Protein content and electrophoretic profile of fat body and ovary extracts from workers of Melipona quadrifasciata anthidioides (Hymenoptera, Meliponini)

Oliveira, Vagner T. Paes de; Cruz-Landim, Carminda da

doi:10.1590/S0073-47212004000400010

Abstract

Workers of Melipona quadrifasciata anthidioides (Lepeletier, 1836) develop their ovaries and lay eggs, therefore the production of vitellogenin is expected. In electrophoretic profiles only fat body extracts from nurse workers and ovary extracts from newly-emerged workers show protein with molecular mass similar to vitellogenin. However, an increase in the protein content was detected in forager fat body. This increase was attributed to storage of vitellogenin or other proteins in the previous phase and not discharged into the hemolymph or to an effect of the increased titre of juvenile hormone in this phase of worker life over the fat body functioning.

Stingless bees; fat body; ovary; vitellogenin; oogenesis

Protein content and electrophoretic profile of fat body and ovary extracts from workers of Melipona quadrifasciata anthidioides (Hymenoptera, Meliponini)

Vagner T. Paes de Oliveira; Carminda da Cruz-Landim

Departamento de Biologia, Instituto de Biociências de Rio Claro, Universidade Estadual Paulista (UNESP), Av. 24A, n° 1515, Bela Vista, 13506-900 Rio Claro, SP, Brazil. (vagnertadeu@yahoo.com.br; cclandim@rc.unesp.br)

ABSTRACT

Workers of Melipona quadrifasciata anthidioides (Lepeletier, 1836) develop their ovaries and lay eggs, therefore the production of vitellogenin is expected. In electrophoretic profiles only fat body extracts from nurse workers and ovary extracts from newly-emerged workers show protein with molecular mass similar to vitellogenin. However, an increase in the protein content was detected in forager fat body. This increase was attributed to storage of vitellogenin or other proteins in the previous phase and not discharged into the hemolymph or to an effect of the increased titre of juvenile hormone in this phase of worker life over the fat body functioning.

Keywords: Stingless bees, fat body, ovary, vitellogenin, oogenesis.

INTRODUCTION

The insect fat body has basically two functions. One is related to the intermediate metabolism, which is responsible for the metabolic processes of synthesis of hemolymph proteins, storage of substances, such as lipids, proteins and carbohydrates (WIGGLESWORTH, 1942; WYATT, 1980; KEELEY, 1985; ROSELL & WHEELER, 1995) and accumulation of toxic materials such as urate (BABTHAN & GILBERT, 1972; LOCKE, 1984; CRUZ-LANDIM, 1985; DEAN et al., 1985). The other is the active participation in vitellogenesis, supplying the soluble precursor for the yolk, i.e., vitellogenin (ENGELMANN, 1971; BEHAN & HAGEDORN, 1978; TADBOWSKI & JONES, 1979). In bees the first function of these cells is carried out in the immature phases, mainly in the larval phase, and the second mainly in the adults (PAES-OLIVEIRA & CRUZ-LANDIM, 2003B).

Fat body is the main source for the proteins found in the hemolymph (PALLI & LOCKE, 1988). There is a constant exchange between the fat body and the hemolymph with alternate phases of release and absorption of proteins (CRUZ-LANDIM, 1983; MARX, 1987). Ultrastructural studies have shown that some proteins of the fat body are not synthesized in its cells, but just stored there after intake from the hemolymph (LOCkE & COLLINS, 1966; Price, 1973; THOMSEN & THOMSEN, 1978; WYATt, 1980).

In adult female insects, vitellogenin, a lipoglycoprotein with molecular mass of 180 kDa, is synthesized in the fat body cells and later secreted into the hemolymph from where it is absorbed by the oocytes in the ovary through the follicular epithelium (ENGELS, 1973; ENGELS et al., 1990). The production of this protein, therefore, is the main function of the fat body cells of adult females (BROOKES, 1969; PAN et al., 1969).

The aim of the present study was to quantify the total proteins in the fat body and ovaries of adult workers of Melipona quadrifasciata anthidioides (Lepeletier, 1836), and to observe eventual differences and similarities in the molecular masses of the proteins present in each phase, in comparison with the stages of ovarian development.

MATERIAL AND METHODS

Adult workers of Melipona quadrifasciata anthidioides were obtained from the apiary of the Instituto de Biociências, Universidade Estadual Paulista, Rio Claro. Workers were classified as newly-emerged when captured just emerging from the brood cells, as nurses when captured in the brood area of the colony, while building and provisioning the brood cells, and as forager workers when returning from the field to the colony.

Portions of the parietal fat body and entire ovaries of 10 newly-emerged, nurse and forager workers, with one replicate, were used, for a total of 60 individuals. The material was dissected and stored at -20°C for protein quantification and polyacrylamide gel electrophoresis. The tissue was homogenized in 40 µl distilled water and centrifuged at 8,160 g for five minutes. Aliquots of the supernatant extracts were used for total protein quantification by Coomassie Blue staining according to the method of SEDMAK & GROSSBERG (1977), modified.

Electrophoretic separation of the proteins present in the fat body and ovary extracts was routinely performed in a 5-20% gradient of polyacrylamide slab gels run under denaturing conditions Sodium Dodecyl Sulphate Polyacrylamide Gel Electrophoresis (SDS-PAGE). Samples from fat body and ovary extracts containing 60 µg protein diluted in buffer were boiled for 5 min, centrifuged at 8,160 g at 5°C and loaded onto the polyacrylamide gels. After electrophoresis, the gels were stained with Coomassie Brillant Blue R-250. Molecular weight markers (MW standard mixture, P7708S-BioLabs) were used as standards to determine the relative molecular mass of protein in the fat body and ovary.

RESULTS

The concentration of proteins was higher in the ovary extracts than in the fat body extracts in newly-emerged and nurse workers, but this situation was inverted in forager workers (fig. 1).

The fat body of newly-emerged workers (fig. 2) lacks the proteins of high molecular mass present in the ovaries, whereas in fat body extracts from nurse workers there is a protein of high molecular mass. There is a similarity between the molecular masses of the bands present in the fat body and ovaries in each stage and little variation among the same tissues in the different stages.

DISCUSSION

The protein content in worker fat body extracts increased with aging, while in the ovaries, as expected, the protein content presented a peak in the nurse phase, during which the workers have vitellogenic ovaries and may lay eggs (SAKAGAMI et al., 1963; BEIG & SAKAGAMI, 1964; BEGO, 1983; PAES-DE-OLIVEIRA & CRUZ-LANDIM, 2003A).

The largest protein content in the ovary extracts coincides with the higher developmental rate of the ovaries in nurse workers. Even for the points considered here as the peak of protein concentration, the values were low as a consequence of the poor ovarian development of workers compared to physogastric queens.

The most intriguing data related to protein content in the fat body extracts are those for forager workers, which show 3-fold higher levels than newly-emerged workers and 2-fold higher levels than nurse workers. Protein content would be expected to be high at the beginning of development (newly-emerged) and to decline with time since morphometric analysis of the fat body cells demonstrates a decrease in cell size related to workers' aging, attributed to the use of cell reserves in order to supply vitellogenin to the ovaries during the vitellogenic period (PAES-DE-OLIVEIRA & CRUZ-LANDIM, 2003a). Nevertheless, the higher protein content observed during this phase agree with the great development of the granular endoplasmic reticulum observed in the fat body cells of foragers and with the hypothesis that not all produced vitellogenin is used during the nurse phase or that not every produced protein is vitellogenin, since proteins of high molecular weight are not observed in the fat body or ovary extracts of forager workers (fig. 2). HARTFELDER & ENGELS (1998) demonstrated that vitellogenin is present in the hemolymph of queens and workers of Apis mellifera Linnaeus, 1758 at almost the same rates; therefore it is probable that, due to the short duration of the vitellogenic phase in workers, vitellogenin or even other proteins are stored in the fat body. In this respect, the divergence between the cell size and the protein content may be explained by the consumption of lipids, which occupy a lot of space and are present in smaller amounts in nurse workers compared to newly-emerged workers (PAES-DE-OLIVEIRA & CRUZ-LANDIM, 2003a)

Since the change from intranidal to extranidal work is mediated by an increase in juvenile hormone concentration in the hemolymph (JAYCOX et al., 1974; FLURI et al., 1982; HUANG et al., 1991), the foragers have higher titres of this hormone than nurse workers. It is known that juvenile hormone controls vitellogenin synthesis by the fat body cells in adult females (ADAMCZYK et al., 1996) and also has a somatotrophic function, activating the general metabolism of the insect (JAYCOX et al., 1974; HUANG et al., 1991). This condition would explain the development of the granular endoplasmic reticulum in the fat body cells of workers during this phase and eventually the occurrence of synthesis of vitellogenin or other proteins in these cells, targeted by the increased hormonal levels. The electrophoretic pattern here observed (fig. 2) does not show proteins of high molecular mass in the extracts of the fat body in this phase. Thus, other proteins may be produced, but not vitellogenin. The high energy consumption by foragers during flight may be responsible for the decrease in lipid storage in the fat body and therefore for the increase in the relative protein rates in the cells. In this case, the decrease in cell size may be due to the lipid loss. The relatively low protein rate in forager workers' ovaries is due to the regressive phase in this organ (PAES-DE-OLIVEIRA & CRUZ-LANDIM, 2003a).

In conclusion, there is an unexpected discrepancy between the protein content and electrophoretic pattern of the fat body and ovarian extracts. Nevertheless these discordances may be explained by taking into account the chronological differences in the development of these organs and the general physiological conditions that can interfere with this development.

Acknowledgments. To Fundação de Amparo à Pesquisa do Estado de São Paulo (Proc. 99/12387-8) and Conselho Nacional de Desenvolvimento Científico e Tecnológico (Proc. 351016194-5) for financial support.

Recebido em agosto de 2003. Aceito em agosto de 2004.

ADAMCZYK, J. J.; FESMYER, H. W. et al. 1996. Sex-specific and hormone controlled expression of a vitellogenin-encoding gene in the gypsy moth. Archives of Insect Biochemistry and Physiology, New York, 31(3):237-256.
BABTHAN, M. & GILBERT, L. I. 1972. Studies on the cytophysiology of the fat body of American silk-moth. Zeitschrift für Zellforschung und Mikroskopische Anatomie, Berlin, 124:433-444.
BEGO, L. R. 1983. On some aspects of bionomics in Melipona bicolor bicolor Lepeletier (Hymenoptera, Apidae, Meliponinae). Revista Brasileira de Entomologia, São Paulo, 27:211-224.
BEHAN, M. & HAGEDORN, H. H. 1978. Ultrastructural changes in fat body of adult female Aedes aegypti in relationship to vitellogenin synthesis. Cell and Tissue Research, New York, 186:499-506.
BEIG, D. & SAKAGAMI, S. F. 1964. Behavior studies of the stingless bees, with special reference to the ovoposition process II. Melipona seminigra merrillae Cockerell. Annotationes Zoologicae Japonenses, Tokyo, 37(2):112-119.
BROOKES, V. J. 1969. The induction of yolk protein synthesis in the fat body of an insect. Leucophaea maderae, by an analog of the juvenile hormone. Development Biology, New York, 20:459-471.
CRUZ-LANDIM, C. 1983. O corpo gorduroso da larva de Melipona quadrifasciata anthidioides LEP. (Apidae, Meliponinae). Naturalia, São Paulo, 8:7-23.
__. 1985. Modificações das células do corpo gorduroso de rainhas de Apis mellifera L. (Hymenoptera, Apidae). Ciência e Cultura, São Paulo, 37:471-475.
DEAN, R. L.; LOCKE, M. & COLLINS, J. V. 1985. Structure of fat body. In: Kerbut, G. A. & Gilbert, L. I. Comprehensive insect physiology, biochemistry and pharmacology Oxford, Pergamon. v.3, p.155-210.
ENGELMANN, F. 1971. Juvenile hormone - controlled synthesis of female specific protein in the cockroach Leucophae maderae Archives of Biochemistry and Biophysics, New York, 145:439-447.
ENGELS, W. 1973. Das zeitliche und räumliche Muster der Dottereinlagerung in die Oocyte von Apis mellifera Zeitschrift für Zellforschung und Mikroskopische Anatomie, Berlin, 142:409-430.
ENGELS, W.; KAATZ, H. et al 1990. Honey bee reproduction: vitellogenin and caste-especific regulation of fertility. In: HOSHI, M. & YAMASHITA, O. Advances in invertebrate reproduction 5 Amsterdam, Elsevier. p.495-502.
FLURI, P.; LÜSHER, M. et al 1982. Changes in weight of the pharyngeal gland and haemolymph titres of juvenile hormone, protein and vitellogenin in worker honey bees. Journal of Insect Physiology, Oxford, 28:61-68.
HARTFELDER, K. & ENGELS, W. 1998. Social insect polymorphism: hormonal regulation of plasticity in development and reproduction in the honeybee. Current Topics in Developmental Biology, Academic Press, Washington, 40:45-77.
HUANG, Z. Y.; ROBINSON, G. E. et al 1991. Hormonal regulation of behavior development in the honey bee is based on changes in the rate of juvenile hormone biosynthesis. Journal of Insect Physiology, Oxford, 37:733-741.
JAYCOX, E. R.; SKOWRONEK, W. & GUYNN, C. 1974. Behavioral changes in worker honey bees (Apis mellifera) induced by injections of a juvenile hormone mimic. Annals of the Entomological Society of America, College Park, 67(4):529-534.
KEELEY, L. L. 1985. Physiology and biochemistry of the fat body In: KERKUT, G. A. & GILBERT, L. I. Compreehensive insect physiology, biochemistry and pharmacology New York, Pergamon. v.3, p.211-248.
LOCKE, M. 1984. The structure and development of the vacuolar system in the fat body of insects. In: KING, R. C. & AKAI, H. Insect ultrastructure New York, Plenum. p.151-197.
LOCKE, M. & COLLINS, J. V. 1966. Sequestration of protein by the fat body of an insect. Nature, New York, 210(5035):552-553.
MARX, R. 1987. Changes in the fat body ultrastructure during the fifth larval instar in workers, queen and drones of the honey bee, Apis mellifera L. In: CHEMISTRY AND BIOLOGY OF SOCIAL INSECTS INTERNATIONAL CONGRESS OF IUSSI, 10th, München, 1986. Proceedings.. München, J. Peperny. p.86-87.
PAES-DE-OLIVEIRA, V. T. & CRUZ-LANDIM, C. 2003a. Size of fat body trophocytes and the ovarian development in workers and queens of Melipona quadrifasciata anthidioides Sociobiology, Chico, 41(3):701-709.
__. 2003b. Morphology and function of insect fat body cells: a review. Biociências, Porto Alegre, 11(2):195-205.
PALLI, S. R. & LOCKE, M. 1988. The synthesis of hemolymph proteins by the larval fat body of an insect Calpodes ethlius (Lepidoptera: Hesperiidae). Insect Biochemistry, Elmford, 18:405-413.
PAN, M. L.; BELL, W. J. & TELFER, W. H. 1969. Vitellogenic blood protein synthesis by insect fat body. Science, Washington, 165:393-394.
PRICE, G. M. 1973. Protein and nucleic acid metabolism in insect fat body. Biology Review, Cambridge, 48:333-375.
ROSELL, R. C. & WHEELER, D. E. 1995. Storage function and ultrastructure of the adult fat body in workers of the ant Camponotus festinates (Bukley) (Hymenoptera: Formicidae). International Journal of Insect Morphology and Embryology, Oxford, 24:413-426.
SAKAGAMI, S. F.; BEIG, D. et al. 1963. Occurrence of ovary-developed workers in queenright colonies of stingless bees. Revista Brasileira de Biologia, Rio de Janeiro, 23(2):115-129.
SEDMAK, J. J. & GROSSBERG, S. E. 1977. A rapid, sensitive and versatile assay for protein using Coomassie brilliant blue G250. Annals of Biochemistry, San Diego, 79:544-552.
TADBOWSKI, J. M. & JONES, J. C. 1979. Changes in fat body and oocytes during starvation and vitellogenesis in mosquito, Aedes aegypti (L.). Journal of Morphology, London, 179:185-264.
THOMSEN, E. & THOMSEN, M. 1978. Production of specific protein secretion granules by fat body cells of the blowfly Calliphora erythrocephala Cell and Tissue Research, New York, 193:25-33.
WIGGLESWORTH, V. B. 1942. The storage of protein, fat, glycogen and uric acid in the fat body and other tissues of mosquito larvae. Journal of Experimental Biology, Cambridge, 19:56-77.
WYATT, G. R. 1980. The fat body as a protein factory. In: Locke, M. & Smith, D. S. Insect biology in the future New York, Academic. p.201-225.

Publication Dates

Publication in this collection
23 June 2005
Date of issue
Dec 2004

History

Accepted
Aug 2004
Received
Aug 2003

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ADAMCZYK, J. J.; FESMYER, H. W. et al. 1996. Sex-specific and hormone controlled expression of a vitellogenin-encoding gene in the gypsy moth. Archives of Insect Biochemistry and Physiology, New York, 31(3):237-256.

[2] BABTHAN, M. & GILBERT, L. I. 1972. Studies on the cytophysiology of the fat body of American silk-moth. Zeitschrift für Zellforschung und Mikroskopische Anatomie, Berlin, 124:433-444.

[3] BEGO, L. R. 1983. On some aspects of bionomics in Melipona bicolor bicolor Lepeletier (Hymenoptera, Apidae, Meliponinae). Revista Brasileira de Entomologia, São Paulo, 27:211-224.

[4] BEHAN, M. & HAGEDORN, H. H. 1978. Ultrastructural changes in fat body of adult female Aedes aegypti in relationship to vitellogenin synthesis. Cell and Tissue Research, New York, 186:499-506.

[5] BEIG, D. & SAKAGAMI, S. F. 1964. Behavior studies of the stingless bees, with special reference to the ovoposition process II. Melipona seminigra merrillae Cockerell. Annotationes Zoologicae Japonenses, Tokyo, 37(2):112-119.

[6] BROOKES, V. J. 1969. The induction of yolk protein synthesis in the fat body of an insect. Leucophaea maderae, by an analog of the juvenile hormone. Development Biology, New York, 20:459-471.

[7] CRUZ-LANDIM, C. 1983. O corpo gorduroso da larva de Melipona quadrifasciata anthidioides LEP. (Apidae, Meliponinae). Naturalia, São Paulo, 8:7-23.

[8] __. 1985. Modificações das células do corpo gorduroso de rainhas de Apis mellifera L. (Hymenoptera, Apidae). Ciência e Cultura, São Paulo, 37:471-475.

[9] DEAN, R. L.; LOCKE, M. & COLLINS, J. V. 1985. Structure of fat body. In: Kerbut, G. A. & Gilbert, L. I. Comprehensive insect physiology, biochemistry and pharmacology Oxford, Pergamon. v.3, p.155-210.

[10] ENGELMANN, F. 1971. Juvenile hormone - controlled synthesis of female specific protein in the cockroach Leucophae maderae Archives of Biochemistry and Biophysics, New York, 145:439-447.

[11] ENGELS, W. 1973. Das zeitliche und räumliche Muster der Dottereinlagerung in die Oocyte von Apis mellifera Zeitschrift für Zellforschung und Mikroskopische Anatomie, Berlin, 142:409-430.

[12] ENGELS, W.; KAATZ, H. et al 1990. Honey bee reproduction: vitellogenin and caste-especific regulation of fertility. In: HOSHI, M. & YAMASHITA, O. Advances in invertebrate reproduction 5 Amsterdam, Elsevier. p.495-502.

[13] FLURI, P.; LÜSHER, M. et al 1982. Changes in weight of the pharyngeal gland and haemolymph titres of juvenile hormone, protein and vitellogenin in worker honey bees. Journal of Insect Physiology, Oxford, 28:61-68.

[14] HARTFELDER, K. & ENGELS, W. 1998. Social insect polymorphism: hormonal regulation of plasticity in development and reproduction in the honeybee. Current Topics in Developmental Biology, Academic Press, Washington, 40:45-77.

[15] HUANG, Z. Y.; ROBINSON, G. E. et al 1991. Hormonal regulation of behavior development in the honey bee is based on changes in the rate of juvenile hormone biosynthesis. Journal of Insect Physiology, Oxford, 37:733-741.

[16] JAYCOX, E. R.; SKOWRONEK, W. & GUYNN, C. 1974. Behavioral changes in worker honey bees (Apis mellifera) induced by injections of a juvenile hormone mimic. Annals of the Entomological Society of America, College Park, 67(4):529-534.

[17] KEELEY, L. L. 1985. Physiology and biochemistry of the fat body In: KERKUT, G. A. & GILBERT, L. I. Compreehensive insect physiology, biochemistry and pharmacology New York, Pergamon. v.3, p.211-248.

[18] LOCKE, M. 1984. The structure and development of the vacuolar system in the fat body of insects. In: KING, R. C. & AKAI, H. Insect ultrastructure New York, Plenum. p.151-197.

[19] LOCKE, M. & COLLINS, J. V. 1966. Sequestration of protein by the fat body of an insect. Nature, New York, 210(5035):552-553.

[20] MARX, R. 1987. Changes in the fat body ultrastructure during the fifth larval instar in workers, queen and drones of the honey bee, Apis mellifera L. In: CHEMISTRY AND BIOLOGY OF SOCIAL INSECTS INTERNATIONAL CONGRESS OF IUSSI, 10th, München, 1986. Proceedings.. München, J. Peperny. p.86-87.

[21] PAES-DE-OLIVEIRA, V. T. & CRUZ-LANDIM, C. 2003a. Size of fat body trophocytes and the ovarian development in workers and queens of Melipona quadrifasciata anthidioides Sociobiology, Chico, 41(3):701-709.

[22] __. 2003b. Morphology and function of insect fat body cells: a review. Biociências, Porto Alegre, 11(2):195-205.

[23] PALLI, S. R. & LOCKE, M. 1988. The synthesis of hemolymph proteins by the larval fat body of an insect Calpodes ethlius (Lepidoptera: Hesperiidae). Insect Biochemistry, Elmford, 18:405-413.

[24] PAN, M. L.; BELL, W. J. & TELFER, W. H. 1969. Vitellogenic blood protein synthesis by insect fat body. Science, Washington, 165:393-394.

[25] PRICE, G. M. 1973. Protein and nucleic acid metabolism in insect fat body. Biology Review, Cambridge, 48:333-375.

[26] ROSELL, R. C. & WHEELER, D. E. 1995. Storage function and ultrastructure of the adult fat body in workers of the ant Camponotus festinates (Bukley) (Hymenoptera: Formicidae). International Journal of Insect Morphology and Embryology, Oxford, 24:413-426.

[27] SAKAGAMI, S. F.; BEIG, D. et al. 1963. Occurrence of ovary-developed workers in queenright colonies of stingless bees. Revista Brasileira de Biologia, Rio de Janeiro, 23(2):115-129.

[28] SEDMAK, J. J. & GROSSBERG, S. E. 1977. A rapid, sensitive and versatile assay for protein using Coomassie brilliant blue G250. Annals of Biochemistry, San Diego, 79:544-552.

[29] TADBOWSKI, J. M. & JONES, J. C. 1979. Changes in fat body and oocytes during starvation and vitellogenesis in mosquito, Aedes aegypti (L.). Journal of Morphology, London, 179:185-264.

[30] THOMSEN, E. & THOMSEN, M. 1978. Production of specific protein secretion granules by fat body cells of the blowfly Calliphora erythrocephala Cell and Tissue Research, New York, 193:25-33.

[31] WIGGLESWORTH, V. B. 1942. The storage of protein, fat, glycogen and uric acid in the fat body and other tissues of mosquito larvae. Journal of Experimental Biology, Cambridge, 19:56-77.

[32] WYATT, G. R. 1980. The fat body as a protein factory. In: Locke, M. & Smith, D. S. Insect biology in the future New York, Academic. p.201-225.

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Protein content and electrophoretic profile of fat body and ovary extracts from workers of Melipona quadrifasciata anthidioides (Hymenoptera, Meliponini)

Abstract

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History