Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

The first true millipede—1306 legs long


The name “millipede” translates to a thousand feet (from mille “thousand” and pes “foot”). However, no millipede has ever been described with more than 750 legs. We discovered a new record-setting species of millipede with 1,306 legs, Eumillipes persephone, from Western Australia. This diminutive animal (0.95 mm wide, 95.7 mm long) has 330 segments, a cone-shaped head with enormous antennae, and a beak for feeding. A distant relative of the previous record holder, Illacme plenipes from California, it belongs to a different order, the Polyzoniida. Discovered 60 m below ground in a drill hole created for mineral exploration, E. persephone possesses troglomorphic features; it lacks eyes and pigmentation, and it has a greatly elongated body—features that stand in stark contrast to its closest surface-dwelling relatives in Australia and all other members of its order. Using phylogenomics, we found that super-elongation (> 180 segments) evolved repeatedly in the millipede class Diplopoda. The striking morphological similarity between E. persephone and I. plenipes is a result of convergent evolution, probably for locomotion in similar soil habitats. Discovered in the resource-rich Goldfields-Esperance region and threatened by encroaching surface mining, documentation of this species and conservation of its habitat are of critical importance.


Among the earliest animals to breathe atmospheric oxygen1 and with some extinct species that grew to two meters in length2, millipedes have lived on this planet for more than 400 million years. Important as decomposers in terrestrial ecosystems3, primary knowledge of millipede diversity lags tremendously behind other animal groups. With fossil taxa dated to the Cretaceous4,5, the millipede order Polyzoniida includes ca. 70 species with a distribution on all continents except Antarctica. Some of its members exhibit parental care of eggs6, others ooze chemical defenses containing alkaloids7 that are sequestered by poison frogs8,9, and some species roll into a ball for protection10. Hatchlings emerge from the egg with four pairs of legs, and continuously add segments during development for an indeterminate period of time, even after adulthood11. Polyzoniidans have never before been observed in deep soil habitats, and most occur in surficial microhabitats of decaying wood and other detritus. Previously known Australian polyzoniidans have at most 400 legs, eyes with 1–3 ommatidia, most with at least some dark pigmentation, a flat wide body (relative to others in the order), and occurrence in epigean microhabitats12. However, distantly related millipedes, such as Illacme species and other members of the family Siphonorhinidae (order Siphonophorida), have been recorded from as deep as 11.5 m below the soil surface13,14. These species possess a suite of adaptations, such as a thin elongated body with up to 750 legs, no eyes, massive antennae, and lack of pigmentation. No siphonorhinid species have been recorded from Australia, and the geographically closest siphonorhinids occur in Madagascar and Indonesia13,14.

Here we report the discovery of E. persephone, the first super-elongated millipede known from Australia, and the new world record holder of the animal with greatest number of legs. It belongs to the family Siphonotidae (order Polyzoniida), yet appears similar to super-elongated millipedes in the order Siphonophorida. Eumillipes persephone lives deep underground, and it was only discovered by surveying geological drill holes originally created for mineral exploration that provided access to a cryptic and previously unexplored underground habitat.


In August 2020, in the Goldfields region of Western Australia, we discovered a pale, thread-like millipede with 1,306 legs at a depth of 60 m in a drill hole created for mineral exploration (Fig. 1). In total, 56 4–81 m deep 150 mm-diameter drill holes located at a site 100 km WSW of Norseman, Western Australia (within the Great Western Woodlands) were sampled for millipedes and other subterranean fauna, according to techniques described in ref.16. These geological drill holes provided a portal to access an interstitial habitat composed of banded iron formations and mafic volcanic rocks, which are known to harbor troglophilic fauna16,17. Eight individuals of the new species were collected from troglofauna traps at depths between 15–60 m from three drill holes (450 m apart), including five individuals from a trap set at a depth of 60 m. Two juveniles were collected in April 2020 and another one in January 2021, always from troglofauna traps, attesting to the species’ true deep subterranean life.

Figure 1
figure 1

The leggiest animal on the planet, Eumillipes persephone, from Australia. (A) female with 330 segments and 1,306 legs (paratype specimen, T147124). (B) ventral view of legs (male holotype, T147101). (C) dorsal view of head and ventral view of gonopods (male holotype, T147101). Scale bars, 0.5 mm.

The specimens superficially appeared to be members of the Siphonorhinidae, due to phenotypic similarity to Illacme plenipes Cook & Loomis, 1928. We used scanning electron microscopy and genome sequencing to conclude that the remarkable anatomical similarity between E. persephone and I. plenipes is a result of convergent evolution of super-elongation (> 180 segments), which we here reveal that has originated at least twice in the millipede class Diplopoda (Fig. 2). Eumillipes persephone appears unlike any other species in the order Polyzoniida. Its highly elongated and narrowed body, lack of eyes, massive antennae, shortened legs, and lack of pigmentation comprise a suite of characters consistent with a fossorial bauplan that has repeatedly evolved in the Diplopoda18,19.

Figure 2
figure 2

Phylogenomic estimation of the evolutionary history of colobognath millipedes. Super-elongation (> 180 segments) is well known from the order Siphonophorida, including Illacme plenipes with 192 segments and 750 legs, but it has independently evolved in the Australian order Polyzoniida with Eumillipes persephone bearing up to 1,306 legs and 330 segments. This feature (dark branches) has evolved between two and four times in diplopods based on a character state reconstruction using parsimony. Maximum likelihood phylogeny of 312 orthologous sequences with Polydesmida, Stemmiulida, Chordeumatida, Spirostreptida, and Sphaerotheriida as outgroup taxa. Julida, Spirobolida, and other diplopod orders omitted from the analysis. Support values on nodes are bootstrap supports. Numbers in parentheses after species names are the maximum segment count for the taxon. Species with super-elongation present denoted in bold. Millipede silhouettes sized relative to one other. Diagram created with Adobe Illustrator 2021 (

Taxonomy section

Class Diplopoda de Blainville in Gervais, 1844

Subterclass Colobognatha Brandt, 1834

Order Polyzoniida Cook, 1895

Family Siphonotidae Cook, 1895

Tribe Rhinotini Hoffman, 1977

Eumillipes, Marek new genus

Type species

Eumillipes persephone Marek, new species.

Generic placement and diagnosis

The genus Eumillipes is placed in the order Polyzoniida, family Siphonotidae, tribe Rhinotini based on the following characters10,20; whether the character is diagnostic for the order (O), family (F), or tribe (T) is denoted in parentheses. Head capsule small, conical, elongated into a sharp snout (O) (Fig. 1C, Supplementary Fig. S1A–C). Prozonites and metazonites of trunk rings the same width (O) (Supplementary Fig. S2A); prozonites not narrow as in the Siphonophorida. Rings smooth (Supplementary Fig. S2B), covered with neither cuticular ornaments nor long setae as in the Siphonophorida. Vertex of head with two macrosetae (O) (Supplementary Fig. S1C). Antennae thick with equally sized antennomeres (O) (Fig. 1C, Supplementary Fig. S3A); antennae not strongly elbowed between antennomeres 3, 4 as in the Siphonorhinidae (Siphonophorida). Gnathochilarium reduced to three sclerites: mentum; left, right stipes (O). Ozopores located far in from lateral edges of tergites; placed two-thirds the distance from midline laterally to tergal margins (F) (Supplementary Fig. S2D). Vasa deferentia open through small conical lobes (penes) on the posterior surfaces of the second leg coxae (F). Telson a complete ring around the anal valves (F) (Supplementary Fig. S2D). Tarsal claw with long sigmoid-shaped accessory claw at its base that exceeds the claw in length (F) (Supplementary Fig. S1D). The genus differs from other siphonotid genera by the following characters. Anterior gonopods (i.e., 9th leg pair) strongly modified with podomeres 3–4 fused, not leg-like as in Siphonotini genera (T) (Fig. 1C, Supplementary figs. S4, S5A). Apex of anterior gonopods distinctly bifurcated into two processes (Fig. 1C, Supplementary figs. S4, S5A), not a single process as in the genera Rhinotus Cook, 1896 and Siphonoconus Attems, 1930.

Eumillipes persephone Marek, new species


Adults of Eumillipes persephone can be differentiated from other polyzoniidan genera and species (and commonly encountered millipedes co-occurring with E. persephone in Western Australia) based on the combination of the following characters. Body extremely long and thread-like (width: ♂ 0.92 mm; ♀ 0.95 mm; length: ♂ 54.7 mm; ♀ 95.7 mm). Exoskeleton uniformly pale, cream-colored (Fig. 1A, Supplementary figs. S6–S8)—with neither dark pigmentation nor longitudinal, nor transverse stripes as in surface-dwelling species (Supplementary Fig. S9). Adult millipedes with an exceptional number of rings and legs: ♀ up to 330 rings and 1,306 legs, and ♂ up to 208 rings and 818 legs (Supplementary tab. S1). Head cone-shaped and eyeless (Fig. 1C, Supplementary Fig. S1A–C)—lacking eyes as are present in surface-dwelling species. Ninth and 10th leg pairs modified into gonopods (Fig. 1C, Supplementary figs. S4, S5). Anterior gonopods (9th leg pair) highly modified, not leg like, and distinctly bifurcated into two processes (Fig. 1C, Supplementary figs. S4, S5A). Medial process of the anterior gonopods saddle-shaped—not pointed and recurved as in Siphonotus flavomarginatus Attems, 191121. Lateral process sheath-like and cupping the medial process. Posterior gonopods (10th leg pair) stylet-like, and in repose threaded through the bifurcated anterior gonopods (Fig. 1C, Supplementary figs. S4, S5B). Sterna of gonopods with four long, slender, curved setae apically studded with spinules (Supplementary figs. S4B, S5A).

Material examined

Male holotype (WAM T147101), two female and one male paratypes (WAM T147100, T147124, T146684), and two juveniles (WAM T147122, T147123) from Western Australia, ca. 100 km WSW of Norseman, 32° 32′ 05.9" S, 120° 47′ 42.74" E, 27 May–4 August 2020, collected by A.J. Mittra and L.P. Masarei (Western Australian Museum).


Males have fewer segments and legs; specimen T147101 has 198 segments and 778 legs (Supplementary Fig. S7), and T147100 has 208 segments and 818 legs (Supplementary Fig. S8). Female specimen T147124 possesses 330 segments and 1,306 legs (Fig. 1A, Supplementary Fig. S6), and T146684 has 253 segments and 998 legs.


The genus is named because it is the first true millipede with more than 1000 legs. The name Eumillipes is a combination of the Greek eu-, meaning ‘true’; Latin mille, ‘thousand’; and Latin pes, ‘foot’. It is to be treated as a noun. The species epithet is derived from the Greek mythological goddess of the underworld, Persephone, who was originally from the surface but was taken to the underworld by Hades.


From studies by Manton22 and video footage of siphonorhinid millipedes, the locomotive biomechanics of super-elongated millipedes has only been studied rudimentarily. Navigating by its enlarged antennae (Fig. 1C, Supplementary Fig. S3A, B) equipped with up to five sensillum types15, the millipede’s elongated trunk with telescopic segments facilitates burrowing in a three-dimensional soil matrix. Its antennae wave independently to locate an opening; once a suitable gap is identified, the millipede enters and walks through. The flexible segments are compressible to squeeze through narrow fissures. The continuous metachronal gait and musculoskeletal action of the segments, which are composed of concentric tubular rings that slide within one another, provide continuous pushing force; in combination with the legs, longitudinal (Supplementary Fig. S10C) and oblique muscles pull the rings together and provide forward locomotion22. This way of burrowing resembles that used by geophilomorph centipedes (another group of greatly elongated myriapods that includes the leggiest centipede, Gonibregmatus plurimipes Chamberlin, 1920 from Fiji with 191 rings and 382 legs) and earthworms. In contrast with millipedes with incompressible rings such as “bulldozer” ecomorphs that walk in a single plane propelled by the additive force of their legs22, colobognath millipedes are able to wind their way through a three-dimensional matrix and can simultaneously walk in up to eight different planes. This telescoping locomotion, by sliding trunk segments (Supplementary Fig. S2A) coupled with the thrust of the legs, propels the animal through a varied and unpredictable underground microhabitat22, and the increase in leg number likely contributes more pushing power to force through small crevices and openings. Super-elongation in the Diplopoda has repeatedly evolved in taxa that live in these microhabitats, such as in Siphonorhinidae (I. plenipes with 192 segments and Nematozonium filum Verhoeff, 1939 with 182 segments), Siphonophoridae (Siphonophora millepeda Loomis, 1934 and Siphonacme lyttoni Cook & Loomis, 1928 each with 190 segments), and E. persephone. Each additional ring provides extra locomotory thrust23, and E. persephone’s up to 330 rings may be specially adapted to locomotion in its comparatively deep soil microhabitat at 60 m—five-fold greater than the maximum depth of Illacme species. Trunk super-elongation may also serve to lengthen the digestive canal to increase the absorptive surface area and assimilation efficiency in a resource-limited subterranean habitat, as may be the case for I. plenipes, which additionally has an even longer corkscrew-shaped gut than the trunk itself15. The diet of E. persephone is unknown, but may be similar to other primarily fungivorous colobognath millipedes, such as the platydesmidan Brachycybe lecontii Wood, 1864 that feeds on up to 176 different genera of fungi24.

Current alpha-level knowledge of Australian Siphonotidae is fragmentary. Although an unpublished dissertation from 1994 documented eight genera and 42 species of the family25, taxonomy of the group remains antiquated with two genera and five species currently listed from the continent described about a century ago21,25,26. Although the phenotypic divergence of E. persephone from surface-dwelling family relatives appears to be associated with adaptations to life underground, extraordinary similarity of its gonopods (species-diagnostic features in diplopods) with Siphonotus flavomarginatus from Torbay, Western Australia, indicates a genus-level affiliation. Close similarity of gonopod anatomy with extremely divergent somatic features suggests rapid evolution of troglomorphic traits.

Invertebrates that live below the Earth’s surface comprise a cryptic and diverse fauna. Although they are challenging to observe and document, notable recent discoveries include beetles and millipedes in Brazilian iron ore caves27,28, snake millipedes of mesovoid shallow substratum of Spain29, and spiders from caves of the Edwards Plateau of Texas30. These habitats are repositories of incredibly rich, but obscure biodiversity. These underground habitats, and their inhabitants, are critically understudied, despite their ecological importance in filtration of groundwater and screening of environmental toxins. The subterranean conditions of Western Australia may consistently be at a much lower temperature and higher humidity and house an evolutionarily closely related mesic-adapted troglofauna. Despite surface temperatures in excess of 46 °C and less than 300 mm/year of precipitation31, the groundwater in the sites where E. persephone was collected never exceeded 22 °C. Surface climatic conditions fluctuated considerably across hundreds of millennia, but underground conditions probably remained comparatively stable. Troglophilic species often represent ancient vestiges of formerly widespread lineages that now persist in subterranean refugia32. Although the date of the split between the clade containing E. persephone and the one containing Siphonotus flavomarginatus is uncertain, divergence may be linked to aridification of the continent between 15–1.75 Ma. The so-called “climatic relict” theory has been useful to explain other such close relationships between troglophilic and epigean taxa, such as springtails, isopods, schizomids, pseudoscorpions, and ground beetles in Western Australia17,33. This theory suggests that cool-adapted epigean ancestors were gradually driven underground where conditions remained favorable, whilst the surface dried and became uninhabitable; following aridification, epigean lineages underwent extinction thereby fostering allopatric speciation33. A similar theory has been invoked for faunal radiations in caves, where analogous extreme adaptive shifts also occur accompanied by morphological change: eyelessness, elaboration of mechanical sensation, lack of pigmentation, and leg elongation. Elongated limbs in troglobionts have been hypothesized to have originated for more efficiently traversing expansive cavernous space for scarce food and mates34. In the case of E. persephone, and its micro-cavernous habitat, the remarkable number of legs may be associated with a comparable search for limited resources in its “micro-cave”-like interstitial habitat. Short legs are likely advantageous in the small cavities of such a habitat, and perhaps compensated for by an increase in their number, which would maintain pushing power.

Located in the Yilgarn Craton, the Eastern Goldfields Province of Western Australia composes a surficial habitat of shrublands (Supplementary Fig. S11) overlaying an ancient terrane that is among the oldest emergent land masses (2.6–4.4 billion years, ref.35). A large quantity of Australia’s gold, nickel, and other minerals are extracted from the Goldfields, and intensive surface mining has occurred in the area for more than a century. Mineral exploration includes surveying underground via millions of drill holes that produced cores for elemental analysis in the region. These holes, which are later rehabilitated, provide fleeting access to sample an expansive vadose zone which houses a subterranean biodiversity hotspot17,36.

Whether troglomorphic species of Eumillipes exist in other parts of Western Australia is an uncertain, but potentially rich avenue of discovery. The unexpected discovery of E. persephone and other troglomorphic animals from the Great Western Woodlands37,38, within the Eastern Goldfields Province of Western Australia, highlights the region as an exceptional repository of biodiversity.



Millipedes were collected from drill holes according to ref.16. Drill holes were preexisting and bored by mining companies for mineral exploration. 56 4–81 m deep 150 mm diameter wide drill holes were sampled with specifically designed traps (trogtraps) that are lowered into holes to sample subterranean invertebrates. Trogtraps consist of cylindrical PVC traps with numerous apertures, which are baited with moist leaf litter and lowered on nylon cord to varying depths. The leaf litter bait is wetted, allowed to decompose over weeks or months and sterilized via microwaving. Holes in the trogtraps are capped at the surface while traps are set to minimize the collection of surface invertebrates. Trogtraps were left in the field for approximately two (but up to five) months for troglofauna to be attracted to the aroma of decaying vegetation. At the end of the sampling period, traps were carefully pulled out of each hole and the contents placed in zip lock bags, allowing enough oxygen for transit back to the laboratory. In the laboratory, troglofauna were extracted from the leaf litter in traps using Tullgren funnels under incandescent lamps: light and heat from the lamps drives the animals out of the litter towards the base of the funnel and into a collection vial containing 100% ethanol. Samples were obtained under the auspices of scientific research permit number BA27000150 from the Department of Biodiversity, Conservation and Attractions of Western Australia. Millipede specimens were fixed and preserved in ethanol and deposited in the Western Australian Museum, Perth, Australia with the following catalog numbers T147100, T147101, T147122–T147124, and T146684.

DNA extraction and sequencing

Tissues were dissected from ethanol preserved specimens and DNA extracted from them according to ref.39. 6–10 rings were removed and pulverized with a micro-pestle in 200 uL lysis buffer containing proteinase K using a Qiagen DNeasy kit. Purified genomic DNA was quantified and quality assessed using a Nanodrop spectrophotometer and Agilent 5400 fragment analyzer. Genomic DNA was randomly fragmented by sonication, Illumina adapters ligated, amplified by PCR, and libraries constructed followed by quantification and a quality-control step. The libraries for each sample were pooled to 1–3 sequencing lanes to obtain a targeted 9 GB of data using an Illumina Novaseq 6000 two channel platform with paired-end 150 bp reads. Standard DNA cytochrome oxidase I gene (COI) barcodes for the holotype specimen, and two juveniles were sequenced with the primer pair LCO1490 and HCO2198 according to methods in ref.39 (NCBI accession #: OK602741).


Raw reads of genomes were data filtered to remove adapter sequences, reads containing > 10% N, and low-quality reads with > 50% of the read with phred ≤ 5. FastQC Version 0.11.940 was used to evaluate quality scores, GC content, sequence length distribution, and duplicated and overrepresented sequences. Reads were deposited in the National Center for Biotechnology Information SRA with the BioProject accession number, PRJNA769673, and the following catalog numbers: Sphaeropoeus Brandt, 1833 (MPE02963), Choctella cumminsi Chamberlin, 1918 (MPE01425), Pseudotremia salisae Lewis, 2000 (MPE04962), Stemmiulus Gervais, 1844 (MPE04756), Apheloria whiteheadi (Shelley, 1986) (MPE05046), Siphonophora Brandt, 1837 (MPE04720), Siphonorhinus robustus (Attems, 1938) (MPE05063), Nematozonium filum Verhoeff, 1939 (T129482), Illacme “Santa Ana” (MPE04624), Illacme plenipes Cook & Loomis, 1928 (SPC001187), Brachycybe lecontii Wood, 1864 (MPE03842), Gosodesmus claremontus Chamberlin, 1922 (SPC00941), Petaserpes Cope, 1870 (MPE00887), Octoglena gracilipes (Loomis, 1971) (Sass.A.230), Eumillipes persephone (T147101), Rhinotus purpureus (Pocock, 1894) (MPE05072). Trimmomatic Version 0.3941 was used to trim low quality bases from the end of the reads using ‘trailing 28’, and omit short reads using ‘minlength 75’. aTRAM version 2.042 was used to assemble sequencing reads using the python script ‘’ onto a set of 312 orthologous genes (matrix 4 from ref.4). A set of BLAST libraries containing sequence shards were assembled with ‘’ implementing the assembler Velvet Version 1.2.1043. Assembled genes were translated and placed in individual matrices with exonerate Version 2.2.044 in the aTRAM module stitcher, ‘’. Amino acids were independently aligned with Mafft V7.40745, allowing for automatic selection of appropriate strategy based on data size, using the Smith-Waterman algorithm for alignment and performing 1000 cycles of iterative refinement. Alignments were then visually inspected, manually refined and concatenated using Geneious Prime 2020.2. A Maximum Likelihood approach was undertaken for phylogenetic reconstruction using IQ-TREE V1.7.0b746 with a partitioned scheme, testing the model of molecular evolution for each partition and an ultrafast bootstrap analysis of 1,000 replicates47.


The holotype male (T147101) and paratype female (T146684) specimens were prepared for scanning electron microscopy (SEM) by removing the anterior, middle, and posterior 10 rings, and air drying them at room temperature until the ethanol preservative evaporated. Dissected structures were then placed on double-sided carbon tape on a 12.7 mm aluminum SEM stub, and sputter coated with a 40-nm layer of palladium and platinum in a Leica EM ACE600 plasma sputter coater. Micrographs were taken with a FEI Quanta scanning electron microscope at the Nanoscale Characterization and Fabrication Laboratory in the Institute for Critical Technology and Applied Science at Virginia Tech. Examination of general morphology for descriptive taxonomy was carried out on a Leica M125 stereomicroscope (10–125X) and a Leica DM500 brightfield microscope (50–400X).

Data availability

The datasets analyzed in the current study are available from Virginia Tech's Digital Repository ( and the National Center for Biotechnology Information ( This publication and its nomenclatural acts have been registered in Zoobank (, the official registry of the International Commission on Zoological Nomenclature. The LSID (Life Science Identifier) of the article is


  1. 1.

    Wilson, H. M. & Anderson, L. I. Morphology and taxonomy of paleozoic millipedes (Diplopoda: Chilognatha: Archipolypoda) from Scotland. J. Paleontol. 78, 169–184.;2 (2004).

    Article  Google Scholar 

  2. 2.

    Lucas, S. G., Lerner, A. J., Hannibal, J. T., Hunt, A. P. & Schneider, J. W. Trackway of a giant Arthropleura from the Upper Pennsylvanian of El Cobre Canyon, New Mexico. Geology of the Chana Basin. New Mexico Geological Society, 56th Field Conference Guidebook. 279–282 (2005).

  3. 3.

    Joly, F. X. et al. Detritivore conversion of litter into faeces accelerates organic matter turnover. Commun. Biol. 3, 1–9. (2020).

    CAS  Article  Google Scholar 

  4. 4.

    Rodriguez, J. et al. Step-wise evolution of complex chemical defenses in millipedes: A phylogenomic approach. Sci. Rep. 8, 1–10. (2018).

    ADS  CAS  Article  Google Scholar 

  5. 5.

    Wesener, T. & Moritz, L. Checklist of the Myriapoda in Cretaceous Burmese amber and a correction of the Myriapoda identified by Zhang (2017). Check List. 14, 1131. (2018).

    Article  Google Scholar 

  6. 6.

    Enghoff, H. Phylogeny of millipedes—a cladistic analysis. J. Zool. Syst. Evol. Res. 22, 8–26. (1984).

    Article  Google Scholar 

  7. 7.

    Wood, W. F., Hanke, F. J., Kubo, I., Carroll, J. A. & Crews, P. Buzonamine, a new alkaloid from the defensive secretion of the millipede, Buzonium crassipes. Biochem. Syst. Ecol. 28, 305–312. (2000).

    CAS  Article  PubMed  Google Scholar 

  8. 8.

    Saporito, R. A., Donnelly, M. A., Hoffman, R. L., Garraffo, H. M. & Daly, J. W. A siphonotid millipede (Rhinotus) as the source of spiropyrrolizidine oximes of dendrobatid frogs. J. Chem. Ecol. 29, 2781–2786. (2003).

    CAS  Article  PubMed  Google Scholar 

  9. 9.

    Shear, W. A. The chemical defenses of millipedes (Diplopoda): biochemistry, physiology and ecology. Biochem. Syst. Ecol. 61, 78–117. (2015).

    CAS  Article  Google Scholar 

  10. 10.

    Shear, W. A. Redescription of the South African millipede Cylichnogaster lawrencei Verhoeff, 1937 and notes on the family Siphonotidae (Diplopoda, Polyzoniida). Zootaxa 4079, 119–128. (2016).

    Article  PubMed  Google Scholar 

  11. 11.

    Enghoff, H., Dohle, W. & Blower, J. G. Anamorphosis in millipedes (Diplopoda)—the present state of knowledge with some developmental and phylogenetic considerations. Zool. J. Linn. Soc-Lond. 109, 103–234. (1993).

    Article  Google Scholar 

  12. 12.

    Black, D. G. Diversity and biogeography of Australian millipedes (Diplopoda). Mem. Mus. Vic. 56, 557–561 (1997).

    Article  Google Scholar 

  13. 13.

    Marek, P. E. & Bond, J. E. Rediscovery of the world’s leggiest animal. Nature 441, 707. (2006).

    ADS  CAS  Article  PubMed  Google Scholar 

  14. 14.

    Marek, P. E., Krejca, J. K. & Shear, W. A. A new species of Illacme Cook & Loomis, 1928 from Sequoia National Park, California, with a world catalog of the Siphonorhinidae (Diplopoda, Siphonophorida). ZooKeys 626, 1–43. (2016).

    Article  Google Scholar 

  15. 15.

    Marek, P. E., Shear, W. A. & Bond, J. E. A redescription of the leggiest animal, the millipede Illacme plenipes, with notes on its natural history and biogeography (Diplopoda, Siphonophorida, Siphonorhinidae). ZooKeys 241, 77–112. (2012).

    Article  Google Scholar 

  16. 16.

    Halse, S. & Pearson, G. B. Troglofauna in the vadose zone: comparison of scraping and trapping results and sampling adequacy. Subterr. Biol. 13, 17–34. (2014).

  17. 17.

    Guzik, M. T. et al. Is the Australian subterranean fauna uniquely diverse?. Invertebr. Syst. 24, 407–418. (2011).

    Article  Google Scholar 

  18. 18.

    Enghoff, H. The millipede genus Cylindroiulus on Madeira—an insular species swarm (Diplopoda, Julida: Julidae). Entomol. Scand. 18, 1–142 (1982).

    Google Scholar 

  19. 19.

    Liu, W., Golovatch, S. I., Wesener, T. & Tian, M. Convergent evolution of unique morphological adaptations to a subterranean environment in cave millipedes (Diplopoda). PLoS ONE 12, e0170717. (2017).

    CAS  Article  PubMed  PubMed Central  Google Scholar 

  20. 20.

    Hoffman, R. L. On the status of Siphonotus brasiliensis Brandt, and of the diplopod family Siphonotidae (Polyzoniida). Dtsch. entomol. Z. 4, 425–431. (1977).

    Article  Google Scholar 

  21. 21.

    Michaelsen, W. & Hartmeyer, R. Attems, C. M. T. Graf Von. Myriopoda excl. Scolopendridae. Gustav Fischer, Jena. In. Die Fauna Südwest-Australiens. 3, 145–204 (1911).

    Google Scholar 

  22. 22.

    Manton, S. M. The evolution of arthropodan locomotory mechanisms—Part 4 The structure, habits and evolution of the Diplopoda. Zool. J. Linn. Soc-Lond. 42, 299–368. (1954).

    Article  Google Scholar 

  23. 23.

    Garcia, A., Priya, S. & Marek, P. Understanding the locomotion and dynamic controls for millipedes: part 1—kinematic analysis of millipede movements. ASME Smart Mater. Adapt. Struct. Intell. Syst. (2015).

    Article  Google Scholar 

  24. 24.

    Macias, A. M. et al. Diversity and function of fungi associated with the fungivorous millipede Brachycybe lecontii. Fungal Ecol. 41, 187–197. (2019).

    Article  PubMed  PubMed Central  Google Scholar 

  25. 25.

    Black, D. G. A taxonomic revision of the Australian Siphonotidae (Diplopoda: Polyzoniida). Dissertation, University of California, Davis. (1994).

  26. 26.

    Verhoeff, K. W. Results of Dr. E. Mjöberg’s Swedish Scientific Expeditions to Australia 1910–1913 34 Myriapoda: Diplopoda. Ark. zool. 16, 1–142 (1924).

    Google Scholar 

  27. 27.

    Shear, W. A., Ferreira, R. L., Iniesta, L. F. M. & Marek, P. A millipede missing link: Dobrodesmidae, a remarkable new polydesmidan millipede family from Brazil with supernumerary rings (Diplopoda, Polydesmida), and the establishment of a new suborder Dobrodesmidea. Zootaxa 4178, 371–390. (2016).

    Article  PubMed  Google Scholar 

  28. 28.

    Asenjo, A., Pietrobon, T. & Ferreira, R. L. A new troglobitic species of Metopioxys (Staphylinidae: Pselaphinae) from Brazilian iron ore caves. Zootaxa 4576, 195–200. (2019).

    Article  Google Scholar 

  29. 29.

    Akkari, N., Gilgado, J. D., Ortuno, V. M. & Enghoff, H. Out of the dark void: Ommatoiulus longicornis n. sp., a new julid from Spain (Diplopoda, Julida) with notes on some troglobiomorphic traits in millipedes. Zootaxa 4420, 415–429. (2018).

    Article  PubMed  Google Scholar 

  30. 30.

    Hedin, M., Derkarabetian, S., Blair, J. & Paquin, P. Sequence capture phylogenomics of eyeless Cicurina spiders from Texas caves, with emphasis on US federally-endangered species from Bexar County (Araneae, Hahniidae). ZooKeys. 769, 49–76. (2018).

    Article  Google Scholar 

  31. 31.

    Australian Government, Bureau of Meteorology, Kalgoorlie-Boulder Airport Climate Statistics. Retrieved 7 July 2021.

  32. 32.

    Shear, W. A. & Shelley, R. M. Solved after 140 years: the identity of the millipede Polydesmus cavicola Packard, 1877, and proposal of Packardesmus n gen (Diplopoda: Polydesmida: Macrosternodesmidae). Zootaxa 4559, 384–390. (2019).

    Article  PubMed  Google Scholar 

  33. 33.

    Giachino, P. M., Eberhard, S. & Perina, G. A rich fauna of subterranean short-range endemic Anillini (Coleoptera, Carabidae, Trechinae) from semi-arid regions of Western Australia. ZooKeys. 1044, 269–337. (2021).

    Article  PubMed  PubMed Central  Google Scholar 

  34. 34.

    Christiansen, K. Morphological adaptations. In Encyclopedia of Caves (eds White, W. B. & Culver, D. C.) 517–528 (Elsevier, Amsterdam, 2012).

    Chapter  Google Scholar 

  35. 35.

    Williams, I. R. Yilgarn Block. Geological Survey of Western Australia, The Geology of Western Australia, Western Australia Geological Survey, ISBN 978–0–7244–6084–7, 33–81 (1975).

  36. 36.

    Hyde, J., Cooper, S. J. B., Humphreys, W. F., Austin, A. D. & Munguia, P. Diversity patterns of subterranean invertebrate fauna in calcretes of the Yilgarn Region, Western Australia. Mar. Freshwater Res. 69, 114–121. (2018).

    Article  Google Scholar 

  37. 37.

    Watson, A., Judd, S. & Watson, J. Flowering plant and vertebrate diversity of the Great Western Woodlands in the Southern Goldfields. In: Proceedings of the Goldfield Environmental Management Workshop (editors: A.B. Fourie, M. Tibbett), Australian Centre for Geomechanics, The University of Western Australia. 116–124 (2008).

  38. 38.

    Car, C. A. & Harvey, M. S. The millipede genus Antichiropus (Diplopoda: Polydesmida: Paradoxosomatidae), part 2: Species of the Great Western Woodlands region of Western Australia. Rec. West. Aust. Mus. 29, 20–77. (2014).

    Article  Google Scholar 

  39. 39.

    Shorter, P. L., Hennen, D. A. & Marek, P. E. Cryptic diversity in Andrognathus corticarius Cope, 1869 and description of a new Andrognathus species from New Mexico (Diplopoda, Platydesmida, Andrognathidae). ZooKeys 786, 19–41. (2018).

    Article  Google Scholar 

  40. 40.

    Andrews, S. FastQC: a quality control tool for high throughput sequence data. (2010).

  41. 41.

    Bolger, A. M., Lohse, M. & Usadel, B. Trimmomatic: A flexible trimmer for Illumina Sequence Data. Bioinformatics, btu170. (2014).

  42. 42.

    Allen, J. M., Lafrance, R., Folk, R. A., Johnson, K. P. & Guralnick, R. P. ATRAM 2.0: An improved, flexible locus assembler for NGS data. Evol. Bioinform. (2018).

    Article  Google Scholar 

  43. 43.

    Zerbino, D. R. & Birney, E. Velvet: Algorithms for de novo short read assembly using de Bruijn graphs. Genome Res. 18, 821–829. (2008).

    CAS  Article  PubMed  PubMed Central  Google Scholar 

  44. 44.

    Slater, G. S. C. & Birney, E. Automated generation of heuristics for biological sequence comparison. BMC Bioinform. 6, 1–11. (2005).

    CAS  Article  Google Scholar 

  45. 45.

    Katoh, K. & Standley, D. M. MAFFT multiple sequence alignment software version 7: Improvements in performance and usability. Mol. Biol. Evol. 30, 772–780. (2013).

    CAS  Article  PubMed  PubMed Central  Google Scholar 

  46. 46.

    Minh, B. Q. et al. IQ-TREE 2: New models and efficient methods for phylogenetic inference in the genomic era. Mol. Biol. Evol. 37, 1530–1534. (2020).

    CAS  Article  PubMed  PubMed Central  Google Scholar 

  47. 47.

    Hoang, D. T., Chernomor, O., von Haeseler, A., Minh, B. Q. & Vinh, L. S. UFBoot2: Improving the ultrafast bootstrap approximation. Mol. Biol. Evol. 35, 518–522. (2018).

    CAS  Article  PubMed  Google Scholar 

Download references


This research was supported by a National Science Foundation grant to PEM (Division of Environmental Biology, Systematics and Biodiversity Sciences, #1916368). Thanks to Charity Hall, Howard Dunleavy, and Bailey Connors for assisting with editing, figure illustration, and specimen measurement. Sergei Golovatch and Henrik Enghoff provided comments on previous versions of the manuscript.

Author information




Conceptualization: P.E.M., B.A.B., W.A.S., M.S.H.; Methodology: P.E.M., B.A.B., W.A.S., M.S.H., J.R.; Analysis: P.E.M., B.A.B., J.C.M., J.R.; Visualization: P.E.M., B.A.B., J.R.; Data curation: P.E.M., B.A.B., M.S.H., J.R.: Writing—original draft: P.E.M.: Writing—review & editing: P.E.M., B.A.B., W.A.S., J.C.M., D.G.B., M.S.H., J.R.

Corresponding author

Correspondence to Paul E. Marek.

Ethics declarations

Competing interests

The authors declare no competing interests.

Additional information

Publisher's note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Supplementary Information

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Marek, P.E., Buzatto, B.A., Shear, W.A. et al. The first true millipede—1306 legs long. Sci Rep 11, 23126 (2021).

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI:


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.


Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing