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Isodontia Auripes & Tree Fig

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Isodontia Auripes & Tree Fig Trap-Nesting Bees and Wasps of Deep East Texas Daniel J. Bennett,1 David L. Kulhavy2, & R. Alan Shadow3 1Department of Biology and 2Arthur Temple College of Forestry and Agriculture, Stephen F. Austin State University, Nacogdoches, TX 3East Texas Plant Materials Center, USDA-NRCS, 6598 FM 2782 Nacogdoches, TX 75964 120 Introduction 10.0-11.9 mm diameter 8 stems (81 total) Solitary, above-ground nesting bees and wasps comprise a distinct guild of 11 8.0-9.9 mm diameter 9 stems (123 total) pollinators and predators in most terrestrial habitats. These insects typically use 100 4 cavities in woody vegetation. In these cavities they provision offspring, which are 6.0-7.9 mm diameter stems (406 total) typically separated by partitions consisting of soil or plant materials (Fig. 7). 3 1 6 8 4.0-5.9 mm diameter 1 80 6 44 5 stems (456 total) 41 2.0-3.9 mm diameter These insects can often be induced to nest in various materials. When these 1 stems (101 total) materials are placed in natural areas and later retrieved, they comprise a trap that 24 10 29 60 can be used as a means to sample the trap-nesting insect fauna of a location. In the 37 lab, trap-nests can be opened to gather data on developing offspring, which may be 3 25 8 4 reared to adulthood under controlled conditions (Krombein, 1967). The vast 2 3 40 4 2 5 2 6 7 majority of studies using trap-nesting techniques have relied on drilled wood 2 8 42 7 1 52 11 37 47 2 23 1 4 5 10 15 blocks, paper tubes, or reed stems. Severed bamboo stems have less often been 1 4 19 10 1 3 2 6 28 3 11 22 2 6 5 2 16 10 3 9 utilized by researchers. 20 8 18 13 5 11 8 23 8 15 10 3 1 17 17 13 2 13 16 10 13 15 6 6 5 8 11 8 1 11 11 7 10 1 Here, we provide preliminary data on the trap-nesting bees and wasps of 8 9 9 7 6 3 4 4 5 4 4 5 5 3 3 2 3 2 2 2 3 2 2 1 3 0 1 1 0 1 1 1 Nacogdoches County, Texas and present a novel trap design for sampling cavity- Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural Urban Rural nesting insects. This design utilizes bamboo stems and a housing constructed from Figs 1–3. Stem-nesting wasp, 5/11/14 5/25/14 6/8/14 6/22/14 7/6/14 7/20/14 8/3/14 8/17/14 8/31/14 9/14/14 9/28/14 10/12/14 10/26/14 11/9/14 Isodontia auripes & tree Fig. 8. Frequency distribution of trap-nests occupied by bees and wasps at urban sites (Nacogdoches, TX) and rural sites (USDA Plant Materials Center, Nacogdoches PVC pipe, a PVC coupler, and window screen. cricket prey, Oecanthus sp. County, TX) from May–November, 2014. Methods Results and Discussion Family Genus/species Trap-nests comprised locally harvested and cut bamboo (Arundinaria Nesting activity. — During the course of this study, 1167 occupied stems Bombyliidae Anthrax (nest parasite) gigantea) with cavities of 2–12 mm diameter and lengths of 10–20 cm. were collected, which produced ca. 2200 individual insects representing Bombyliidae Lepidophora (nest parasite) Stems were held in a housing (Fig. 6) that utilized two perforated 21 genera (Table 1). Chrysididae Chrysis ? (nest parasite) panels of window screen. The screen panels were held taught between 4 a 4” long section of 4” diameter PVC pipe and PVC pipe couplers. This Nesting activity was recorded from early May until early November 2014 Crabronidae Trypoxylon (2 spp.) (Fig. 8). Peak activity occurred in the urban sites on July 6 and August 31 design allowed for easy retrieval and replacing of the stems as well as Messatoporus Ichneumonidae for spacing between the stems, which was believed to reduce the and in the rural sites on August 3. Stems with 4.0–5.9 mm diameter (nest parasite) spread of fungus and provide maximum ventilation. Moreover, other openings were used most frequently (456), followed by 6.0–7.9 mm stems Megachilidae Megachile (3 spp.) studies have shown that some stem-nesting insects prefer space (406), 8.0–9.9 mm stems (123), 2.0–3.9 mm stems (101), and 10.0–11.9 Megachilidae Coelioxys between their nest and their neighbors’ nests (Sheffield et al., 2008). mm stems (81). This housing was placed within a 12” long, green-painted PVC pipe to Megachilidae Osmia (3 spp.) provide shelter from sun and rain (Fig. 5). A set of stems comprised six During each collection event, typically < 10 stems were active per set. In Mutillidae Dasymutilla ? (nest parasite) 2.0–3.9 mm stems, six 4.0–5.9 mm stems, six 6.0–7.9 mm stems, three most cases, unoccupied stems for each size class outnumbered occupied 8.0–9.9 mm stems, and three 10.0–11.9 mm stems. Each set was stems. Thus, stems of all size classes were consistently available to insects Pompilidae Auplopus spread across two separate housings, which were wired to metal T- at each trap site over the course of the study (i.e., certain size classes Rhipiphoridae Macrosiagon (nest parasite) posts about 1.5 meters above ground (Figs 4–5). Two sets of stems were not excluded as possible nest sites due to previous insect activity). 5 were attached to each post; posts were situated in groups of threes, Sarcophagidae Senotainia (nest parasite) with 30 meters between posts. Performance of trap-nests. — The housings developed to suspend the stems functioned well. They were inexpensive, durable, and reusable. Sphecidae Chalybion zimmermani To test this new trap design, 18 sets of stems were placed at each of They provided good shading, ventilation, and spacing of stems. They Sphecidae Isodontia auripes two sites in Nacogdoches County, Texas from late April until early allowed the stems to be easily retrieved and replaced and were easily Vespidae Ancistrocerus November 2014. Site one comprised forested areas within the town of affixed to fence posts. Further, they apparently shielded the stems from Nacogdoches along La Nana Creek (NAC). Site two comprised the USDA attack by insect-eating birds. Vespidae Euodynerus (3 spp.) Plant Materials Center (PMC) located within the Stephen F. Austin Vespidae Monobia quadridens State University Experimental Forest (Fig. 4). The bamboo stems also functioned well in the field. They were utilized by 6 bees and wasps at a substantial rate, easily carried in large numbers, Vespidae Pachodynerus erynnis Traps were checked for nesting activity twice monthly, active stems easily split to observe nest occupants, durable, easily fitted with insect- Vespidae Parancistrocerus (2 spp.) were removed, and replacement stems were added to the traps. emergence containers, and were not prone to harboring moisture. Occupied stems were fitted with vials to trap emerging insects. Stems Disadvantages included the time required to harvest, cut, and sort stems Vespidae Stenodynerus were stored in a shed at ambient conditions to ensure development at to size classes, and the variations in shape of their inner cavities. In areas 7 Vespidae Symmorphus natural rates and were checked often for newly emerged adults. The where readily available, such as the southeastern United States, bamboo Figs 4–7. 4. USDA Plant Materials Center latter are currently undergoing pinning, labeling, identification, and Nacogdoches, TX. 5. Trap-nest housing. with offers an excellent trap-nesting material for use in surveys of bees, wasps Table 1. Bees, wasps, and their nest rain shield. 6. trap-nest housing 7. Opened stem and their parasites. parasites documented utilizing bamboo archival in the Dept. of Biology at Stephen F. Austin State University. showing pupae. and cell divisons. trap-nests in Nacogdoches County, TX. Literature Cited Acknowledgements 1. Krombein, K. V. 1967. Trap-nesting wasps and bees: life histories, nests, and associates. Smithsonian Press, Washington D.C. We gratefully acknowledge the tireless efforts of Brian Humphreys, Lufkin, TX Eagle Scout, who 2. Sheffield, C. S., P. G. Kevan, S. M. Westby, & R.F. Smith. 2008. Diversity of cavity-nesting bees (Hymenoptera: Apoidea) within apple orchards and wild habitats in the Annapolis Valley, Nova Scotia, Canada. Canadian Entomologist 140: 235–249. contributed to the construction and monitoring of trap-nests used in this study. .
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