Abstract
Chira River is located on the north coast of Peru. The scant information of the ichthyofauna from coastal drainages from Peru is noteworthy. The aim of this study is to characterize the ichthyofauna along the Chira River basin in terms of diversity and altitudinal range distribution. The material examined belongs to the Ichthyological collection of the Natural History Museum (MUSM). The diversity of fishes is composed of 27 species belonging to 19 families and ten orders. Siluriformes and Characiformes were the most diverse, consisting of 22% (six species) for each one. Five species are new records for the Chira River (three natives and two non-natives). Six marine species and seven exotic species were recorded as well. The altitudinal distribution patterns for all species were registered. This study increases the known diversity of freshwater fishes from Pacific Drainage Rivers in Peru, and it could be used for management and conservation plans.
Resumen
El río Chira está ubicado en la costa norte del Perú. La escasa información de la ictiofauna de las cuencas costeras del Perú es notable. El objetivo de este estudio es caracterizar la ictiofauna en la cuenca del río Chira en términos de diversidad y rango de distribución altitudinal. El material examinado pertenece a la colección ictiológica del Museo de Historia Natural (MUSM). La diversidad de peces está compuesta por 27 especies pertenecientes a 19 familias y 10 órdenes. Cinco especies son nuevos registros para el río Chira (tres nativas y dos no nativas). Fueron registradas seis especies marinas y siete especies exóticas. Este estudio incrementa el conocimiento de la diversidad de peces de las cuencas costeras en Perú, y puede ser usado para planes de manejo y conservación.
Keywords:
North Andean Pacific Slopes; seasonal dry forest; Tropical coastal rivers; Peruvian coastal drainage; geographic distribution; ichthyofauna; exotic fishes.
Palabras clave:
Vertientes del Pacífico Norte Andino; Bosque seco estacional; Cuencas costeras peruanas; Ríos costeros tropicales; distribución geográfica; ictiofauna; peces exóticos.
Introduction
The rivers of Andes western slopes of Peru are characterized by being independent, seasonable, short, and drain directly to the Pacific Ocean (Ortega & Hidalgo 2008). Most of the coast from Peru is a desert, except for the northern regions in Piura and Tumbes departments, which have tropical weather with marked rainy seasons. Contrary to most rivers in the Peruvian Pacific drainages, the Chira River (Piura department) has permanent flowing water. Also, the Chira River is the southernmost portion of North Andean Pacific Slopes-Rio Atrato ecoregion of the South America, according to the classifications of ecoregions for freshwater fishes (301, Abell et al. 2008, Reis et al. 2016).
The Pacific slope basins have relatively poor diversity in fishes but a high degree of endemism, making the northern slope richer than the southward (Ortega & Hidalgo 2008, Reis et al. 2016). The lack of knowledge on the distribution and taxonomy of ichthyofauna from coastal drainages from Peru is noteworthy. The Chira River is the second most diverse river of the Peruvian coast after the Tumbes River (Ortega et al. 2015). Studies on freshwater fishes from this basin are scarce; the first study was made by Fowler (1945) registering three species for the basin, followed by Lopez et al. (1982) who registered eight species. Furthermore, other research recorded 13 species (Bonastre 2008) and 20 species (Marchena 2013, Ortega et al. 2015). However, recent collections revealed the presence of new records for the basin.
Moreover, anthropogenic activities, like agriculture, artisanal mining, pollution, and domestic wastewater discharge, have affected the preservation of the aquatic systems and biodiversity of the basin (More 2019, Ortega 2012). The aim of this study is to (1) update the composition of freshwater fishes from the Chira basin and (2) provide the altitudinal distribution of the species along the basin to better understand the ichthyofauna.
Material and methods
Study area. The Chira River is in Piura department in north western Peru. The Chira is considered part of the bi-national basin Catamayo-Chira between Ecuador and Peru. The headwaters of the Catamayo-Chira basin are in the complex lakes in the Pacific slope of Parque Nacional Podocarpus, Loja Province in Ecuador; and in the complex lakes Las Huaringas and Arrabiatadas, Ayabaca Province in Peru (SOFIA, 2018). The bi-national basin has a total surface drainage area of 19095 km2, where 11933 km2 (62%) are in Peru (MINAM 2012) which drain to the Pacific Ocean.
The area of the Chira River and its tributaries goes from 0 - 3600 m above sea level. and crosses the provinces of Ayabaca and Sullana, flowing from east to west. Their main tributaries in Peru are Macara, Quiroz, Chipillico and Alamor rivers, and Jaguay de Poechos, Venados and Saman streams (Fig. 1).
The distribution of species is strongly related to elevation and vegetation; therefore, we show the distribution of species following ecosystem classification in Peru. Along the Peruvian coast are eleven ecosystems and the Chira basin passes through seven of them; Coastal desert (Dc, 0 - 2500 m a.s.l.), Andean scrub (Ma, 1500 - 3900 m a.s.l.), Paramo (Pa, more than 3000 m a.s.l.), Seasonally dry hill and mountain forest (Bes-cm, 400 - 2000 m a.s.l.), Seasonally dry plain forest (Bes-ll, 0 - 500 m a.s.l), Seasonally dry riparian forest (Besr, 100 - 700 m a.s.l.), Western relic montane forest (Br-mvoc, 1400 - 3000 m a.s.l.) according to MINAM (2019).
Sampling. Fish samples from the Chira River belong to scientific collections and correspond to extensive sampling in October 2015 of 47 sites along the Chira basin and tributaries (Fig. 1, Appendix 1). Fishes were collected using seine nets, gill nets, cast nets and hand nets using the standardized collecting according to Birindelli et al. (2016).
The captured fishes were anesthetized in clove oil (Lucena et al. 2013), then were fixed in 10% formalin and after 48 hours were preserved in 70% ethanol. Species were identified by primarily literature and deposited at the fish collection from Museo de Historia Natural, Universidad Nacional Mayor de San Marcos, Lima (MUSM) and Royal Ontario Museum, Toronto (ROM).
List of fishes. The complete list of species is arranged by the classification of order and family following Eschmeyer Catalog (Fricke et al. 2020). Additionally, information of the habitats (freshwater, brackish, and marine), the origin of species (native or introduced), the categorization of IUCN, and references are provided.
Results
The compilation of data recorded 27 species for the Chira River basin, distributed in 10 orders, 19 families (Table 1, Appendix 2). The ichthyofauna was predominantly Characiformes and Siluriformes representing 44% of all species (Fig. 2) with six species in each order. The most diverse families were Characidae and Cichlidae with four species in each family (Fig. 3).
Five species are considered new records for the Chira River: Astroblepus rosei, Basilichthys semotiius, Trichomycterus piurae, Oncorhynchus mykiss and Poecilia reticulata. Trichomycterus sp. is probably a new species to science. Furthermore, six marine species were recorded, collected approximately 90 m from the mouth of the river. Among the species recorded, 20 species are native; one catfish species (Chinchaysuyoa ortegai) is endemic to the Chira River; and seven species are introduced (Table 1).
Related to the abundance, a total of 3896 specimens were captured during fieldwork (October 2015). However, Poeciliidae were the most abundant with 39% of all specimens represented by Poecilia reticulata and Gambusia affinis which are non-native species; followed by Characidae with 27% of total represented by Eretmobrycon peruanus, Landonia latidens and Rhoadsia altipinna; Bryconidae with 13% of total represented by Brycon atrocaudatus; and Cichlidae with 15% represented by the native species Andinoacara rivulatus and A. stalsbergi, and the introduced species Coptodon rendalli and Oreochromis niloticus. Remaining families have less than 10% abundance (Fig. 3).
Regarding the ecosystems present in the basin, 15 species were exclusively found in the seasonally dry forest of the plain, eight species were found in both seasonally dry forest of the plain and seasonally dry forest of hill and mountain; Astroblepus rosei, Trichomycterus sp. and Basilichthys semotilus are exclusive from the latest. In Andean scrub ecoregion, Oncorhynchus mykiss is exclusive and Astroblepus rosei was found in both, Andean scrub and seasonally dry forest of hill and mountain (Fig. 4, Fig. 5).
In the Chira River 11 species have been categorized according to IUCN (2020) conservation status, most of them euryhaline (occurs in freshwater, brackish, and marine habitats) and four introduced species (Table 1). Among native species, six are Least Concern (LC) and one species is in the Deficient Data (DD) category.
Discussion
The Chira River basin has characteristics of ecoregion and ecosystem that make it unique and because that is considered an endemic area (Albert et al. 2011, Reis et al. 2016). Although the Chira river basin is unique in comparison to other Peruvian river basins, little research has been done to demonstrate the diversity of the area. This survey represents the most thorough sampling of the Chira basin and most complete sampling on the Peruvian coast.
Although the river is considered an ecosystem (MINAM, 2019), it is not uniform from headwater to mouth in terms of fishes. There has been observed differential distribution of fishes along the Chira basin, which are related to ecosystems it crosses. As ecosystems are established by considering biodiversity and characteristics of habitats as elevation, vegetation, ecosystem services, weather, etc. (MINAM, 2019), future monitoring of biodiversity can be integrated with ecosystem assessments as well (Llambi et al. 2020).
Diversity of fishes in the basin was increased to 27 species, compared to previous ichthyofauna diversity studies in the basin and its tributaries (Bonastre 2008, Marchena 2013, Ortega et al. 2015). Most prolific species are the orders Characiformes and Siluriformes which belong to the superorder of Ostariophysi, predominant in most freshwater rivers of the Neotropical region (Roberts 1972, Lowe-McConnell 1987, Reis et al. 2003, 2016) and in coastal rivers from the northeast of Peru (Ortega et al. 2015). Besides, species show restricted distribution for altitude. For instance, most of them are distributed less than 500 m a.s.l, Astroblepus, Basilichthys and Trichomycterus are present in a range between 5001500 m a.s.l. and the introduced species Oncorhynchus is found more than 2000 m a.s.l.
Among new additions there are three genera (Chinchaysuyoa, Astroblepus and Basilichthys), of which the catfish Chinchaysuyoa ortegai is a new genus, and species, endemic from the Chira River (Marceniuk et al. 2019). Additionally, the presence of Astroblepus rosei Eigenmann (1922), originally described from Jequetepeque River, 300 km south of Chira River, represents an extension in its distribution. The current distribution of Basilichthys semotilus is from Reque River, Lambayeque department to Sama River, Tacna department (Dyer 2003); however, the species was recorded in the Chira basin in the present study and by Bonastre (2008) in her unpublished undergraduate project (no voucher deposited in any fish collection), representing the northernmost distribution of B. semotilus.
Non-native fish species were introduced to several rivers in Peru as biological control vectors (Gambusia affinis and Poecilia reticulata), farming and sport fishing (Oncorhynchus mykiss), fish culture (Oreochromis niloticus), and living food to big fishes (Coptodon rendalli) (Ortega et al. 2007). Ortega et al. (2015) recorded Gambusia affinis and Oreochromis niloticus from Tumbes and Chira River which is the northernmost distribution for these species; in this study we added Poecilia reticulata, Oncorhynchus mykiss, and Coptodon rendalli (previously introduced as Tilapia rendalli) which represent the northernmost distribution for these species in the Pacific drainages. As non-native species have increased along the Chira River, the future impact that these exotic species could have on native species is of high importance. Some impacts on native species include competition, predation, and habitat alteration (Primack 1993, Simberloff 2000), which has already happened in some native species in the Amazonian drainages and Pacific coastal basins in Peru (Ortega et al. 2007). Additionally, Hypostomus sp. should be treated carefully, as the genus is well distributed along the Amazonian basin and not found in the Peruvian coast. This implies the species was transferred from the Peruvian amazon, or is a species related to Hypostomus species of the north coastal rivers from Ecuador; however, more taxonomic studies are needed. Also, Arapaima gigas (paiche) is the most recent species transferred to San Lorenzo reservoir for farming purposes to improve the economy of the residents of Las Lomas municipality (Produce 2018), but future studies could show us the impact of the introduction of this non-native species.
During fieldwork, anthropogenic activities were identified which have modified aquatic bodies, such as agriculture, mining, dams, pollution and even proliferation of exotic species which threaten native species (Ortega et al. 2007). Changes in environmental conditions can affect biodiversity and its distribution (Lujan et al. 2013, Albert et al. 2020); hence those anthropogenic activities are contributing to the modification of habitats. For instance, the lower Chira River, headwater of Chipillico and Queiroz River are highly impacted by agriculture (MINAM, 2019). Also, as was pointed out in Meza-Vargas et al. (2019), water diversion between Chira and Piura basins can explain the presence of Landonia latidens in the latest basin. We recommend increasing efforts for regulation of these activities for the sake of keeping in good conditions and conservation of the basin and the region. Finally, most of the species in the Chira basin lack categorization according to IUCN; therefore, we recommend categorizing mainly native species from the Chira River to avoid loss of fish diversity along the coastal rivers of Peru.
Citación
Meza-Vargas V, Faustino-Fuster DR, Marchena J, Faustino-Meza N, Ortega H. 2022. Fishes from Chira River basin, Piura, Peru. Revista peruana de biología 29(3): e21993 001 - 010 (Agosto 2022). doi: http://dx.doi. org/10.15381/rpb.v29i3.21993
Presentado: 13/01/2022
Aceptado: 25/07/2022
Publicado online: 29/08/2022
Editor: Leonardo Romero
Agradecimientos / Acknowledgments:
We are grateful to all people who kindly assisted in collecting and sorted samples: N. Lujan (AMNH), J. Armbruster, D. Werneke, C. Black (AUM); J. Espino, A. Cortijo, C. Bustamante, J. Garnillo (MUSM). For allowing us to use their live photos, we thank N. Lujan (Brycon atrocaudatus, Eretmobrycon peruanus, Lebiasina bimaculata) and W. Ohare (Andinoacara stalbergi). We are thankful to all anonymous reviewers for their valuable comments.
Conflicto de intereses / Competing interests:
The authors declare no conflict of interest.
Rol de los autores / Authors Roles:
VM-V: Conceptualización, Curacion de datos, Escritura- Preparación del borrador original, Redacción-revisión y edición.
DRF-F: Conceptualización, Curacion de datos, Redacción-revisión y edición.
JM: Conceptualización, Curacion de datos, Redacción-revisión y edición.
NF: Curacion de datos, Redacción-revisión y edición.
HO: Redacción-revisión y edición.
Fuentes de fínanciamiento / Funding:
El estudio fue financiado por el Vicerrectorado de Investigación y Posgrado de la Universidad Nacional Mayor de San Marcos, Lima, Perú. INCLAN Group Consulting (SBCC N°001-ANA-PMGRH BID 2015).
Aspectos éticos / legales; Ethics / legals:
Authors declare that they did not violate or omit ethical or legal norms in this research. All materials used belong to the Natural History Museums.
Literature cited
Abell R, Thieme ML, Revenga C, Bryer M, Kottelat M, Bogutskaya N, Coad B, Mandrak N, Balderas SC, Bussing W, Stiassny ML. 2008. Freshwater ecoregions of the world: a new map of biogeographic units for freshwater biodiversity conservation. BioScience, 58(5):403414. https://doi.org/10.1641/B580507
Albert JS, Destouni G, Duke-Sylvester SM, Magurran AE, Ober-dorff T, Reis RE, Kirk OW, Ripple WJ. 2020. Scientists' warning to humanity on the freshwater biodiver-sity crisis. Ambio, 1-10. https://doi.org/10.1007/ s13280-020-01318-8
Bonastre BM. 2008. Caracterización y distribución de la fauna íctica en la subcuenca del río Queiroz, Ayabaca (Perú). Proyecto de Final de Carrera. Barcelona: Universitat Autónoma de Barcelona. Facultat de Ciencies. 78 pp.
Birindelli J, Meza-Vargas V, Sousa L, Hidalgo M. 2016. Standardized Rapid Biodiversity Protocols: Freshwater Fishes. In: Larsen TH (Eds) Core Standardized Methods for Rapid Biological Field Assessment. Arlington: Conservation International, 127-138. https://www. conservation.org/docs/default-source/publicationpdfs/ci biodiversity handbook lowres.pdf
Dyer BS. 2003. Family Atherinopsidae (Neotropical Silversides). In: Reis RE, Kullander SO, Ferraris CJ (Eds) Check list of the Freshwater Fishes of South and Central America. Edipucrs, Porto Alegre, 515-525.
Eigenmann. 1922. The fishes of western South America, Part I. The fresh-water fishes of northwestern South America, including Colombia, Panama, and the Pacific slopes of Ecuador and Peru, together with an appendix upon the fishes of the Rio Meta in Colombia. Memoirs of the Carnegie Museum v. 9 (no. 1): 1-346, Pls. 1-38. https://doi.org/10.5962/p.234839
Fowler. 1945. Los peces del Perú. Catálogo sistemático de los peces que habitan en aguas peruanas. Lima, Perú. Museo de Historia Natural "Javier Prado" Universidad Nacional Mayor de San Marcos. 1-298.
Fricke R, Eschmeyer WN, Van der Laan R. 2020. Eschmeyer's catalog of fishes: genera, species, references. Electronic version accessed 12 Ene 2022. http://researcharchive.calacademy.org/research/ichthyology/ catalog/fishcatmain.asp
Llambí LD, Becerra MT, Peralvo M, Avella A, Baruffol M, Flores LJ. 2020. Monitoring Biodiversity and Ecosystem Services in Colombia's High Andean Ecosystems: Toward an Integrated Strategy. Mountain Research and Development, 39(3), A8. https://doi.org/10.1659/MRDJ0URNAL-D-19-00020.1
Lopez C, Brack, A, Dourojeanni, M. 1982. Evaluación de Impacto ecológico de la irrigación San Lorenzo (Piura, Perú). Zonas Áridas 2(1):1-22.
Lowe-McConnell RH. 1987. Ecological Studies in Tropical Fish Communities. Cambridge University Press, Cambridge, 536 pp. https://doi.org/10.1017/ CB09780511721892
Lucena CAS, Calegari BB, Pereira EHL, Dallegrave E. 2013. O uso de óleo de cravo na eutanásia de peixes. Boletim Sociedade Brasileira de Ictiología, 105:20-24.
Lujan NK, Roach KA, Jacobsen D, Winemiller KO, Meza-Vargas V, Rimarachin-Ching V, Maestre JA. 2013. Aquatic community structure across an Andes to Amazon fluvial gradient. Journal of Biogeography, 40(9):17151728. https://doi.org/10.1111/jbi.12131
Marchena J. 2013. Ictiofauna del río Chira y descripción de microhábitats. Tesis de título de Biólogo. Piura: Universidad Nacional de Piura. 82 pp.
Marceniuk AP, Marchena J, Oliveira C, Betancur-RR. 2019. Chinchaysuyoa, a new genus of the fish family Ariidae (Siluriformes), with a redescription of Chinchaysuyoa labiata from Ecuador and a new species description from Peru. Zootaxa, 4551(3):361-378. http://dx.doi.org/10.11646/zootaxa.4551.3.5
Meza-Vargas V, Faustino-Fuster D, Marchena J, Ortega H. 2019. Geographic distribution extension of Landonia latidens Eigenmann & Henn, 1914 (Characidae, Stevardiinae) in coastal drainages of Peru. Check List 15(5):851-855. https://doi.org/10.15560/15.5.851
MINAM. 2019. Definiciones Conceptuales de los ecosistemas del Peru. http://geoservidor.minam.gob.pe/informacion-institucional/publicaciones/
PRODUCE (28 de setiembre de 2018) Ministerio de la Producción inicia repoblamiento del recurso paiche en la región Piura. Recuperado https://www.gob.pe/ institucion/produce/noticias/19538-ministerio-dela-produccion-inicia-repoblamiento-del-recursopaiche-en-la-region-piura
More F. 2019. Análisis de consistencia de caudales del río Chira entre las presas de Poechos y Sullana. Tesis para optar el título de Ingeniero Civil. Universidad de Piura, Facultad de Ingeniería. Programa Académico de Ingeniería Civil. Piura 157 pp.
Ortega LMC. 2012. Sistematización y análisis de los resultados del monitoreo de la calidad de agua en la cuenca Catamayo Chira parte peruana. Autoridad Nacional del Agua. https://hdl.handle.net/20.500.12543/28
Ortega H, Guerra H, Ramírez R. 2007. The introduction of nonnative fishes into freshwater systems of Peru. In Bert, T. M. (Eds) Ecological and Genetic Implications of Aquaculture Activities. Methods and Technologies in Fish Biology and Fisheries, vol 6. Springer, Dordrecht, 247-278. 'https://doi.org/10.1007/978-1-40206148-6 14
Ortega H, Espino J, Valenzuela S, Valenzuela L, Armas M, Marchena J. 2015. Ríos y Arroyos Costeros Representativos del Perú: Caracterización, diversidad de la biota acuática y amenazas a la conservación. In: Lasso CA, Sánchez-Duarte P, Blanco-Libreros JF (Eds) XII. Cuencas pericontinentales de Colombia, Ecuador, Perú y Venezuela: Tipología; Biodiversidad; Servicios ecosistémicos y sostenibilidad de los ríos, quebradas y arroyos costeros. Instituto de Investigación de Recursos Biológicos Alexander von Humboldt, Bogotá, 379-395 http://hdl.handle. net/20.500.11761/31362
Ortega H, Hidalgo M. 2008. Freshwater fishes and aquatic habitats in Peru: Current knowledge and conservation. Aquatic Ecosystem Health & Management, 11(3):257271. https://doi.org/10.1080/14634980802319135
Primack RB. 1993. Essentials of Conservation Biology. Sinauer Associates Incorporated, Sunderland, Massachusetts, 564 pp.
Roberts TR. 1972. Ecology of fishes in the Amazon and Congo Basin. Bulletin of the Museum of Comparative Zoology 143(2):117-147.
Reis RE, Kullander SO, Ferraris-Jr CJ. 2003. Check list of the freshwater fishes of South and Central America. Edipucrs, Porto Alegre, 729 pp.
Reis RE, Albert JS, Di-Dario F, Mincarone MM, Petry P, Rocha LA. 2016. Fish biodiversity and conservation in South America. Journal of Fish Biology 89: 12-47. https:// doi.org/10.1111/jfb.13016
SOFIA, 2018. Autoridad Nacional del Agua (ANA). Ministerio de Agricultura y Riego, Perú. http://sofia.ana.gob. pe/public/
Simberloff D. 2000. Nonindigenous species-a global threat to biodiversity and stability. In: Smithsonian Institution (Eds), Nature and Human Society. Smithsonian Institution, Washington D.C., 325-334.
IUCN 2020. The IUCN Red List of Threatened Species. Version 2020-1. https://www.iucnredlist.org. Downloaded on 19 March 2020
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Abstract
Chira River is located on the north coast of Peru. The lack of knowledge of the ichthyofauna from coastal drainages from Peru is noteworthy. The aim of this study is to characterize the ichthyofauna along the Chira River basin in terms of diversity and altitudinal range distribution. The material examined belongs to the Ichthyological collection of the Natural History Museum (MUSM). The diversity of fishes is composed of 27 species belonging to 19 families and ten orders. Siluriformes and Characiformes were the most diverse, consisting of 22% (six species) for each one. Five species are new records for the Chira River (three natives and two non-natives). Six marine species and seven exotic species were recorded as well. The altitudinal distribution patterns for all species were registered. This study increases the known diversity of freshwater fishes from Pacific Drainage Rivers in Peru, and it could be used for management and conservation plans.