Vampyrellids (Vampyrellida, Rhizaria) are a relatively easily recognizable group of predatory amoebae feeding on protists and small metazoans in aquatic and terrestrial systems [1]. They display an impressive diversity of feeding strategies varying from prey engulfment to protoplast feeding, the latter characterized by the perforation of the prey cell wall and protoplast extraction [2]. As all formally described vampyrellid species so far have been recorded in freshwater or soil ecosystems, the group was initially thought to be confined to non-marine habitats [2,3,4]. However, recent molecular surveys revealed a high diversity of these organisms in marine microbial assemblages [1]. Although the understanding of vampyrellid phylogeny and life history has improved substantially in recent years [3, 5,6,7], little is known about their abundance and impact on prey populations. Consumption of plankton prey has been observed mainly through feeding experiments [6] or algal mass cultures [7]. The putative genus Asterocaelum is the only known example of a vampyrellid preying on freshwater natural plankton assemblages, where they are frequently reported as a significant source of mortality for diatoms and cyanobacteria [8,9,10,11].

Here we present the first record of the high-frequency predator–prey dynamics for a vampyrellid in a marine system. We followed the phytoplankton dynamics in Rodrigo de Freitas Lagoon (RFL), a eutrophic coastal system in Rio de Janeiro (Brazil), from January 2012 to December 2016. Samplings were performed twice-weekly at five sampling stations (Fig. S1; see Supplementary Materials for methodological details). This lagoon is dominated by small eukaryotic phytoplankton (<20 μm) and high temporal variability [12]. The diatom Chaetoceros minimus was one of these dominant species highly fluctuating over the time series (Fig. 1a). Predation on C. minimus by a vampyrellid was first detected in July 2013 in all the sampling stations. Microscopic observations revealed that only C. minimus was consumed by Hyalodiscus sp. in both field populations and feeding experiments using cultures from other microalgal species occurring in RFL (listed in supplementary materials). Although studies on vampyrellids’ prey range are still insipient, both broad ranges of preys, including fungi, algae, and nematodes [13, 14], and trophic specialization [6] were reported. Protoplast-feeding vampyrellids have been observed so far feeding on large-sized algae [3, 5, 6, 15]. To the best of our knowledge, this is the first report of a vampyrellid with such feeding strategy preying on a nanosized planktonic microalgae.

Fig. 1
figure 1

a Healthy diatom Chaetoceros minimus, the only microalgae observed to be predated by Hyalodiscus sp. in mixed plankton assemblage from the Rodrigo de Freitas Lagoon (RFL) over the time series. be Different stages of Hyalodiscus sp.: trophozoite (amoeboid free-living, feeding stage) (b), feeding stage attached to C. minimus cells (c), digestive cysts (d), and resting cysts (e). f Maximal likelihood phylogeny (SSU rDNA) of vampyrellids showing the inclusion of Hyalodiscus sp. sequences (in blue) into Hyalodiscidae. Only bootstrap values >70% are shown (expanded tree is given in Fig. S2; see Supplementary Material for details on the analysis). Small white arrows = feeding peduncle; large black arrows = order of transition between the different Hyalodiscus sp. stages as observed in cultures from RFL (transition from resting cysts to the free-living stage is depicted with a question mark as it was not observed in cultures); arrow heads indicate the four layers of resting cyst envelops. Asterisks = individuals recorded from Lugols’ samples during quantification (others originated from cultures)

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A culture of the vampyrellid (now lost) was established using a C. minimus strain previously isolated from RFL as prey. Typical vampyrellid life stages were recognized from wild and cultured populations (Fig. 1b–e). Both trophozoites (amoeboid free-living, feeding stages) and digestive cysts having orange cytoplasmic colouration are typical for vampyrellids (e.g., refs. [3, 5]). The vampyrellid was identified as Hyalodiscus sp. based on the sequencing of the small subunit ribosomal DNA (SSU rDNA) of the obtained culture. SSU rRNA gene sequences affiliated to Hyalodiscus sp. accounted for 20–50% of the clone libraries (data not shown) when the highest abundances of the vampyrellid occurred. Maximum likelihood analysis (Fig. 1f, Fig. S2) indicated that SSU rRNA gene sequences of the cultured and environmental vampyrellids grouped together within the Hyalodiscus flabelus clade (100% bootstrap) and fell into the linage B3 [1], which was recently suggested as encompassing the family Hyalodiscidae [5]. Sequences belonging to this clade have been reported worldwide in sediments of coastal systems [1].

We observed a strong interannual environmental heterogeneity in RFL, mainly related to salinity and Brunt–Väisälä frequency (NBV; an estimate of stratification) (Fig. 2a). Dynamics of the main phytoplankton groups also reflected such variability (Fig. 2b). Of special notice was the long period of intermittent C. minimus predominance (June 2013 to August 2014) (Fig. 2c) related to high Si(OH)4 (Figs. S3, S4). Hyalodiscus sp. was observed only between July and August 2013 (Fig. 2d). The high sampling frequency allowed the detection of classic Lotka–Volterra dynamics between C. minimus and Hyalodiscus sp. (Fig. 2e), with a 6-day time lag (t−6) between the abundance peaks of the prey and its predator (cross-correlation t−6 = 0.7; p > 0.01; Fig. S5). No natural enemies (i.e., grazers or parasites) other than Hyalodiscus sp. showed such a coupled dynamic with C. minimus during its period of predominance (Alves-de-Souza, data not shown). Wavelet coherence analysis demonstrated a significant time-delayed negative interaction between prey and predator (Fig. S6), whereas multiple polynomial regressions identified the lagged (t−6) Hyalodiscus sp. abundance as the main factor affecting the abundance of its diatom prey during the period of their co-occurrence (R2 = 0.40; p < 0.001; Table S1).

Fig. 2
figure 2

a, b Interannual and seasonal variability of average values (for the five sampling stations) of water temperature (°C), salinity (PSU), Brunt–Väisälä frequency (NBV) (s−1) as an estimate of water stratification and phytoplankton biovolume (mm3 L−1). c, d Average abundance (cells ml−1) of Chaetoceros minimus (c) and Hyalodiscus sp. (d). e Detail showing the time-lagged interaction between C. minimus and Hyalodiscucs sp. (grey area in ad). f Outlying mean index (OMI) analysis showing the relative importance of environmental variables (blue vectors) to C. minimus (Cm) and Hyalosdiscus sp. (H) realized niches (depicted by grey and orange polygons, respectively). Black points represent the average mean habitat conditions of the two species for the sampling domain (delimited by the dashed line). g Distribution of samples for the entire study period in a 3-D space determined by water temperature, salinity and NBV. Samples where Hyalodiscus sp. was present are indicated in orange

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Hyalodiscus sp. showed a narrow niche breadth when compared to its prey (Fig. 2f), which was related to an apparent preference of the vampyrellid for temperatures <23 °C, intermediate salinities (12–16 PSU) and stratified conditions (NBV > 0.01 s−1) (Fig. 2g). This precise combination of abiotic parameters was observed only during Hyalodiscus sp. occurrence. Polynomial regressions based on environmental variables and time lagged values (t−6) of C. minimus abundance indicated that Hyalosdiscus sp. abundance was mostly affected by the interaction between temperature, NBV and lagged (t−6) C. minimus abundance (R2 = 0.95; p > 0.01; Table S2). A slightly different pattern was obtained for the period of C. minimus predominance, with interaction between temperature and lagged (t−6) C. minimus abundance, explaining most variability in Hyalodiscus sp. abundance (partial R2 = 0.75; p > 0.01). These results indicated that NBV was mostly important at the interannual scale and partly explained the restricted occurrence of Hyalodiscus sp. in 2013. However, the importance of this variable decreased when a shorter time period was considered because the water column was mostly stratified during the period of predominance of C. minimus. During this restricted time window, the increase in temperature may explain why Hyalodiscus disappeared even when the water column was still stratified and the prey present. Shifts in the relative importance of the environmental variables according to temporal scale have been also previously reported for other microbial communities [16, 17], including phytoplankton assemblages of RFL [12].

The restricted temporal occurrence of Hyalodiscus sp. in the RFL was in agreement with an extensive study on vampyrellids’ diversity in marine systems where only 13% of the vampyrellid sequences were recorded from pelagic samples, with the major relative abundance (87%) for this group detected in sediments [1]. While information on microbial benthic assemblages is not yet available for RFL, further studies should access the relevance of resting cysts in the sediments for the Hyalodiscus sp. predator–prey dynamics in this system. The conjunction of specific abiotic conditions (i.e., relatively low temperature, intermediate salinity and stratified waters) associated with specific prey availability seemed to determine the time window for Hyalodiscus sp. pelagic presence in RFL. Considering the worldwide distribution of vampyrellids within the Hyalodiscidae clade [1] and the cosmopolitan nature of C. minimus [18], our results provide valuable insights into the population dynamics of vampyrellids and the factors behind their elusive occurrence in plankton assemblages. They also suggest that this group can indeed be ecologically relevant in marine plankton systems, with their relative importance to the planktonic dynamics depending strongly on complex interactions between both biotic and abiotic factors.