JHR 81: 165-180 (2021) ee, JOURNAL OF Seerertensetiene

doi: 10.3897/jhr.8 1.59365 RESEARCH ARTICLE ) I Tymenopter a
%

https://jhr.pensoft.net The Inarational Society of Hymenoperiss, RESEARCH

Missing for almost 100 years: the rare and potentially
threatened bee, Pharohylaeus lactiferus
(Hymenoptera, Colletidae)

James B. Dorey!”

I College of Science and Engineering, Flinders University, GPO Box 2100, SA, 5001, Adelaide, Australia
2 Terrestrial Invertebrates, South Australian Museum, GPO Box 234, SA, 5001, Adelaide, Australia

Corresponding author: James B. Dorey (jbdorey@me.com)

Academic editor: Jack Neff | Received 6 October 2020 | Accepted 4 January 2021 | Published 25 February 2021
http-//z00bank.org/LD8&CD33F-25C3-4B87-9F17-D9A151D8FE9B

Citation: Dorey JB (2021) Missing for almost 100 years: the rare and potentially threatened bee, Pharohylaeus lactiferus
(Hymenoptera, Colletidae). Journal of Hymenoptera Research 81: 165-180. https://doi.org/10.3897/jhr.8 1.59365

Abstract

The Australian endemic bee, Pharohylaeus lactiferus (Colletidae: Hylaeinae) is a rare species that requires
conservation assessment. Prior to this study, the last published record of this bee species was from 1923 in
Queensland, and nothing was known of its biology. Hence, I aimed to locate extant populations, provide
biological information and undertake exploratory analyses relevant to its assessment. Pharohylaeus lactiferus
was recently rediscovered as a result of extensive sampling of 225 general and 20 targeted sampling sites
across New South Wales and Queensland. Collections indicate possible floral and habitat specialisation
with specimens only found near Tropical or Sub-Tropical Rainforest and only visiting Stenocarpus
sinuatus (Proteaceae) and Brachychiton acerifolius (Malvaceae), to the exclusion of other available floral
resources. Three populations were found by sampling bees visiting these plant species along much of the
Australian east coast, suggesting population isolation. GIS analyses used to explore habitat destruction in
the Wet Tropics and Central Mackay Coast bioregions indicate susceptibility of Queensland rainforests
and P /actiferus populations to bushfires, particularly in the context of a fragmented landscape. Highly
fragmented habitat and potential host specialisation might explain the rarity of P /actiferus. Targeted
sampling and demographic analyses are likely required to thoroughly assess the status of this species and
others like it.

Keywords
Conservation, extinction risk, fragmentation, Hylaeinae, invertebrate conservation, Queensland, wildfire,

rainforest

Copyright James B. Dorey. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0),
which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

166 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

Introduction

The greatest threats to ecosystems and species worldwide are habitat loss, fragmentation
and degradation (Vie et al. 2009). Australia has already cleared over 40% of its forests
and woodlands since European colonisation, leaving much of the remainder fragmented
and degraded (Bradshaw 2012). The vast majority of clearing has occurred on freehold
and leasehold land and for animal agriculture (Evans 2016). In particular, Queensland
is a contemporary land-clearing hotspot and is responsible for more than half of all land-
clearing in Australia over the past four decades (Evans 2016). It is a failing of state and
federal government policy and regulation that land clearing in Queensland continues at
rates that should be of concern both nationally and internationally (Reside et al. 2017).

Despite the ecological importance of Australian native bees, we know very lit-
tle about their biology (Batley and Hogendoorn 2009) or conservation status. North
Queensland hosts high species richness and endemism (Crisp et al. 2001; Orme et al.
2005; Hurlbert and Jetz 2007) and several bee genera that are found nowhere else in
Australia (Houston 2018; Smith 2018). These restricted bee genera include: Ctenoplectra
Kirby (Apidae: Apinae), Nomada Scopoli (Apidae: Nomadinae), Mellitidia Guérin-
Méneville (Halictidae: Nomiinae), Reepenia Friese (Halictidae: Nomiinae), Patellapis
Friese (Halictidae: Halictinae) and Pharohylaeus Michener (Colletidae: Hylaeinae).

Pharohylaeus has only two described species: P papuaensis Hirashima & Roberts in
Papua New Guinea and P /actiferus (Cockerell) in Australia (Houston 1975; Hirashi-
ma and Roberts 1986). Both species are relatively large (9-11 mm), robust, mostly
black with distinctive white facial and body markings, and have the first three ter-
gal segments enlarged and enclosing the others. The former is known only from two
females which were collected on Syzygium aqueum (Burm.f.) Alston (Myrtaceae) in
1982 (Hirashima and Roberts 1986). No published records of P lactiferus have been
made since the third of January 1923, when three males were collected in the Atherton
Tablelands; in May of 1900 a male and a female were collected in Mackay while an-
other female was collected in Kuranda prior to 1910 (Cockerell 1910; Houston 1975).
However, the collection localities of these specimens are imprecise and no biological
data were recorded.

Due to the dearth of biological information on P Jactiferus prior to this study, |
aimed to locate extant populations and contribute biological information as part of
a broader bee survey. Because of this, much of what follows are exploratory analyses
of the potential risks for P lactiferus and suggestions for future research. Hence, |
undertook a series of post-hoc analyses in order to provide insights into the biology,
ecology and potential extinction risks associated with P /actiferus. | provide insights
into the circumstances of the rediscovery of P /actiferus and what is now known of its
floral and habitat associations. I also explore spatial data relating to P lactiferus (vegeta-
tion association, potential fire risks and occurrences) and my sampling methods (for
potential biases). The possible floral and habitat specialisation along with the rarity of
P. lactiferus raises concerns about its conservation status. I further highlight the need
for preservation of remnant vegetation and better arthropod-diversity monitoring, par-
ticularly for at-risk and phylogenetically important species.

Missing almost a century: Pharohylaeus lactiferus 167

Methods

Sample locations and methods

I undertook general collections in parts of Queensland and New South Wales in a
variety of habitats with most collections made across two sampling periods from De-
cember to February 2018-19 and November to December of 2019 (summer). I chose
sampling sites by the presence of flowering vegetation on the side of roads and trails. |
caught specimens by sweep-netting (up to 13 m from the ground using an 11 m Lito
net) off flowering plants, vegetation or potential bee-nesting sites. After collection, |
transferred specimens to 99% ethanol and stored them at ~2 °C. For each collection
event I recorded latitude, longitude and elevation in metres above sea level (m asl) and
later checked these to ensure accuracy. I estimated the number of bees for each vial
while in the field. Other data that I collected included date, time, collector, sampling
effort (in minutes), sampling notes and, where possible, flower species visited and the
resource that I used to identify that plant. I undertook general collections between
0525 and 2200 (Suppl. material 2: Table S1). I did not collect any plant vouchers. I
identified Pharohylaeus using the keys by Houston (1975) and Smith (2018).

I used two initial collection events of P /actiferus to inform targeted sampling (see
results). However, I undertook general collections and observations at every site where
I found P /actiferus in an attempt to find additional associated plant species. I chose
targeted sampling sites haphazardly as target plant species were encountered, gener-
ally near the side of roads or hiking trails. | undertook observations of the target plant
species, Stenocarpus sinuatus (Loudon) Endl. (Proteaceae) and Brachychiton acerifolius
(A.Cunn. ex G.Don) EMuell. (Malvaceae), for a minimum of five minutes (maxi-
mum of 67 minutes) for each collection event (Suppl. material 2: Table S1). Where
I increased sampling time, I did so to collect P dactiferus specimens and to determine
their distribution or activity times. I did not undertake a systematic temporal sampling
regime; however, I made targeted collections throughout the day (between 0730 and
1751) (Suppl. material 2: Table S1).

Representative materials are stored at the South Australian Museum (SAMA 32-
37949, SAMA 32-37950, SAMA 32-40838, SAMA 32-40846, SAMA 32-40847,
SAMA 32-40848, SAMA 32-40849).

Data sources and terminology

Historic bee records

I sourced general bee collection data for Australian bioregions from the Atlas of Liv-
ing Australia (ALA 2019) and overlaid them with Australian bioregion data using QGIS
version 3.8 (QGIS Development Team 2020). I analysed all data using R version 3.6.1
(R Development Core Team 2019) and produced plots using the R packages graphics and
geplot2 (Wickham 2016). Because I sampled flowering plants as I encountered them, |
also examined potential collection biases (Suppl. material 1: Appendix).

168 James B. Dorey / Journal of Hymenoptera Research 81: 165-180 (2021)

Geographic information system data

I sourced current and pre-European National Vegetation Information System maps
from the National Mapping Division (NMD 2003b, a), which defines 85 Major Veg-
etation Subgroups for Australia (e.g., Tropical or Sub-Tropical Rainforests (TSTRs);
Major Vegetation Subgroup 2). NMD (2003b) compiled pre-European maps using
the best-available data collected at varying scales, on varying dates and by several or-
ganisations. I sourced Interim Biogeographic Regionalisation for Australia maps from
the Department of Environment and Energy (DEE 2017), which defines 89 large and
distinct bioregions (e.g., the Wet Tropics and Central Mackay Coast).

Results

Sampling

Of the ~3,585 bee specimens that I collected in Queensland over 3,446 sampling-
minutes, I collected 694 (19%) in the Wet Tropics and 153 (4%) in the Central
Mackay Coast bioregions (Suppl. material 5: Fig. S3; Suppl. material 2: Table $3). In
the adjacent bioregions of Cape York Peninsula, Einasleigh Uplands and the Brigalow
Belt North, I collected 260 (7%), 453 (13%) and 271 (8%) bee specimens, respec-
tively (Suppl. material 5: Fig. S3). In New South Wales, I collected 2,141 bee speci-
mens over 2,441 sampling-minutes (Suppl. material 2: Table $3). In total I sampled
225 general collection sites; 130 in Queensland and 95 in New South Wales (Suppl.
material 2: Table S3).

Following my initial collection of a P lactiferus female on foliage adjacent to Hal-
lorans Hill Conservation Park, Queensland (Atherton; Wet Tropics), I intensified my
sampling of flowering plants around the park for a period of three days between the
3" and 5* of February 2019 (Fig. 1). Subsequently, I collected five males patrolling
the flowers of an ~8 m high S. sinuatus tree (flowering times range from February to
June (Floyd 1978; Foreman 2020)). Pharohylaeus lactiferus males patrolled all flowers
(5-8 m high). I undertook further sampling of S. sinuatus (and other plants) in nearby
rainforest patches between the 5 and 19" of February 2019 but I did not collect any
further P /actiferus during this period (Fig. 1).

I resampled Hallorans Hill Conservation Park on the 13° of November 2019 and
collected P /actiferus foraging on B. acerifolius (flowers November to January (Guymer
1988)). I then undertook further sampling on B. acerifolius in Queensland and New
South Wales between the 13" and 28" of November (Suppl. material 5: Fig. $3). From
these collections, I collected four (2429) P /actiferus near Hallorans Hill Conserva-
tion park on B. acerifolius. In Kuranda (Wet Tropics) and Eungella (Central Mac-
kay Coast), I collected five (4419) and seven (3449) specimens, respectively, on
B. acerifolius (Fig. 1).

Missing almost a century: Pharohylaeus lactiferus 169

A A ” Current rainforests

M8 Tropical or sub-tropical rainforest
(9) Other rainforests

Rainforests cleared since 1788

MN Tropical or sub-tropical rainforest
_ Other rainforests

Pharohylaeus lactiferus

@ Present

"| @ Absent

; . (B) Central Mackay
(A) Wet Tropics Coast

Figure |. (blues) Current rainforests and (reds) rainforests cleared since European arrival (1788) in the
A Wet Tropics and the B Central Mackay Coast (NMD 2003b, a). Black markers indicate flowering
Stenocarpus sinuatus or Brachychiton acerifolius, sites where no Pharohylaeus lactiferus were detected, and

green markers (Kuranda, Hallorans Hill C.P. (Atherton), and Eungella) indicate those where they were

present. Inset shows Queensland and northern New South Wales as well as sample locations.

From the sites where I successfully collected P /actiferus, 1 sampled most plant spe-
cies that were flowering at the time (and with flowers at or below ~13 m). The plants
on which I collected bees — other than P Jactiferus — at these sites included: Alpinia
sp. (Zingiberaceae), Asteraceae sp., Callicarpa pedunculata R.Br. (Lamiaceae), Duranta
repens L. (Verbenaceae), Leptospermum sp. (Myrtaceae), Melicope rubra (Lauterb. &
K.Schum.) T.G.Hartley (Rutaceae), Parsonsia straminea (R.Br.) EMuell. (Apocynace-
ae), Senna. sp. (Fabaceae), Solanum seaforthianum Andrews (Solanaceae), and Syzygium
sp. (Myrtaceae) (Suppl. material 2: Table S3). I only identified plants on which I caught
bee specimens; thus, this represents a subset of those examined.

I undertook a total of 42 observation events on either S. sinuatus or B. acerifolius.
Ten of my observation events resulted in P /actiferus collections across three sites and
32 of my observation events returned no P Jactiferus across 20 sites (Fig. 1). I was only
successful in collecting P lactiferus between 351 and 877 m asl and only at three sites
in the Atherton, Kuranda and Eungella regions of Queensland (Fig. 1; Suppl. mate-
rial 2: Table S1). Successful collections were made between 0855 and 1637 (Suppl.
material 2: Table $1). Of the 20 sites examined, 15 were within 1 km of TSTRs and

170 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

(A) Wet Tropics (B) Central QLD Coast
=4 O°
3 a
[o)
[o)
o ive)
oe 2
fg g
by [o)
-
g 2 15
Eo
> Oo 2 7
NA
7 3
[o)
4
° 1 2
y T T T T T T 1 T_T &,+- +T °&+F °F — 0. J
1880 1900 1920 1940 1960 1980 2000 2020 1880 1900 1920 1940 1960 1980 2000 2020

Figure 2. The number of bee specimens recorded on the Atlas of Living Australia for the A Wet Tropics
and B Central Mackay Coast bioregions in ten-year intervals. Numbers above bars indicate Pharohylaeus

lactiferus specimen collections.

(A) (B) (C)
: ‘ /

Figure 3. An A oblique and B dorsal photo of a female and an C oblique photo of a male Pharohylaeus

lactiferus. Scale bar: 5 mm (B). Photos are not to scale.

12 were within 213 m (Suppl. material 2: Table $1). According to Beck et al. (2018)’s
K6ppen-Geiger climate classification map, P /actiferus occurs in both tropical and
sub-tropical climates.

Historic collection data

Historic bee records. The Atlas of Living Australia has a total of 2,198 bee records for
the Wet Tropics and 584 for the Central Mackay Coast. Of these records, 637 (29%)
in the Wet Tropics and 250 (43%) in the Central Mackay Coast do not include year of
collection. Of the records that included year of collection, the Atlas of Living Australia
only had 11 of 1,561 and 15 of 334 records that pre-dated 1924 for the Wet Tropics
and Central Mackay Coast, respectively (Fig. 2).

Missing almost a century: Pharohylaeus lactiferus 171

Supplementary results summary

I caught significantly more P /actiferus and other bees and spent more time sampling
near TSTRs (Suppl. material 1: Appendix; Suppl. material 6: Fig. $4). However, the
sum of sampling time was not significantly correlated with the number of P Jactiferus
caught, suggesting some resilience of data interpretation to bias (Suppl. material 1:
Appendix; Suppl. material 6: Fig. S4). Pharohylaeus lactiferus was only collected within
213 m of TSTR (Suppl. material 1: Appendix). Tropical or Sub-Tropical Rainforests
have undergone habitat destruction and fragmentation since European colonisation
and are susceptible to fire (Suppl. material 1: Appendix). In New South Wales and

Queensland, most B. acerifolius and S. sinuatus records occur in rainforests.

Discussion

Despite my extensive non-targeted and targeted sampling as well as bee collection
records on the Atlas of Living Australia, P /actiferus records remain rare. Appar-
ent habitat specialisation to TSTRs and few associated floral taxa (S. sinuatus and
B. acerifolius) might explain the rarity of P dactiferus. However, in many cases I found
P. lactiferus difficult to catch due to the height of the associated plant species (of the
trees that I sampled, flowers were between 1 m and 13 m high) and the bees’ quick
flight (Suppl. material 1: Appendix). It is possible that P /actiferus is a naturally
rare species that is not threatened. But, why at least two early collectors sampled
P. lactiferus on three separate occasions prior to 1924 (Houston 1975) and no pub-
lished records have been made in the years since, despite a greater sampling effort
(Fig. 2), is both unclear and of concern.

The occurrence of host plant species could limit suitable habitat for P lactiferus.
For example, the persistence of a P /actiferus population in any one rainforest could re-
quire several host plant species to provide food throughout their activity period. From
current and historical collections, we know that P /actiferus is active at least between
November and May. This could indicate a long flight period, bivoltinism or, like many
other tropical bee species (e.g., (ALA 2019; Dorey et al. 2019)), activity could be
year-round. Additionally, as many hylaeines nest in preformed holes (Almeida 2008;
Houston 2018), P dactiferus might require very specific nesting substrates (Hearn et al.
2019). Nesting substrate could further be limited to certain plant species, and by cer-
tain stem-borers that pre-excavate potential nests (Dew and Schwarz 2013; Houston
2018). Habitat destruction and fragmentation might also limit the persistence of the
required species in fragments (Suppl. material 1: Appendix). These factors might be
particularly relevant to P /actiferus, which was only found within ~200 m of TSTR,
suggesting a low foraging and dispersal distance (Suppl. material 1: Appendix).

That bees use S. sinuatus and B. acerifolius might be unexpected for two primary
reasons. Firstly, both plant species exhibit a pollination syndrome that is associated

72 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

with birds (e.g., they are bright red) (Nicolson and Van Wyk 1998; Williams and
Adam 2010; Shrestha et al. 2013). Bee vision is shifted towards ultraviolet wavelengths
and they are thought to not perceive red wavelengths (Dyer et al. 2015); although,
this is not always the case (Peitsch et al. 1992) and insect visual perception is complex
(Horridge 1998). It is possible that the flowers of S. sinuatus and B. acerifolius have
ultraviolet, or similar, markings or produce olfactory cues that attract bees. That at least
ten bee species across eight genera were foraging on B. acerifolius could indicate that
this plant is not exclusively bird-pollinated (Suppl. material 2: Table S1). Hylaeinae
bees were the primary visitors of B. acerifolius during observations (Suppl. material 2:
Table S1) which could indicate phylogenetically conserved traits that allow the use
of flowers that exhibit bird-pollination syndromes (e.g., pollen specialisation or red-
shifted vision). Secondly, Guymer (1988) reported that B. acerifolius lacks nectaries.
While I did not observe bees inside flowers due to the height of trees, I did observe
bees ‘drinking’ from flowers of the related B. populneus (Schott & Endl.) R.Br., which
Guymer (1988) also reports as lacking nectaries. Melittologists might avoid sampling
plants that exhibit bird-pollination syndromes and this could bias their collections. The
foraging preferences of P Jactiferus require further study, likely with a particular focus
on plants exhibiting bird-pollination syndromes (e.g., Alloxylon pinnatum (Maiden &
Betche) PH. Weston & Crisp, Castanospermun australe A.Cunn. ex Mudie or Erythrina
vespertilio Benth.) or even on canopy-flowering plants in general (Roubik 1993).

In the bioregions that P lactiferus has been found, this major vegetation subgroup
has undergone habitat destruction and fragmentation since European colonisation
(Suppl. material 1: Appendix) (Bradshaw 2012). Although Queensland’s Wet Tropics
have largely been protected from clearing in contemporary times, like much of the
state, habitat fragmentation remains a major conservation concern (Tucker 2000). Ad-
ditionally, three of four rainforest vegetation types (including TSTR) burnt every year
between 1988 and 2020 (for which data are available; Suppl. material 1: Appendix).
While there was no significant change over time in the area of rainforest burnt during
that period, the 2019-2020 bushfire season burnt a greater area than in any year prior
for each rainforest type (Suppl. material 1: Appendix).

To monitor and assess the conservation status of each species we require an under-
standing of their biology and targeted sampling. Data deficiency for rare species raises
concerns that other rare or specialist species could become extinct before being discov-
ered, leaving no opportunity to conserve those taxa. We must increase biomonitoring,
particularly of diverse invertebrate fauna to assess and protect such taxa worldwide.
Additionally, increasing institutional investment to digitise collections would vastly
increase the research utility of online databases and potentially allow us to differentiate
rare from threatened taxa.

Future research should aim to increase our understanding of the biology, ecol-
ogy and population genetics of P /actiferus. This work could use targeted seasonal
sampling throughout the year at sites where P /actiferus is known to occur, providing
insights into phenology and host plant species. Future studies could also use trap-nests
at various heights from the ground and targeted searches to uncover nesting require-
ments and inform conservation management (Roubik 1993; Sutherland et al. 2010).

Missing almost a century: Pharohylaeus lactiferus 173

These data, along with an expanded a priori sampling regime, should allow accurate
implementation of species distribution models to uncover other potential populations
or translocation sites. To determine if P /actiferus is threatened (undergone population
declines in the recent past) or simply rare (stable population in the recent past), genetic
data could be used to examine past demographies. Additionally, genetic data for each
population could allow examination of population isolation. Such research will be
invaluable to assess the conservation status of P dactiferus and provide an exemplar for
the assessment of other poorly-studied and threatened bee taxa.

Conclusions

Despite extensive sampling undertaken during this study and from publicly avail-
able records, P /actiferus remains poorly collected and little is known of its biology.
Pharohylaeus lactiferus has only been collected on two plant species (S. sinuatus and
B. acerifolius), to the exclusion of other available resources. Thus far, only males have
been collected on S. sinuatus. These collections might indicate floral specialisation,
potentially on plants that exhibit bird-pollination syndromes.

Many of the analyses undertaken here are exploratory and this must be considered
when making conclusions. However, it is important for likely issues to be raised in
order to inform future research and conservation efforts. To these ends, I make the fol-
lowing remarks. Pharohylaeus lactiferus could be a floral- and habitat-specialist bee. The
absence of P lactiferus collections since 1923, despite far-greater sampling effort prior
to this study, raises concerns about its conservation status. Habitat destruction and
fragmentation might have acted synergistically with the floral- and habitat-specialisa-
tion of P /actiferus to explain its rarity. However, collection habits of melittologist (e.g.,
possible avoidance of plants with bird-pollination syndromes) and the height of known
associated plants might make possible declines difficult to confirm. Regardless, known
populations of P /actiferus remain rare and susceptible to habitat destruction (e.g., from
changed land use or stochastic events such as fires; Suppl. material 1: Appendix).

Acknowledgements

I would like to thank Olivia K. Davies, Michael P. Schwarz and Mark I. Stevens for
proofing early versions of the manuscript. I further thank Lori Lach, Jack Neff, Terry
Houston and four anonymous reviewers for their insightful comments on the manu-
script that led to its improvement. I would also like to thank Erinn P. Fagan-Jeffries
and Peter Rihr for their company during field work. I would finally like to thank
the funders of this research (Holsworth Wildlife Research Endowment, Playford Trust
PhD Scholarship and AJ and IM Naylon PhD Scholarship) that support and promote
the research of many young scientists. This work was carried out under the Queensland
national parks research permit number PTU18-001277-1 and the New South Wales
National Parks & Wildlife Service scientific licence number SL102137.

174 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

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Missing almost a century: Pharohylaeus lactiferus 177

Supplementary material |

Appendix

Authors: James B. Dorey

Data type: pdf file

Explanation note: Bee flight observations, collection bias analysis, geographical infor-
mation systems, and historic associated plant records.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl1

Supplementary material 2

Tables S1—S5

Authors: James B. Dorey

Data type: Collection, site, plant and GIS data

Explanation note: Table $1. Collection data and notes for both successful and unsuc-
cesful searches for Pharohylaeus lactiferus in QLD and north-east NSW, Australia.
Table S2. Atlas of Living Australia data for Brachychiton acerifolius and. Stenocarpus
sinuatus by major vegetation subgroup (MVS) number in New South Wales and
Queensland. Green highlighted rows indicate rainforest major vegetation subgroups.
Table $3. Collection data from New South Wales and Queensland. Table $4. Major
vegetation subgroup (MVS) data including MVS number, MVS name. Measure-
ments include total MVS area (km7”) and proportions, and sampled MVS area (km’)
and proportions. Sum of the number of bees, sample time and the total area of NSW
and QLD for each MVS are also included. Table $5. Summary of fragmentation
statistics for the two bioregions, the Wet Tropics and Central Mackay Coast.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl2

178 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

Supplementary material 3

Figure S1

Authors: James B. Dorey

Data type: Figure relating to GIS analyses of plant taxa (Brachychiton acerifolius and

Stenocarpus sinuatus) associated with Pharohylaeus lactiferus

Explanation note: The number of A Brachychiton acerifolius and B Stenocarpus sinuatus
in New South Wales (NSW; blue) and Queensland (QLD; maroon) by each major
vegetation subgroup (MVS).

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.supp13

Supplementary material 4

Figure S2

Authors: James B. Dorey

Data type: The number of each plant taxa (Brachychiton acerifolius and Stenocarpus

sinuatus) associated with Pharohylaeus lactiferus by each MVS region and by year of

collection.

Explanation note: The number of A & B Brachychiton acerifolius and C & D Stenocar-
pus sinuatus in New South Wales (NSW; blue) and Queensland (QLD; maroon) by
each major vegetation subgroup (MVS).

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl4

Missing almost a century: Pharohylaeus lactiferus 1a]

Supplementary material 5

Figure S3

Authors: James B. Dorey

Data type: GIS data and map of bee collections across New South Wales and Queensland

Explanation note: Heatmap of bee collections by Australian bioregion with the focus
bioregions bolded. Points indicate the location of bee samples.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl5

Supplementary material 6

Figure S4

Authors: James B. Dorey

Data type: Results of collection bias analyses

Explanation note: The sum of A number of bees, B sample time (mins) and C P
lactiferus by distance from major vegetations subgroup (MVS) 2 — tropical or sub-
tropical rainforest — in 10 km bins. The sum of E number of bees, F sample time
(mins) and G P Lactiferus by distance from MVS 2 in the first 10 km bin of a, b and
c split in 200 m bins. The sum of P /actiferus in D 10 km bins and H 200 m bins
over sampling time (mins) where bin width is 100 minutes.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl6

180 James B. Dorey / Journal of Hymenoptera Research 81: 165—180 (2021)

Supplementary material 7

Figure S5

Authors: James B. Dorey

Data type: Sampling effort

Explanation note: Bars show the cumulative A number of insects and B sampling time
by the major vegetation subgroups (MVS) that were sampled in New South Wales
(NSW) and Queensland (QLD) (left-most Y-axes).

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl7

Supplementary material 8

Figure S6

Authors: James B. Dorey

Data type: Wildfire data for Australian rainforests

Explanation note: The area of Major Vegetation Subgroups (MVS) A one (cool tem-
perate rainforest), B two (tropical or sub-tropical rainforest), C six (warm temper-
ate rainforest) and D 62 (dry rainforest or vine thickets) burnt by year from 1988
to 2016 and the 2019-20 fire season (red).

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.81.59365.suppl8