The age and growth of the tongue sole Cynoglossus canariensis (Steind 1882)

The geometric mean regression equation for the weight; length relationship of Cynoglossus canariensis was W = 0.0025 L super(3.1770). The Von Bertalanffy constants Woo, Loo, K, and to were 507.5852 g, 47.3683 cm, 0.3333 and 0.1397 for males and 839.0753 g, 54.4720 cm, 0.3062 and 0.1737 for females. Total mortality coefficient Z ranged from 0.6482 and 0.8021

Ceratium hirundinella (O.F.Mull.) Bergh. 1882 [Translation from: Flora Slodkowodna Polski. Tom 4. Cryptophyceae, Dinophyceae, Raphidoiphyceae p395-400. Warsaw, Polska Academia Nauk, 1974]

Morphological observations of the dinoflagellate Ceratium hirundinella are given and a key to the difference in types provided. Illustrations are included.

Croissance et détermination de l'âge par lecture d'écailles d'un poisson plat de Côte d'Ivoire, Cynoglossus canariensis (Steind. 1882)

Cynoglossus canariensis has a very rapid growth. The rate of the males is 0,36 and the female one is 0,32. The asymptotic size is 55,0cm for the females and 50,5cm for the males. Females and males younger than three years (40cm), which represent 90 per cent of the Côte d'Ivoire stock have a similar growth, so the average equation: Lt=53,5 (1-e -0,34(t+1)) will be used.

La merluza del Mar Argentino (Biología y Taxonomía).

la Sección Ictiología del Museo Argentino de Ciencias Naturales "Bernardino Rivadavia" de Buenos Aires, comenzó desde principios del año 1952 el estudio de la merluza del sector bonaerense. Las investigaciones se limitaron a la obtención de datos biológicos de pequeñas muestras, seleccionadas de los lances de los buques pesqueros de altura, que actuaban en las áreas de pesca ubicadas hacia el sur de la latitud de Mar del Plata. Para llegar a un estudio completo biológico-pesquero de esta especie, se hizo imperiosa la necesidad de realizar investigaciones tanto sobre las particularidades merísticas y estadísticas de las poblaciones, como también de las condiciones hidrológicas del ambiente en el cual viven, abarcando áreas más extensas y manteniendo una continuidad en el tiempo. Pero, todo ello estaba supeditado a la existencia y utilización de un buque oceanográfico y de pesca experimental, como es de práctica en los países del litoral marítimo del hemisferio norte, en los cuales las investigaciones pesqueras se hallan grandemente desarrolladas. Entretanto el Servicio de Hidrografía Naval de la Secretaría de Marina, por intermedio del Departamento de Oceanografía, planeó el estudio oceanográfico sistemático del Mar Epicontinental Argentino según distintas regiones geográficas, con el fin de lograr un conocimiento más completo de la dinámica de sus aguas. Como el mundo biológico está íntimamente relacionado con la dinámica de las masas de agua, para complementar los datos hidrográficos con algunos biológicos que podrían ser de utilidad para la pesca marítima del país, se incluyó en el mencionado plan el estudio de la merluza. A tal ppropósito en las campañas efectuadas bajo la denominación de "Operación Merluza", durante el período de mayo de 1954 a febrero de 1956. ha participado en lo que a trabajos de biología pesquera se refiere, personal de la Sección Ictiología del Museo Argentino de Ciencias Naturales "B. Rivadavia" y del Departamento de Investigaciones Pesqueras del Ministerio de Agricultura y Ganadería de la Nación. A los efectos de la correlación de las observaciones biológicas con las fisicoquímicas del ambiente, se procuró realizar salidas coordinadas a bordo de algunos barcos pesqueros que actuaban en la misma región de los cruceros oceanográficos, buscando la posibilidad de coincidencia en tiempo y espacio. Conforme a este planteamiento se efectuaron varias salidas a las áreas de pesca de altura del sector bonaerense, principalmente a bordo del barco pesquero "Presidente Mitre" de la compañía "Pesquería Argentina de los Mares del Sud" de Buenos Aires. De acuerdo con el plan general de las campañas oceanográficas de la "Operación Merluza" (ver Capurro, 1955), los estudios de biología pesquera tuvieron los siguientes objetivos: 1o) Conocer la composición faunística, por distintos grupos de organismos, de los lances efectuados en la zona de pesca de altura del sector bonaerense y el grado de abundancia aparente de las especies de peces de importancia comercial; 2o) Determinar desde el punto de vista taxonómico las especies de peces extraídas, en particular las de la familia Merlucciidae, tratando de dilucidar si la merluza del Mar Argentino pertenece o no a una sola especie y si dentro de la misma existen entidades menores; 3o) Estudiar la estadística biológica de la población de merluza, según la distribución de las frecuencias por clases de largo total, y al mismo tiempo establecer el porcentaje de las clases comerciales y el estado del efectivo de la población;4o) Determinar las clases de edad, el ritmo de crecimiento y las relaciones entre la longitud y el peso total del cuerpo; 5o) Obtener un conocimiento más exacto acerca de la proporción de los sexos y el estado fisiológico de las gonadas a través del ciclo sexual; 6o) Determinar los componentes faunísticos que constituyen el alimento principal de la merluza, la cadena alimentaria, las variaciones individuales, estacionales y regionales del régimen nutritivo; 7o) Establecer las relaciones entre la dinámica de la población de merluza y las condiciones hidrológicas del ambiente; y 8o) Calcular el rendimiento de captura por unidad de esfuerzo en la zona de pesca de altura y relacionar los valores promedios con el fin de lograr alguna información acerca de los desplazamientos estacionales de la merluza. El presente trabajo se refiere a los tóptópicos mencionados y contiene los resultados obtenidos durante un período de 22 meses, es decir desde mayo de 1954 a febrero de 1956. Las conclusiones a las cuales se arribó tienen validez para la zona de pesca de altura del sector bonaerense y en especial para las condiciones de captura del buque "Presidente Mitre" en lo que a la estadística biológica se refiere. Además, uno de los fines de aplicación práctica de este trabajo fué el de verificar en qué medida las muestras biológicas obtenidas de los lances de la pesca comercial de altura, pueden servir de base para el estudio estadístico de la población de una determinada especie que se captura en gran cantidad. También merece destacarse que el presente trabajo constituye el punto de partida para el estudio biológico estadístico de la población de merluza en su dinámica a través del factor tiempo para un período mayor que debe sobrepasar el lapso normal del ciclo vital de esta especie. La finalidad de todo esto es la de obtener una base de comparación científica y estadística para un futuro control racional de la pesca de merluza en el Mar Argentino. Por último, los resultados del estudio de la merluza — en conexión con los de las campañas oceanográficas efectuadas en el sector bonaerense — podrían constituir los fundamentos iniciales para la confección de la carta pesquera del Mar Argentino. (PDF tiene 223 paginas.)

Accelerating loss of seagrasses across the globe threatens coastal ecosystems

Coastal ecosystems and the services they provide are adversely affected by a wide variety of human activities. In particular, seagrass meadows are negatively affected by impacts accruing from the billion or more people who live within 50 km of them. Seagrass meadows provide important ecosystem services, including an estimated $1.9 trillion per year in the form of nutrient cycling; an order of magnitude enhancement of coral reef fish productivity; a habitat for thousands of fish, bird, and invertebrate species; and a major food source for endangered dugong, manatee, and green turtle. Although individual impacts from coastal development, degraded water quality, and climate change have been documented, there has been no quantitative global assessment of seagrass loss until now. Our comprehensive global assessment of 215 studies found that seagrasses have been disappearing at a rate of 110 square kilometers per year since 1980 and that 29% of the known areal extent has disappeared since seagrass areas were initially recorded in 1879. Furthermore, rates of decline have accelerated from a median of 0.9% per year before 1940 to 7% per year since 1990. Seagrass loss rates are comparable to those reported for mangroves, coral reefs, and tropical rainforests and place seagrass meadows among the most threatened ecosystems on earth.

NOAA Coastal Change Analysis Program (C-CAP): Guidance for Regional Implementation

EXECUTIVE SUMMARY: The Coastal Change Analysis Programl (C-CAP) is developing a nationally standardized database on landcover and habitat change in the coastal regions of the United States. C-CAP is part of the Estuarine Habitat Program (EHP) of NOAA's Coastal Ocean Program (COP). C-CAP inventories coastal submersed habitats, wetland habitats, and adjacent uplands and monitors changes in these habitats on a one- to five-year cycle. This type of information and frequency of detection are required to improve scientific understanding of the linkages of coastal and submersed wetland habitats with adjacent uplands and with the distribution, abundance, and health of living marine resources. The monitoring cycle will vary according to the rate and magnitude of change in each geographic region. Satellite imagery (primarily Landsat Thematic Mapper), aerial photography, and field data are interpreted, classified, analyzed, and integrated with other digital data in a geographic information system (GIS). The resulting landcover change databases are disseminated in digital form for use by anyone wishing to conduct geographic analysis in the completed regions. C-CAP spatial information on coastal change will be input to EHP conceptual and predictive models to support coastal resource policy planning and analysis. CCAP products will include 1) spatially registered digital databases and images, 2) tabular summaries by state, county, and hydrologic unit, and 3) documentation. Aggregations to larger areas (representing habitats, wildlife refuges, or management districts) will be provided on a case-by-case basis. Ongoing C-CAP research will continue to explore techniques for remote determination of biomass, productivity, and functional status of wetlands and will evaluate new technologies (e.g. remote sensor systems, global positioning systems, image processing algorithms) as they become available. Selected hardcopy land-cover change maps will be produced at local (1:24,000) to regional scales (1:500,000) for distribution. Digital land-cover change data will be provided to users for the cost of reproduction. Much of the guidance contained in this document was developed through a series of professional workshops and interagency meetings that focused on a) coastal wetlands and uplands; b) coastal submersed habitat including aquatic beds; c) user needs; d) regional issues; e) classification schemes; f) change detection techniques; and g) data quality. Invited participants included technical and regional experts and representatives of key State and Federal organizations. Coastal habitat managers and researchers were given an opportunity for review and comment. This document summarizes C-CAP protocols and procedures that are to be used by scientists throughout the United States to develop consistent and reliable coastal change information for input to the C-CAP nationwide database. It also provides useful guidelines for contributors working on related projects. It is considered a working document subject to periodic review and revision.(PDF file contains 104 pages.)

Prediction of discard mortality for Alaskan crabs after exposure to freezing temperatures, based on a reflex impairment index

Millions of crabs are sorted and discarded in freezing conditions each year in Alaskan fisheries for Tanner crab (Chionoecetes bairdi) and snow crab (C. opilio). However, cold exposures vary widely over the fishing season and among different vessels, and mortalities are difficult to estimate. A shipboard experiment was conducted to determine whether simple behavioral observations can be used to evaluate crab condition after low-temperature exposures. Crabs were systematically subjected to cold in seven different exposure treatments. They were then tested for righting behavior and six different ref lex actions and held to monitor mortality. Crabs lost limbs, showed ref lex impairment, and died in direct proportion to increases in cold exposure. Righting behavior was a poor predictor of mortality, whereas reflex impairment (scored as the sum of reflex actions that were lost) was an excellent predictor. This composite index could be measured quickly and easily in hand, and logistic regression revealed that the relationship between reflex impairment and mortality correctly predicted 80.0% of the mortality and survival for C. bairdi, and 79.4% for C. opilio. These relationships provide substantial improvements over earlier approaches to mortality estimation and were independent of crab size and exposure temperature.

An assessment of discard mortality for two Alaskan crab species, Tanner crab (Chionoecetes bairdi) and snow crab (C. opilio), based on reflex impairment

Delayed mortality associated with discarded crabs and fishes has ordinarily been observed through tag and recovery studies or during prolonged holding in deck tanks, and there is need for a more efficient assessment method. Chionoecetes bairdi (Tanner crab) and C. opilio (snow crab) collected with bottom trawls in Bering Sea waters off Alaska were evaluated for reflexes and injuries and held onboard to track mortality. Presence or absence of six reflex actions was determined and combined to calculate a reflex impairment index for each species. Logistic regression revealed that reflex impairment provided an excellent predictor of delayed mortality in C. opilio (91% correct predictions). For C. bairdi, reflex impairment, along with injury score, resulted in 82.7% correct predictions of mortality, and reflex impairment alone resulted in 79.5% correct predictions. The relationships between reflex impairment score and mortality were independent of crab gender, size, and shell condition, and predicted mortality in crabs with no obvious external damage. These relationships provide substantial improvement over earlier predictors of mortality and will help to increase the scope and replication of fishing and handling experiments. The general approach of using reflex actions to predict mortality should be equally valuable for a wide range of crustacean species.

The U.S. Fish Commission Steamer Albatross: A History (Papers from a Symposium)

At her launch on 19 October 1882 in Wilmington, Del., the Albatross was the world’s first large deep-sea oceanographic and fisheries research vessel, and she would go on to have a distinguished 40-year career, ranging from the north Atlantic Ocean to the Gulf of Mexico, around Cape Horn in 1887–88, and into the North Pacific. By 1908, Deputy Fish Commissioner Hugh M. Smith reported that “The Albatross has contributed more to the knowledge of marine biology than has any other vessel.” And, of course, her career continued for another 13 years, being decommissioned in late 1921, serving later as a training vessel for nautical cadets, and disappearing from the records in Hamburg, Germany, in late 1928.

A Century of Copepods: The U.S. Fisheries Steamer Albatross

The marine invertebrates of North America received little attention before the arrival of Louis Agassiz in 1846. Agassiz and his students, particularly Addison E. Verrill and Richard Rathbun, and Agassiz's colleague Spencer F. Baird, provided the concept and stimulus for expanded investigations. Baird's U.S. Commission of Fish and Fisheries (1871) provided a principal means, especially through the U.S. Fisheries Steamer Albatross (1882). Rathbun participated in the first and third Albatrossscientific cruises in 1883-84 and published the fist accounts of Albatross parasitic copepods. The first report of Albatross planktonic copepods was published in 1895 by Wilhelm Giesbrecht of the Naples Zoological Station. Other collections were sent to the Norwegian Georg Ossian Sars. The American Charles Branch Wilson eventually added planktonic copepods to his extensive published works on the parasitic copepods from the Albatross. The Albatross copepods from San Francisco Bay were reported upon by Calvin Olin Esterly in 1924. Henry Bryant Bigelow accompanied the last scientific cruise of the Albatross in 1920. Bigelow incorporated the 1920 copepods into his definitive study of the plankton of the Gulf of Maine. The late Otohiko Tanaka, in 1969, published two reviews of Albatross copepods. Albatross copepods will long be worked and reworked. This great ship and her shipmates were mutually inspiring, and they inspire us still.

The Status of Queen Conch, Strombus gigas, Research in the Caribbean

Today there are approximately 230 published scientific papers on queen conch, Strombus gigas. Publication on this species began in the 1960's and increased rapidly during the 1980's and 1990's (Fig. 1). The increase in publication after 1980 was associated with three particular areas ofendeavor. First, many articles were published to document the rapid depletion of conch stocks throughout the Caribbean Sea. Second, substantial progress was made in understanding processes related to growth, mortality, and reproduction in queen conch. Third, because of the apparent and widespread decline in conch, several research laboratories, especially in Florida, Puerto Rico, Venezuela, and the Turks and Caicos Islands began experiments related to hatchery production of juvenile conch. The primary intent was to replenish wild stocks by releasing hatchery-reared animals. Today, hatchery production has been relatively well perfected, and the increase in numbers of scientific papers related specifically to culture has slowed. A thorough review of the history of conch mariculture was provided by Creswell (1994), and Davis (1994) summarized the details of larval culture technique.

Charles H. Gilbert, Pioneer Ichthyologist and Fishery Biologist

Charles Henry Gilbert (Fig. 1) was a pioneer ichthyologist and, later, fishery biologist of particular significance to natural history of the western United States. Born in Rockford, Illinois on 5 December 1859, he spent his early years in Indianapolis, Indiana, where, in 1874, he came under the influence of his high school teacher, David Starr Jordan (1851-1931). Gilbert graduated from high school in 1875, and when Jordan became a professor of natural history at Butler University in Irvington, Indiana, Gilbert followed, and received his B.A. degree in 1879. Jordan moved to Indiana University, in Bloomington, in the fall of 1879, and Gilbert again followed, earning his M.S. degree in 1882 and his Ph.D. in 1883 in zoology. His doctorate was the first ever awarded by Indiana University.