Accidental importation of a Japanese bat into New Zealand

Abstract

A juvenile female Japanese pipistrelle (Pipistrellus javanicus abramus) wap found dead on 9 December 1981 in Hamilton, New Zealand, in a package of car parts from Japan. This is apparently the first accidental importation of an exotic bat to New Zealand.     

Feeding by the short‐tailed bat (Mystacina tuberculata) on fruit and possibly nectar

New Zealand's short‐tailed bat (Mystacina tuberculata Gray, 1843) feeds on fruit, insects, and possibly nectar in North Island kauri (Agathis australis) forest. Fruits eaten by members of a colony of 500 bats in May included those of Freycinetia baueriana (Pandanaceae), Collospermum hastatum, and C. microspermum (Liliaceae). Pollen analyses of bat guano, and of the stomach contents of 4 short‐tailed bats from Omahuta Forest (Lat. 35°10'S) and 3 from Stewart Island and adjacent islands (Lat. 47°15'S), showed that most of the pollen was from flowers of Metrosideros and Leptospermum (Myrtaceae), Knightia excelsa (Proteaceae), and Collospermum, and that spores of the tree fern Cyathea (Cyatheaceae) were present also. Both Metrosideros and Knightia have abundant nectar. The partially extensile tongue of Mystacina is tipped with a brush of fine papillae, possibly to extract nectar and pollen; but the pollen and spores in the bat stomachs and guano could have come from insects eaten by the bats. Transverse ridges on the tongue may assist removal of juice from ripe fruits. These bats may disperse the small seeds of Freycinetia baueriana. The anatomical modifications of Mystacina for terrestrial and arboreal locomotion may have evolved primarily in response to its frugivorous and suspected nectarivorous habits.     

Parallel Evolution of the Glycogen Synthase 1 (Muscle) Gene Gys1 Between Old World and New World Fruit Bats (Order: Chiroptera)

Glycogen synthase, which catalyzes the synthesis of glycogen, is especially important for Old World (Pteropodidae) and New World (Phyllostomidae) fruit bats that ingest high-carbohydrate diets. Glycogen synthase 1, encoded by the Gys1 gene, is the glycogen synthase isozyme that functions in muscles. To determine whether Gys1 has undergone adaptive evolution in bats with carbohydrate-rich diets, in comparison to insect-eating sister bat taxa, we sequenced the coding region of the Gys1 gene from 10 species of bats, including two Old World fruit bats (Pteropodidae) and a New World fruit bat (Phyllostomidae). Our results show no evidence for positive selection in the Gys1 coding sequence on the ancestral Old World and the New World Artibeus lituratus branches. Tests for convergent evolution indicated convergence of the sequences and one parallel amino acid substitution (T395A) was detected on these branches, which was likely driven by natural selection.     

Human activities link fruit bat presence to Ebola virus disease outbreaks

1. A significant link between forest loss and fragmentation and outbreaks of Ebola virus disease (EVD) in humans has been documented. Deforestation may alter the natural circulation of viruses and change the composition, abundance, behaviour and possibly viral exposure of reservoir species. This in turn might increase contact between infected animals and humans.
2. Fruit bats of the family Pteropodidae have been suspected as reservoirs of the Ebola virus. At present, the only evidence associating fruit bats with EVD is the presence of seropositive individuals in eight species and polymerase chain reaction-positive individuals in three of these.
3. Our study investigates whether human activities can increase African fruit bat geographical ranges and whether this influence overlaps geographically with EVD outbreaks that, in turn, are favoured by deforestation.
4. We use species observation records for the 20 fruit bat species found in favourable areas for the Ebola virus to determine factors affecting the bats' range inside the predicted Ebola virus area. We do this by employing a hypothetico-deductive approach based on favourability modelling.
5. We show that the range of some fruit bat species is linked to human activities within the favourable areas for the Ebola virus. More specifically, the areas where human activities favour the presence of five fruit bat species overlap with the areas where EVD outbreaks in humans were themselves favoured by deforestation. These five species are as follows: Eidolon helvum, Epomops franqueti, Megaloglossus woermanni, Micropteropus pusillus and Rousettus aegyptiacus. Of these five, all but Megaloglossus woermanni have recorded seropositive individuals. For the remaining 15 bat species, we found no biogeographical support for the hypothesis that positive human influence on fruit bats could be associated with EVD outbreaks in deforested areas within the tropical forest biome in West and Central Africa.
6. Our work is a useful first step allowing further investigation of the networks and pathways that may lead to an EVD outbreak. The modelling framework we employ here can be used for other emerging infectious diseases.

     

Cloning and Molecular Evolution of the Aldehyde Dehydrogenase 2 Gene (Aldh2) in Bats (Chiroptera)

Old World fruit bats (Pteropodidae) and New World fruit bats (Phyllostomidae) ingest significant quantities of ethanol while foraging. Mitochondrial aldehyde dehydrogenase (ALDH2, encoded by the Aldh2 gene) plays an important role in ethanol metabolism. To test whether the Aldh2 gene has undergone adaptive evolution in frugivorous and nectarivorous bats in relation to ethanol elimination, we sequenced part of the coding region of the gene (1,143 bp, ~73 % coverage) in 14 bat species, including three Old World fruit bats and two New World fruit bats. Our results showed that the Aldh2 coding sequences are highly conserved across all bat species we examined, and no evidence of positive selection was detected in the ancestral branches leading to Old World fruit bats and New World fruit bats. Further research is needed to determine whether other genes involved in ethanol metabolism have been the targets of positive selection in frugivorous and nectarivorous bats.     

A new bat‐fly family from New Zealand (Diptera: Mystacinobiidae)

Mystacinobia zelandica n.sp. is described. It is the sole member of Mystacinobia new genus and of Mystacinobiidae new family, and belongs to the superfamily Drosophiloidea. The species lives in large communities in roosts of the New Zealand short‐tailed bat, Mystacina tuberculata, and requires temperatures around 30°c for development and survival. Adults are physogastric, apterous, and have reduced eyes. The claws are adapted for movement over bat fur, but the mouthparts are not modified for blood‐feeding. Adults and larvae feed on guano. Eggs are laid in clusters in roost wood, and have non‐functional respiratory horns. Larvae have elongate anterior spiracles, tubular posterior spiracles, and 5 pairs of anal papillae. The puparium has a reduced operculum. Dispersal to new roosts depends entirely on transport by Mystacina, and as many as 10 phoretic flies have been found embedded in fur of individual bats leaving a roost to feed at night. The species has reached a degree of sociality which includes group oviposition, partial overlapping of generations, clustering of all stages, mutual grooming, male polymorphism, and extension of the males’ life‐span beyond the reproductive phase to form a sound‐producing guard caste which probably prevents the bats from interfering with the bat‐fly community. Mystacinobia zelandica is part of the New Zealand Endemic (Archaic) Element, which also includes Mystacina tuberculata.     

Bat and hummingbird pollination of an AUTOTETRAPLOID COLUMNAR CACTUS,Weberbauerocereus weberbaueri (Cactaceae)

I present data on flower morphology, pollination, breeding system, and genetic diversity of the columnar cactus Weber-bauerocereus weberbaueri at 2500 m elevation in southwestern Peru. Weberbauerocereus weberbaueri is a self-compatible columnar cactus that is visited and pollinated by one species of rare endemic bat, Platalina genovensium, and two species of hummingbirds, Patagona gigas and Rhodopis vesper. W. weberbaueri exhibits pronounced interplant variation in floral color and size, and flowers exhibit traits corresponding to both bat and hummingbird pollination syndromes. Starch-gel electrophoresis of flower bud tissue indicated that W. weberbaueri is an autotetraploid and that genetic diversity (Hep = 0.257) of the study population was high relative to diploid plants but similar to other tetraploid species. Initial fruit set from pollinator exclusion experiments conducted in 1991 and 1993, at the onset of and after a drought associated with the El Niño event of 1991–1992, revealed that bats were the most important pollinators in 1991, but that hummingbirds and diurnal insects were most important in 1993. In both years, however, autogamy and lepidopteran larval infestation of fruits reduced differences in mature fruit production among pollinator exclusion treatments so that differences in mature fruit set were not statistically significant. Reduced bat pollination in 1993 is attributed to the reduced abundance of bats at the study site during a drought caused by El Niño. I hypothesize that interaction among several factors, including tetraploidy, autogamy, larval infestation of developing fruits, and variation in pollinator abundance, may not result in strong selection for a bat vs. hummingbird floral morph, thus allowing the persistence of floral variation in this cactus.     

Nectarivory by Endemic Malagasy Fruit Bats During the Dry Season1

Madagascar has a distinctive fruit bat community consisting of Pteropus rufus, Eidolon dupreanum, and Rousettus madagascariensis. In this study, we observed fruit bat visits to flowering baobabs (Adansonia suarezensis and Adansonia grandidieri) and kapok trees (Ceiba pentandra) during the austral winter. Eidolon dupreanum was recorded feeding on the nectar of baobabs and kapok, P. rufus was observed feeding on kapok only and no R. madagascariensis were seen. Three mammals species, two small lemurs (Phaner furcifer and Mirza coquereli) and E. dupreanum, made nondestructive visits to flowering A. grandidieri and are therefore all potential pollinators of this endangered baobab. This is the first evidence to show that A. grandidieri is bat‐pollinated and further demonstrates the close link between fruit bats and some of Madagascar's endemic plants. Eidolon dupreanum was the only mammal species recorded visiting A. suarezensis and visits peaked at the reported times of maximum nectar concentration. Pteropus rufus visited kapok mostly before midnight when most nectar was available, but E. dupreanum visited later in the night. These differences in timing of foraging on kapok can be explained either by differing distances from the roost sites of each species or by resource partitioning. We advocate increased levels of protection, education awareness, and applied research on both mammal‐pollinated baobab species and fruit bats, and suggest that both baobabs and bats are candidate “flagship species” for the threatened dry forests of Madagascar.     

The Distribution of Henipaviruses in Southeast Asia and Australasia: Is Wallace’s Line a Barrier to Nipah Virus?

Nipah virus (NiV) (Genus Henipavirus) is a recently emerged zoonotic virus that causes severe disease in humans and has been found in bats of the genus Pteropus. Whilst NiV has not been detected in Australia, evidence for NiV-infection has been found in pteropid bats in some of Australia’s closest neighbours. The aim of this study was to determine the occurrence of henipaviruses in fruit bat (Family Pteropodidae) populations to the north of Australia. In particular we tested the hypothesis that Nipah virus is restricted to west of Wallace’s Line. Fruit bats from Australia, Papua New Guinea, East Timor and Indonesia were tested for the presence of antibodies to Hendra virus (HeV) and Nipah virus, and tested for the presence of HeV, NiV or henipavirus RNA by PCR. Evidence was found for the presence of Nipah virus in both Pteropus vampyrus and Rousettus amplexicaudatus populations from East Timor. Serology and PCR also suggested the presence of a henipavirus that was neither HeV nor NiV in Pteropus alecto and Acerodon celebensis. The results demonstrate the presence of NiV in the fruit bat populations on the eastern side of Wallace’s Line and within 500 km of Australia. They indicate the presence of non-NiV, non-HeV henipaviruses in fruit bat populations of Sulawesi and Sumba and possibly in Papua New Guinea. It appears that NiV is present where P. vampyrus occurs, such as in the fruit bat populations of Timor, but where this bat species is absent other henipaviruses may be present, as on Sulawesi and Sumba. Evidence was obtained for the presence henipaviruses in the non-Pteropid species R. amplexicaudatus and in A. celebensis. The findings of this work fill some gaps in knowledge in geographical and species distribution of henipaviruses in Australasia which will contribute to planning of risk management and surveillance activities.     

A comparison of two bat detectors: which is most likely to detect New Zealand’s Chalinolobus tuberculatus?

ABSTRACT

The presence of bat species is commonly determined by placing acoustic bat detectors that record bat echolocation calls in the habitat they are likely to use. Detection rates are affected by variables including type of detection unit used. We compared detection rates of long-tailed bat (Chalinolobus tuberculatus) echolocation calls between two types of automated bat detectors: Wildlife Acoustics SMZC Zero Crossing Bat Recorders (ZC), and Frequency Compression Automated Bat Monitoring units (FC) produced by New Zealand’s Department of Conservation. Units were placed in locations where bats were known to be present, but not all detected bats. The median number of bat passes recorded by FC units over 10 nights was 20 compared with a median of 3 bat passes for ZC units. ZC units also detected bats over significantly fewer nights than FC units. These results suggest FC units are more sensitive and therefore better to use where long-tailed bats are expected to be at low abundance or only present infrequently. Because of inconsistencies in detection rates, we recommend the use of only one model of the detector within a monitoring project. Our data also suggests that surveys should take place over long periods to maximise likelihood of detecting bats, if present.     

Quararibea (Bombacaceae): Five new species from moist and wet forests of Costa Rica and Panama

Five new species ofQuararibea from costa Rica and Panama are described and illustrated, with notes on their ecology and relationships.Quararibea gomeziana, Q. pendula, andQ. santaritensis are from the Caribbean lowlands of the Provinces of Limón, Costa Rica, and of Bocas del Toro and Colón, Panama.Quararibea aurantiocalyx andQ. costaricensis are from montane habitats of Panama and Costa Rica. The exceptionally long pedicels ofQ. pendula far exceed those of other known members ofQuararibea and may prove to be the most striking example of adaptation to bat pollination and fruit dispersal in the genus.Quararibea costaricensis, a relatively common species, has long been erroneously identified asQ. platyphylla, a much rarer inhabitant of the same region.     

The New Zealand short-tailed bat,Mystacina tuberculata; a review of present knowledge

Abstract

Research on the New Zealand short-tailed bat is reviewed from published and unpublished studies. The monotypic family Mystacinidae, at present assigned with the Vespertilionidae and Molossidae to the Vespertilionoidea, is considered to be best re-associated with the Emballonuridae and Noctilionidae in the Emballonuroidea. The two subspecies of Mystacina tuberculata Gray are retained pending elevation to specific status. The dichotomy of Mystacina stock probably occurred in the Pliocene, with the lesser short-tailed bat (M. t. tuberculata) and the greater short-tailed bat (M. t. robusta) evolving north and south respectively of the Pliocene Manawatu Strait at the onset of Pleistocene cooling. Mystacina has no known fossil record, and its origin and phylogeny are uncertain. The possibilities of an early to mid Tertiary origin in Antarctica, Australia, or South America and of an earlier Cretaceous origin in Gondwanaland are discussed.

Mystacina feeds seasonally on forest fruits, pollen, and nectar, and probably the year round on flying and resting arthropods. The Mystacinidae thus join the tropical Phyllostomatidae and Pteropodidae as the only families among 19 at present recognised in the Chiroptera with representatives feeding wholly or partially on plants. The partially extensile tongue of Mystacina has a brush of fine papillae on the tip suggesting modification and specialisation for this diet.

Several adaptations of Mystacina for terrestrial behaviour, such as the manner of folding and protecting the wings, and the basal talons on the claws of the robust feet, are unique among the Chiroptera. These assist the bat while feeding as well as roosting. Colonies reside usually in hollow trees or caves, but occur also in other terrestrial sites such as abandoned seabird burrows, holes in cliffs of volcanic pumice, and bat-excavated tunnels in the decayed floors and sides of fallen, hollow kauri trees. The short, erect, velvet-like fur of this bat, and its talons, are probably adaptations for this crevice-dwelling and tunnel-digging behaviour. The absence of mammalian predators and the lack of competition from other mammals throughout the Tertiary are thought to have significantly influenced the evolution of its terrestrial and arboreal adaptations.

Mystacina is a relatively small bat. Adult male and female lesser short-tailed bats weigh about 12–15 g and have forearm lengths of 40–43 mm. A female bat with full-term foetus weighed 20 g, and a juvenile soon after birth weighed 3.2 g. Greater short-tailed bats have forearm lengths of 44–49 mm, and probably weigh 25–35 g. Lesser short-tailed bats at latitude 35°S are monoestrous and monotocous. Copulation probably occurs in autumn and parturition in summer (December-January). Reproductive data for greater short-tailed bats at latitude 47°S suggest that they may be polyoestrous and monotocous, parturition occurring between spring and autumn.

Parasites and associated fauna of Mystacina include a recently described family, genus, and species of bat-fly (Mystacinobia zelandica) which, unlike all other bat-flies, feeds on the guano in the roosts and not on bat blood. Mystacina also has an undescribed tick (Argas (Carios) sp.), about six undescribed species of fur mite, and a recently described subfamily, genus, and species of sarcoptic wing mite (Chirophagoides mystacops). This bat appears to have no streblids, nycteribiids, fleas, or parasitic bugs, nor have any demodicid hair follicle mites, cestodes, nematodes, or blood parasites been found.     

果实红色与黄色番茄品种植株茎部内生细菌群落结构及代谢功能特征

[目的]比较果实颜色分别为红色和黄色的番茄植株茎部内生细菌群落组成及代谢功能特征,旨在探究番茄果色形成与植株内生细菌的关联,为构建番茄育种新型的评价体系,以及开发利用有益微生物功能提供理论依据和技术支撑.[方法]基于MiSeq高通量测序技术,分析果实颜色分别为红色和黄色番茄品种植株茎部内生细菌群落组成及相关代谢功能生物...     

Tropical Secondary Forest Management Influences Frugivorous Bat Composition,Abundance and Fruit Consumption in Chiapas,Mexico

Most studies on frugivorous bat assemblages in secondary forests have concentrated on differences among successional stages, and have disregarded the effect of forest management. Secondary forest management practices alter the vegetation structure and fruit availability, important factors associated with differences in frugivorous bat assemblage structure, and fruit consumption and can therefore modify forest succession. Our objective was to elucidate factors (forest structural variables and fruit availability) determining bat diversity, abundance, composition and species-specific abundance of bats in (i) secondary forests managed by Lacandon farmers dominated by Ochroma pyramidale, in (ii) secondary forests without management, and in (iii) mature rain forests in Chiapas, Southern Mexico. Frugivorous bat species diversity (Shannon H’) was similar between forest types. However, bat abundance was highest in rain forest and O. pyramidale forests. Bat species composition was different among forest types with more Carollia sowelli and Sturnira lilium captures in O. pyramidale forests. Overall, bat fruit consumption was dominated by early-successional shrubs, highest late-successional fruit consumption was found in rain forests and more bats consumed early-successional shrub fruits in O. pyramidale forests. Ochroma pyramidale forests presented a higher canopy openness, tree height, lower tree density and diversity of fruit than secondary forests. Tree density and canopy openness were negatively correlated with bat species diversity and bat abundance, but bat abundance increased with fruit abundance and tree height. Hence, secondary forest management alters forests’ structural characteristics and resource availability, and shapes the frugivorous bat community structure, and thereby the fruit consumption by bats.     

Pollination system of the Pilosocereus leucocephalus columnar cactus (tribe Cereeae) in eastern Mexico

It has been suggested that there is a geographic dichotomy in the pollination systems of chiropterophilous columnar cacti: in intra‐tropical areas they are pollinated almost exclusively by bats, whereas in extratropical areas they are pollinated by bats, birds and bees. However, currently the studies are clumped both taxonomically (mainly Pachycereeae species) and geographically (mainly in the Tehuacan Valley and the Sonoran Desert). This clumping limits the possibility of generalising the pattern to other regions or cactus tribes. Only four of the 36 chiropterophilous cacti in Pilosocereus have been studied. Despite the tropical distribution of two Pilosocereus species, bees account for 40–100% of their fruit set. We examined how specialised is the pollination system of P. leucocephalus in eastern Mexico. As we studied tropical populations, we expected a bat‐specialised pollination system. However, previous studies of Pilosocereus suggest that a generalised pollination system is also possible. We found that this cactus is mainly bat‐pollinated (bats account for 33–65% of fruit set); although to a lesser degree, diurnal visitors also caused some fruit set (7–15%). Diurnal visitors were more effective in populations containing honeybee hives. P. leucocephalus is partially self‐compatible (14–18% of fructification) but unable to set fruit without visitors. Despite the variation in pollination system, P. leucocephalus shows more affinity with other columnar cacti from tropical regions than with those from extratropical regions. Although we report here that a new species of tropical Pilosocereus is relatively bat‐specialised, this Cereeae genus is more flexible in its pollination system than the Pachycereeae genera.     

Flower Visitation by Bats in Cloud Forests of Western Ecuador1

The importance of bat pollination has been demonstrated for many plant species. Yet this mutualism has rarely been studied on a community–wide level. In this paper we present results of a yearlong study of a bat–flower community in cloud forests on the western slopes of the Ecuadoran Andes. Of eight plant–visiting bat species caught, only Anoura caudifera and A. geoffroyi were carrying pollen. These species of Anoura supplement their diets with insects. Unlike glossophagines in other environments, however, which switch completely to a frugivorous or insectivorous diet during certain seasons, they are nectarivorous year–round and were never found with seeds or fruit pulp in their feces. Of the 13 morphotypes of pollen carried by the bats, 11 were identified to genus and 7 to species. Floral characteristics of all of these plants fit the traditional chiropterophilous syndrome well. Our study represents the first direct evidence of bat pollination for those plants identified to species, including four species of Burmeistera (Campanulaceae), as well as the first record of bat pollination for a plant of the genus Meriania (Melastomataceae). While overlap in the diets of the two Anoura was high, significant differences in visitation frequencies to particular plant species were detected. The larger bat species (A. geoffroyi) preferred large flowers, whereas the smaller species (A. caudifera) preferred small flowers.     

Ecological Responses of Frugivorous Bats to Seasonal Fluctuation in Fruit Availability in Amazonian Forests

Lowland Amazon is climatically one of the least seasonal regions on the planet, but little is known about how this is reflected in ecological seasonality. The central objective of this study was to determine whether seasonal fluctuations in the availability of fruit resources in Neotropical forests are sufficiently marked to affect the ecology and physiology of frugivorous bats. Seasonal variations in the overall bat abundance and in the captures, body condition, and reproductive activity of the two most abundant species, Carollia perspicillata and Artibeus planirostris, were studied within a region of central Brazilian Amazonia dominated by a mosaic of nonflooded (terra firme) and seasonally flooded forests (várzea and igapó). Concurrent seasonal changes in fruit availability were measured. The abundance of fruits was markedly seasonal, with far fewer resources available during the low-water season. There was a positive correlation between fruit and bat abundance. Overall, bats did not increase the consumption of arthropods during the period of fruit shortage. In A. planirostris, the body condition declined when fruits were scarcer. In both C. perspicillata and A. planirostris, foraging and reproductive activity were positively correlated with fruit availability. Consequently, the results suggest that resource seasonality is sufficiently marked to affect frugivorous bats and force them to make important eco-physiological adjustments.     

Seasonal variation in food availability and relative importance of dietary items in the Gambian epauletted fruit bat (Epomophorus gambianus)

相似文献   

What weta want: colour preferences of a frugivorous insect

Plants use colours as signals to attract mutualists and repel antagonists. Fleshy-fruits are often conspicuously coloured to signal different types of information including fruit maturity and spatial location. Previous work on fruit colour selection focus on large diurnal vertebrates, yet fruit colours are perceived differently by frugivores with different types of visual systems. Here, we tested whether a nocturnal, frugivorous, seed-dispersing insect selects fruits based on their pigmentation and whether different lighting conditions affect fruit colour selection. We captured 20 Wellington tree weta (Hemideina crassidens) from a forest reserve on the North Island of New Zealand and brought them into laboratory conditions to test their fruit colour preferences. The fruits of Coprosma acerosa, a native shrub species that naturally produces translucent, blue-streaked fruits, were dyed either red or blue. Fruits were then offered to weta in a binary (y-maze) choice test in two light conditions, either at night during a full moon or under artificial light conditions in the lab. Weta preferred unmanipulated, naturally blue-streaked fruits and artificially-blue coloured fruits over those dyed red. Furthermore, their colour preferences were unaffected by light environment. Our results therefore suggest that weta can discriminate between colours (using colour vision) in both light and dark light environments. Their consistent preferences for colours other than red indicate that weta might be responsible for the unusual colours of fleshy-fruits in New Zealand.