vertebrates and invertebrates. - Biochemical Journal, 126, 49-58.
- Crabtree B., Newsholme E. A. (1972). The Activities of lipases and carnitine pahnitoyltransferase in muscles from vertebrates and invertebrates. - Biochemical Journal, 130, 697-705.
- Dzeja P. P., Terzic A. (2003. Phosphotransfer networks and cellular energetic. - The Journal of Experimental Biology, 206, 2039-2047.
- Ellington C.P., Machin K.E., Casey T.M. (1990). Oxygen consumption of bumblebees forward flight. – Nature, 347, 472-473.
- Ellington W.R. (1989). Phosphocreatine represents a thermodynamic and functional improvement over other muscle phosphagenes. - The Journal of Experimental Biology, 143, 177-189.
- Ellington W.R., Hines A.C. (1991). Mitochondrial activities of phosphagen kinases are not widely distributed in the invertebrates. – Biol. Bull., 180, 505-507.
- Esch H. (1976). Body temperature and flight performance of honey bees in a servomechanically controlled wind tunnel. - Journal of Comparative Physiology, 109, 265-277.
- Esch H. (1988). The effects of temperature on flight muscle potentials in honeybees and cuculiinid winter moths. - The Journal of Experimental Biology, 135, 109-117.
- Esch H., Nachtigall W., Kogge S. N. (1975). Correlations between aerodynamic output, electrical activity in the indirect flight muscles and wing positions of bees flying in a servomechanically controlled wind tunnel. - Journal of Comparative Physiology, 100, 147-159.
- Esch H., Goller F. (1991). Neural control of fibrillar muscles in bees during shivering and flight. – Journal of Experimental Biology, 159, 419-431.
- Gmeinbauer R., Crailsheim K. (1993). Glucose utilization during flight of honeybee (Apis mellifera) workers, drones and queens. - Journal of Insect Physiology, 39, 11, 959-967 (st).
- Goller F., Esch H. (1990). Comparative study of chill-coma temperatures and muscle potentials in insect flight muscles. - Journal of Experimental Biology, 150, 221-231.
- Greive H., Surholt B. (1990). Dependence of fructose-bis-phosphatase from flight muscles of the bumblebee (Bombus terrestris L.) on calcium. - Comp. Biochem. Physiol., 97B, 197-200.
- Fell R. D. (1990). The qualitative and quantitative analysis of insect hemolymph sugars by high performance thin-layer chromatography. - Comp.Biochem. Physiol., 95A, 539–544.
- Harrison J.M. (1987). Roles of individual honeybee workers and drones in colonial thermogenesis - J. exp. Biol. 129, 53-61.
- Heinrich B. (1972). Temperature regulation in the bumblebee Bombus vagans: a field study. – Science, 175, 185-187.
- Heinrich B. (1980). Mechanisms of body-temperature regulation in honeybees, Apis mellifera. I. Regulation of head temperature. - Journal of Experimental Biology, 85, 61-72.
- Heinrich B. (1980). Mechanisms of body-temperature regulation in honeybees, Apis mellifera. II. Regulation of thoracic temperature at high air temperatures. - Journal of Experimental Biology, 85, 73-87.
- Heinrich B., Kammer A. E. (1973). Activation of the fibrillar muscles in the bumblebee during warm-up, stabilization and flight. - Journal of Experimental Biology, 58, 67-688.
- Himmer A. (1927). Ein Beitrag zur Kenntnis des Warmehaushalts im Nestbau Sozialer Hautfluger. - Zeitschrift fur Vergleichende Physiologie 5, 375-379.
- Himmer A. (1927). Der soziale Wa?rmehaushalt der Ho?ngbiene. II. Die Wa?rme der Bienenbrut. - Erlanger Jb. Bienenkd. 5, 1-32.
- Himmer A. (1932). Die Temperaturverhaeltnisse bei den sozialen Hymenopteren. - Biological Review, 7, 224-253.
- Jacobus W. E. (1985). Theoretical support for the heart phosphocreatine energy transport shuttle based on the intracellular diffusion limited mobility of ADP. - Biochem. Biophys. Res. Commun., 133, 1035-1041.
- Josephson R. K., Malamud J. G., Stokes D. R. (2000). Asynchronous muscle: a primer. - The Journal of Experimental Biology, 203, 2713-2722.
- Kammer A. E., Heinrich B. (1974). Metabolic rates related to muscle activity in bumblebees. - The Journal of Experimental Biology, 61, 219-227.
- Kammer A. E., Heinrich B. (1978). Insect flight metabolism. - Adv. Insect Physiol. 13, 133–228.
- Krogh A., Zeuthen E. (1941). The mechanism of flight preparation in some insects. - The Journal of Experimental Biology, 18, 1-10.
- Kucharski R., Maleszka R. (1998). Arginine kinase is highly expressed in the compound eye of the honey-bee, Apis mellifera. - Gene, 211, 2, 343-349.
- Jung S-K., Kauri L.M., Qian W-J., Kennedy R.T. (2000).Correlated oscillations in glucose consumption, oxygen consumption, and intracellular free Ca21 in single islets of Langerhans. - The Journal of Biological Chemistry, 275, 9, 6642–6650.
- Lefebvre Y.A., Huber R.E. (1970). Solubilization, purification and properties of trehalase from honeybee (Apis mellifera) – Archiv. Biochem. Biophys., 140, 514-518.
- Lee J., Tsui M., Nakamura M., Nishimito M., Okuyama M., Mori H., Kimura A., Matsui H., Chiba S. (2001). Purification and identification of the essential ionizable groups of honeybee trehalase. – Biosci. Biotechnol. Biochem., 65, 12, 2657-2665.
- Leite A., Neto J.A., Leyton J.F., Crivellaro O., El-Dorry H.A. (1988) Phosphofructokinase from bumble bee flight muscle. Molecular and catalytic properties and role of the enzyme in regulation of the fructose-6-phosphate/fructose-1,6-biphosphate cycle. – The Journal of Biological Chemistry, 263, 33, 17527-17533.
- Leta M. A., Gilbert C., Morse R. A. (1996). Levels of hemolymph sugars and body glycogen of honeybees (Apis mellifera L.) from colonies preparing to swarm. - J. Insect Physiol., 42, 239–245.
- Lighton J.R., Lovegrove B.G. (1990). A temperature-induced switch from diffusive to convective ventilation in the honeybee. - Journal of Experimental Biology, 154, 509-516.
- McMullen D. C., Ramnanan C. J., Storey K.B. (2010). In cold-hardy insects, seasonal, temperature, and reversible phosphorylation controls regulate sarco/endoplasmic reticulum Ca2+-ATPase (SERCA). - Physiol Biochem Zool., 83, 4, 677-86.
- Meyer R. A., Sweeney H. L., Kushmerick M. J. (1984). A simple analysis of the phosphocreatine shuttle. - Am. J. Physiol., 246, C365-C377.
- Nachtigall W., Rothe U., Feller P., Jungmann R. (1989). Flight of the honey bee. III. Flight metabolic power calculated from gas analysis, thermoregulation and fuel consumption. – Journal of Comparative Physiology, B 158, 729–737.
- Nachtigall W., Hanauer-Thieser U., Morz M. (1995). Flight of the honey bee VII: metabolic power versus flight speed relation. - J. Comp. Physiol. B 165, 484-489.
- Newsholme E.A., Crabtree B., Higgins S.J., Thornton S.D., Start C. (1972). The activities of fructose diphosphatase in flight muscles from the bumble-bee and the role of this enzyme in heat generation. - Biochemical Journal, 128, 89-97.
- Newsholme E.A, Crabtree B. (1976). Substrate cycles in metabolic regulation and in heat generation. – Biochem. Soc. Symp., 41, 61-109.
- Newsholme E.A. (1978). Substrate cycles: their metabolic, energetic and thermic consequences in man. – Biochem. Soc. Symp., 43, 183-205.
- Ørtenblad N., Macdonald W.A., Sahlin K. (2009). Glycolysis in contracting rat skeletal muscle is controlled by factors related to energy state - Biochemistry Journal, 420, 161–168.
- Read G., Crabtree B., Smith G.H. (1 977).The activities of 2-oxoglutarate dehydrogenase and pyruvate dehydrogenase in hearts and mammary glands from ruminants and non-ruminants. - Biochemistry Journal, 164, 349-355.
- Roces F., Blatt J. (1999). Haemolymph sugars and the control of the proventriculus in the honey bee Apis mellifera. – Journal of Insect Physiology, 45, 221–229.
- Schneider A., Wiesner R.J., Grieshaber M.K. (1989). On the role of arginine kinase in insect flight muscle. - Insect Biochemistry, 19, 471-480.
- Schultze-Motel P. (1991). Heat loss and thermoregulation in a nest of the bumblebee Bombus lapidarius (Hymenoptera, Apidae). - Thermochim. Acta, 193, 57–66.
- Schultze-Motel P., Lamprecht I. (1994). Correlation of sound generation and metabolic heat flux in the bumblebee Bombus lapidarius. – The Journal of Experimental Biology, 187, 315-318.
- Sinclair B.J., Klok C.J., Chown S.L. (2004). Metabolism of the sub-Antarctic caterpillar Pringleophaga marioni during cooling, freezing and thawing. - The Journal of Experimental Biology, 207, 1287-1294.
- Staples J.F., Koen E.L., Laverty T.M. (2004). ‘Futile cycle’ enzymes in the flight muscles of North American bumblebees. - The Journal of Experimental Biology, 207, 749-754.
- Storey K. B. (1978). Purification and properties of fructose diphosphatase from bumblebee flight muscle. - Biochim. Biophys. Acta, 523, 443-453.
- Suarez R.K. (2003). Shaken and stirred: muscle structure and metabolism. – The Journal of Experimental Biology, 206, 2021-2029.
- Suarez R.K., Lighton J.R.B., Joos B., Roberts S.P., Harrison J.F. (1996). Energy metabolism, enzymatic flux capacities and metabolic flux rates in flying honeybees. – Proceedings of the National Academy of Sciences. U.S.A., 93, 12616-12620.
- Suarez R. K., Staples J. F., Lighton J. R. B., Mathieu-Costello O. (2000). Mitochondrial function in flying honeybees (Apis mellifera): respiratory chain enzymes and electron flow from complex III to oxygen. - Journal of Experimental Biology, 203, 905-911.
- Surholt B., Newsholme E.A. (1981). Maximum activities and properties of glucose 6-phosphatase in muscles from vertebrates and invertebrates. – Biochemistry Journal, 198, 621-629.
- Surholt B., Greive H., Baal T., Bertsch A. (1990). Non-shivering thermogenesis in asynchronous fligt muscles of bumblebees? Comparative studies on males of Bombus terrestris, Xylocopa sulcatipes and Acherontia atropos. – Comp. Biochem. Physiol., A97, 493-499.
- Surholt B., Greive H., Baal T., Bertsch A. (1991). Warm-up and substrate cycling in flight muscles of male bumblebees, Bombus terrestris. – Comp. Biochem. Physiol., A98, 299-303.
- Talbot B.G., Muir J.G., Huber R.E. (1975). Properties of a free and a solubilized form of bound a,a-trehalase purified from honey bee thorax. – Canad. J. Biochem., 53, 1106-1117.
- Wegener G. (1996). Flying insects: model systems in exercise physiology. - Experientia, 52, 5, 404-412.
- Wegener G., Schmidt H., Leecht A.R., Newsholme E.A. (1986). Antagonistic effects of hexose 1,6-bisphosphates and fructose 2,6-bisphosphate on the activity of 6-phosphofructokinase purified from honey-bee flight muscle. - Biochemical Journal , 236, 925-928.
- Wolf T. J., Ellington C. P., Davis S., Feltham M. J. (1996). Validation of the doubly labelled water technique for bumblebees Bombus terrestris (L.). - The Journal of Experimental Biology, 199, 959-972.
- Woodring J., Boulden M., Das S., Gade G. (1993) Studies on blood sugar homeostasis in the honeybee (Apis mellifera, L.) - Journal of Insect Physiology, 39, 1, 89-97.
6. Литература
- Матвеев В.В. (2010). Революция в физиологии клетки? (статья размещена на сайте: http://www.bioparadigma.spb.ru/revolution.htm) (еще: Химия и жизнь, 1994, 8, 42-47)
- Al-Lawati H., Kamp G., Bienefeld K. (2009). Characteristics of the spermathecal contents of old and young honeybee queens. - Journal of Insect Physiology, 55, 2, 117-122.
- Allen M. D. (1959). Respiration rates of worker honeybees of different ages and at different temperatures. - The Journal of Experimental Biology, 36, 92-101.
- Askew G.N., Tregear R.T., Ellington Ch.P. (2010). The scaling of myofibrillar actomyosin ATPase activity in apid bee flight muscle in relation to hovering flight energetics. - The Journal of Experimental Biology 213, 1195-1206.
- Beenakkers A.M.T, Van der Horst D.J, Van Marrewijk J.A. (1984) Insect flight muscle metabolism. - Insect Biochemistry, 14, 243–60.
- Becker A., Schlöder P., Steele J.E., Wegener G. (1996). The regulation of trehalose metabolism in insects. – Experientia (Cellular and Molecular Life Sciences), 52, 5, 433-439.
- Beis I., Newsholme E.A. (1975). The contents of adenine nucleotides, phosphagens and some glycolytic intermediates in resting muscles from vertebrates and invertebrates. - Biochemical Journal, 152, 23-32.
- Blatt J., Roces F. (2001). Haemolymph sugar levels in foraging honeybees (Apis mellifera carnica): dependence on metabolic rate and in vivo measurement of maximal rates of trehalose synthesis. – The Journal of Experimental Biology, 204, 2709-2716.
- Bloxham D.P., Clark M.G., Holland P.C., Lardy H.A. (1973). A model study of the fructose diphosphatase-phosphofructokinase substrate cycle. - Biochemical Journal, 134, 581-586.
- Bosca L., Challiss R.A., Newsholme E.A. (1985). The effect of fructose 2,6-bisphosphate on muscle fructose-1,6-bisphosphatase activity. – Biochim. Biophys. Acta, 828, 2, 151-154.
- Bounias M., Morgan M. R. J. (1984). Induction of honeybee haemolymph sucrase activity by high levels of dietary sucrose. - Comp.Biochem. Physiol., 79B, 75–80.
- Bozic J., Woodring J. (1997). Effect of activity on the haemolymph sugar titres in honey bees. - J. Apic. Res., 36, 33–39.
- Brandt N.R., Huber R.E. (1979). Carbohydrate utilisation in the thoraces of honey bee (Apis mellifera) during early times of flight. - Journal of Insect Physiology, 25, 6, 483-486.
- Brandt N.R., Huber R.E. (1979a). The localization of honey bee thorax trehalose. - Canadian Journal of Biochemistry, 57, 2, 145-154.
- Brandt N.R., Hurlburt K.L., Huber R.E. (1979). The kinetic parameters of trehalase in whole and disrupted mitochondrial preparations from two insects with asynchronous muscle. - Canadian Journal of Biochemistry, 57, 10, 1210-5.
- Chamberlin M.E. (1997). Mitochondrial arginine kinase in the midgut of the tobacco hornworm (Manduca sexta). – The Journal of Experimental Biology, 200, 2789-2796.
- Clark M.G., Bloxham D.P., Holland P.C., Lardy H.A. (1973). Estimation of the fructose diphosphatase-phosphofructokinase substrate cycle in the flight muscle of Bombus affinis. – Biochemical Journal, 134, 2, 589-597.
- Clegg J.S., Evans D.R. (1961). The physiology of blood trehalose and its function during flight in the blowfly. - The Journal of Experimental Biology, 38, 771-792.
- Crabtree B., Newsholme E. A. (1972). The activities of phosphorylase, hexokinase, phosphofructokinase, lactate dehydrogenase and the glycerol 3-phosphate dehydrogenase in muscle from vertebrates and invertebrates. - Biochemical Journal, 126, 49-58.
- Crabtree B., Newsholme E. A. (1972). The Activities of lipases and carnitine pahnitoyltransferase in muscles from vertebrates and invertebrates. - Biochemical Journal, 130, 697-705.
- Dzeja P. P., Terzic A. (2003. Phosphotransfer networks and cellular energetic. - The Journal of Experimental Biology, 206, 2039-2047.
- Ellington C.P., Machin K.E., Casey T.M. (1990). Oxygen consumption of bumblebees forward flight. – Nature, 347, 472-473.
- Ellington W.R. (1989). Phosphocreatine represents a thermodynamic and functional improvement over other muscle phosphagenes. - The Journal of Experimental Biology, 143, 177-189.
- Ellington W.R., Hines A.C. (1991). Mitochondrial activities of phosphagen kinases are not widely distributed in the invertebrates. – Biol. Bull., 180, 505-507.
- Esch H. (1976). Body temperature and flight performance of honey bees in a servomechanically controlled wind tunnel. - Journal of Comparative Physiology, 109, 265-277.
- Esch H. (1988). The effects of temperature on flight muscle potentials in honeybees and cuculiinid winter moths. - The Journal of Experimental Biology, 135, 109-117.
- Esch H., Nachtigall W., Kogge S. N. (1975). Correlations between aerodynamic output, electrical activity in the indirect flight muscles and wing positions of bees flying in a servomechanically controlled wind tunnel. - Journal of Comparative Physiology, 100, 147-159.
- Esch H., Goller F. (1991). Neural control of fibrillar muscles in bees during shivering and flight. – Journal of Experimental Biology, 159, 419-431.
- Gmeinbauer R., Crailsheim K. (1993). Glucose utilization during flight of honeybee (Apis mellifera) workers, drones and queens. - Journal of Insect Physiology, 39, 11, 959-967 (st).
- Goller F., Esch H. (1990). Comparative study of chill-coma temperatures and muscle potentials in insect flight muscles. - Journal of Experimental Biology, 150, 221-231.
- Greive H., Surholt B. (1990). Dependence of fructose-bis-phosphatase from flight muscles of the bumblebee (Bombus terrestris L.) on calcium. - Comp. Biochem. Physiol., 97B, 197-200.
- Fell R. D. (1990). The qualitative and quantitative analysis of insect hemolymph sugars by high performance thin-layer chromatography. - Comp.Biochem. Physiol., 95A, 539–544.
- Harrison J.M. (1987). Roles of individual honeybee workers and drones in colonial thermogenesis - J. exp. Biol. 129, 53-61.
- Heinrich B. (1972). Temperature regulation in the bumblebee Bombus vagans: a field study. – Science, 175, 185-187.
- Heinrich B. (1980). Mechanisms of body-temperature regulation in honeybees, Apis mellifera. I. Regulation of head temperature. - Journal of Experimental Biology, 85, 61-72.
- Heinrich B. (1980). Mechanisms of body-temperature regulation in honeybees, Apis mellifera. II. Regulation of thoracic temperature at high air temperatures. - Journal of Experimental Biology, 85, 73-87.
- Heinrich B., Kammer A. E. (1973). Activation of the fibrillar muscles in the bumblebee during warm-up, stabilization and flight. - Journal of Experimental Biology, 58, 67-688.
- Himmer A. (1927). Ein Beitrag zur Kenntnis des Warmehaushalts im Nestbau Sozialer Hautfluger. - Zeitschrift fur Vergleichende Physiologie 5, 375-379.
- Himmer A. (1927). Der soziale Wa?rmehaushalt der Ho?ngbiene. II. Die Wa?rme der Bienenbrut. - Erlanger Jb. Bienenkd. 5, 1-32.
- Himmer A. (1932). Die Temperaturverhaeltnisse bei den sozialen Hymenopteren. - Biological Review, 7, 224-253.
- Jacobus W. E. (1985). Theoretical support for the heart phosphocreatine energy transport shuttle based on the intracellular diffusion limited mobility of ADP. - Biochem. Biophys. Res. Commun., 133, 1035-1041.
- Josephson R. K., Malamud J. G., Stokes D. R. (2000). Asynchronous muscle: a primer. - The Journal of Experimental Biology, 203, 2713-2722.
- Kammer A. E., Heinrich B. (1974). Metabolic rates related to muscle activity in bumblebees. - The Journal of Experimental Biology, 61, 219-227.
- Kammer A. E., Heinrich B. (1978). Insect flight metabolism. - Adv. Insect Physiol. 13, 133–228.
- Krogh A., Zeuthen E. (1941). The mechanism of flight preparation in some insects. - The Journal of Experimental Biology, 18, 1-10.
- Kucharski R., Maleszka R. (1998). Arginine kinase is highly expressed in the compound eye of the honey-bee, Apis mellifera. - Gene, 211, 2, 343-349.
- Jung S-K., Kauri L.M., Qian W-J., Kennedy R.T. (2000).Correlated oscillations in glucose consumption, oxygen consumption, and intracellular free Ca21 in single islets of Langerhans. - The Journal of Biological Chemistry, 275, 9, 6642–6650.
- Lefebvre Y.A., Huber R.E. (1970). Solubilization, purification and properties of trehalase from honeybee (Apis mellifera) – Archiv. Biochem. Biophys., 140, 514-518.
- Lee J., Tsui M., Nakamura M., Nishimito M., Okuyama M., Mori H., Kimura A., Matsui H., Chiba S. (2001). Purification and identification of the essential ionizable groups of honeybee trehalase. – Biosci. Biotechnol. Biochem., 65, 12, 2657-2665.
- Leite A., Neto J.A., Leyton J.F., Crivellaro O., El-Dorry H.A. (1988) Phosphofructokinase from bumble bee flight muscle. Molecular and catalytic properties and role of the enzyme in regulation of the fructose-6-phosphate/fructose-1,6-biphosphate cycle. – The Journal of Biological Chemistry, 263, 33, 17527-17533.
- Leta M. A., Gilbert C., Morse R. A. (1996). Levels of hemolymph sugars and body glycogen of honeybees (Apis mellifera L.) from colonies preparing to swarm. - J. Insect Physiol., 42, 239–245.
- Lighton J.R., Lovegrove B.G. (1990). A temperature-induced switch from diffusive to convective ventilation in the honeybee. - Journal of Experimental Biology, 154, 509-516.
- McMullen D. C., Ramnanan C. J., Storey K.B. (2010). In cold-hardy insects, seasonal, temperature, and reversible phosphorylation controls regulate sarco/endoplasmic reticulum Ca2+-ATPase (SERCA). - Physiol Biochem Zool., 83, 4, 677-86.
- Meyer R. A., Sweeney H. L., Kushmerick M. J. (1984). A simple analysis of the phosphocreatine shuttle. - Am. J. Physiol., 246, C365-C377.
- Nachtigall W., Rothe U., Feller P., Jungmann R. (1989). Flight of the honey bee. III. Flight metabolic power calculated from gas analysis, thermoregulation and fuel consumption. – Journal of Comparative Physiology, B 158, 729–737.
- Nachtigall W., Hanauer-Thieser U., Morz M. (1995). Flight of the honey bee VII: metabolic power versus flight speed relation. - J. Comp. Physiol. B 165, 484-489.
- Newsholme E.A., Crabtree B., Higgins S.J., Thornton S.D., Start C. (1972). The activities of fructose diphosphatase in flight muscles from the bumble-bee and the role of this enzyme in heat generation. - Biochemical Journal, 128, 89-97.
- Newsholme E.A, Crabtree B. (1976). Substrate cycles in metabolic regulation and in heat generation. – Biochem. Soc. Symp., 41, 61-109.
- Newsholme E.A. (1978). Substrate cycles: their metabolic, energetic and thermic consequences in man. – Biochem. Soc. Symp., 43, 183-205.
- Ørtenblad N., Macdonald W.A., Sahlin K. (2009). Glycolysis in contracting rat skeletal muscle is controlled by factors related to energy state - Biochemistry Journal, 420, 161–168.
- Read G., Crabtree B., Smith G.H. (1 977).The activities of 2-oxoglutarate dehydrogenase and pyruvate dehydrogenase in hearts and mammary glands from ruminants and non-ruminants. - Biochemistry Journal, 164, 349-355.
- Roces F., Blatt J. (1999). Haemolymph sugars and the control of the proventriculus in the honey bee Apis mellifera. – Journal of Insect Physiology, 45, 221–229.
- Schneider A., Wiesner R.J., Grieshaber M.K. (1989). On the role of arginine kinase in insect flight muscle. - Insect Biochemistry, 19, 471-480.
- Schultze-Motel P. (1991). Heat loss and thermoregulation in a nest of the bumblebee Bombus lapidarius (Hymenoptera, Apidae). - Thermochim. Acta, 193, 57–66.
- Schultze-Motel P., Lamprecht I. (1994). Correlation of sound generation and metabolic heat flux in the bumblebee Bombus lapidarius. – The Journal of Experimental Biology, 187, 315-318.
- Sinclair B.J., Klok C.J., Chown S.L. (2004). Metabolism of the sub-Antarctic caterpillar Pringleophaga marioni during cooling, freezing and thawing. - The Journal of Experimental Biology, 207, 1287-1294.
- Staples J.F., Koen E.L., Laverty T.M. (2004). ‘Futile cycle’ enzymes in the flight muscles of North American bumblebees. - The Journal of Experimental Biology, 207, 749-754.
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В.Г. Маршаков,
e-mail: volmar_georg@mail.ru