JHR 97: 541-544 (2024) or % JOURNAL OF = *22ereewee openasces journal

doi: 10.3897/jhr.97. 123853 SHORT COMMUNICATION () I Tymenopter a
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https://jhr.pensoft.net The international Society of Hymenopteriss REGEARCH

Use of a novel nesting material by the spider wasp
Dipogon variegatus (Hymenoptera, Pompilidae)

Sergio Albacete'”, Gonzalo Sancho!”, Jordi Bosch?

| Universitat Autonoma de Barcelona, 08193 Bellaterra, Spain 2. Centre for Ecological Research and Forestry
Applications (CREAF), 08193 Bellaterra, Spain

Corresponding author: Sergio Albacete (s.albacete@creaf.uab.cat)

Academic editor: Christopher K. Starr | Received 24 March 2024 | Accepted 20 May 2024 | Published 24 July 2024
https://zoobank. org/4EOC2EBF-229F-4294-88 1 E-659A972E360B

Citation: Albacete S, Sancho G, Bosch J (2024) Use of a novel nesting material by the spider wasp Dipogon variegatus
(Hymenoptera, Pompilidae). Journal of Hymenoptera Research 97: 541-544. https://doi.org/10.3897/jhr.97.123853

Abstract

A female spider wasp Dipogon variegatus was filmed stealing fragments of pollen-nectar provision from a
solitary bee (Osmia cornuta) nest and using them for the construction of her nest. The female wasp applied
the sticky fragments of the pollen-nectar provision to the outer surface of her closing nest plug, thus glu-
ing together pieces of debris filling the nesting cavity. Previous descriptions of D. variegatus nests indicate
that females of this species usually use spider silk to provide cohesion to the nest plug. Our observations
provide an example of behavioural plasticity and innovation in the use of nesting materials. We describe

the structure of the nest and the sequence of emergence of the progeny.

Keywords
Behavioural plasticity, nesting biology, Osmia, solitary bee

Most bees and wasps in the superfamilies Apoidea, Pompiloidea and Vespoidea are soli-
tary and build nests in which they deposit food provisions for their progeny. Many of
these species excavate their nests (usually underground), but some use a variety of pre-es-
tablished cavities (O’Neill 2001; Danforth et al. 2019). Cavity-nesters typically incorpo-
rate external materials such as mud, pebbles, and various sorts of plant matter, including
resin, pubescence, leaf cuttings and masticated leaf, to delimit cells and close their nests.
The nesting materials used are species-specific. Most species use a single type of material,
but some use a combination (Stephen et al. 1969; Iwata 1976). Notably among the latter

Copyright Sergio Albacete et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
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542 Sergio Albacete et al. / Journal of Hymenoptera Research 97: 541-544 (2024)

are Dipogon and other related genera of spider wasps (Pompilidae), which use a combi-
nation of materials of mineral, plant, and animal origin (Krombein 1967; Shimizu and
Ishikawa 2002). Here we describe a nest of the spider wasp Dipogon variegatus (Linnaeus,
1758) and report on the collection and use of a novel nesting material by this species.

In May 2020 we observed a D. variegatus female nesting at a nesting station for mason
bees (Osmia spp.) in Santa Caterina, Parc del Montgri (Girona, NE Spain). The nesting
station contained four nesting wooden blocks. Each block had 25 drilled holes into which
paper straws (15 cm long, 8 mm diameter) were inserted. At the time of the observations,
several Osmia cornuta (Latreille 1805) females were nesting in the wooden blocks. Like
other solitary bees, O. cornuta stock their nests with provisions of pollen mixed with nectar.

On 5 May, we observed a D. variegatus female, entering an active O. cornuta nest
and coming out with small pieces of provision between her mandibles (https://youtu.
be/umbqd9v9n-s). The wasp female then walked to her nesting cavity and applied the
stolen piece of provision to the plug of her nest (Fig. 1). This sequence of events was
repeated at least 3 times.

On 7 May, the paper straw containing the D. variegatus nest was taken to the labo-
ratory and on 17 May we analysed its contents. The spider provisions had completely
been consumed and the wasp larvae had already spun their cocoons.

The nest occupied most of the length of the paper tube and had a loose struc-
ture, without clearly-defined cell partitions. It contained six cocoons longitudinally
or obliquely arranged along the inner third of the paper straw (Fig. 2). The rest of the
nest was filled with loose debris, including clumps of soil, pebbles, fragments of leafs
and twigs, male pine cones and snail feces. The fragments of O. cornuta pollen-nectar
provision were only found on the outer surface of the closing plug (Figs 1, 2).

Cocoons were 0.8—1 cm long and 2—3 mm wide and had two distinct layers. ‘The
inner layer consisted of a non-translucent whitish matrix with a shiny inner surface.
The outer layer was a mesh of silk strands with debris attached to them (Fig. 3). We
placed the cocoons individually in small plastic containers and kept them outdoors in a
shaded area. Four adults emerged over a period of 4 days (a male from cocoon 5 on the

Figure |. Plug of Dipogon variegatus nest (top left) plastered with pieces of orange-coloured pollen-nectar

provision stolen from an Osmia cornuta nest. The two mud plugs at the bottom are O. cornuta nests.

Use of a novel nesting material by a spider wasp 543

Figure 2. Dipogon variegatus nest. The blue arrows indicate the location of the six cocoons, partially hid-

den by the debris. The red arrow indicates the fragments of the orange-coloured Osmia cornuta provision.

~s,

Figure 3. Close-up of the six cocoons after partial removal of the debris.

4" of June, two females from cocoons | and 3 on the 6" June, and a male from cocoon
6 on the 7" June). On July 15" we dissected the two remaining cocoons. Cocoon 2
contained a dead prepupa and cocoon 4 a dead male pupa.

Species of Dipogon and related genera are known to use a wide variety of materials
to build their nests (Krombein 1967), including parts of dead insects and even entire
ant corpses (Staab et al. 2014). To our knowledge, however, this is the first report of a
solitary wasp using pollen as a nesting material. D. variegatus is known to use spider silk
to bind together the debris filling its nest, especially at the entrance (Junco and Reyes
1951; Day 1988). The nest we examined had no traces of spider silk. The female we
observed used a completely different kind of sticky material, the pollen-nectar provision
from a solitary bee nest, to provide cohesion to the various fragments of debris con-
forming the nest plug. The nesting station created a situation in which a large number
of uncapped active solitary bee nests were available in close vicinity of the wasp’s nest.
This scenario probably facilitated the encounter and use of pollen-nectar provisions by
the D. variegatus female.

The use of novel nesting materials, sometimes of anthropic origin, has long been
documented in birds and has been interpreted as a behavioural innovation in response
to a new environmental situation (Hansell 2000). Although not so frequently, this phe-
nomenon has also been reported in solitary wasps and bees. A potter wasp Symmorphus
murarius (Linnaeus) female was found to cover the external surface of her mud nest plug
with flakes of dry paint (Westrich 2020), and various leafcutting bee species, Megachile
spp., have been reported to use plastic cuttings to line their nests (Maclvor and Moore
2013; Allasino et al. 2019; Wilson et al. 2020; Quintos-Andrade et al. 2021). Our study

544 Sergio Albacete et al. / Journal of Hymenoptera Research 97: 541-544 (2024)

provides another example of the capacity of solitary bees and wasps to modify an a priori
well-established behaviour whenever the need and/or the opportunity arise.

We thank C. Schmid-Egger for kindly confirming the identification of the spider
wasp. [his study was supported by the Spanish MCINN project RT12018-098399-B-100.

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