Gulf of Mexico estuarine blue carbon stock, extent and flux: Mangroves, marshes, and seagrasses: A North American hotspot.

The Gulf of Mexico blue carbon habitats (mangroves, seagrass, and salt marshes) form an important North American blue carbon hot spot. These habitats cover 2,161,446 ha and grow profusely in estuaries that occupy 38,000 km2 to store substantial sedimentary organic carbon of 480.48 Tg C. New investigations around GoM for Mexican mangroves, Louisiana salt marshes and seagrasses motivated our integration of buried organic carbon to elucidate a new estimate of GoM blue carbon stocks. Factors creating this include: large GoM watersheds enriching carbon slowly flowing through shallow estuarine habitats with long residence times; fewer SE Mexican hurricanes allowing enhanced carbon storage; mangrove carbon productivity enhanced by warm southern basin winter temperatures; large Preservation reserves amongst high anthropogenic development. The dominant total GoM mangrove blue carbon stock 196.88 Tg from total mangrove extent 650,482 ha is highlighted from new Mexican data. Mexican mangrove organic carbon stock is 112.74 Tg (1st sediment meter) plus USA 84.14 Tg. Mexican mangroves vary greatly in storage, total carbon depositional depths and in sediment age (to 3500 y). We report Mexican mangrove's conservative storage fraction for the normally-compared top meter, whereas the full storage depth estimates ranging above 366.78 Tg (high productivity in very deep sediment along the central Veracruz/Tabasco coast) are not reflected in our reported estimates. Seagrasses stock of 184.1 Tg C organic is derived from 972,327 ha areal extent (in 1st meter). The Louisiana marshes form the heart of GoM salt marsh carbon storage 99.5 Tg (in 1st meter), followed by lesser stocks in Florida, Texas, finally Mexico derived from salt marsh extent totaling 650,482 ha. Constraints on the partial estuarine fluxes given for this new data are discussed as well as widespread anthropogenic destruction of the GoM blue carbon. A new North American comparison of our GoM blue carbon stocks versus Atlantic coastal blue carbon stock estimates is presented.

Factores ambientales que influyen en la ictiofauna de la laguna La Mancha, sitio Ramsar, Golfo de México / Environmental factors influencing the ichthyofauna of the La Mancha lagoon, Ramsar site, Gulf of Mexico

Resumen La laguna La Mancha en el Golfo de México, es un sistema costero con categoría Ramsar por su alta biodiversidad, numerosas especies de peces dependen de el para realizar sus ciclos de vida. Fue analizada la variación espacial y temporal de la diversidad, abundancia y asociaciones de peces y su relación con los factores fisicoquímicos. Entre abril de 2005 y enero de 2008, se realizaron 95 muestreos diurnos en siete sitios donde se registraron las características del agua y la composición de la comunidad de peces. El sistema presentó variaciones espacio temporales de los parámetros físicoquímicos, definiendo ambientes contrastantes de acuerdo con los gradientes locales. Se recolectaron 5 974 individuos, pertenecientes a 50 especies, 39 géneros y 25 familias, cuatro especies son registros nuevos para el sistema. La diversidad y riqueza de especies fueron altas en el ambiente salobre y bajos en zonas dulceacuícolas. En septiembre (lluvias) y noviembre (nortes) la diversidad (H' = 1.52) y riqueza (D = 1.99) fue más alta. La abundancia de los peces fue mayor hacia la boca de conexión con el mar. La densidad y biomasa (1.17 indiv./m2, 4.33 g/m2) fue mayor en abril (secas) y el peso promedio (30.82 g/ind) en julio (lluvias). El Índice de Valor de Importancia (IVI) definió cuatro especies dominantes que representan el 75 % de la abundancia numérica y el 46 % de la captura total en peso. El Análisis de Correspondencia Canónica (ACC) mostró que la relación peces-hábitat fue explicada en un 57 % de la varianza total para los primeros dos ejes, donde las variaciones de temperatura, salinidad, oxígeno disuelto y profundidad fueron los factores ambientales que determinaron la composición, distribución, componentes comunitarios y categorías tróficas de los peces en la comunidad. Este estudio aporta información sobre la relación del ambiente con la estructura de la comunidad íctica de La Mancha, y representa una base para realizar monitoreo ecológico que permita incrementar el conocimiento necesario sobre el ecosistema y sus poblaciones de peces, con la finalidad de proponer estrategias de manejo para la conservación de los recursos pesqueros de Veracruz.

Abstract La Mancha lagoon in the Gulf of Mexico, is a coastal system with Ramsar category because of its high biodiversity, many species of fish depend on it to complete their life cycles. In this study we analyzed the spatial and temporal variation of fish diversity, abundance and associations, and its relationship with physicochemical factors. Between April 2005 and January 2008, 95 daytime samplings were carried out at seven sites, where water characteristics and the composition of fish community were recorded. The system presented spatial-temporal variations of the physicochemical parameters, defining contrasting environments according to the local gradients. A total of 5 974 fish individuals, belonging to 50 species, 39 genera and 25 families were collected; four species were new records for the system. The diversity and richness of species were high in the brackish environment and low in freshwaters areas. In September (rainy season) and November ("nortes" season), diversity (H' = 1.52) and richness (D = 1.99) were highest. Fish abundance was greater towards the mouth connecting with the sea. The density and biomass (1.17 ind/m2, 4.33 g/m2) was higher in April (dry season) and the average weight (30.82 g/ind) in July (rainy season). The Importance Value Index (IVI) defined four dominant species representing 75 % of the numerical abundance and 46 % of the total catch in weight. The Canonical Correspondence Analysis (CCA) showed that the fish-habitat relationship was explained in 57 % of the total variance for the first two axes, where the variations in temperature, salinity, dissolved oxygen and depth were the environmental factors that determined the composition, distribution, community components and trophic categories of the fish community. This study provides information on the relationship between the environment and the structure of the fish community in La Mancha, and represents a basis for ecological monitoring to increase the knowledge needed about the ecosystem and fish populations, in order to boost management strategies for the fishery resources conservation in Veracruz. Rev. Biol. Trop. 66(1): 246-265. Epub 2018 March 01.

Dynamic control of osmolality and ionic composition of the xylem sap in two mangrove species.

• Premise of the study: Xylem sap osmolality and salinity is a critical unresolved issue in plant function with impacts on transport efficiency, pressure gradients, and living cell turgor pressure, especially for halophytes such as mangrove trees.• Methods: We collected successive xylem vessel sap samples from stems and shoots of Avicennia germinans and Laguncularia racemosa using vacuum and pressure extraction and measured their osmolality. Following a series of extractions with the pressure chamber, we depressurized the shoot and pressurized again after various equilibration periods (minutes to hours) to test for dynamic control of osmolality. Transpiration and final sap osmolality were measured in shoots perfused with deionized water or different seawater dilutions.• Key results: For both species, the sap osmolality values of consecutive samples collected by vacuum extraction were stable and matched those of the initial samples extracted with the pressure chamber. Further extraction of samples with the pressure chamber decreased sap osmolality, suggesting reverse osmosis occurred. However, sap osmolalities increased when longer equilibration periods after sap extraction were allowed. Analysis of expressed sap with HPLC indicated a 1:1 relation between measured osmolality and the osmolality of the inorganic ions in the sap (mainly Na+, K+, and Cl-), suggesting no contamination by organic compounds. In stems perfused with deionized water, the sap osmolality increased to mimic the native sap osmolality.• Conclusions: Xylem sap osmolality and ionic contents are dynamically adjusted by mangroves and may help modulate turgor pressure, hydraulic conductivity, and water potential, thus being important for mangrove physiology, survival, and distribution.

Using ecotechnology to address water quality and wetland habitat loss problems in the Mississippi basin: a hierarchical approach.

Human activities are affecting the environment at continental and global scales. An example of this is the Mississippi basin where there has been a large scale loss of wetlands and water quality deterioration over the past century. Wetland and riparian ecosystems have been isolated from rivers and streams. Wetland loss is due both to drainage and reclamation, mainly for agriculture, and to isolation from the river by levees, as in the Mississippi delta. There has been a decline in water quality due to increasing use of fertilizers, enhanced drainage and the loss of wetlands for cleaning water. Water quality has deteriorated throughout the basin and high nitrogen in the Mississippi river is causing a large area of hypoxia in the Gulf of Mexico adjacent to the Mississippi delta. Since the causes of these problems are distributed over the basin, the solution also needs to be distributed over the basin. Ecotechnology and ecological engineering offer the only ecologically sound and cost-effective method of solving these problems. Wetlands to promote nitrogen removal, mainly through denitrification but also through burial and plant uptake, offer a sound ecotechnological solution. At the level of the Mississippi basin, changes in farming practices and use of wetlands for nitrogen assimilation can reduce nitrogen levels in the River. There are additional benefits of restoration of wetland and riverine ecosystems, flood control, reduction in public health threats, and enhanced wildlife and fisheries. At the local drainage basin level, the use of river diversions in the Mississippi delta can address both problems of coastal land loss and water quality deterioration. Nitrate levels in diverted river water are rapidly reduced as water flows through coastal watersheds. At the local level, wetlands are being used to treat municipal wastewater. This is a cost-effective method, which results in improved water quality, enhanced wetland productivity and increased accretion. The problems in the Mississippi basin serves as an example for other watersheds in the Gulf of Mexico. This is especially important in Mexico, where there is a strong need for economical solutions to ecological problems. The Usumacinta delta-Laguna de Terminos regional ecosystem is an example where ecotechnological approaches offer realistic solutions to environmental problems.