An osteometric approach to reconstruct the length and weight of Lutjanus argentiventris (Perciformes: Lujtanidae) for archaeological and ecological purposes

Martínez-Polanco, María Fernanda; Béarez, Philippe

doi:10.1590/1982-0224-2019-0106

ABSTRACT

Lutjanus argentiventris presents a large intertropical distribution within the Eastern Pacific, which is as important to fisheries now as it was in the pre-Hispanic period. The purpose of this article is to present an allometric model that enables the size and weight of L. argentiventris to be predicted, using the isolated bones found in archaeological and paleontological contexts or the stomach contents of ichthyophagous species. A modern collection of L. argentiventris from Ecuador was used, composed of 37 individuals covering a wide range of sizes and weights. The total length (TL), standard length (SL), and total fresh weight (W) of each individual was gathered. The TL of the sample ranged between 210 and 760 mm, the SL between 164 and 627 mm and the W ranged between 123 and 6550 g. The most frequent bones (15) and otoliths were chosen and 39 measurements were taken. The total length-weight relationship was W = 6E-06 TL^3.1513 with R ² = 0.997. In general, it was observed that the relationships between the TL and the bone measurements had a strong correlation (R² > 0.95). The allometric model will be useful not only for archaeologists but also for biologists working on historical ecology.

Keywords:
Allometry; Ichthyoarchaeology; Osteometry; Tropical Eastern Pacific; Length-weight relationship

RESUMEN

Lutjanus argentiventris presenta una distribución intertropical en el Pacífico Oriental, siendo una especie importante desde épocas prehispánicas hasta la actualidad. El propósito de este artículo es presentar un modelo alométrico que prediga la talla y el peso de L. argentiventris, usando restos óseos aislados encontrados en contextos arqueológicos y paleontológicos. Se empleó una colección de 37 individuos con tallas y pesos variados, provenientes del Ecuador. La longitud total (LT), la longitud estándar (LE) y el peso (P) de cada individuo fueron recolectados. La LT varió entre 210 y 760 mm, la LE entre 164 y 627 mm y el P entre 123 y 6550 g. Se escogieron los huesos más frecuentes (15) y los otolitos para realizar 39 mediciones. La relación de la longitud total y el peso fue P = 6E-06 TL^3,1513 con un valor de R ² = 0,997. En términos generales se observa que las relaciones entre la LT y las medidas de los huesos presentan una correlación fuerte (R² > 0,95). El modelo alométrico presentado puede utilizarse para predecir el tamaño y el peso, no sólo de L. argentiventris, sino también de sus congéneres, y será útil para arqueólogos y biólogos interesados en ecología histórica.

Palabras clave:
Alometría; Ictioarqueología; Osteometría; Pacífico Oriental Tropical; Relación longitud-peso

INTRODUCTION

The Lutjanidae family consists of 17 genera and 112 species, which are distributed in tropical and subtropical seas worldwide, but mostly in the Indo-Pacific (Fricke et al., 2020Fricke R, Eschmeyer W, Van Der Laan R. Eschmeyer’s Catalog of Fishes: Genera, Species, References [Internet]. 2020. Available from: http://researcharchive.calacademy.org/research/ichthyology/catalog/fishcatmain.asp
http://researcharchive.calacademy.org/re... ). The genus Lutjanus Bloch, 1790 is by far the most speciose, containing 73 species, including nine in the Eastern Pacific: Lutjanus aratus (Günther, 1864); L. argentiventris (Peters, 1869); L. colorado Jordan, Gilbert, 1882; L. guttatus (Steindachner, 1869); L. inermis (Peters, 1869), L. jordani (Gilbert, 1898); L. novemfasciatus Gill, 1862; L. peru Nichols, Murphy, 1922; and L. viridis (Valenciennes, 1846). The maximum total length (TL) of these species ranges between 300 mm (L. viridis) and 1700 mm (L. novemfasciatus) (Allen, 1985Allen GR. FAO Species Catalogue Vol. 6. Snappers of the world. An annotated and illustrated catalogue of lutjanid species known to date. FAO fish synop. 1985; 125(6)., 1995Allen GR. Lutjanidae. Pargos. In: Fischer W, Krupp F, Schneider W, Sommer C, Carpenter KE, Niem VH, editors. Guía FAO para la identificación de especies para los fines de la pesca Pacífico centro-oriental. Rome: FAO; 1995. p.1231-44.).

Snappers are important resources to artisanal and commercial fisheries worldwide, with the biggest catches in the Western Central Pacific and Western Central Atlantic (Allen, 1985Allen GR. FAO Species Catalogue Vol. 6. Snappers of the world. An annotated and illustrated catalogue of lutjanid species known to date. FAO fish synop. 1985; 125(6).; Salas et al., 2011Salas S, Chuenpagdee R, Charles A, Seijo JC. Coastal fisheries of Latin America and the Caribbean. Roma: FAO; 2011. 430p. Available from: http://www.fao.org/3/a-i1926e.pdf
http://www.fao.org/3/a-i1926e.pdf... ). In the Tropical Eastern Pacific (TEP), the catch is less, however L. argentiventris is an important species for small-scale fisheries (e.g.Alava et al., 2015Alava JJ, Lindop A, Jacquet J. Marine fisheries catch reconstructions for continental Ecuador: 1950-2010. Working Paper Series, Fisheries Centre, University of British Columbia, Vancouver. 2015:34.). In Mexico, the annual landings of the artisanal fleet have oscillated between 0.5 and 1.5 t (Espino-Barr et al., 2004Espino-Barr E, Cabral-Solís EG, García-Boa A, Puente-Gómez M. Especies marinas con valor comercial de la costa de Jalisco, México. Manzanillo: CRIP; 2004.). A long-term study (1983-1998) of artisanal marine fisheries in Colima, Mexico, shows that L. argentiventris is the seventh most abundant species in the region’s catches (Espino-Barr et al., 2002Espino-Barr E, Ruiz-Luna A, Arturo Garcia-Boa A. Changes in tropical fish assemblages associated with small-scale fisheries: a case study in the Pacific off central Mexico. Rev Fish Biol Fisher. 2002; 12:393-401. https://doi.org/10.1023/A:1025355102004
https://doi.org/10.1023/A:1025355102004... ). At Bahia de Navidad, Jalisco, Mexico, another study, covering 47 months (5 days per month in 1994-1995 / 1998-2000) reveals that ten species accounted for more than 60% of the total abundance and biomass, with L. argentiventris in eighth place (Rojo-Vázquez et al., 2008Rojo-Vázquez J, Quiñonez-Velázquez C, Echavarria-Heras H, Lucano-Ramírez G, Godínez-Domínguez E, Ruiz-Ramírez S, Galván-Piña V, Sosa-Nishizaki O. The fish species composition and variation of catch from the small-scale gillnet fishery before, during and after the 1997-1998 ENSO event, central Mexican Pacific. Rev Biol Trop. 2008; 56(1):133-52. https://doi.org/10.15517/rbt.v56i1.5513
https://doi.org/10.15517/rbt.v56i1.5513... ). In the southwestern Gulf of California, Mexico, L. argentiventris is among the eight most commercially important reef fishes (Erisman et al., 2010Erisman B, Mascarenas I, Paredes G, Sadovy de Mitcheson Y, Aburto-Oropeza O, Hastings P. Seasonal, annual, and long-term trends in commercial fisheries for aggregating reef fishes in the Gulf of California, Mexico. Fish Res. 2010; 106(3):279-88. https://doi.org/10.1016/j.fishres.2010.08.007
https://doi.org/10.1016/j.fishres.2010.0... ). It is normally captured using various types of craft nets, gillnets, harpoons, and hook-and-lines (Rojas et al., 2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... ; Lucano-Ramírez et al., 2014Lucano-Ramírez G, Ruiz-Ramírez S, González-Sansón G, Ceballos-Vázquez BP. Reproductive biology of the yellow snapper, Lutjanus argentiventris (Pisces, Lutjanidae), from the Mexican central Pacific. Ciencias Mar. 2014; 40(1):33-44.).

The archaeological record shows the importance of the species along the Pacific coast for millennia. In Mexico, archaeo-ichthyological samples from the site of Huatabampo (Sonora) exhibit high numbers (Number of identified specimens [NISP] = 106; Minimum number of individuals [MNI] = 10) of snappers (Lutjanus cf. argentiventris). The presence of this species suggests that the ancient inhabitants of Huatabampo were fishing in areas with a strong marine influence (Guzmán, 2008Guzmán AF. Archaeoichthyological analysis of two Mexican Pacific sites. Quat Int. 2008; 185(1):34-45. https://doi.org/10.1016/j.quaint.2007.09.033
https://doi.org/10.1016/j.quaint.2007.09... ). In Panama, snappers are present in the archaeological material of Cerro Mangote (Cooke, Ranere, 1999Cooke RG, Ranere AJ. Precolumbian fishing on the Pacific Coast of Panama. In Blake M, editor. Pacific Latin America in Prehistory: the evolution of archaic and formative cultures. Pullman: Washington University Press; 1999. p.103-21.) and, more commonly, in the Pearl Islands archipelago, in Pedro Gonzalez (Cooke, Jiménez, 2009Cooke RG, Jiménez-Acosta M. Fishing at pre-Hispanic settlements on the Pearl Island archipelago (Panama, Pacific), I: Pedro González Island (4030-3630 cal BCE). In: Makowiecki D, Hamilton-Dyer S, Riddler I, Trzaska-Nartowski N, Makohonienko M, editors. Proceedings of the 15th meeting of the Fish Remains Working Group of the International Council for Archaeozoology. Poznan; 2009. p.167-71.) and Bayoneta Island (Martínez-Polanco et al., 2009Martínez-Polanco MF, Jiménez-Acosta M, Cooke RG. Fishing at pre-Hispanic settlements on the Pearl Island Archipelago (Panama, Pacific), II: Bayoneta Island (900-1300CE). In: Makowiecki D, Hamilton-Dyer S, Riddler I, Trzaska-Nartowski N, Makohonienko M, editors. Proceedings of the 15th meeting of the Fish Remains Working Group of the International Council for Archaeozoology. Poznan. 2009. p.172-78.). Pre-Ceramic occupations at Pedro Gonzalez (4030-3630 BC) and Ceramic occupations at Bayoneta Island (ca. 900 and 1300 AD) fishing data suggest that snappers were taken with similar frequency during both time periods (Cooke, Jimenez-Acosta, 2009Cooke RG, Jiménez-Acosta M. Fishing at pre-Hispanic settlements on the Pearl Island archipelago (Panama, Pacific), I: Pedro González Island (4030-3630 cal BCE). In: Makowiecki D, Hamilton-Dyer S, Riddler I, Trzaska-Nartowski N, Makohonienko M, editors. Proceedings of the 15th meeting of the Fish Remains Working Group of the International Council for Archaeozoology. Poznan; 2009. p.167-71.; Martínez-Polanco et al., 2009Martínez-Polanco MF, Jiménez-Acosta M, Cooke RG. Fishing at pre-Hispanic settlements on the Pearl Island Archipelago (Panama, Pacific), II: Bayoneta Island (900-1300CE). In: Makowiecki D, Hamilton-Dyer S, Riddler I, Trzaska-Nartowski N, Makohonienko M, editors. Proceedings of the 15th meeting of the Fish Remains Working Group of the International Council for Archaeozoology. Poznan. 2009. p.172-78.). Snappers are evenly distributed in low numbers in Ecuadorian sites (e.g.Béarez, 1996Béarez P. Comparaison des ichtyofaunes marines actuelle et holocène et reconstitution de l’activité halieutique dans les civilisations précolombiennes de la côte du Manabí Sud (Équateur). [PhD Thesis]. Paris: Muséum national d´histoire naturelle; 1996.; Béarez et al., 2012Béarez P, Gay P, Lunniss R. Sea Fishing at Salango (Manabí Province, Ecuador) During the Middle Formative Machalilla Phase. Lat Am Antiq. 2012; 23(2):195-214. https://doi.org/10.7183/1045-6635.23.2.195
https://doi.org/10.7183/1045-6635.23.2.1... ).

Just as the weight increases with the size of the fish, bone size also increases with body size. The growth rate of each body part varies depending on species ontogeny and morphology (Teissier, 1948Teissier G. La relation d’allométrie. Sa signification statistique et biologique. Biometrics. 1948; 4(1):14-53.). In archaeology, fish body size and weight are used to study human diet, and to infer on fishing strategies and techniques, human exploitation and the overexploitation of fish faunas (e.g.Reitz et al., 1987Reitz EJ, Quitmyer IR, Hale HS, Scudder SJ, Wing ES. Application of Allometry to Zooarchaeology. Am Antiq . 1987; 52(2):304-17. https://www.jstor.org/stable/281782
https://www.jstor.org/stable/281782... ; Lambrides, Weisler, 2015Lambrides ABJ, Weisler MI. Applications of vertebral morphometrics in Pacific Island archaeological fishing studies. Archaeol Ocean. 2015; 50(2):53-70. https://doi.org/10.1002/arco.5059
https://doi.org/10.1002/arco.5059... ; Thieren, Van Neer, 2016Thieren E, Van Neer W. New equations for the size reconstruction of sturgeon from isolated cranial and pectoral girdle bones. Int J Osteoarchaeol . 2016; 26(2):203-10. https://doi.org/10.1002/oa.2407
https://doi.org/10.1002/oa.2407... ; Prestes-Carneiro, Béarez, 2017Prestes-Carneiro G, Béarez P. Swamp-Eel (Synbranchus spp.) Fishing in Amazonia from Pre-Columbian to Present Times. J Ethnobiol. 2017; 37(3):380-97. https://doi.org/10.2993/0278-0771-37.3.380
https://doi.org/10.2993/0278-0771-37.3.3... ; Lidour et al., 2018Lidour K, Vorenger J, Béarez P. Size and weight estimations of the spangled emperor (Teleostei: Lethrinidae: Lethrinus nebulosus) from bone measurements elucidate the fishing grounds exploited and ancient seasonality at Akab (United Arab Emirates). Int J Osteoarchaeol. 2018; 28(6):681-94. https://doi.org/10.1002/oa.2683
https://doi.org/10.1002/oa.2683... ; Rurua et al., 2020Rurua VA, Béarez P, Hermann A, Conte E. Length and weight reconstruction of Chlorurus microrhinos (Scaridae) from isolated cranial bones and vertebrae. Cybium. 2020; 44(1): 61-68. https://doi.org/10.26028/cybium/2020-441-008
https://doi.org/10.26028/cybium/2020-441... ). In particular, some aspects of fishing can be studied in depth: (1) changes in the geographic ranges of species, (2) reductions in their abundances, (3) signatures of trophic cascades and (4) marine fisheries trophic level changes (Erlandson, Rick, 2010Erlandson J, Rick T. Archaeology Meets Marine Ecology: The Antiquity of Maritime Cultures and Human Impacts on Marine Fisheries and Ecosystems. Annu Rev Mar Sci. 2010; 2:231-51. https://doi.org/10.1146/annurev.marine.010908.163749
https://doi.org/10.1146/annurev.marine.0... ).

On the other hand, Karachle, Stergiou (2012Karachle P, Stergiou K. Morphometrics and Allometry in Fishes. In: Wahl C, editor. Morphometrics [Internet]. 2012. p.65-86. Available from: http://www.intechopen.com/books/morphometrics/morphometrics-and-allometry-in-fishes
http://www.intechopen.com/books/morphome... ) summarize the importance of length-weight models in three aspects of modern ecology studies: (1) use of length data as an estimation of biomass; (2) to ascertain the condition of the species; and (3) to compare the life history of different populations of the same species. In fisheries management, the weight and the size of fish are used to estimate population parameters, life history characteristics and to develop programs for the protection and management of the species (Castellanos-Galindo, Zapata-Padilla, 2019Castellanos-Galindo G, Zapata-Padilla LA. Small-Scale fisheries on the Pacific coast of Colombia: historical context, current situation, and future challenges. In: Salas S, Barragán-Paladines MJ, Chuenpagdee R, editors. Viability and sustainability of small-scale fisheries in Latin America and The Caribbean. Gewerbestrasse: Springer International Publishing AG; 2019. p.79-100.). This kind of information could be used to determine the minimum permissible lengths of capture and identification of suitable periods for a closed fishing season. The identification of age-classes and male to female ratios are relevant to evaluate the status of an exploited stock and to establish future harvest levels, and the relationship between fish-size and its life-history traits and habitats (Castellanos-Galindo, Zapata-Padilla, 2019Castellanos-Galindo G, Zapata-Padilla LA. Small-Scale fisheries on the Pacific coast of Colombia: historical context, current situation, and future challenges. In: Salas S, Barragán-Paladines MJ, Chuenpagdee R, editors. Viability and sustainability of small-scale fisheries in Latin America and The Caribbean. Gewerbestrasse: Springer International Publishing AG; 2019. p.79-100.; Froese, Pauly, 2019Froese R, Pauly D. FishBase. World Wide Web electronic publication. Available from: http://www.fishbase.org version (08/2019).
http://www.fishbase.org... ).

In modern fisheries, the concept of baseline is understood as the fish population that was present before human influence (Pauly, 1995Pauly D. Anecdotes and the shifting baseline syndrome of fisheries. Trends Ecol Evol. 1995; 10(10):430. https://doi.org/10.1016/S0169-5347(00)89171-5
https://doi.org/10.1016/S0169-5347(00)89... ). This author addresses the shifting baseline syndrome, but this can only be resolved by developing a pre-industrial baseline that extends beyond the origins of modern fishing, both artisanal and commercial (Froyd, Willis, 2008Froyd CA, Willis KJ. Emerging issues in biodiversity & conservation management: The need for a palaeoecological perspective. Quat Sci Rev. 2008; 27(17-18):1723-32. https://doi.org/10.1016/j.quascirev.2008.06.006
https://doi.org/10.1016/j.quascirev.2008... ; Betts et al., 2011Betts MW, Maschner HDG, Clark DS. Zooarchaeology of the “Fish that stops” using archaeofaunas to construct long-term time series of Atlantic and Pacific cod populations. In: Moss ML, Cannon A, editors. The archaeology of North Pacific fisheries. Fairbanks: University of Alaska Press; 2011. p.171-95., 2014Betts MW, Noël S, Tourigny E, Burns M, Pope PE, Cumbaa SL. Zooarchaeology of the historic cod fishery in Newfoundland and Labrador, Canada. JONA. 2014; 24:1-21.; Barrett, 2019Barrett JH. An environmental (pre)history of European fishing: past and future archaeological contributions to sustainable fisheries. J Fish Biol. 2019; 94(6):1033-44. https://doi.org/10.1111/jfb.13929
https://doi.org/10.1111/jfb.13929... ). Baselines should not assume static environments but rather dynamic systems (Rick, Lockwood, 2012Rick TC, Lockwood R. Integrating paleobiology, archeology, and history to inform biological conservation. Conserv Biol. 2012; 27(1):45-54. https://doi.org/10.1111/j.1523-1739.2012.01920.x
https://doi.org/10.1111/j.1523-1739.2012... ). It is in this point where zooarchaeology and particularly ichthyoarchaeology can contribute with information to manage modern fisheries (Betts et al., 2011Betts MW, Maschner HDG, Clark DS. Zooarchaeology of the “Fish that stops” using archaeofaunas to construct long-term time series of Atlantic and Pacific cod populations. In: Moss ML, Cannon A, editors. The archaeology of North Pacific fisheries. Fairbanks: University of Alaska Press; 2011. p.171-95., 2014Betts MW, Noël S, Tourigny E, Burns M, Pope PE, Cumbaa SL. Zooarchaeology of the historic cod fishery in Newfoundland and Labrador, Canada. JONA. 2014; 24:1-21.; Barrett, 2019Barrett JH. An environmental (pre)history of European fishing: past and future archaeological contributions to sustainable fisheries. J Fish Biol. 2019; 94(6):1033-44. https://doi.org/10.1111/jfb.13929
https://doi.org/10.1111/jfb.13929... ). Fish size comparison between modern, historical and archaeological data could be used to regulate marine protected areas and to propose clear conservation objectives. For example, if archaeological data are used as baselines, new indicators could be proposed, and compared over time. Similarly, reference levels of objectives, thresholds or limits could be developed to inform the management of marine resources and ecosystems (Schwerdtner-Máñez et al., 2014Schwerdtner-Máñez K, Holm P, Blight L, Coll M, MacDiarmid A, Ojaveer H, Poulsen B, Tullet M. The Future of the oceans past: towards a global marincssse historical research initiative. PLoS ONE . 2014; 9(7): e101466. https://doi.org/10.1371/journal.pone.0101466
https://doi.org/10.1371/journal.pone.010... ). At the same time, it could determine the absolute magnitude of the changes that can occur in a heavily exploited fish stock. Analysis of long-term trends in fish size can provide a key indicator of changes in ecological baselines (Betts et al., 2011Betts MW, Maschner HDG, Clark DS. Zooarchaeology of the “Fish that stops” using archaeofaunas to construct long-term time series of Atlantic and Pacific cod populations. In: Moss ML, Cannon A, editors. The archaeology of North Pacific fisheries. Fairbanks: University of Alaska Press; 2011. p.171-95., 2014Betts MW, Noël S, Tourigny E, Burns M, Pope PE, Cumbaa SL. Zooarchaeology of the historic cod fishery in Newfoundland and Labrador, Canada. JONA. 2014; 24:1-21.; Barrett, 2019Barrett JH. An environmental (pre)history of European fishing: past and future archaeological contributions to sustainable fisheries. J Fish Biol. 2019; 94(6):1033-44. https://doi.org/10.1111/jfb.13929
https://doi.org/10.1111/jfb.13929... ). Other contributions of the study of the archaeological fish size are to measure fluctuations in the aquatic environment and the intensity of exploitation (Betts et al., 2011, 2014; Barrett, 2019Barrett JH. An environmental (pre)history of European fishing: past and future archaeological contributions to sustainable fisheries. J Fish Biol. 2019; 94(6):1033-44. https://doi.org/10.1111/jfb.13929
https://doi.org/10.1111/jfb.13929... ).

In this article, the attention will focus on the yellow snapper, L. argentiventris, which has a subtropical distribution, ranging in the Eastern Pacific from southern California to northern Peru, including the Galapagos Islands (Allen, 1985Allen GR. FAO Species Catalogue Vol. 6. Snappers of the world. An annotated and illustrated catalogue of lutjanid species known to date. FAO fish synop. 1985; 125(6).) (Fig. 1). The species is found in coral and rocky reefs at a depth range of 3-60 m and also in estuaries and river mouths, being tolerant to freshwater. It is characterized by a pinkish red colour of the anterior part of the body, which becomes bright orange to yellow in its posterior part. The fins are mainly yellow or orange. The yellow snapper is an active predator, feeding mainly at night on fish, shrimp, crabs and mollusks (Allen, 1985Allen GR. FAO Species Catalogue Vol. 6. Snappers of the world. An annotated and illustrated catalogue of lutjanid species known to date. FAO fish synop. 1985; 125(6).). Individuals can form small aggregations during the day or shelter in caves. The species also form seasonal spawning aggregations, a trait that makes many species vulnerable to overfishing (Sala et al., 2003Sala E, Aburto-Oropeza O, Paredes G, Thompson G. Spawning aggregations and reproductive behavior of reef fishes in the Gulf of California. Bull Mar Sci. 2003; 72:103-21.). The species has been recorded up to a TL of 760 mm and a maximum weight (W) of 6550 g (Béarez, 1996Béarez P. Comparaison des ichtyofaunes marines actuelle et holocène et reconstitution de l’activité halieutique dans les civilisations précolombiennes de la côte du Manabí Sud (Équateur). [PhD Thesis]. Paris: Muséum national d´histoire naturelle; 1996.: 44). For Gorgona Island in Colombia, Rojas et al. (2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... ) reported that the average size at sexual maturity was 515 mm TL and that the length-weight relationships were not significantly different between sexes. In the case of the central Mexican Pacific, the size range at sexual maturity was 260-330 mm for females and 240-320 mm for males (Lucano-Ramírez et al., 2014Lucano-Ramírez G, Ruiz-Ramírez S, González-Sansón G, Ceballos-Vázquez BP. Reproductive biology of the yellow snapper, Lutjanus argentiventris (Pisces, Lutjanidae), from the Mexican central Pacific. Ciencias Mar. 2014; 40(1):33-44.).

FIGURE 1
| Lutjanus argentiventris geographical distribution (Map adapted from Robertson, Allen, 2015Robertson DR, Allen GR. Shorefishes of the Tropical Eastern Pacific: online information system [Internet]. Smithsonian Tropical Research Institute. 2015. Available from: https://biogeodb.stri.si.edu/sftep/es/pages
https://biogeodb.stri.si.edu/sftep/es/pa... ; Image represents a 645 mm TL individual).

Our purpose is to present an allometric model that enables the length and weight of Lutjanus argentiventris to be predicted, using the isolated bones from archaeological and paleontological contexts or the stomach contents of ichthyophagous species. Length-weight relationships for L. argentiventris can be found for Mexico (González et al., 2004González-Acosta AF, De la Cruz Agüero G, De la Cruz Agüero J. Length-weight relationships of fish species caught in a mangrove swamp in the Gulf of California (Mexico). J Appl Ichthyol . 2004; 20(2):154-55. https://doi.org/10.1046/j.1439-0426.2003.00518.x
https://doi.org/10.1046/j.1439-0426.2003... ; Aburto-Oropeza et al., 2009Aburto-Oropeza O, Dominguez-Guerrero I, Cota-Nieto J, Plomozo-Lugo T. Recruitment and ontogenetic habitat shifts of the yellow snapper (Lutjanus argentiventris) in the Gulf of California. Mar Biol. 2009; 156(12):2461-72. https://doi.org/10.1007/s00227-009-1271-5
https://doi.org/10.1007/s00227-009-1271-... ; García-Contreras et al., 2009García-Contreras OE, Quiñónez-Velázquez C, Morán-Angulo RE, Valdez-Pineda MC. Age, growth, and age structure of amarillo snapper off the Coast of Mazatlán, Sinaloa, Mexico. N Am J Fish Manag. 2009; 29(1):223-30. https://doi.org/10.1577/M06-025.1
https://doi.org/10.1577/M06-025.1... ; Piñón et al., 2009Piñón A, Amezcua F, Duncan N. Reproductive cycle of female yellow snapper Lutjanus argentiventris (Pisces, Actinopterygii, Lutjanidae) in the SW Gulf of California: Gonadic stages, spawning seasonality and length at sexual maturity. J Appl Ichthyol . 2009; 25(1):18-25. https://doi.org/10.1111/j.1439-0426.2008.01178.x
https://doi.org/10.1111/j.1439-0426.2008... ; Velázquez-Velázquez et al., 2009Velázquez-Velázquez E, Navarro Alberto J, Domínguez Cisneros SE, Vega Cendejas ME. Length-weight relationships for 24 fish species in a coastal lagoon of the Mexican South Pacific. J Appl Ichthyol . 2009; 25(2):228-29. https://doi.org/10.1111/j.1439-0426.2008.01199.x
https://doi.org/10.1111/j.1439-0426.2008... ), Panama (Bonilla-Gómez et al., 2014Bonilla-Gómez JL, Robles YA, Vega AJ. Length-weight relationship and biological information of the yellow snapper Lutjanus argentiventris from a tropical estuary: Río caté, Gulf of Montijo, Panama. J Appl Ichthyol. 2014; 30(1):227-29. https://doi.org/10.1111/jai.12258
https://doi.org/10.1111/jai.12258... ) and Colombia (Rojas et al., 2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... ) but not for Ecuador. As there is no information available for the southernmost part of the range of L. argentiventris, it is useful to check whether this relationship is similar or different from those already known in more northern countries. Rojas et al. (2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... ) reported that the species is moderately slow growing, appears to be long-lived and has a low natural mortality rate, making it easily vulnerable to overfishing. It is therefore important to build osteometric models that could be used for in-depth long-term studies of L. argentiventris populations, with the aim of proposing management strategies.

MATERIAL AND METHODS

All the skeletons came from the fish collection of the Muséum national d’histoire naturelle in Paris. The modern collection of Lutjanus argentiventris is composed of 37 individuals covering a wide range of sizes and weights: 36 are from Ecuador and one is from Panama. The TL of the sample ranged between 210 and 760 mm, and the SL between 164 and 627 mm. The W ranged between 123 and 6550 g. The fish from Ecuador (MNHN-ICOS-1776 to -1811) were sampled between 1992 and 1998 in the vicinity of Puerto López (Fig. 1) mostly over rocky reefs, and using harpoons. The specimen from Panama (MNHN-ICOS-1812) was sampled at Isla del Rey (Pearl Island Archipelago) in 2000. All individuals have complete information about their total length (TL) and standard length (SL), which were recorded in millimeters (mm), and their total fresh weight (W) in grams (g).

Specimens from other Lutjanus species were also used, such as: L. novemfasciatus (n = 3); L. colorado (n = 1); L. peru (n = 1); L. guttatus (n = 4) and L. argentimaculatus (n = 1). These specimens were also collected from the same locations and at the same time period as L. argentiventris, except for the last one which comes from Kenya (Indian Ocean). For this study, all the specimens were used, including the Panamanian specimen and the other species individuals, to test the model. We included other species because in the archaeological record it is sometimes very difficult to arrive at a species level determination, at times we only succeed to determine the genus, which is quite often the case within the genus Lutjanus (e.g.Guzmán, 2008Guzmán AF. Archaeoichthyological analysis of two Mexican Pacific sites. Quat Int. 2008; 185(1):34-45. https://doi.org/10.1016/j.quaint.2007.09.033
https://doi.org/10.1016/j.quaint.2007.09... ).

Among the most frequently preserved bones in the archaeological archives, 15 were selected, 39 measurements were taken, and otoliths were included (Tab. 1, Fig. 2). Measuring points were chosen in such a way that they had a good probability of being found among archaeological remains; for this reason, the slender and fragile parts were discarded and the robust parts were preferred (Desse, 1984Desse J. Propositions pour une réalisation collective d’un corpus: fiches d’identification et d’exploitation métrique du squelette des poissons. In: Desse-Berset N, editor. 2èmes rencontres d’archéo-ichtyologie. Notes et Monographies Techniques. Valbonne: CRA-CNRS; 1984. p.67-86.). The measurements were taken using a digital caliper with a precision of two decimal points. Following convention, the left side bones were measured. However, in the case of the otoliths, both sagittae (left and right) were measured and a two-sample (paired samples) t-test was performed in order to identify eventual differences between sides (the null hypothesis being that the means of two populations are equal).

FIGURE 2
| Lutjanus argentiventris bone measurements.

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TABLE 1
| Lutjanus argentiventris bone measurements descriptions (see also ).

An allometric regression model was employed to determine the length-length and length-weight relationships for the L. argentiventris collection. This model assumes that the growth of each body part is relative to its total body length and weight, but with distinct growth rates (Teissier, 1948Teissier G. La relation d’allométrie. Sa signification statistique et biologique. Biometrics. 1948; 4(1):14-53.; Reitz et al., 1987Reitz EJ, Quitmyer IR, Hale HS, Scudder SJ, Wing ES. Application of Allometry to Zooarchaeology. Am Antiq . 1987; 52(2):304-17. https://www.jstor.org/stable/281782
https://www.jstor.org/stable/281782... ; Marean et al., 2001Marean CW, Abe Y, Nilssen PJ, Stone EC. Estimating the minimum number of skeletal elements (MNE) in zooarchaeology: a review and a new image-analysis GIS approach. Am Antiq. 2001; 66(2):94-98. https://doi.org/10.2307/2694612
https://doi.org/10.2307/2694612... ). The length-weight relationship is represented by a power function:

$Y = {a X}^{b}$

Where “Y” is the total weight of the fish, “X” is the total length, “a” a constant and “b” the allometric coefficient. To create this model, we also used 11 more specimen data (TL, SL, W) measured in Ecuador from fresh fishes that could not be preserved. The total sample was 48 (37 collected and preserved fishes + 11 fresh fishes not preserved).

In the case of the length-length relationships the same function was used; however, “Y” is the total length, and “X” is the body part measurement. The quality of the relationship is given by the coefficient of determination (R ² ). The best fitted measurements allowed us to reliably estimate the length and the weight of the fish from its isolated bones.

Desse et al. (1989Desse J, Desse-Berset N, Rocheteau M. Les profils rachidiens globaux. Reconstitution de la taille des poissons et appréciation du nombre minimal d’individus à partir des pièces rachidiennes. Rev paléobiol. 1989; 8(1):89-94.) proposed to establish Global Rachidian Profiles (GRP) to identify the position of the vertebrae along the spine. This approach is really helpful in archaeological cases where the vertebrae are the most common element. At the same time, by knowing the height of an archaeological vertebra it is possible to estimate the size of an individual. To construct the GRP of L. argentiventris, four individuals with different sizes were selected, and measurements were taken on the caudal (diameters M1 and M2) and ventral faces (M3) of the vertebrae (Tab. 1, Fig. 2).

RESULTS

The total length-weight relationships reflected a slight allometric growth (b = 3.1513), with a high coefficient of determination (R ² = 0.997) (Tab. 2, Fig. 3).

FIGURE 3
| Total length (TL) to weight relationship of the modern sample of Lutjanus argentiventris.

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TABLE 2
| Lutjanus argentiventris length to length and length to weight equation parameters (Length in mm and weight in g) (n = 37).

In general, it was observed that the relationships had a strong correlation (R² > 0.95) (see Tab. 1, Fig. 2 for bone measurements). The measurements relating to the maximal length of the element were well correlated with the TL. However, other measurements, based on small parts of the bones, which are the most frequently preserved, were also well correlated (see Fig. 4 for other Lutjanus species and the Panamanian specimen).

FIGURE 4
| Examples of Lutjanus argentiventris graphs modelling the regression formulae. A. Dentary (Dn1); B. Maxilla (M1); C. Premaxilla (Pmx1); D. Hyomandibula (Hm2); E. Preopercle (Pop1) and F. Quadrate (Qd3).

Regarding the GRP, four M2 profiles from four individuals are represented in Fig. 5A, and profiles for the M1, M2 and M3 of a single individual are represented in Fig. 5B. In both figures, two main zones could be distinguished: the anterior zone from vertebrae 1 to 7, and the posterior zone from vertebrae 8 to 24. The anterior zone is more heterogeneous while the posterior zone is more homogeneous.

FIGURE 5
| Global Rachidian Profiles of Lutjanus argentiventris. A. Measurement 2 of four Lutjanus argentiventris individuals (TL = 384 mm; TL = 509 mm; TL = 625 mm; TL = 760 mm). B. Measurements 1, 2 and 3 of one Lutjanus argentiventris individual (TL = 509 mm).

In the case of the otoliths, it was observed that the exponent of the allometric equation was superior to 1 (Tab. 2). This implies that they grow more slowly than the rest of the body. There were no significant differences between the length, height and weight of the right and left otoliths (Tab. 3).

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TABLE 3
| Lutjanus argentiventris otholith measurements.

Some degree of similarity was observed between the “b” values of the length-weight relationship obtained in this study and those from previous studies from Mexico, Panama and Colombia (Tab. 4). These results indicate that Lutjanus argentiventris has a similar, often isometric, growth all along its range.

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TABLE 4
| Lutjanus argentiventris total length to weight equation parameters from Mexico, Panama and Colombia (*data in cm were transformed into mm).

The tests made using other species of the same genera (Fig. 4) showed that the model could be used, at least in some instances, at genus level without much distortion. This is an important issue when dealing with Lutjanus species from other geographic areas. With regards the GRP profiles, the similar M2 values of the vertebrae of the posterior zone (Fig. 5) allowed us to use their measurement without knowing their exact rank in the rachis, which is often difficult to determine with isolated caudal vertebrae.

The otoliths on both sides can be used to estimate the size of the fish (Tab. 3).

DISCUSSION

The relationships between bone measurements and body-length were robust (Tab. 2), which makes us confident that they can be used with archaeological samples. Also, it is interesting to point out that the model also works with small fish, such as the 109 mm TL Panamanian specimen (Fig. 4). Such applications have already been carried out and have shown their interest. This is notably the case of recent studies in the fresh waters of South America (Peña-León, 2011Peña-León GA. Pescadores de los raudales del río magdalena durante el periodo formativo tardío. CALDASIA. 2011; 33(2):295-314. Available from: https://revistas.unal.edu.co/index.php/cal/article/view/36391/38010
https://revistas.unal.edu.co/index.php/c... , 2013Peña-León GA. Pescadores de los raudales del río Magdalena durante el período Formativo Tardío (Siglos V al I a.C.). Bogotá: Universidad Nacional de Colombia; 2013.; Prestes-Carneiro et al., 2019Prestes-Carneiro G, Beárez P, Pearl Shock M, Prümers H, Jaimes Betancourt C. Pre-Hispanic fishing practices in interfluvial Amazonia: Zooarchaeological evidence from managed landscapes on the Llanos de Mojos savanna. PLoS ONE. 2019; 14(5): e0214638. https://doi.org/10.1371/journal.pone.0214638
https://doi.org/10.1371/journal.pone.021... ) or in the marine waters of the Persian Gulf (Yeomans, 2015Yeomans L. Size estimation of kingsoldier bream (Argyrops spinifer) and evidence of fishing strategies. Int J Osteoarchaeol . 2015; 26(5):799-807. https://doi.org/10.1002/oa.2481
https://doi.org/10.1002/oa.2481 ... ; Lidour et al., 2018Lidour K, Vorenger J, Béarez P. Size and weight estimations of the spangled emperor (Teleostei: Lethrinidae: Lethrinus nebulosus) from bone measurements elucidate the fishing grounds exploited and ancient seasonality at Akab (United Arab Emirates). Int J Osteoarchaeol. 2018; 28(6):681-94. https://doi.org/10.1002/oa.2683
https://doi.org/10.1002/oa.2683... ).

However, this kind of study is not frequent in Latin American archaeological literature of despite its great informative potential. The study of the body length of the archaeological L. argentiventris could provide information on where the specimens were captured, depending on their size, and on ancient fishing techniques. The early life stages of L. argentiventris are found in mangroves, estuaries or shallow bays, which provide them with food and protection from large predators; adults then move to the outer rocky reefs where they continue to grow (Rojas et al., 2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... ). With this in mind, small-sized archaeological fish are expected to have been captured in mangroves, or at least close inshore, while larger fish came from deeper waters. The proportion of juveniles to adults can also provide information about fishing grounds and/or the health of nurseries and, beyond that, mangroves. However, these inferences should be accepted with caution because different populations of the same species may present different life history characteristics (e.g.Rojas et al., 2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
http://dx.doi.org/10.4067/S0717-71782004... , Lucano-Ramírez et al., 2014Lucano-Ramírez G, Ruiz-Ramírez S, González-Sansón G, Ceballos-Vázquez BP. Reproductive biology of the yellow snapper, Lutjanus argentiventris (Pisces, Lutjanidae), from the Mexican central Pacific. Ciencias Mar. 2014; 40(1):33-44.), and direct interpolation with the past could be risky. Ancient size data obtained from archaeological material could be helpful in modern ecological studies and fisheries management, given that such information could provide insight into: (1) the long-term effects of human activities on fisheries and aquatic ecosystems; (2) the acceleration and geographical extension of these effects over time; (3) the distribution and ecology of past fish populations (Erlandson, Rick, 2010Erlandson J, Rick T. Archaeology Meets Marine Ecology: The Antiquity of Maritime Cultures and Human Impacts on Marine Fisheries and Ecosystems. Annu Rev Mar Sci. 2010; 2:231-51. https://doi.org/10.1146/annurev.marine.010908.163749
https://doi.org/10.1146/annurev.marine.0... ).

The allometric model presented here can be used to predict the size and weight, not only of L. argentiventris, but also of its congeners, using isolated bones found in archaeological and paleontological contexts or the stomach contents of piscivorous species. This model could be useful not only for archaeologists but also for biologists working in historical ecology.

ACKNOWLEDGMENTS

The authors wish to thank Héctor Parrales, Cruz Elías Pincay, Enrique Toro, Johnny Vera and the numerous other fishermen who helped to obtain the fish. The Institut français d’études andines (IFEA) provided financial support to the second author. Thanks to Jill Cucchi for the copy-editing, to María del Pilar Martínez Polanco for preparing the map, and to the reviewers and to the editor for their valuable comments

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Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003
» http://dx.doi.org/10.4067/S0717-71782004000200003
Rojo-Vázquez J, Quiñonez-Velázquez C, Echavarria-Heras H, Lucano-Ramírez G, Godínez-Domínguez E, Ruiz-Ramírez S, Galván-Piña V, Sosa-Nishizaki O. The fish species composition and variation of catch from the small-scale gillnet fishery before, during and after the 1997-1998 ENSO event, central Mexican Pacific. Rev Biol Trop. 2008; 56(1):133-52. https://doi.org/10.15517/rbt.v56i1.5513
» https://doi.org/10.15517/rbt.v56i1.5513
Rurua VA, Béarez P, Hermann A, Conte E. Length and weight reconstruction of Chlorurus microrhinos (Scaridae) from isolated cranial bones and vertebrae. Cybium. 2020; 44(1): 61-68. https://doi.org/10.26028/cybium/2020-441-008
» https://doi.org/10.26028/cybium/2020-441-008
Sala E, Aburto-Oropeza O, Paredes G, Thompson G. Spawning aggregations and reproductive behavior of reef fishes in the Gulf of California. Bull Mar Sci. 2003; 72:103-21.
Salas S, Chuenpagdee R, Charles A, Seijo JC. Coastal fisheries of Latin America and the Caribbean. Roma: FAO; 2011. 430p. Available from: http://www.fao.org/3/a-i1926e.pdf
» http://www.fao.org/3/a-i1926e.pdf
Schwerdtner-Máñez K, Holm P, Blight L, Coll M, MacDiarmid A, Ojaveer H, Poulsen B, Tullet M. The Future of the oceans past: towards a global marincssse historical research initiative. PLoS ONE . 2014; 9(7): e101466. https://doi.org/10.1371/journal.pone.0101466
» https://doi.org/10.1371/journal.pone.0101466
Thieren E, Van Neer W. New equations for the size reconstruction of sturgeon from isolated cranial and pectoral girdle bones. Int J Osteoarchaeol . 2016; 26(2):203-10. https://doi.org/10.1002/oa.2407
» https://doi.org/10.1002/oa.2407
Teissier G. La relation d’allométrie. Sa signification statistique et biologique. Biometrics. 1948; 4(1):14-53.
Velázquez-Velázquez E, Navarro Alberto J, Domínguez Cisneros SE, Vega Cendejas ME. Length-weight relationships for 24 fish species in a coastal lagoon of the Mexican South Pacific. J Appl Ichthyol . 2009; 25(2):228-29. https://doi.org/10.1111/j.1439-0426.2008.01199.x
» https://doi.org/10.1111/j.1439-0426.2008.01199.x
Yeomans L. Size estimation of kingsoldier bream (Argyrops spinifer) and evidence of fishing strategies. Int J Osteoarchaeol . 2015; 26(5):799-807. https://doi.org/10.1002/oa.2481
» https://doi.org/10.1002/oa.2481

ADDITIONAL NOTES

6
Martínez-Polanco MF, Béarez P. An osteometric approach to reconstruct the length and weight of Lutjanus argentiventris (Perciformes: Lutjanidae) for archaeological and ecological purposes. Neotrop Ichthyol. 2020; 18(3):e190106. https://doi.org/10.1590/1982-0224-2019-0106

Edited by

Fernando Gibran

Data availability

Data citations

Fricke R, Eschmeyer W, Van Der Laan R. Eschmeyer’s Catalog of Fishes: Genera, Species, References [Internet]. 2020. Available from: http://researcharchive.calacademy.org/research/ichthyology/catalog/fishcatmain.asp

Froese R, Pauly D. FishBase. World Wide Web electronic publication. Available from: http://www.fishbase.org version (08/2019).

Publication Dates

Publication in this collection
04 Sept 2020
Date of issue
2020

History

Received
07 Sept 2019
Accepted
10 June 2020

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

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» https://doi.org/10.15517/rbt.v56i1.5513

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» https://doi.org/10.26028/cybium/2020-441-008

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» http://www.fao.org/3/a-i1926e.pdf

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» https://doi.org/10.1002/oa.2407

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» https://doi.org/10.1111/j.1439-0426.2008.01199.x

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» https://doi.org/10.1002/oa.2481

Measurement	Abbrev.	Description
Vomer M1	Vo M1	Maximal mediolateral width of the vomer
Basioccipital M1	Boc M1	Maximal width of the articular surface of the basioccipital
Basioccipital M2	Boc M2	Maximal height of the articular surface of the basioccipital
Premaxilla M1	Pmx M1	Maximal length of the premaxilla
Premaxilla M2	Pmx M2	Rostro-caudal length of the basis of combined ascending and articular processes
Premaxilla M3	Pmx M3	Thickness of the ascending process at mid-height distance from the lower part of the symphysis to the coronid fossa
Dentary M1	Dn M1	Maximal length, from the rostral tip of the dentary to the caudal tips of the coronoid and ventral processes
Dentary M2	Dn M2	Height of the symphysis
Dentary M3	Dn M3	Maximal width of the rostral extremity
Maxilla M1	Mx M1	Maximal length of the maxilla, from the rostral tip of the external process to the tip of the caudal processes
Maxilla M2	Mx M2	Maximal width of the dorsal condyle
Maxilla M3	Mx M3	Medio-lateral width at posterior level of the dorsal process
Anguloarticular M1	Ang M1	Maximal length between the line joining the quadrate facet and the post-articular process and the rostral tip of the anterior process
Anguloarticular M2	Ang M2	Distance between the cranio-ventral tip and the little notch situated between the quadrate facet and the post-articular process
Anguloarticular M3	Ang M3	Maximal width of the quadrate facet
Quadrate M1	Qd M1	Distance between the tip of the mesial condyle and the tip of the preopercular process
Quadrate M2	Qd M2	Distance between the ventral tip of the mesial condyle and the dorsal tip of the ectopterygoid margin
Quadrate M3	Qd M3	Distance between the external tip of the lateral condyle and the internal tip of the mesial condyle
Palatine M1	Pal M1	Maximal length of the palatine, Dorso-ventral diameter of the anterior (maxillary) process (M3)
Palatine M2	Pal M2	Distance between the recess situated in the condyle coiling and the cranial tip of the maxilla process
Palatine M3	Pal M3	Distance between the median recess of the dorsal edge and the posteroventral base of the anterior (maxillary) process (M2)
Hyomandibula M1	Hm M1	Distance between the symplectic facet and the line joining the tips of the sphenotic and pterotic facets
Hyomandibula M2	Hm M2	Distance between the sphenotic facet and the opercular process
Hyomandibula M3	Hm M3	Distance between the ventral bases of the pterotic facet and the opercular process
Preopercle M1	Pop M1	Maximal length of the preopercle
Preopercle M2	Pop M2	Distance between the anterior margin and the median notch of the posterior margin
Preopercle M3	Pop M3	Maximal thickness of the quadrate crest
Opercle M1	Op M1	Distance from the supra-articular process to the ventral extremity of the opercle
Opercle M2	Op M2	Height of the articular fossa
Opercle M3	Op M3	Cranio-caudal length of the articular fossa
Post-temporal M1	Ptp M1	Distance between the tip of the dorsal process and the articular facet
Post-temporal M2	Ptp M2	Distance between the tip of the ventral process and the articular facet
Supracleithrum M1	Spcl M1	Maximal length of the supracleithrum
Supracleithrum M2	Spcl M2	Maximal thickness of the supracleithrum in its median part
Cleithrum M1	Cl M1	Maximal length of the cleithrum
Cleithrum M2	Cl M2	Distance between the tip of the anterodorsal process and the scapula joint
Cleithrum M3	Cl M3	Width of the cleithrum at level of the posterodorsal notch
Otolith sagitta M1	Oto M1	Maximal length (rostro-caudal axis)
Otolith sagitta M2	Oto M2	Maximal height (dorso-ventral axis)

Body element	Measurement	n	Mean	SD	Min.	Max.	Relationship	a	b	R	r2
Standard length		48	362.27	133.58	164.00	627.00	TL vs. SL	0.84110	17.71600	0.998	0.999
Total length		48	451.75	160.01	210.00	760.00	W vs. TL	0.00001	3.15130	0.997	0.999
Weight		47	1902.43	1794.05	123.00	6550.00	W vs. SL	0.00003	3.00870	0.996	0.998
Vomer	1	34	12.86	4.91	6.52	25.33	vo M1 vs. TL	36.46500	0.94810	0.980	0.990
Basioccipital	1	35	3.66	1.46	1.78	8.21	boc M1 vs. TL	127.57000	0.89530	0.906	0.952
Basioccipital	2	35	7.17	3.46	3.37	16.73	boc M2 vs. TL	89.47600	0.77720	0.965	0.982
Premaxilla	1	36	30.77	12.27	15.84	61.97	pm M1 vs. TL	16.45600	0.93400	0.995	0.998
	2	36	9.36	4.18	4.58	20.53	pm M2 vs. TL	60.46500	0.85200	0.981	0.991
	3	36	7.10	3.61	2.78	17.71	pm M3 vs. TL	94.61600	0.74790	0.956	0.978
Dentary	1	36	32.23	12.01	16.80	63.02	dn M1 vs. TL	13.06600	0.98690	0.996	0.998
	2	36	6.77	3.08	3.22	14.35	dn M2 vs. TL	85.51900	0.81810	0.986	0.993
	3	36	19.41	7.03	10.40	33.19	dn M3 vs. TL	20.21900	1.00760	0.979	0.989
Maxilla	1	36	35.05	13.95	17.85	71.75	mx M1 vs. TL	14.30200	0.93920	0.996	0.998
	2	36	5.22	2.46	2.23	11.69	mx M2 vs. TL	111.30000	0.78710	0.984	0.992
	3	36	6.78	2.78	3.54	15.48	mx M3 vs. TL	68.77500	0.92470	0.968	0.984
Anguloarticular	1	35	36.35	13.11	18.80	66.73	ar M1 vs. TL	10.52800	1.01500	0.995	0.997
	2	35	12.97	4.95	6.27	23.11	ar M2 vs. TL	35.52900	0.94980	0.985	0.992
	3	35	5.97	2.99	2.68	15.26	ar M3 vs. TL	101.64000	0.78360	0.984	0.992
Quadrate	1	36	24.05	8.77	12.53	45.31	qd M1 vs. TL	16.23600	1.00900	0.994	0.997
	2	36	20.41	8.70	10.28	41.48	qd M2 vs. TL	28.70700	0.87800	0.988	0.994
	3	36	6.63	2.94	3.32	14.36	qd M3 vs. TL	79.06500	0.86520	0.987	0.994
Palatine	1	36	26.87	10.26	13.89	52.15	pl M1 vs. TL	16.88700	0.96390	0.994	0.997
	2	36	5.78	2.47	2.87	12.51	pl M2 vs. TL	86.18100	0.88170	0.963	0.981
	3	36	1.59	0.81	0.75	3.62	pl M3 vs. TL	290.91000	0.74100	0.924	0.961
Hyomandibula	1	36	33.54	13.34	17.14	67.32	hm M1 vs. TL	14.95100	0.93840	0.993	0.996
	2	36	18.10	7.35	8.96	36.47	hm M2 vs. TL	28.66100	0.91400	0.992	0.996
	3	36	12.96	5.17	6.32	25.86	hm M3 vs. TL	41.47900	0.88100	0.949	0.974
Preopercle	1	36	57.29	22.37	29.12	112.08	pop M1 vs TL	8.85350	0.94350	0.997	0.998
	2	36	12.55	5.27	6.70	24.74	pop M2 vs. TL	42.64300	0.88920	0.951	0.975
	3	36	2.98	1.55	1.40	7.39	pop M3 vs. TL	183.24000	0.73870	0.941	0.970
Opercle	1	36	34.70	14.59	17.27	68.15	op M1 vs. TL	17.21400	0.89060	0.990	0.995
	2	36	5.26	2.38	2.32	12.17	op M2 vs. TL	100.66000	0.84070	0.962	0.981
	3	36	4.72	1.93	2.54	9.39	op M3 vs. TL	97.03600	0.91910	0.958	0.979
Post-temporal	1	36	21.31	8.26	11.16	40.22	ptp M1 vs. TL	21.78000	0.95400	0.989	0.994
Post-temporal	2	36	14.13	4.85	6.71	23.75	ptp M2 vs. TL	28.24000	1.00140	0.968	0.984
Supracleithrum	1	35	31.09	11.75	15.99	57.79	scl M1 vs. TL	14.71700	0.96450	0.989	0.995
Supracleithrum	2	35	2.52	1.04	1.29	5.01	scl M2 vs. TL	177.00000	0.89950	0.964	0.982
Cleithrum	1	35	70.36	28.67	35.02	139.09	cl M1 vs. TL	8.42960	0.91150	0.996	0.998
	2	35	34.80	14.07	16.82	68.10	cl M2 vs. TL	15.79000	0.91510	0.988	0.994
	3	35	9.12	3.04	5.14	17.04	cl M3 vs. TL	37.12200	1.07600	0.892	0.944
Otolith sagitta	1	30	11.53	2.80	7.26	17.53	oto M1 vs. TL	12.52300	1.41320	0.963	0.981
Otolith sagitta	2	30	6.59	1.87	3.85	11.08	oto M2 vs. TL	37.20100	1.25850	0.975	0.987

Measurement	Side	n	Mean	t	p
Length	right	30	11.36	-0.0352	0.9721
Length	left	30	11.36	-0.0352	0.9721
Height	right	30	6.48	-0.4224	0.6758
Height	left	30	6.50	-0.4224	0.6758
Weight	right	30	0.16	2.17E-15	1
Weight	left	30	0.16	2.17E-15	1

Reference	Country	a	b
García-Contreras et al. (2009García-Contreras OE, Quiñónez-Velázquez C, Morán-Angulo RE, Valdez-Pineda MC. Age, growth, and age structure of amarillo snapper off the Coast of Mazatlán, Sinaloa, Mexico. N Am J Fish Manag. 2009; 29(1):223-30. https://doi.org/10.1577/M06-025.1 https://doi.org/10.1577/M06-025.1... )*	Mexico	0.0000126	3.03
Piñón et al. (2009Piñón A, Amezcua F, Duncan N. Reproductive cycle of female yellow snapper Lutjanus argentiventris (Pisces, Actinopterygii, Lutjanidae) in the SW Gulf of California: Gonadic stages, spawning seasonality and length at sexual maturity. J Appl Ichthyol . 2009; 25(1):18-25. https://doi.org/10.1111/j.1439-0426.2008.01178.x https://doi.org/10.1111/j.1439-0426.2008... )*	Mexico	0.0000087	3.10
Bonilla-Gómez et al. (2014Bonilla-Gómez JL, Robles YA, Vega AJ. Length-weight relationship and biological information of the yellow snapper Lutjanus argentiventris from a tropical estuary: Río caté, Gulf of Montijo, Panama. J Appl Ichthyol. 2014; 30(1):227-29. https://doi.org/10.1111/jai.12258 https://doi.org/10.1111/jai.12258... )*	Panama	0.0000103	3.07
Rojas et al. (2004Rojas PA, Gutiérrez CF, Puentes V, Villa AA, Rubio EA. Aspectos de la biología y dinámica poblacional del pargo coliamarillo Lutjanus argentiventris en el Parque Nacional Natural Gorgona, Colombia. Investig Mar. 2004; 32(2):23-36. http://dx.doi.org/10.4067/S0717-71782004000200003 http://dx.doi.org/10.4067/S0717-71782004... )	Colombia	0.0000063	3.12
This study	Ecuador	0.0000060	3.15

Brasil

Brasil

An osteometric approach to reconstruct the length and weight of Lutjanus argentiventris (Perciformes: Lujtanidae) for archaeological and ecological purposes

ABSTRACT

RESUMEN

INTRODUCTION

MATERIAL AND METHODS

RESULTS

DISCUSSION

ACKNOWLEDGMENTS

REFERENCES

ADDITIONAL NOTES

Edited by

Data availability

Data citations

Publication Dates

History