Biodiversity Data Journal 9: e60315 CO)
doi: 10.3897/BDJ.9.e60315 open access
Data Paper

Flower-visiting insects of genus Melastoma
(Myrtales: Melastomataceae) at the Fushan
Botanical Garden, Taiwan

Joe Chun Chia Huang?, Yun Chen Hsieh§, Sheng Shan Lu®!, Wen Chi Yeh§, Jia Yuan Liang},
Chien Jung Lin!, Gene Sheng Tung+

+ Botanical Garden Division, Taiwan Forestry Research Institute, Taipei, Taiwan
§ Forest Protection Division, Taiwan Forestry Research Institute, Taipei, Taiwan
| Fushan Research Center, Taiwan Forestry Research Institute, Yuan Shan Township, Taiwan

Corresponding author: Gene Sheng Tung (gene.tung@gmail.com)

Academic editor: Yasen Mutafchiev

Received: 03 Nov 2020 | Accepted: 17 Dec 2020 | Published: 26 Jan 2021

Citation: Huang JCC, Hsieh YC, Lu SS, Yeh WC, Liang JY, Lin CJ, Tung GS (2021) Flower-visiting insects of
genus Melastoma (Myrtales: Melastomataceae) at the Fushan Botanical Garden, Taiwan. Biodiversity Data
Journal 9: e60315. https://doi.org/10.3897/BDJ.9.e60315

Abstract

Background

We investigated the diversity and behaviour of insects that visit flowers of four native
Melastoma (Family Melastomataceae) species of Taiwan and a horticultural hybrid
Melastoma species at the Fushan Botanical Garden, Taiwan biweekly from May to August
2020. Visits of flower-visiting insects were classified into seven behavioural categories,
based on the insects' behaviour and positions on the flower. The data are further assigned
into four insect-flower interactions, namely pollination, herbivory, commensalism and
neutralism. Our goal is to provide baseline data of insect-plant interactions of Melastoma,
which is a common, but understudied plant genus in the country.

© Huang J et al. 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.

2 Huang J et al

New information

A total of 1,289 visits to flowers were recorded by at least 63 insect morphospecies
belonging to seven orders. The number of insect species recorded per Melastoma species
ranged from 9 to 39. Visiting, sonication and passing were the three most frequently
recorded types of behaviour, collectively accounting for 90.2% (n = 1,240) of the total
observations. Pollination was the most dominant insect-flower interaction, accounting for
70.2% of the total observations, followed by neutralism (20.0%), herbivory (6.3%) and
commensalism (3.5%). Sweat bees of the genera Lasioglossum and Maculonomia
(Hymenoptera: Halictidae) are considered key pollinators to Melastoma species in Fushan
Botanical Garden, based on their high number of visits and sonication behaviour. Our study
provides the first list of insects that visit the flowers of all Taiwan's known Melastoma
species and description of their interactions with the plants.

Keywords

buzz pollination, Lasioglossum, Maculonomia, Melastoma kudoi, sonication

Introduction

With over 5,000 species, Melastomataceae represents one of the largest Angiosperm
families distributed in the subtropical and tropical regions around the world (POWO 2019).
Members of this flowering family have a complicated evolutionary history (Renner 1993,
Stein and Tobe 1989) and exhibit diverse morphological traits (Dellinger et al. 2018,
Renner 1989, Varassin et al. 2008) and reproduction biology (Dellinger et al. 2019, dos
Santos et al. 2012, Peng et al. 2014). The diversification of Melastomataceae is partially a
result of hybridisation events. Interspecific hybridisation within a genus (Dai et al. 2012,
Hawkins et al. 2016) and between genera (Hawkins et al. 2016, Zhou et al. 2020) have
been reported. Empirical studies suggest that hybridisation in some genera of
Melastomataceae are likely mediated by specialised insect pollinators. The pollination
syndrome in Melastomataceae is mainly, but not exclusively, dependent on bees
(superfamily Apoidea) that are able to vibrate pollen from poricidal anthers by sonication
(Renner 1989). Although interspecific hybridisation via insect pollinators has been
observed in Melastomataceae native to Asia, studies on insect-flower interactions in
Melastomataceae are largely focused on New World species (e.g. Brito et al. 2016, Brito et
al. 2017, Pereira et al. 2011, Renner 1989).

There are 18 species belonging to 12 genera of Melastomataceae in Taiwan (Huang and
Huang 1996). Of these, Melastoma is the most speciose genus with four species. Two of
which, namely Melastoma kudoi Sasaki and M. scaberrima (Hayata) (previously known as
Otanthera scaberrima, but see Yang and Liu 2002) are endemic to the Island country,
whereas the other two species, V/. candidum D. Don and M. malabathricum L. are widely
distributed in Asia, the Pacific and Australia (GBIF Secretariat 2019). Amongst the four
species, M/. kudoi/ is the rarest species, which has only been recorded from the type locality

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 3

in central Taiwan. The population of M. kudo/ is considered highly threatened and included
in the national Red List (Editorial Committee of the Red List of Taiwan Plants 2017, listed
as M. intermedia Dunn, but see the recent taxonomy revision by Dai et al. 2019) due to
habitat disturbance and lack of inclusion in protected areas (Huang and Huang 1996). The
other three Melastoma species can be commonly found in the lowlands up to mid-altitude
mountainous areas (Huang and Huang 1996). Despite the great richness of Melastoma
species in Taiwan, information about pollinators of these species is limited.

To date, only one study on the pollination biology of one Melastoma species, M. candidum,
in Taiwan has been published (Liu et al. 2008). Noteworthy, interspecific hybridisation in
this genus is often observed in both wild and cultivated plants in China and Southeast Asia
(Cai et al. 2019, Wu et al. 2019, Zhou et al. 2017). Although genetic introgression has not
been reported from Taiwan, co-occurrence of congeners, including the endangered and
endemic M. kudoi, is common in Taiwan (C.J. Lin, unpublished data). Moreover, studies
show that the primary pollinators for Melastoma species are non-specialised bees (e.g.
Amegilla, Nomia (Maculonomia) and Xylocopa bees for M. affine (M. malabathricum),
Gross 1993; Bombus, Nomia (Maculonomia) and Xylocopa bees for M. candidum, Liu et al.
2008). These generalist bees are also widely distributed in Taiwan (WCY and SSL,
unpublished data) and their habitats commonly overlap with Melastoma species in the
country. Whether these bees would visit all Melastoma species remains unknown.
Therefore, understanding the pollinator fauna of all Melastoma species in Taiwan is
essential to protect the Melastoma diversity, particularly the two endemic species, from
potential genetic introgression. In the present project, we present the first checklist of
flower-visiting insects of all known Melastoma species in Taiwan, based on empirical data.

Project description

Funding: Project of Future Plants

Sampling methods

Study extent: Established in 1990, Fushan Botanical Garden (FBG) (24°45'21.2"N,
121°35'43.5"E) is located in the mountainous area in the northeast of Taiwan Island (Fig.
1). The garden is part of the Fushan Experimental Forest, which covers approximately
1,098 ha. The vegetation is characterised mainly by natural broad-leaf forest, dominated by
trees of the families Lauraceae and Fagaceae (Su et al. 2010). The region has a
subtropical monsoon climate and is generally humid throughout the year. The mean
temperature of 18.4°C ranging from 10°C to 30°C and peaks in the summer season (June-
August). The annual rainfall is 3,787 mm, with more rain during the typhoon season (late
August-October) (Lu and Huang 2013). The study was conducted at the garden’s nursery
and surrounding trails.

4 Huang J et al

A
"ue
}

01530 60 90 120
se daal

Figure 1. EES

Fushan Botanical Garden, Taiwan. The red polygon delineates the Fushan Experimental
Forest.

Sampling description: Melastoma flower visiting insect survey

Data on the diversity of insects that visited the flowers of all Melastoma species were
obtained biweekly at FBG from 7 May 2020 to 19 August 2020. Melastoma species
included M. malabathricum L., M. candidum D. Don, M. kudoi Sasaki and M. scaberrima
(Hayata). We primarily follow the taxonomy of Yang and Liu (2002), but treat M.
septemnervium as a synonym of M. candidum as suggested by the backbone of most
catalogues (GBIF Secretariat 2019). Melastoma malabathricum is the only species of the
four that is native to this region of Taiwan (CJL, unpublished data). For VM. candidum, we
included both the typical purple-flowered form and the white-flowered form. Ten wild /.
malabathricum individuals were selected along the trails adjacent to the nursery. For the
remaining species, including the white flower variant of M. candidum, 10-15 planted
individuals for each type/species were used from the nursery. Ten planted individuals of a
horticultural hybrid of VM. scaberrima and M. kudoi (tentatively named as Melastoma kudoi x
Melastoma scaberrima) were also included. For each survey session, observations of
insects were made by 2-4 people at the same time for two consecutive days. The
observation began roughly 45 mins after sunrise, usually between 6:30 am and 6:45 am
and ended at around 11:30 am when flowers began closing or were out of pollen (JCCH,
unpublished data). In the early stage of the study by mid-June 2020, continuous
observations were made for /. malabathricum in the trails and the rest of the species in
the nursery alternatively at 20-min intervals. After the end of M. malabathricum flowering
season in mid-June, the observations were made continuously for all samples in the
nursery site. Additional data, made by random observations outside of the scheduled

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 5

survey sessions during the weekly phenology suvey (usually one hour in the morning) in
another project during the same period, were also included to maximise our understanding
of the diversity of flower-visiting insects. Taxa and behaviour (see the next section for
details) of insects with body length > 3 mm present on the adaxial surface of flowers were
recorded. Insects were identified visually in the field to the finest taxonomy level, whenever
possible. For pollinators that could not be identified in the field, 1-3 individuals of each
morphospecies were collected using a butterfly net or a plastic bag. All insect species were
identified morphologically, following existing keys (Dubitzky et al. 2008, Hsu et al. 2018,
Johnson and Triplehorn 2005, Starr 1992).

Behaviour and insect-flower interaction classification

Types of behaviour of insects visiting flowers of Melastoma species were recorded by
direct observations in the field. Further confirmations were made, based on pictures and
videos taken using phone cameras. Seven behaviour categories were defined, depending
on how insects interact with the flower and the location on the flower where the behaviour
occurred, namely sonication, visiting, stamen herbivory, petal herbivory, recycling, drinking
and passing (Table 1, Fig. 2). We did not include pollen theft, another important insect
behaviour related to interactions with flowers reported in other studies (e.g. Hargreaves et
al. 2009). Despite bees often being observed placing their mouth parts at the porous
dehiscence of the anther during our observation, there was no evidence that they removed
pollen grains from the anthers. In many cases, bees stepped on anthers before they
inserted their tongues and then sonicate the anthers afterwards. In other cases, especially
near the end of the flowering season or at the last two hours before flowers closed, bees
often left the flowers without sonicating the anthers after they performed such behaviour.
Therefore, instead of pollen theft, we assume that bees assess pollen capacity of the
anthers using both mouth parts and legs before they decide to buzz flowers. Under this
context, both types of behaviour were included into the category of visiting. The
observations of insect behaviour were further assigned into four types of insect-plant
interactions, namely pollination, herbivory, commensalism and neutralism, based upon
expected direct effects of each behaviour category for both insects and flowers (Table 1).

Table 1.
The interactions, definitions and expected effects of the seven types of behaviour of insects that
were observed to visit the flowers of Melastoma species. “+”, “-” and “OQ” signs denote positive,

negative and neutral effects, respectively, of each type of behaviour on the insect (before the left
slash) and the plant (after the left slash).

Insect-flower Type of Sign of Definition
interaction behaviour expected
effect
Pollination
Sonication +/+ Emit buzz sounds when contacting stamens or pistil, producing

vibrations that attempt to expel pollen out from anthers

6 Huang J et al

Insect-flower Type of Sign of Definition
interaction behaviour expected
effect
Visiting 0/0, O/+ Contact any part of pistil and stamens without consuming and

collecting materials and cause no obvious damage to the
reproductive organs

Herbivory
Stamen +/- Damage stamens, but not the anthers
herbivory
Petal +/- Damage petals
herbivory
Commensalism
Recycling +/0 Consume pollens expelled by other insects from the flower and
water, usually on the petals, but occasionally at the female and
male organs
Drinking +/0 Consume secretion from the flower
Neutralism
Passing 0/0 Contact only the petals without consuming and collecting

materials and cause no obvious damage to the petals

Figure 2. EES

Examples of the seven types of flower-visiting behaviour exhibited by insects on Melastoma
species: sonication (a), visiting (b), stamen herbivory (c), petal herbivory (d), recycling (e),
drinking (f) and passing (g).

Geographic coverage

Description: Fushan Botanical Garden, north-eastern Taiwan

Coordinates: 24.755 and 24.755 Latitude; 121.595 and 121.595 Longitude.

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 7

Taxonomic coverage

Description: 63 insect morphospecies belonging to seven orders that are associated with
five Melastoma plant species, including a horticultural hybrid.

Taxa included:

Rank Scientific Name Common Name

class Insecta insect

order Coleoptera beetle

order Hymenoptera bee, wasp, hornet

order Diptera fly, midge

order Hemiptera bug, plant hopper

order Lepidoptera moth, butterfly, caterpillar
order Blattodea cockroach

order Orthoptera grasshopper, cricket

Temporal coverage

Notes: 2020-05-07 through 2020-08-19

Collection data
Collection name: Forest Arthropod Collection of Taiwan

Specimen preservation method: pinned

Usage licence
Usage licence: Creative Commons Public Domain Waiver (CC-Zero)

IP rights notes: This work is licensed under a Creative Commons Attribution Non
Commercial (CC-BY-NC) 4.0 License.

Data resources
Data package title: Flower visiting insects of Melastoma in Taiwan

Resource link: https:/Awww.gbif.org/dataset/51b39c28-ce6f-4c7f-ba01-261748411e31

8 Huang J et al

Alternative identifiers: https://ipt.taibif.tw/resource?r=taiwanmelastomapollinator;
51b39c28-ce6f-4c7f-ba01-261748411e31

Number of data sets: 1
Data set name: Flower-visiting insects of Melastoma in Taiwan
Data format: Darwin Core

Description: This resource (Huang et al. 2020) is a summary of the flower-visiting
insect occurrence records, based on the observations of this project. The information of
flower visiting and flower are addressed in "occurrenceRemarks" and
"associatedTaxa", respectively. The dataset is in Darwin Core and published on GBIF.

Column label Column description

occurrencelD An identifier for the Occurrence (as opposed to a particular digital record of the
occurrence). In the absence of a persistent global unique identifier, construct one
from a combination of identifiers in the record that will most closely make the

occurrencelD globally unique.
basisOfRecord The specific nature of the data record.

eventDate The date-time or interval during which an Event occurred. For occurrences, this is

the date-time when the event was recorded. Not suitable for a time in a geological

context.
country The name of the country or major administrative unit in which the Location occurs
county The full, unabbreviated name of the next smaller administrative region than

stateProvince (county, shire, department etc.) in which the Location occurs.

municipality The full, unabbreviated name of the next smaller administrative region than county
(city, municipality etc.) in which the Location occurs. Do not use this term for a

nearby named place that does not contain the actual location.

locality The specific description of the place. Less specific geographic information can be
provided in other geographic terms (higherGeography, continent, country,
stateProvince, county, municipality, waterBody, island, islandGroup). This term may
contain information modified from the original to correct perceived errors or

standardise the description. Comments

minimumElevationInMetres The lower limit of the range of elevation (altitude, usually above sea level), in
metres.
decimalLatitude The geographic latitude (in decimal degrees, using the spatial reference system

given in geodeticDatum) of the geographic centre of a Location. Positive values
are north of the Equator, negative values are south of it. Legal values lie between

-90 and 90, inclusive.

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 9

decimalLongitude

geodeticDatum

coordinateUncertaintyInMetres

scientificName

kingdom
phylum

class

order

family

genus
specificEpithet

infraspecificEpithet

taxonRank
identificationRemarks

lifeStage

vernacularName

associatedTaxa

behaviour

fieldNumber

catalogNumber

The geographic longitude (in decimal degrees, using the spatial reference system
given in geodeticDatum) of the geographic centre of a Location. Positive values
are east of the Greenwich Meridian, negative values are west of it. Legal values lie

between -180 and 180, inclusive.

The ellipsoid, geodetic datum or spatial reference system (SRS) upon which the

geographic coordinates given in decimalLatitude and decimalLongitude are based.

The horizontal distance (in metres) from the given decimalLatitude and
decimalLongitude describing the smallest circle containing the whole of the
Location. Leave the value empty if the uncertainty is unknown, cannot be
estimated or is not applicable (because there are no coordinates). Zero is nota

valid value for this term.

The full scientific name, with authorship and date information if known. When
forming part of an Identification, this should be the name in the lowest level
taxonomic rank that can be determined. This term should not contain identification

qualifications, which should instead be supplied in the IdentificationQualifier term.
The full scientific name of the kingdom in which the taxon is classified.

The full scientific name of the phylum or division in which the taxon is classified.
The full scientific name of the class in which the taxon is classified.

The full scientific name of the order in which the taxon is classified.

The full scientific name of the family in which the taxon is classified.

The full scientific name of the genus in which the taxon is classified.

The name of the first or species epithet of the scientificName.

The name of the lowest or terminal infraspecific epithet of the scientificName,

excluding any rank designation.
The taxonomic rank of the most specific name in the scientificName.
Comments or notes about the Identification.

The age class or life stage of the biological individual(s) at the time the Occurrence

was recorded.
A common or vernacular name.

A list (concatenated and separated) of identifiers or names of taxa and their

associations with the Occurrence.

A description of the behaviour shown by the subject at the time the Occurrence

was recorded.

An identifier given to the event in the field. Often serves as a link between field

notes and the Event.

An identifier (preferably unique) for the record within the dataset or collection.

10 Huang J et al

institutionCode The name (or acronym) in use by the institution having custody of the object(s) or

information referred to in the record.

recordedBy A list (concatenated and separated) of names of people, groups or organisations
responsible for recording the original Occurrence. The primary collector or
observer, especially one who applies a personal identifier (recordNumber), should
be listed first.

Additional information
Results

A total of 1,298 insect visits were observed, which generated 911 occurrence records of
flower-visiting insects, of which more than one-third of the visits were made to the
horticultural hybrid species, Melastoma kudoi x Melastoma scaberrima (n = 437). Of the
remaining observations, 12-19% were recorded for each of the remaining species/forms
and only 3.8% of the observations were recorded for M. scaberrima. Around 15.6% and
56.3% of the insects sampled could be identified to species and genus, respectively and
the rest are identified to family or higher levels (Table 2). The number of insect taxa
recorded from each Melastoma species ranged from 9 to 39 morphospecies, for a total
across all Melastoma species of at least 63 insect morphospecies of seven orders (Table
2).

Table 2.

Diversity of flower-visiting insects and the accumulative number of visits for each Melastoma
species.

M. M. candidum M.candidum_ M. M. Hybrid
malabathricum _ purple- white- kudoi_ = scaberrima
flowered form flowered form

Blattodea

Blaberoidea

Ectobiidae

Symploce sp. 1
Coleoptera

Chrysomeloidea

Chrysomelidae

Arthrotus tricolor 1
Basilepta varians 3
Lagria sp. 1

Monolepta hieroglyphica 1

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ...

M. M. candidum
malabathricum _ purple-

flowered form

Monolepta signata

Nonarthra chengi

Nonarthra sp. 1
Theopea sauteri 2

Unidentified leaf beetle 7

Elateroidea

Elateridae

Elateridae gen. sp. 2

Scarabaeoidea
Scarabaeidae

Cetoniinae gen. sp.

Popillia livida

Popillia taiwana 1
Scarabaeidae gen. sp. 1
Tenebrionoidea

Mordellidae

Mordellidae gen. sp.
Unidentified coleopteran 1
Diptera

Ephydroidea

Drosophilidae

Drosophilidae gen sp. 3
Muscoidea

Anthomyiidae

Anthomyia illocata

Oestroidea

Calliphoridae

Calliphoridae gen. sp.

Chrysomya sp.1 5 4
Chrysomya sp.2 3
Sciaroidea

Sciaridae

M. candidum M. M.
white- kudoi_ = scaberrima

flowered form

5 5 1

11

Hybrid

26

13

12

Sciaridae gen. sp.
Syrphoidea
Syrphidae
Episyrphus balteatus
Paragus sp.
Sphaerophoria sp.
Syrphidae gen. sp.
Tephritoidea
Tephritidae
Spathulina acroleuca
Unidentified dipteran
Hemiptera
Coreoidea
Coreidae

Coreidae sp.

Fulgoroidea

Unidentified planthopper

Lygaeoidea
Geocoridae
Geocoris varius
Miroidea
Miridae

Eurystylus sp.

Pilophorus formosanus

Miridae gen. sp.
Reduvoidea
Reduviidae
Reduviidae gen. sp.
Unidentified bug
Hymenoptera
Apoidea

Apidae

Huang J et al
M. M.candidum M.candidum_ M. M. Hybrid
malabathricum _ purple- white- kudoi__scaberrima

flowered form flowered form

2
1
1
1
9 2 1 1
1 1
8 4 2 2 8
1
1
1
1 1
2 6
2 1
1
1
5 3 1

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 13

M. M.candidum M.candidum_ M. M. Hybrid
malabathricum _ purple- white- kudoi = scaberrima
flowered form flowered form

Amegilla calceifera 1

Amegilla sp. 5 1 2 1

Amegilla urens 2 1
Apis cerana 6 4
Bombus eximius/flavescens 3 1 2 4
Bombus flavescens 1

Ceratina pulchripes 4 2

Ceratina sauteri 2

Ceratina sp. 4 1 1 1

Xylocopa dejeanii sauteri 1 2
Xylocopa rufipes 12

Xylocopa tranquebarorum 8 7 1 4
Halictidae

Lasioglossum formosae 8 2 5 1 2
Lasioglossum 2

scaphonotum

Lasioglossum subopacum 1 1 1 1 2

subopacum

Lasioglossum sp. 15 33 92 31 5 105

Maculonomia planiventris 1

Maculonomia proxima 2 1 2
Maculonomia sp. 1 50 31 63 15 162
Megachilidae

Megachile rufovittata 1

Megachile sp. 2

Vespidae

Vespa velutina 2 2
Vespidae gen. sp. 1

Unidentified bee 11 1 4

Formicoidea

Formicidae

Crematogaster sp. 17 4 1

14

Formicidae gen. sp.
Myrmicinae sp.
Polyrhachis sp.
Tetraponera thagatensis
Ichneumonoidea

Unidentified parasitoid
wasp

Braconidae
Braconidae gen. sp.
Ichneumonidae

Ichneumonidae sp.

Unidentified hymenopteran

Lepidoptera
Arctiidae

Arctiidae gen. sp.
Erebidae

Euproctis sp.
Noctuidae
Noctuidae gen. sp.
Papilionoidea
Hesperiidae

Borbo cinnara
Hesperiidae gen. sp.
Lycaenidae
Lycaenidae gen. sp.
Nymphalidae
Athyma selenophora
Papilionidae
Graphium sarpedon
Unidentified butterfly
Orthoptera

Unidentified orthopteran

Huang J et al

M. M. candidum
malabathricum _ purple-

flowered form

22 32
1
1 1
1
1
1
1
2 2
1
1 2
9 1

1

M. candidum M.
white- kudoi
flowered form

23 27
1

4
7 7
3 1
1
1
7 1
1
3 1
1 3

Hybrid

51

17

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 15

M. M.candidum M.candidum_ M. M. Hybrid
malabathricum _ purple- white- kudoi_ =scaberrima

flowered form flowered form

Acridoidea

Unidentified grasshopper 2 5
Acrididae

Xenocatantops 3

brachycerus

Tettigonioidea
Unidentified bush cricket 5

Tettigoniidae

Conocephalus melas 3
Mecopoda sp. 2
Mecopodinae gen. sp. 3

Visiting, sonication and passing were the three most commonly-recorded types of
behaviour, comprising 37.3%, 32.8% and 20.0%, respectively, of the total observations of
behaviour (n = 1,240). The other four behaviour categories only accounted for less than
10.0% of the total observations. With 870 observations, pollination was the most dominant
insect-flower interaction recorded on Melastoma species, followed by neutralism (n = 248),
herbivory (n = 78) and commensalism (n = 44).

Pollinating insects that demonstrated sonication behaviour were exclusively bees in
families Apidae and Halictidae (Hymenoptera: Superfamily Apoidea). Amongst. all
sonicating bees, sweat bees of genera Lasioglossum and Maculonomia were the two most
common taxa, accounting for 89% of all flower visits (Fig. 3). There was a higher diversity
of pollinator taxa showing visiting behaviour than other types of behaviour on Melastoma
flowers, including insects of 22 families of all seven orders. Lasioglossum and
Maculonomia bees, adult insects of Coleoptera (mainly families Chrysomelidae and
Elateroidea) and Formicidae (Hymenoptera) were the four most frequently encountered
taxa in our samples (Table 1Fig. 4).

Discussion

This study provides the first checklist of flower-visiting insects to all Melastoma species in
Taiwan with an emphasis on insect-plant interactions, based on our field observations. Our
data show a diverse flower-visiting insect fauna of at least 63 morphospecies which is
higher than observations in similar studies on Melastoma (Gross 1993, Liu et al. 2008,
Peng et al. 2014, Peng et al. 2012). The majority of the insects exhibited sonicating and
visiting behaviour, which presumably can be linked to pollination interaction. Buzz-
pollinating bees of the families Apidae and Halictidae and particularly members of the
genera Lasioglossum and Maculonomia, were the most common pollinators of Melastoma

16 Huang J et al

plants in our study site. These findings support the previous conclusion that this genus is
primarily buzz-pollinated and highly dependent on bees for pollination.

300

250
=
w 200
>
Se
°
¥Y 150
3)
2
5
100
2
50
Lo —
Maculonomia Lasioglossum Xylocopa Bombus Amegilla Unidentified
bee
Bee Taxa
Figure 3. EES]

Number of visit by different bee taxa that exhibit sonicating behaviour on flowers of Melastoma
species.

Despite the commonality in the dependence of buzz-pollinating bees, our results reveal a
different bee pollinator composition to other studies on Melastoma plants, even for the
same plant species. Liu et al. (2008) studied pollination biology of MWelastoma candidum
and other three confamiliar species in Melastomataceae in central Taiwan and found that
bees of genera Bambus and Xylocopa (both Apidae) are the primary pollinators. Studies on
M. malabathricum (affine) in Australia (Gross 1993) reported Xylocopa, Amegilla (family
Apidae) and Nomia (Maculonomia) as the main pollinators. Studies on several Melastoma
species in southern China suggested that Bambus and Xylocopa, as well as Amegilla
bees, are the most important pollinators (Liu et al. 2008, Luo et al. 2008, Peng et al. 2012,
Peng et al. 2014). Except Maculonomia bees, these common bee pollinators of Melastoma
, particularly the genus Amegilla, represent the minority in our observations.

The discrepancy between studies could be explained by the variations in local bee fauna.
Landscape features (Ferreira et al. 2013, Sritongchuay and Bumrungsri 2016), elevation
effect (Hoiss et al. 2015) and biogeography (Traveset et al. 2016) could greatly shape bee
assemblages and associated pollination networks via trait-filtering resource partitioning and
phenological mismatches between pollinators and plants. This might not be the case in this
study, because Amegilla and Bambus bees are both considered common and abundant at
the Fushan Botanical Garden (WCY and SSL, unpublished data). For example, Amegilla
were abundant at the nursery, but rarely visited Melastoma flowers throughout the study
period (JCCH, YCH, WCY and SSL, unpublished data). A possible cause of the shifted

Flower-visiting insects of genus Melastoma (Myrtales: Melastomataceae) ... 17

pollination niches is that local bees might not recognise the experimental Melastoma plants
as an available food resource (Williams 2002) since three of the four plant species are not
native to Fushan. Nevertheless, lack of experience cannot completely explain why these
bees did not visit the native M/. malabathricum often. Other studies show that inter-specific
competition of pollinators and pollens mediated by floral neighbourhoods (Bruckman and
Campbell 2014) and the presence of a super pollinator (Gross and Mackay 1998, Thomson
2004), respectively, could also significantly change the pollinator-plant partnership. Further
studies are necessary to clarify the causes of the shifted pollination network in Fushan.

Number of Visit

is
> > 2
e BS om
oO °
> Q

a. ——_,

2
.)

> J
tes Ss we

60 +
40 4
a i LT
0 + r T 7 T T r i r a
& 2 2 e > 2 e >
& ng 2 . >
> om < (> Oy se & &
os? S ) > ys > iy o >
~ ~ Of aad eer oO LQ -O

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Py XN v * > ¢
or? ze & 2 > “ 2)

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> >
@ > &
2 a KO >, eo a\
PS S$
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%
ao,
,Y,
%
%,
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Insect Taxa

Figure 4. EES

Number of visits by different insect taxa that exhibit pollinating behaviour on flowers of
Melastoma species. On the x-axis, Hym denotes order Hymenoptera; Unid. Bee denotes
unidentified bee.

The occurrence of herbivores and their damage to flower structures could supress the
pollination process in several ways. First, complete loss of stamens and pollens inside
certainly terminate the further chances of pollen transferring. Konzmann et al. (2020)
demonstrated that physical modification of anthers could greatly affect the efficiency of
pollen-spreading to bees in a neotropical Melastomataceae species. In this case, bees
may fail to load pollen to their body if they sonicate damaged stamens, regardless of the
amount of pollen remaining inside. Loss and modification of stamen(s) and petal(s) could
also reduce the chance of flowers being visited by bees as these floral traits are often
found as a resource guide in Melastomataceae plants (Larson and Barrett 1999, Luo et al.
2008). Moreover, in our observations, many herbivorous insects, particularly those with
large body size, hindered other flower visitors by active-guarding behaviour or simply
covering the reproductive organs with their body (as shown in Fig. 2c). Such trait-mediated
processes, mediated by flower herbivores, could also diminish the pollination process at an
early stage (Gongalves-Souza et al. 2008).

18 Huang J et al

While reproduction biology is recognised as an essential part of plant conservation,
identifying key pollinators and pollination mechanisms becomes fundamental (Havens et
al. 2006, Moza and Bhatnagar 2007). Without such information, cultivation of closely-
related species with high hybridisation potential, as observed in Melastoma (Dai et al.
2012, Liu et al. 2014, Wu et al. 2019) in ex situ collection sites, may increase chances of
genetic introgression (Lozada-Gobilard et al. 2020). The hybridisation risk in ex situ
collections might be more severe for sanctuaries in the tropics as most countries in the
tropical regions usually have mega-diverse flora, but often grow high numbers of species in
a confined area due to lack of sufficient infrastructure. Noteworthy, Target 8 of the Global
Strategy for Plant Conservation aims to preserve at least 75% of threatened species of
global flora by 2020. Following the Target, many national and regional botanical gardens,
for example, Taiwan Forestry Research Institute, have been expanding their ex situ
collections since 2012 (Botanic Gardens Conservation International 2012). Further studies
on how environmental and ecological factors may drive pollination networks are helpful in
preventing ex situ plant conservation from accidental hybridisation events.

Acknowledgements

This study is supported financially by the Project of Future Plants to GST. We thank Yider
Hsu and nursery staff of Fushan Research Center for various level of support to the field
work and experimental setting-up, Ming-Jer Yeh for assisting mapping, Le Tuan Quan for
sharing insect pictures, Melissa Jean-Yi Liu of TAIBIF for technical support of data
publication to GBIF and Tian-Chuan Hsu for suggestions of Melastoma taxonomy. We also
appreciate the valuable comments from the editors and reviewers to both the dataset and
manuscript.

Author contributions

JCCH and GST designed the experiment. GST acquired funding. JOCCH, CJL and GST set-
up and maintained the experimental plants in the nursery. JOCCH, YCH and SSL contributed
to fieldwork. JCCH, YCH, WCY and SSL identified insect samples. YCH prepared the
specimens. JCCH, YCH and JYL cleaned and formatted the data. JCCH wrote the first
draft. YCH, SSL, YCH, JYL, CUL and GST are the joint co-authors with equal contribution.

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