DOI: https://doi.org/10.21203/rs.3.rs-1534802/v1
This work aimed to improve the techniques for cultivating the species Gelidium floridanum, testing different sources of calcium. Tetraspores and explants were grown in the laboratory for 20 days with seawater enriched with 50% von Stosch solution and oyster or mussel shell powder (252 mg L− 1 and 336 mg L− 1), or calcium chloride (147 mg L− 1 and 295 mg L− 1). Tetraspores or explants cultivated with no calcium salts or shell powder were used as control. Tetraspores germination rate and morphology, and germlings morphology, average length, and growth rate were evaluated. Besides, the morphology, upright axes formation, and growth rate of explants were also evaluated. There was no difference in tetraspore germination among treatments and control. Treatments with shell powder impaired the tetraspores' viability, indicated by a greenish color, cellular disorganization, and delay in germ tube development. Germlings cultivated with CaCl2 show better initial development but with no improvement to control. Concerning explants, those cultivated with mussel shell powder showed the highest growth rate (3.92 and 4.28% day− 1, according to concentration) in relation to other treatments. In particular, those cultivated in 252 mg L− 1 showed a significant formation of upright axes (10.15 ± 0.85 upright axes) compared to the control (5.18 ± 0.42 upright axes). Based on the results, we recommend using mussel shell powder at a concentration of 252 mg L− 1 to optimize explant cultivation.
Gelidium species have commercial importance due to their higher grade and purified agar, used in pharmacological, biomedical, biotechnological industries, and other specific applications (Armisén 1991; Santos and Melo 2018). Approximately 14,500 tons of agar are produced each year, yielding around US$ 246 million (Porse and Rudolph 2017). Although agar extracted from Gelidium currently represents only about 1.6% of the world's production of phycocolloids, its high resistance to natural gelation and low gelation temperatures makes it difficult to replace it with agar extracted from other species (Santos and Melo 2018).
One of the limiting factors in agar from Gelidium production is that there are no commercial crops. The industry depends on natural stocks worldwide, which are being depleted at an alarming rate. Massive cultivation of Gelidium is still in the experimental stage, and few attempts have been made in the laboratory and field (Callaway 2015; Porse and Rodolph 2017). Strategies for small-scale cultivation of Gelidium in tanks have been carried out for a long time in Chile (Santelices 1976), India (Mairh and Rao 1978), United States (Hansen 1980), and Norway (Fredriksen and Rueness 1989). Long-line cultivation using the vegetative propagation method was carried out in China, on a small and large scale (Fei and Huang 1991), in South Africa, on experimental farms of G. robustum and G. nudifrons (Melo et al. 1991) and in India, with G. pristoides and G. pusillum (Aken et al. 1993, Veeragurunathan et al. 2018). However, none of those experiments managed to expand on a large scale, even with methods showing results to justify these attempts (Yarish and Pereira 2008).
Most of these Gelidium cultivation works are based on vegetative propagation or spores' germination. In both cases, the calcium ion (Ca2+) presence is fundamental for its development (Santelices 1991; Simioni et al. 2015; Bouvie 2018). Ca2+ enters through calcium channels, increasing its concentration gradient in the region where the germ tube is formed; it regulates actin filaments and induces seaweed growth (Derksen et al. 1995; Filipin et al. 2019).
In plants and animals, it is well established that cell polarization occurs due to the involvement of the cytoskeleton, mainly in the growth and early development of eukaryotic organisms (Green et al. 2013). Cytoskeletal proteins, such as microtubules and filamentous actin (F-actin), are responsible for the organelle's movement, vesicle targeting, and cell organization (Cárdenas et al. 2008, Cai and Cresti 2010). In experiments using cytoskeletal blockers in tetraspores of G. floridanum, Filipin et al. (2019) concluded that F-actin directed the cell wall components and contributed to maintaining chloroplast shape and elongation during the germ tube formation. Therefore, it seems that extracellular calcium is essential for the organization of microtubules and consequent organization and cell growth. In fact, Bouvie (2018) observed an acceleration in germ tube formation of G. floridanum spores cultivated with different concentrations of CaCl2, compared to the control, with no CaCl2 addition in the culture medium.
However, when considering large-scale production, the use of CaCl2 can be costly. Considering that the mollusks shell is a cheap and available source of calcium, this work aimed to evaluate the effect of the calcium salts from these shells in tetraspores and explants development of the G. floridanum species.
Gelidium floridanum tetrasporophytes were collected during low tide, on the rocky shore of Sambaqui beach (27°29′18.8″ S and 48°32'12.9″ W), located in Florianopolis, State of Santa Catarina, and transported in dark containers to the Seaweed Laboratory (LCM Macroalgas) of the Federal University of Santa Catarina (UFSC). Once in the laboratory, samples were brushed and cleaned with sterilized seawater. The seawater was passed through 25, 10, and 5 mm filters and sterilized by an ultraviolet lamp (UV).
Tetrasporophytic thalli were acclimated in 1 L conical flasks with sterile seawater enriched with 50% von Stosch solution (McLachlan 1973), 35‰ salinity, temperature 24 ± 1°C, 12 h photoperiod, 50 µmol photons m− 2 s− 1 irradiance and constant aeration one week before the experiment for acclimation.
Shells of Crassostrea gigas oysters and Perna perna mussels were collected in the Marine Farms Atlântico Sul and Marpesca, located at Florianopolis. They were cleaned, sanitized with 2% sodium hypochlorite, rinsed abundantly in freshwater, and placed in the oven for 48 hours at 100 ºC. After drying, they were griding in the Laboratory of Vitroceramic Materials (VitroCer) at the Mechanical Engineering Department of UFSC, using the Hammer Mill (Servitech CT-058) to obtain smaller parts and the Planetary Mill (Servitech CT-242) to transform particles into powder.
Two standard solutions (1 and 2 mM) of calcium chloride (Ca1 and Ca2, respectively) were prepared with sterilized seawater, based on Bouvie (2018). Two mussel powder (Mx1 and Mx2) and two oyster powder (Os1 and Os2) solutions were also prepared with sterilized seawater, based on the best concentrations (252 mg L− 1 and 336 mg L− 1, respectively) found by Zhou et al. (2016). These solutions were placed in beakers with aeration for five days. After this period, they were filtered in low pressure with a 47 mm glass fiber microfilter to remove residues. The calcium ion concentration (Ca2+) was quantified by the Analysis Center of the Chemistry Laboratory (EQA) of UFSC, as follow:
- Ca1: 39.2 mg L− 1 and Ca2: 78.4 mg L− 1;
- Mx1: 68 mg L− 1 and Mx2: 106 mg L− 1
- Os1: 84 mg L− 1 and Os2:133 mg L− 1.
The culture medium was composed of sterilized seawater enriched with 50% von Stosch solution supplemented with one of these solutions (treatments). Only sterilized seawater enriched with 50% von Stosch solution was used as a control.
Fertile tetrasporophytes were placed on four slides inside 2 L white plastic boxes with 500 mL of culture media for tetraspores release and germination according to each treatment and control, in triplicates (n = 3). After 24 h, thalli were carefully removed, and one slide from each repetition was collected for morphological analysis and germination rate quantification. The remaining slides were cultivated for 20 days under the following conditions: 24 ºC ± 1 ºC temperature, 37 ± 3 µmol photons m− 2 s− 1 irradiance, 33‰ salinity, and 12 h photoperiod. The culture medium was changed every five days. After this period, the slides were removed for morphological analyses and growth rate and seedlings' average length calculations.
For explants, healthy thalli were selected and acclimated for seven days in the culture media. In the last two days, 2 mL L− 1 of antimycotic and antibiotic solution (composed of 10,000 units mL− 1 penicillin G, 10 mg mL− 1 sulfate of streptomycin, and 25 µg mL− 1 amphotericin B - SIGMA) were added. Subsequently, the thalli were washed several times in sterilized seawater. The lateral branches were removed. The main thalli were sectioned in 5 millimeters (explants), following the methodology described by Yokoya and Handro (1997). According to the treatment or control, ten explants were cultivated in 250 mL conical flasks with culture media in the same conditions described for tetraspores cultivation for 20 days in quadruplicates (n = 4). Once a week, the culture medium was changed. At the end of the experimental period, explants were removed for morphological analyses and growth rate and seedlings' average length calculations.
Released spores were analyzed under the Leica DM500 microscope with an image capture system (OPTHD 3.7 software) at Plant Cell Biology Laboratory (LABCEV - UFSC). One hundred tetraspores of each treatment and control (n = 3) were selected at random and classified according to the following characteristics: a) germinated tetraspores (with the formation of the germ tube), b) non-germinated but viable tetraspores, and c) unfeasible tetraspores, with green pigmentation.
After 20 cultivation days, germlings and explants of each treatment and control were evaluated under Olympus SZX16 stereoscope, with an image capture system (CellSens Dimension 1.12) at the Multi-User Laboratory for Studies in Biology (LAMEB - UFSC). The growth rate was calculated according to Altamirano et al. (2003):
where GR = growth rate; Il = initial length; Fl = final length and t = days.
The length of 30 germlings from each repetition (n = 3) was measured. The length and number of upright axes at each end of the explants (n = 4) were also evaluated.
All results were submitted to a Shapiro-Wilk test to verify the normality and an F-test for homoscedasticity. One-way analysis of variance (ANOVA) was used, followed by Tukey's test. All statistical analyzes were performed using the Statistica software package (version 10.0), considering p < 0.05.
After 24 hours, germ tubes were observed both in control and treatments (Fig. 1). Control and Ca2 presented a significantly higher germination percentage (53.3 ± 10% and 66 ± 7%, respectively) (average ± standard deviation) than the other treatments (Fig. 2) (ANOVA: F6 = 9.89, p < 0.01). Tetraspores treated with shell powder showed few germinated tetraspores, and among them, most delayed the germ tube's formation (Figs. 1d to 1g) with change in cell division pattern.
Viable tetraspores that did not germinate but showed reddish coloration (Fig. 1) presented significant differences in Ca1 e Ca2 to the Mx1 and control, presenting the lowest viable rate tetraspores (ANOVA F6 = 3.82, p = 0.0049). Unviable tetraspores were presented in all treatments and control, indicated by the greenish color (Fig. 1). Tetraspores of Mx1 showed an unviable tetraspore rate significantly higher them those from Os1 treatment, but with no difference among other treatments and control (Fig. 2) (ANOVA F6 = 2.90, p = 0.021).
After 20 cultivation days, well-developed seedlings in clusters formation were observed. Two specific patterns were identified among seedlings treated with shells powder and CaCl2 (Fig. 3). The first pattern was characterized by dense clusters with homogeneous germlings observed in control and treatments Ca1 and Ca2 (Figs. 3a to 3c). The second pattern showed seedlings of several sizes, observed in shell powder treatments (Figs. 3d to 3g). Control and treatments presented rhizoid formation.
Germlings from Ca2 treatment showed length significantly higher (847.7 ± 139.6 µm) than those from shell powder treatments but similar to control (805.9 ± 143 µm) and Ca1 treatment (697.1 ± 26.7 µm) (average ± standard deviation) (ANOVA F6 = 8.42, p < 0.01). On the other hand, germlings from Os1 were significantly shorter (389.7 ± 82.8 µm) than control and those from treatments with CaCl2 but similar to the other treatments with shell powder (Fig. 4A). In general, growth rates were similar among the treatments and control, except again for germlings from Os1 treatment, which show growth rates significantly lower than control and CaCl2 treatments but similar to the shell powder treatments (Fig. 4B) (ANOVA F6 = 9.14, p < 0.01).
Explants of control, Ca1, and Ca2 treatments formed the upright axes mainly at one end (Figs. 5a – 5c). Explants from Mx1 and Mx2 formed a greater amount and visibly larger upright axes at both ends than the other treatments (Figs. 5d − 5e). However, explants treated with oyster shell powder showed thalli degradation and subsequent death (Figs. 5f − 5g). For this reason, there are no Os1 and Os2 results for quantifying formed upright axes and growth rates.
Explants from Mx1 presented a significantly higher formation of upright axes (10.15 ± 0.85 upright axes) in relation to explants from control (5.18 ± 0.42 upright axes), Ca1 (5.87 ± 0.62 upright axes), and Ca2 (5.18 ± 0.40 upright axes) and similar to them from Mx2 (8.37 ± 0.45 upright axes) (Fig. 6A) (ANOVA F6 = 11.31, p < 0.01). Growth rates were also significantly higher in explants from Mx1 and Mx2 in relation to the other treatments and control (Fig. 6B) (ANOVA F6 = 10.49, p < 0.01).
The germination of Gelidium floridanum tetraspores was not stimulated by adding CaCl2, as there was no significant difference compared to the control. This result differs from Bouvie (2018), where tetraspores treated with 2 mM CaCl2 showed a significantly higher germination rate than the control and germ tube formation in 4 hours of cultivation.
In general, the shell powder caused a lower germination rate than the control. Tetraspores from these treatments showed a change in cell division pattern, with alteration in the migration of cytoplasmic content and successive cell divisions as well as an alteration in the formation of rhizoids. In particular, tetraspores treated with oyster powder started germination but died in the process, indicated by the presence of a greenish mass. This greenish mass probably comes from tetraspores that did not adhere to the substrate, dying and disintegrating (Simioni et al. 2015). Possibly, even after filtration, the shell powder solution presented microparticles deposited on the slides, making it difficult to tetraspores adhesion, causing their degradation.
Moreover, the oyster shell has calcite in its composition, making the powder finer than mussel's powder because of the less organized molecular structure and fragile bonds. This finer powder could also influence the tetraspores' development since there was an apparent difference between them and those cultivated in mussel powder. For instance, after 20 cultivation days, germlings cultivated in Ca2 showed dense clusters, while those from shell powder showed small low-density clusters. In particular, germlings from Os1, Mx1, and Mx2 were shorter than other treatments and control. Probably, these results are a consequence of what happened in the germination process, confirming the adhesion of tetraspores cultivated in shell powder.
The explants from Mx1 and Mx2 developed upright axes in both ends with significantly higher numbers and growth rates. On the other hand, explants treated with CaCl2 showed upright axes in only one extremity. The calcium gradient in the cytoplasm is responsible for F-actin organization, which results in the correct cell polarization (Hable and Hart, 2010). The higher calcium concentration CaCl2 treatment (78.4 mg L− 1) is slightly higher than the lowest mussel powder (68 mg L− 1) treatment. In this case, it seems that calcium availability is not the only factor influencing the polarization. Oyster powder treatments, in turn, resulted in the degradation of the thallus. This degradation probably is not caused by calcium since the concentration (84 and 133 mg L− 1) is slightly higher than mussel powder. Since the main component of the powder is calcium carbonate, the toxicity of carbon dioxide should be considered. Hamester et al. (2012) characterized the calcium carbonate of the same species used in the present work, finding that there are no significant differences in the percentage of calcium oxide (CaO) and sulfur trioxide (SO3); however, these oxides were the only common, and mussels powder showed more diversity in other oxides, including K2O, SiO2, SrO, Fe2O3, MgO and Al2O3. Probably, these cations are working as a buffer in the seawater, avoiding the toxicity caused by the carbonate excess. More detailed studies are needed to understand the effects of these oxides in the growth of G, floridanum.
Santa Catarina is the leading Brazilian Producer of mollusks (EPAGRI 2019). Thus, there is high consumption of mussels and oysters, generating a high amount of shell waste. These wastes can be purchased free of charge. There is no need to use a chemical process during the transformation into powder, under the conditions described, offering a sustainable solution if it could be used in Gelidium farming, replacing CaCl2.
In conclusion, the shell powder did not improve tetraspores' germination, but it can be considered to cultivate explants since it stimulates new upright axes. Mussel powder at 252 mg L− 1 is recommended rather than oyster powder.
Funding
This work was funding by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001, Fundação de Amparo à Pesquisa e Inovação do Estado de Santa Catarina (FAPESC) for the master's scholarship of Camila Pereira Bruzinga and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the Productivity Fellowship (Process number 311680/2020-8) of Leila Hayashi.
Competing interests
Not applicable
Availability of data and material
The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.
Code availability
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Authors' contributions
All authors whose names appear on the submission
1) made substantial contributions to the conception or design of the work; or the acquisition, analysis, or interpretation of data; or the creation of new software used in the work;
2) drafted the work or revised it critically for important intellectual content;
3) approved the version to be published; and
4) agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.
Acknowledgments
CPB thanks Fundação de Amparo à Pesquisa e Inovação do Estado de Santa Catarina (FAPESC) for the master's scholarship. LH thanks Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the Productivity Fellowship (Process number 311680/2020-8). This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – Brasil (CAPES) – Finance Code 001. We also thanks Fernando Zwierzikowski da Silva for the technical support and Prof. Zenilda L. Bouzon for the Plant Cell Biology Laboratory infrastructure.