Network analysis with either Illumina or MinION reveals that detecting vertebrate species requires metabarcoding of iDNA from a diverse fly community

Metabarcoding of vertebrate DNA obtained from invertebrates (iDNA) has been used to survey vertebrate communities, but we here show that it can also be used to study species interactions between invertebrates and vertebrates in a spatial context. We sampled the dung and carrion fly community of a swamp forest remnant along a disturbance gradient (10 sites: 80-310m from a road). Approximately, 60% of the baited 407 flies yield 294 vertebrate identifications based on two COI fragments and 16S sequenced with Illumina and/or MinION. A bipartite network analysis finds no specialization in the interaction between flies and vertebrate species, but a spatial analysis revealed that surprisingly 18 of the 20 vertebrate species can be detected within 150m of the road. We show that the fly community sourced for iDNA was unexpectedly rich (24 species, 3 families) and carried DNA for mammals, birds, and reptiles. They included common and rare ground-dwelling (e.g., wild boar, Sunda pangolin), and arboreal species (e.g., long-tailed macaque, Raffles’ banded langur) as well as small bodied vertebrates (skinks, rats). All of our results were obtained with a new, greatly simplified iDNA protocol that eliminates DNA extraction by obtaining template directly through dissolving feces and regurgitates from individual flies with water. Lastly, we show that MinION- and Illumina-based metabarcoding yield similar results. Overall, flies from several families (calliphorids, muscids and sarcophagids) should be used in iDNA surveys because we show that uncommon fly species carry the signal for several vertebrate species that are otherwise difficult to detect with iDNA.

[1]  Marisa C. W. Lim,et al.  Rapid in situ identification of biological specimens via DNA amplicon sequencing using miniaturized laboratory equipment , 2022, Nature Protocols.

[2]  R. Meier,et al.  Hitchhiking into the future on a fly: Toward a better understanding of phoresy and avian louse evolution (Phthiraptera) by screening bird carcasses for phoretic lice on hippoboscid flies (Diptera) , 2022, Systematic Entomology.

[3]  K. Katoh,et al.  ONTbarcoder and MinION barcodes aid biodiversity discovery and identification by everyone, for everyone , 2021, BMC biology.

[4]  S. Rossiter,et al.  Dung beetles as samplers of mammals in Malaysian Borneo—a test of high throughput metabarcoding of iDNA , 2021, PeerJ.

[5]  Jennifer M. Allen,et al.  Invertebrates for vertebrate biodiversity monitoring: Comparisons using three insect taxa as iDNA samplers , 2021, Molecular ecology resources.

[6]  C. Picard,et al.  Blow fly stable isotopes reveal larval diet: A case study in community level anthropogenic effects , 2021, PloS one.

[7]  M. Kinnison,et al.  Spatial Heterogeneity of eDNA Transport Improves Stream Assessment of Threatened Salmon Presence, Abundance, and Location , 2021, Frontiers in Ecology and Evolution.

[8]  E. Harvey,et al.  Large‐scale eDNA metabarcoding survey reveals marine biogeographic break and transitions over tropical north‐western Australia , 2021, Diversity and Distributions.

[9]  R. Meier,et al.  Mangroves are an overlooked hotspot of insect diversity despite low plant diversity , 2020, BMC Biology.

[10]  M. Oren,et al.  Identification of plastic-associated species in the Mediterranean Sea using DNA metabarcoding with Nanopore MinION , 2020, Scientific Reports.

[11]  Stefan Prost,et al.  NGSpeciesID: DNA barcode and amplicon consensus generation from long‐read sequencing data , 2020, Ecology and evolution.

[12]  F. Rasambainarivo,et al.  Next-generation technologies applied to age-old challenges in Madagascar , 2020, Conservation Genetics.

[13]  J. Rowley,et al.  Surveying frogs from the bellies of their parasites: Invertebrate-derived DNA as a novel survey method for frogs , 2020, Global Ecology and Conservation.

[14]  Zhewei Chen,et al.  A workflow for accurate metabarcoding using nanopore MinION sequencing , 2020, bioRxiv.

[15]  Zacchaeus G. Compson,et al.  DNA metabarcoding reveals metacommunity dynamics in a threatened boreal wetland wilderness , 2020, Proceedings of the National Academy of Sciences.

[16]  J. Watson,et al.  Intense human pressure is widespread across terrestrial vertebrate ranges , 2020, Global Ecology and Conservation.

[17]  Ian Holmes,et al.  Pair consensus decoding improves accuracy of neural network basecallers for nanopore sequencing , 2020, Genome Biology.

[18]  D. Paull,et al.  Camera-traps are a cost-effective method for surveying terrestrial squamates: A comparison with artificial refuges and pitfall traps , 2020, PloS one.

[19]  Rizaldi,et al.  Faecal DNA to the rescue: Shotgun sequencing of non-invasive samples reveals two subspecies of Southeast Asian primates to be Critically Endangered species , 2019, bioRxiv.

[20]  R. Meier,et al.  Rapid, large-scale species discovery in hyperdiverse taxa using 1D MinION sequencing , 2019, BMC Biology.

[21]  N. Nagarajan,et al.  Boosting natural history research via metagenomic clean-up of crowdsourced feces , 2019, PLoS biology.

[22]  R. Meier,et al.  MinION sequencing of seafood in Singapore reveals creatively labelled flatfishes, confused roe, pig DNA in squid balls, and phantom crustaceans , 2019, bioRxiv.

[23]  Kevin E. Langergraber,et al.  Fly‐derived DNA and camera traps are complementary tools for assessing mammalian biodiversity , 2019, Environmental DNA.

[24]  M. Gastauer,et al.  Vertebrate diversity revealed by metabarcoding of bulk arthropod samples from tropical forests , 2019, Environmental DNA.

[25]  L. Tedersoo,et al.  Relative Performance of MinION (Oxford Nanopore Technologies) versus Sequel (Pacific Biosciences) Third-Generation Sequencing Instruments in Identification of Agricultural and Forest Fungal Pathogens , 2019, Applied and Environmental Microbiology.

[26]  L. McRae,et al.  Below the canopy: global trends in forest vertebrate populations and their drivers , 2019, Proceedings of the Royal Society B.

[27]  Nicholas E. Manicke,et al.  Female Blow Flies As Vertebrate Resource Indicators , 2019, Scientific Reports.

[28]  Jesse F. Abrams,et al.  Shifting up a gear with iDNA : From mammal detection events to standardised surveys , 2019, Journal of Applied Ecology.

[29]  Christoph von Beeren,et al.  Species‐level predation network uncovers high prey specificity in a Neotropical army ant community , 2019, Molecular ecology.

[30]  Douglas W. Yu,et al.  An efficient and robust laboratory workflow and tetrapod database for larger scale environmental DNA studies , 2019, GigaScience.

[31]  M. Siddall,et al.  Ideating iDNA: Lessons and limitations from leeches in legacy collections , 2019, PloS one.

[32]  Ryan R. Wick,et al.  Performance of neural network basecalling tools for Oxford Nanopore sequencing , 2019, Genome Biology.

[33]  A. Kawahara,et al.  Barcoding blood meals: New vertebrate-specific primer sets for assigning taxonomic identities to host DNA from mosquito blood meals , 2018, PLoS neglected tropical diseases.

[34]  Douglas W. Yu,et al.  Debugging diversity – a pan‐continental exploration of the potential of terrestrial blood‐feeding leeches as a vertebrate monitoring tool , 2018, Molecular ecology resources.

[35]  Michael Tessler,et al.  Using terrestrial haematophagous leeches to enhance tropical biodiversity monitoring programmes in Bangladesh , 2018 .

[36]  Aaron Pomerantz,et al.  Real-time DNA barcoding in a rainforest using nanopore sequencing: opportunities for rapid biodiversity assessments and local capacity building , 2018, GigaScience.

[37]  Niranjan Nagarajan,et al.  A MinION-based pipeline for fast and cost-effective DNA barcoding , 2018, bioRxiv.

[38]  Anne-Laure Bañuls,et al.  iDNA screening: Disease vectors as vertebrate samplers , 2017, Molecular ecology.

[39]  Cesare Centomo,et al.  On site DNA barcoding by nanopore sequencing , 2017, PloS one.

[40]  Douglas W. Yu,et al.  Carrion fly-derived DNA metabarcoding is an effective tool for mammal surveys: evidence from a known tropical mammal community , 2017, bioRxiv.

[41]  N. Johnson,et al.  Molecular approaches for blood meal analysis and species identification of mosquitoes (Insecta: Diptera: Culicidae) in rural locations in southern England, United Kingdom. , 2017, Zootaxa.

[42]  V. Bennett Effects of Road Density and Pattern on the Conservation of Species and Biodiversity , 2017 .

[43]  R. Meier,et al.  Next-generation freshwater bioassessment: eDNA metabarcoding with a conserved metazoan primer reveals species-rich and reservoir-specific communities , 2016, Royal Society Open Science.

[44]  John-James Wilson,et al.  Field calibration of blowfly-derived DNA against traditional methods for assessing mammal diversity in tropical forests. , 2016, Genome.

[45]  N. Blüthgen,et al.  Specialization of oribatid mites to forest microhabitats—the enigmatic role of litter , 2016 .

[46]  Rudolf Meier,et al.  $1 DNA barcodes for reconstructing complex phenomes and finding rare species in specimen‐rich samples , 2016, Cladistics : the international journal of the Willi Hennig Society.

[47]  P. Taberlet,et al.  obitools: a unix‐inspired software package for DNA metabarcoding , 2016, Molecular ecology resources.

[48]  Douglas W. Yu,et al.  iDNA from terrestrial haematophagous leeches as a wildlife surveying and monitoring tool – prospects, pitfalls and avenues to be developed , 2015, Frontiers in Zoology.

[49]  Kong-Wah Sing,et al.  Reading Mammal Diversity from Flies: The Persistence Period of Amplifiable Mammal mtDNA in Blowfly Guts (Chrysomya megacephala) and a New DNA Mini-Barcode Target , 2015, PloS one.

[50]  A. Vogler,et al.  Comparing the effectiveness of metagenomics and metabarcoding for diet analysis of a leaf‐feeding monkey (Pygathrix nemaeus) , 2015, Molecular ecology resources.

[51]  E. Chuang,et al.  A reliable multiplex genotyping assay for HCV using a suspension bead array , 2014, Microbial biotechnology.

[52]  Brian Bushnell,et al.  BBMap: A Fast, Accurate, Splice-Aware Aligner , 2014 .

[53]  Jiajie Zhang,et al.  PEAR: a fast and accurate Illumina Paired-End reAd mergeR , 2013, Bioinform..

[54]  J. Geller,et al.  Redesign of PCR primers for mitochondrial cytochrome c oxidase subunit I for marine invertebrates and application in all‐taxa biotic surveys , 2013, Molecular ecology resources.

[55]  R. Green,et al.  Building Development and Roads: Implications for the Distribution of Stone Curlews across the Brecks , 2013, PloS one.

[56]  M. Grella,et al.  Richness and composition of Calliphoridae in an Atlantic Forest fragment: implication for the use of dipteran species as bioindicators , 2013, Biodiversity and Conservation.

[57]  M. Grella,et al.  Richness and composition of Calliphoridae in an Atlantic Forest fragment: implication for the use of dipteran species as bioindicators , 2013, Biodiversity and Conservation.

[58]  V. Ranwez,et al.  A new versatile primer set targeting a short fragment of the mitochondrial COI region for metabarcoding metazoan diversity: application for characterizing coral reef fish gut contents , 2013, Frontiers in Zoology.

[59]  B. D. Todd,et al.  Relative abundance and demographic structure of Agassiz's desert tortoise (Gopherus agassizii) along roads of varying size and traffic volume , 2013 .

[60]  Christophe Boesch,et al.  Carrion fly-derived DNA as a tool for comprehensive and cost-effective assessment of mammalian biodiversity. , 2013, Molecular ecology.

[61]  K. Katoh,et al.  MAFFT Multiple Sequence Alignment Software Version 7: Improvements in Performance and Usability , 2013, Molecular biology and evolution.

[62]  A. Chao,et al.  Coverage-based rarefaction and extrapolation: standardizing samples by completeness rather than size. , 2012, Ecology.

[63]  M. Thomas P. Gilbert,et al.  Screening mammal biodiversity using DNA from leeches , 2012, Current Biology.

[64]  T. Gregory,et al.  Identifying the last supper: utility of the DNA barcode library for bloodmeal identification in ticks , 2012, Molecular ecology resources.

[65]  H. Skovgård,et al.  Molecular identification of bloodmeals from biting midges (Diptera: Ceratopogonidae: Culicoides Latreille) in Denmark , 2011, Parasitology Research.

[66]  IR Gheorghe,et al.  Optimizing the technological and informational relationship of the health care process and of the communication between physician and patient. The impact of Preventive Medicine and social marketing applied in Health Care on youth awareness–Preliminary study , 2011, Journal of medicine and life.

[67]  D. Macdonald,et al.  The accuracy of scat identification in distribution surveys: American mink, Neovison vison, in the northern highlands of Scotland , 2010, European Journal of Wildlife Research.

[68]  Rebecca J. Foster,et al.  Differential Use of Trails by Forest Mammals and the Implications for Camera‐Trap Studies: A Case Study from Belize , 2010 .

[69]  Graham K. Taylor,et al.  The Typical Flight Performance of Blowflies: Measuring the Normal Performance Envelope of Calliphora vicina Using a Novel Corner-Cube Arena , 2009, PloS one.

[70]  Mutsuo Kobayashi,et al.  Dispersal of a blow fly, Calliphora nigribarbis, in relation to the dissemination of highly pathogenic avian influenza virus. , 2009, Japanese journal of infectious diseases.

[71]  J. Chambers,et al.  Regional ecosystem structure and function: ecological insights from remote sensing of tropical forests. , 2007, Trends in ecology & evolution.

[72]  Gaurav Vaidya,et al.  DNA barcoding and taxonomy in Diptera: a tale of high intraspecific variability and low identification success. , 2006, Systematic biology.

[73]  N. Blüthgen,et al.  Measuring specialization in species interaction networks , 2006, BMC Ecology.

[74]  D. Norris,et al.  Identification of mammalian blood meals in mosquitoes by a multiplexed polymerase chain reaction targeting cytochrome B. , 2005, The American journal of tropical medicine and hygiene.

[75]  A. H. Azahari,et al.  Determination of the flight range and dispersal of the house fly, Musca domestica (L.) using mark release recapture technique. , 2005, Tropical biomedicine.

[76]  Jerilyn A. Walker,et al.  Preparation of PCR-quality mouse genomic DNA with hot sodium hydroxide and tris (HotSHOT). , 2000, BioTechniques.

[77]  R. Wall,et al.  Estimates of population density and dispersal in the blowfly Lucilia sericata (Diptera: Calliphoridae) , 1998 .

[78]  R. Morton,et al.  Dispersal of the Old World screw‐worm fly Chrysomya bezziana , 1995, Medical and veterinary entomology.

[79]  R. Vrijenhoek,et al.  DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. , 1994, Molecular marine biology and biotechnology.

[80]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[81]  R. Meier,et al.  REPRODUCTION AND INFANT PELAGE COLOURATION OF THE BANDED LEAF MONKEY (MAMMALIA: PRIMATES: CERCOPITHECIDAE) IN SINGAPORE , 2010 .

[82]  T. Nakashizuka,et al.  A PRELIMINARY STUDY OF TWO SYMPATRIC MAXOMYS RATS IN SARAWAK, MALAYSIA: SPACING PATTERNS AND POPULATION DYNAMICS , 2007 .

[83]  J. Flowerdew,et al.  Live trapping to monitor small mammals in Britain , 2004 .

[84]  Didier Raoult,et al.  Molecular identification by , 2000 .

[85]  P. G. Taylor Reproducibility of ancient DNA sequences from extinct Pleistocene fauna. , 1996, Molecular biology and evolution.

[86]  L. Braack,et al.  Dispersal, density and habitat preference of the blow-flies Chrysomyia albiceps (Wd.) and Chrysomyia marginalis (Wd.) (Diptera: Calliphoridae). , 1986, The Onderstepoort journal of veterinary research.

[87]  K. Norris The Bionomics of Blow Flies , 1965 .

[88]  M. D. Murray,et al.  Notes on the screw-worm fly, Chrysotnya bezziana (Díptera: Calliphoridae), as a pest of cattle in New Guinea. , 1964 .

[89]  G. A. Mcintyre,et al.  An Account of Experiments undertaken to determine the natural Population Density of the Sheep Blowfly, Lucilia cuprina Wied. , 1946 .