Preliminary data of antioxidant activity of green seaweeds (Ulvophyceae) from the Southwestern Atlantic and Antarctic Maritime islands

Bernardi, Juliane; Vasconcelos, Edson R. T. P. P. de; Lhullier, Cintia; Gerber, Thaise; Neto, Pio Colepicolo; Pellizzari, Franciane M.; Bernardi, Juliane; Vasconcelos, Edson R. T. P. P. de; Lhullier, Cintia; Gerber, Thaise; Neto, Pio Colepicolo; Pellizzari, Franciane M.

Servicios Personalizados

Revista

Articulo

Indicadores

Citado por SciELO
Accesos

Links relacionados

Similares en SciELO

Otros
Otros

Permalink

Hidrobiológica

versión impresa ISSN 0188-8897

Hidrobiológica vol.26 no.2 Ciudad de México may./ago. 2016

Articles

Preliminary data of antioxidant activity of green seaweeds (Ulvophyceae) from the Southwestern Atlantic and Antarctic Maritime islands

Datos preliminares de la actividad antioxidante de algas verdes (Ulvophyceae) del Antlántico del Sur y de las islas marítimas de Antártida

Juliane Bernardi¹^*

Edson R. T. P. P. de Vasconcelos¹

Cintia Lhullier²

Thaise Gerber³

Pio Colepicolo Neto⁴

Franciane M. Pellizzari⁵

^¹Laboratório de Macroalgas, Departamento de Oceanografia, Universidade Federal de Pernambuco. Av. Professor Moraes Rego, 1235. Cidade Universitária. CEP: 50670-901 Recife, PE. Brasil.

^²Laboratório de Química Farmacêutica, Departamento de Ciências Farmacêuticas, Universidade Federal de Santa Catarina. Florianópolis, SC. Brasil.

^³Departamento de Botânica, Universidade Federal de Santa Catarina. Florianópolis, SC. Brasil.

^⁴Departamento de Bioquímica, Instituto de Química, Universidade de São Paulo. São Paulo, SP. Brasil.

^⁵Universidade Estadual do Paraná, Campus Paranaguá. Paranaguá, Brasil.

Abstract:

Background:

Seaweeds must survive in highly competitive environments and thus develop defense strategies that may produce highly diversified antioxidant compounds.

Goals:

The main objective of this work was to assess the antioxidant activity of green seaweeds.

Methods:

Six species of ulvophycean chlorophytes were collected during spring/summer, between the Antarctic (Monostroma hariotii, Protomonostroma rosulatum and Ulva hookeriana - formerly as U. bulbosa) and the southwestern Atlantic Ocean (Gayralia brasiliensis, Protomonostroma undulatum and Ulva fasciata). They were then tested for their antioxidant activities using the 2.2-diphenyl-picrylhydrazyl (DPPH) radical scavenging method and by quantification of their phenolic (expressed as gallic acid equivalent - GAE - and carotenoid contents.

Results:

Among the evaluated species, P. rosulatum and U. hookeriana showed high antioxidant potential (77.9±2.8 and 53.1±15.0%, respectively) and high phenolic content (176±6.0 and 144.7±8.9 µg GAE g^-1, respectively). These species were collected on King George Island (South Shetland archipelago, around the Antarctic Peninsula) and their higher antioxidant potential may be associated with adaptation to the high incidence of UV rays in this region during summer. In general, tested seaweeds, mainly the samples collected in the Antarctic and Chilean Patagonia, showed higher values of phenolic (from 58.3±2.0 to 144.7±8.9 µg GAE g^-1) and carote noid contents (from 23.4±0.2 to 51.5±0.1 µg β-carotene g^-1).

Conclusions:

The presence and levels of these compounds suggest that the target seaweeds may have high antioxidant potential. Also the antioxidant activity could be associated with the occurrence area of the species instead of the order or taxonomic group to which they belong.

Key words: Green seaweeds; reactive oxygen species; phenolic contents; photoprotectants

Resumen:

Antecedentes:

Las algas marinas tienen que sobrevivir en entornos altamente competitivos, lo que hace que desarrollan estrategias de defensa que pueden dar lugar a una gran diversidad de compuestos antioxidantes.

Objetivos:

El principal objetivo de este trabajo fue evaluar la actividad antioxidante de algas verdes.

Métodos:

Seis especies de clorófitos (Ulvophyceae) recogidos durante el primavera/verano entre la Antártida (Monostroma hariotii, Protomonostroma rosulatum y Ulva hookeriana - antes como U. bulbosa) y el Atlántico Sur (Gayralia brasiliensis, Protomonostroma undulatum y Ulva fasciata) fueron probados por su actividad antioxidante usando el método de secuestro de radicales libres con 2,2-diphenil-picrylhidrazil (DPPH) y pela cuantificación de contenidos fenólicos (expreso como equivalente de ácido gálico (GAE)) y contenidos de carotenoides.

Resultados:

Entre las especies evaluadas, P. rosulatum y U. hookeriana mostraron alto potencial antioxidante (77,9±2,8 y 53,1±15%, respectivamente) y alto contenido fenólico (176±6,0 y 144,7±8,9 µg GAE g^-1, respectivamente). Estas especies fueron recolectadas en la Isla Rey Jorge (cerca de la Península Antártida) y su mayor potencial antioxidante puede estar asociado con la adaptación a la alta incidencia de los rayos UV en esta región. En general, las algas marinas probadas, principalmente las muestras recogidas en la Patagonia Antártida y chilena, mostraron valores más altos de fenólico (de 58,3 ± 2,0 a 144,7 ± 8,9 mg GAE g^-1) y el contenido de carotenoides (de 23,4 ± 0,2 a 51,5 ± 0,1 mg g^-1 β-caroteno).

Conclusiones:

La presencia y los niveles de estos compuestos sugieren que las algas marinas diana pueden tener un alto potencial antioxidante. También la actividad antioxidante podría estar asociada con el área de ocurrencia de las especies en lugar de la orden o grupo taxonómico a la que pertenecen.

Palabras clave: Algas verdes; especies reactivas del oxígeno; contenidos fenólicos; fotoprotectores

Introduction

Monostroma, Protomonostroma and Gayralia are foliose green seaweeds widely distributed throughout the Southern Hemisphere, with a concentrated biomass between the South Atlantic, Antarctic Peninsula and adjacent archipelagos. These ecosystems show variable and extreme chemical and physical conditions. Benthic organisms, such as seaweeds, can be exposed to high ultraviolet (UV) radiation, herbivory and fouling in higher latitudes, which are factors that may drive the development of defense strategies associated with their secondary metabolism (^{Verpoorte, 2000}; ^{Hartmann, 2007}).

The isolation and chemical characterization of secondary metabolites are relevant since some of these compounds demonstrate biological activities against human pathologies (^{Camarero et al., 1990}; ^{Gagioti et al., 1995}; ^{Maschek & Baker, 2008}). Specifically, antioxidants are the primary natural product known to be inhibitors of reactive oxygen species (ROS) accumulation and can prevent skin oxidative stress, skin cancer and premature skin aging (^{Guaratini et al., 2007}; ^{Guaratini et al., 2012}). As such, they have been often applied in the pharmaceutical, nutraceutical and cosmetic industries (^{Guaratini et al., 2007}; ^{Hwang et al., 2010}; ^{Guaratini et al., 2012}).

Phenolic compounds are the major substances responsible for antioxidant activity in land plants (^{Hayase & Kato, 1984}). In seaweeds, they are primarily involved in UV protection, anti-herbivory defense, pathogen resistance and epiphyte growth defense (^{Amsler & Fairhead, 2006}; ^{Bittencourt-Oliveira et al., 2005}).

In addition, carotenoids, a pigment class common in plants and algae, also protect cells against ROS (^{Hollnagel et al., 1996}; ^{Olson, 1999}; ^{Naguib, 2000}; ^{Gressler et al., 2010}, ²⁰¹¹).

Polar ecosystems are the most extreme on the planet, and the organisms inhabiting such environments, including seaweeds, are highly adapted (^{Dummermuth, 2003}). These organisms tolerate low temperatures, long ice-covering periods, low levels of visible irradiance during the winter as well as high quantities and long durations of solar incidence during the summer. Moreover, the stratospheric ozone, which protects organisms from harmful UV radiation, suffers seasonal oscillations over the Antarctic headed by climate global changing and cyclonic winds around this polar area. Therefore, interest in the seaweeds adaptations in polar zones with regard to their production of defense compounds against high levels of UV and fluctuations in ozone levels has been increasing (^{Dummermuth, 2003}).

Recently, ^{Zamora et al. (2010)} described high levels of antioxidant production enzymes in the shoots of Deschampsia antarctica Desvaux, an Antarctic vascular plant, subjected to drought stress. In addition, other studies have found strong antioxidant activity in Antarctic lichen species (^{Paudel et al., 2008}; ^{Luo et al., 2009}) and filamentous fungi (^{Tosi et al., 2010}). Apart from those studies, no description of antioxidant activity in Antarctic seaweeds have been reported to date.

In other instance, in the South Atlantic area many studies searching for antioxidant activity in seaweeds have been done in the last 10 years, but only a few of them considered green seaweeds. ^{Cruces et al. (2012)} reported a positive correlation between the antioxidant activities of two sub-Antarctic brown seaweeds in response to UV radiation. ^{Raymundo et al. (2004)}, using the ferric thiocyanate method to measure the antioxidant activity, found levels of inhibition of lipid peroxidation above 70% in Ulva intestinalis Linnaeus and Chaetomorpha antennina (Bory de Saint-Vicent) Kützing extracts collected in southern Brazil. ^{Sousa et al. (2008)} tested the antioxidant potential by assaying for α and β-carotene and α-tocopherol (vitamin E) levels in 32 seaweed species from northeastern Brazil, and higher contents of these substances were obtained mainly in green seaweeds.

Considering that meteorological and oceanographic traits along the Antarctic region influence air and seawater mass circulation throughout the Southwestern Atlantic and due to the scarcity of studies evaluating chlorophyte bioactive compounds from the Antarctic Peninsula and Southwestern Atlantic Ocean, this contribution aims to analyze and compare the antioxidant activity of three South American ulvophycean species (Gayralia brasiliensis Pellizzari, M.C. Oliveira et N. S. Yokoya, Protomonostroma undulatum (Wittrock) K. L. Vinogradova and Ulva fasciata Delile) and three other species from King George island around the Antarctic Peninsula (Protomonostroma rosulatum Vinogradova, Monostroma hariotii Gain and Ulva hookeriana (Suhr) Hariot). This study is the first report, although preliminary, of antioxidant activities in seaweeds collected in the Maritime Antarctic islands and surroundings.

Materials and methods

Seaweed material (approx. 500 g wet weight) was handly collected during spring/summer seasons in the intertidal zones of the Antarctic Peninsula surroundings and Southwestern Atlantic Ocean locations showed in Figure 1, Tables 1 and 2. Samples were washed with local seawater to remove epiphytes, associated fauna and sediments. In the laboratory, the seaweeds were washed with distilled water before freezing. The analyzed species, sites, sampling dates and voucher numbers of the species deposited in the “Maria Eneyda P. K. Fidalgo” Herbarium of Instituto de Botânica de São Paulo (SP) are listed in Table 1.

Figure 1: Map showing the sampling locations at Southwestern Atlantic Ocean. In Parana, Brazil, seaweeds were collected at the inner sector of Antonina Bay and outer sector of Guaratuba Bay. In Montevideo, Uruguay, samplings were made at the Rio de La Plata outfall. In Punta Arenas, Chile, seaweeds were sampled at Fuerte Bulnes beach. In Antarctic Peninsula, samplings took place at Punta Plaza and Botany Point beaches.

Table 1: Sampled chlorophyte species, sampling sites, coordinates, sampling dates and voucher numbers.

SP = Initials of Maria Eneyda P. K. Fidalgo Herbarium, of the Instituto de Botanica de Sao Paulo.

Table 2: Chlorophyte species sampled, sites, equivalent occurrence zone, average temperature and salinity data and sampling season.

*Data from: http://www.cptec.inpe.br; http://www.niwa.co.nz/sites/niwa.co.nz

Aiming to obtain crude chlorophyte extracts, the algae were defrosted and dried in a laminar flow hood (Splabor model SP 808/6-HLV) at room temperature (approx.. 25ºC) for approximately 48 h. Dried algal samples were triturated into a powder using liquid nitrogen. The material was weighed, and the volume of solvents to be added was calculated for each sample. For each 10g of algae sample was added 50 mL of the particular solvents. The first extraction was conducted with methanol P.A. for 48h before subsequently filtration with cotton. The filtered extract was poured into a 500 mL beaker to evaporate in a laminar flow hood. The second extraction, conducted with dichloromethane P.A. (50 mL of solvent to each 10 g of algae), was performed with the algae fraction retained after the filtration. After 48 h, the extract was filtered, added to the same beaker used before and evaporated completely in a laminar flow hood.

The antioxidant properties assay on seaweed samples using DPPH (2.2-diphenyl-picrylhydrazyl) radical scavenging was described by ^{Kim et al. (2002)}. Briefly, a 2.9 mL aliquot of a methanolic solution of the DPPH radical (Sigma, 0.1 mM in 80% methanol) was added to 0.1 mL of each sample (in 80% methanol). All algal extracts were solubilized with 80% methanol and evaluated at three different dilutions (1.0, 0.5 and 0.16 mg mL^-1). A blank sample was prepared with 80% methanol as control. The absorbance decrease at 517 nm relative to the negative control was measured with a UV-visible spectrophotometer with a microplate reader after 30 minutes of sample incubation. The percentage of absorbance decrease, indicating antioxidant activity (AA), was calculated using the equation: %AA = {(Abs_control - Abs_sample)/Abs_control} x 100. All tests were performed in triplicate.

Phenolic contents were determined using the method described by ^{Rhandir et al. (2002)} with modifications. A 40 µL aliquot of each algae extract was added to a reaction mixture containing 3.16 mL of distilled water, 200 µL of Folin-Ciocalteu reagent and 600 µL of Na₂CO₃ (20% in water) and then thoroughly mixed. After 2 hours incubation in a dark chamber, the absorbance was measured at 750 nm using a UV spectrophotometer. The total phenolic content was analyzed using a gallic acid standard curve. The results from triplicate tests were expressed as µg of gallic acid equivalent (GAE) per gram of dry biomass.

Carotenoid quantification was carried out according to ^{Aman et al. (2005)} with modifications. 3 mg of each algae crude extract were solubilized in 3 mL of hexane P.A. and the absorbance was read at 450 nm using a UV spectrophotometer. The results from triplicate tests and the mean absorbance obtained were used in a regression equation calculated from the β-carotene standard curve (y = 0.0856x + 0.0074, where x is the average and y is the concentration). The results were expressed as µg of β-carotene per gram of dry mass.

To compare the AA of the distinct extracts of marine chlorophytes, a one-way analysis of variance (ANOVA) was performed. Variance homogeneity was tested by a Cochran test, and the normal distribution of the data was observed by a histogram. Tukey’s post-hoc test was used when the data showed significant differences (p <0.05). When the ANOVA assumptions were not attempted, a non-parametric Kruskal-Wallis test was used. A linear regression was made between the phenolic contents and the radical scavenging assay. All analyses were performed in Statistica Software version 07 (^{StatSoft, 2004}) and the graphic was made using Microsoft Excel® 2010.

Results

The AA average values from chlorophyte extracts, obtained by the DPPH method at three extract concentrations, are shown in Table 3. The DPPH radical reduction percentages ranged from 3.5±2.1% in Ulva fasciata to 77.9±2.8% in Protomonostroma rosulatum. The extract dilution of 1 mg mL^-1 showed the most satisfactory results. Two species collected in the Antarctic Peninsula, P. rosulatum and Ulva hookeriana showed the highest apparent AA potential (77.9±2.8% and 53.1±15%, respectively) and the differences were statistically significant from the other analyzed species (p<0.05). The species Protomonostroma undulatum, Gayralia brasiliensis, Monostroma hariotii and U. fasciata did not differ (Tukey´s post-hoc, p>0.05) and showed lower antioxidant potential (Table 3).

Table 3: Marine chlorophyte species, their distribution and extracts analysis results.

Results of DPPH radical scavenging percentages in different concentrations of chlorophyte extracts, phenolic and carotenoid contents to evaluate antioxidant activity. Values are expressed as the mean ± standard deviation.

- Undetectable values.

Table 3 shows the average values of total phenolic contents expressed as the gallic acid equivalent (GAE) detected in the tested species. The lowest value was obtained by Ulva fasciata (58.3±2 µg GAE g^-1) collected in southern Brazil, and the highest value was identified in P. rosulatum (176±6 µg GAE g^-1) sampled in Antarctic. In this analysis, interspecific variance comparisons showed significant differences (Kruskal-Wallis, p <0.05). Figure 2 shows a linear regression between the phenolic contents and the DPPH radical scavenging percentages. In general, the radical reduction rates followed the phenolic contents. Values are presented in Table 3.

Figure 2: Linear regression between total phenolic contents of the crude extracts of chlorophytes from the Antarctic Peninsula and South Atlantic expressed as the average and standard deviation (n=3) of the gallic acid equivalent (μg GAE g-1) and the percentages of DPPH radical scavenging at a concentration of 1 mg mL^-1. R²= 0.7688; p < 0.01.

The average values found for carotenoid contents in the analyzed chlorophytes are presented in Table 3. The values ranged from 23.4±0.2 µg β-carotene g^-1 in Ulva fasciata to 51.5±0.1 µg β-carotene g^-1 in Ulva hookeriana. The comparison of the variances was significantly different (Kruskal-Wallis, p <0.05) only between those two species and no significant differences was detected for the other species analyzed.

Discussion

Among the Ulvophyceaean species collected between the Antarctic Peninsula and the southern Atlantic, Protomonostroma rosulatum and Ulva hookeriana, from King George Island, Antarctic, showed higher antioxidant potential. This result suggests that the AA levels could be associated with the occurrence area of the analyzed species and not necessarily with the order or taxonomic group to which the species belongs. Futhermore, they indicate that antioxidant potential is maybe an adaptation strategy for increased tolerance to heightened UV irradiation in the algae’s habitat.

UV data around the world is controversial due to differences on units of measurements and sort of equipment used to such purpose, besides, long term measurements and data in broad areas are presented as averages. However, following data retrieved from the Brazilian Weather Forecast and Climate Studies Center from the National Institute of Space Research (CPTEC/INPE - http://www.cptec.inpe.br) we can observe data of IUV max for Paraná sampling station between 5 and 9, considering also a crucial factor when discussing antioxidant activity and its relation with UV rays, the photoperiod in the area and for spring season, 12:12h (light/dark). Southern Chilean coast during summer register IUV data between 10 and 13, presenting a photoperiod of 15:9h. Following data retrieved from the National Institute of Water and Atmospheric Research of New Zealand (https://www.niwa.co.nz/sites/niwa.co.nz/, citing ^{Liley & Mckenzie, 2008}), during summer NZ, including subantarctic islands and islands around Peninsula, experiences IUV higher than 14, and a photoperiod of 20:4h. Considering these pool of data we justify in part our inferences above.

Based on previous results obtained from Gingko biloba L., an extract used as indicator of antioxidant potential with 80% of AA (^{Martins et al. 2012}), our report infers that P. rosulatum showed high antioxidant potential. ^{Dummermuth (2003)} quantified AA in extracts of Arctic seaweeds, and the chlorophytes showed higher AA compared to red and brown algae. This author also found that Monostroma grevillei var. arcticum (Wittrock) Rosenvinge, had higher antioxidant potential compared with other Arctic green seaweeds (^{Dummermuth, 2003}).

In our study, P. undulatum, collected in the Chilean Patagonia, and Monostroma hariotii, sampled in the Antarctic Peninsula, showed high rates of phenolic contents but showed non-satisfactory antioxidant efficacy using methanolic extracts (<60% of reduction). This result could imply differences in the chemical composition among phenolic compounds of the tested algae, and also differences in the solubility of these compounds in the applied solvent, or the influence of associated antioxidant compounds, such as carotenoids, on the AA efficiency present in these algal extracts.

The antioxidant properties of natural products are related to the presence of phenolic compounds that naturally occur in terrestrial and aquatic plants (^{Hayase & Kato, 1984}). In the present study, the higher percentage of AA was obtained in the extract of P. rosulatum, whose biomass had a higher content of phenolic compounds, corroborating the previous study. U. hookeriana, also collected in King George Island, showed high phenolic contents and was the species showing second highest AA among the ones we sampled in this study.

^{Trigui et al. (2012)} studied seasonal variations of AA levels in Ulva rigida C. Agardh and concluded that variations in activity correspond to the variations observed in the total phenolic contents. The authors also suggest that these differences could be assigned to seasonal changes in abiotic factors, such as climatic changes, temperature, salinity, nutrients, pollution, epiphytism and different reproductive or metabolic stages of the plant.

Carotenoids are also known to function as antioxidants (^{Naguib, 2000}). ^{Sousa et al. (2008)} found α- and β-carotene in all tested green algae. Green and yellow vegetables have been reported to have high carotenoid contents (^{Bendich & Olson, 1989}; ^{Grune et al., 2010}), e.g., carrots (33 µg g^-1) and pumpkins (53 µg g^-1) (^{Rodrigues-Amaya et al., 2008}). Literature data report that Enteromorpha (Ulvales) can present higher ç-carotene contents than some vegetables, showing concentrations nearing 250 µg g^-1 (^{Ito & Hori, 1989}). These data support our high concentrations detected in Ulva hookeriana (previously reported as Enteromorpha bulbosa (Suhr) Montagne) sampled in the surrounding islands of Antarctic Peninsula.

Finally, the higher AA observed in P. rosulatum and U. hookeriana seems to be related to the phenolic and carotenoid contents. Both phenolics and carotenoids are directly related to protection against UV rays in vegetables and likely in seaweeds. One hypothesis for the higher antioxidant potential found in this two species from the Antarctic Peninsula is that these populations are exposed to higher and continuous UV radiation mainly during summer and thus may be naturally selected for high antioxidant potential.

Therefore, these preliminary results suggest that Antarctic Ulvophyceans may have a wide range of chemical constituents from secondary metabolism, mainly phenolic compounds and carotenoids, that can present AA and that probably these contents are higher when compared to the same orders or family taxa collected in temperate or subtropical zones due to adaptive routes. This contribution is the first comparative report of AA in Ulvophyceae species from Brazil, Chile and maritime Antarctic. The high AA of P. rosulatum, endemic to King George Island, Antarctic Peninsula, corroborates the relevance of elucidating bioactive compounds from high latitudes as possible new sources of natural products with potential uses in cosmetic, nutraceutical and pharmacological industries for their anti-oxidative stress effects.

Acknowledgments

The authors thank Marinha do Brasil, Comissão Interministerial para os Recursos do Mar, Programa Antártico Brasileiro, Ministério da Ciência, Tecnologia e Inovação and Conselho Nacional de Desenvolvimento Científico e Tecnológico for logistics and financial support during samplings. The authors also thank Coordenação de Aperfeiçoamento de Pessoal de Nível Superior and the Post-Graduation Program in Coastal and Oceanic Systems (PGSISCO/CEM) of Universidade Federal do Paraná for the scholarship grant. The authors acknowledge Dr. Paulo Antunes Horta for use of equipment in the Phycology Laboratory of Universidade Federal de Santa Catarina, and Dr. Erik Lam, from State University of New Jersey, for caring reviewing of the manuscript.

References

Aman, R., R. Carle, J. Conrad, U. Beifuss & A. Schieber. 2005. Isolation of carotenoids from plant materials and dietary supplements by high-speed counter-current chromatography. Journal of Chromatography A 1074: 99-105. [ Links ]

Amsler, C. D. & V. A. Fairhead. 2006. Defensive and sensory chemical ecology of brown algae. Advances in Botanical Research 43: 1-91. [ Links ]

Bendich, A. & J. A. Olson. 1989. Biological actions of carotenoids. Journal of the Federation of American Societies for Experimental Biology 3: 1927-1932. [ Links ]

Bittencourt-Oliveira, M. C., P. Kujbida, K. H. M. Cardozo, V. M Carvalho, A. N. Moura, P. Colepicolo & E. Pinto E. 2005. A novel rhythm of microcystin biosynthesis is described in the cyanobacterium Microcystis panniformis Komárek. Biochemical and Biophysical Research Communications 326: 687-694. [ Links ]

Camarero, V. C. P. C., V. B. Junqueira, P. Colepicolo, M. L. Karnovsky & M. Mariano. 1990. Epithelioid macrophages secret a deactivating factor for superoxide release. Journal of Cellular Physiology 145: 481-487. [ Links ]

Cruces, E., P. Huovinen & I. Gómez. 2012. Interactive effects of UV radiation and enhanced temperature on photosynthesis, phlorotannin induction and antioxidant activities of two sub-Antarctic brown algae. Marine Biology 160 (1): 1-13. DOI: 10.1007/s00227-012-2049-8. [ Links ]

Dummermuth, A. 2003. Antioxidative properties of marine macroalgae from the Arctic. Bremerhaven, Germany. Doctorate Tesis, Alfred Wegener Institute for Polar and Marine Research. [ Links ]

Gagioti, S., P. Colepicolo & E. M. A. F. Bevilacqua. 1995. Post-implantation mouse embryo has the ability to generate reactive oxygen species. Reproduction, Fertility and Development 7: 1111-1116. [ Links ]

Gressler, V., N. S. Yokoya, M. T. Fujii, P. Colepicolo, J. Mancini, R. P. Torres & E. Pinto. 2010. Lipid, fatty acid, protein, amino acid and ash contents in four Brazilian red algae species. Food Chemistry 120: 585-590. [ Links ]

Gressler, V., M. T. Fujii, A. P. Martins, P. Colepicolo, J. Mancini & E. Pinto. 2011. Biochemical composition of two red seaweed species grown on the Brazilian coast. Journal of the Science of Food and Agriculture 91: 1687-1692. [ Links ]

Grune, T., G. Lietz, A. Palou, A. C. Ross, W. Stahl, G. Tang, D. Thurnham, S. Yin & H. K Biesalski. 2010. β-Carotene is an important vitamin A source for humans. Journal of Nutricion 140 (12): 2268S-2285S. DOI: 10.3945/jn.109.119024. [ Links ]

Guaratini, T., M. H. G. Medeiros & P. Colepicolo. 2007. Antioxidantes na manutenção do equilíbrio redox cutâneo: uso e avaliação de sua eficácia. Química Nova Vol. 30 (1): 206-213. [ Links ]

Guaratini, T. , N. P. Lopes, E. Marinho-Soriano, P. Colepicolo. & E. Pinto. 2012. Antioxidant activity and chemical composition of the non-polar fraction of Gracilaria domingensis (Kützing) Sonder ex Dickie and Gracilaria birdiae (Plastino & Oliveira). Brazilian Journal of Pharmacognosy 22: 724-729. [ Links ]

Hartmann, T. 2007. From waste products to ecochemicals: fifty years research of plant secondary metabolism. Phytochemistry 68: 2831-2846. [ Links ]

Hayase, F. & H. Kato. 1984. Antioxidative components of sweet potatoes. Journal of Nutritional Science and Vitaminology 30: 37-46. [ Links ]

Hollnagel, H. C, P. Di Mascio, C. S. Asano, O. K. Okamoto, C. G. Stringher, M. C. Oliveira & P. Colepicolo. 1996. The effect of light on the biosynthesis of β-carotene and superoxide dismutase activity in the photosynthetic alga Gonyaulax polyedra. Brazilian Journal of Medical and Biological Research 29: 105-111. [ Links ]

Huang, J., Y. Liu & X. Wang. 2008. Selective adsorption of tannin from flavonoids by organically attapulgite clay. Journal of Hazard Materials 160: 382-387. [ Links ]

Hwang, P. A., C. H. Wu, S. Y. Gau, S. Y. Chien & D. F. Hwang. 2010. Antioxidant and immune-stimulating activities of hot-water extract from seaweed Sargassum hemiphyllum. Journal of Marine Science and Technology 18 (1): 41-46. [ Links ]

Ito, K. & K. Hori. 1989. Seaweed: chemical composition and potential food uses. Food Reviews International 5 (1): 101-144. [ Links ]

Kim, Y. K., Q. Guo & L. Packer. 2002. Free radical scavenging activity of red ginseng aqueous extracts. Toxicology 172: 149-156. [ Links ]

Liley, J. B. & McKenzie, R. L. 2008. Where on Earth has the highest UV? National Institute of Water and Atmospheric Research (NIWA), Lauder, Central Otago, New Zealand. [ Links ]

Luo, H., Y. Yamamoto, J. A. Kim, J. S. Jung, Y. J. Koh & J. K. Hur. 2009. Lecanoric acid, a secondary lichen substance with antioxidant properties from Umbilicaria antarctica in maritime Antarctica (King George Island). Polar Biology 32:1033-1040. DOI: 10.1007/s00300-009-0602-9. [ Links ]

Martins, C. D. L., F. Ramlov, N. P. N. Carneiro, L. M. Gestinari, B. F. Santos, L. M. Bento, C. Lhullier, L. Gouvea, E. Bastos, P. A. Horta & A. R. Soares. 2012. Antioxidant properties and total phenolic contents of some tropical seaweeds of the Brazilian coast. Journal of Applied Phycology 25 (4): 1179-1187. DOI: 10.1007/s10811-012-9918-x. [ Links ]

Maschek, J. A. & B. J. Baker. 2008. The chemistry of algal secondary metabolism. In: Algal Chemical Ecology. Springer-Verlag Berlin Heidelberg, Germany, 322 p. [ Links ]

Naguib, Y. M. A. 2000. Antioxidant activities of astaxanthin and related carotenoids. Journal of Agricultural and Food Chemistry 48: 1150-1154. [ Links ]

National Institute of Water and Atmospheric Research of New Zealand. Avaiable at http://www.niwa.co.nz/sites/niwa.co.nz, accessed in Feberuary 2^nd, 2016. [ Links ]

Olson, J. A. 1999. Carotenoids and human health. Archivos Latinoamericanos de Nutrición 49: 7S-11S. [ Links ]

Paudel, B., H. D. Bhattarai, J. S. Lee, S. G. Hong, H. W. Shin & J. H. Yim. 2008. Antioxidant activity of polar lichens from King George Island (Antarctica). Polar Biology 31: 605-608. [ Links ]

Raymundo, M. S., P. A. Horta & R. Fett. 2004. Atividade antioxidante in vitro de extratos de algumas algas verdes (Chlorophyta) do litoral catarinense (Brasil). Brazilian Journal of Pharmaceutical Sciences 40 (4): 495-503.DOI: 10.1590/S1516-93322004000400007. [ Links ]

Rhandir, R., S. Preethi & S. Kalidas. 2002. L-DOPA and total phenolic stimulation in dark germinated fava bean in response to peptide and phytochemical elicitors. Process Biochemistry 37: 1247-1256. [ Links ]

Rodrigues-Amaya, D. B., M. Kimura, J. Amaya-Farfan, L. Coradin & V. B. Pombo. 2008. Fontes brasileiras de carotenoides: tabela brasileira de composição de carotenoides em alimentos. Ministério do Meio Ambiente, Secretaria de Biodiversidade e Florestas, Brasília, 100 p. [ Links ]

StatSoft, Inc. 2004. STATISTICA (data analysis software system), version 7. Available in: http://www.statsoft.com [ Links ]

Shahidi, F. & M. Naczk. 2006. Phenolics in food and nutraceuticals. CRC Press, London, 566 p. [ Links ]

Souza, M. B., K. M. S. Pires, D. B. Alencar, A. H. Sampaio & S. Saker-Sampaio. 2008. α- e β-caroteno, e α-tocopherol em algas marinhas in natura. Ciência e Tecnologia de Alimentos, Campinas 28 (4): 953-958. [ Links ]

Tosi, S., N. Kostadinova, E. Krumova, S. Pashova, V. Dishliiska, B. Spassova, B. Vassilev & M. Angelova. 2010. Antioxidant enzyme activity of filamentous fungi isolated from Livingston Island, Maritime Antarctica. Polar Biology 33:1227-1237. [ Links ]

Trigui, M., L. Gasmi, I. Zouari & S. Tounsi. 2012. Seasonal variation in phenolic composition, antibacterial and antioxidant activities of Ulva rigida (Chlorophyta) and assessment of antiacetylcholinesterase potential. Journal of Applied Phycology 25 (1): 319-328. DOI: 10.1007/s10811-012-9866-5. [ Links ]

Verpoorte, R. 2000. Secondary metabolism. In: Verpoorte R, Alfermann AW (eds) Metabolic engineering of plant secondary metabolism, 1ed. Kluwer Academic Publichers, Netherlands, pp. 1- 9. [ Links ]

Zamora, P., S. Rasmussen, A. Pardo, H. Prieto & G.E. Zúñiga. 2010. Antioxidant responses of in vitro shoots of Deschampsia antarctica to Polyethylene glycol treatment. Antarctic Science 22: 163-169. [ Links ]

Received: March 11, 2015; Accepted: February 17, 2016

*Autor de correspondencia: bernardijuliane@gmail.com

This is an open-access article distributed under the terms of the Creative Commons Attribution License