Coastal zones as important habitats of coccolithophores: A study of species diversity, succession, and life‐cycle phases

Godrijan, Jelena; Young, Jeremy R.; Pfannkuchen, Daniela Marić; Robert, Paul; Pfannkuchen, Martin

doi:10.1002/lno.10801

Cited by 34 publications

(28 citation statements)

References 67 publications

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“…However, Mozetić et al (2012) and Marić et al (2012) observed a strong reduction in amplitude of this bloom from the period 1989-2002to 2003and from 1972 and some large diatoms (Dactyliosolen blavyanus, Lioloma pacificum, Guinardia striata, Asterionellopsis glacialis) were typical of this period. The presence of coccolithophores in autumn assemblages has already been reported in the eastern Adriatic Sea (Šupraha et al 2011;Cabrini et al 2012;Cerino et al 2017;Godrijan et al 2018;Skejić et al 2018). In general, autumn coccolithophores are related to high nutrient concentrations (Godrijan et al 2013), as indicated by the positive correlation between coccolithophores and phosphate concentration.…”

Section: Seasonal Cyclementioning

confidence: 56%

“…Generally, non-redtide dinoflagellates are reported to be well-adapted to thermal stratification conditions with low nutrient availability (Latasa et al 2010). The coccolithophore Rhabdolithes claviger was also identified as a distinctive summer coccolithophore in the Adriatic Sea (Bernardi Aubry et al 2006;Godrijan et al 2013;Cerino et al 2017;Godrijan et al 2018) as well as in other Mediterranean areas (Cros and Fortuño 2002;Dimiza et al 2015;Karatsolis et al 2017) and in thermal stratified waters worldwide (Okada and McIntyre 1977;Hagino et al 2000). It is reported to be related to high temperature and low nitrate concentrations (Haidar and Thierstein 2001;Bernardi Aubry et al 2006;Godrijan et al 2013).…”

Section: Seasonal Cyclementioning

confidence: 98%

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Phytoplankton temporal dynamics in the coastal waters of the north-eastern Adriatic Sea (Mediterranean Sea) from 2010 to 2017

Cerino¹,

Fornasaro²,

Kralj³

et al. 2019

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Phytoplankton community structure was analysed from 2010 to 2017 at C1-LTER, the coastal Long-Term Ecological Research station located in the Gulf of Trieste, which is the northernmost part of the Mediterranean Sea. Phytoplankton abundance and relevant oceanographic parameters were measured monthly in order to describe the seasonal cycle and interannual variability of the main phytoplankton taxa (diatoms, dinoflagellates, coccolithophores and flagellates) and to analyse their relationship with environmental conditions. Overall, phytoplankton abundances showed a marked seasonal cycle characterised by a bloom in spring, with the peak in May. During the summer, phytoplankton abundances gradually decreased until September, then slightly increased again in October and reached their minima in winter. In general, the phytoplankton community was dominated by flagellates (generally <10 µm) and diatoms co-occurring in the spring bloom. In this period, diatoms were also represented by nano-sized species, gradually replaced by larger species in summer and autumn. Phytoplankton assemblages differed significantly between seasons (Pseudo-F = 9.59; p < 0.01) and temperature and salinity were the best predictor variables explaining the distribution of the multivariate data cloud. At the interannual scale, a strong decrease of the late-winter bloom was observed in recent years with the spring bloom being the main phytoplankton increase of the year.

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Section: Seasonal Cyclementioning

confidence: 56%

Section: Seasonal Cyclementioning

confidence: 98%

Phytoplankton temporal dynamics in the coastal waters of the north-eastern Adriatic Sea (Mediterranean Sea) from 2010 to 2017

Cerino¹,

Fornasaro²,

Kralj³

et al. 2019

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“…The process of haploidization and reduction of genome size by half probably requires major reorganization in the pattern of gene expression, leading to the creation of two largely different cellular types (De Vargas and Probert ). Moreover, the expansion of the ecological niches by different life strategies may be particularly appropriate for survival in ecosystems with fluctuating nutrient availability (Godrijan et al ). We noted a difference between organic uptake by haploid and diploid phases in Isochrysidales and Coccolithales orders.…”

Section: Discussionmentioning

confidence: 99%

Mixotrophic uptake of organic compounds by coccolithophores

Godrijan

Drapeau

Balch

2020

Limnology & Oceanography

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Osmotrophy is one of the main modes of mixotrophic acquisition of carbon by phytoplankton, but historically it has been under‐investigated and its physiological and ecological relevance remains poorly understood. Here, we investigate osmotrophy in coccolithophores. Coccolithophores are one of the major contributors to the ocean biomass inhabiting both euphotic and subeuphotic depths in the marine environment. Coccolithophores demonstrate the potential to utilize a wide array of organic compounds in darkness. In experiments with BioLog Ecoplates, we screened a wide array of organic compounds as potential carbon sources, and observed that the major types of organic compounds taken up by coccolithophores were primarily carbohydrates along with a few amino acids and polymers. Furthermore, in subsequent radiotracer experiments, the uptake rates of 14C‐labeled dissolved organic carbon compounds in the dark were low relative to the maximal rates of photosynthetic carbon fixation in the light. The time course of uptake for some compounds suggests constitutive capacity for their transport, while for others the transport appears to be activated. Nonetheless, the collective slow uptake rate of a large array of organic compounds found in seawater, might be the only way that osmotrophy could fuel significant coccolithophore growth in the deep euphotic and subeuphotic zones in the sea.

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“…Coccolithophore abundance measurements were compiled from 36 studies, constituting 2534 measurements, and representing all major oceans (Table 1). These studies utilized scanning electron microscopy (SEM) to enumerate or further identify coccolithophores rather than soley relying on the more commonly utilized light or cross polarized microscopy which under-represents coccolithophore biodiversity (Godrijan et al, 2018), in particular holococcolithophores (Bollmann et al, 2002;Cerino et al, 2017). We used this data set to investigate global, and vertical distribution patterns of haploid and diploid coccolithophore life cycle phases, specifically focusing on holococcolith forming species.…”

Section: Metadata Compilationmentioning

confidence: 99%

“…While niche differentiation has been widely observed for haplo-diplontic seaweeds (Couceiro et al, 2015;Guillemin et al, 2013;Lees et al, 2018;Lubchenco and Cubit, 1980), and coccolithophores (Houdan et al, 2006;Cros and Estrada, 2013;Godrijan et al, 2018;Frada et al, 2018), to-date no research has quantitatively investigated the extent of niche overlap and niche expansion for haplo-diplontic algae. For coccolithophores this is because research has primarily focused on the diploid life phases, and relatively little is known in regards to the haploid life phase (Taylor et al, 2017;Frada et al, 2018).…”

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confidence: 99%

The haplo-diplontic life cycle expands niche space of coccolithophores

Vries¹,

Monteiro²,

Wheeler³

et al. 2020

Preprint

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Abstract. Coccolithophores are globally important marine calcifying phytoplankton that utilize a haplo-diplontic life cycle. The haplo-diplontic life cycle allows coccolithophores to divide in both life cycle phases, and has been proposed to allow coccolithophores to expand their niche space. To-date research has however largely overlooked the life cycle of coccolithophores, and has instead focused on the diploid life cycle phase. Through a synthesis of global scanning electron microscopy (SEM) coccolithophore abundance data (n = 2534), we show that the haploid life cycle phase contributes significantly to coccolithophore abundance, constituting ≈18 % of species abundance for which haploid-diploid pairs are defined. Using hypervolumes to quantify the niche space of coccolithophores, we furthermore show that the haploid and diploid life cycle phases inhabit contrasting niches, and that this allows coccolithophores to expand their niche space by ≈17 %. Our results highlight that future coccolithophore research should consider both life cycle stages, as omission of the haploid life cycle phase in current research limits our understanding of coccolithophore ecology.

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Coastal zones as important habitats of coccolithophores: A study of species diversity, succession, and life‐cycle phases

Cited by 34 publications

References 67 publications

Phytoplankton temporal dynamics in the coastal waters of the north-eastern Adriatic Sea (Mediterranean Sea) from 2010 to 2017

Phytoplankton temporal dynamics in the coastal waters of the north-eastern Adriatic Sea (Mediterranean Sea) from 2010 to 2017

Mixotrophic uptake of organic compounds by coccolithophores

The haplo-diplontic life cycle expands niche space of coccolithophores

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