]]>
The availability of data sets for time periods of more than a year is scarce for tropical environments. Advances in hardware and software speed-up the re-analysis of old data sets and facilitates the description of population oscillations. Using recent taxonomic literature and software we have updated and re-analized the information on crustacean diversity and population fluctuations from a set of cores collected at a mud-sand flat in the mid upper Gulf of Nicoya estuary, Pacific coast of Costa Rica (1984-1988). A total of 112 morphological species of macroinvertebrates ]]>
Pinnixa valerii, the ostracod Cyprideis pacifica, and the cumacean Coricuma nicoyensis were analized with the Generalized Additive Models of the free software R. The models evidenced a variety of population oscillations during the sampling period. These oscillations probably included perturbations induced by external factors, like the strong red tide events of 1985. In additon, ]]>
C. nicoyensis, an endemic species, are the highest reported for a tropical estuary. Comparative data from tropical tidal flat crustaceans continues to be ]]>
P. valeri, C. pacifica and C. nicoyenis.
Key words: Crustacea, ]]>
benthos, caging, estuary, tidal flat, Gulf of Nicoya, Costa Rica.
Resumen
La disponibilidad de ]]>
hardware y software pueden acelerar el re-análisis de grupos antiguos de datos y facilitar la descripción de oscilaciones poblacionales ocultas. Mediante el uso de literatura taxonómica y programas de cómputo recientes actualizamos y re-analizamos la información ]]>
Pinnixa valerii, el ]]>
Cyprideis pacifica, y el cumáceo Coricuma nicoyensis fueron analizadas con los Modelos Generales Aditivos (GAM) del programa de cómputo R de acceso libre. Los modelos evidenciaron una variedad de oscilaciones poblacionales durante el periodo de toma de muestras. Estas oscilaciones probablemente incluyen perturbaciones inducidas por factores externos, como los fuertes eventos de mareas rojas de 1985. Además, al inicio de 1984 las poblaciones podrían haber estado alteradas debido al impacto de El ]]>
Coricuma nicoyensis, una especie endémica, son las más altas informadas para un estuario tropical. Datos comparativos sobre planicies arenoso-fangosas en el ]]>
P. valeri, C. pacifica y C. nicoyenis.
Palabras clave: Crustacea, Coricuma, Cyprideis, Pinnixa, bentos, estuario, Golfo de Nicoya, Costa Rica.
From 1979 to 1983 ecological surveys were conducted in the Gulf of Nicoya estuary to provide baseline information in support of management policies (see references ]]>
Pinnixa valerii, the ostracod Cyprideis pacifica and the cumacean Coricuma nicoyensis. ]]>
Materials & Methods
The survey methods have been described in detail by Vargas (1987). In summary: cores (core area 17.7cm2, 15cm deep) were collected from February, 1984 to April, 1987 ]]>
Fig. 1). From February 1984 to February 1985 semi-monthly sampling (two sets of 14 cores per date) was conducted at 12 to 18 day intervals (25 dates), with monthly sampling afterwads (24 dates, two sets of 7 cores per date). Each set was collected at different locations within the plot. To further study population fluctuations of the cumacean C. nicoyensis, ]]>
The species lists included in Vargas (1987, 1988) was updated using Wehrtmann & Cortés (2009) and on the web with w.w.w.WORMS (World Register of Marine Species). Temporal trends were analyzed for the top three numerically abundant (in 14 cores) identified species of crustaceans (P. valerii, C. pacifica, and C. nicoyensis) with the Generalized Additive Model (GAM) of the free mgcv package in The R Project for Statistical Computing, with abundances log10 (x+1) transformed to homogenize variances (Collie et al. 2000, Stoner et al. 2001, Wood 2006). The GAM was carried out with the subroutine quasi (Wood 2006). For the first year of data we used the first of the two sets of 14 cores collected per date as input for the GAM. The mean abundances per season (with 95% confidence limits) of the three species were computed also with log10 (x+1) transformed data and back to the original scale for graphical display. To illustrate spatial variability in the abundances of P. valerii, C pacifica and C. nicoyensis, the Morisita index of dispersion (Colby & Fonseca 1984) was computed for the date with the higest number of individuals of each species. Cages (0.5x0.5x0.2m, galvanized wire, 5mm mesh) to exclude macropredators were deployed by Vargas (1988) during the dry and rainy seasons of 1985. Crustacean abundances inside and outside cages were compared with a paired t-test on log10 (x+1) transformed data. A Chi-square (χ2) test was used to compare the total number of individuals and of species inside and outside cages.
Results
Uncaged sediments
Information on environmental data is included in Vargas (1987, 1988, 1989a),Vargas & Solano (2011), and Vargas-Zamora & Sibaja-Cordero (2011). In summary: sediment composition was on the average 65% sand and 32% silt+clay. Water salinity ranged from 22‰ (rainy season) to 34‰ (dry season). Seasonal trends in sediment and water temperatures were not reported by Vargas (1987, 1988). Water temperatures above 30oC were the norm, with a maximum of 40oC on April 1984 (Vargas 1987). The estuarine water flows of the Gulf of Nicoya have been described by Voorhis et al. (1983), which are driven mainly by seasonal input of freshwater (dry season: December-April; rainy season: May-November).
The updated macrofaunal list included 112 species (Table 1) of macroinvertebrates (= retained on a 500 micron sieve) of which 29 were crustaceans (Table 1): 16 decapods, four amphipods, two cumaceans, two ostracods, two stomatopods, and one each of penaeid shrimps, mysids and tanaidaceans. In addition, other species of crustaceans reported for the site near the time of the survey, and deposited in the collections of the Museum of Zoology of the University of Costa Rica, are also included in table 1.
Abundances found at sem[i-monthly intervals during the first year (25 dates, 1st set of 14 cores), and at montly intervals afterwards were included in Figs. 2, 3 and 4, for P. valerii, C. pacifica and C. nicoyensis, respectively. These species were characterized by population fluctuations of different magnitude during the sampling period.
The application of a GAModel to the abundances of the crab P. valerii resulted (Fig. 5A) in three peaks of abundance that do not coincide with periods of either the rainy or the dry seasons during the three year study. However, peaks appear to decline shortly after the onset of the transition between seasons (F=17.80, p<0.001, Fig. 5A,B). When the pooled abundances per season were compared, no significant difference between seasons was detected (t=-1.08, p=0.285, Fig. 5C).
The GAModel applied to the abundances of the ostracod C. pacifica also evidenced (Fig. 5D) no seasonal peaks, but a declining population over the three year survey (F=19.13, p <0.001). However, in 1984-85 there were higher abundances during the dry seasons, while in 1986-87 lower abundances characterized these seasons (Fig. 5D,E). When pooled abundances per season were compared, no significant difference between seasons was detected (t=-0.50, p=0.619, Fig. 5F).
The abundance data (75 dates) for the cumacean C. nicoyensis presented in Fig. 4 showed more frequent peaks during the dry seasons, with higher values during the dry seasons of 1984, 1985, and 1988, but not as evident as during the dry season of 1986-1987. The application of a GAModel confirmed this oscillation in time (F=12.78, p<0.001, Fig. 6A,B). The abundance of this species declined from 1984 until mid 1987, when the population began a recovery (F=7.89, p<0.001, Fig. 6B). Moreover, when pooled abundances per season were compared, a highly significant difference (t=-3.76, p<0.001, Fig. 6 D) between seasons was detected.
The data on Figs 2, 3, 4 reveals a patchy distribution of the three species in time. Pachiness was also evident at the spatial scale. Differences were evident in the total abundances found in selected sets of 14 cores and collected at different positions and dates (Table 2). In addition, examples of the patchy abundance in individual cores are also included in table 2.
Caged sediments
The total number of invertebrates was found significantly higher inside cages during the rainy season only (Table 3). Crustaceans as a group was more abundant outside cages during the rainy season (Table 3). Cumaceans were found significantly more abundant outside cages than inside, and the ostracods were significantly more abundant inside cages (Table 3). The crab P. valerii decreased its abundance inside cages during the rainy season (t=5.00, p=0.002, Fig. 7A). Total abundance of C. pacifica was higher inside cages than outside during the dry season (Fig. 7B), while the cumacean C. nicoyensis had the opposite trend (Fig. 7C). C. pacifica and C. nicoyensis had very low abundances outside and inside cages during the rainy season.
Discussion
The survey in perspective
Information on environmental factors acting at different temporal and spatial scales is long overdue twenty five years after the survey of the sand-mud flat. Several of these factors were relevant in 1984-88 and continue to be relevant today: Core sampling at the sand-mud flat in the Gulf of Nicoya started in February 1984, shortly after Pacific coastal ecosystems were impacted by one of the stronger El Niño Southern Oscillation (ENSO) on record (1982-1983). This event altered global climatic patterns and raised water temperatures enough to cause severe coral mortalities on the Pacific coast of Costa Rica (Glynn et al. 1988). To what extent the intertidal macrofauna was at an altered state early in 1984 is not known. Drastic temperature oscillations caused by El Niño (warming) and La Niña (cooling) have produced important changes on the abundance and diversity of macrobenthos of intertidal and subtidal environments in Pacific Colombia and Ecuador (Tarazona et al. 1988, Vanagt et al. 2006). Was the ostracod Cyprideis pacifica taking advantage of El Niño and declined when it dissapeared remains a possibility. The most conspicuous local environmental disturbance ]]>
Tellina sp., clams found on the sediment surface on August, 1985 (Vargas-Zamora & Sibaja-Cordero 2011), other visible signs of the impact of these blooms on the benthos went unnoticed. In addition, data were not collected during July 1985. High ]]>
Pinnixa sayana collected before the red tide were not found at the site one month after the bloom. The direct impact of a toxic dinoflagellate bloon on the benthos (Wellington Harbour, 41ºS, New Zealand) has been documented by Wear & Gardner (2001) where small burrowing ]]>
Fig. 1) and offshore (Ramírez & Szelistowski 1989).
]]>
Pollution is often blamed worldwide as the cause of population fluctuations and extinctions and may also be a potential source of community change. An evaluation of trace metal concentrations in sediments and invertebrates (including several crustaceans) was conducted in the Gulf of Nicoya in 1981-82, with one station in front of Punta Morales. Trace metal concentrations in the Gulf were found comparable to those of non-industrialized estuaries (Dean et al. 1986) and no evidence of any ]]>
One other potential environmental variation that could have effected the crustacean populations in the Gulf of Nicoya at this time is changes in the sediments. According to Vargas (1996) the sediments at the study site were covered at times by a thin film of pennate diatoms. Benthic diatoms produce biofilms that modify sediment characteristics and dynamics (Brouwer
et al. 2005).
With the above mentioned stressors in mind, the population oscillations documented in this study are considered atypical for a seasonal (dry vs rainy) estuary like the Gulf of Nicoya. ]]>
The crustaceans of the uncaged sediments
The three year survey at the tropical estuarine sand-mud flat yielded an updated list of 112 species of macroinvertebrates. Dittman (2002) compared the species richness found at four ]]>
Although comparisons of latitudinal diversity gradients are useful in ecology, the lack of a standardized ]]>
et al. (2001), based on 20 estuarine surveys (including Vargas 1996) with similar methods (500 micron mesh sieve being one of them) and environmental conditions (salinity, and mean grain size), found a significant increase towards the tropics on ]]>
This study recorded 29 species (26% of the total 112) of crustaceans at the sand-mud flat. Dittmann & Vargas (2001) compared the taxonomic composition of the macrofauna in tidal flats in Australia and Central America and found that the percentages of crustacean species were between 10 to 40% and most of the species were represented by very low abundances or ]]>
Table 1 have abudances below 30 individuals).
There were 17 species of decapods found in the sand-mud flat. There are about 437 species of decapods reported for the Pacific coast of Costa Rica (Vargas & Wehrtmann 2009). The most recent (1992) trawl survey of subtidal sediments in the ]]>
table 1 is within the range reported for similar habitats on the Pacific coast of Panana (9oN), where 16 species were found on a sandy beach, 20 were associated to mangroves, and 78 to rocky substrates (Abele 1976). These surveys focused on the spatial distribution of the crustacean fauna. However, studies on temporal fluctuations of decapods are scarce for the Gulf of Nicoya estuary, and those available focused mainly on subtidal species ]]>
Callinectes arcuatus (see Dittel et al. 1985). The study by Díaz-Fergusson & Vargas-Zamora (2001) described the abundance of the intertidal porcellanid crab Petrolisthes armatus at the rocky outcrops bordering the sand-mud flat study site. No seasonal trends were detected during the one year study. But recent research on this species at Punta Morales indicates high reproductive plasticity ]]>
et al. 2011).
The abundance of crab larvae was evaluated by Dittel & Epifanio (1990) at the Punta Morales tidal creek North of the study site. They found that larval crustacean species richness was higher than in temperate estuaries and that individual taxa showed marked seasonality, athough reproduction occurred throughout the year. Crab larvae mainly of the genera U
ca, Pinnixa, Pinnotheres, Petrolisthes, and Callinectes, occurred in the plankton samples. Uca larvae, as well as those from several other decapod species, use floating mangrove leaves as a transport mechanism at the Punta Morales tidal creek (Wehrtmann & Dittel 1990). Mangrove (Rhizophora mangle, Avicenia germinans) roots provide the substrate for interactions among other Punta Morales crustaceans, like the boring isopod Sphaeroma ]]>
barnacles, and the hermit crab Clibanarius panamensis (Perry 1988).
The survey by de Goeij et al. (2003) on a tropical intertidal flat in Australia (18oS) provides examples of the diversity of population fluctuation patterns in core samples (10.3 cm2) collected monthly over a period of 72 months (1996-2001). Excluding the polychaetes (not identified in the report), ]]>
Macrophthalmus spp., 873 individuals) had population oscillations over the study period, with a maximun in 1998 and declining numbers afterwards. They found scarce evidence in support of repeated annual population cycles.
Abundances (14 ]]>
P. valerii, the ostracod C. pacifica, and the cumacean C. nicoyensis found at monthly intervals (37 dates, Feb. 1984-Feb. 1987) were illustrated by Vargas (1989a). The abundances of these three species found at semi-monthly intervals during the first year (25 ]]>
monthly intervals afterwards were included in Figs. 2, 3 and 4, respectively. The three year survey of the sand-mud flat in the Gulf of Nicoya yielded the longest data set yet available for these three species of tropical estuarine crustaceans. There has been no further research on these crustaceans. ]]>
The crab P. valerii was described by Rathbun (1931) from specimens collected in the Gulf of Nicoya. A grab survey conducted in 1980 yielded 16 species of decapods, of which P. valerii was collected at six stations ranging in depth from 9 to 24m and silt+clay from 36 to 87% (Vargas et al. 1985). ]]>
The ostracod C. pacifica was described by Hartmann (1957a,b) from estuarine habitats of El Salvador (13oN), where he reported 21 other ostracod species. C. pacifica was found on sandy sediments containing a mixture of silt+clay and detritus, and at salinities above 17‰, within a temperature range of 25 to 29oC. This species was not ]]>
C. pacifica collected at a station (no reference to type of sampling gear) by Hartmann (1957b) was 35 individuals. Swain & Gilby (1967) studied the ostracod fauna of Corinto bay (12oN) on the Pacific coast of Nicaragua and were able to identify 37 species. Cyprideis mexicana was the only one for the genus and was collected from a sandy silty-clay bottom and 36‰ water salinity. Although other ]]>
C. pacifica nor this species has been reported again from Costa Rica since 1989. From these reports it appears that the ostracod fauna of the Punta Morales site is not as species rich as that found on similar estuarine environments further North. Moreover, Vargas et al. (1985) found only two species of ostracods in a grab survey at 42 subtidal stations in the Gulf of Nicoya in 1980. However, the survey by de Goeij
et al. (2003) in Australian (18oS) intertidal flats also collected three species of ostracods, none identified to species and with total abundances of 1 071, 125 and 87 individuals, respectively, over the study period.
The abundance pattern of C. pacifica over the study period characterized a declining population. ]]>
Cyprideis torosa, a brackish water, euryhaline, eurithermic, detritus feeder ostracod also found in other temperate latitude sites. As it occurred with C. pacifica the population of C. torosa had exponential bursts of abundance, followed by exponential declines. Yearly summer population ]]>
Two species of cumaceans were collected by coring at the sand-mud flat in the Gulf of Nicoya, one of them yet unidentified. The grab survey at 42 subtidal stations in the Gulf yielded only one species ]]>
Diastylis sp.) at a station near the Punta Morales port (Vargas et al. 1985). The total number of cumacean species identified for the Pacific and Caribbean coasts of Costa Rica is about 25, with several species requiring further taxonomic work. Coricuma nicoyensis was described by Watling & Breedy (1998) from type material collected during the three year survey. The systematics of the Cumacea has been ]]>
Coricuma remains as mono-specific. C. nicoyensis is considered endemic to the Gulf of Nicoya (Foster et al. 2009). The low diversity of cumaceans is surprising for a tropical site when compared, for instance, with the 22 species found in front of the port city of Barcelona (41oN) in the Mediterranean (Corbera & Cardell 1995). However, these 22 cumaceans were found in a wider area of bottom ]]>
Iphinoe rhodanienses was found by Corbera & Cardell (1995) associated with higher (mean: 4.7%) values ]]>
2) were found near sludge discharge points. Seven species of cumaceans were also reported from a littoral survey in Japan, with half of them represented by less than 10 individuals. Bodotria similis presented spatial and temporal fluctuations in abundance, with a maximum of about 50ind./225cm2 at a littoral station, and 359ind./400cm2 at a sublittoral station (Yoda & Aoki 2002). These ]]>
C. nicoyensis at the sand-mud flat in Punta Morales, where a peak of 380ind./250cm2 was found in 14 cores on April 17, 1984. The abundances included here are the highest reported so far for a tropical cumacean. However, there were no major sources of organic pollution near the study site. A low number of cumacean species in estuarine systems appears to be the rule rather than the exception. For ]]>
2) similar to that of the Gulf of Nicoya (1 500km2), yielded only five species of which Oxyurostylis smithi was the most abundant (75% of a total of 1 789). This species had seasonal peaks of abundance correlated with higher concentrations of salinity and dissolved oxygen ]]>
C. nicoyensis during the period 1984-85 prompted Vargas (1989b) to call this a seasonal species, but the pattern was not as clear afterwards, particularly after the 1985 red tides. However, pooled abundances during the dry seasons were higher than those from the rainy seasons. Repeated seasonality of cumaceans has been reported for Diastylis rathkei in Northern Germany (54oN), with peaks during the ]]>
et al. 1982). However, more reports from tropical sites are lacking. The four year survey by de Goeij et al. (2003) of an Australian mud flat found only three cumacean specimens, and 56 gammaridean amphipods.
There were four morphological ]]>
et al. (2009) gathered about 43 ]]>
Ampelisca being the most speciose for the Pacific coast. This survey does not include the report by Vargas et al. (1985), who listed 16 records of amphipods collected during the 1980 grab survey in the Gulf of Nicoya (Maurer & Vargas 1984). Among these, only one was tentatively identified to the species level and the others to genera. A sandy (8% silt+clay, 10m depth) station yielded ten species of amphipods associated to dense mats of tubes of the chaetopterid ]]>
Mesochaetopterus alipes.
Spatial patchiness
The description of spatial patterns is an important aspect in ecological studies, as it provides indirect ]]>
2 plot to minimize the scale of spatial variability and enhace the detection of temporal patterns. However, spatial heterogeneity within the 400m2 plot was evidenced by differences in abundance for the same species in the two sets of cores taken during ]]>
2), as evidenced by Morisita`s index for the date with most individuals per species. Cumaceans in general live buried in the top sediment layer during the day and swim (mostly males) at night (Yoda & Aoki 2002), thus varying their spatial distributions daily. ]]>
Cyprideis torosa has been studied by Heip (1976b), who found that patches have a radius of about 13cm and patterns vary between sexes. The study by Colby & Fonseca (1984) on the spatial pattern (Morisita’s index) of the temperate crab
Uca pugilator indicates that this species appear to increase aggregation during the colder months.
The crustaceans of the caged sediments
Vargas (1996) conducted a caging ]]>
et al. (2004) did not find an increase in density inside cages (3mm mesh) kept for eight weeks at interidal muddy-sand flat in the Mediterranean (42oN).
The application of the caging methodology to tropical sedimentary environments has been scarce to date and the few data reported indicate a varying response of the ]]>
table 3 indicate that the cumaceans and the ostracods were responding to changes in the caged plots. Although the absense of mesh fouling and of significant changes in sedimentary characteristics (grain size, organic matter, color, topographic relief) was reported by Vargas (1988), the sediments inside the caged plots appeared softer when the cages were lifted for sampling.
Decapod crustaceans ]]>
P. valerii ) were found outside cages than inside during the rainy season when birds were more common might reflect changes on recruitment than on predation.
Birds are not the only group of ]]>
Squilla aculeata (Dittel 1991, Vargas 2009), and the blue crab Callinectes arcuatus (Dittel et al. 1985) were also found at the site. ]]>
Acknowledgments
We thank Harlan K. Dean for a review of the first draft, and two anonymous reviewers for comments on the manuscript. Sergio Aguilar prepared the figures. Cyprideis pacifica was ]]>
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*Correspondencia: José A. Vargas-Zamora: Centro de Investigación en Ciencias del Mar y Limnología (CIMAR), Universidad de Costa Rica, 11501-2060, San José, Costa Rica. javargasz@biologia.ucr.ac.cr. Escuela de Biología, Universidad de Costa Rica, 11501-2060, San José, Costa Rica. Jeffrey A. Sibaja-Cordero: Centro de Investigación en Ciencias del Mar y Limnología (CIMAR), Universidad de Costa Rica, 11501-2060, San José, Costa Rica. Escuela de Biología, Universidad de Costa Rica, 11501-2060, San José, Costa Rica; jeffro.alejandro@gmail.com Rita Vargas-Castillo: Museo de Zoología, Escuela de Biología. Universidad de Costa Rica, 11501-2060, San José, Costa Rica; rita.vargas@ucr.ac.cr ]]>
1. Centro de Investigación en Ciencias del Mar y Limnología (CIMAR), Universidad de Costa Rica, 11501-2060, San José, Costa Rica. javargasz@biologia.ucr.ac.cr 2. Escuela de Biología, Universidad de Costa Rica, 11501-2060, San José, Costa Rica; jeffro.alejandro@gmail.com 3. Museo de Zoología, Escuela de Biología. Universidad de Costa Rica, 11501-2060, San José, Costa Rica; rita.vargas@ucr.ac.cr
Received 27-II-2012. Corrected 04-V-2012. Accepted 20-VI-2012.