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Brazilian Archives of Biology and Technology

Print version ISSN 1516-8913On-line version ISSN 1678-4324

Braz. arch. biol. technol. vol.46 no.4 Curitiba Dec. 2003

http://dx.doi.org/10.1590/S1516-89132003000400025 

BIOLOGICAL AND APPLIED SCIENCES

 

Plants and pollinating bees in Maringá, State of Paraná, Brazil

 

 

Vagner de Alencar Arnaut de ToledoI, *; Adriano Ernesto de Toledo FritzenI; Carolina Antunes NevesI; Maria Claudia Colla Ruvolo-TakasusukiII; Silvia Helena SofiaIII; Yoko TeradaII

IDepartment of Animal Science; Universidade Estadual de Maringá – UEM; vaatoledo@uem.br; Avenida Colombo, 5790; 87020-900; Maringá - PR - Brazil
IIDepartment of Cell Biology and Genetics; Universidade Estadual de Maringá – UEM; Avenida Colombo, 5790; 87020-900; Maringá - PR - Brazil
IIIDepartment of Biology; Universidade Estadual de Londrina; Londrina - PR - Brazil

 

 


ABSTRACT

The present study was carried out to survey the bees as visitors to melliferous flora in the region of Maringá, state of Paraná, Brazil. A total of 331 insects were captured, and the fauna comprised 39.88% Trigona spinipes, 38.37% Apis mellifera, 8.16% Tetragonisca angustula, 3.93% Halictidae, 1.21% Megachilidae, 2.42% Anthophoridae, and 3.32% other Hymenoptera. Eleven plant species from nine families were observed. The four families most frequently visited by A. mellifera were Pontederiaceae (93.53%), Sterculiaceae and Polygoniaceae (47.22%), Apocynaceae and Apiaceae (42.86%). The families most visited by T. spinipes were Lamiaceae (64.70%), Apocynaceae (57.14%), Sterculiaceae (51.85%) and Anacardiaceae (48.39%), and the families most visited by T. angustula were (28.57%), Asteraceae (22.22%) and Labiatae (16.47%). Three species predominated in number of bee visits Dombeya wallichii (32.63%), Ocimum americanum (15.5%) and Antigonon leptopus (15.2%). T. angustula was the most frequent visitor of O. gratissimum flowers (60.87%).

Key words: Stingless bees, pollination, melliferous flora


RESUMO

As abelhas sem ferrão são responsáveis por cerca de 30-90% da reprodução dos vegetais nas florestas tropicais, através do mecanismo de polinização, na fecundação cruzada (Kerr et al. , 1994). Esse trabalho teve o objetivo de realizar um levantamento de angiospermas e os insetos que as polinizam na região de Maringá, PR, com o intuito de contribuir com o entendimento da biodiversidade dessa região. As abelhas foram coletadas entre agosto de 1999 a janeiro de 2000, com o auxílio de uma rede entomológica, durante suas visitas às flores. As coletas foram semanais. Foram coletados 331 insetos, dos quais 39,88% eram Trigona spinipes, 38,37% Apis mellifera, 8,16% Tetragonisca angustula, 3,93% Halictidae, 1,21% Megachilidae, 2,42% Anthophoridae e 3,32% de outros Hymenoptera. Foram observadas 11 espécies vegetais pertencentes a nove famílias. As quatro famílias mais visitadas pelas abelhas A. mellifera foram Pontederiaceae – 93,55%, Lamiaceae – 55,56%, Sterculiaceae e Polygoniaceae – 47,22%; por T. spinipes foram Lamiaceae – 63,95%, Apocynaceae – 57,14%, Sterculiaceae - 51,85% e Anacardiaceae – 48,39% e por T. Angustula, Lamiaceae – 60,87%, Apiaceae – 28,57%, Anacardiaceae – 16,13% e Asteraceae – 12,50%. Três espécies vegetais foram predominantes em número de visitas pelas abelhas, concentrando 61,7% das visitas, destacando-se: Dombeya wallichii (32,63%), Ocimum americanum (16,31%) e Antigonon leptopus (10,88%). T. angustula foi o visitante mais freqüente (60,87%) em O. gratissimum.


 

 

INTRODUCTION

The melliferous flora of a certain region is subject to constant changes due to ecological factors and agricultural treatments. Some changes, such as land clearing by burning, monoculture areas and pesticides, strongly affect the native bee species and their populations. On a short-term basis, this may imply a higher dependence on pollination by Apis mellifera and Tetragonisca angustula to ensure good production. Plant pollination by insects is important for better productivity (Nogueira-Couto and Carmona, 1993). Nogueira-Couto et al. (1988) noticed the need for pollinators in Crotalaria; when pollinators were absent the plant did not produce pods.

Stingless bees are responsible for 30% to 90% of plant sexual reproduction in rainforests through pollination and cross-fecundation (Kerr et al. , 1994). Bees from the tribe Meliponini, usually associated with rainforest flora, forage according to the resources present, colony necessity and competitors (Roubik, 1981). Bee colonies can make about four million trips per year. During each forager flight, an average of 100 flowers is visited (Free, 1970). Pollen shortages may occur at any time of the year due to environmental factors (Taber and Poole, 1974; Doull, 1975), or due to bee visitations to plants with lots of nectar and little pollen (Stanger and Laidlaw, 1974; Johansson and Johansson, 1977).

Even though pollen and nectar are present at different times of day in different plant species (Free, 1970) and in different places, bees are able to find and gather them due to a well-developed orientation sense and excellent foraging skill (Von Frisch, 1967).

Many plants of economic importance depend upon insects to increase fruit and seed production. Thus, this study was carried out to survey the angiosperms and their insect pollinators in the region of Maringá, state of Paraná, in the south of Brazil to contribute to the understanding of the region's biodiversity.

 

MATERIAL AND METHODS

The study was carried out from August 1999 to January 2000 in the campus of Universidade Estadual de Maringá, state of Paraná, Brazil (23º 55' S., 51º57' W., 542 m altitude), with a mean annual precipitation of 1677 mm and a mean temperature of 22ºC. Eleven plant species from nine families were examined: Mangifera indica (Anacardiaceae); Allamanda sp. (Apocynaceae); Tabebuia serratifolia (Bignoneaceae); Cosmos bipinnatus (Asteraceae); Leonorus sibinicu, Ocimum americanum and Ocimum gratissimum (Lamiaceae); Eichornia crassipes (Pontederiaceae); Antigonon leptopus (Polygoniaceae); Dombeya wallichii (Sterculiaceae) and Foeniculum vulgare (Apiaceae). A herbarium was prepared with these species. The collection is housed at the Herbarium of Universidade Estadual de Maringá (HUM). Insect visitors were collected during the flowering of these plants. Each collection (three per plant species) was carried out from 8:30 a.m. to 11:30 a.m. The insects collected were identified and an entomological collection was prepared.

 

RESULTS

During the study 331 insects were collected and the bees found in higher percentages were T. spinipes (39.88%) and A. mellifera (38.37%), with 13.59% corresponding to other Hymenoptera and other insects (Table 1). Fig. 1 shows the percentages of T. angustula visits to different flower species. T. angustula was collected at highest frequency on flowers of Ocimum gratissimum (60.87%) and Foeniculum vulgare (28.57%). The total numbers of insects collected on flowers of different species showed that Trigona spinipes, A. mellifera and T. angustula were the most abundant (Table 1). T. angustula comprised 8.16% of the total number of insects collected. These bees were not found on flowers of Allamanda sp., L. sibinicus, O. americanum, E. crasseps or D. wallichii (Table 1). T. spinipes may be the main pollinator of O. americanum because it was the only species collected on flowers of this plant. This bee can also be considered as a main pollinator of Allamanda (57.4%), D. wallichii (51.85%) and M. indica (48.39%), corresponding to about 50% of all floral visitors to each family (Table 1). A. mellifera was collected on the flowers of all plants except O. americanum.

 

 

 

 

On the basis of the total number of insects gathered on each plant family, as well as its percentage from the total collected/family, it could be seen that the two families with higher percentages of gathered insects were Sterculiaceae (32.98%) and Lamiaceae (25.98%), for a total of 58.61% (Table 2).

 

 

DISCUSSION

The three bee species more frequently collected were T. spinipes, A. mellifera and T. angustula. Africanized and stingless bees are likely visitors since they are generalists and overlap greatly in time and place of foraging. They have different recruitment systems or differing responses to pollen or nectar rewards (Roubik, 1978). However, those bees play an important role in pollination.

Meliponini, especially those of small size, usually start their activity later and come back to the hive earlier (Nogueira-Neto, 1970). Temperature, luminosity and relative humidity are factors that affect the external activity of T. angustula (Iwama, 1977). These observations confirm the results obtained by Brito and Rego (1992), who also found T. spinipes (58%) and A. mellifera (21.4%) as the bees with the largest number of individuals collected in the cerrado in Barreirinhas, state of Maranhão, in the Northeast of Brazil.

Carvalho and Bego (1992) obtained similar results for 1226 individuals collected 75 botanical species in a region of cerrado in Panga ecological park (Uberlandia, Minas Gerais, Brazil). Sterculiaceae was the most visited family, and also the one that showed the largest number of collected individuals.

T. spinipes could be considered the main pollinator agent of O. americanum, Allamanda, D. wallichii and M. indica. Among the plant families observed, A. mellifera was the main pollinator of L. sibinicus and E. crassipes (93.55%). T. angustula is considered to be a generalist because it visited flowers of several plants for resources (Cortopassi-Laurino, 1982). Some plant families such as Euphorbiaceae were preferred in its diet (Knoll, 1990). In Maringá and the surrounding area, this bee preferred Lamiaceae (60.87%), Apiaceae (28.57%), Anacardiaceae (16.13%) and Asteraceae (12.50%) as food resources.

We found that 16.13% of T. angustula bees were collected on flowers of Anacardiaceae. These results agree with those of Carvalho and Marchini (1999), who observed T. angustula gathering pollen from Anacardiaceae plants. Slaa et al. (2000) compared the pollinating activity between two species of stingless bees (Nannotrigona testaceicornis and Tetragonisca angustula) and honey bees (A. mellifera) on the ornamental plant Salvia farinacea var. strata (Laminaceae) in enclosures. The plant visit rate of A. mellifera was almost twice as high as that of T. angustula. Comparison of the bees showed that pollination by A. mellifera was the most effective. It was suggested that the lower seed production obtained with stingless bees in comparison with honey bees might have been a consequence of their lower foraging activity, which in turn was probably related to their much smaller population of foragers. Seed yield evaluated per unit of foraging activity was similar for all three species of bees.

 

REFERENCES

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Received: September 25, 2001
Revised: May 07, 2002
Accepted: July 25, 2003

 

 

* Author for correspondence

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