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Ciencias marinas

versión impresa ISSN 0185-3880

Cienc. mar vol.45 no.3 Ensenada sep. 2019  Epub 30-Jul-2021

https://doi.org/10.7773/cm.v45i3.2969 

Articles

Feeding habits of the Mexican barracuda, Sphyraena ensis Jordan and Gilbert, 1882, in the southeastern end of the Gulf of California

Hábitos alimentarios de la barracuda mexicana, Sphyraena ensis Jordan y Gilbert, 1882, en el extremo sureste del golfo de California

Xchel Gabriel Moreno-Sánchez1 
http://orcid.org/0000-0002-4376-1753

Deivis Samuel Palacios-Salgado2 
http://orcid.org/0000-0001-7804-1222

Jasmin Granados-Amores2 
http://orcid.org/0000-0003-4486-4399

Leonardo Andrés Abitia-Cárdenas1  * 

Ofelia Escobar-Sánchez3 
http://orcid.org/0000-0002-7841-0080

1Instituto Politécnico Nacional (IPN), Centro Interdisciplinario de Ciencias Marinas, Av. Instituto Politécnico Nacional, s/n, Col. Playa Palo de Santa Rita, CP 23096, La Paz, Baja California Sur, Mexico.

2Escuela Nacional de Ingeniería Pesquera, Universidad Autónoma de Nayarit, Bahía de Matanchén, km 12, Carretera a los Cocos, CP 63740, San Blas, Nayarit. Mexico.

3Universidad Autónoma de Sinaloa (UAS), Facultad de Ciencias del Mar (FACIMAR), Paseo Claussen S/N, Colonia Los Pinos, CP 82000, Mazatlán, Sinaloa, Mexico.


Abstract

Understanding the feeding habits of the Mexican barracuda, Sphyraena ensis Jordan and Gilbert, 1882, is important to elucidate relevant aspects of its trophic ecology (prey intake, diet breadth, trophic level, and energy flows), which in general provide valuable information on the dynamics of marine communities. Therefore, the purpose of this work was to assess the dietary habits of the Mexican barracuda, S. ensis, and to determine dietary variations by sex (males, females), size (small, medium, and large individuals), and season (rainy and dry). Monthly samples were obtained from February 2014 to January 2015 in the San Blas region, Nayarit, Mexico. A total of 308 specimens were captured. Individuals measured between 30.6 and 58.7 cm total length and weighed between 405 and 836 g. Of the analyzed stomachs, 264 (86%) contained food and 44 (14%) were empty. The diet of the Mexican barracuda comprised 13 prey items from 11 families, 12 genera, and 9 species. According to the index of relative importance, the most important prey were fishes, particularly Sardinops spp. (40.36%), Hemiramphus saltator (40.24%), Opisthopterus dovii (10.83%), Anchoa spp. (4.17%), and Mugil cephalus (3.05%). We conclude that the Mexican barracuda can be categorized as an opportunistic ichthyophagous predator in coastal epipelagic zones that feeds mainly on schooling fish species. The trophic spectrum did not vary significantly by sex or size, but the consumption of preferred prey varied significantly by season.

Key words: Sphyraenidae; pelagic predator; ichthyophagous; Sardinops spp.; Hemiramphus saltator

Resumen

El estudio de los hábitos alimentarios de la barracuda mexicana, Sphyraena ensis Jordan y Gilbert, 1882, es importante para conocer los aspectos relevantes de su ecología trófica (presas consumidas, amplitud de dieta, nivel trófico y flujos de energía), ya que brindan información valiosa sobre la dinámica de las comunidades marinas. En este contexto, el objetivo del presente trabajo fue determinar los hábitos alimentarios de la barracuda mexicana, S. ensis, así como las variaciones tróficas con respecto a sexo (machos, hembras), tallas (individuos pequeños, medianos y grandes) y estacionalidad (lluvias y secas). Se obtuvieron muestras mensuales durante el periodo de febrero de 2014 a enero de 2015 en la región de San Blas, Nayarit, México. En total se capturaron 308 organismos, con tallas de entre 30.6 y 58.7 cm de longitud total y pesos de entre 405 y 836 g. De los estómagos analizados, 264 (86%) contenían alimentos y 44 (14%) estaban vacíos. El espectro trófico de la barracuda mexicana se conformó de 13 tipos de presa, agrupadas en 11 familias, 12 géneros y 9 especies. De acuerdo con el índice de importancia relativa, las presas más importantes fueron los peces, particularmente Sardinops spp. (40.36%), Hemiramphus saltator (40.24%), Opisthopterus dovii (10.83%), Anchoa spp. (4.17%) y Mugil cephalus (3.05%). Con base en los resultados obtenidos, la barracuda mexicana puede categorizarse como un depredador ictiófago oportunista de la zona epipelágica costera que se alimenta, principalmente, de especies de peces que forman densos cardúmenes. Su espectro trófico no presentó variaciones significativas por sexo y talla, pero el consumo de las presas más importantes varió significativamente por estación.

Palabras clave: Sphyraenidae; depredador pelágico; ictiófago; Sardinops spp.; Hemiramphus saltator

Introduction

Barracudas (Sphyraenidae) are carnivorous predators that affect the behavior and recruitment of the species they prey on and, as such, function as regulators of fish communities in coastal areas (Barreiros et al. 2002, Hooker et al. 2007, Mohammadizadeh et al. 2010). There are 27 barracuda species worldwide, all belonging to one genus, Sphyraena (Nelson et al. 2016). There are 5 barracuda species in the Gulf of California: the Pacific barracuda (Sphyraena argentea Girard, 1854), the Mexican barracuda (Sphyraena ensis Jordan and Gilbert, 1882), the pelican barracuda (Sphyraena idiastes Heller and Snodgrass, 1903), the Cortés barracuda (Sphyraena lucasana Gill, 1863), and the blackfin barracuda (Sphyraena qenie Klunzinger, 1870) (Robertson and Allen 2015). The most abundant barracuda species in the southeastern end of the Gulf of California is the Mexican barracuda, S. ensis, a pelagic/neritic species that forms schools comprising several hundred individuals, although solitary individuals can also be found (Sommer 1995). Barracudas inhabit waters between 0 and 25 m deep, sandy, muddy bottoms, and rocky and coralline reefs near the coast (Sommer 1995, Robertson and Allen 2015).

The Mexican barracuda sustains a permanent fishery that is only interrupted during strong storms or hurricanes. This species is captured with several types of fishing gear (trolling lines, seine nets, gill nets, and handlines). Given the high quality of the flesh and low price, demand for this species is high in regional markets (Espino-Barr et al. 2003, Ulloa-Ramírez et al. 2008). Despite the ecological and economic importance of S. ensis, there is no published information on its basic ecology. Research on this species could include studies on food intake, diet composition, diet breadth, diet overlap, trophic levels, energetic physiology, and ecosystem-wide management (Pauly and Christensen 2000, Abitía-Cárdenas et al. 2002). All of these aspects can influence ecological characteristics such as growth, reproduction, and mortality of marine fish (Wootton 1998).

According to Zavala-Leal et al. (2018), previous biological studies on barracudas worldwide have mostly focused on feeding habits. Studies have included the trophic aspects of Sphyraena viridensis in the northeastern Atlantic Ocean (Barreiros et al. 2002), Sphyraena barracuda off Colombia (Hooker et al. 2007), Sphyraena putnamae in the Persian Gulf (Mohammadizadeh et al. 2010), and S. viridensis, Sphyraena sphyraena, and Sphyraena cryzotaenia in the Indo-Pacific Ocean (Kalogirou et al. 2012), among others. In Mexico, no studies on the trophic biology of the Mexican barracuda have been carried out. The only previous study was that of López-Peralta and Arcila (2002), who analyzed the stomach contents of 5 Mexican barracuda specimens caught in Colombian waters. These authors reported that Mexican barracuda fed on mainly nekton (fishes) and, in smaller portions, on zoobenthos (crustaceans).

In this context, we evaluated the dietary spectrum of the Mexican barracuda to determine possible diet variations with sex, size, and/or season. We provide basic information necessary to characterize the feeding interactions and, by extension, the role of this species in the energy flow of trophic webs in the coastal ecosystems of the southeastern end of the Gulf of California.

Materials and methods

Mexican barracuda specimens were obtained from the artisanal fishery in the San Blas region, Nayarit, Mexico (21º29′42.07″-21º26′47.47″N; 105º17′27.30″-105º13′43.88″W) (Fig. 1). Fish were caught at night (19:00 to 06:00) using 5- to 20-m-long weighted handlines and J-type hooks (numbers 6 and 7). It should be noted that S. ensis can be caught using other types of fishing gear; however, off the coast of Nayarit, barracudas are caught mainly with handlines at night and in the early hours of the morning. According to artisanal fishermen, barracudas are not available during the day.

Figure 1 Map showing the Mexican barracuda, Sphyraena ensis, sampling area (shaded area) off San Blas, Nayarit, Mexico. 

The habitat where organisms were captured is characterized by soft, sandy, muddy bottoms, with depths of 8.5-15.0 m. Sampling was carried out over an annual cycle (February 2014 to January 2015), catching approximately 30 fish per month. Specimens were frozen and transported to the Laboratorio de Ecología Trófica at the Escuela Nacional de Ingeniería Pesquera (Nayarit, Mexico), where biometric measurements (total length and weight with precision of 1 mm and 0.1 g, respectively) were taken and stomachs collected.

Stomach contents were separated by taxonomic group, and each item was identified to the lowest taxonomic level possible. Depending on the digestion state of prey, fish taxonomic identification was carried out using the keys by Clothier (1950), Miller and Jorgensen (1973), and Fischer et al. (1995a, b). Crustaceans and mollusks were identified using the keys by Brusca (1980) and Morris et al. (1980).

A species accumulation curve was created with the program EstimateS Swin820 (Colwell 2009) using the Shannon-Wiener diversity index (H′) value obtained for each stomach to determine the representativeness of the number of analyzed stomachs. The coefficient of variation (CV) was calculated to obtain a quantitative estimate of the number of stomachs representative of the diet. If the CV was equal to or less than 5% (0.05), the number of examined stomachs was considered adequate to represent the diet (Jiménez-Valverde and Hortal 2003, Moreno-Sánchez et al. 2015).

The frequency of occurrence (%FO), numerical (%N), and gravimetric (%W) percentages were calculated (Hyslop 1980) and used to estimate the index of relative importance (IRI) proposed by Pinkas et al. (1971) and modified by Hacunda (1981): IRI = (%N + %W) × %FO. To facilitate comparisons with previous studies, the standardized version of the index (%IRI) was also used (Cortés 1997): %IRIi=100IRIii=1 IRIIn.

In addition to the characterization of the general trophic spectrum, diets by sex (male or female), size, and season were also determined. Because size at maturity for the Mexican barracuda has not yet been determined and with the purpose of detecting a possible change in food intake (biomass) with size of organisms (total length), a cluster analysis was performed using the program Primer v.6.0. The results obtained when we “let the data speak” consisted of a series of groups without a defined pattern. These groups comprised different size records with no logical trend; that is, there was no increase in prey biomass intake with the increase in predator size. Considering the above and to simplify the ontogenetic analysis, 3 groups based on total length were created (Sturges’ rule, Daniel 1997): small (30-39 cm), medium (40-49 cm), and large (50-60 cm). In the case of the seasonal analysis, monthly precipitation over the study area was taken into account, and 2 seasons were identified: a rainy season from June to October and a dry season from November to May (CONAGUA 2013).

The breadth of the Mexican barracuda trophic spectrum was calculated with the absolute values of the numerical index using Levins’ standardized index of niche breadth (B i ) (Hurlbert 1978). Values for this index range from 0 to 1; values <0.6 indicate a diet that includes few prey items and corresponds to a specialist predator, and values >0.6 indicate that the diet includes several prey items and corresponds to a generalist predator (Krebs 1999). This index was calculated as Bi= 1n-11jPij2-1, where jPij2 is the proportion of the jth prey species in the diet of predator i, and n is the total number of prey species.

A scatter plot was constructed using the graphical method of Costello (1990) as modified by Amundsen et al. (1996) to interpret the Mexican barracuda’s feeding strategy. These authors distinguished 4 strategies: (1) specialization on different types of prey, (2) a more generalized diet with some individual variation in diet breadth, (3) specialization on one type of prey while occasionally consuming other species, and (4) a mixed foraging strategy in which some individuals consume a specialized diet and others employ a more generalized foraging strategy. The Costello method was used as a complementary technique to corroborate trophic niche breadth because it allows identifying patterns of population specialization or individual diet, and testing for significant differences in the diet.

In order to assess potential differences in the diet of the barracuda as a function of sex (male or female), size (small, medium, or large), season (dry or rainy), and possible interactions between factors, we applied a permutation analysis of variance (PERMANOVA, 1,000 permutations) to the obtained numerical data (N). The dissimilarity matrix used for the PERMANOVA test was constructed by calculating the Bray-Curtis dissimilarity distances matrix using the original data (no data transformation was used). Because some likelihood-based tests of differences in multivariate data can be sensitive to the heterogeneity of multivariate dispersion, we performed a PERMDISP analysis (Anderson 2006) to assess potential differences in dispersion among factors (sex, size, and season); PERMDISP can be used as a multivariate analogue of Levene’s test for homogeneity of variances (Anderson 2006, Oksanen et al. 2016). We used the betadisp and adonis functions for the PERMDISP and PERMANOVA tests, respectively, using a significance level of 95%; both functions belong to the Vegan package (v.2.4-1, Oksanen et al. 2016) in the R environment (R Core Team 2016).

The equation proposed by Cortés (1999) was used to determine the trophic level of the Mexican barracuda (TL k ), which considers the type of prey found in stomach contents: TLk=1+(j=111Pj × TLj, where TL j is the trophic level of the jth prey and P j is the proportion of each prey item in the diet. The trophic level of each prey item was obtained from Cortés (1999), López-García et al. (2012), and Froese and Pauly (2016). Numerical data were used for these analyses.

Results

A total of 308 Mexican barracuda were obtained, ranging between 30.6 and 58.7 cm total length and between 405 and 836 g. Of the analyzed stomachs, 264 (86%) contained food and 44 (14%) were empty. According to the CV (≤0.05), the prey species accumulation curve reached its asymptote at 85 stomachs, indicating that the total number of analyzed stomachs was adequate for the characterization of the feeding habits of the Mexican barracuda and the characterization of the diet by sex, size, and season (Fig. 2, Table 1).

Figure 2 Species accumulation curve of Sphyraena ensis prey. The upward arrow indicates the asymptote of the curve. H′, Shannon-Wiener diversity; HMax, maximum diversity; HMean, mean diversity; HMin, minimum diversity; and CV, coefficient of variation.  

Table 1 Minimum Sphyraena ensis sample size for all samples by sex, by size, and by season. Ns, number of analyzed stomachs; Nsm, minimum number of stomachs by category; CV, coefficient of variation for the respective sample size. 

Category Ns Nsm CV
General 264 85 0.05
Female 173 60 0.05
Male 91 50 0.05
Small 62 30 0.05
Medium 158 60 0.05
Large 44 28 0.05
Dry season 158 63 0.05
Rainy season 106 46 0.05

The diet of the Mexican barracuda comprised 13 prey items, including 9 fish, 2 squid, and 2 shrimp species, and unidentified fish remains. Stomach contents weighed 951.35 g in total and included 273 prey items, of which fishes comprised 885.00 g and 235 prey items. The most frequent species in the diet were the fishes Sardinops spp. (Hubbs, 1929) (26.8%, n = 73), Hemiramphus saltator (Gilbert and Starks, 1904) (25.7%, n = 71), and Opisthopterus dovii (Günther, 1868) (12.8%, n = 37). According to the %IRI, the most important prey species in the Mexican barracuda diet were the fishes Sardinops spp. (40.36%), H. saltator (40.24%), O. dovii (10.83%), Anchoa spp. (4.17%), and Mugil cephalus (3.05%) (Fig. 3a, Table 2).

Figure 3 3-D graphs showing trophic indices for prey consumed by Sphyraena ensis (number [abundance], weight [biomass], and frequency of occurrence). Data: general (a), males (b), females (c), small size (d), medium size (e), large size (f), dry season (g), rainy season (h). Abbreviations: Sar, Sardinops spp.; Hem, Hemiramphus saltator; Opd, Opisthopterus dovii; Anc, Anchoa spp.; Muc, Mugil cephalus; Lop, Lolliguncula panamensis; Hyp, Hyaloteuthis pelagica; Cac, Caranx caballus; Laa, Larimus argenteus; Lut, Lutjanus spp.; Otp, Other prey.  

Table 2 Absolute values, numerical percentage (%N), weight percentage (%W), frequency of occurrence percentage (%FO), index of relative importance (IRI), and trophic level (TL) for each food item in the diet of Sphyraena ensis

Species N %N W %W FO %FO IRI %IRI TL
Mollusca
Cephalopoda
Loliginidae
Lolliguncula panamensis 4 1.47 7.90 0.83 4 1.52 3.48 0.09 3.90
Ommastrephidae
Hyaloteuthis pelagica 1 0.37 5.20 0.55 1 0.38 0.35 0.01 3.20
Crustacea
Decapoda
Penaeidae
Penaeus spp. 1 0.37 1.30 0.14 1 0.38 0.19 0.01 2.70
Xyphopenaeus spp. 7 2.56 6.00 0.63 4 1.52 4.84 0.13 2.70
Vertebrata
Actinopterygii
Carangidae
Caranx caballus 5 1.83 17.20 1.81 4 1.52 5.51 0.15 3.40
Clupeidae
Sardinops spp. 73 26.74 272.21 28.61 71 26.89 1488.66 40.36
Engraulidae
Anchoa spp. 37 13.55 39.10 4.11 23 8.71 153.88 4.17 3.40
Mugilidae
Mugil cephalus 17 6.23 107.10 11.26 17 6.44 112.59 3.05 2.40
Hemiramphidae
Hemiramphus saltator 71 26.01 300.84 31.62 68 25.76 1484.40 40.24 3.60
Sciaenidae
Larimus argenteus 8 2.93 6.80 0.71 8 3.03 11.05 0.30 3.08
Lutjanidae
Lutjanus guttatus 2 0.73 5.00 0.53 2 0.76 0.95 0.03 3.55
Lutjanus spp. 10 3.66 3.80 0.40 8 3.03 12.31 0.33 3.55
Pristigasteridae
Opisthopterus dovii 37 13.55 166.10 17.46 34 12.88 399.40 10.83 3.25
Fish Remains 0 0 12.80 1.35 22 8.33 11.21 0.30
Total 273 100 951.35 100 264 3688.83 100

Of the 264 stomachs containing food, 91 were extracted from males and 173 from females. The male diet comprised 10 prey items, whereas the female diet included 13 items. According to the %IRI, the most important prey for both sexes were H. saltator and Sardinops spp. (Fig. 3b, c). There were no significant differences in trophic spectra between males and females (PERMANOVA F = 13.514, P > 0.05) (Table 3).

Table 3 Significance values obtained with the permutational multivariate analysis of variance between sizes, sexes, and seasons for Sphyraena ensis in the southeastern end of the Gulf of California. 

Factor F r P Significance
Size 14.468 0.00508 0.206 No
Sex 13.514 0.00474 0.229 No
Season 184.661 0.06481 0.001 Yes
Size-sex 0.794 0.00279 0.545 No
Size-season 10.969 0.00385 0.353 No
Sex-season 37.768 0.01325 0.004 Yes
Size-sex-season 20.078 0.00705 0.058 No

There were 62 small-sized specimens, which fed on 10 prey items. According to the %IRI, the most important prey in this group’s diet were the fishes H. saltator (48%), Sardinops spp. (24%), O. dovii (14%), Mugil cephalus (Linnaeus, 1758) (6%), Anchoa spp. (Jordan and Evermann, 1927) (5%), and other prey (0.84%) (Fig. 3d). There were 158 medium-sized fish, which fed on 12 prey items. The diet of this group comprised mainly fish, of which the most important, according to the %IRI, were H. saltator (51%), Sardinops spp. (35%), O. dovii (6%), Anchoa spp. (3%), M. cephalus (3%), and other prey (1.61%) (Fig. 3e). There were 44 large barracuda, which fed on 8 prey items. The most important prey in this group’s diet were Sardinops spp. (67%), O. dovii (21%), H. saltator (6%), Anchoa spp. (3%), and other prey (0.04%) (Fig. 3f). There were no significant differences in diets between size categories (PERMANOVA F = 14.468, P > 0.05) (Table 3).

A total of 158 stomachs collected in the dry season and 106 stomachs collected in the rainy season were analyzed. During the dry season, the diet comprised 10 prey items; according to the %IRI the most important prey were Sardinops spp. (71%), O. dovii (11%), Anchoa spp. (10%), and H. saltator (4%), and the remaining items comprised only 4% of the diet (Fig. 3g). During the rainy season, the diet comprised 8 items; the main prey, according to the %IRI, were H. saltator (84%), Sardinops spp. (5%), O. dovii (4%), M. cephalus (3%), and Lutjanus spp. (Bloch 1790) (1%) (Fig. 3h). Significant differences were observed between seasons (PERMANOVA F = 184.66, P < 0.05) and in the interactions between sex and season (PERMANOVA F = 14.488, P < 0.05) (Table 3). The dispersions of the Bray-Curtis dissimilarities were not statistically different for any of the analyzed factors (F: sex = 0.6537, size = 0.7452, season = 1.4383; P: sex = 0.4195, size = 0.4756, season = 0.2315).

The Mexican barracuda can be categorized as a specialist predator (B i = 0.34). This feeding behavior was consistent for males and females (males: B i = 0.37; females: B i = 0.36), for the 3 size intervals (small: B i = 0.38; medium: B i = 0.36; large: B i = 0.48), and for the 2 analyzed seasons (dry: B i = 0.41; rainy: B i = 0.39). The feeding strategy confirmed that the Mexican barracuda is a specialist predator (ichthyophagous) that consumes mainly the fishes H. saltator, Sardinops spp., Anchoa spp., O. dovii, M. cephalus, and Lutjanus spp. (Fig. 4). The trophic level calculated for S. ensis and for each sex was 4.1. Small-sized individuals occupied a trophic level of 4.0, medium-sized individuals a trophic level of 4.1, and large-sized individuals a trophic level of 4.0. The trophic level during the rainy season was 4.2, and during the dry season, it was 3.9.

Figure 4 Feeding strategy graph obtained with the Costello method. Prey-specific abundance (%N) and percentage frequency of occurrence (%F) in the general diet of Sphyraena ensis. Abbreviations: Sar, Sardinops spp.; Hem, Hemiramphus saltator; Opd, Opisthopterus dovii; Anc, Anchoa spp.; Muc, Mugil cephalus; Lop, Lolliguncula panamensis; Hyp, Hyaloteuthis pelagica; Pen, Penaeus spp.; Xyp, Xyphopenaeus spp.; Cac, Caranx caballus; Laa, Larimus argenteus; Lug, Lutjanus guttatus; Lut = Lutjanus spp. 

Discussion

Mexican barracuda fed mainly on the fishes Sardinops spp., H. saltator, O. dovii, and Anchoa spp. These are all small pelagic/neritic species that gather in schools and are distributed along the eastern Pacific Ocean, from Baja California, including the Gulf of California, to northern Peru and even Chile (Sommer 1995, Robertson and Allen 2015).

In general, evidence indicates that the 5 barracuda species found along the Pacific coast of Mexico play a similar ecological role within the limits of their geographical distribution, because the 5 species (S. ensis, S. argentea, S. lucasana, S. idiastes, and S. qenie) are carnivorous predators that feed mainly on small school-forming fish in the pelagic-neritic zone but can also consume benthic crustaceans and cephalopods (Sommer 1995, López-Peralta and Arcila 2002, Robertson and Allen 2015).

The Mexican barracuda has a specialist ichthyophagous feeding strategy. This type of strategy has been reported for S. viridensis, S. sphyraena, and Sphyraena chrysotaenia in the Mediterranean Sea (Kalogirou et al. 2012), for S. barracuda in the San Andrés Archipelago in Colombia (Hooker et al. 2007), and for Sphyraena guachancho in the Gulf of Mexico (Bedia-Sánchez et al. 2011).

No significant differences were detected between males and females or between sizes (small, medium, and large) in the diet of the Mexican barracuda due to the predominant consumption of the same fish species (Sardinops spp., H. saltator, O. dovii, Anchoa spp., and M. cephalus) in similar proportions. This trophic behavior indicated no feeding segregation by sex or size. However, large individuals fed on a larger proportion of Sardinops spp. These larger individuals probably have better search, attack, and capture abilities than smaller barracuda. Sardinops spp. are extremely abundant in the southern Gulf of California and in waters along the Pacific coast of Mexico (Fischer et al. 1995a).

According to the optimal foraging theory, feeding on small abundant fish would allow barracudas to obtain greater energetic benefits than they would feeding on large, less available prey that would represent greater energy expenditure during the search, capture, and consumption (Gerking 1994). It should be noted that the diet breadth of the Mexican barracuda increased with size, as larger barracuda also included demerso-pelagic prey in their diet (Carangidae, Lutjanidae, and Mugilidae). Kalogirou et al. (2012) also reported that the diet breadth of S. viridensis, S. sphyraena, and S. chrysotaenia increased with size, which could be related to improved predatory abilities as they grow.

Although results obtained in this study indicated a specialist feeding strategy, differences found in the diet of the Mexican barracuda between seasons reflected changes in the consumption of Sardinops spp. (84%) during the dry season and of H. saltator (71%) during the rainy season. This alternation of the main prey species could be related to the natural fluctuations in the populations of the prey species. Although no specific data on variations in prey abundance in the study area are available, it is probable that Mexican barracuda prey on the most abundant species in the pelagic-neritic zone, improving their chances of feeding success throughout the year. This would indicate that instead of being a specialist predator, the Mexican barracuda is an opportunistic ichthyophagous predator, with trophic plasticity that allows it to feed on available and abundant fish species. Bedia-Sánchez et al. (2011) and De Sylva (1963) reported that the barracudas S. guachancho and S. barracuda alternated the main food components in their diet according to environmental conditions, which affected the availability and abundance of prey species.

The trophic level calculated for the Mexican barracuda was 4.1. This is similar to what has been reported for other ichthyophagous predators with specialist tendencies, such as Xiphias gladius (Linnaeus, 1758) (4.5), Coryphaena hippurus (Linnaeus, 1758) (4.3), Fistularia commersonii (Rüppell, 1838) (4.3), Scomberomorus sierra (Jordan and Starks, 1895) (4.2), Thunnus albacares (Bonnaterre, 1788) (4.1), and Alectis ciliaris (Bloch, 1787) (4.0) (López-Peralta and Arcila 2002, Stergiou and Karpouzi 2002, Moreno-Sánchez et al. 2011, Tripp-Valdez et al. 2015, Froese and Pauly 2016, Alatorre-Ramirez et al. 2017), which also feed on school-forming pelagic fishes and on cephalopods and crustaceans. It should be noted that the Mexican barracuda is part of the same trophic guild and interacts with these species in the ecosystems of the southern Gulf of California, which suggests possible interspecific competition. However, it seems that the availability and abundance of small pelagic fishes that form large schools (families Engraulidae and Clupeidae) (Tripp-Valdez et al. 2015, Varela et al. 2017, Zambrano-Zambrano et al. 2019), in addition to the morphological differences of predators, allow these species to coexist without affecting their population densities (Cruz-Escalona et al. 2000, Moreno-Sánchez et al. 2015).

We conclude that the Mexican barracuda is an opportunistic ichthyophagous predator that does not present differences in its diet by sex or size, but it can change its preferred prey intake seasonally, depending the availability and abundance of its prey in the environment. This behavior, as stated in the optimal foraging theory, ensures optimization of the trade-off between consumption and energy use and, therefore, better bioenergetic performance.

Acknowledgments

All of the authors are grateful for the economic support provided by the Secretaría de Investigación y Posgrado-IPN (project no. 20150852), Secretaría de Educación Pública-Consejo Nacional de Ciencia y Tecnología (CONACYT, Mexico) (project no. 241486), and CONACYT (project no. 205024). XGMS and LAAC are grateful for the support received through the IPN Comisión de Operación y Fomento de Actividades Académicas and Estimulos al Desempeño de los Investigadores. OES thanks CONACYT for funding provided through the Cátedra CONACYT program, and FACIMAR-UAS. We appreciate the special collaboration of Dr. Emigdio Marín-Enríquez (CONACYT-FACIMAR-UAS), who helped with the statistical analysis, and the comments and suggestions of 2 anonymous reviewers. In memory of DSPS, an excellent researcher, colleague, and friend; rest in peace.

References

Abitía-Cárdenas LA, Muhlia-Melo A, Cruz-Escalona V, Galván-Magaña F. 2002. Trophic dynamics and seasonal energetics of striped marlin Tetrapturus audax in the southern Gulf of California, Mexico. Fish Res. 57(3): 287-295.https://doi.org/10.1016/S0165-7836(01)00350-2 [ Links ]

Alatorre-Ramirez VG, Galván-Magaña F, Torres-Rojas YE, Olson RJ. 2017. Trophic segregation of mixed schools of yellowfin tuna (Thunnus albacares) and skipjack tuna (Katsuwonus pelamis) caught in the eastern tropical Pacific Ocean. Fish. Bull. 115(2): 252-268. https://doi.org/10.7755/FB.115.2.11 [ Links ]

Amundsen PA, Gabler HM, Staldvik FJ. 1996. A new approach to graphical analysis of feeding strategy from stomach contents data-modification of the Costello (1990) method. J. Fish Biol. 48(4): 607-614. https://doi.org/10.1111/j.1095-8649.1996.tb01455.x [ Links ]

Anderson MJ. 2006. Distance-based tests for homogeneity of multivariate dispersions. Biometrics 62: 245-253. https://doi.org/10.1111/j.1541-0420.2005.00440.x [ Links ]

Barreiros JP, Santos RS, Borba AE. 2002. Food habits, schooling and predatory behaviour of the yellowmouth barracuda, Sphyraena viridensis (Perciformes: Sphyraenidae) in the Azores. Cybium 26: 83-88. [ Links ]

Bedia-Sánchez C, Franco-López J, Barrera-Escorcia H. 2011. Análisis de la relación peso-longitud, alimentación y maduración gonádica de Sphyraena guachancho Cuvier, 1829 (Sphyraenidae) en Playa Barrancas, Municipio de Alvarado, Veracruz. Rev. Zool. 22: 23-32. [ Links ]

Brusca RC. 1980. Common Intertidal Invertebrates of the Gulf of California. 2nd ed. Tucson (AZ): University of Arizona Press; 513 pp. [ Links ]

Clothier CR. 1950. A key to some southern California fishes based on vertebral characters. Calif. Dep. Fish and Game Fish Bull. 79: 1-83. [ Links ]

Colwell RK. 2009. EstimateS: Statistical Estimation of Species Richness and Shared Species from Samples. V.8.2. [Unknown]: [publisher unknown]; [accessed 2017 Jan 01]. http://viceroy.eeb.uconn.edu/estimatesLinks ]

[CONAGUA] Comisión Nacional del Agua (MX). 2013. Estadísticas del agua en México. Mexico City: CONAGUA; 165 pp. [ Links ]

Cortés E. 1997. A critical review of methods of studying fish feeding based on analysis of stomach contents: application to elasmobranch fishes. Can. J. Fish. Aquat. Sci. 54(3): 726-738. https://doi.org/10.1139/f96-316 [ Links ]

Cortés E.1999. Standardized diet compositions and trophic levels of sharks. ICES J. Mar. Sci. 56(5): 707-717. https://doi.org/10.1006/jmsc.1999.0489 [ Links ]

Costello MJ. 1990. Predator feeding strategy and prey importance: a new graphical analysis. J. Fish Biol. 36 (2): 261-263. https://doi.org/10.1111/j.1095-8649.1990.tb05601.x [ Links ]

Cruz-Escalona VH, Abitia-Cardenas LA, Campos-Dávila L, Galvan-Magaña F. 2000. Trophic interrelations of the three most abundant fish species from Laguna San Ignacio, Baja California Sur, Mexico. Bull. Mar. Sci. 66(2): 361-373. [ Links ]

Daniel WW. 1997. Bioestadística: Base para el Análisis de las Ciencias de la Salud. Mexico: Limusao; 878 pp. [ Links ]

De Sylva DP. 1963. Systematics and Life History of the Great Barracuda Sphyraena barracuda (Walbaum). Coral Gables (FL): University of Miami Press; 179 pp. [ Links ]

Espino-Barr E, Cruz-Romero M, García-Boa A. 2003. Peces marinos con valor comercial de la costa de Colima, México. Manzanillo (Colima, Mexico): CONABIO E INAPESCA; 106 pp. [ Links ]

Fischer W, Krupp F, Schneider W, Sommer C, Carpenter KE, Niem VH. 1995a. Guía FAO para la Identificación de Especies para los Fines de Pesca, Pacífico Centro-Oriental. Vol. 2, Vertebrados: Parte 1. Rome (Italy): Food and Agriculture Organization of the United Nations; pp. 647-1200. [ Links ]

Fischer W, Krupp F, Schneider W, Sommer C, Carpenter KE, Niem VH. 1995b. Guía FAO para la Identificación de Especies para los Fines de Pesca, Pacífico Centro-Oriental. Vol. 3, Vertebrados: Parte 2. Rome (Italy): Food and Agriculture Organization of the United Nations; pp. 1201-1813. [ Links ]

Froese R, Pauly D, editors. 2016. FishBase: World Wide Web electronic publication; [accessed 2017 March 10]. http://www.fishbase.orgLinks ]

Gerking SD. 1994. Feeding Ecology of Fish. USA: Academic Press; 416 pp. https://doi.org/10.1016/c2009-0-03283-8 [ Links ]

Hacunda JS. 1981. Trophic relationships among demersal fishes in a coastal area of the Gulf of Maine. Fish. Bull. 79(4): 775-788. [ Links ]

Hooker HB, Castro-González E, Howard AA, Quintero JA, Sanabria MP. 2007. Hábitos tróficos de la Gran Barracuda, Sphyraena barracuda (Walbaum, 1792) (Pisces: Perciformes: Sphyraenidae) en la Isla de San Andrés, Cayos Bolívar y Albuquerque, Reserva de la Biosfera Sea Flower = Food Habits of the Great Barricuda, Sphyraena barracuda (Walbaum, 1792) (Pisces: Perciformes: Sphyraenidae) on the Islands of San Andres, Cayos Bolivar, and Albuquerque Sea Flower BioReserve, Colombia. Proc. Gulf Caribb. Fish. Inst. 58: 208-215. [ Links ]

Hurlbert SH. 1978. The measurement of niche overlap and some relatives. Ecology 59(1): 67-77. https://doi.org/10.2307/1936632 [ Links ]

Hyslop EJ. 1980. Stomach contents analysis-a review of methods and their application. J. Fish Biol. 17(4): 411-429. https://doi.org/10.1111/j.1095-8649.1980.tb02775.x [ Links ]

Jiménez-Valverde A, Hortal J. 2003. Las curvas de acumulación de especies y la necesidad de evaluar la calidad de los inventarios biológicos. Rev. Iber. Aracnol. 8(31): 151-161. [ Links ]

Kalogirou S, Mittermayer F, Pihl L, Wennhage H. 2012. Feeding ecology of indigenous and non-indigenous fish species within the family Sphyraenidae. J. Fish. Biol. 80(7): 2528-2548. https://doi.org/10.1111/j.1095-8649.2012.03306.x [ Links ]

Krebs CJ. 1999. Ecological Methodology. Menlo Park (CA): Addison-Wesley Educational Publishers; 620 pp. [ Links ]

López-García J, Navia AF, Mejía-Falla PA, Rubio EA. 2012. Feeding habits and trophic ecology of Dasyatis longa (Elasmobranchii: Myliobatiformes): sexual, temporal and ontogenetic effects. J. Fish. Biol. 80(5): 1563-1579. https://doi.org/10.1111/j.1095-8649.2012.03239.x [ Links ]

López-Peralta RH, Arcila CAT. 2002. Diet composition of fish species from the southern continental shelf of Colombia. Naga, World Fish Center Quarterly 25(3-4): 22-29. [ Links ]

Miller GL, Jorgenson SC. 1973. Meristic characters of some marine fishes of the western Atlantic Ocean. Calif. Dep. Fish and Game Fish Bull. 71: 301-312. [ Links ]

Mohammadizadeh F, Valinassab T, Jamili S, Matinfar A. 2010. A study on diet composition and feeding habitats of sawtooth barracuda (Sphyraena putnamae) in Bandar-Abbas (North of Persian Gulf). J. fish. Aquat. Sci. 5(3): 179-190. https://doi.org/10.3923/jfas.2010.179.190 [ Links ]

Moreno-Sánchez XG, Palacios-Salgado DS, Abitia-Cárdenas LA, Nieto-Navarro JT, Navia FA. 2015. Diet of the yellowfin snook, Centropomus robalito (Actinopterygii: Perciformes: Centropomidae), in the southwestern Gulf of California. Acta. Ichthyol. Piscat. 45(1): 21-29. https://doi.org/10.3750/AIP2015.45.1.03 [ Links ]

Moreno-Sánchez XG, Quiñonez-Velázquez C, Abitia-Cárdenas LA, Rodríguez-Romero J. 2011. Diet of the Pacific sierra Scomberomorus sierra (Perciformes: Scombridae) in two areas of north-west Mexico coast. Aqua Int. J. Ichthyol. 17(4): 185-192. [ Links ]

Morris RH, Abbott DP, Haderlie EC. 1980. Intertidal Invertebrates of California. Stanford (CA): Stanford University Press; 690 pp. [ Links ]

Nelson JS, Grande TC, Wilson MVH. 2016. Fishes of the world. 5th Ed. Hoboken (NJ): John Wiley and Sons; 707 pp. [ Links ]

Oksanen J, Blanchet FG, Friendly M, Kindt R, Legendre P, McGlinn D, Minchin PR, O’Hara RB, Simpson GL, Solymos P, et al. 2016. Vegan: Community Ecology Package. v.2.4-1: R documentation. [Unknown]: [publisher unknown]; [accessed 2019 Feb 14] http://CRAN.R-project.org/package=veganLinks ]

Pauly D, Christensen V. 2000. Trophic ecology. In: Froese R, Pauly D (eds.), FishBase 2000: Concepts, design and data sources. Makati City (Philippines): International Center for Living Aquatic Resource Management; 344 pp. [ Links ]

Pinkas L, Oliphant MS, Iverson LK. 1971. Food habits of albacore, bluefin tuna, and bonito in California waters. Calif. Dep. Fish and Game Fish Bull. 152: 1-105. [ Links ]

R Core Team. 2016. R: A language and environment for statistical computing. Vienna (Austria): R Foundation for Statistical Computing. https://www.R-project.org/Links ]

Robertson DR, Allen GR. 2015. Shore fishes of the Tropical Eastern Pacific: online information system. v.2.0. Balboa (Panama): Smithsonian Tropical Research Institute; [accessed 2017 January 10]. http://biogeodb.stri.si.edu/sftep/en/pagesLinks ]

Sommer C. 1995. Sphyraenidae. Barracudas, picudas. In: Fischer W, Krupp F, Schneider W, Sommer C, Carpenter KE, Niem V. (eds.), Guia FAO para identificacion de especies para los fines de la pesca. Pacífico Centro-Oriental. Vol. 3, Vertebrados: Parte 2. Roma (Italia): Food and Agriculture Organization of the United Nations; pp. 1618-1621. [ Links ]

Stergiou KI, Karpouzi VS. 2002. Feeding habits and trophic levels of Mediterranean fish. Rev. Fish Biol. Fisher. 11(3): 217-254. https://doi.org/10.1023/A%3A1020556722822 [ Links ]

Tripp-Valdez A, Galván-Magaña F, Ortega-García S. 2015. Food sources of common dolphinfish (Coryphaena hippurus) based on stomach content and stable isotopes analyses. J. Mar. Biol. Assoc. UK. 95(3): 579-591. http://dx.doi.org/10.1017/S0025315414001842 [ Links ]

Ulloa-Ramírez PA, Patiño-Valencia JL, Guevara-Rascado ML, Hernández-Ventura S, Sánchez-Regalado R, Pérez-Velázquez A. 2008. Peces marinos de valor comercial del estado de Nayarit, México. Bahía de Banderas (Nayarit, México): Instituto Nacional de Pesca; 91 pp. [ Links ]

Varela JL, Lucas-Pilozo CR, González-Duarte MM. 2017. Diet of common dolphinfish (Coryphaena hippurus) in the Pacific coast of Ecuador. J. Mar. Biol. Assoc. UK. 97(1): 207-213. https://doi.org/10.1017/S0025315416000175 [ Links ]

Wootton RJ. 1998. Ecology of teleost fishes. 2nd Ed. Dordrecht (Holland): Kluwer Academic Publishers; 386 pp. [ Links ]

Zambrano-Zambrano RW, Mendoza-Moreira PE, Gómez-Zamora W, Varela JL. 2019. Feeding ecology and consumption rate of broadbill swordfish (Xiphias gladius) in Ecuadorian waters. Mar. Biodiv. 49(1): 373-380. https://doi.org/10.1007/s12526-017-0814-0 [ Links ]

Zavala-Leal I, Palacios-Salgado DS, Ruiz-Velazco JMJ, Valdez-González F, Pacheco-Vega JM, Granados-Amores J, Flores-Ortega JR. 2018. Reproductive aspects of Sphyraena ensis (Perciformes: Sphyraenidae) inhabiting the coast of San Blas Nayarit, southeast Gulf of California. Calif. Fish and Game 104(1): 7-18. [ Links ]

Received: February 01, 2019; Accepted: June 01, 2019

*Corresponding author. E-mail: laabitia@gmail.com

On behalf of all authors, the corresponding author states that there is no conflict of interest.

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