Determination of catchability-at-age for the Mexican Pacific shrimp fishery in the southern Gulf of California

Journal Pre-proof Determination of catchability-at-age for the Mexican Pacific shrimp fishery in the southern Gulf of California Fernando Aranceta-Garza, Francisco Arreguín-Sánchez, Juan Carlos Seijo, Germán Ponce-Díaz, Daniel Lluch-Cota, Pablo del Monte-Luna

PII: DOI: Reference:

S2352-4855(19)30141-0 https://doi.org/10.1016/j.rsma.2019.100967 RSMA 100967

To appear in:

Regional Studies in Marine Science

Received date : 26 February 2019 Revised date : 12 November 2019 Accepted date : 19 November 2019 Please cite this article as: F. Aranceta-Garza, F. Arreguín-Sánchez, J.C. Seijo et al., Determination of catchability-at-age for the Mexican Pacific shrimp fishery in the southern Gulf of California. Regional Studies in Marine Science (2019), doi: https://doi.org/10.1016/j.rsma.2019.100967. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

© 2019 Published by Elsevier B.V.

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Title: Determination of catchability-at-age for the Mexican Pacific shrimp fishery in the southern

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Gulf of California

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Aranceta-Garza, Fernando1; Arreguín-Sánchez, Francisco2,*; Seijo, Juan Carlos3; Ponce-Díaz,

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Germán2; Lluch-Cota, Daniel1; del Monte-Luna, Pablo 2

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1

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COMITAN" La Paz, BCS 23201, México.

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2

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592, La Paz, 23000, Baja California Sur, México

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pro of

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Centro de Investigaciones Biológicas del Noroeste, Km. 1 Carretera a San Juan de La Costa "EL

Instituto Politécnico Nacional, Centro Interdisciplinario de Ciencias Marinas, Apartado Postal

Universidad Marista de Mérida, Periférico Norte Tablaje 13941 Carretera Mérida-Progreso,

Mérida 97300, Yucatán, México.

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* Corresponding author: [email protected] / Fax (52±612) 122-53-22.

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ORCID:

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Aranceta-Garza, Fernando, https://orcid.org/0000-0003-1298-1814

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Arreguín-Sánchez, Francisco, https://orcid.org/0000-0002-0143-6629

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Seijo, Juan Carlos, https://orcid.org/0000-0003-2064-8894

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Ponce-Díaz, Germán, https://orcid.org/0000-0002-7409-6880

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Lluch-Cota, Daniel https://orcid.org/0000-0002-9045-9821

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del Monte-Luna, Pablo https://orcid.org/0000-0002-9526-0846

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Summary: One of the main problems in the sequential Mexican-shrimp fisheries is the use of a

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constant catchability coefficient for fleets exploiting different population components implying a

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constant vulnerability in the population structure over time and age which denies important

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population processes and causes bias in fishery model outputs. The purpose of this study was to

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determine the catchability-at-age 𝑞

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,

coefficients in time and across ages the sequential shrimp

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fishery fleets exploiting white, blue and brown shrimp in the southern Gulf of California. The

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𝑞

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denoting important population processes (e.g. migration, recruitment and reproduction) per

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species. The 𝑞

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the offshore fleet in the white shrimp, showing an increase in the inshore fishing vulnerability

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which is associated to subadult migrations. The 𝑞

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similar magnitude among species with the highest observed values in the brown shrimp. However,

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their patterns showed differential peaks of recruitment to the marine fishery and reproductive

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aggregations. For the blue and brown species, the increment in their vulnerability could be

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associated to the offshore fishery recruitment and the reproductive aggregations, observing an

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increase in the 𝑞

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over time and across ages into the Mexican management of the shrimp fishery could improve the

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harvest rates and aid to reduce the growth and/or recruitment overfishing for the southern Gulf of

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California.

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Running title: Catchability-at-age for the shrimp fishery in the Gulf of California

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Keywords: Catchability, sequential fisheries, penaeid shrimp, Gulf of California, bioeconomic

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parameters

values were able to identify the catchability patterns in time and across ages for each fleet,

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for the offshore fleets were found to be of

values in relation to the first maturity ages. The integration of the 𝑞

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variability

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values of the inshore fleet were three orders of magnitude lower than those from

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1 Introduction

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The catchability coefficient (q) has an important role in establishing fisheries’ management

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policies, that aim to control fishing mortality (F) through fishing effort (Arreguín-Sánchez 1996,

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Mackinson et al. 1997). This coefficient is estimated as the proportion of fish in the population

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being caught per unit effort and reflects the fishing efficiency whilst relating the stock availability

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with fishing yields under the continuous population distribution assumption (Seijo et al. 1998).

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Current fisheries management usually target the adult population by applying a constant value of

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q to approach the average pattern of the variation of catchability reasonably well (Arreguín-

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Sánchez 1996). In contrast, in sequential fisheries (i.e. multifleets exploiting different population

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components in specific habitats and with diverse fishing gears; e.g. shrimp, groupers and squids

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fisheries), the q varies in time and across ages due to several factors; spatial age distribution (e.g.

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juveniles and preadults are present in the inshore habitat and adults in the offshore habitat);

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changes in stock availability between ontogenetic habitats produce by population processes such

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as recruitment, migrations and reproductive-protective aggregations, which increases fishing

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vulnerability (Martínez-Aguilar et al., 1996); and density-dependent population effects (e.g.

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hyperstability or density dependent catchability in Martínez-Aguilar et al. 2009). Also, other

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important sources of variability in q are caused by different fishing power between fleets (e.g.

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industrial trawlers and artisanal boats) and the environmental conditions (e.g. shrimp: García and

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Le Reste 1986, Zhou et al. 2007; small pelagics: Martínez-Aguilar et al. 1996, Mackinson et al.

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1997; red grouper: Arreguin-Sánchez 1996, López-Rocha and Arreguín-Sánchez 2008; red

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octopus: Velázquez-Abunader et al. 2013).

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In México, the most important fishery is the Pacific sequential shrimp fishery (i.e. in value,

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infrastructure and volume: CONAPESCA 2015). In the southern Gulf of California, this fishery

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is composed by two fleets mainly exploiting three commercial species: 1) brown,

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Farfantepenaeus californiensis; 2) blue, Litopenaeus stylirostris; and 3) white shrimps,

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Litopenaeus vannamei. The inshore fleet captures mostly juveniles of white shrimp using casting

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nets, canoes and seasonal channel blockades to shrimp migrations called “tapos”. The industrial

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or offshore fleet is comprised of fishing trawlers that target the adults of the three species in the

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marine grounds using trawling nets.

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The penaeid annual life cycle starts in the marine bottom grounds where mature adults mate,

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fertilize the eggs and produce the pelagic larvae (García and Le Reste 1986). The larvae then

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develop for relatively 20 days until recruiting in the shallow-protected coastal waters, then

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becoming a benthonic postlarvae (20mm of total length “TL”). The postlarvae grow until the pre-

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adult phase (90-150mm TL), and then begin a migration into deep marine waters for the marine

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recruitment and successive reproductive aggregation (210-240mm TL), afterwards, they disperse

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whilst some migrate to deeper waters (Lluch 1977). These population processes increase

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temporarily the shrimp densities, whilst increasing the stock vulnerability to fishing effort

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(Gracia 1996). Most penaeid shrimp present an annual lifespan, although, their maximum

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longevity is about 2-3 years (Garcia 1988). The penaid reproduction cycle varies among the

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species. The blue and white shrimps present the main reproduction peaks in spring and summer

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for the, while for the brown shrimp it is present all year long (Lluch 1977; Aragón -Noriega and

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Alcántara-Razo 2005).

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Shrimp fishery in México is regulated by the Mexican Official Norm (NOM-002-SAG/PEC-

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2013) and currently presents no official management plan (SAGARPA 2018). The current

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management strategy is to maintain a minimal spawning biomass size at the end of the fishing

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season (SAGARPA 2018). This is based on instruments such as fishing permits, fishing gear

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regulations, annual closed seasons and spatial segregation of fleets’ fishing grounds (SAGARPA

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2018). There are no explicit calculations for fishing mortality coefficients or harvest rates. The

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general stock status is categorized as maximally sustainably fished (SAGARPA 2018), however,

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some stocks are reported under deterioration and overexploitation status, such as white and blue

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shrimp in Sinaloa (INP 2004, Madrid-Vera et al. 2012). This status is mainly attributed to growth

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overfishing by inshore fishermen (i.e. mesh size below legal size), and illegal fishing operation

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during the reproductive season closure causing recruitment overfishing. This has been further

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reported in other marine regions of Mexico (e.g. Gulf of Tehuantepec: Cervantes et al. 2006;

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Ramos et al. 2006; Gulf of Mexico: Gracia 1996; Cervantes-Hernández and Gracia 2011).

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The current Mexican shrimp management still uses a constant q in time and/or across ages in

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their stock assessments (e.g. INP 2003; García-Juárez et al. 2009; Cervantes-Hernández et al.

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2010, Meraz-Sánchez et al. 2013). This creates and introduces a bias by the assignation of same

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probabilities of the catch and fishing vulnerabilities to all the population, thereby excluding

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important population processes (i.e. recruitment, migration and reproductive aggregations). This

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management bias is thought to have detrimental consequences applied in deteriorated shrimp

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stocks (Madrid-Vera et al. 2012).

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Current approaches estimating catchability-at-age (𝑞 , ) in other sequential fisheries have

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demonstrated to be useful for fisheries management. In the pacific sardine (Martínez-Aguilar et

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al. 2009) the variability in q-at-length estimates represented a pattern of hyperstability (i.e.

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density-dependent catchability) suggesting a management strategy of a low constant harvest rate.

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For the red grouper fishery (López-Rocha and Arreguín-Sánchez 2008) the q-at-length

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differences suggest an application of spatial management policies for stock recovery. For these

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reasons, the main objective of this study is to determine the catchability-at-age (𝑞 , ) values in the

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shrimp sequential fishery, describing their variability across ages and stock vulnerability patterns

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in a temporal and spatial scale in relation with the shrimp biology in the southern Gulf of

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California. This study aims to improve the management of the shrimp fishery, through the

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knowledge of a variable catchability-per-fleet that impacts harvest rate whilst preventing

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overfishing in this sequential fishery.

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2 Material and methods

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Information used to estimate catchability-at-age (𝑞 , ) was comprised of inshore and offshore data

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from the shrimp fishery fleets from Mazatlán to Escuinapa (southern of Sinaloa, México) during

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the 2014-2015 fishing season (from September 2014 to March 2015) (Figure 1).

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2.1. Fleet effort and catch estimation

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2.1.1 Inshore effort

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The inshore fishing effort was estimated in cast net throws per month (from September to

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December 2014). For each month only the effective fishing days were accounted. The effort was

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estimated as follows:

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a) The reported fishing effort (i.e. number of fishermen per season) and their respective effective

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fishing days were obtained from the SAGARPA-CONAPESCA database using the local fishery

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offices in Mazatlán, Rosario and Escuinapa (Table1a-b). The seasonal fishing dynamics reported

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by local fishermen established a maximum effort during the first month following by a drastically

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decrease towards December associated to early shrimp migration during the fishing season;

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b) The total monthly throws were estimated in the study site from the cast net samplings during the

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fishing season reported by Muñoz-Rubi et al. (2012) using the equation:

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𝑐 𝑒

𝐶 ∴ 𝐸 𝐸

𝐶 𝑒 𝑐

Eq. 1

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Where 𝑐 is sampling catch in kg per month, 𝑒 is the sampling number of cast net throws per

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month, 𝐶 is monthly SAGARPA inshore catch (2014) and 𝐸 is total estimated monthly throws;

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c) The total estimated fishermen per day were obtained dividing estimated monthly throws by the

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product of daily throws by fisherman and effective fishing days;

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d) The estimated fleet monthly fishing days was calculated as the product of the estimated

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fishermen and the fisherman effective fishing days.

pro of

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The fishing power among the inshore fishing effort is assumed as relative constant, comprising a

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canoe with paddles or small outside motor (15-20 HP) with two casting nets.

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2.1.2 Inshore fleet catch estimation

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The inshore fleet catch estimation targeted exclusively the white shrimp. The reported commercial

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catch per month (September to December 2014) was obtained from the SAGARPA-CONAPESCA

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database for the local fishery offices in Mazatlán, Rosario and Escuinapa. The monthly catch per

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cast net throw was the ratio of Muñoz-Rubi et al. (2012) catch in tons and number of cast net throws

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(Table 1h). The catch per fisherman was estimated as the product of total estimated monthly throws

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and the catch per cast net throw in tons (Table 1i).

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The cast net samplings of Muñoz-Rubi et al. (2012) during the fishing season were used to estimate

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the catch in numbers per cast net throw per month, with the assumption that the sampling and

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commercial catch used the same fishing gear and are equivalent. Each sampling presented a catch

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length structure (5mm length class intervals) in numbers (individuals) and in biomass (kg). The

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estimation of the sampling catch structure relative frequencies (in kg) per month was multiplied by

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the total commercial catch (in kg) per month. The catch database, in kilograms, was converted to

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catch in individuals per length using the length/age keys in section 2.3 and obtaining the catch in

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individuals per cast net throws per month.

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2.2.1 Offshore effort

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The offshore fishing effort was estimated in boats (i.e. trawlers) per month. For each month only

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the effective fishing days were accounted. The total boats per month in the study area were obtained

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from the SAGARPA-CONAPESCA satellite database. The fishing power among the offshore

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fishing effort was assumed relatively constant and even conformed a statically Representative

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Production Units (RPU) for Mazatlán (Almendarez-Hernández et al. 2015).

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2.2.2 Offshore fleet catch estimation

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The commercial catch database (from October 2014 to March 2015) for the offshore fleet targeted

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white, blue and brown shrimps and were obtained from the SAGARPA-CONAPESCA satellite

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database. The catch length-structure per month was obtained from a report from a shrimp packing

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plant enterprise, “Mexican Shrimp Paradise”, located in Mazatlán port. They pack for the 55% of

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the total port shrimp trawlers (380 trawlers), therefore, the observed catch length-structure was

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assumed to represent the offshore fishery in the southern Gulf of California.

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Total commercial catch was corrected to only include the observed fishing boats in the study site

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during the fishing season using a rule of three in the equivalence sampling catch/sampling effort =

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total catch/total effort and solving for the sampling catch. Same as in the inshore catch estimation,

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for each species per month, the catch structure relative frequencies per length (class intervals of

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5mm) from the shrimp packing plant (in kg) was estimated and multiplied by its monthly

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commercial catch (in kg). The conversion to catch in individuals per month was made using the

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length/age keys in section 2.3.

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2.3 Age/length key estimation

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The total catch per species was transformed to catch in number of individuals using the age/length

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keys following the methodology on penaeid shrimp in López-Martínez (2000). Only the brown

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shrimp already had an age/length key (López-Martínez 2000). Briefly, a) for the white and blue

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specie s a length frequency dataset was constructed using the total season catch length frequencies

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and previous studies on the study area (inshore length frequencies in the white shrimp: Gutiérrez

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(1980) and Muñoz-Rubi et al. (2012); offshore length frequencies in the white shrimp: Chávez

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(1973) and Mexican Shrimp Paradise 2014-2015 season dataset; blue shrimp: Castro-Ortiz and

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Sánchez-Rojas (1976), National Fisheries Bureau (INP 1974 a-d, 1975a-g) and Mexican Shrimp

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Paradise 2014-2015 season dataset); b) following a), the mean and standard deviation (sd) were

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then calculated for the length frequency database using Bhattacharya (1967) in software FISAT II

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- FAO-ICLARM Stock Assessment (v.1.2.2); c) each mean and sd per species database were fitted

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to a quadratic function; d) a mean total length was then estimated for each relative age in months

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(ranging from 1 – 24 months) using the von Bertalanffy equations per specie (for the white shrimp:

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Aranceta-Garza et al. 2016; blue shrimp: Sáenz-Martínez and Lluch-Belda 1990; and brown

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shrimp: López-Martínez 2000), and assigning for each modal length class its corresponding sd

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estimated from the quadratic function equation; e) the construction of the age/length key was based

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on the normal distribution of each mean length and sd per species. This allowed to assign a

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probability that an individual of length L belongs to one or several ages.

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The age structure was obtained as follows:

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𝐿 𝑃

𝐸 (Eq. 2)

where:

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𝐿 is the transposed vector of the length frequencies;

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𝑃 is the age/length key matrix; and

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𝐸 is the age structure vector.

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2.3.1 Catch-per-unit of effort per fleet

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Catch-per-unit of effort (CPUE) was estimated for the inshore fleet as the catch in numbers per

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cast-net throw per month. The CPUE for the offshore fleet was estimated as catch in numbers per

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boat per month.

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2.4 Catchability-at-age estimation

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Catchability-at-age (𝑞 , ) was estimated following Arreguín-Sánchez (1996) and Arreguín-

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Sánchez and Pitcher (1999), and used the computation algorithm by Martínez-Aguilar et al. (1999).

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The method computes the catchability-at-length (𝑞 , ) based on the transition matrix (Shepherd

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1987, Caswell 1989), as follows: 𝐴

,

,

𝑁

,

Eq. 3

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𝑁

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pro of

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213 

where:

214 

𝑘 and 𝑙 are successive length classes;

215 

𝑁

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𝐴 is the transition matrix, which depends on growth and mortality probabilities calculated by:

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is the number of individuals of length 𝑙 at time t; and

,

𝐴

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𝐺

,

,

𝑆

Eq. 4

,

where:

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𝐺

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growth probabilities to each length class interval; and

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𝑆

,

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represents the elements of the growth matrix estimated following Shepard (1987) to assign

represents elements of the survival matrix (following Caswell 1989), which are defined by: ,

𝑒

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𝑆

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,

𝑒

,

Eq. 5

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where:

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𝑍 𝑘 is the instantaneous rate of total mortality for the 𝑘-length at time 𝑡;

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𝑀 is the instantaneous rate of natural mortality, assumed constant for all length classes, and

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estimated from Aranceta et al. (2016);

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𝑠

is the probability of gear selection for length 𝑘 (assumed to be 𝑠

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and per fleet because of the absence of data); and

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𝐸

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trawlers per month.

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From substituting Eq. 4 and 5 in Eq. 2 we obtain:

1 for all length classes

𝑁

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𝐺

,

,

𝑒

,

pro of

is the fishing effort at time t given as cast-net throws per month for the inshore fleet and

𝑁

Eq. 6

,

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Following Arreguín-Sánchez and Pitcher (1999), to solve Eq. 6, 𝑁

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using the CPUE (𝑈 ,

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biomass in the fishery. Then, since all the remaining variables are known, 𝑞

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The 𝑞 , model assumes that catchability 1) is length dependant; 2) depends on fish behaviour; 3)

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is density dependent; 4) the units of effort have static properties or have consistent fishing power

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over time; 5) the fishing fleets present differences in fish-length/age catchability patterns implying

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differences in vulnerability due to differences in fishing strategies, fishing areas, available

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population structure and fish behaviour; 6) because the model (Eq.6) considered a constant growth,

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constant natural mortality and no variation in effort, the main source of variability is the

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survivorship (𝑆

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(Arreguín-Sánchez 1996; Arreguín-Sánchez and Pitcher 1999).

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Following the pattern of 𝑞 , with age, a logistic function represented as:

values were approached

,

can be estimated.

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by the assumption that the CPUE is an acceptable proxy to the available

) related to the fishing mortality and consequently to the catchability-at-age

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where:

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𝑞,

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,

𝑞𝑚𝑎𝑥 ,

1

𝑒𝑥𝑝

Eq. 7  

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𝑙 is length class; 𝑡 is a unit of time, in our case month; 𝑞 , represents the catchability-at-length

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per time; 𝑞𝑚𝑎𝑥 , represents the maximum 𝑞 , for each species, at time 𝑡; 𝑏 is

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the change of catchability-at-length with change in length class; 𝑐 is a fitting parameter.

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Global catchability pattern per species was estimated including all the 𝑞 , values per fishing

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season in a single function. Once the pattern of catchability-at-length class was estimated with

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equation 7, the catchability-at-age was computed according with the corresponding mid length

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for each age.

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Based on the observed data, this model was deemed appropriate as the assumption of catchability

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increased with length until a certain length limit was achieved and no further increase was

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observed. The function was empirically fitted per fleet and species to obtain a model describing

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catchability-at-length; and the form of the function described the data and the species’ biology.

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3 Results

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Monthly estimates of fishing effort for inshore and offshore fleets are shown in Table 1 and Table

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2, respectively. The CPUE per fleet and per species is shown in Figure 2, where higher values

262 

tended to appear in September, declining afterwards for all but the brown shrimp. The maximum

263 

CPUE for the brown shrimp was found in December.

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The monthly averaged (𝑞 , ± sd) in the white shrimp for the inshore fleet was (7.44×10-07±

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8.14×10-07). For the offshore fleet, the monthly average for white was (2.13×10-04 2.10×10-04); for

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blue (2.11×10-04±1.01×10-04); and (1.41×10-04 9.73×10-05) for the brown shrimp. Each monthly

267 

𝑞

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the white shrimp (Figure 3A) showed the aggregation of migrating ages into the “tapos” overtime.

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The offshore 𝑞

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recruitment to the marine fishing grounds (ages 4-5 months) or the reproductive aggregations (<9

, representing

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,

pattern presented high variability among all species (Figure 3). The inshore 𝑞

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,

,

,

pattern for

patterns (Figure 3B-D) for the three species showed monthly increments in either

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months). Only the white shrimp presented 𝑞

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species of the inshore lagoon in southern Sinaloa. The 𝑞

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fishery (Figure 3B-D). Global 𝑞

,

patterns, involving all species, ages and fleets, is represented in

274 

Figure 4. The white shrimp 𝑞

,

pattern showed increases with age until an asymptotic trend

275 

towards older ages. On the other hand, the blue shrimp 𝑞

276 

ages, which remained constant and further increased for older ages. Finally, the brown shrimp

277 

𝑞

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As shown in Figure 5, the increments in the monthly 𝑞

279 

vulnerability. For the white shrimp in the inshore grounds, the high slope value in November could

280 

be associated to the pre-adult migration (Figure 5A) and, for the three species in the offshore

281 

grounds, the high slope values were associated to marine recruitment (i.e. first maturity ages) and

282 

reproductive aggregations (Figure 5B-D).

283 

4 Discussion

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Based on the results obtained, we successfully demonstrate the catchability-at-age (𝑞

285 

the sequential shrimp fishery for the 2014-2015 season in the Mexican Pacific. The 𝑞

286 

varied in time and across ages per fleet and per species. The vulnerability of each species to the

287 

fishery could be related with the recognized aggregations of individuals in response to their

288 

population processes: recruitment, migration, reproduction.

289 

This study successfully showed high fluctuations in the fleets 𝑞

290 

responded to several variability factors. Shrimp population processes associated to age behaviour,

291 

(e.g. recruitment, migration, and reproduction in García (1988)), were observed in the 𝑞

292 

(as shown in Figure 3) showing vulnerability increases (Figure 5). This is due to individual

293 

aggregation (i.e. density effects) and fishing gear efficiency (Arreguín-Sánchez 1996). These

for both fleets (Figure 3A,B) being the dominant values were higher for the offshore

pro of

,

,

appeared to be relatively high in early

appeared to have a gradual increase with age, but with a high uncertainty.

slope per species denoted the fishing

re-

,

lP

Jo

urn a

,

,

,

,

values for ,

patterns

values (Figures 3 and 4) which

,

patterns

Journal Pre-proof

294 

density effects in 𝑞 have been reported for other shrimp fisheries (Australian banana prawns,

295 

Penaeus semisulcatus: Zhou et al. 2007), and in other sequential fisheries on other species such as

296 

red grouper (López-Rocha et al. 2008) and pacific sardine (Martínez-Aguilar et al. 2009). Other

297 

possible variation factors for 𝑞

298 

habitat along ontogeny of species (Caddy 1975); changes of fishing power related to fishing gear

299 

or operations between fleets (Arreguín-Sánchez 1996); responses to environment changes (Castro-

300 

Aguirre and Lluch-Belda 2008, López-Martínez et al. 2008, Aragón Noriega et al. 2012) and

301 

fishermen behaviour, where at the beginning of the fishing season the CPUE was concentrated in

302 

the blue shrimp (Figure 2C) (i.e. bigger size, better profits), amongst many others.

303 

The offshore fleet 𝑞

304 

1.41×10-04 9.73×10-05 were in accordance with the magnitude of independent catchability values

305 

(𝑞) estimated for the Mexican shrimp fishery in the Gulf of California (3.30×10-04 to 1.74×10-04,

306 

Morales-Bojórquez et al. 2001, García-Juárez et al. 2009, Meraz-Sánchez et al. 2013) and even

307 

with q values of other regions like Australian banana prawn fishery (6.15×10-04 to 1.09×10-04 in

308 

Zhou et al. 2011). Of importance, these constant seasonal values cannot give any further

309 

information about the resource vulnerability-at-age patterns, which may underestimate the fishing

310 

mortality values.

311 

Other studies showing inshore fleet q values were very scarce in Mexican shrimp fishery. This

312 

study used several information sources from the fishery office, including field fisher’s logs, in order

313 

to estimate robust inshore 𝑞

314 

7.44×10-07 8.14×10-07. Other studies assessing the inshore fleet fishery in Oaxaca ( 1,600km

315 

away from study site) do not explicitly present any q values methodology, however, they are

316 

implicitly estimated by biomass models assuming constant values (Rivera-Velázquez et al. 2009,

values in the shrimp sequential fishery, are those associated to

pro of

,

re-

average values for the three shrimp species (2.13×10-04 2.10×10-04 to

Jo

urn a

lP

,

,

values (observed in Figures 3 and 4), with an average value of

Journal Pre-proof

Cervantes-Hernández et al. 2012). Only one study assessing the white shrimp inshore fishery in

318 

Chiapas (≈1,750km away from study site) presented q value of 6.3×10-04 (Ramos-Cruz 2013) using

319 

similar fishing gear (i.e. cast nets). According to our findings, Ramos-Cruz (2013) q value was

320 

three orders of magnitude larger than the values found for our inshore fleet and ranged with the

321 

trawlers q values, which may suggest a possible overestimation. In this case, caution must be taken

322 

when assessing sequential inshore fisheries using inflated q values because it will overestimate the

323 

fishing mortality values for the inshore fleet and consequently, its management may cause a growth

324 

overfishing in the shrimp fishery.

325 

The global 𝑞

326 

fleet associated to the migration ages (Figure 4A). This increment was also associated in the

327 

offshore fleet with the first maturity ages and observing the highest values over the older ages

328 

(Figure 4 A,B,C) probably because the reproductive aggregations. This pattern has been observed

329 

in other fisheries with aggregating behaviour (Sardinops caeruleus, in the Gulf of California,

330 

Martínez-Aguilar et al. 2009; Epinephelus morio, Campeche Banks, López-Rocha and Arreguín-

331 

Sánchez 2008).

332 

Particularly for the white shrimp, 𝑞

333 

(Figure 4A). Most young shrimps are exposed to fishing gear at inshore water mostly from

334 

September to November and is reflected by high values of catchability and vulnerability (Figure

335 

5A) with a rapid decrease afterwards. Catchability was also found to increase rapidly at offshore

336 

waters from November to December due to the migration to offshore waters (Figure 5B). Once

337 

migration was completed, the catchability decreased at offshore waters following the stock

338 

decrement.

log function (Figure 4) indicated an increment in the vulnerability for the inshore

Jo

urn a

lP

re-

,

pro of

317 

,

values at inshore waters tended to increase as shrimps grow

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The blue shrimp showed a constant catchability for pre-adults increasing for older ages and over

340 

time (Figure 4B and 5C). This pattern was found to be congruent with their biology and fishing

341 

operations. At the beginning of the season (Figure 5C: October), most fishing occurs with blue

342 

shrimp in shallow coastal waters as they reach higher market prices. Even when the CPUE

343 

decreases over time, shrimps tend to move into deeper waters and aggregate for reproduction. This

344 

allowed to reach a maximum catchability and vulnerability value prior to the end of fishery seasons

345 

designated to prevent recruitment overfishing (Figure 5C: Jan-Feb).

346 

The catchability behaviour for the brown shrimp appears to depend on both, the reproductive adult

347 

aggregations (e.g. October, December and February in Figure 3D) and the recruitment to the fishery

348 

(e.g. November, January, March in Figure 3D), which can be explained because it is an all-year-

349 

round reproductive period in southern Sinaloa (Aragón-Noriega and Alcántara-Razo 2005). Even

350 

when catchability-at-age is the most uncertain pattern, it suggests that catchability tends to increase

351 

with age (Figure 4C), which is probably associated with reproductive aggregation ages. However,

352 

changes in catchability tend to decrease with time along the fishing season (Figure 5D), which,

353 

according to our assumption in equation 6, also coincides with the decrease of the stock availability,

354 

probably due to the stock depletion at the end of the season. The proportionality between the stock

355 

availability and CPUE does not imply linearity and could be reflecting a density-dependent

356 

catchability or hyperstability, as demonstrated previously in the pacific sardine (Martínez-Aguilar

357 

et al. 2009).

358 

Following Caddy (1979), catchability relates available stock, or individuals removed, by a fishing

359 

effort unit which, at the same time, depends of the stock distribution and behaviour. In this sense,

360 

and regarding its management, further research is warranted. the next step of research, once

361 

catchability is known, will be to relate the CPUE with the real stock abundance measures.

362 

5 Conclusion

Jo

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pro of

339 

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The management efficiency of any fishery can be increased using fishing effort as a control variable

364 

coupled with knowledge of catchability patterns. Estimated patterns of catchability-at-age over

365 

time and across ages appear to offer an opportunity to evaluate potential success of management

366 

for the three main shrimp species in the southern Gulf of California. Additionally, such patterns

367 

provide specific information on how fishing could be applied in a sequential fishery. In the case of

368 

the white shrimp, it can offer realistic fishing mortality estimates for an adequate management to

369 

aid restoring the already deteriorated stocks. For blue and brown shrimp, catchability patterns can

370 

offer more detailed information on fishing mortality related to reproductive aggregation and, in the

371 

case of Mexico, help increase the confidence in defining seasonal fishing closures. Finally, even

372 

when estimated catchability-at-age patterns can be taken as global patterns for each species, the

373 

relative catchability values also depend on other factors affecting shrimp behaviour such as changes

374 

in habitats, climate, and distribution of individuals. To improve management practices that

375 

anticipate natural or induced changes, we strongly suggest reinforcing the monitoring programme

376 

year to year in order to adapt management as required.

377 

ACKNOWLEDGEMENTS

378 

FAG thanks CONACyT, IPN-BEIFI and COFAA for the grants received. A Special thanks to Raul

379 

Villaseñor (CONAPESCA), Jesús Ortiz (industrial fleet leader) and Miguel Rose (Mexican Shrimp

380 

Paradise). FAS, GPD and PDM thank Instituto Politécnico Nacional support through EDI and

381 

COFAA programs. Authors acknowledge the support through projects CONACYT (221705), SIP-

382 

IPN (20172122, 20180929).

383 

REFERENCES

384 

Almendarez-Hernández, L.C., Ponce-Díaz, G., Lluch-Belda, D., del Monte-Luna, P., Saldívar-

385 

Lucio, R. 2015. Risk assessment and uncertainty of the shrimp trawl fishery in the Gulf of

Jo

urn a

lP

re-

pro of

363 

Journal Pre-proof

386 

California considering environmental variability. Latin American Journal of Aquatic Research.

387 

43, 651-661. Aragón-Noriega, E.A., Alcántara-Razo, E. 2005. Influence of sea surface temperature on

389 

reproductive period and size at maturity of brown shrimp (Farfantepenaeus californiensis) in

390 

the Gulf of California. Marine Biology. 146, 373-379.

pro of

388 

391 

Aragón-Noriega, E.A., Pérez-Arvizu, E.M., Valenzuela-Quiñonez, W. 2012. Latitudinal variation

392 

in reproduction timing of whiteleg shrimp Litopenaeus vannamei (Decapoda, Penaeidae) of

393 

the Mexican Pacific coast. Crustaceana. 85, 287-300.

Aranceta-Garza, F., Arreguín-Sánchez, F., Ponce-Díaz, G., Seijo, J.C. 2016. Natural mortality of

395 

three commercial penaeid shrimps (Litopenaeus vannamei, L. stylirostris and Farfantepenaeus

396 

californiensis) of the Gulf of California using gnomonic time divisions. Sci. Mar. 80, 199-206.

397 

Arreguín-Sánchez, F. 1996. Catchability: a key parameter for fish stock assessment. Rev. Fish. Biol. Fisher. 6, 221-242.

lP

398 

re-

394 

Arreguín-Sanchez, F., Pitcher, T.J. 1999. Catchability estimates and their application to the red

400 

grouper (Epinephelus morio) fishery of the Campeche Bank, Mexico. Fish. Bull. 97, 746-757.

401 

Bhattacharya, C.G. 1967. A simple method of resolution of a distribution into Gaussian

402  403  404 

urn a

399 

components. Biometrics. 23, 115-135.

Caddy, J.F. 1975. Spatial model for an exploited shellfish population, and its application to the Georges Bank scallop fishery. J. Fish. Res. Board Can. 32, 1305-1328. Caddy, J.F. 1979. Some considerations underlying definitions of catchability and fishing effort in

406 

shellfish fisheries, and their relevance for stock assessment purposes. Fish Mar Serv Rep. No.

407 

1489. 22 pp.

Jo

405 

408 

Castro-Ortiz, J., Sánchez-Rojas, M. 1976. Notas Preliminares del comportamiento y dinámica

409 

poblacional de Penaeus stylirostris (Stimpson 1871), en los sistemas lagunarios del centro de

Journal Pre-proof

410 

Sinaloa. In: Castro-Ortiz J.C. (Ed.), Memorias del Simposio sobre Biología y Dinámica

411 

Poblacional de Camarones. INP-FAO, Guaymas, pp. 213–253.

413  414  415  416  417 

Castro-Ortiz, J.L., Lluch-Belda, D. 2008. Impacts of interanual environmental variation on the shrimp fishery off the Gulf of California. CalCOFI Rep. 49, 183-190.

pro of

412 

Caswell, H. 1989. Analysis of life table response experiments I. Decomposition of effects on population growth rate. Ecol. Model. 46, 221-237.

Cervantes-Hernández, P., Ramos-Cruz, S., & Gracia Gasca, A. 2006. Evaluación del estado de la pesquería de camarón en el Golfo de Tehuantepec. Hidrobiologica. 16(3),233-239. Cervantes-Hernández, P., Flores-Gómez, A., Serrano-Guzmán, S.J., Ramos-Cruz, S., Gallardo-

419 

Berumen M.I. 2010. Historical exploitation and evaluation of brown shrimp fishery

420 

Farfantepeneaeus californiensis (Decapoda, Dendrobranchiata) in the Gulf of Tehuantepec,

421 

Oaxaca, Mexico. PANAMJAS. 5, 486-494.

lP

re-

418 

Cervantes-Hernández, P., Gracia, A. 2011. Análisis de la mortalidad para el camarón rosado

423 

Farfantepenaeus duorarum (Decapoda, Dendrobranchiata) del Banco de Campeche, México.

424 

PanamJAS. 6(2), 100-108.

urn a

422 

425 

Cervantes-Hernández, P., Berumen, M.I.G., Serrano-Guzmán, S.J. 2012. Explotación y

426 

distribución de la captura artesanal de camarón en el sistema lagunar Huave, Oaxaca, México.

427 

REVMAR. 4, 67-81.

Chávez, E.A. 1973. Estudio sobre la tasa de crecimiento del camarón blanco (Litopenaeus

429 

vannamei Boone) de la región Sur del Golfo de California. Cienc. Mex. XXVIII. 2, 79-85.

Jo

428 

430 

CONAPESCA. 2015. Anuario estadístico de pesca 2014. SAGARPA, México, 301 pp.

431 

García, S., Le Reste, L. 1986. Ciclos vitales, dinámica, explotación y ordenación de las poblaciones

432 

de camarones peneidos costeros. FAO Doc. Téc. Pesca. Rome, FAO, 180 pp.

Journal Pre-proof

433  434 

García, S. 1988. Tropical Penaeid Prawns. In: Gulland J.A. (Ed.), Fish Population Dynamics. John Wiley and Sons, USA, pp. 219–249. García-Juárez, A.R., Rodríguez-Domínguez, G., Lluch-Cota, D.B. 2009. Blue shrimp (Litopenaeus

436 

stylirostris) catch quotas as a management tool in the Upper Gulf of California. Cienc. Mar.

437 

35, 297-30.

438  439  440  441 

pro of

435 

Gracia, A. 1996. White shrimp (Penaeus setiferus) recruitment overfishing. Mar Freshwater Res. 47(1), 59-65.

Gulland, J.A., Rothschild, B.J. 1984. Penaeid shrimps: their biology and management. Fishing News Books Ltd.

Gutiérrez, J.L. 1980. Ecología y crecimiento de Penaeus vannamei en laguna “Las Cabras” del

443 

Sistema Chametla-Teacapán, Sinaloa. Professional thesis, I.P.N.- C.I.C.I.M.A.R., La Paz, 80

444 

pp.

lP

re-

442 

INP. 1974ª. Resultados del muestreo de altamar junio. INP, México.

446 

INP. 1974b. Resultados del muestreo de altamar julio. INP, México.

447 

INP. 1974c. Resultados del muestreo de altamar agosto. INP, México.

448 

INP. 1974d. Resultados del muestreo de altamar septiembre. INP, México.

449 

INP. 1975ª. Resultados del muestreo de altamar mayo. INP, México.

450 

INP. 1975b. Resultados del muestreo de altamar octubre y noviembre 1974 y enero 1975. México,

451 

INP.

urn a

445 

INP. 1975c. Resultados del muestreo de altamar mayo. INP, México.

453 

INP. 1975d. Resultados del muestreo de altamar junio. INP/SI: i42, México.

454 

INP. 1975e. Resultados del muestreo de altamar julio. INP/SI: i78, México.

455 

INP. 1975f. Resultados del muestreo de altamar junio-julio. INP/SI: i43, México.

456 

INP. 1975g. Resultados del muestreo de altamar agosto. INP, México.

Jo

452 

Journal Pre-proof

457 

INP.2003. SAGARPA. Mazatlán. 34 pp.

458 

INP. 2004. Evaluación de la migración y reclutamiento de las poblaciones de camarón en aguas

460  461 

protegidas y en el frente costero de Sinaloa y Sonora. SAGARPA. Guaymas.179 pp. Lluch, D. 1977. Diagnóstico, modelo y régimen óptimo de la pesquería de camarón de altamar en

pro of

459 

el noroeste de México. Ph.D thesis, I.P.N. México, 430 pp.

462 

López-Martínez, J. 2000. Dinámica de la pesquería de camarón café (Penaeus californiensis) en el

463 

litoral sonorense y su relación con algunos parámetros océano-atmosféricos. Ph.D thesis,

464 

I.P.N.- C.I.C.I.M.A.R., La Paz, 160 pp.

López-Martínez, J., Vázquez, S.H., Valdivia, E.H., Romero, J.R., Chávez, E.A. 2008. Influencia

466 

ambiental en la pesquería de camarón. In: López-Martínez J. (ed.), Variabilidad Ambiental y

467 

Pesquerías de México. Comisión Nacional de Acuacultura y Pesca, México, pp. 115-127.

468 

López‐Rocha, J.A., Arreguín‐Sánchez, F. 2008. Spatial distribution of red grouper Epinephelus

469 

morio (Serranidae) catchability on the Campeche Bank of Mexico. J. Appl. Ichthyol. 24, 282-

470 

289.

472  473 

lP

Mackinson, S., Sumaila, U.R., Pitcher, T.J. 1997. Bioeconomics and catchability: fish and fishers

urn a

471 

re-

465 

behaviour during stock collapse. Fish. Res. 31, 11-17. Madrid-Vera, J., Chávez-Herrera, D., Melchor-Aragón, J., Meraz-Sánchez, R.,

Rodríguez-

474 

Preciado, J.A. 2012. Management for the white shrimp (Litopenaeus vannamei) from the

475 

southeastern Gulf of California through biomass models analysis. O. J. Mar. Scien. 2, 8-15. Martínez-Aguilar, S., de Anda Montañez, J.A., Arreguín-Sánchez, F. 1996. Densidad y”

477 

capturabilidad” de la sardina monterrey, Sardinops sagax (pisces: Clupeidae) del Golfo de

478 

California, México. Rev. Biol. Trop. 44, 527-535.

Jo

476 

Journal Pre-proof

479 

Martínez-Aguilar, S., Morales-Bojórquez, E., Arreguín-Sánchez, F., De Anda-Montañez, J.A.

480 

1999. Catchability: programa computarizado para estimar el coeficiente de capturabilidad en

481 

función de la longitud. SAGARPA, CICIMAR, CIBNOR. La Paz, México. Martínez-Aguilar, S., De Anda-Montañez, J.A., Arreguín-Sánchez, F., Cisneros-Mata M.A. 2009.

483 

Constant harvest rate for the Pacific sardine (Sardinops caeruleus) fishery in the Gulf of

484 

California based on catchability-at-length estimations. Fish. Res. 99, 74-82.

pro of

482 

Meraz-Sánchez, R., Madrid-Vera, J., Cisneros-Mata, M.A., Herrera, D.C. 2013. An Approach to

486 

Assessment to Population of the Brown Shrimp, Farfantepenaeus californiensis (Holmes,

487 

1900), as a Management Fisheries Tool in the Southeastern Gulf of California. OJMS. 3, 40-

488 

47.

re-

485 

Morales-Bojórquez, E., López-Martínez, J., Hernández-Vázquez, S. 2001. Dynamic catch-effort

490 

model for brown shrimp Farfantepenaeus californiensis (Holmes) from the Gulf of California,

491 

Mexico. Cienc. Mar. 27, 105-124.

lP

489 

Muñoz-Rubí, H.A., Chávez-Herrera, D., Villegas-Hernández, F. 2012. Evaluación de las

493 

poblaciones de Litopenaeus vannamei, L. stylirostris y Farfantepenaeus californiensis en el

494 

sistema lagunar Huizache-Caimanero, Sinaloa, en 2011. SAGARPA, Mazatlán, 23 pp.

urn a

492 

495 

Norma Oficial Mexicana-002-SAG/PESC-2013. Para ordenar el aprovechamiento de las especies

496 

de camarón en aguas de jurisdicción federal de los Estados Unidos Mexicanos:

497 

http://www.dof.gob.mx/nota_detalle_popup.php?codigo=5306294 Ramos-Cruz, S., Sánchez-Meraz, B., Carrasco-Ayuso, F., Cervantes-Hernández, P. 2006.

499 

Estimación de la tasa de mortalidad natural de Farfantepenaeus californiensis (Holmes, 1900)

500 

y Litopenaeus vannamei (Boone, 1931) en la zona costera del Golfo de Tehuantepec, México.

501 

Rev Biol Mar Oceanogr. 41(2), 221-229.

Jo

498 

Journal Pre-proof

502  503 

Ramos-Cruz, S. 2013. Evaluación de la pesquería artesanal de camarón en el sistema lagunar La Pampita-Joya-Buenavista, Chiapas, México. Cien. Pesq. 21, 5-11. Rivera-Velázquez, G., Soto, L.A., Ugarte, I.H.S., Naranjo, E.J. 2009. Assessment of an artisanal

505 

shrimp fishery of Litopenaeus vannamei in a lagoon-estuarine system based on the concept of

506 

maximum sustainable yield. Rev. Biol. Mar. Oceanogr. 44, 635-646.

508  509  510  511  512 

Sáenz-Martínez, P.G., Lluch-Belda, D. 1990. Análisis de una temporada de pesca de camarón azul en alta mar. Secretaria de Pesca, México, 20 pp.

SAGARPA. 2018.  ACUERDO por el que se da a conocer la actualización de la Carta Nacional Pesquera. DOF, México, 69 pp.

Seijo, J.C., Defeo, O., Salas, S. 1998. Fisheries bioeconomics: theory, modelling and management.

re-

507 

pro of

504 

FAO Fisheries Technical Paper. No. 368. Rome, FAO. 108p. Shepherd, J.G. 1987. Towards a method for short-term forecasting of catch rates based on length

514 

composition. In: Pauly D., Morgan G.R. (eds.), Length-based methods in fisheries research.

515 

ICLARM Conf. Proc, Manila, pp. 167-176.

lP

513 

Velázquez-Abunader, I., Salas, S., Cabrera, M.A. 2013. Differential catchability by zone, fleet,

517 

and size: the case of the red octopus (Octopus maya) and common octopus (Octopus vulgaris)

518 

fishery in Yucatan, Mexico. J. Shellfish Res. 32, 845-854.

519  520 

urn a

516 

Zhou, S., Dichmont, C., Burridge, C.Y., Venables, W.N., Toscas, P.J., Vance, D. 2007. Is catchability density-dependent for schooling prawns?. Fish. Res. 85, 23-36. Zhou, S., Punt, A.E., Deng, R., Bishop, J. 2011. Estimating multifleet catchability coefficients and

522 

natural mortality from fishery catch and effort data: comparison of Bayesian state–space and

523 

observation error models. Can. J. Fish. Aquat. Sci. 68, 1171-1181.

524  525 

Jo

521 

Journal Pre-proof

TABLES

528 

Table 1. Inshore fishing effort and observed catch of white shrimp during the 2014-15 fishing

529 

season in southern Gulf of California. Sep a. Reported inshore fishing effort (total fishermen) b. Fisherman effective monthly fishing days c. Total throws per fisherman

25

25

25

150.96

67.14

73.56

re-

Dec

1,978,337

733,818

681,259

2,529

524

437

370

58,155

13,105

10,930

9,261

424.53

183.48

40.99

30.29

0.0073

0.0140

0.0038

0.0033

1.48E-04

9.30E-05

5.60E-05

4.4E-05

f. Estimated fleet effective monthly

h. Catch per fisherman (t day-1)b

urn a

(t day-1)b

Nov

2,873,546

e. Estimated fishermen (day) b

i. Catch per cast net throw

Oct

lP

d. Total estimated monthly throws b

g. Reported monthly catch (t)a

23

49.41

(day)b

fishing days

4000

pro of

526  527 

a

531 

from local fishing offices and surveys in southern Sinaloa.

532  533 

SAGARPA-CONAPESCA 2014 database; b Muñoz et al. (2012); observed data were obtained

Jo

530 

Journal Pre-proof

534 

Table 2. Offshore fishing effort and observed catch of white shrimp (Litopenaeus vannamei);

536 

blue shrimp (L. stylirostris) and brown shrimp (Farfantepenaeus californiensis) during the 2014-

537 

15 fishing season in the southern Gulf of California. Observed satellite tracking Oct

Nov

Dec

189

95

140

Number of shrimp trawlers Effective fishing days per boat 17.69

21.02

27.25

White shrimp

17.6

22.19

27.81

Brown shrimp

17.71

19.75

Mean±sd

17.67±0.06 20.99±1.22

27.51

27.52±0.17

lP

Effective fishing days per fleet

Jan

Feb

Mar

165

203

135

22.61

31.35

21.28

23.72

30.84

24

44.1

31.58

20.95

re-

Blue shrimp

pro of

535 

30.14±10.42 31.26±0.37 22.08±1.54

Blue shrimp

3343

1996

3815

3731

6364

2873

White shrimp

3326

2108

3894

3914

6261

3240

Brown shrimp

3348

1876

3851

3777

6410

2828

3348

2108

3894

3914

6410

3240

582

195

274

92

178

104

69

24

25

35

63

12

437

340

890

348

909

299

1088

559

1189

475

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Table 3. Catchability-at-age logistic function parameters for commercial shrimps in the 2014-15

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fishing season in the southern Gulf of California.

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White shrimp (Litopenaeus vannamei) a b c 7.4E-06 0.038 -7.420 3.9E-06 0.029 -5.790 1.6E-06 0.285 -28.913 8.1E-07 -0.140 18.877 White shrimp (L. vannamei) F(x) parameters Log (a) Log (b) Log (c) October -3.845 -0.054 13.562 -3.793 -0.108 25.240 November December -4.219 0.159 -21.968 January -4.744 -0.032 8.077 February -143.943 0.004 -4.313 1.00E-04 -0.093 18.706 March Fishery (Log) -8.046 -0.017 3.325 Blue shrimp (L. stylirostris) F(x) parameters a b c October 0.369 0.019 -11.036 November 3.00E-04 -0.040 7.326 December 4.00E-04 -0.013 3.104 January 5.00E-04 0.035 -7.153 1.00E-04 0.041 -7.042 February March 7.00E-05 -0.323 68.426 Fishery (Log) -3.73461 -0.118 27.849 Brown shrimp (Farfantepenaeus californiensis) F(x) parameters a b c October 2.35 E-04 0.0862 -14.089 November 3.54 E-04 -0.069 10.000 December 2.84 E-04 0.047 -6.127 January 2.48 E-04 0.024 -3.782 February 5.60 E-04 -0.200 29.793 March 1.20 E-04 -0.084 12.672 -3.95796 -0.049 12.103 Fishery (Log) *a is 𝑞𝑚𝑎𝑥 , ; 𝑏 is Δ𝑞 , ⁄Δ𝑙 ; 𝑐 is a fitting parameter.

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F(x) parameters September October November December

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R 0.897 0.785 0.654 0.825 R 0.926 0.574 0.588 0.688 0.709 0.693 0.812 R 0.860 0.601 0.524 0.586 0.467 0.381 0.368 R 0.970 0.902 0.490 0.446 0.946 0.999 0.295

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FIGURES

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Figure 1 - Study regions for the shrimp fishery in southern Gulf of California.

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*Inshore fleet surveys applied in: Huizache; Chametla; Teacapán lagoon; Palmilla; and

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Teacapán marine area in Sinaloa.

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the offshore fleet.

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California. The season length was from September to December (2014) for inshore fleet and from October (2014) to March (2015) for

(Farfantepenaeus californiensis) as number of individuals per trawler per month for the offshore fleet (2) in southern Gulf of

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and from October (2014) to March (2015) for the offshore fleet.

for the offshore fleet (2) in southern Gulf of California. The season length was from September to December (2014) for inshore fleet

fleet (1); and of B) white shrimp (L. vannamei); C) blue shrimp (L. stylirostris) and D) brown shrimp (Farfantepenaeus californiensis)

Figure 3 – Catchability-at-age and log function estimation (dashed line) of A) white shrimp (Litopenaeus vannamei) for the inshore

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(L. stylirostris) and C) brown shrimp (Farfantepenaeus californiensis) in southern Gulf of California.

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A)

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Figure 5 - Slope of catchability-at-age pattern (Table 3) showing the change of catchability pattern with time: A) white shrimp (Litopenaeus vannamei) – inshore fleet; B) white shrimp (L. vannamei) – offshore fleet; C) blue shrimp (L. stylirostris) – offshore fleet; D) brown shrimp (Farfantepenaues californiensis) – offshore fleet, during the 2014-15 season in southern Gulf of California.

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    La Paz, Baja California Sur, Mexico, September 27th, 2019. 

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        Dr. Gunnar Lauenstein  Regional Studies in Marine Science  Editor 

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Regarding  the  manuscript  titled  “Determination  of  catchability‐at‐age  for  the  Mexican  Pacific  shrimp  fishery in the southern Gulf of California”, authored by Aranceta‐Garza F., Arreguín‐Sánchez F., Seijo JC.,  Ponce‐Díaz  G.,  Lluch‐Cota  D.,  del  Monte‐Luna  P.;  we  declare  that  there  is  not  any  conflict  of  interest  regarding use of data. Also, we declare that the described has not been published previously, that it is not  under consideration for publication elsewhere, and that it was approved by all authors and tacitly by the  responsible authorities of my institution 

With no other thing to declare, I appreciate very much your kind attention   

         

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Sincerely yours 

Dr. Francisco Arreguín Sánchez