DOCSLIB.ORG

Distinctive Hydrocarbons Among Giant Honey Bees, the Apis Dorsata Group (Hymenoptera: Apidae) Da Carlson, Dw Roubik, K Milstrey

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Distinctive Hydrocarbons Among Giant Honey Bees, the Apis Dorsata Group (Hymenoptera: Apidae) Da Carlson, Dw Roubik, K Milstrey Distinctive hydrocarbons among giant honey bees, the Apis dorsata group (Hymenoptera: Apidae) Da Carlson, Dw Roubik, K Milstrey To cite this version: Da Carlson, Dw Roubik, K Milstrey. Distinctive hydrocarbons among giant honey bees, the Apis dorsata group (Hymenoptera: Apidae). Apidologie, Springer Verlag, 1991, 22 (3), pp.169-181. hal- 00890905 HAL Id: hal-00890905 https://hal.archives-ouvertes.fr/hal-00890905 Submitted on 1 Jan 1991 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Original article Distinctive hydrocarbons among giant honey bees, the Apis dorsata group (Hymenoptera: Apidae) DA Carlson DW Roubik K Milstrey 1 US Department of Agriculture, IAMARL, PO Box 14565, Gainesville, FL 32604, USA; 2 Smithsonian Tropical Research Institute, APDO 2072, Balboa, Panamá; 3 University of Florida, Department of Entomology and Nematology, Gainesville, FL 32611, USA (Received 10 April 1988; accepted 11 February 1991) Summary — Cuticular hydrocarbon pattern (CHP) analysis was performed on giant honey bees (the Apis dorsata group) including: 1), those occasionally given species status-Himalayan honey bees, Philippine honey bees, Sulawesi honey bees; 2), those separated since the Pleistocene- common A dorsata of the Indian and Asian lowlands and islands on the continental shelf (India and Sri Lanka, Thailand and Sumatra); and 3), giant honey bees of Borneo and Palawan, potential step- ping-stones to the Philippines and Sulawesi. Four groups were found among giant honey bees by this CHP analysis. Most distinctive were those of Palawan and Nepal. The widespread lowland Apis dorsata differed very little among mainland and island populations, whereas those of Borneo, Sulaw- esi, and Philippines proper formed a single group. Those of the Himalayas appear to have diverged from A dorsata. Apis dorsata / Apis laboriosa / systematics / hydrocarbon / gas chromatography INTRODUCTION The giant honey bees, formerly subgenus Megapis (Ruttner, 1988) apparently con- Taxonomic problems having evolutionary tain cryptic species, notably Apis laborio- implications and applied importance sa, the Himalayan honey bee (Maa, 1953; abound in honey bees (Ruttner, 1988; Sakagami et al, 1980; Roubik et al, 1985; Roubik, 1989). Geographic races or sub- McEvoy and Underwood, 1988). New spe- species, although often purely artificial in cies have also been confirmed for other taxonomic work, have special value in Asian honey bees. Apis andreniformis (F studies of organisms such as honey bees Smith, 1858), proved to be distinct from because they may lead to recognition of the widespread "little honey bee" A florea bionomic characteristics that differ among (Wu and Kuang, 1986; Roubik, 1989). populations (Mayr, 1970; Ruttner, 1988). Also, a distinctive Saban honey bee, Apis * Correspondence and reprints : DW Roubik, Smithsonian Tropical Research Institute, APO Miami 34002-0011, FL, USA koschevnikovi (Buttel-Reepen, 1906), is merly Celebes; A ’binghami’ from Minahassa; found in northeastern Borneo and shares Dumoga), the Philippine Islands (A ’breviligula’ from Los Banõs, and its habitat with the closely similar Apis ce- Laguna: Leyte: Visca). Samples of Apis dorsata were collected from rana et al, 1988; et al, (Koeniger Tingek much of its geographic range and several is- 1988). These last 2 species (A koschevni- lands and included: 1), Palawan Islands (collect- kovi was called Apis vechti) not only have ed by SF Sakagami and T Inoue); 2), Sabah, distinctive male genitalic structure but also Borneo (collected by B Sutton); 3), New Delhi, different times of mating flight activity- India (DWR); Chaing Rai, northern Thailand both features that would prevent interspe- (DWR); Sri Lanka; Monaragala (DWR), and Su- western Indonesia From cific mating. Recently, McEvoy and Under- matra; Padang, (DWR). 4 to 13 bees were assayed from each giant hon- wood no differences in the (1988) reported ey bee group (table I), ie a total of 41 bees. All male endophallus of Himalayan honey were collected at flowers or had flown to lights bees and the common giant honey bee at night, making it likely that they were older Apis dorsata, but believed they could be bees. This is important for cuticular hydrocarbon distinct species. The Himalayan honey study, since younger bees, those that do not bee and other populations of giant honey leave the nest or forage, have different chemi- cal traits than older worker bees (D Carlson, un- bees are still under study because we do published observations). not know which races and which represent The identification of 3 classes of cuticular hy- are species. As a step toward definitive drocarbons-alkanes, alkenes, and methyl- analysis, we studied the giant honey bees branched alkanes-was made solely on the ba- using a chemoanalytical technique that sis of gas chromatograph retention times. Fol- can be applied to dead pinned museum lowing the methods of Carlson and Service specimens without damaging them- (1980) lipids were extracted from individual bees immersion in and then cuticular hydrocarbon pattern analysis during overnight hexane, fractionated by liquid chromatography using and Bolten, 1984; Francis et al, (Carlson small columns made from disposable 0.4 x 5.0 Based 1985; Lockey, 1988; Smith, 1988). cm pipettes packed with silica gel. The hydrocar- on the analysis presented here, we con- bon fraction of each extract was eluted with hex- clude that 4 natural groups and at least 2 ane, then subjected to gas chromatography. A species may exist. These hypotheses are varian Model 3700 flame ionization instrument was used, fitted with a DB-1 fused silica corroborated by a biogeographic analysis. capil- lary column (15 m length x 0.32 mm internal di- ameter; J & W Scientific, Folsom, CA). An OCI-3 glass on-column injector (Scientific Glass Engi- MATERIALS AND METHODS neering Inc, Austin, TX) was used in the split- less mode with the column oven at 40 °C. It was then temperature-programmed from 40 °C to The names of candidate giant honey bee spe- 320 °C, at a 20 °C increase per min. The sam- cies first suggested by Maa (1953) will appear ples were evaporated to dryness and taken up within quotation marks throughout the present in 50 μl of hexane solvent just before the injec- text. Pinned specimens of worker bees are now tion of one μl. The gas chromatograph was cou- in the collection of DWR or SF Sakagami, and pled through a 760-series interface and a Nel- were supplied from the collections of CK Starr son Analytical system to an IBM PC/XT (Philippine bees), B Sutton (Borneo bees), SF computer, an Epson FX80+ printer, and a Hew- Sakagami (Palawan, Nepal, Sulawesi bees), or lett-Packard 7470A plotter for data output. The were collected by DWR. These specimens in- column had ≈ 60 000 theoretical plates with a cluded workers collected up to 18 yr before our C13 n-alkane standard. The samples were the analysis. The bees, identified by SF Sakagami, equivalent of 2% of the amount obtained from were from: central Nepal (A ’laboriosa’ from Kal- one bee. Each was injected together with alkane li La, Drandikhola, Trubkin Kharka, Tukucha standards for determination of Kovats retention Palpa and Tharepati-Melemchi), Sulawesi (for- indices (KI) (Kovats, 1966). KI values were con- verted to equivalent chain lengths (ECL) by di- RESULTS viding by 100. The bee specimens used here were undamaged by hydrocarbon extraction. Five ratios were derived for each specimen by Visual dividing the recorded integrated areas of 2 se- comparison lected alkenes (2 475 and 2 675 retention times), and 3 methyl alkanes (2 735, 2 935, Alkanes, alkenes and internally methyl- 3 the of the 2 700 135) by area alkane peak. branched alkanes in each sample con- The areas were calculated for the peaks printed tained 23 to 36 carbons (fig 1 a-f). In gen- out by the plotter, as shown in the following re- sults. eral, the bees exhibited variation in 4 sets of triple peaks, with the center peak always Precautions were taken to screen for the ex- an n-alkane of or 31 carbons. In traction technique and possible effects of other 25, 27, 29 a series of alkenes was hydrocarbons found on the bodies of worker addition, larger bees. Pollens on the bodies of Apis mellifera found, having 34- to 37-carbon (outside of the load carried in the corbicula) "backbones" (Ki 3 365 to 3 665). A series were found to contribute insignificant amounts of alkadienes with the same ’backbone’ (KI of to that extracted from hydrocarbon compared 3 343 to 3 643) was also found in the de- a bee The of as specimen. quality hydrocarbons scendants of African honey bees in Vene- shown by GC patterns did not appear to differ appreciably between honey bees extracted zuela (Carlson and Bolten, 1984). Each of overnight in hexane, compared to nest mates the bee groups we examined was evaluat- that were placed in hexane for 10 min. ed as follows: Apis dorsata neo bees (fig 1c and fig 2) were substan- tially similar to those of the Philippine bees and but unlike those of the Asian The 5 worker bees from Palawan exhibited Sulawesi, mainland or Palawan. The CHPs of bees consistent CHPs, comprised primarily of 4 from Thailand, Sri Lanka, and India were sets of triple peaks with a smaller fourth similar to each other Indian bee, peak (fig 1 a). The Kovats retention indices very (see and to an A dorsata worker from of 2 675, 2 700 and 2 735 here correspond fig 1b), Pakistan (Francis et al, 1985).
Load more

Recommended publications
  • Ecology, Behaviour and Control of Apis Cerana with a Focus on Relevance to the Australian Incursion
    Insects 2013, 4, 558-592; doi:10.3390/insects4040558 OPEN ACCESS insects ISSN 2075-4450 www.mdpi.com/journal/insects/ Review Ecology, Behaviour and Control of Apis cerana with a Focus on Relevance to the Australian Incursion Anna H. Koetz Biosecurity Queensland, Department of Agriculture, Fisheries and Forestry, 21-23 Redden St., Portsmith, QLD 4870, Australia; E-Mail: [email protected]; Tel.: +61-419-726-698; Fax: +61-7-4057-3690 Received: 27 June 2013; in revised form: 13 September 2013 / Accepted: 24 September 2013 / Published: 21 October 2013 Abstract: Apis cerana Fabricius is endemic to most of Asia, where it has been used for honey production and pollination services for thousands of years. Since the 1980s, A. cerana has been introduced to areas outside its natural range (namely New Guinea, the Solomon Islands, and Australia), which sparked fears that it may become a pest species that could compete with, and negatively affect, native Australian fauna and flora, as well as commercially kept A. mellifera and commercial crops. This literature review is a response to these concerns and reviews what is known about the ecology and behaviour of A. cerana. Differences between temperate and tropical strains of A. cerana are reviewed, as are A. cerana pollination, competition between A. cerana and A. mellifera, and the impact and control strategies of introduced A. cerana, with a particular focus on gaps of current knowledge. Keywords: Apis cerana; Apis mellifera; incursion; pest species; Australia; pollination; competition; distribution; control 1. Introduction Apis cerana Fabricius (also known as the Asian honeybee, Asiatic bee, Asian hive bee, Indian honeybee, Indian bee, Chinese bee, Mee bee, Eastern honeybee, and Fly Bee) is endemic to most of Asia where it has been used for honey production and pollination services for thousands of years.
    [Show full text]
  • The Distribution and Nest-Site Preference of Apis Dorsata Binghami at Maros Forest, South Sulawesi, Indonesia
    Journal of Insect Biodiversity 4(23): 1‐14, 2016 http://www.insectbiodiversity.org RESEARCH ARTICLE The distribution and nest-site preference of Apis dorsata binghami at Maros Forest, South Sulawesi, Indonesia Muhammad Teguh Nagir1 Tri Atmowidi1* Sih Kahono2 1Department of Biology, Faculty of Mathematics and Natural Sciences, Bogor Agricultural University, Dramaga Campus, Bogor 16680, Indonesia. 2Zoology Division, Research Center for Biology-LIPI, Bogor 16911, Indonesia. *Corresponding author: [email protected] Abstract: The giant honey bee, Apis dorsata binghami is subspecies of Apis dorsata. This species of bee was only found in Sulawesi and its surrounding islands. This study is aimed to study the distribution and characteristics of nest and nesting trees, nesting behavior of Apis dorsata binghami in the forests of Maros, South Sulawesi, Indonesia. The distributions of nests were observed using a survey method to record the species and characteristics of nesting trees, as well as the conditions around the nest. Results showed that 102 nests (17 active nests, 85 abandoned combs) of A. d. binghami were found. We found 34 species belong to 27 genera in 17 families of plants as nesting sites of giant honey bee. The common tree species used as nesting sites were Ficus subulata (Moraceae), Adenanthera sp. (Fabaceae), Spondias pinnata (Anacardiaceae), Artocarpus sericoarpus (Moraceae), Alstonia scholaris (Apocynaceae), Knema cinerea (Myristicaceae), Litsea mappacea (Lauraceae), and Palaquium obovatum (Sapotaceae). The nests were found in 0-11 meters (11 nests), 11-20 meters (40 nests), and more than 21 meters (51 nests) from ground level. The nests of giant honey bee were found in sturdy and woody branches, hard to peel, the slope of the branches was <60°, and nests were protected by liane plants, foliage, or both them.
    [Show full text]
  • UC Berkeley UC Berkeley Previously Published Works
    UC Berkeley UC Berkeley Previously Published Works Title Effects of forest and cave proximity on fruit set of tree crops in tropical orchards in Southern Thailand Permalink https://escholarship.org/uc/item/9bv4z153 Journal Journal of Tropical Ecology, 32(4) ISSN 0266-4674 Authors Sritongchuay, T Kremen, C Bumrungsri, S Publication Date 2016-07-01 DOI 10.1017/S0266467416000353 Peer reviewed eScholarship.org Powered by the California Digital Library University of California Journal of Tropical Ecology http://journals.cambridge.org/TRO Additional services for Journal of Tropical Ecology: Email alerts: Click here Subscriptions: Click here Commercial reprints: Click here Terms of use : Click here Effects of forest and cave proximity on fruit set of tree crops in tropical orchards in Southern Thailand Tuanjit Sritongchuay, Claire Kremen and Sara Bumrungsri Journal of Tropical Ecology / Volume 32 / Issue 04 / July 2016, pp 269 - 279 DOI: 10.1017/S0266467416000353, Published online: 13 July 2016 Link to this article: http://journals.cambridge.org/abstract_S0266467416000353 How to cite this article: Tuanjit Sritongchuay, Claire Kremen and Sara Bumrungsri (2016). Effects of forest and cave proximity on fruit set of tree crops in tropical orchards in Southern Thailand. Journal of Tropical Ecology, 32, pp 269-279 doi:10.1017/ S0266467416000353 Request Permissions : Click here Downloaded from http://journals.cambridge.org/TRO, IP address: 136.152.209.123 on 10 Aug 2016 Journal of Tropical Ecology (2016) 32:269–279. © Cambridge University Press 2016
    [Show full text]
  • Top-Down Sequencing of Apis Dorsata Apamin by MALDI-TOF MS and Evidence of Its Inactivity Against Microorganisms
    Toxicon 71 (2013) 105–112 Contents lists available at SciVerse ScienceDirect Toxicon journal homepage: www.elsevier.com/locate/toxicon Top-down sequencing of Apis dorsata apamin by MALDI-TOF MS and evidence of its inactivity against microorganisms D. Baracchi a,*, G. Mazza a, E. Michelucci b, G. Pieraccini b, S. Turillazzi a,b, G. Moneti b a Department of Biologia Evoluzionistica “Leo Pardi”, University of Firenze, Via Romana 17, 50125 Firenze, Italy b Mass Spectrometry Centre, University of Firenze, Viale G. Pieraccini 6, 50139 Firenze, Italy article info abstract Article history: Apis mellifera venom is one of the best characterized venoms among Hymenoptera, yet Received 13 March 2013 relatively little is known about venom belonging to other species in the genus Apis. Received in revised form 18 May 2013 Melittin, one of the most important bioactive peptides, has been isolated and characterized Accepted 22 May 2013 in A. mellifera, Apis cerana, Apis dorsata and Apis florea, while apamin has been only Available online 7 June 2013 characterized in A. mellifera and A. cerana. At present, no information is available about the sequence of A. dorsata apamin. Moreover, while the antiseptic properties of melittin and Keywords: MCD peptides are well documented, the antimicrobial activity of apamin has never been MALDI-TOF Venom tested. In the present study, we isolated and characterized apamin from the venom of the Honeybee giant honeybee A. dorsata. We tested the activity of apamin against bacteria and yeasts in a Antimicrobial peptides microbiological assay to gain a more complete understanding of the antimicrobial Peptide sequencing competence of the medium molecular weight venom fraction.
    [Show full text]
  • Training Manual for Rafter Beekeeping
    Training Manual The following document is intended to serve as a training manual and has been developed on the basis of related literature and the personal observations of the author. It aims to provide the essential requirements for the implementation of rafter beekeeping and presents guidelines for rafter construction and management as a means of sustainable harvesting. Nevertheless, it should not be considered as a substitute for practical training by an experienced rafter beekeeper, at least in the first stages of implementation. As is the case for any beekeeping activity, experience is a key factor for success. Eric Guerin Beekeeping consultant [email protected] December 2019 1. INTRODUCTION .............................................................................. 3 2. WHAT IS RAFTER BEEKEEPING? ................................................... 4 3. BASIC REQUIREMENTS FOR RAFTERING ...................................... 6 3.1 Presence of bees in the environment ........................................................... 6 3.2 Lack of “natural” nesting sites ..................................................................... 6 3.3 Abundance of bee friendly floral resources ................................................. 7 3.4 A widely recognized tenure or ownership of the rafters by individuals enforced by community laws and culture .......................................................... 8 3.5 Clarity on the tenure and management of the land ...................................... 9 4. RAFTER DESIGN AND CONSTRUCTION
    [Show full text]
  • Apis Mellifera 7
    Invite international cooperation and investors By Ir. Bambang Soekartiko Bina Apiary Indonesia Email : [email protected] INDONESIA GLOBAL Located between Asia and Australia continent – 200.000.000 ha land and 500.000.000 ha of sea. – 243.000.000 population ( No 4 after China, India, USA) – 120.000.000 ha of Tropical Rain Forest – Consist of 17.508 islands A potential country for bee products producers and consumers Beekeeping to make people healthy and wealthy 241 millions population, 4th after China, India and USA – 60 % in Java island – Many people living at isolated and remote area and small islands – Health problems : infection deseases – Honey bee products and Apitherapy best alternative to maintain healthy and wealthy for rural people Variety of Honey Bee in Indonesia 1. Apis dorsata 2. Apis andreniformis 3. Apis cerana Ada di Indonesia 4. Apis koschevnikovi 5. Apis nigrocincta 6. Apis mellifera 7. Apis nuluensis 8. Apis laboriosa 9. Apis florea Apis dorsata Apis cerana Apis mellifera - Traditional beekeeping Apis cerana have been practiced by rural people of Java and Bali long time ago using hollow logs and clay pots – Honey hunting of Apis dorsata in Natural forest at Sumatera, Kalimantan, Sulawesi, NTT, NTB, and Papua/Irian – Modern beekeeping Apis mellifera start in 1974 at Java island by small beekeepers Honey hunting of indigeneous species of Tropical Rain Forest Apis dorsata practice by people living surrounding forest at outer island of Java. – Nesting at big trees protecting by Law – Claims as individual ownership
    [Show full text]
  • Diversity in Traditional Techniques for Enticing Apis Dorsata Colonies in Indonesia
    DIVERSITY IN TRADITIONAL TECHNIQUES FOR ENTICING APIS DORSATA COLONIES IN INDONESIA Soesilawati Hadisoesilo Forest and Nature Conservation Research and Development Jl. Gunung Batu 5, Bogor, Indonesia Telp. 62-251-315-222, Fax. 62-251-325-111 [email protected] or [email protected] It is known that Indonesia has the most diverse honey bee species in the world. Apis dorsata or the giant honey bee is one of the seven indigenous honey bees of Indonesia. Although A. dorsata is the main honey producer in Indonesia, especially outside the island of Java, every attempt to manage this bee like the cavity-nesting honey bees always fails. However, in some parts of Indonesia, honey collectors have been practicing traditional techniques to entice A. dorsata colonies to artificial nesting sites. On the island of Belitung this technique is called “Sunggau”, in Lake Sentarum, West Kalimantan it is named “Tikung”, and in an area close to Poso Lake, Central Sulawesi, it is called “Tingku”. The principles of these three techniques are similar. The differences among them are the condition and the topography of the place where they are built, and the way they are erected. Sunggau are built in dry places with flat topography, Tikung are built in wetland areas, and Tingku are built in hilly areas. Sunggau are erected with the support of one or two poles or branches of a tree which act as poles, whereas Tikung are erected with the support of two branches of a tree. Tingku, on the other hand, are erected without any support but are inserted into slopes.
    [Show full text]
  • Genetic Differentiation of the Giant Honey Bee (Apis Dorsata) in Thailand Analyzed by Mitochondrial Genes and Microsatellites
    Biochemical Genetics, Vol. 45, Nos. 3/4, April 2007 (C 2007) DOI: 10.1007/s10528-007-9079-9 Genetic Differentiation of the Giant Honey Bee (Apis dorsata) in Thailand Analyzed by Mitochondrial Genes and Microsatellites S. Insuan,1 S. Deowanish,2 S. Klinbunga,3,4 S. Sittipraneed,1,6 H. A. Sylvester,5 and S. Wongsiri2 Received 7 August 2006—Final 13 November 2006 Published online: 7 March 2007 Genetic diversity and population differentiation of the giant honey bee (Apis dor- sata) in Thailand were examined. Six PCR-RFLP mitotypes were generated from digestion of the COI-COII, Cytb-tRNAser, ATPase6-8, and lrRNA genes with Dra I and Hin fI. Low genetic diversity (h = 0.074, π = 0.032%) and a lack of genetic population differentiation between A. dorsata originating from geographically different regions were observed from mtDNA polymorphisms (P > 0.05). In con- trast, microsatellite (A14, A24, and A88) polymorphisms revealed a relatively high level of genetic diversity in A. dorsata (Ho = 0.68–0.74, average number of alleles per locus = 6.0–9.0). Both A24 and A88 indicated significant population differentiation between bees from the north-to-central region (north, northeast, and central regions), peninsular Thailand, and Samui Island. KEY WORDS: Apis dorsata; honey bee; genetic diversity; mtDNA; microsatellites. 1Department of Biochemistry, Faculty of Science, Chulalongkorn University, Bangkok 10330, Thailand. 2Department of Biology, Faculty of Science, Chulalongkorn University, Bangkok 10330, Thailand. 3National Center for Genetic Engineering and Biotechnology, National Science and Technology Development Agency, 113 Paholyothin Road, Klong 1, Klong Luang, Pathumthani 12120, Thailand. 4Center of Excellence for Marine Biotechnology, Department of Marine Science, Faculty of Science, Chulalongkorn University, Bangkok 10330, Thailand.
    [Show full text]
  • Parasites, Pathogens, and Pests of Honeybees in Asia Panuwan Chantawannakul, Lilia I
    Parasites, pathogens, and pests of honeybees in Asia Panuwan Chantawannakul, Lilia I. de Guzman, Jilian Li, Geoffrey R. Williams To cite this version: Panuwan Chantawannakul, Lilia I. de Guzman, Jilian Li, Geoffrey R. Williams. Parasites, pathogens, and pests of honeybees in Asia. Apidologie, Springer Verlag, 2016, 47 (3), pp.301-324. 10.1007/s13592-015-0407-5. hal-01532338 HAL Id: hal-01532338 https://hal.archives-ouvertes.fr/hal-01532338 Submitted on 2 Jun 2017 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Apidologie (2016) 47:301–324 Review article * INRA, DIB and Springer-Verlag France, 2015 DOI: 10.1007/s13592-015-0407-5 Parasites, pathogens, and pests of honeybees in Asia 1 2 3 4,5 Panuwan CHANTAWANNAKUL , Lilia I. de GUZMAN , Jilian LI , Geoffrey R. WILLIAMS 1Bee Protection Laboratory (BeeP), Department of Biology, Faculty of Science, Chiang Mai University, Chiang Mai 50200, Thailand 2Honey Bee Breeding, Genetics and Physiology Laboratory, USDA-ARS, Baton Rouge, LA 70820, USA 3Key Laboratory of Pollinating Insect Biology of the Ministry of Agriculture, Institute of Apicultural Research, Chinese Academy of Agricultural Sciences, Beijing 100093, China 4Institute of Bee Health, Vetsuisse Faculty, University of Bern, 3003, Bern, Switzerland 5Agroscope, Swiss Bee Research Centre, 3003, Bern, Switzerland Received 20 May 2015 – Revised 7 October 2015 – Accepted 26 October 2015 Abstract – Asia is home to at least nine honeybee species, including the introduced Apis mellifera .Inadditionto A.
    [Show full text]
  • A Field-Based Quantitative Analysis of Sublethal Effects of Air Pollution on Pollinators
    A field-based quantitative analysis of sublethal effects of air pollution on pollinators Geetha G. Thimmegowdaa,1, Susan Mullenb, Katie Sottilareb, Ankit Sharmac, Saptashi Soham Mohantaa, Axel Brockmanna, Perundurai S. Dhandapanyc,d,e, and Shannon B. Olssona,1 aNational Centre for Biological Sciences, Tata Institute of Fundamental Research, Bangalore, India 560065; bMassachusetts Institute of Technology, Cambridge, MA 02139; cInstitute for Stem Cell Science and Regenerative Medicine (inStem), Bangalore, India 560065; dThe Knight Cardiovascular Institute, Oregon Health and Science University, Portland, OR 97239; and eDepartment of Medicine and Molecular and Medical Genetics, Oregon Health and Science University, Portland, OR 97239 Edited by Gene E. Robinson, University of Illinois at Urbana Champaign, Urbana, IL, and approved July 13, 2020 (received for review May 12, 2020) While the impact of air pollution on human health is well studied, enemies through direct impacts on sensory physiology and be- mechanistic impacts of air pollution on wild systems, including havior (14). For insects, air pollutants are likely to impact those providing essential ecosystem services, are largely un- olfactory-guided behavior strongly, as chemosensory information known, but directly impact our health and well-being. India is is used in almost every aspect of insect biology from locating the world’s largest fruit producer, second most populous country, food, mates, and host sites, to avoiding predators (15). For ex- and contains 9 of the world’s 10 most polluted cities. Here, we ample, the transport of chemical signals in the air used by pol- sampled Giant Asian honey bees, Apis dorsata, at locations with linators to locate flowers and other organisms may be hindered varying air pollution levels in Bangalore, India.
    [Show full text]
  • Towards a Sweeter Future
    Towards a sweeter future Conserving the giant Asian honey bee in Peninsular Malaysia TEXT BY THOMAS S. KRAFT, VIVEK V. VENKATARAMAN, GREEN JOHN CHAN & DR. M. NAZIP SURATMAN IMAGES BY VIVEK V. VENKATARAMAN & GREEN JOHN CHAN ACROSS SOUTHEAST Asia, the arrival of a giant Asian honey bee (Apis dorsata) colony near one’s home or garden is regarded as a good luck omen (Oldr d Nanork 2009). And for good reason: these iconic insects, which form conspicuous semi-circular nests on the undersides of tree branches or rock ledges, are respected for the important services they provide to both humans and local forest ecosystems. The relationship between humans and A. dorsata is ancient, dating back potentially more than 40,000 years (Crane 1999). Despite the prominence of these iconic insects in the Asian landscape and their profound biological and cultural significance, however, little is known about A. dorsata, including the conservation status of populations in Peninsular Malaysia and beyond. Although insects tend to receive less attention than charismatic megafauna such as hornbills or tigers, it is crucial that basic information on these small but vital pollinators is collected before it is too late. At home up high The global distribution of A. dorsata stretches from Indonesia in the southeast to western India and Pakistan in the northwest (Hepburn and Radloff 2011), with 28 Malaysian Naturalist 2006). In Peninsular Malaysia, A. dorsata can be easily distinguished from the other honey bee species present, which include A. cerana, A. koschevnikovi, A. florea, and A. andreniformis. Spanning one metre or more in length, the nests are covered by layers of worker bees, with the honey and brood (young developing bees) located beneath.
    [Show full text]
  • The Comb Structure of Apis Dorsata F. (Hymenoptera: Apidae)
    Chiang Mai J. Sci. 2014; 41(5.1) 1077 Chiang Mai J. Sci. 2014; 41(5.1) : 1077-1083 http://epg.science.cmu.ac.th/ejournal/ Contributed Paper The Comb Structure of Apis dorsata F. (Hymenoptera: Apidae): 3-dimensional Architecture and Resource Partitioning Ninat Buawangpong [a], Prakaimuk Saraithong [a], Kitiphong Khongphinitbunjong [a], Panuwan Chantawannakul [a]* and Michael Burgett [b] [a] Department of Biology, Faculty of Science, Chiang Mai University, Chiang Mai, 50200 Thailand. [b] Department of Horticulture, Oregon State University, Corvallis, OR 97331 USA. *Author for correspondence; e-mail: [email protected] Received: 28 February 2013 Accepted: 6 September 2013 ABSTRACT The architecture of the comb structure of the giant honeybee Apis dorsata was examined, including cell sizes, comb area, comb volume, and gravimetric capacity. Regardless of comb area, the partitioning of comb between brood rearing and food storage centered around 83% of the comb surface being used for brood production. The potential gravimetric capacity of the total comb was variable displaying a range of 1–2 g per cm2 of comb surface. The largest comb examined would have had a hypothetical weight of ca. 17 kg, while the smallest comb ca. 2.0 kg. These calculations do not include the weight of adult bees. A large colony would possess as much as 8 kg of adult worker bees based on an average worker weight of 160 mg. Key words: Apis dorsata, comb structure, hexagon architecture, gravimetric capacity, comb partitioning 1. INTRODUCTION Apis dorsata F. is one of two species can be very large, with reported dimensions of Asian giant honeybees with a range of 1.5 m x 1 m [6], each colony relocation throughout the Indian subcontinent, therefore requires the construction of a new Southeast Asia and numerous southwestern nest comb which represents a major Pacific archipelagos [1].
    [Show full text]