Aquatic larval of the genus <i>Arrenurus</i> (Trombidiformes: Parasitengonina: Arrenuridae) associated with Odonata species from Pampa Biome, Brazil

Bizarro, Gabriel Lima; Périco, Eduardo; Dalzochio, Marina; Silva, Guilherme Liberato da; Ferla, Noeli Juarez; Johann, Liana

doi:10.1590/1676-0611-BN-2020-1157

Abstract:

Many studies have reported that the interaction between water mite larvae and their Odonata hosts affects mating success, flight, and longevity. Males and females of Odonata species collected in the steppes and coastal plains (Pampa Biome) of Rio Grande do Sul were analyzed. Mites were removed when present and the prevalence and intensity of parasites was calculated. The aim of this study was to search and report new Odonata hosts species that are parasitized by water mite larvae and also to evaluate the prevalence and intensity rates; the differences in mite occurrence and frequency between males and females, and between thorax and abdomen of the dragonflies and damselflies in the southern Pampa biome located in Rio Grande do Sul. A total of 162 larval mites were found associated to two Odonata families: Coenagrionidae (Acanthagrion lancea Selys, 1876, Ischnura capreolus Hagen, 1861 and Ischnura fluviatilis Selys, 1876) and Libelullidae (Micrathyria ocellata Martin, 1897 and Perithemis mooma Kirby, 1889). All mites were identified as Arrenurus (Arrenurus) sp. (Arrenuridae) and showed high numbers when attached to I. capreolus (55.5%), I. fluviatilis (33.3%), followed by low numbers on M. ocellata (6.1%), A. lancea (3.7%), and P. mooma (1.2%). Mites were found on males and females of I. capreolus and I. fluviatilis, females of A. lancea and P. mooma and in M. ocellata only in males. As the parasitized Odonata species are generalist and abundant in all water body types, traits associated with mating and oviposition or larval behavior are believed to explain the frequency of parasitism in these species.

Keywords:
water mites; lentic systems; dragonfly; damselfly; parasitism

Resumo:

Muitos estudos relatam que a interação entre as larvas parasitas e seus hospedeiros Odonata afetam o sucesso do acasalamento, o voo e a longevidade. Foram analisados machos e fêmeas de espécies de Odonata coletados nas estepes e planícies costeiras do bioma Pampa do Rio Grande do Sul. Os ácaros foram removidos quando presentes e a prevalência e intensidade dos parasitas foram calculadas. O objetivo deste estudo foi pesquisar e relatar novas espécies hospedeiras de Odonata que estão parasitadas por larvas de ácaros aquáticos, avaliar as taxas de prevalência e intensidade; avaliar a diferença na ocorrência e frequência de ácaros em fêmeas e machos e entre o tórax e abdômen de libélulas e libelulinhas no bioma Pampa meridional localizado no Rio Grande do Sul. Um total de 162 ácaros foram encontrados associados a duas famílias de Odonata: Coenagrionidae (Acanthagrion lancea Selys, 1876, Ischnura capreolus Hagen, 1861 e Ischnura fluviatilis Selys, 1876) e Libelullidae (Micrathyria ocellata Martin, 1897 e Perithemis mooma, 1889) Kirby. Todos os ácaros foram identificados como Arrenurus (Arrenurus) sp. (Arrenuridae) e apresentaram números elevados quando anexados a I. capreolus (55,5%), I. fluviatilis (33,3%), seguido por números baixos em M. ocellata (6,1%), A. lancea (3,7%) e P. mooma (1,2%). Os ácaros foram encontrados em machos e fêmeas de I. capreolus e I. fluviatilis, fêmeas de A. lancea e P. mooma e em M. ocellata apenas em machos. Como as espécies de Odonata parasitadas são generalistas e abundantes em todos os tipos de corpos d’água, acredita-se que características associadas ao acasalamento e oviposição ou comportamento larval explicam a frequência de parasitismo nessas espécies.

Palavras-chave:
ácaros aquáticos; sistema lêntico; libélulas; libelulinhas; parasitismo

Introduction

The hyporder Parasitengonina is characterized by mites that have parasitic larva and predatory nymphs and adults; the resting stages provide an adaptation to avoid unfavorable conditions in unstable environments, and larval parasitism on flying insects provides substantial advantages, ensuring dispersal and rapid exploitation of new habitats (Smith et al. 2001, Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586., Proctor et al. 2015PROCTOR, HC., SMITH, IM., COOK, DR., SMITH, BP 2015. Subphylum Chelicerata, Class Arachnida. In: Thorp, J., Rogers, D.C. (Eds.), Ecology and General Biology: Thorp and Covich’s Freshwater Invertebrates, Academic Press, p.599-660.). Hydrachnidiae, or water mites, are a highly diverse group of Parasitengonina, comprising over 6,000 described species and reported in all regions of the world, except for Antarctica (Cook 1974COOK, DR 1974. Water mite genera and subgenera. Mem. Amer. Ent. Inst. 21: 1-860, Viets 1987VIETS, KO 1987. Die Milben des Süflwassers (Hydrachnellae und Halacaridae [part.], Acari). II.: Katalog. Sonderbände des Naturwissenschaftlichen Naturwiss. Ver Hamb, 8: 1-1012.). They are found in lotic and lentic habitats, as well as in springs, interstitial waters, wetlands, temporary pools, marine habitats, torrential waterfalls, ponds, streams, and lakes (Smith & Cook 1991SMITH, IM., COOK, DR 1991. Water Mites. In THORP, JH., COVICH AP (Eds.) Ecology and Classification of North American Freshwater Invertebrates. Academic Press, Toronto: p.523-592., Smith et al. 2001SMITH, IM., COOK, DR 2001. Water mites (Hydrachnidia) and other arachnids. In: THORP JH ., COVICH AP (Eds.) Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.551-659., Goldschmidt 2016GOLDSCHMIDT, T 2016. Water mites (Acari, Hydrachnidia): powerful but widely neglected bioindicators - a review. Neotrop Biodivers, 2 (1): 12-25. doi:10.1080/23766808.2016.1144359.
https://doi.org/10.1080/23766808.2016.11... ).

A very ordinary family of Hydrachnidiae is Arrenuridae, and in the preparasitic phase they are very fast and active, searching out their hosts under the water surface walking on the substrate or swimming. The survival period for free-swimming larvae in the preparasitic phase ranges from 4 days to 6 weeks (Smith & Oliver 1986SMITH, IM., OLIVER, DR 1986. Review of parasitic associations of larval water mites (Acari: Parasitengona: Hydrachnida) with insect hosts. Can Entomol, 118 (5): 407-472., Smith 1988SMITH, BP 1988. Host-parasite interaction and impact of larval water mites on insects. Annu Rev Entomol, 33 (1): 487-507., Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586.). Their larvae parasitize species of Diptera, Coleoptera, and Odonata orders, all groups with the final instar active in the water or flying (Smith & Cook 1991SMITH, IM., COOK, DR 1991. Water Mites. In THORP, JH., COVICH AP (Eds.) Ecology and Classification of North American Freshwater Invertebrates. Academic Press, Toronto: p.523-592., Smith et al. 2001SMITH, IM., COOK, DR 2001. Water mites (Hydrachnidia) and other arachnids. In: THORP JH ., COVICH AP (Eds.) Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.551-659., Zawal 2008ZAWAL, A 2008. Morphological characteristics of water mite larvae of the genus Arrenurus Duges, 1834, with notes on the phylogeny of the genus and an identification key. Zootaxa, 1765 (1): 1-75., Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586., Gerecke et al. 2016GERECKE R., GLEDHILL, T., PESIC, V., SMIT, H 2016. Süßwasserfauna Von Mitteleuropa, Bd. Chelicerata: Acari III. Springer, 7: 2-3.). The predominant water mite genus that uses Odonata larvae and adults as hosts is Arrenurus Dugès (stricto sensu) (Arrenuridae) (Andrew et al. 2012ANDREW, RJ., THAOKAR, N & VERMA, P. 2012. Ectoparasitism of anisopteran dragonflies (Insecta: Odonata) by water mite larvae of Arrenurus spp. (Arachnida: Hydrachnida: Arrenuridae) in Central India. Acarina, 20 (2): 194-198.), and at least 55 species have been described as Odonata ectoparasites (Davids 1997DAVIDS, C 1997. Watermijten als parasieten van libellen. Brachytron, 1 (2): 51-55., Zawal & Dyatlova 2006ZAWAL, A., DYATLOWA, ES 2006. Preliminary data for parasitizing on Ischnura elegans (Vander Linden, 1820) (Odonata: Coenagrionidae) by Arrenurus (Acari: Hydrachnidia) larvae from Odessa province (Southwestern Ukraine). In: PESIC V., HADIABLAHOC S (eds.) Proceedings of the Symposium, II International Symposium of Ecologists of Montenegro. Kotor, p.17-20., Baker et al. 2007BAKER, RA., MILL, PJ & ZAWAL, A 2007. Mites on Zygoptera, with particular reference to Arrenurus species, selection sites and host preferences. Odonatologica, 36 (4): 339-347., Zawal 2008ZAWAL, A 2008. Morphological characteristics of water mite larvae of the genus Arrenurus Duges, 1834, with notes on the phylogeny of the genus and an identification key. Zootaxa, 1765 (1): 1-75.). The genus Arrenurus is one of the most species-rich of the Hydrachnidiae, with about 1000 species present in most of the zoogeographic regions (Smit 2020SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.). However, the genus lacks cosmopolitan species, and each region supports its own set of species (Zawal 2008ZAWAL, A 2008. Morphological characteristics of water mite larvae of the genus Arrenurus Duges, 1834, with notes on the phylogeny of the genus and an identification key. Zootaxa, 1765 (1): 1-75.). A list of South American water mites species was published by Rosso de Ferradás and Fernández (2005)ROSSO-DE-FERRADAS, B., FERNANDEZ, H.R 2005. Elenco y biogeografía de los ácaros acuáticos (Acari, Parasitengona, Hydrachnidia) de Sudamérica. Graellsia, 61 (2): 181-224. who listed 150 Arrenurus species. The number of reported South America Arrenurus reaches now 153 species (Smit 2020SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.). Some species listed for Brazil are A. clavipes Lundblad, 1941, A. corniger Koenike, 1894, A. epimerosus Marshall, 1919, A. ludificator Koenike, 1905, A. nitidus K. Viets, 1937VIETS, KO 1987. Die Milben des Süflwassers (Hydrachnellae und Halacaridae [part.], Acari). II.: Katalog. Sonderbände des Naturwissenschaftlichen Naturwiss. Ver Hamb, 8: 1-1012., A. quadrituberculatus K. Viets, 1937VIETS, KO 1987. Die Milben des Süflwassers (Hydrachnellae und Halacaridae [part.], Acari). II.: Katalog. Sonderbände des Naturwissenschaftlichen Naturwiss. Ver Hamb, 8: 1-1012., A. triconicus Marshall, 1919 and A. undulatus Lundblad, 1937 (Smit 2020SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.).

Arrenurus s. str. has not been precisely determined, mainly due to the lack of possibility to identify mite larvae (Smith,1988SMITH, BP 1988. Host-parasite interaction and impact of larval water mites on insects. Annu Rev Entomol, 33 (1): 487-507., Zawal 2008ZAWAL, A 2008. Morphological characteristics of water mite larvae of the genus Arrenurus Duges, 1834, with notes on the phylogeny of the genus and an identification key. Zootaxa, 1765 (1): 1-75., Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586., Zawal & Buczyński 2013ZAWAL, A., BUCZYŃSKI, P 2013. Parasitism of Odonata by Arrenurus (Acari: Hydrachnidia) larvae in the lake Świdwie, nature reserve (NW Poland). Acta Parasitol, 58 (4): 486-495.). Contemporary taxonomical knowledge on water mites is based primarily on males, but the description of the female should also be provided as they show significant morphological differences as well; the larval and nymphal stages are considerably less known (Zawal 2008ZAWAL, A 2008. Morphological characteristics of water mite larvae of the genus Arrenurus Duges, 1834, with notes on the phylogeny of the genus and an identification key. Zootaxa, 1765 (1): 1-75., Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586., Smit 2020SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.).

Larvae of many subfamilies of water mites exhibit strong selectivity in their attachment to particular parts of the host body (Smith & Oliver 1986SMITH, IM., OLIVER, DR 1986. Review of parasitic associations of larval water mites (Acari: Parasitengona: Hydrachnida) with insect hosts. Can Entomol, 118 (5): 407-472.). Larvae of Arrenurus s. str species have preferences for either thoracic or abdominal sites and are less seen in the head or wings of odonate hosts (Smith et al. 2010SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.). Studies indicate that mite parasitism can affect longevity, flight, and fecundity (Åbro 1979ÅBRO A 1979. Attachment and feeding devices of water-mite larvae (Arrenurus spp.) parasitic on damselflies (Odonata, Zygoptera). Zool. Scr, 8 (1-4): 221-234., Åbro 1982ÅBRO A 1982. The effects of parasitic water mite larvae (Arrenurus spp.) on Zygopteran imagoes (Odonata). J. Invertebr. Pathol. 39 (3): 373-381., Forbes 1991FORBES, MR 1991. Ectoparasites and mating success of male Enallagma ebrium damselfly (Odonata: Coenagrionidae). Oikos, 60: 36-42. doi:10.2307/3545076
https://doi.org/doi:10.2307/3545076... , Forbes & Baker 1991FORBES, MRL., BAKER, RL 1991. Condition and fecundity of the damselfly, Enallagma ebrium (Hagen): the importance of ectoparasites. Oecol., 86 (3): 35-41. doi: 10.1007/BF00317598
https://doi.org/doi: 10.1007/BF00317598... ).

Many odonate species respond to attached mites by aggregating their haemocytes at the sites of puncture and by producing melanotic encapsulation of feeding tubes, but Arrenurus genus have a developed powerful mouthpart specialized in anchor to the host’s body; the pedipalps have a well-developed claw that fixes in the cuticle and then with its chelicerae saber pierces the body till finds the hemolymph; then the larva produces a feeding device characterized by a narrow gelatinous resilient blind sac called stylostome, which seems to inject cytotoxins into the wound of the damselfly, thus, producing a paralysis which allows sufficient time to develop a stylostome to absorb nutrients, and this makes the damselfly’s defensive apparatus ineffective to cope with the stylostome (Åbro 1979ÅBRO A 1979. Attachment and feeding devices of water-mite larvae (Arrenurus spp.) parasitic on damselflies (Odonata, Zygoptera). Zool. Scr, 8 (1-4): 221-234.).

Heavy mite infestation brings several wounds in close proximity, accompanied by loss of more or less extensive areas of the epidermis. Despite Odonata wound repair by congregating hemocytes, local lack of epidermis seems to enfeeble the host, presumably owing to desiccation, thus, the infestation contributes to reduced longevity (Âbro 1982ÅBRO A 1982. The effects of parasitic water mite larvae (Arrenurus spp.) on Zygopteran imagoes (Odonata). J. Invertebr. Pathol. 39 (3): 373-381.).

Through this form of feeding, Reinhardt (1996)REINHARDT, K 1996. Negative effects of Arrenurus water mites on the flight distances of the damselfly Nehalennia speciosa (Odonata: Coenagrionidae). Aqua Insect, 18 (4): 233-240. observed that ectoparasitic mites have a negative influence on flight ability one meter was the longest distance flown by 35.2 % of the infested adults immediately after release while none flew farther than five meters; in the group of the non-parasitized damselflies, 75% flew more than one meter, and this pattern was consistent in both sexes. Oviposition injuries were observed by Rolff (1999)ROLFF, J 1999. Parasitism increases offspring size in a damselfly: experimental evidence for parasite-mediated maternal effects. Anim Behav, 58 (5): 1105-1108. which tested Arrenurus cuspidator (O. F. Müller, 1776) on Coenagrion puella Linnaeus, 1758 and found that the number of eggs laid by the damselfly decreased with increased ectoparasite abundance.

Rodrigues et al. (2013)RODRIGUES, ME., CARRIÇO, C., PINTO, ZT., MENDONÇA, PM., QUEIROZ, MMC 2013. First record of acari Arrenurus Dugès, 1834 as a parasite of Odonata species in Brazil. Biota Neotrop, 13 (4): 365-367. were the first to report larval of the Arrenurus genus parasites on Odonata species Ischnura fluviatilis Selys, 1876 (Coenagrionidae) and Miathyria marcella Selys, 1857 (Libellulidae) in Brazil.

The present study had the main objective to search and report new Odonata hosts for parasitic larvae of Arrenurus genus and also to evaluate the prevalence and intensity rates; the differences in mite occurrence and frequency between males and females, and between thorax and abdomen of the dragonflies and damselflies in the Pampa biome located in the Rio Grande do Sul state, Brazil.

Material and Methods

The present study was the first one performed in the Pampa biome. This biome covers the southern half of the state of Rio Grande do Sul and extends to Argentina and Uruguay. This biome constitutes the Brazilian portion of the South American Pampas, which are classified as steppes by the international phytogeographic system. The Pampa is limited by the Atlantic Forest biome to the north, and by the Chaco and the Patagonian steppes to the west. The steppes in the Pampa region have no dry season. However, they undergo high thermal amplitude and intense drying cold fronts, which increase evapotranspiration, and consequently, cause occasional droughts. This factor limits arboreal flora and riverbanks, valley bottoms, and protects lands from cold fronts; in other areas, grassy-woody species predominate. Steppes have been undergoing an intense anthropization process, due to cattle raising, grain cultivation, and fires (IBGE 2019IBGE. 2019. Biomas e sistema costeiro-marinho do Brasil: compatível com a escala 1:250 000 / Coordenação de Recursos Naturais e Estudos Ambientais. - Rio de Janeiro. 168 - (Relatórios metodológicos, ISSN 0101-2843; v. 45).). The coastal area (Coastal Plains) comprises sedimentary land of both fluvial and marine origin, flattened or depressed areas, generally with sandy soils. Pioneer Formations are predominant in this area. This vegetation occupies unstable land and is in constant ecological succession (IBGE 2019IBGE. 2019. Biomas e sistema costeiro-marinho do Brasil: compatível com a escala 1:250 000 / Coordenação de Recursos Naturais e Estudos Ambientais. - Rio de Janeiro. 168 - (Relatórios metodológicos, ISSN 0101-2843; v. 45).).

1. Study area

Samplings were conducted between 2016/17 in the municipalities of Caçapava do Sul, Manoel Viana, Mata, Quaraí, Rosário do Sul, Santa Margarida do Sul, Santana da Boa Vista, São Francisco de Assis, São Gabriel, São Pedro do Sul, São Sepé, São Vicente do Sul, and Uruguaiana (steppe) in temporary waters, rivers, streams lakes and wetlands. Samplings in coastal plains were conducted only in wetlands (the most common water body type in that phytophysiognomy) in the municipalities of Arroio Teixeira, Capão da Canoa, Cidreira, Curumin, Pinhal, Torres, Tramandaí and Xangri-lá between 2016/18.

2. Sampling methods

The material referred to Renner et al. (2017)RENNER, S., PÉRICO, E., ELY, GJ., SAHLÉN, G 2017. Preliminary dragonfly (Odonata) species list from the Pampa biome in Rio Grande do Sul, Brazil, with ecological notes for 19 new records for the State. Biota Neotrop, 17 (4): 1-10. doi:10.1590/1676-0611-bn-2017-0374
https://doi.org/10.1590/1676-0611-bn-201... and Renner et al. (2018)RENNER, S. , PÉRICO, E. , DALZOCHIO, MS., SAHLÉN, G 2018. Water body type and land cover shape the dragonfly communities (Odonata) in the Pampa biome, Rio Grande do Sul, Brazil. J Insect Conserv, 22 (1): 113-125. was used in the present study. Odonata specimens were preserved in 96% alcohol in glass pots with lids and identification labels. Specimens are deposited at the Natural Science Museum (MCNU) of Univates and the collection authorization process was issued by IBAMA, via the SISBio system under the number 50624-1.

3. Laboratory activities and identification

Odonata specimens were observed using a Zeiss 435063-9010-100 Stemi 305 Stereo Microscope and photographed using Zen software. Mites were removed from dragonflies and damselflies with the help of histological needle and tweezers, and stored in Eppendorf tubes in Koenike’s fluid (10mL acetic acid; 40mL distilled water; 50mL glycerin) (Walter & Krantz 2009WALTER, DE., KRANTZ GW 2009. A manual of acarology. 3rd ed. Lubbock (TX): Texas Tech University Press.).

Subsequently, mites were mounted on microscopic slides in Hoyer’s medium and dried at 60-70ºC for seven days. After this period, slides were sealed with crystal varnish to prevent contamination, and then, they were stored at the Laboratory of Acarology - Univates collection, where air humidity is controlled for proper storage of the material. Larval mites were analyzed using a Zeiss Imager Z2 optical microscope with phase contrast and were photographed using the Zen software. Mites were identified to the genus level using the most recent key provided by Smith et al. (2010)SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586.. Odonata specimens were identified according to Garrison et al. (2006GARRISON, RW., VON ELLENRIEDER, N., LOUTON, JA 2006. Dragonfly genera of the New World: an illustrated and annotated key to the Anisoptera. JHU Press. p.368; 2010)GARRISON, RW., VON ELLENRIEDER, N., LOUTON, JA 2010. Damselfly genera of the new world: an illustrated and annotated key to the Zygoptera. JHU Press. p.666. doi:10.1653/024.093.0434
https://doi.org/doi:10.1653/024.093.0434... and Lencioni (2006)LENCIONI, FAA 2006. The damselflies of Brazil: an illustrated identification guide 2-Coenagrionidae. All Print Editora, São Paulo, p.419.

4. Data analysis

Two indices were calculated: 1. Prevalence (number of parasitized individuals/total number of analyzed individuals X 100), 2. Intensity (total number of parasite/number of parasitized individuals).

In order to analyze the differences in mite occurrence between: (1) thorax and abdomen and (2) females and males was performed a G-test (p≤0.05), using Bioestat 5.0 software (Ayres et al. 2007AYRES, M., AYRES, JM., AYMER, DL & SANTOS AAS 2007. Bioestat: aplicações estatísticas nas áreas das ciências biomédicas. Ong Mamiraua. Belém, PA.).

Results

A total of 3134 specimens divided of 100 species were analyzed (^{Suplementary material} Supplementary Material The following online material is available for this article: Table S1 - Analyzed species. ) but only 44 specimens of five species had larval mites attached; they were found in lakes, rivers, and temporary waters of São Francisco de Assis, and in wetlands of São Pedro do Sul, Mata, Caçapava do Sul and Santa Margarida do Sul (steppe); in the coastal area, mites were found in wetlands of Tramandaí, Pinhal, and Cidreira (Figure 1). Four new Odonata species are reported to the host list for Arrenurus s.str: Ischnura capreolus Hagen, 1861, Acanthagrion lancea Selys, 1876, Perithemis mooma Kirby, 1889 and Micrathyria ocellata Martin, 1897. (Table 1).

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Table 1
Municipalities and coordinates where Arrenurus (A.) sp. was found along with the water body and Odonata species collected at each site.

Figure 1
Map with collection points in Rio Grande do Sul state where Arrenurus sp. larvae were and were not present.

A total of 162 Arrenurus (Arrenurus) sp. larvae (Table 2; Figure 2 A-B) were found to parasitizing five Odonata species: M. ocellata (Figure 3 A-B) and P. mooma (Figure 3 C-D) (Libellulidae) and A. lancea (Figure 4 A-B), I. capreolus and I. fluviatilis (Coenagrionidae).

Figure 2
Ventral view of Arrenurus (A.) sp. parasitic larvae. A Pedipalps, Coxal Plates and Legs; B Excretory Pore

Figure 3
A Micrathyria ocellata male (in lateral view) with larvae on thorax; B Micrathyria ocellata close up of thorax, ventral view; C Perithemis mooma female (in lateral view); D Perithemis mooma close up of thorax, lateral view.

Figure 4
A.Acanthagrion lancea male with larvae attached on abdomen (in the circle) and arrow pointing to larvae attached in the thorax; B. Close up in the circle.

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Table 2
Occurrence of Arrenurus (A.) sp. larvae in Odonata species from the Pampa Biome, Brazil.

A high number of mites occurred when they were attached to I. capreolus (55.5%), I. fluviatilis (33.3%), followed by low numbers when attached to M. ocellata (6.1%), A. lancea (3.7%), and P. mooma (1.2%). Mites found in the steppes were associated to the five Odonata species listed above; whereas only I. fluviatilis and I. capreolus were found in the coastal area. The collection points of the steppe did not had urbanization, that results in a higher diversity of Odonata species, and also more hosts for the parasitic mites. In the Coast, higher levels of urbanization were found around the collection points, thus, decreasing the number and diversity of species.

Mites attached to A. lancea, M. ocellata, and P. mooma were only found on the thorax, while mites attached to I. capreolus and I. fluviatilis were found both on the thorax and abdomen (Table 3). Significant difference was observed in the body’s part where water mite larvae was found in the species from steppe (p = 0.0005), but not for the coastal species (p = 0.8776).

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Table 3
Mites found in each part of the body and Odonata individuals parasitized by sex from the Pampa Biome, Brazil.

Larvae attached to A. lanceae and P. mooma were found only in females; when attached to M. ocellata, they were found only in males, and when attached to I. capreolus and I. fluviatilis, they were found in both females and males. No significant differences between host’s sex preferences were found in I. capreolus and I. fluviatilis (p=0.1413).

Discussion

The present study demonstrates that despite having a range of Odonata species for colonization (about 130 different species evaluated) only five of them were found with parasites. The species that were found being parasitized are very common and generalist in our state, they can be found either in lentic and lotic environments, with presence or absence of luminosity, and saturated O₂ or not. The parasitized species in the steppe areas of the Pampa were found in all types of water bodies present in the region: lakes, rivers, wetland and temporary waters, and in the coastal region only in wetlands (which occur most frequently in this area), indicating that there is no preferred location for infestation to occur. The mites did not seem to have any preferences either for thoracic or abdominal attachment on the host’s body, and either for females or males, and that may indicate that attachment happens by chance.

One important aspect from the analyzed species is that they lay eggs directly in the water, and sometimes in plants and small pieces of wood floating in surface; those species can also mate with more than one partner. In traits and general behavior shown in Corbet (1999)CORBET, PS 1999. Dragonflies: behaviour and ecology of Odonata. Colchester. UK: Harley Books. p.864, Córdoba-Aguilar (2008)CÓRDOBA-AGUILAR, A (Ed.) 2008. Dragonflies and damselflies: model organisms for ecological and evolutionary research. Oxford University Press. p.288. and Dalzochio et al. (2018)DALZOCHIO, MS., PÉRICO, E., RENNER, S., SAHLÉN, G 2018. Effect of tree plantations on the functional composition of Odonata species in the highlands of southern Brazil. Hydrobiologia, 808 (1): 283-300., A. lancea exhibit larval climbing behavior and their oviposition is epiphytic, which means that egg laying occurs on leaves, woods, or rocks, whether or not submerged in water. I. capreolus and I. fluviatilis are also climbers but they exhibit endophytic oviposition pattern, i.e. damselflies lay eggs inside plant tissue in the waters surface. On the other hand, Libelullidae larvae, e.g. P. mooma and M. ocellata, are sprawlers and exophytic, which means egg laying occurs directly into the water. All these species spend a long period near the water, and it is easier for larval mites to attach to the host than those in Aeshnidae and Gomphidae, which never climb, are very active, and difficult to collect. Thus, species with terrestrial behavior are less prone to being parasitized (Smith et al. 2010SMITH, IM., COOK, DR., SMITH, BP 2010. Water mites (Hydrachnidia) and other Arachnids. In: THORP JH., COVICH AP (Eds). Ecology and Classification of North American Freshwater Invertebrates. Academic Press, San Diego, p.485-586.). A general rule in Coenagrionidae is that adult males spend more time near water bodies searching for mating while adult females disperse in the vicinity and return to the water to breed (Corbet 1999CORBET, PS 1999. Dragonflies: behaviour and ecology of Odonata. Colchester. UK: Harley Books. p.864, Córdoba-Aguilar 2008CÓRDOBA-AGUILAR, A (Ed.) 2008. Dragonflies and damselflies: model organisms for ecological and evolutionary research. Oxford University Press. p.288.). This may explain the numbers of mites found on Ischnura spp. males, as these individuals spend a long time in the water and are very abundant in all kinds of water bodies, and that agrees with some of the Ilvonen et al. 2016ILVONEN, JJ., KAUNISTO, KM., SUHONEN, J 2016. Are sexes equally parasitized in damselflies and dragonflies? Oikos, 125 (3): 315-325. doi: 10.1111/oik.02437
https://doi.org/10.1111/oik.02437... , Ilvonen & Suhonen, 2016ILVONEN, JJ. , SUHONEN, J 2016. Phylogeny affects host’s weight, immune response and parasitism in damselflies and dragonflies. Roy Soc Open Sci, 3(11): 160421 found, where many Coeanagrionidae are reported being parasitized by Arrenuridae mites.

Ilvonen et al. (2016)ILVONEN, JJ. , SUHONEN, J 2016. Phylogeny affects host’s weight, immune response and parasitism in damselflies and dragonflies. Roy Soc Open Sci, 3(11): 160421 found no differences in infestation by water mites between damselfly males and females, which conflicts with the findings of Rob and Forbes (2005)ROBB, T., FORBES, MR 2005. On understanding seasonal increases in damselfly defence and resistance against ectoparasitic mites. Ecol Entomol, 30 (3): 334-341. doi:10.1111/j.0307-6946.2005.00689.x
https://doi.org/10.1111/j.0307-6946.2005... , who observed a higher infestation by water mites on Lestes disjunctus Selys, 1862 (Lestidae) females. Ilvonen & Suhonen 2016ILVONEN, JJ. , SUHONEN, J 2016. Phylogeny affects host’s weight, immune response and parasitism in damselflies and dragonflies. Roy Soc Open Sci, 3(11): 160421 tested Odonata immune responses to water mites; mass was significantly different between sexes, females being heavier than males; between species, the encapsulation response was different, but not between sexes; it was also found considerable differences in the encapsulation response between different odonate species, e.g I. elegans (Coenagrionidae) had the lowest encapsulation rate, whereas dragonfly Leucorrhinia dubia Vander Linden, 1825 (Libellulidae) had the highest. These defense mechanisms add up to an effective immune system, capable of defending against parasites and thus prolonging the host’s lifespan and reproductive success. In their study, also found that damselflies had also much higher water mite prevalence than dragonflies.

In Brazil, studies on parasitism of aquatic mites on odonates and other host species are scarce, and many species can only be identified as morphospecies of specific genera due to the lack of taxonomic studies for the Neotropics. It is important to collect adults and conduct oviposition studies with females in order to correctly associate the larvae with their parents. Also, full descriptions of Hydrachnidiae must have males, females and larvae. In addition, molecular tools (e.g. barcoding) can be useful for creating a database for the identification of species and even larvae. Thus, further studies must be carried out in lotic and lentic environments in order to find and describe larvae, and adults either females and males to report the existing and describe the new species in Brazil; studies on the damage caused on dragonflies and damselflies by mites should be performed in order to discover whether flight, longevity and oviposition are really affected. This type of analysis was already performed by Reinhardt (1996)REINHARDT, K 1996. Negative effects of Arrenurus water mites on the flight distances of the damselfly Nehalennia speciosa (Odonata: Coenagrionidae). Aqua Insect, 18 (4): 233-240. who observed that ectoparasitic mites have a negative influence on flight ability of Nehalennia speciosa Charpentier, 1840 (Coenagrionidae); one meter was the longest distance flown by 35.2 % of the infested adults immediately after release, whereas none flew farther than five meters; in the group of the non-parasitized damselflies, 75% flew more than one meter and this pattern was consistent in both sexes. Advanced adults of Coenagrion hastulatum Charpentier, 1825 and Enallagma cyathigerum Charpentier, 1840 heavily loaded with parasites had often lost the typical agility to move and could be easily catched (Åbro 1981), this flight injuries is due to the mites attachment in the thoracic region where there is more hemolymph stream and consequently more consumed energy due to the time that Odonata spends flapping their wings (Corbet 1999CORBET, PS 1999. Dragonflies: behaviour and ecology of Odonata. Colchester. UK: Harley Books. p.864). Oviposition test was performed by Rolff (1999)ROLFF, J 1999. Parasitism increases offspring size in a damselfly: experimental evidence for parasite-mediated maternal effects. Anim Behav, 58 (5): 1105-1108. which tested Arrenurus cuspidator (O. F. Müller, 1776) on C. puella Linnaeus, 1758 and found that the number of eggs laid by the damselfly decreased with increased ectoparasite abundance. New hosts should also be sought to report new host-parasite interactions and continue to build knowledge on aquatic mite fauna for Rio Grande do Sul state.

Supplementary Material

The following online material is available for this article:

Table S1 - Analyzed species.

Acknowledgements

We are grateful to the Brazilian National Council for Scientific and Technological Development (CNPq) to EP (PQ process 307303/2019-5), to NJF (PQ process n° 310035/2017-1) and to MSD (post-doctoral process nº 153902/2018-3), for the financial support and research fellowship. We also thank Universidade do Vale do Taquari - Univates for providing the opportunity to conduct this study. Thanks are also due to FAPERGS for the scholarship granted to the first author.

References

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» https://doi.org/doi: 10.1007/BF00317598
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Publication Dates

Publication in this collection
26 Feb 2021
Date of issue
2021

History

Received
06 Nov 2020
Reviewed
06 Jan 2021
Accepted
15 Jan 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ÅBRO A 1979. Attachment and feeding devices of water-mite larvae (Arrenurus spp.) parasitic on damselflies (Odonata, Zygoptera). Zool. Scr, 8 (1-4): 221-234.

[2] ÅBRO A 1982. The effects of parasitic water mite larvae (Arrenurus spp.) on Zygopteran imagoes (Odonata). J. Invertebr. Pathol. 39 (3): 373-381.

[3] ANDREW, RJ., THAOKAR, N & VERMA, P. 2012. Ectoparasitism of anisopteran dragonflies (Insecta: Odonata) by water mite larvae of Arrenurus spp. (Arachnida: Hydrachnida: Arrenuridae) in Central India. Acarina, 20 (2): 194-198.

[4] AYRES, M., AYRES, JM., AYMER, DL & SANTOS AAS 2007. Bioestat: aplicações estatísticas nas áreas das ciências biomédicas. Ong Mamiraua. Belém, PA.

[5] BAKER, RA., MILL, PJ & ZAWAL, A 2007. Mites on Zygoptera, with particular reference to Arrenurus species, selection sites and host preferences. Odonatologica, 36 (4): 339-347.

[6] IBGE. 2019. Biomas e sistema costeiro-marinho do Brasil: compatível com a escala 1:250 000 / Coordenação de Recursos Naturais e Estudos Ambientais. - Rio de Janeiro. 168 - (Relatórios metodológicos, ISSN 0101-2843; v. 45).

[7] COOK, DR 1974. Water mite genera and subgenera. Mem. Amer. Ent. Inst. 21: 1-860

[8] COOK, DR 1980. Neotropical Water Mites. Mem. Amer. Ent. Inst. 31: 1-645.

[9] CORBET, PS 1999. Dragonflies: behaviour and ecology of Odonata. Colchester. UK: Harley Books. p.864

[10] CÓRDOBA-AGUILAR, A (Ed.) 2008. Dragonflies and damselflies: model organisms for ecological and evolutionary research. Oxford University Press. p.288.

[11] DAVIDS, C 1997. Watermijten als parasieten van libellen. Brachytron, 1 (2): 51-55.

[12] DALZOCHIO, MS., PÉRICO, E., RENNER, S., SAHLÉN, G 2018. Effect of tree plantations on the functional composition of Odonata species in the highlands of southern Brazil. Hydrobiologia, 808 (1): 283-300.

[13] DI SABATINO, A., SMIT, H., GERECKE, R., GOLDSCHMIDT, T., MATSUMOTO, N., CICOLANI, B 2008. Global diversity of water mites (Acari, Hydrachnidia; Arachnida) in freshwater. Hydrobiologia, 595: 303-315.

[14] FORBES, MR 1991. Ectoparasites and mating success of male Enallagma ebrium damselfly (Odonata: Coenagrionidae). Oikos, 60: 36-42. doi:10.2307/3545076
» https://doi.org/doi:10.2307/3545076

[15] FORBES, MR., BAKER, RL 1990. Susceptibility to parasitism: experiments with the damselfly Enallagma ebrium (Odonata: Coenagrionidae) and larval water mites, Arrenurus spp.(Acari: Arrenuridae). Oikos, 61-66.

[16] FORBES, MRL., BAKER, RL 1991. Condition and fecundity of the damselfly, Enallagma ebrium (Hagen): the importance of ectoparasites. Oecol., 86 (3): 35-41. doi: 10.1007/BF00317598
» https://doi.org/doi: 10.1007/BF00317598

[17] FORBES, MR., MUMA, KE., SMITH, BP 1999. Parasitism of Sympetrum dragonflies by Arrenurus planus mites: maintenance of resistance particular to one species. International Journal for Parasitology, 29 (7): 991-999.

[18] GARRISON, RW., VON ELLENRIEDER, N., LOUTON, JA 2006. Dragonfly genera of the New World: an illustrated and annotated key to the Anisoptera. JHU Press. p.368

[19] GARRISON, RW., VON ELLENRIEDER, N., LOUTON, JA 2010. Damselfly genera of the new world: an illustrated and annotated key to the Zygoptera. JHU Press. p.666. doi:10.1653/024.093.0434
» https://doi.org/doi:10.1653/024.093.0434

[20] GERECKE R., GLEDHILL, T., PESIC, V., SMIT, H 2016. Süßwasserfauna Von Mitteleuropa, Bd. Chelicerata: Acari III. Springer, 7: 2-3.

[21] GOLDSCHMIDT, T 2002. The biodiversity of Neotropical water mites. In BERNINI, F., R. NANNELLI, G. NUZZACI & de LILLO, F. (Eds), Acarid Phylogeny and Evolution. Adaptations in mites and ticks. Springer, Dordrecht. p.91-99.

[22] GOLDSCHMIDT, T 2016. Water mites (Acari, Hydrachnidia): powerful but widely neglected bioindicators - a review. Neotrop Biodivers, 2 (1): 12-25. doi:10.1080/23766808.2016.1144359.
» https://doi.org/10.1080/23766808.2016.1144359

[23] ILVONEN, JJ., KAUNISTO, KM., SUHONEN, J 2016. Are sexes equally parasitized in damselflies and dragonflies? Oikos, 125 (3): 315-325. doi: 10.1111/oik.02437
» https://doi.org/10.1111/oik.02437

[24] ILVONEN, JJ. , SUHONEN, J 2016. Phylogeny affects host’s weight, immune response and parasitism in damselflies and dragonflies. Roy Soc Open Sci, 3(11): 160421

[25] LAJEUNESSE, MJ 2007. Ectoparasitism of damselflies by water mites in Central Florida. Fla Entomol, 90(4): 643-649.

[26] LENCIONI, FAA 2006. The damselflies of Brazil: an illustrated identification guide 2-Coenagrionidae. All Print Editora, São Paulo, p.419

[27] PROCTOR, HC., SMITH, IM., COOK, DR., SMITH, BP 2015. Subphylum Chelicerata, Class Arachnida. In: Thorp, J., Rogers, D.C. (Eds.), Ecology and General Biology: Thorp and Covich’s Freshwater Invertebrates, Academic Press, p.599-660.

[28] REINHARDT, K 1996. Negative effects of Arrenurus water mites on the flight distances of the damselfly Nehalennia speciosa (Odonata: Coenagrionidae). Aqua Insect, 18 (4): 233-240.

[29] RENNER, S., PÉRICO, E., ELY, GJ., SAHLÉN, G 2017. Preliminary dragonfly (Odonata) species list from the Pampa biome in Rio Grande do Sul, Brazil, with ecological notes for 19 new records for the State. Biota Neotrop, 17 (4): 1-10. doi:10.1590/1676-0611-bn-2017-0374
» https://doi.org/10.1590/1676-0611-bn-2017-0374

[30] RENNER, S. , PÉRICO, E. , DALZOCHIO, MS., SAHLÉN, G 2018. Water body type and land cover shape the dragonfly communities (Odonata) in the Pampa biome, Rio Grande do Sul, Brazil. J Insect Conserv, 22 (1): 113-125.

[31] ROBB, T., FORBES, MR 2005. On understanding seasonal increases in damselfly defence and resistance against ectoparasitic mites. Ecol Entomol, 30 (3): 334-341. doi:10.1111/j.0307-6946.2005.00689.x
» https://doi.org/10.1111/j.0307-6946.2005.00689.x

[32] RODRIGUES, ME., CARRIÇO, C., PINTO, ZT., MENDONÇA, PM., QUEIROZ, MMC 2013. First record of acari Arrenurus Dugès, 1834 as a parasite of Odonata species in Brazil. Biota Neotrop, 13 (4): 365-367.

[33] ROLFF, J 1999. Parasitism increases offspring size in a damselfly: experimental evidence for parasite-mediated maternal effects. Anim Behav, 58 (5): 1105-1108.

[34] ROSSO-DE-FERRADAS, B 2006. Arrenúridos de la cuenca del Río Paraná, Argentina (Acari: Parasitengona: Hydrachnidia). Rev Soc Entomol Arg, 65 (3-4): 23-34.

[35] ROSSO-DE-FERRADAS, B., FERNANDEZ, H.R 2005. Elenco y biogeografía de los ácaros acuáticos (Acari, Parasitengona, Hydrachnidia) de Sudamérica. Graellsia, 61 (2): 181-224.

[36] SMITH, IM., OLIVER, DR 1986. Review of parasitic associations of larval water mites (Acari: Parasitengona: Hydrachnida) with insect hosts. Can Entomol, 118 (5): 407-472.

[37] SMITH, BP 1988. Host-parasite interaction and impact of larval water mites on insects. Annu Rev Entomol, 33 (1): 487-507.

[38] SMIT, H 2020. New records of the water mite genus Arrenurus Dugès, 1834 from South America (Acari: Hydrachnidia: Arrenuridae), with the description of five new species and one new subspecies. Acarologia, 60 (2): 371-389.

[39] SMITH, IM., COOK, DR 1991. Water Mites. In THORP, JH., COVICH AP (Eds.) Ecology and Classification of North American Freshwater Invertebrates. Academic Press, Toronto: p.523-592.

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	Municipality	W	S	Water body	Species
Steppe	São Pedro do Sul	54º50'22.2"	29º65'96"	Wetland	Acanthagrion lancea
	Mata	54º42'85.8"	29º65'29"	Wetland	Ischnura capreolus
				Wetland	Ischnura fluviatilis
	Caçapava do Sul	53º27'7.1"	30º53'35.4"	Wetland	Ischnura capreolus
	Santa Margarida do Sul	53º84'94.4"	30º34'32"	Wetland	Acanthagrion lancea
				Wetland	Perithemis mooma
				Wetland	Ischnura fluviatilis
	São Francisco de Assis	55º17'07.6''	30º34'32"	Lake	Ischnura capreolus
				Lake	Ischnura fluviatilis
				Lake	Micrathyria ocellata
				Lake	Perithemis mooma
	São Francisco de Assis	55º19'20.4''	30º34'32"	Lake	Ischnura capreolus
				Lake	Ischnura fluviatilis
				Lake	Micrathyria ocellata
				Lake	Perithemis mooma
	São Francisco de Assis	55º08'54.7''	29º36'28.2''	River	Micrathyria ocellata
				River	Perithemis mooma
	São Francisco de Assis	55º07'7.3''	29º35'43,1''	Temporary waters	Ischnura fluviatilis
Coast	Tramandaí	50º10'26''	30º05'37''	Wetland^* * modified environment (high level of urbanization)	Ischnura fluviatilis
				Wetland^* * modified environment (high level of urbanization)	Ischnura capreolus
	Cidreira	50º12'03''	30º09'26''	Wetland^* * modified environment (high level of urbanization)	Ischnura fluviatilis
				Wetland^* * modified environment (high level of urbanization)	Ischnura capreolus
	Cidreira	50º13'14''	30º10'57''	Wetland^* * modified environment (high level of urbanization)	Ischnura fluviatilis
				Wetland^* * modified environment (high level of urbanization)	Ischnura capreolus
	Pinhal	50º17'31.7''	30º12'50.1''	Wetland	Ischnura fluviatilis
				Wetland	Ischnura capreolus
	Tramandaí	50º09'01''	30º01'16''	Wetland^* * modified environment (high level of urbanization)	Ischnura fluviatilis
				Wetland^* * modified environment (high level of urbanization)	Ischnura capreolus

Brasil

Brasil

Aquatic larval of the genus Arrenurus (Trombidiformes: Parasitengonina: Arrenuridae) associated with Odonata species from Pampa Biome, Brazil

Larvas aquáticas do gênero Arrenurus (Trombidiformes: Parasitengonina: Arrenuridae) associada a espécies de Odonata do bioma Pampa, Brasil

Abstract:

Resumo:

Introduction

Material and Methods

1. Study area

2. Sampling methods

3. Laboratory activities and identification

4. Data analysis

Results

Discussion

Supplementary Material

Acknowledgements

References

Publication Dates

History

Ecosystem	Odonata species	Analyzed individuals	Parasitized individuals	Prevalence of infestation (%)	Total of parasites found	Intensity of infestation
Steppe	I. capreolus	19	9	47.4	38	4.2
	I. fluviatilis	53	12	22.6	15	1.3
	A. lancea	11	4	36.4	6	1.5
	M. ocellata	11	1	9.1	10	10
	P. mooma	12	1	8.3	2	2
Coast	I. capreolus	37	7	18.9	52	7.4
Coast	I. fluviatilis	49	10	20.4	39	3.9

	Parasites on host´s body		Specimens parasitized by sex
Steppe	Abdomen	Thorax	♀	♂
A. lancea	0	6	4	0
I. capreolus	22	16	2	7
I. fluviatilis	10	5	4	8
M. ocellata	0	10	0	1
P. mooma	0	2	0	1
Coast	Abdomen	Thorax	♀	♂
I. capreolus	31	21	3	4
I. fluviatilis	23	16	2	8