Miguel Ángel Puerto scite author profile

Black hake, Merluccius polli and M. senegalensis, are demersal species that inhabit the continental shelf and upper slope off Morocco, Mauritania, and Senegal, and are targeted by Spanish trawlers and bottom longliners. Merluccius senegalensis generally occurs at shallower depths than M. polli, although both species share a wide bathymetric range. Due to their external resemblance and overlapping occurrence at certain depths, both species are mixed in catches and are commonly marketed as Merluccius spp. From 2003 to 2009 biological samplings were performed in Mauritanian waters for numerous specimens of M. polli and M. senegalensis during 15 commercial fishing trips, seven experimental longline surveys, and three trawl surveys carried out within the black hake depth range and mainly during their reproductive periods. Data sets for 1334 fishing stations were thus gathered. The georeferenced macroscopic analysis of the female-assigned maturity stages was combined with the monthly evolution of the gonadosomatic index and with the time series of roe landings from 1984 to 2006 to determine the potential spawning areas, depths, and seasons for both species, showing an intense spawning period from November to February. Size at first maturity was estimated for both species in separate spawning periods and was higher for M. polli females (44 cm) than for M. senegalensis females (39 cm). Sex ratios were also determined by length classes (1 cm) for the experimental survey data and were analyzed according to fishing gear and latitude. The results showed a general predominance of females throughout the depths explored, both for M. polli (1:1.7) and M. senegalensis (1:1.5). Histological samples of ovaries and spawning progression data were jointly analyzed and indicated an apparent spawning delay for the deeper hake, M. polli (October), in comparison with the shallower hake, M. senegalensis (September).

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Contrasting energy allocation strategies of two sympatric Merluccius species in an upwelling system

Rey

Fernández-Peralta

Quintanilla

et al. 2015

Journal of Fish Biology

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This study investigated the somatic growth and energy allocation strategy of two sympatric hake species (Merluccius polli and Merluccius senegalensis), coexisting under the strong influence of the Mauritanian upwelling. The results revealed that ontogeny, bathymetry, geography and reproduction shaped the differences found between the condition dynamics of the two species. Aside from species-specific differences, individuals were observed in better condition in the northernmost area (more influenced by the permanent upwelling) and in the deepest waters, probably the most favourable habitat for Merluccius spp. Both species also displayed contrasting trade-offs in energy allocation probably due to the dissimilarity of their habitats, which favours the existence of divergent adaptive strategies in response to different ontogenic requirements. It was hypothesized that M. polli invests in mass and energy reserves while sacrificing growth, as larger sizes may not provide an ecological advantage in a deeper and more stable environment. Moreover, M. senegalensis capitalizes on a steady growth without major disruptions, enabling earlier spawning at the expense of a lower somatic mass, which is fitting to a less stable shallower environment. This study sheds new light on differences in the biological traits and life strategies of Merluccius spp., which permit their overlap in a complex upwelling system and may contribute to the long-lasting scientific-based management of these species.

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Does otolith macrostructure record environmental or biological events? The case of black hake (Merluccius polli and Merluccius senegalensis)

et al. 2012

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Spawning area of the tropical Skipjack Tuna, Katsuwonus pelamis (Scombridae), in the western Mediterranean Sea

Puerto

Saber

Urbina

et al. 2022

scimar

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Skipjack is an important commercial species with a tropical distribution, although captures in the Mediterranean Sea have been recorded for decades. The western Mediterranean Sea, specifically the Balearic Sea, is a spawning area for several tuna species. We hypothesized that the western Mediterranean warming in the last few decades could lead to the expansion of skipjack tuna spawning areas from tropical areas to the Mediterranean Sea. We analysed 454 individuals (41.8-81 cm straight fork length) caught by sport fishing vessels in offshore trolling championships in Spanish Mediterranean waters during summer months from 2014 to 2019. Analysis of the gonadosomatic index and microscopic examination of the ovaries (n=192) showed that the skipjack is reproductively active in the western Mediterranean, particularly in the Balearic Sea. These results indicate that the skipjack has expanded its distribution and spawning area from tropical waters to the Mediterranean, probably owing to the gradual warming detected in the area in the last few decades. This new spawning activity in the area should be monitored in the near future to study the possible impact on other tuna species that share the distribution range and spawning area with skipjack tuna in the western Mediterranean.

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