First continuous marine sponge cell line established

Scientific Reports volume 13, Article number: 5766 (2023) Cite this article

2276 Accesses

1 Citations

25 Altmetric

Metrics details

The potential of sponge-derived chemicals for pharmaceutical applications remains largely unexploited due to limited available biomass. Although many have attempted to culture marine sponge cells in vitro to create a scalable production platform for such biopharmaceuticals, these efforts have been mostly unsuccessful. We recently showed that Geodia barretti sponge cells could divide rapidly in M1 medium. In this study we established the first continuous marine sponge cell line, originating from G. barretti. G. barretti cells cultured in OpM1 medium, a modification of M1, grew more rapidly and to a higher density than in M1. Cells in OpM1 reached 1.74 population doublings after 30 min, more than twofold higher than the already rapid growth rate of 0.74 population doublings in 30 min in M1. The maximum number of population doublings increased from 5 doublings in M1 to at least 98 doublings in OpM1. Subcultured cells could be cryopreserved and used to inoculate new cultures. With these results, we have overcome a major obstacle that has blocked the path to producing biopharmaceuticals with sponge cells at industrial scale for decades.

Approximately 30% of the thousands of marine natural products discovered every year originate from sponges and sponge‐derived microbes1,2,3,4. Sponges also contain structural components with potential human health applications in tissue engineering, for example, as a scaffold to grow bone implants5,6,7. Many sponge‐derived products are potential drug candidates to treat human diseases8,9,10, such as cancer11,12 and infections with viruses13, fungi14 and drug-resistant bacteria15. For example, avarol, produced by the Mediterranean sponge Dysidea avara, has a strong cytostatic effect on leukemia cells16,17 and a recently discovered compound from a sponge-derived microbe prevents growth and biofilm formation of the bacterium Staphylococcus epidermidis, which poses a risk to patients who underwent surgery as it forms biofilms on implants and medical devices18. The model organism used in this study, Geodia barretti, produces barettins, a family of anti-inflammatory and antioxidant compounds19. For a comprehensive review of various types of bioactive compounds and their effects and structures, see Han et al. 201920. Whilst their potential is enormous, sponge-derived drug candidates in various clinical trial stages face serious supply problems21. Wild harvest is unsustainable, and many compounds are too complex for chemical synthesis to be economically feasible22. Most efforts to overcome supply issues have thus focused on producing biomass using mariculture22,23,24,25 or cell culture22,26,27,28. Mariculture shows promise in some cases24,25, but culturing cells in vitro has major advantages: it allows close monitoring and control of conditions and is easy to optimize and scale up. Despite efforts of many groups, for a long time only primary cultures were established. Main obstacles in sponge cell culture were contaminating microbes and limited understanding of conditional requirements of sponge cells in vitro26.

Recently, we reported that cells of multiple sponge species could divide rapidly in M129, a sponge-specific medium developed by Munroe et al. in 201930. M1 medium is based on the defined M199 medium30, that was previously modified and used to set up primary cell cultures of various sponge species27,28,31,32,33. Amino acid concentrations were fine-tuned through multiple rounds of optimization using a genetic algorithm30. Proliferation in M1 medium was observed for cells from grass flat sponges Geodia sp. and Amphimedon erina, reef sponge Geodia neptuni and boreal deep-sea sponge G. barretti, among other species. Cultures of all 3 Geodia species divided rapidly until plateauing and could be passaged by subculturing up to 5 times and reach up to 7 population doublings (Nd) depending on the species. This was the first concrete lead for developing stable marine sponge cell lines29. While these results represented a breakthrough, the number of passages and population doublings reached in M1 medium do not yield enough biomass to produce compounds at an industrial scale. To improve these growth characteristics of sponge cells in vitro, M1 medium was used as a base to optimize other components such as vitamins, fetal bovine serum and several growth factors (Table 1), using the same genetic algorithm that was used to develop M1 medium30. This resulted in a new medium composition, OpM1. Aiming to provide proof of concept that a sponge cell line could be scaled up to produce bioactive compounds in vitro, we tested whether G. barretti cells cultured in OpM1 medium had a higher growth rate, maximum cell density and maximum number of population doublings, due to the additional components.

To compare sponge cells proliferating in M1 and OpM1, growth of cells from 3 individuals of G. barretti was measured in both media (Fig. 1). These individuals were 3 different individuals from those used in our previous study29. Cells of 3 G. barretti individuals cultured in M1 reached 0.74 population doublings (Nd) (from 3.0E+06 to 5.0E+06 ± 5.9E+05 cells/mL) after 30 min, where the cells cultured in OpM1 reached Nd = 1.74 (from 3.0E+06 to 1.0E+07 ± 9.9E+05 cells/mL) in the same period (Fig. 1). Cells of 3 G. barretti individuals in M1 reached a maximum density of 6.4E+06 ± 5.4E+05 cells/mL on average within 5 h after inoculation (Fig. 1), while cells in OpM1 medium reached a significantly (p = 1.6E−10) higher density of 1.2E+07 ± 2.3E+05 cells/mL after only 2 h (Fig. 1). After reaching their respective plateaus, the cells remained at the same density until the end of the culture (t = 48 h) in both media, with final cell densities averaging 6.9E+06 ± 1.2E+05 in M1 and a significantly higher value of 1.3E+07 ± 3.0E+05 cells/mL (p = 5.7E−14) in OpM1 (Fig. 1).

Growth curves of G. barretti cells of 3 individuals, cultured in M1 and OpM1 media. Error bars indicate the standard deviation from the average of biological (N = 3) and technical (n = 3) replicates.

OpM1 contains 13 additional components compared to M1 (see Table 1): growth factor cocktail 1 (GF1), platelet-derived growth factor (PDGF), pifithrin-α (PFTα), fetal bovine serum (FBS), insulin-transferrin-selenium-ethanolamine (ITS-X), lipid mixture-1 (LM-1), vitamin solution 1 (Vit1, consisting of sodium ascorbate (SA) and sodium pyruvate (SP)), trace elements solution (TE, consisting of sodium metasilicate and zinc sulfate), and Roswell Park Memorial Institute 1640 vitamin solution (RPMI). Effects of each component were assessed by comparing growth of cells from 1 individual of G. barretti in a set of media, in each of which a different component was absent, using OpM1 and M1 media as controls. The impact of leaving out the different components on the maximum cell density varied (Fig. 2).

Impact of the additional components in OpM1 on the growth curve of G. barretti cells from 1 individual. Cells were cultured in different OpM1 media compositions, in each of which one component was replaced by sterile dH2O. (A) OpM1-PFTα, -PDGF, or -GF1, (B) OpM1- ITS-X, -LM-1 or -FBS, (C) OpM1-Vit1, -TE or -RPMI. OpM1 and M1 were used as controls. Error bars indicate the standard deviation from the average of technical replicates (n = 3).

Without GF1, which consists of epidermal growth factor (EGF), insulin-like growth factor-1 (IGF-1) and phytohemagglutinin (PHA) (Table 1), the growth curve was the same as in M1 medium (Fig. 2A). When PHA, IGF-1 and EGF were tested separately, all medium compositions without PHA performed like M1, while the composition with PHA showed no difference with the OpM1 control (Fig. S1A). The effect of PHA on cell density was dose-dependent: concentrations below 75% of the PHA concentration in OpM1 decreased the final density of G. barretti cells (Fig. S2A). Concentrations of PHA above 100% (up to 800%) did not increase the final cell density compared to OpM1 (Figure S2B). Absence of the small chemical apoptosis inhibitor PFTα34 or FBS lowered the cell density compared to the OpM1 control after 6 h, and after 24 h the density had decreased to the same level as in the M1 control (Fig. 2A,B). When Vit1 was omitted, the final density significantly decreased compared to OpM1 (Fig. 2C). Cells cultured in OpM1 without Vit1 but with either of its components, SA and SP (Table 1), reached a lower density than in OpM1 after 6 h, but after 24 h the difference with OpM1 was no longer significant (Figure S1B). In OpM1 without PDGF, LM-1, ITS-X or RPMI, a modest but significant decrease in cell density was observed (Fig. 2A–C). TE did not significantly affect the final density reached by G. barretti cells when omitted (Fig. 2C).

Subculture experiments were carried out in both M1 and OpM1 media at 4 °C to determine the maximum number of population doublings (Ndmax) and passages that can be reached by cells of 3 G. barretti individuals. In M1 medium, cells subcultured twice a week divided until the 5th passage (P5) (Fig. 3). Cells of 3 G. barretti individuals cultured in M1 medium reached on average Ndmax = 5.1 ± 0.9 population doublings over 5 passages (Fig. 4). The Nd per passage was the highest in the first 3 passages and the cumulative Nd then plateaued, with only minor increases in cell number over the last 2 passages (Figs. 3 and 4). In contrast, for G. barretti cells cultured in OpM1, the Nd per passage was nearly constant at 1.8 ± 0.02 over 19 passages. After P19, cell densities increased for 3 passages, then decreased and cells stopped growing after 25 passages and Nd = 46.9 ± 0.7 (Fig. 3). Cells cryopreserved at the time of the 16th passage were used to inoculate OpM1 medium (OpM1_P16). This new culture was subcultured 30 times and reached Nd = 98.4 ± 0.8 (Fig. 4). The G. barretti cells in OpM1 continued to divide, and the Ndmax remains to be determined. At each passage, a portion of the cells was cryopreserved to create a cell bank for use in future experiments.

Passaging of G. barretti cells cultured in M1 and OpM1 media. OpM1_P16 represents cell cultures restarted from cells cryopreserved at passage 16. Error bars indicate the standard deviation from the average of biological (N = 3) and technical (n = 3) replicates.

Cumulative population doublings (Nd) of cells from 3 individuals of G. barretti cultured in M1 and OpM1 over 5 and 25 passages, respectively. OpM1_P16 shows doublings made by cells cryopreserved after passage 16 and used to start a new culture in OpM1, which continued for at least 30 more passages (46 passages total). Error bars indicate the standard deviation from the average of biological (N = 3) and technical (n = 3) replicates.

In the first 2 passages (P1, P2), densities reached among the cells of 3 G. barretti individuals cultured in M1 varied significantly. In P1, the cells of 1 individual (GB1) reached 5.9E + 06 ± 3.6E + 05 cells/mL, while the other 2 individuals reached higher cell densities of 1.0E+07 ± 6.6E+05 (GB2) and 8.1E+06 ± 5.1E+05 cells/mL (GB3), respectively. A similar pattern was observed in P2, where these individuals reached cell densities of 6.4E+06 ± 2.9E+05 (GB1), 9.8E+06 ± 4.6E+05 (GB2), and 7.7E+06 ± 4.5E+05 (GB3) cells/mL, respectively. Although this pattern of individual variation was not observed in P3 and P4, it occurred in P5. It should be noted that starting densities were calculated, rather than counted, by dividing the counted cell density by the dilution factor. This could also partially account for variations in starting and final cell densities between samples. Cells in OpM1 medium reached higher densities than those in M1 with little individual variation (Fig. 3).

18S rRNA gene sequencing was used prior to inoculation (P0) and after 19 passages (P19) to confirm that the cells growing in culture were G. barretti cells. At P0 all sequences had Geodia barretti voucher ZMBN:77922 18S rRNA gene (NCBI Genbank accession number KC481224.1) as best match (97–100% identity). Although three P19 samples were discarded due to a too low number of reads obtained (< 300), from each of the G. barretti specimens at least one P19 sample was successful. Two P19 samples, Gb1_P19_2 and Gb2_P19_3, contained a small fraction of Komagataella phaffii (yeast) cells, but this was less than 1.3%. All other reads identified as 18S rRNA in the P19 samples corresponded to Geodia barretti voucher ZMBN:77922 18S rRNA gene (97–100% identity) (Fig. 5A). DNA extraction yields were low for the P19 samples (30 ng/1.0E+08 cells on average) compared to the P0 samples (500 ng/1.0E+08 cells on average) that were directly extracted from the cell banks. Another noticeable difference between the P0 and P19 was that from the P19 samples an average of 22.3% of the reads (± 23.7%) obtained returned no blast hit or returned a hit that was no 18S rRNA gene (Fig. 5B). However, sequence identity for all reads with a non-18S rRNA gene match was below 92%; these were derived from fish (salmon, carp), tomato, and a bacterium (Novospingobium pentaromativorans). It is unclear what these sequences are derived from, but they may be related to media components containing DNA, such as FBS. However, there are no indications of substantial contamination of the G. barretti cell line with other eukaryotic cells at P19.

Eukaryotic community composition of G. barretti cell cultures. (A) Distribution of 18S rRNA genes in G. barretti cell cultures from the cell banks (t0) and after passage 19 (P19) separated by the dashed line. (B) Distribution of 18S rRNA gene sequences and other sequences that were generated from the cell banks (t0) and after passage 19 (P19). The color legend indicates the best Blastn hit obtained and in parentheses the percentage of identity.

We established the first continuous marine sponge cell line, originating from the boreal deep-sea sponge G. barretti. We previously reported that cells from multiple sponge species, including G. barretti, divided rapidly in M1 medium and could be maintained for up to 5 passages and 7 population doublings29. In this study, we compared G. barretti cell growth in amino acid-optimized M1 medium30 and its derivative OpM1 medium that contains optimized concentrations of additional nutrients like growth factors, lipids, vitamins, and trace elements, among others (Table 1).

OpM1 significantly increased the growth rate and maximum cell density reached by G. barretti cells in culture, reducing the already short doubling time of less than 1 h in M1 medium to less than 30 min in OpM1. Doubling times in other animal cells are typically much longer, for example, Chinese hamster ovary (CHO) cells divide once per 20–24 h. However, sponge cells are known to proliferate rapidly in situ35,36: Within 6 h, 70.5% of all choanocytes in the sponge Mycale microsigmatosa had incorporated labelled bromodeoxyuridine (BrdU) while replicating their genome before dividing35. Sponge cells possess the same genes that regulate and drive cell cycling in all other animals37. Differences in these genes between sponges and other animals, and/or yet unknown genes or mechanisms, could have increased the speed of sponges’ replication machinery. It is also possible sponge cells do not need to replicate their genome before dividing when first placed in M1 or OpM1 medium. For example, G. barretti could possess pools of tetraploid cells (4 genome copies) that divide rapidly when the animal is damaged, as were found in other invertebrates, including the fresh‐water polyp Hydra attenuata38 and upside‐down jellyfish Cassiopea sp39. Such cell populations could be responsible for sponges’ potential to “heal” rapidly after mechanical damage40,41, although no significant pooling of tetraploid cells was observed in 2 freshwater sponge species42. Investigating how the G. barretti cell cycle progresses over multiple passages and how many genome copies cells have before and after dividing could shed light on how sponge cells proliferate so rapidly.

The maximum number of population doublings that could be reached by G. barretti cells increased from 5 doublings in M1 to at least 98 doublings in OpM1. Cells that were cryopreserved after the 16th passage were used to inoculate new cultures that could be subcultured at least 30 more times, demonstrating that the established cell line can be stored in a cell bank for future research. The G. barretti cell line continued to divide in OpM1; research is currently ongoing in our group to determine whether the number of doublings the cell line can reach is limited, or whether the G. barretti cells are naturally immortal. In humans and most other animals, somatic cells can divide a limited number of times before they become senescent43. This so-called Hayflick limit lies between 40 and 60 divisions in human cells44 and is caused by shortening of the protective telomeres at the ends of chromosomes with each replication. Once a critical length is reached, the genome becomes instable and DNA damage response halts the cell cycle45. This mechanism stops uncontrollable cell division in multicellular organisms and is partly responsible for biological aging43. Sponges46 are among a number of marine invertebrate animals, including lobsters47, scallops48, and jellyfish49, known to maintain telomerase activity in their somatic cells, regardless of their age. Therefore, it would not be surprising to learn that the G. barretti cell line is naturally immortal. Comparing telomere length in cells from different passages could provide an answer to this question.

Our results show that all additions to OpM1, except the TE solution, EGF, and IGF-1, contributed to its superior performance compared to M1, but the impact of each component varied. PHA was paramount for the difference between OpM1 and M1, which is in line with previous reports of PHA-induced proliferation in cells of other marine sponges, Axinella corrugata33 and Hymenidacidon heliophila27. Higher PHA concentrations than in OpM1 did not further increase the cell density, suggesting other factors limit the maximum cell density in G. barretti cultures. Small chemical inhibitor of p53-mediated apoptosis34 PFTα and FBS also had a large impact, and removing these components reduced G. barretti cell growth similarly. After 6 h, G. barretti cells cultured in OpM1 without either component reached densities in between M1 and OpM1. After 24 h, the cell density had decreased to the same level as in M1. Therefore, we hypothesize PFTα and FBS together can prevent apoptosis in G. barretti cells. These results provide the first insights into specific nutrients and medium components required to maintain sponge cells in vitro. However, further testing is necessary to fully understand the effect of the different components in OpM1 on G. barretti cell growth and to learn how they affect the number of times G. barretti cells can divide.

Strong interspecies variation has been observed in sponges29 and it remains to be determined whether OpM1 medium can support cells of species other than G. barretti in long-term in vitro cultures. Each species will react differently to certain medium components and culture conditions to some degree, as illustrated by differences between cells from 12 different sponge species cultured in M1 medium in our previous work29. Additionally, both M130 and OpM1 media were optimized for the Caribbean sponge D. etheria (unpublished data), in which it significantly increased metabolic activity but did not stimulate cells to divide. Individual variation needs to be considered when selecting source material29,30,50, even for species with low individual variation such as G. barretti29. Our results show that cells from the same individual can respond differently in separate experiments under the same culture conditions. While this could be because different medium batches and cryovials vary slightly, it would be beneficial to repeat (sub)culture experiments when screening sponge species and individuals. Another factor to consider is the presence and concentration of compounds of interest, or the sponge chemotype, which varies widely between species and also between individuals due to ecophysiological and seasonal factors51,52. In short, developing a production strain for any particular metabolite will require careful screening of source material, and species-specific optimizing of medium and culture conditions29.

In vitro sponge cell cultures can be used as model systems to test a wide variety of hypotheses about cell biology and how early animals evolved from unicellular organisms and developed symbiotic relationships with microbes. Metabolomics approaches can help identify pathways that synthesize secondary metabolites such as barettins. When such compounds are produced by the sponge itself, sponge cell lines can be used directly as a production platform. In cases where symbiotic microbes produce the compounds, sponge cell lines can be used to establish co-cultures with these microbes to create a production platform. The continuous G. barretti cell line presented here enables future steps to exploit the enormous potential of sponge-derived bioactive compounds.

We established the first continuous marine sponge cell line, originating from the deep-sea boreal sponge G. barretti, by culturing cells in OpM1 medium. This derivative of M1 medium with added nutrients increased the growth rate, maximum cell density and maximum number of population doublings of G. barretti cells in vitro. PHA was the most important added component in OpM1, while PFTα and FBS also had large impacts. Our results may serve as a blueprint to establish cell lines for other sponge species. Interspecific and intraspecific (individual) variation makes careful screening of source material and species- and application-specific optimization of the culture medium essential to developing sponge cell lines. Cell lines for G. barretti and other sponge species can consistently produce enough biomass to develop small-scale production platforms and supply pharmaceutically relevant compounds for clinical trial studies. Producing biopharmaceuticals with sponge cells on an industrial scale is now one step closer to becoming a reality.

Three individuals of Geodia barretti (Phylum Porifera, Class Demospongiae, Order Tetractinellida, Family Geodiidae) were collected from the ocean floor in a single trawl at a depth of ~ 500 m in a fjord close to Bergen, Norway (59°58.8″N 5°22.4″E). Cells were dissociated by squeezing fragments of the sponge through sterile gauze (B. Braun Medical, grade 16 mesh), and the resulting cell suspension was passed through a 40 μm filter to remove debris. Two wash steps followed, each consisting of centrifugation at 300 × g for 5 min and resuspension of the pellet in ASW. Cells were counted microscopically using hemocytometers (C-Chip™ Neubauer Improved, NanoEnTek) to determine cell concentrations. The cells were centrifuged once more at 300 × g for 5 min and resuspended in cryoprotectant (10% fetal bovine serum (FBS) and 10% dimethyl sulfoxide (DMSO) in ASW) at a density of approximately 1.0E + 08 cells/mL. Aliquots of 1 mL cell suspension in cryogenic vials were placed inside Nalgene® Mr. Frosty freezing containers, that cooled the cell suspension at a steady rate of 1 °C/minute when placed at −80 °C.

M130 and OpM1 culture media compositions were as described in Table 1, where stock and final concentrations, manufacturer, and catalog number for each component can be found. Salt solutions added to M199 powder in dH2O resulted in a final osmolality and salt composition close to sea water (≈1000 mOsm). Next, stock solutions for each amino acid were added to reach the desired final concentration. Before the final addition of dH2O, antimicrobials (30 µg/mL rifampicin and 3 µg/mL amphotericin B) and additional OpM1 ingredients, aliquots of the medium were stored at -20 °C for up to 1 month. When medium was required, a thawed aliquot was either supplemented with dH2O and antimicrobials to make M1 medium, or with dH2O, antimicrobials and the other ingredients required to make OpM1. The final pH of both media was ≈8.2, similar to the pH of sea water. The concentrations of components in M1 and OpM1 during medium preparation were adjusted to account for dilution by addition of the inoculum, dH2O and antimicrobials. The inoculum always made up 1/16 of the total culture volume and contained 16 × the inoculation density (3.0E + 06 cells/mL): 4.8E + 07 cells/mL in ASW.

To characterize the growth of G. barretti cells in M1 and OpM1 media, cells from three individuals of G. barretti were cultured at 4 °C for 2 days (t = 48 h). Cryopreserved cells of each individual were thawed rapidly in a water bath set to 50 °C, then transferred to 1.5 mL Eppendorf tubes. The cells were washed twice in ASW by centrifugation at 300 × g for 5 min, removal of the supernatant and subsequent resuspension in 1 mL ASW. Cell concentrations were obtained using disposable hemocytometers (C-Chip™ Neubauer Improved, NanoEnTek). The cell suspension used to inoculate the culture was 1/16 of the final culture volume and always contained 4.8E + 07 cells/mL in ASW, to obtain a starting cell density of 3.0E + 06 cells/mL. The dilution of medium components by addition of the inoculum was considered during medium preparation, so that the final concentration of each component was as described in Table 1 after addition of the inoculum. The cells were microscopically counted every hour for the first 6 h, then after 24 and 48 h. From one constantly mixed cell suspension, triplicates of 250 µL cultures (≈ 3.0 + E06 cells/mL) in 48-well plates (CELLSTAR®, Greiner Bio-one, Cat. No. 677180) were prepared for each time point (8 time points per individual).

Cells of three G. barretti individuals were cultured at 4 °C in triplicate in 48-well plates (CELLSTAR®, Greiner Bio-one, Cat. No. 677180), with 250 µL cell suspension per well and a seeding density of 3.0 + E06 cells/mL. Cultures were passaged every 3 or 4 days. Cells that adhered to the bottom of the well were resuspended in the spent medium by pipetting up and down, then cell concentrations were determined microscopically, as described above. Subsequently, part of the cell suspension was mixed with fresh M1 or OpM1 medium to dilute back to the starting density in a total volume of 250 µL per well. This was continued until the cells were no longer dividing to determine the maximum number of population doublings of the cultures in each medium.

Cells remaining after subculturing in OpM1 were cryopreserved to create a cell bank for each passage. The method described in the section ‘Sample collection, dissociation & cryopreservation’ was used, except that OpM1 was used instead of ASW in the cryoprotectant (with 10% FBS and 10% DMSO) and the cell density was lower, around 1.0E + 07 cells/mL. To start a new culture from the cryopreserved cells in the cell bank, cells of 1 G. barretti individual were thawed and washed twice with ASW, following the protocol described in ‘Growth characterization’. Cells were then inoculated in triplicate in 48-well plates (CELLSTAR®, Greiner Bio-one, Cat. No. 677180), with 250 µL cell suspension per well and a seeding density of 3.0 + E06 cells/mL, and subcultured following the method described above.

To verify the identity of the cells in culture, eukaryotic community composition was assessed from cell cultures from the three G. barretti individuals after passage 19, each cell culture in triplicate. In addition, eukaryotic community composition from triplicate cell bank samples from the same individuals were characterized. DNA was extracted from all samples using the FastDNA SPIN kit for soil (MP Biomedicals, Irvina, CA, USA) following the manufacturer’s instructions and using a pellet obtained by centrifuging cell suspension containing 1E8 cells (based on cell counts) as starting material. The concentration of the extracted DNA was determined with a Nanodrop 1000 spectrophotometer (Nanodrop Technologies, Wilmington, DE, USA), and its integrity was examined by gel electrophoresis on a 1% (w/v) agarose gel. The extracted DNA was dissolved in TE buffer and stored at -20 °C until PCR amplification. Amplification of v7-v8 region of the 18S rRNA genes was done according to Naim et al.53 with the modification that a 2-step PCR approach was applied. Briefly, in the first PCR step primers FF390 (CGATAACGAACGAGACCT) and FR1 (ANCCATTCAATCGGTANT)54 were were added to the 3’ end of Unitag1 and Unitag2, respectively55. The first PCR step was performed as in Naim et al., but with 25 instead of 30 cycles of amplification53. Subsequently, the first PCR product was used as template in a second PCR in order to add sample specific barcodes. The second PCR (5 cycles of amplification), PCR clean-up, and preparation of an equimolar mix of all samples was performed as described by Dat et al.55. The samples were sequenced on an Illumina HiSeq platform at Novogene (Cambridge, UK).

Illumina sequencing data were processed and analyzed using the NG-Tax pipeline56. Briefly, paired-end libraries were combined, and only read pairs with perfectly matching primers and barcodes were retained. To this end, both primers were barcoded to facilitate identification of chimeras produced during library generation after pooling of individual PCR products. Both forward and reverse reads were trimmed to 100 bp and concatenated to yield sequences of 200 bp. Demultiplexing, amplicon sequence variant (ASV) picking, chimera removal and taxonomic assignment were performed within one single step using the ASV_picking_pair_end_read script in NG-Tax. Reads were ranked per sample by abundance and ASVs (at a 100% identity level) were added to an initial ASV table for that sample starting from the most abundant sequence until the abundance was lower than 0.1%. The final ASV table was created by clustering the reads that were initially discarded as they represented ASVs < 0.1% of the relative abundance with the ASVs from the initial ASV table with a threshold of (98.5% similarity). Samples with < 300 reads were removed from the analysis and for all ASVs with an overall relative abundance > 0.2% and ASVs with a relative abundance > 1% in at least one sample were taxonomy assigned was by Blasting (Blastn) the ASVs against the nr/nt NCBI database on March 7, 2021. Hits were sorted based on the highest total score.

Sequencing data were deposited in the NCBI Sequence Read Archive under BioProject ID: PRJNA765353 with accession numbers: SAMN21554876-SAMN21554890. Other datasets generated and/or analyzed during the current study are available from the corresponding author upon reasonable request.

Blunt, J. W. et al. Marine natural products. Nat. Prod. Rep. 31, 160–258 (2014).

Article CAS PubMed Google Scholar

Carroll, A. R. et al. Marine natural products. Nat. Prod. Rep. 38(2), 362–413 (2021).

Article CAS PubMed Google Scholar

Leal, M. C. et al. Trends in the discovery of new marine natural products from invertebrates over the last two decades–Where and what are we bioprospecting?. PLoS ONE 7(1), e30580 (2012).

Article ADS CAS PubMed PubMed Central Google Scholar

Mehbub, M. F. et al. Marine sponge derived natural products between 2001 and 2010: Trends and opportunities for discovery of bioactives. Mar. Drugs 12(8), 4539–4577 (2014).

Article PubMed PubMed Central Google Scholar

Gabbai-Armelin, P. R. et al. Characterization and cytotoxicity evaluation of a marine sponge biosilica. Mar. Biotechnol. 21(1), 65–75 (2019).

Article CAS Google Scholar

Lin, Z. et al. In vitro evaluation of natural marine sponge collagen as a scaffold for bone tissue engineering. Int. J. Biol. Sci. 7(7), 968–977 (2011).

Article CAS PubMed PubMed Central Google Scholar

Nandi, S. K. et al. In vitro and in vivo evaluation of the marine sponge skeleton as a bone mimicking biomaterial. Integrat. Biol. 7(2), 250–262 (2015).

Article CAS Google Scholar

Abdelmohsen, U. R. et al. Potential of marine natural products against drug-resistant fungal, viral, and parasitic infections. Lancet. Infect. Dis. 17(2), e30–e41 (2017).

Article CAS PubMed Google Scholar

Rangel, M. & Falkenberg, M. An overview of the marine natural products in clinical trials and on the market. J. Coast. Life Med 3, 421–428 (2015).

CAS Google Scholar

Shinde, P., Banerjee, P. & Mandhare, A. Marine natural products as source of new drugs: A patent review (2015–2018). Expert Opin. Ther. Pat. 29(4), 283–309 (2019).

Article CAS PubMed Google Scholar

Calcabrini, C. et al. Marine sponge natural products with anticancer potential: An updated review. Marine drugs https://doi.org/10.3390/md15100310 (2017).

Article PubMed PubMed Central Google Scholar

Ruiz-Torres, V. et al. An updated review on marine anticancer compounds: The use of virtual screening for the discovery of small-molecule cancer drugs. Molecules https://doi.org/10.3390/molecules22071037 (2017).

Article PubMed PubMed Central Google Scholar

Sagar, S., Kaur, M. & Minneman, K. P. Antiviral lead compounds from marine sponges. Mar. Drugs 8(10), 2619–2638 (2010).

Article CAS PubMed PubMed Central Google Scholar

El-Hossary, E. M. et al. Antifungal potential of marine natural products. Eur. J. Med. Chem. 126, 631–651 (2017).

Article CAS PubMed Google Scholar

Liu, M. et al. Potential of marine natural products against drug-resistant bacterial infections. Lancet Infect. Dis. 19(7), e237–e245 (2019).

Article PubMed Google Scholar

Muller, W. E. et al. Avarol-induced DNA strand breakage in vitro and in Friend erythroleukemia cells. Can. Res. 47(24 Pt 1), 6565–6571 (1987).

CAS Google Scholar

Müller, W. E. G. et al. Avarol, a cytostatically active compound from the marine sponge Dysidea avara. Comp. Biochem. Physiol. Part C: Comp. Pharmacol. 80(1), 47–52 (1985).

Article Google Scholar

Balasubramanian, S. et al. A new bioactive compound from the marine sponge-derived Streptomyces sp. SBT348 inhibits staphylococcal growth and biofilm formation. Front. Microbial. 9, 1473 (2018).

Article Google Scholar

Lind, K. F. et al. Antioxidant and anti-inflammatory activities of Barettin. Mar. Drugs 11, 2655–2666 (2013).

Article PubMed PubMed Central Google Scholar

Han, B., et al., Natural products from sponges. Symbiotic Microbiomes of Coral Reefs Sponges and Corals, 2019: p. 329–463.

Singh, A. & Thakur, N. L. Significance of investigating allelopathic interactions of marine organisms in the discovery and development of cytotoxic compounds. Chem. Biol. Interact. 243, 135–147 (2016).

Article CAS PubMed Google Scholar

Sipkema, D. et al. Large-scale production of pharmaceuticals by marine sponges: Sea, cell, or synthesis?. Biotechnol. Bioeng. 90(2), 201–222 (2005).

Article CAS PubMed Google Scholar

Brummer, F. & Nickel, M. Sustainable use of marine resources: Cultivation of sponges. Prog. Mol. Subcell. Biol. 37, 143–162 (2003).

Article CAS PubMed Google Scholar

Duckworth, A. R. & Battershill, C. Sponge aquaculture for the production of biologically active metabolites: The influence of farming protocols and environment. Aquaculture 221(1), 311–329 (2003).

Article Google Scholar

Page, M. J. et al. Aquaculture trials for the production of biologically active metabolites in the New Zealand sponge Mycale hentscheli (Demospongiae: Poecilosclerida). Aquaculture 250(1), 256–269 (2005).

Article CAS Google Scholar

Grasela, J. J. et al. Efforts to develop a cultured sponge cell line: Revisiting an intractable problem. In Vitro Cell. Dev. Biol. Anim. 48, 12–20 (2012).

Article PubMed Google Scholar

Pomponi, S. A. & Willoughby, R. Sponge Cell Culture for Production of Bioactive Metabolites in Sponges in Time and Space 395–400 (Balkema, Rotterdam, 1994).

Google Scholar

Pomponi, S. A., Willoughby, R. & Kelly-Borges, M. Sponge cell culture. In Molecular Approaches to the Study of the Ocean 423–433 (Springer, 1998).

Chapter Google Scholar

Conkling, M. et al. Breakthrough in marine invertebrate cell culture: sponge cells divide rapidly in improved nutrient medium. Sci. Rep. 9(1), 17321 (2019).

Article ADS PubMed PubMed Central Google Scholar

Munroe, S. et al. Genetic algorithm as an optimization tool for the development of sponge cell culture media. In Vitro Cell. Dev. Biol. Anim. 55(3), 149–158 (2019).

Article PubMed PubMed Central Google Scholar

Pomponi, S. A. Biology of the Porifera: Cell culture. Can. J. Zool. 84, 167–174 (2006).

Article CAS Google Scholar

Pomponi, S. A. & Willoughby, R. Development of sponge cell cultures for biomedical applications. In Aquatic invertebrate cell culture (eds Mothersill, C. & Austin, B.) 323–336 (Springer-Verlag, 2000).

Google Scholar

Pomponi, S.A., et al. Development of techniques for in vitro production of bioactive natural products from marine sponges. In Proceedings from the World Congress on in vitro biology. San Fransisco, CA.

Komarov, P. G. et al. A chemical inhibitor of p53 that protects mice from the side effects of cancer therapy. Science 285(5434), 1733–1737 (1999).

Article CAS PubMed Google Scholar

Alexander, B. E. et al. Cell turnover and detritus production in marine sponges from tropical and temperate benthic ecosystems. PLoS ONE 9(10), e109486 (2014).

Article ADS PubMed PubMed Central Google Scholar

De Goeij, J. M. et al. Cell kinetics of the marine sponge Halisarca caerulea reveal rapid cell turnover and shedding. J. Exp. Biol. 212(Pt 23), 3892–3900 (2009).

Article PubMed Google Scholar

Srivastava, M. et al. The Amphimedon queenslandica genome and the evolution of animal complexity. Nature 466(7307), 720–726 (2010).

Article ADS CAS PubMed PubMed Central Google Scholar

David, C. N. & Campbell, R. D. Cell cycle kinetics and development of Hydra attenuata I. Epithelial cells. J. Cell Sci. 11(2), 557–568 (1972).

Article CAS PubMed Google Scholar

Curtis, S. K. & Cowden, R. R. Some aspects of regeneration in the Scyphistoma of Cassiopea (Class Scyphozoa) as revealed by the use of antimetabolites and microspectrophotometry. Am. Zool. 14(2), 851–866 (2015).

Article Google Scholar

Alexander, B. E. et al. Cell kinetics during regeneration in the sponge Halisarca caerulea: How local is the response to tissue damage?. PeerJ 3, e820 (2015).

Article PubMed PubMed Central Google Scholar

Ayling, A. L. Growth and regeneration rates in thinly encrusting demospongiae from temperate waters. Biol. Bull. 165(2), 343–352 (1983).

Article PubMed Google Scholar

Harrison, F. W. & Cowden, R. R. Feulgen microspectrophotometric analysis of deoxyribonucleoprotein organization in larval and adult freshwater sponge nuclei. J. Exp. Zool. 193(2), 131–135 (1975).

Article CAS PubMed Google Scholar

Shay, J. W. Role of telomeres and telomerase in aging and cancer. Cancer Discov. 6(6), 584–593 (2016).

Article CAS PubMed PubMed Central Google Scholar

Hayflick, L. The limited in vitro lifetime of human diploid cell strains. Exp. Cell Res. 37, 614–636 (1965).

Article CAS PubMed Google Scholar

Shay, J. W. & Wright, W. E. Hayflick, his limit, and cellular ageing. Nat. Rev. Mol. Cell Boil. 1(1), 72–76 (2000).

Article CAS Google Scholar

Koziol, C. et al. Sponges (Porifera) model systems to study the shift from immortal to senescent somatic cells: The telomerase activity in somatic cells. Mech. Ageing Dev. 100(2), 107–120 (1998).

Article CAS PubMed Google Scholar

Klapper, W. et al. Longevity of lobsters is linked to ubiquitous telomerase expression. FEBS Lett. 439(1–2), 143–146 (1998).

Article CAS PubMed Google Scholar

Owen, R., Sarkis, S. & Bodnar, A. Developmental pattern of telomerase expression in the sand scallop, Euvola ziczac. Invertebr. Biol. 126(1), 40–45 (2007).

Article Google Scholar

Ojimi, M. C., Isomura, N. & Hidaka, M. Telomerase activity is not related to life history stage in the jellyfish Cassiopea sp.. Comp. Biochem. Physiol. Part A Mol. Integr. Physiol. 152(2), 240–244 (2009).

Article Google Scholar

Munroe, S. et al. Comparison of cryopreservation techniques for cells of the marine sponge Dysidea etheria. Cryo Lett. 39(4), 269–278 (2018).

Google Scholar

Maslin, M. et al. Marine sponge aquaculture towards drug development: An ongoing history of technical, ecological, chemical considerations and challenges. Aquacult. Rep. 21, 100813 (2021).

Google Scholar

Page, M. J. et al. Successes and pitfalls of the aquaculture of the sponge Mycale hentscheli. Aquaculture 312(1), 52–61 (2011).

Article Google Scholar

Naim, M. A., Smidt, H. & Sipkema, D. Fungi found in Mediterranean and North Sea sponges: How specific are they?. PeerJ 5, e3722 (2017).

Article PubMed PubMed Central Google Scholar

Vainio, E.J. and J. Hantula, Direct analysis of wood-inhabiting fungi using denaturing gradient gel electrophoresis of amplified ribosomal DNA. 2000. p. 927–936.

Dat, T. T. H. et al. Archaeal and bacterial diversity and community composition from 18 phylogenetically divergent sponge species in Vietnam. PeerJ 6, e4970 (2018).

Article PubMed PubMed Central Google Scholar

Ramiro-Garcia, J., et al., NG-Tax, a highly accurate and validated pipeline for analysis of 16S rRNA amplicons from complex biomes. F1000Research, 2018. 5, (1791).

Download references

This research was supported by the European Union Horizon 2020 Project SponGES (grant agreement No. 679848) (to D.S., S.P., D.M.), the European Union Marie Curie Grant (ITN-2013-BluePharmTrain-607786) (to D.S.), the Harbor Branch Oceanographic Institute Foundation, Aquaculture and Save Our Seas Specialty License Program (to S.P.), and the National Oceanic and Atmospheric Administration, Cooperative Institute for Ocean Exploration, Research, and Technology (award number NA14OAR43202600 (to S.P.). This document reflects only the authors’ views; sponsors are not responsible for any use that may be made of the information it contains. We gratefully remember Dr. Hans Tore Rapp (University of Bergen) for his leadership in Project SponGES, his unrelenting optimism, kindness, and willingness to help us and other colleagues, for example, by collecting and transporting live Geodia barretti samples used in this paper. May his memory continue to inspire us.

Bioprocess Engineering, Wageningen University and Research, Wageningen, The Netherlands

Kylie Hesp, Jans M. E. van der Heijden, Stephanie Munroe, Dirk E. Martens, Rene H. Wijffels & Shirley A. Pomponi

Harbor Branch Oceanographic Institute, Florida Atlantic University, Fort Pierce, FL, USA

Stephanie Munroe & Shirley A. Pomponi

Laboratory of Microbiology, Wageningen University and Research, Wageningen, The Netherlands

Detmer Sipkema

Faculty of Biosciences and Aquaculture, Nord University, Bodø, Norway

Rene H. Wijffels

You can also search for this author in PubMed Google Scholar

K.H. conceived, designed, and conducted experiments, analyzed data, prepared figures for the paper, and wrote the paper. J.H. designed and conducted medium component experiments, analyzed data and reviewed drafts of the paper. S.M. conceived, designed, and conducted experiments to optimize the M1 medium composition and develop OpM1 medium. D.M. conceived and designed experiments, analyzed data, contributed reagents/materials/analysis tools, and reviewed drafts of the paper. D.S. conceived and designed experiments, analyzed data, contributed reagents/materials/analysis tools, and reviewed drafts of the paper. R.W. conceived and designed experiments, contributed reagents/materials/analysis tools, and reviewed drafts of the paper. S.P. conceived, designed, and conducted experiments, supervised the research, analyzed data, contributed reagents/materials/analysis tools, and contributed to and reviewed drafts of the paper.

Correspondence to Kylie Hesp.

The authors declare no competing interests.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and Permissions

Hesp, K., van der Heijden, J.M.E., Munroe, S. et al. First continuous marine sponge cell line established. Sci Rep 13, 5766 (2023). https://doi.org/10.1038/s41598-023-32394-x

Download citation

Received: 09 September 2022

Accepted: 27 March 2023

Published: 08 April 2023

DOI: https://doi.org/10.1038/s41598-023-32394-x

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.