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Phytoplankton community in a tropical estuarine gradient after an exceptional harmful bloom of Akashiwo sanguinea (Dinophyceae) in the Todos os Santos Bay

Abstract

The objective of this study was to evaluate variations in the composition and abundance of the phytoplankton community after an exceptional harmful bloom of Akashiwo sanguinea that occurred in Todos os Santos Bay (BTS) in early March, 2007. Samples were collected every ten days, between April, 2007 and March, 2008, from the estuarine gradient of the Paraguaçu River to BTS. The physical and chemical variables were measured in situ using a multiparameter sensor. Water samples were collected for analysis of the dissolved inorganic nutrient concentrations and for the study of composition and abundance of the microphytoplankton. Overall, 135 taxa were identified, with a higher richness of diatoms. The total cell density ranged from 2.92 × 103 to 1.16 × 107 (5.47 × 105 ± 1.69 × 106) cells L−1, with higher values in the freshwater zone than in the marine area. Five species showed peaks of abundance throughout the study, forming small blooms. Four of these blooms occurred in the rainy season, formed by the species Guinardia striata (April, 2007), Scrippsiella cf. acuminata (August, 2007), Euglena gracilis (August, 2007), and Skeletonema cf. costatum (September, 2007), while a new bloom of the species Akashiwo sanguinea occurred during the dry season (December, 2007). The environment was typically oligotrophic, with low spatiotemporal variation in the concentrations of dissolved nutrients. Even so, we observed short-term variations in the structure and composition of the phytoplankton community, demonstrated by rapid bloom events, followed by an increase in the total abundance of microphytoplankton, especially during the rainy season. The blooms did not cause any notable changes in the water column and did not present any harmful effects on the system.

Descriptors:
Algal blooms; Brazilian coast; Marine phytoplankton; Paraguaçu river estuary

INTRODUCTION

The composition and dynamics of phytoplankton communities in estuarine systems are modulated by the variability of abiotic and ecological factors such as gradients of salinity, nutrients, temperature, and inter- and intraspecific interactions (Rabalais, 2002RABALAIS, N. N. 2002. Nitrogen in aquatic ecosystems. Ambio, 31(2),102-112.; Cloern and Dufford, 2005CLOERN, J. E. & DUFFORD, R. 2005. Phytoplankton community ecology: principles applied in San Francisco Bay. Marine Ecology Progress Series, 285, 11-28.; Litchman and Klausmeier, 2008LITCHMAN, E. & KLAUSMEIER, C. A. 2008. Trait-based community ecology of phytoplankton. Annual Review of Ecology, Evolution, and Systematics, 39, 615-639.; Córdoba-Mena et al., 2020CÓRDOBA-MENA, N., FLOREZ-LEIVA, L., ATEHORTÚA, L. & OBANDO, E. 2020. Changes in phytoplankton communities in a tropical estuary in the Colombian Caribbean Sea. Estuaries and Coasts, 43, 2106-27, DOI: https://doi.org/10.1007/s12237-020-00750-z
https://doi.org/10.1007/s12237-020-00750...
). Algae are of significant ecological importance as indicators of ecosystem changes. The fluctuation of physical and chemical variables under the influence of tidal cycles and rainfall events are reflected very rapidly by phytoplankton, presenting changes in composition, diversity, and abundance of the community, thereby affecting ecosystem function (Morse et al., 2014MORSE, R. E., MULHOLLAND, M. R., EGERTON, T. A. & MARSHALL, H. G. 2014. Daily variability in phytoplankton abundance and nutrient concentrations in a tidally dominated eutrophic estuary. Marine Ecology Progress Series, 503, 59-74.; Moser et al., 2017MOSER, G. A. O., PIEDRAS, F. R., OAQUIM, A. B. J., SOUZA, D. S., LELES, S. G., DE LIMA, D. T. & FERNANDES, A. M. 2017. Tidal effects on phytoplankton assemblages in a near-pristine estuary: a trait-based approach for the case of a shallow tropical ecosystem in Brazil. Marine Ecology, 38(4), e12450, DOI: https://doi.org/10.1111/maec.12450
https://doi.org/10.1111/maec.12450...
; Affe et al., 2018AFFE, H. M. J., MENEZES, M. & NUNES, J. M. C. 2018. Microphytoplankton in a tropical oligotrophic estuarine system: spatial variations and tidal cycles. Revista Brasileira de Botânica, 41, 1-13.).

Qualitative and quantitative changes in phytoplankton community and primary productivity in tropical environments are usually related to the increase in the input of dissolved nutrients in the system (Heisler et al., 2008HEISLER, J., GLIBERT, P. M., BURKHOLDER, J. M., ANDERSON, D. M., COCHLAN, W., DENNISON, W. C., DORTCH, Q., GOBLER, C. J., HEIL, C. C., HUMPHRIES, E., LEWITUS, A., MAGNIEN, R., MARSHALL, H. G., SELLNER, K., STOCKWELL, D. A., STOECKER, D. K. & SUDDLESON, M. 2008. Eutrophication and harmful algal blooms: a scientific consensus. Harmful Algae, 8(1), 3-13, DOI: http://dx.doi.org/10.1016/j.hal.2008.08.006
http://dx.doi.org/10.1016/j.hal.2008.08....
). These changes are often related to the formation of blooms, which are usually natural events, corresponding to a significant increase in biomass in the organic production chain (Smayda, 1997SMAYDA, T. J. 1997. What is a bloom? A commentary. Limnology and Oceanography, 42(5 Pt 2), 1132-1136, DOI: https://doi.org/10.4319/lo.1997.42.5_part_2.1132
https://doi.org/10.4319/lo.1997.42.5_par...
). On the other hand, blooms of harmful species can harm ecosystem services by compromising water quality, aesthetic characteristics, and recreational activities, for example, and such blooms appear to be increasing in frequency and magnitude in different systems (Moore et al., 2008MOORE, S. K., TRAINER, V. L., MANTUA, N. J., PARKER, M. S., LAWS, E., BACKER, L. C. & FLEMING, L. E. 2008. Impacts of climate variability and future climate change on harmful algal blooms and human health. Environmental Health, 7(Suppl 2), S4, DOI: http://dx.doi.org/10.1186/1476-069X-7-S2-S4
http://dx.doi.org/10.1186/1476-069X-7-S2...
; Hallegraeff, 2010HALLEGRAEFF, G. M. 2010. Ocean climate change, phytoplankton community responses, and harmful algal blooms: a formidable predictive challenge. Journal of Phycology, 46(2), 220-235, DOI: http://dx.doi.org/10.1111/j.1529-8817.2010.00815.x
http://dx.doi.org/10.1111/j.1529-8817.20...
; Affe et al., 2016AFFE, H. M. J, CAIRES, T. A., SILVA, E. M. & NUNES, J. M. C. 2016. Floración de Trichodesmium erythraeum en la región costera tropical de Brasil. Revista de Biología Marina y Oceanografía, 51(1), 175-179, DOI: https://doi.org/10.4067/S0718-19572016000100017
https://doi.org/10.4067/S0718-1957201600...
).

Because estuarine systems are highly hydrodynamic, the trigger responsible for iniciating a bloom has yet to be identified, and short-term monitoring is required to identify rapid changes in water quality and algal biomass (Morse et al., 2014MORSE, R. E., MULHOLLAND, M. R., EGERTON, T. A. & MARSHALL, H. G. 2014. Daily variability in phytoplankton abundance and nutrient concentrations in a tidally dominated eutrophic estuary. Marine Ecology Progress Series, 503, 59-74.). In general, the bloom is detected only when it becomes visible, covering the water surface (Egerton et al., 2014EGERTON, T. A., MORSE, R. E., MARSHALL, H. G. & MULHOLLAND, M. R. 2014. Emergence of algal blooms: the effects of short-term variability in water quality on phytoplankton abundance, diversity, and community composition in a tidal estuary. Microorganisms, 2(1), 33-57, DOI: https://doi.org/10.3390/microorganisms2010033
https://doi.org/10.3390/microorganisms20...
) or due to its deleterious effects, such as the harmful algal bloom of the species Akashiwo sanguinea (Hirasaka) G. Hansen and Moestrup, which occurred in early March, 2007 in Todos os Santos Bay (BTS). This bloom caused the death of more than 50 tons of fish due to anoxic conditions in the water column and obstruction of the gills caused by the rapid increase in the biomass of this dinoflagellate (Reis-Filho et al., 2012REIS-FILHO, J. A., SILVA, E. M., NUNES, J. A. C. C. & BARROS, F. 2012. Effects of a red tide on the structure of estuarine fish assemblages in northeastern Brazil. International Review of Hydrobiology, 97(5), 389-404, DOI: https://doi.org/10.1002/iroh.201101457
https://doi.org/10.1002/iroh.201101457...
).

This bloom event revealed an important knowledge gap about phytoplankton in the Paraguaçu River estuary, which had persisted until then, although this is one of the main coastal aquatic systems of Northeastern Brazil. Thus, the present study aimed to analyze short-term variations in the composition and abundance of the phytoplankton community after the exceptional harmful bloom of Akashiwo sanguinea, as the first study on the dynamics of the community along this estuarine gradient.

METHODS

Study area

The Paraguaçu River estuarine system (12° 00’S and 13° S and 38° 30 ‘W and 39° 30’W) (Figure 1) is approximately 80 km2 in area, with a volume of about 4,650,000 m3 (Genz et al., 2008GENZ, F., LESSA, G. C. & CIRANO, M. 2008. Vazão mínima para estuários: um estudo de caso no rio Paraguaçu (BA). Revista Brasileira de Recursos Hídricos, 13(3), 73-82.). The climate of the region is hot and humid, with an average annual temperature of 24ºC (Genz et al., 2008GENZ, F., LESSA, G. C. & CIRANO, M. 2008. Vazão mínima para estuários: um estudo de caso no rio Paraguaçu (BA). Revista Brasileira de Recursos Hídricos, 13(3), 73-82.). Throughout its course, the estuarine system is affected by anthropogenic activities, which involve the artificial control of the hydrological regime by the Pedra do Cavalo dam, domestic effluent discharges, agriculture, and subsistence activities of the human populations, based on consumption and commercialization of fish and shellfish (Hydros, 2005; Lessa et al., 2001LESSA, G. C., DOMINGUEZ, J. M. L., BITTENCOURT, A. C. S. P. & BRICHTA, A. 2001. The tide and tidal circulation of Todos os Santos Bay, Northeast Brazil: a general characterization. Anais da Academia Brasileira de Ciências, 73(2), 245-261.).

Figure 1
Paraguaçu estuarine gradient - Todos os Santos Bay, with the locations of sampling stations in the freshwater zone (P1), transitional zone (P2, P3, and P4) and marine zone (P5 and P6). *The distribution of points was defined to cover the entire estuarine gradient in the sample design. The delimitation of the estuarine zones was defined posteriorly, based on an analysis of salinity (refer to Results section).

The estuarine system is divided between the low river course (freshwater zone), the Iguape Bay (transition zone), and the Paraguaçu channel, flowing into BTS (12º50 S 38º38 W) as the main tributary of the same (Genz et al., 2008GENZ, F., LESSA, G. C. & CIRANO, M. 2008. Vazão mínima para estuários: um estudo de caso no rio Paraguaçu (BA). Revista Brasileira de Recursos Hídricos, 13(3), 73-82.). The BTS is about 1223 km2 in length and has an average depth of 9.8 m (Cirano and Lessa, 2007CIRANO, M. & LESSA, G. C. 2007. Oceanographic characteristics of Baía de Todos os Santos, Brazil. Revista Brasileira de Geofísica, 25(4), 363-387.). Internal circulation in the bay is forced by semi-diurnal tides, which, in addition to the seasonal pattern of wind circulation, the main forcing factor in the surface layers, conditions a well-mixed water column with oceanic characteristics (Lessa et al., 2009LESSA, G. C., CIRANO, M., GENZ, F., TANAJURA, C. A. S. O. & SILVA, R. R. 2009. Oceanografia Física. In: HATJE, V. & ANDRADE, J. B. (orgs.). Baía de Todos os Santos: aspectos oceanográficos. Salvador: EDUFBA.; Santana et al., 2018SANTANA, R., TEIXEIRA, C. & LESSA, G. 2018. The impact of different forcing agents on the residual circulation in a tropical estuary (Baía de Todos os Santos, Brazil). Journal of Coastal Research, 34(3), 544-558, DOI: https://doi.org/10.2112/JCOASTRES-D-17-00044.1
https://doi.org/10.2112/JCOASTRES-D-17-0...
).

Sampling and analyses

Six stations along the course of the estuarine system (Figure 1) were sampled every ten days, over twelve months (April, 2007 to March, 2008). The physical and chemical variables (i.e., temperature, salinity, dissolved oxygen, and pH) were measured in situ, in the subsurface (~ 0.5 m depth), using a multiparameter sensor. To analyze the dissolved inorganic nutrients (i.e., nitrite, nitrate, and phosphate), 1L water samples were collected at each point using a Van Dorn bottle. The samples were immediately filtered after each collection through fiberglass filters (Whatman GF/F - 0.7 µm pore), using a vacuum pump. Aliquots of 250 mL of the filtrated volume of each sample were kept frozen until the respective analyses were carried out by the classic colorimetric method, adapted from Strickland and Parsons (1972)STRICKLAND, J. D. H. & PARSONS, T. R. 1972. A practical handbook of seawater analysis. Ottawa: Fisheries Research Board of Canada.. The rainfall data were obtained by consulting the database from the Weather Forecast and Climate Studies Center (https://www.cptec.inpe.br/).

For phytoplankton analyses, water samples (250 mL at each collection point) were collected using a plankton net (20 µm) in horizontal tows. Subsurface (~ 0.5 m depth) water samples (1L) were collected at each station using a Van Dorn bottle. Each water sample was stored in dark bottles and fixed with 1% lugol. In the laboratory, samples were analyzed on slides under a light microscope (Olympus CX31), with 200x or 400x magnification, to identify the microphytoplankton taxa. Samples were analyzed according to the Utermöhl method (1958)UTERMÖHL, H. 1958. Zur Vervollkommnung der quantitativen Phytoplankton‐Methodik. International Association of Theoretical and Applied Limnology, 9, 1-38, DOI: https://doi.org/10.1080/05384680.1958.11904091
https://doi.org/10.1080/05384680.1958.11...
, counting the entire bottom of the chamber (50 or 100 mL), under an inverted microscope (Olympus IX50) to determine microphytoplankton cell densities (cell L-1).

To characterize the microphytoplankton composition and structure along the estuarine gradient, species richness (S), Shannon diversity index (H’), Pielou’s uniformity index (J’), and abundance (cell density) were estimated. The data normality of the community abundance and environmental variables was verified using the Kolmogorov-Smirnov test; homogeneity of variance was tested using Levene’s test. The Kruskal-Wallis analysis of variance, followed by the p-values multiple comparison test, was used to assess the occurrence of significant differences (p < 0.05) in the community abundance, as well as the differences in abiotic variables in the estuarine gradient, between the dry and rainy seasons.

Spearman’s correlation tests were performed to analyze possible correlations of rainfall with salinity and of these factors with the abundance of the phytoplankton community in the estuarine gradient. Non-metric multidimensional scaling (NMDS) analysis was carried out based on distance matrices, calculated from the Bray-Curtis index, to observe the ranking of the samples as functions of the dissimilarity in species composition and abundance along the estuarine gradient, between the dry and rainy seasons. Variance partition analysis (Borcard et al., 1992BORCARD, D., LEGENDRE, P. & DRAPEAU, P. 1992. Partialling out the spatial component of ecological variation. Ecology, 73(3), 1045-1055.; Peres-Neto et al., 2006PERES-NETO, P. R., LEGENDRE, P., DRAY, S. & BORCARD, D. 2006. Variation partitioning of species data matrices: estimation and comparison of fractions. Ecology, 87(10), 2614-2625.; Oksanen et al., 2019OKSANEN, J., BLANCHET, F. G., FRIENDLY, M., KINDT, R., LEGENDRE, P., MCGLINN, D., MINCHIN, P. R., O’HARA, R. B., SIMPSON, G. L., SOLYMOS, P., HENRY, M., STEVENS, H., SZOECS, E. & WAGNER, H. 2019. Vegan: community ecology package - 2018. R package version, 2, 17-4.) was used to verify the relative contribution of physical and chemical variables, dissolved inorganic nutrients, and rain in the microphytoplankton abundance along the estuarine gradient, in the dry and rainy seasons. All statistical analyses were performed using R statistical software (R Core Team, 2020R CORE TEAM. 2020. R: a language and environment for statistical computing. Vienna: R Foundation for Statistical Computing.).

RESULTS

Abiotic variables

Based on the variations in rainfall (Figure 2), we characterized rainy season as the months with average precipitation greater than 100 mm, with a monthly average of 151.18 (± 44.43) mm, while the monthly average in the dry period was 44.33 (± 31.68) mm. The estuarine gradient was characterized by a wide variation in salinity (Figure 2), based on which, three estuarine zones were characterized, with significant variation in salinity in both pluviometric seasons (p < 0.001): (1) freshwater zone, represented by P1 site; (2) transitional zone, represented by P2 to P4 sites; and (3) marine zone represented by P5 and P6 sites (Figure 1). We observed that in the freshwater zone, there was a clear pattern of variation in salinity as a function of rainfall (Figure 2). The Spearman test showed a negative correlation between these variables (ρ = -0.68) in this zone, with lower correlation in the transition (ρ = -0.23) and marine (ρ = -0.46) zones.

Figure 2
Monthly rainfall variability (line), and monthly and spatial salinity variability (bars) between April, 2007 and March, 2008 in the Paraguaçu estuarine gradient. FZ = freshwater zone; TZ = transitional zone; MZ = marine zone.

The other physical and chemical variables analyzed did not show significant variations along the estuarine gradient (between the zones) or between the dry and rainy seasons (p > 0.05). The water temperature presented a low average monthly variation, with the greatest amplitude of variation (7°C) occurring in the transition zone between the dry and rainy seasons. The concentrations of dissolved oxygen (OD) were occasionally below 6 mg L-1 (with > 6 being the reference value for estuaries), and the pH values showed the typical alkalinity characteristic of estuarine waters (i. e., > 7 and < 8.5) (Table 1).

Table 1
Minimum - maximum (average ± standard deviation) of environmental variables: salinity, temperature (ºC), dissolved oxygen (mg L-1), pH, concentration of dissolved inorganic nutrients: nitrite, nitrate, and phosphate (µM) in the rainy (April-September, 2007, and March, 2008) and dry (October-December, 2007, and January and February, 2008) seasons in the Paraguaçu estuarine gradient. FZ = freshwater zone; TZ = transitional zone; MZ = marine zone.

The dissolved inorganic nutrients showed concentration patterns that were characteristic of oligotrophic environments, along the estuarine gradient. Nitrite was the nutrient with the greatest variation between the two rainfall stations (Table 1), with concentrations below the detection limit of the method, at all sampling points in January (dry season). In the rainy season, significant increases in nitrite concentration were recorded in the three estuarine zones (FZ, p = 0.023; TZ, p = 0.027; MZ, p = 0.024). For nitrate, the lowest concentrations were always recorded in the marine zone (Table 1), but without significant differences (p > 0.05) with the other estuarine zones, or between the dry and rainy seasons. The same pattern of low spatio-temporal variation was recorded for phosphate (Table 1).

Structure and composition of the phytoplankton community

A total of 135 taxa were identified (Table 2). Diatoms were the most representative group (60% of taxa), followed by dinoflagellates (16%), cyanobacteria (9%), chlorophytes (5%), desmids (5%), and euglenophytes (5%). The transition zone was the area with the highest species richness, both in the dry and rainy seasons, always followed by the marine zone. The species diversity index varied between 2.91 to 4.05 bits ind-1, with an increase in the average diversity along the estuarine gradient, highest in the marine zone, as well as having a discrete increase during the dry season in the three estuarine zones (Figure 3). The same pattern was also registered for the evenness index; there was no dominance of any taxon (J’ ranged between 0.82 and 0.96) in the estuarine zones in any of the pluviometric stations.

Table 2
Phytoplankton community composition of the Paraguaçu estuarine gradient.

Figure 3
Average variation of the microphytoplankton abundance/cell density (cell L-1) (bars) and Shannon-Weaver Index (H’) (lines) in the rainy (April-September, 2007, and March, 2008) and dry seasons (October-December, 2007, and January and February, 2008) , and indication of the months of occurrence of the blooms of: Guinardia striata (TZ; April), Scrippsiella cf. acuminata (FZ; August), Euglena gracilis (TZ; August), Skeletonema cf. costatum (TZ; September) and Akashiwo sanguinea (TZ; December) in the Paraguaçu estuarine gradient. FZ = freshwater zone; TZ = transitional zone; MZ = marine zone.

The total phytoplankton density varied between 2.92 × 103 and 1.16 × 107 (5.47 × 105 ± 1.69 × 106) cells L-1. The transitional zone showed the highest average densities in both the dry and rainy seasons, except in June and July (Figure 3). Blooms of five species were identified during the study period. In the rainy season, Guinardia striata (Stolterfoth) Hasle (1.39 × 106 cell L-1), Euglena gracilis G.A.Klebs (2.71 × 106 cell L-1), and Skeletonema cf. costatum (Greville) Cleve (1.16 × 106 cell L-1), formed blooms in the transitional zone in the months of April, August and September, 2007, respectively, and Scrippsiella cf. acuminata (Ehrenberg) Kretschmann, Elbrächter, Zinssmeister, S.Soehner, Kirsch, Kusber & Gottschling (7.23 × 106 cell L-1) formed a bloom (August, 2007) in the freshwater zone. In the dry season (December, 2007), a bloom of Akashiwo sanguinea (K. Hirasaka) Gert Hansen & Moestrup (1.03 × 106 cells L-1) occurred in the transitional zone (Figure 3). Unlike the exceptional harmful bloom of this species recorded in 2007, which covered an extensive area in BTS, this new bloom occurred in a punctual area, restricted to the P3 site. All five blooms recorded showed a fast development cycle (< 10 days), and were not detected in the collections made immediately after their registries. Because they were relatively small blooms, no changes in water characteristics that could characterize potential harmful effects were detected.

In the freshwater zone, salinity was the variable that was most strongly correlated with the abundance of the species present (ρ = -0.405), and in the transitional and marine zones, in addition to salinity (ρ = -0.380 and -0.477, respectively), the species abundance was correlated with the nitrate concentrations (ρ = 0.389 and 0.463, respectively). Despite the variations recorded in the total phytoplankton abundance, with higher abundance in the rainy season (8.36 × 105 ± 2.17 × 106 cells L-1) than in the dry season (1.42 × 105 ± 2.95 × 105 cells L-1), the variance partition analysis demonstrated a low explanation of the environmental variables for community abundance (Table 3). In the rainy season, environmental variables explained 41% of the variance in the freshwater zone (residuals = 0.59%), 24% in the transition zone (residuals = 0.76%), and 16% in the marine zone (residuals = 0.84%). In the dry season, these factors explained 42% of the variance in the freshwater zone (residuals = 0.58%), 14% in the transition zone (residuals = 0.86%), and 17% in the marine zone (residuals = 0.83%). We observed that the environmental factor rain better explained community abundance in the rainy season and dissolved inorganic nutrients better explained abundance in the dry season (Table 3).

Table 3
Relative contribution (%) of environmental variables (physicochemical, nutrients and rain) to the microphytoplankton abundance in the rainy (April-September, 2007, and March, 2008) and dry (October-December, 2007, and January and February, 2008) seasons in the Paraguaçu estuarine gradient. FZ = freshwater zone; TZ = transitional zone; MZ = marine zone.

The NMDS analysis (stress = 0.16) suggested that habitat differentiation was a predominant factor for community structure in the estuarine gradient. The analysis indicated a typical pattern of ordering of samples according to the composition of freshwater species in the freshwater zone, and the overlapping of samples from the transition and marine zones (Figure 4). The freshwater species Aulacoseira sp., A. granulata (Ehrenberg) Simonsen, Dictyosphaerium sp., Euglena gracilis, Geitlerinema sp., Phacus acutus Pochmann, P. longicauda (Ehrenberg) Dujardin and Scenedesmus acuminatus (Lagerheim) Chodat, predominated in the freshwater zone. The exception was a Scrippsiella cf. acuminata bloom in the freshwater zone, which is a typical marine species but had a wide distribution in the Paraguaçu estuarine gradient. Further, Nitzschia sp. and Peridinium sp., whose genera are found in marine and freshwater habitats also predominated in the freshwater zone. The maximum abundance of these species occurred during the rainy season. In the dry season, in addition to S. cf. acuminata species, Dictyosphaerium sp. and Pleodorina sp., both freshwater species, predominated.

Figure 4
Non-metric multidimensional scaling (NMDS) analysis of the taxa identified in the three estuarine zones of the Paraguaçu estuarine gradient. FZ = freshwater zone; TZ = transitional zone; MZ = marine zone.

In the transitional zone, in addition to the species that formed blooms during the rainy season, the most abundant species were from marine habitats, with a predominance of diatoms, followed by dinoflagellates. In the dry season, besides the bloom of A. sanguinea, there was also a greater abundance of the dinoflagellate S. cf. acuminata. However, marine diatoms were predominant, with a greater abundance of the following species: Cerataulina pelagica (Cleve) Hendey, Cyclotella meneghiniana Kützing, Gyrosigma sp., Paralia sulcata (Ehrenberg) Cleve, Pseudo-nitzschia spp., Skeletonema cf. costatum, and Thalassiosira cf. leptopus (Grunow) Hasle & G.Fryxell, besides, Euglena sp. and Eutreptiella sp., both Euglenophyceans. The marine zone presented a predominance of marine diatom species, together with the marine dinoflagellate Metadinophysis sinensis Nie & Wang and the marine cyanobacteria Johannesbaptistia sp., in the rainy season. In the dry season, marine diatoms predominated: Cylindrotheca closterium (Ehrenberg) Reimann & J.C.Lewin, Guinardia delicatula (Cleve) Hasle, Pseudo-nitzschia sp., and Leptocylindrus minimus Gran.

DISCUSSION

The historical average rainfall in the region of Paraguaçu River Estuary - Todos os Santos Bay is 2,100 mm per year, with the highest rainfall recorded between April and September, and a dry season from October to March (Cirano and Lessa, 2007CIRANO, M. & LESSA, G. C. 2007. Oceanographic characteristics of Baía de Todos os Santos, Brazil. Revista Brasileira de Geofísica, 25(4), 363-387.; Hatje and Andrade, 2009HATJE, V. & ANDRADE, J. B. 2009. Baía de Todos os Santos: aspectos oceanográficos. Salvador: EDUFBA.). This pattern was verified throughout the study, with the exception of March, which presented greater precipitation (161.15 mm) than the typical average of the dry season (44.33 ± 31.68 mm).

In general, during the rainy season, greater continental drainage influences water quality standards, increasing the concentration of dissolved inorganic nutrients in estuaries, for example, due to increased inputs from rivers (Noriega et al., 2019NORIEGA, C., ARAUJO, M., FLORES-MONTES, M. & ARAUJO, J. 2019. Trophic dynamics (Dissolved Inorganic Nitrogen-DIN and Dissolved Inorganic Phosphorus-DIP) in tropical urban estuarine systems during periods of high and low river discharge rates. Anais da Academia Brasileira de Ciências, 91(2), e20180244, DOI: https://doi.org/10.1590/0001-3765201920180244
https://doi.org/10.1590/0001-37652019201...
). In the case of the Paraguaçu River estuary, the influence of the Pedra do Cavalo dam that controls the flow of freshwater in the estuarine gradient must be considered, which ats as a physical barrier, retaining the material in the river channel. However, during our study period, the dam flow data was not available.

Thus, even with the variation recorded for the volume of rainfall throughout the study, discrete variations were recorded in the pattern of dissolved nutrients in the estuarine system, which maintained oligotrophic characteristics along the estuarine gradient, in the two pluviometric seasons. In the monitoring carried out between 2013 and 2014 in Todos os Santos Bay, with points distributed from the marine zone (coinciding with the delimitation that we used in the present study), an increase in the concentrations of dissolved nutrients during the period of greatest rainfall was registered. However, Lessa et al. (2018)LESSA, G. C., SOUZA, M. F. L., MAFALDA JUNIOR, P. O., GOMES, D. F., SOUZA, C. S., TEIXEIRA, C. E. P., SOUZA, J. R. L. B. & ZUCCHI, M. R. 2018. Variabilidade intra-anual da oceanografia da Baía de Todos os Santos: evidências de três anos de monitoramento. In: HATJE, V., DANTAS, L. M. V. & ANDRADE, J. B. (orgs.). Baía de Todos os Santos: avanços nos estudos de longo prazo. Salvador: EDUFBA. identified dilution effects that maintained low nutrient concentrations in BTS, even under conditions of greater discharges into the Paraguaçu River.

We observed the typical species composition pattern from the tropical coastal environments (e.g. Rochelle-Newall et al., 2011ROCHELLE-NEWALL, E. J., CHU, V. T., PRINGAULT, O., AMOUROUX, D., ARFI, R., BETTAREL, Y., BOUVIER, T., BOUVIER, C., GOT, P., NGUYEN, T. M. H., MARI, X., NAVARRO, P., DUONG, T. N., CAO, T. T. T., PHAM, T. T., OUILLON, S. & TORRÉTON, J. P. 2011. Phytoplankton distribution and productivity in a highly turbid, tropical coastal system (Bach Dang Estuary, Vietnam). Marine Pollution Bulletin, 62(11), 2317-2329.; Chowdhury et al., 2017CHOWDHURY, M., HARDIKAR, R., KESAVAN, H. C., THOMAS, J., MITRA, A., ROKADE, M. A., NAIDU, V. S. & SUKUMARAN, S. 2017. Nutrient stoichiometry and freshwater flow in shaping of phytoplankton population in a tropical monsoonal estuary (Kundalika Estuary). Estuarine, Coastal and Shelf Science, 198(Pt A), 73-91, DOI: https://doi.org/10.1016/j.ecss.2017.08.019
https://doi.org/10.1016/j.ecss.2017.08.0...
; Saifullah et al., 2019SAIFULLAH, A. S. M., KAMAL, A. H. M., IDRIS, M. H. & RAJAEE, A. H. 2019. Community composition and diversity of phytoplankton in relation to environmental variables and seasonality in a tropical mangrove estuary. Regional Studies in Marine Science, 32, e100826, DOI: https://doi.org/10.1016/j.rsma.2019.100826
https://doi.org/10.1016/j.rsma.2019.1008...
), with greater richness of the groups Charophyta, Chlorophyta and Euglenozoa in the zone under the most direct influence of the river input, and the greater richness of diatoms, followed by dinoflagellates, in the transition and marine zones. In the rainy season, species of Cyanophyta and Chlorophyta showed a greater spatial distribution in the estuarine gradient, certainly influenced by the greater river input in the system.

The algal blooms, in principle, represent a major source of food at the base of the aquatic food chain (Smayda, 1997SMAYDA, T. J. 1997. What is a bloom? A commentary. Limnology and Oceanography, 42(5 Pt 2), 1132-1136, DOI: https://doi.org/10.4319/lo.1997.42.5_part_2.1132
https://doi.org/10.4319/lo.1997.42.5_par...
). In this sense, the blooms recorded throughout the present study can be considered as a positive increase in the abundance and biomass of primary producers in the estuarine gradient, since they did not present any detectable harmful effects. However, it is important to consider that, among the five species that formed blooms, Skeletonema cf. costatum, Scrippsiella cf. acuminata, and Akashiwo sanguinea are classified as potentially harmful species (Castro and Moser, 2012CASTRO, N. O. & MOSER, G. A. O. 2012. Florações de algas nocivas e seus efeitos ambientais. Oecologia Australis, 16(2), 235-264.), already registered as causing deleterious effects in some systems.

Skeletonema cf. costatum is a cosmopolitan, neritic species (Cupp, 1943CUPP, E. E. 1943. Marine plankton diatoms of the west coast of North America. Berkeley: University of California Press.; Hasle and Syvertsen, 1997HASLE, G. R. & SYVERTSEN, E. E. 1997. Dinoflagellates. In: TOMAS, C. R. (ed.). Identifying marine phytoplankton. San Diego: Academic Press, pp. 387-584.), commonly recorded as forming summer blooms, under conditions of high temperatures, high irradiance, little mixing in the water column, higher concentrations of phosphate, and nitrate-limited (Shikata et al., 2008SHIKATA, T., NAGASOE, S., MATSUBARA, T., YOSHIKAWA, S., YAMASAKI, Y., SHIMASAKI, Y., OSHIMA, Y., JENKINSON, I. R. & HONJO, T. 2008. Factors influencing the initiation of blooms of the raphidophyte Heterosigma akashiwo and the diatom Skeletonema costatum in a port in Japan. Limnology and Oceanography, 53(6), 2503-2518.; Liu et al., 2005LIU, D. Y., SUN, J., ZOU, J. Z. & ZHANG, J. 2005. Phytoplankton succession during a red tide of Skeletonema costatum in Jiaozhou Bay of China. Marine Pollution Bulletin, 50(1), 91-94.; Hu et al., 2011HU, H. H., ZHANG, J. & CHEN, W. D. 2011. Competition of bloom-forming marine phytoplankton at low nutrient concentrations. Journal of Environmental Sciences, 23(4), 656-663.). We observed similar conditions: rainy season, very low concentrations of nitrite (<0.01) and nitrate (0.05 µM) and higher phosphate concentration (0.13 µM) during the bloom of S. cf. costatum in the Paraguaçu estuarine system. Along the Brazilian coast, it has also been recorded at high densities in the Paranaguá Bay, influenced by the greater fluvial input, periods of high rainfall (Fernandes and Brandini, 2004FERNANDES, L. F. & BRANDINI, F. P. 2004. Diatom associations in shelf waters off Parana State, Southern Brazil: annual variation in relation to environmental factors. Brazilian Journal of Oceanography, 52(1), 19-34.) and associated with higher concentrations of ammonia in the water on the coast of Rio de Janeiro (Silva et al., 1988SILVA, N. M., VALENTIN, J. L. & BASTOS, C. T. B. 1988. O microfitoplâncton das águas costeiras do litoral fluminense (Estado do Rio de Janeiro): lista de espécies e aspectos ecológicos. Boletim do Instituto Oceanográfico, 36(1-2), 01-16.). This diatom is classified as a potentially harmful species since it can cause the death of fish and invertebrates when forming blooms with high biomass (e.g., Hallegraeff et al., 1995HALLEGRAEFF, G. M., ANDERSON, D. M. & CEMBELLA, A. D. 1995. Manual on harmful marine microalgae. IOC Manuals and Guides N° 33. Paris: UNESCO Publishing.; Moestrup et al., 2009MOESTRUP, Ø., AKSELMAN-CARDELLA, R., CRONBERG, G., ELBRAECHTER, M., FRAGA, S., HALIM, Y., HANSEN, G., HOPPENRATH, M., LARSEN, J., LUNDHOLM, N., NGUYEN, L. N. & ZINGONE, A. 2009. IOC-UNESCO taxonomic reference list of harmful microalgae [online]. Paris: UNESCO. Avaliable at: http://www.marinespecies.org/HAB [Acessed 22 Apr 2020].
http://www.marinespecies.org/HAB...
; Proença et al., 2011PROENÇA, L. A. O., FONSECA, R. S. & PINTO, T. O. 2011. Microalgas em área de cultivo do litoral de Santa Catarina. São Carlos: RiMa.). This is therefore a potential risk, considering that one of the main ecosystem services of the estuarine system of the Paraguaçu River is the provision of fish for riverside families.

A prominent ecological characteristic of Scrippsiella cf. acuminata is its efficiency in forming temporary cysts, as a form of resistance, which can remain in benthic reservoirs and return to plankton, forming blooms under favorable conditions (Cloern and Dufford, 2005CLOERN, J. E. & DUFFORD, R. 2005. Phytoplankton community ecology: principles applied in San Francisco Bay. Marine Ecology Progress Series, 285, 11-28.; Wang et al., 2007WANG, Z. H., QI, Y. Z. & YANG, Y. F. 2007. Cyst formation: an important mechanism for the termination of Scrippsiella trochoidea (Dinophyceae) bloom. Journal of Plankton Research, 29(2), 209-218.). These conditions generally include a high incidence of sunlight, high temperature, and high nutrient concentrations (Gárate-Lizárraga et al., 2009GÁRATE-LIZÁRRAGA, I., BAND-SCHMIDT, C. J., LÓPEZ-CORTÉS, D. J. & MUÑETÓN-GÓMEZ, M. D. S. 2009. Bloom of Scrippsiella trochoidea (Gonyaulacaceae) in a shrimp pond in the southwestern Gulf of California, Mexico. Marine Pollution Bulletin, 58(1), 145-149.; Okolodkov et al., 2014OKOLODKOV, Y. B., MERINO-VIRGILIO, F. D. C., AGUILAR-TRUJILLO, A. C., OSORIO-MORENO, I. & HERRERA-SILVEIRA, J. A. 2014. The genus Scrippsiella (Dinoflagellata) in coastal waters of the northern Yucatan Peninsula, SE Gulf of Mexico. Boletín de la Sociedad Mexicana de Ficología y de la Sociedad Ficológica de América Latina y el Caribe, 4, 21-32.; Kumar et al., 2018KUMAR, P. S., KUMARASWAMI, M., RAO, G. D., EZHILARASAN, P., SIVASANKAR, R., RAO, V. R. & RAMU, K. 2018. Influence of nutrient fluxes on phytoplankton community and harmful algal blooms along the coastal waters of southeastern Arabian Sea. Continental Shelf Research, 161, 20-28.). However, even in an oligotrophic system such as the Paraguaçu River estuary, this species can be favored by small nutrient inputs in periods of higher rainfall. Records of blooms causing changes in water color and the death of fish and invertebrates, due to the depletion of dissolved oxygen, have been reported even under conditions of low nutrient availability (Hallegraef, 2003HALLEGRAEFF, G. M. 2003. Harmful algal blooms: a global overview. Manual on harmful marine microalgae, 33, 1-22.; Yin et al., 2008YIN, K., SONG, X. X., LIU, S., KAN, J. & QIAN, P. Y. 2008. Is inorganic nutrient enrichment a driving force for the formation of red tides? A case study of the dinoflagellate Scrippsiella trochoidea in an embayment. Harmful Algae, 8, 54-59.).

Guinardia striata and Euglena gracilis are species that are considered non-harmful, the first a marine species and the second, a species typical of freshwater. These species are often reported as forming blooms in their respective habitats. Although Whichard et al. (2008)WICHARD, T., POULET, S. A., BOULESTEIX, A. L., LEDOUX, J. B., LEBRETON, B., MARCHETTI, J. & POHNERT, G. 2008. Influence of diatoms on copepod reproduction. II. Uncorrelated effects of diatom-derived α, β, γ, δ-unsaturated aldehydes and polyunsaturated fatty acids on Calanus helgolandicus in the field. Progress in Oceanography, 77(1), 30-44. point to possible deleterious effects of G. striata, leading to a reduction in the incubation success of eggs and an increase in the incidence of larval deformity of copepods, no ecological impacts were registered due to blooms of this species in the coastal waters of Cabo Frio - Rio de Janeiro, Ubatuba - São Paulo, and the Paranaguá Bay - Paraná. These are sites associated with conditions of high temperature, low nutrient concentration, and increased rainfall (Silva et al., 1988SILVA, N. M., VALENTIN, J. L. & BASTOS, C. T. B. 1988. O microfitoplâncton das águas costeiras do litoral fluminense (Estado do Rio de Janeiro): lista de espécies e aspectos ecológicos. Boletim do Instituto Oceanográfico, 36(1-2), 01-16.; Sassi and Kutner, 1982SASSI, R. & KUTNER, M. B. 1982. Variação sazonal do fitoplâncton da região do Saco da Ribeira (Lat. 23º30’S; Long. 45º07’W), Ubatuba, Brasil. Boletim do Instituto Oceanográfico, 31(2), 29-42.; Fernandes and Brandini, 2004FERNANDES, L. F. & BRANDINI, F. P. 2004. Diatom associations in shelf waters off Parana State, Southern Brazil: annual variation in relation to environmental factors. Brazilian Journal of Oceanography, 52(1), 19-34.), conditions similar to those recorded during the bloom period of the species in the Paraguaçu estuary.

The Euglena gracilis bloom is notable because this is an indicator species of organic pollutants (Li et al., 2014LI, M., GAO, X., WU, B., QIAN, X., GIESY, J. P. & CUI, Y. 2014. Microalga Euglena as a bioindicator for testing genotoxic potentials of organic pollutants in Taihu Lake, China. Ecotoxicology, 23(4), 633-640.). Although we have shown oligotrophic characteristics in the estuarine gradient, it must be considered that the entire region surrounding the estuary and BTS has problems with basic sanitation infrastructure, with domestic sewage discharging into the water bodies. Further, an additional potential risk of water contamination could be due to the industrial activities developed in BTS (Hatje and Andrade, 2009HATJE, V. & ANDRADE, J. B. 2009. Baía de Todos os Santos: aspectos oceanográficos. Salvador: EDUFBA.).

Harmful blooms of Akashiwo sanguinea can mainly cause conditions of anoxia in the water column, or the clogging of gills of fish and invertebrates (Hallegraeff, 2003HALLEGRAEFF, G. M. 2003. Harmful algal blooms: a global overview. Manual on harmful marine microalgae, 33, 1-22.; Jessup et al., 2009JESSUP, D. A., MILLER, M. A., RYAN, J. P., NEVINS, H. M., KERKERING, H. A., MEKEBRI, A., CRANE, D. B., JONHSON, T. A. & KUDELA, R. M. 2009. Mass stranding of marine birds caused by a surfactant-producing red tide . PLoS One, 4(2), e4550.). In BTS, the bloom of this species, which motivated the present study, was favored by conditions such as low wind intensity and high temperature, after a period of heavy rains in the region of the head of the river, which caused a high intake of freshwater into the estuarine system. This is evident from the reduction of salinity to below 30, whereas the normal range varies between 32 and 39 (Lessa et al., 2018LESSA, G. C., SOUZA, M. F. L., MAFALDA JUNIOR, P. O., GOMES, D. F., SOUZA, C. S., TEIXEIRA, C. E. P., SOUZA, J. R. L. B. & ZUCCHI, M. R. 2018. Variabilidade intra-anual da oceanografia da Baía de Todos os Santos: evidências de três anos de monitoramento. In: HATJE, V., DANTAS, L. M. V. & ANDRADE, J. B. (orgs.). Baía de Todos os Santos: avanços nos estudos de longo prazo. Salvador: EDUFBA.). Increased rainfall can result in the opening of the gates of the Pedra do Cavalo dam. This process promotes greater freshwater fluxes and consequently large dissolved nutrients input, which are carried along the estuary up to BTS.

It is suggested that the establishment of these favorable environmental conditions provided the breakdown of resistance cysts deposited in the system, thus forming an enormous bloom of A. sanguinea, as evidenced by Badylak et al. (2017)BADYLAK, S., PHLIPS, E. J., MATHEWS, A. L. & KELLEY, K. 2017. In situ observations of Akashiwo sanguinea (Dinophyceae) displaying life cycle stages during blooms in a subtropical estuary. Botanica Marina, 60(6), 653-664. in the Caloosahatchee estuary in Florida. According to the authors, the deposit of cysts subsidized the formation of a bloom, under conditions of low salinity, high temperature, and increase in the total concentrations of phosphorus and nitrogen. In estuaries subject to large freshwater inflows, A. sanguinea presents cell densities around 7.4 x 105 cells L-1, in a great range of salinities (Badylak et al., 2014), forming blooms (1.5 x 106 cells L-1) in conditions of warm surface waters and near the end of the upwelling phase (White et al., 2014WHITE, A. E., WATKINS-BRANDT, K. S., MCKIBBEN, S. M., WOOD, A. M., HUNTER, M., FOSTER, Z., DU, X. & PETERSON, W. T. 2014. Large-scale bloom of Akashiwo sanguinea in the Northern California current system in 2009. Harmful Algae, 37, 38-46, DOI: https://doi.org/10.1016/j.hal.2014.05.004
https://doi.org/10.1016/j.hal.2014.05.00...
). This species has a wide distribution in the estuarine systems of Northeast Brazil, presenting short-term variations in abundance under tidal effects (e.g.Affe et al., 2018AFFE, H. M. J., MENEZES, M. & NUNES, J. M. C. 2018. Microphytoplankton in a tropical oligotrophic estuarine system: spatial variations and tidal cycles. Revista Brasileira de Botânica, 41, 1-13.; Santos et al., 2020SANTOS, L. P. N, AFFE, H. M. J. & NUNES, J. M. C. 2020. Microfitoplâncton na Baía de Todos Os Santos (Brasil): composição, diversidade e abundância em um curto período de tempo. Acta Botanica Malacitana, 45, 27-36, DOI: https://doi.org/10.24310/abm.v45i.5301
https://doi.org/10.24310/abm.v45i.5301...
). Besides, its density increases during the rainy seasons, in low tide periods, especially under conditions of increasing concentrations of organic and inorganic phosphorus (Koening et al., 2014KOENING, M. L., FLORES MONTES, M. J., ESKINAZI LEÇA, E. & TIBURCIO, A. S. X. S. 2014. New record of Akashiwo sanguinea (Dinophyta) in the tropical estuarine waters of Northeastern Brazil (Western Atlantic). Brazilian Journal of Biology, 74(1), 191-198.).

Although blooms did not cause any notable changes in the water column, it is important to consider that a possible establishment of favorable environmental conditions can provide the formation of a more expressive bloom, which can trigger harmful effects on the system. The existence of the anthropogenic pressures and the occurrence of potentially harmful species need to be considered to better understand the dynamics of the phytoplankton community in the estuarine system, as well as to guide initiatives to mitigate possible new harmful algal blooms.

ACKNOWLEDGMENTS

LPC acknowledges Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES-Finance Code 001) for a Doctoral Scholarship. JMCN acknowledges Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq # 308542/2018-5) for a Productivity Scholarship in Research.

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Edited by

Editor: Rubens M. Lopes

Publication Dates

  • Publication in this collection
    23 Apr 2021
  • Date of issue
    2021

History

  • Received
    21 Aug 2020
  • Accepted
    19 Jan 2021
Instituto Oceanográfico da Universidade de São Paulo Praça do Oceanográfico 191, CEP: 05508-120, São Paulo, SP - Brasil, Tel.: (11) 3091-6501 - São Paulo - SP - Brazil
E-mail: diretoria.io@usp.br