Open-access Influence of temperature and culture media on growth and lipolytic activity of deep-sea Halomonas sulfidaeris LAMA 838 and Marinobacter excellens LAMA 842

Abstract

Bacteria with lipolytic activity are widespread in the marine environment. These organisms can be used as a source of lipases with activity in unusual conditions such as low temperatures and high salinities. These characteristics allow them to be applied to several industrial processes and products including wastewater treatment and detergent production. In this context the lipolytic activity of bacteria isolated from deep-sea sediments of the South Atlantic was evaluated. Among the collection studied, two strains, Halomonas sulfidaeris LAMA 838 and Marinobacter excellens LAMA 842, were selected for further analysis concerning their growth and lipolytic activity in different temperatures and culture media. Both strains were characterized as mesophiles: H. sulfidaeris LAMA 838 grew best at 30ºC, while M. excellens LAMA 842 showed a maximum growth rate between 20 and 25ºC. Maximum lipolytic activity for both microorganisms was observed above 45ºC, but only M. excellens LAMA 842 had lipolytic activity at low temperatures (5ºC) as well. Considering the culture media employed, H. sulfidaeris LAMA 838 grew better in marine broth without Tween 40, while M. excellens LAMA 842 grew best in marine broth supplemented with Tween 40. Both organisms had maximum lipolytic activity in rich or minimal media supplemented with Tween 40. These results demonstrate the potential of deep-sea bacteria as sources of lipases and indicate conditions that may be used in their cultivation and for the production of industrially relevant enzymes.

Descriptors: deep-sea bacteria; microbial growth; lipolytic activity; psychrotolerants

INTRODUCTION

Lipases are enzymes capable of catalyzing the hydrolysis of long-chain triglycerides to free fatty acids (Treichel et al., 2010), as well as synthesizing esters from glycerol (Lailaja and Chandrasekaran, 2013). These enzymes are used in the food and paper industries, as supplements to detergents, synthesis of biopolymers, production of biodiesel, purification of pharmacologically relevant chemical compounds, cosmetics, agrochemicals, bioremediation, and in wastewater treatment (López-López et al., 2014).

Lipases from deep-sea bacteria may have peculiar characteristics, such as tolerance to high pressures and low temperatures. They are also easy to adapt to large scale cultivation and are active in a wide range of pH values and temperatures. These features confer high stability and a high specificity for their substrates, and can be attributed to the oligotrophic environments and low temperatures to which these organisms are imposed, as well as the molecules involved in their complex metabolisms. They have great potential in research seeking new products of industrial interest (Dalmaso et al., 2015; Hu et al., 2015). In this context, different marine microorganisms have already been described as extracellular enzyme producers (Odisi et al., 2012).

Lipase production by deep-sea bacteria may be influenced by environmental factors such as glucose and yeast extract concentration, as reported for Thalassospira permensis (Kai and Peisheng, 2016). The types of lipids present in the medium may also influence the activity of lipases, as reported for the strain Psychrobacter sp. C18 (Chen et al., 2011). All these influences may be interpreted as mechanisms to increase the survival of bacteria in deep-sea environments when organic matter containing lipids becomes available for growth. Nevertheless, variations may occur according to the needs or tolerances of the microorganisms, and these variations may influence the enzymatic activity (Kiran et al., 2014).

The genera Marinobacter (Gorshkova et al., 2003) and Halomonas (Kaye and Baross, 2004) belong to the class Gammaproteobacteria and are commonly found in different marine ecosystems; they may present different optimum temperatures for growth, being psychrophiles, mesophiles or thermophiles, and they show great tolerance to salinity and pH (Silva et al., 2013; Ng et al., 2014; Zhang et al., 2016). The ability to occupy various physical and chemical environments indicates great versatility and phenotypic diversity in these genera, so some species of Halomonas and Marinobacter have already been described to produce lipases (Kumar et al., 2012). The strains of Halomonas and Marinobacter studied by these authors produced lipases with optimum temperature between 50 and 65ºC, and optimum pH between 9.0 and 9.5. The lipases of the Marinobacter evaluated were also stable at 60ºC for one hour. Thermal stability for the Halomonas strain was not assessed. Oves et al. (2017) reported the thermal (70ºC) and pH (6-8) stability of the lipolytic activity of Marinobacter lipolyticus strain CEES 33 isolated from the Red Sea. Finally, the lipase of Marinobacter litoralis strain SW-45 was active and stable between pH values of 7.0 and 9.5, and temperatures of 30 and 50°C, with maximum activity at pH 8.0 and 50°C (Musa et al., 2018).

The study of lipases of these deep-sea bacteria is important in several ways. Firstly, it provides us with a better understanding of the mechanisms of microbial survival at these harsh environments. Secondly, the success of the biotechnological applications of these enzymes requires that we know the conditions under which they are able to function. Lastly, the basic knowledge about lipases and their producing organisms is essential to enable an eventual commercial production of these molecules. In this context, the objective of this work was to evaluate the influence of the Tween substrate and temperature on the growth of Halomonas sulfidaeris LAMA 838 and Marinobacter excellens LAMA 842 bacteria and the activity of their synthesized extracellular lipases. This objective was stimulated by the fact that few studies have identified these bacterial species as lipases producers (Silva et al., 2013).

MATERIAL AND METHODS

SOURCE OF STRAINS

The bacteria used in this work were isolated and identified by Silva et al. (2013) from sediment samples of two different regions of the South Atlantic Ocean: the Walvis Ridge Sector - WRS (20°-33° S, 5°W, 10°E) and the South Equatorial MAR Sector - SEMS (2°N- 10°S, 12°-22°W) (Perez et al., 2012). Further details of the strains used are given in Table 1. The bacteria were evaluated for lipolytic potential and through a selection for best performance on imposed substrates and culture conditions.

Table 1
Bacterial strains used in the present study, their isolation medium and identification (Silva et al., 2013). MA, Marine Agar; MBC, Marine Agar supplemented with carboxymethylcellulose (1%); MAT40, Marine Agar supplemented with Tween40 (1%).

SCREENING FOR LIPOLYTIC ACTIVITY

The collection of strains was screened for lipolytic activity on 55.25g/l Zobell Marine Agar 2216 plates (Himedia Laboratories, Mumbai, India) supplemented with 0.5% Tween 20 (T20), Tween 40 (T40), Tween 60 (T60) or Tween 80 (T80). The plates were point-inoculated in triplicate and incubated at three different temperatures, 5ºC (fourteen days of incubation), 15º (also fourteen days of incubation), and 30ºC (incubated for seven days). After incubation, substrate hydrolysis was visualized as the precipitation of crystals around the colonies (Smibert and Krieg, 1994). This activity was quantified by an enzymatic index (EI) obtained from the diameters of the colonies (C) and their respective hydrolysis zones (H) according to the formula: EI = H/C (Hankin and Agnostakis, 1975).

LIPASE ASSAY

For the lipase assay, crude enzymatic extracts were prepared by culturing the microorganisms in Erlenmeyer flasks containing 75ml of 40.25g/l Zobell Marine Broth 2216 (MB, Himedia Laboratories, Mumbai, India) supplemented with 0.5% T20 and 75µl of bacterial inoculums. The culture flasks were incubated at 30ºC for 48h. After incubation, 1ml aliquots were collected from the culture flasks and centrifuged at 8,116.6 x g for 10mins. The supernatant was considered the crude enzymatic extract.

Spectrophotometric assays of lipolytic activity were conducted as described by Pinsirodom and Parkin (2001). Briefly, 1.0ml of crude enzymatic extracts were added to 2.5ml of a Tris HCl buffer solution (pH=8.2) and 2.5ml of the substrate p-nitrophenyl palmitate (pNPP). As controls, we used crude enzymatic extracts that were inactivated by boiling (100ºC) for 10mins on a thermoblock. A blank was also prepared using distilled water in place of the crude enzymatic extract. The assay mixtures were incubated at different temperatures depending on the experiment (described below) for one hour. After the incubation period, the absorbance at the wavelength of 410nm was measured against the blank. The absorbance values obtained were then converted to concentration units using a calibration curve based on p-nitrophenol as standard (Table 2).

Table 2
Calibration curves for colony-forming units for H. sulfidaeris LAMA 838 and M. excellens LAMA 842, and the curve of p. nitrophenol for the lipolytic activity.

INFLUENCE OF TEMPERATURE ON GROWTH AND LIPASE ACTIVITY

To estimate the optimum, maximum and minimum temperatures for growth, Erlenmeyer flasks of 125ml capacity containing 75ml of MB supplemented with 1.0% T20 were inoculated with 75µl of bacteria, in triplicate, from a culture prepared in Marine Broth (30ºC, incubated for 24 hours). T20 was chosen for this analysis because of its lower complexity molecular structure, which facilities its use by the microorganisms for their growth. The inoculated flasks were incubated at 5, 10, 15, 20, 25 and 30ºC under an agitation at 2,012 x g for different periods of time, depending on the incubation temperature. For 25 and 30ºC, the incubation time was 24h; for 15 and 20ºC, 48h; and for 5 and 10ºC, 120h. Using the calibration curve (Table 2), the optimal growth was determined from the highest growth rate by converting the absorbance at 600nm to cells per milliliter (Breznak and Costilow, 1994). To investigate the influence of temperature on enzymatic activity, the crude enzymatic extracts were incubated for one hour at the following temperatures: 5, 10, 15, 20, 25, 30, 35, 40, 45 and 50ºC. Otherwise, the lipase assays were conducted as described above.

INFLUENCE OF CULTURE MEDIA ON GROWTH AND LIPASE ACTIVITY

Growth of selected bacteria was also evaluated in two complex media, MB and MB supplemented with 0.5% T40 (MB+T40), and a minimal medium supplemented with 0.5% T40 (MM+T40). Composition of the minimal medium (1,000ml) was as follows: Tris HCl (pH 7.5), 7.88ml; NH4Cl, 10.16g; K2HPO4, 0.075g; FeSO4*7H2O, 0.028g; solution of vitamins (for 200ml: pyridoxine, 0.02g; thiamine, 0.01g; riboflavin, 0.01g; calcium pentanoate, 0.01g; nicotinic acid, 0.01g; vitamin B12, 0.01g; biotin, 0.004g; folic acid, 0.004g), 1.00ml; artificial sea water (for 1,000ml: NaCl, 23.38g; MgSO4*7H2O, 24.65g; KCl, 1.49g; CaCl*2H2O, 2.94g), 500ml; distilled water, 500ml. In this experiment, T40 was chosen because its carbon chain is palmitate, and this reagent was also used in the culture media in the enzyme assay.

From precultures prepared in the three different media (30ºC, incubated for 24 hours), Erlenmeyer flasks of 125ml capacity containing 75ml of the three different media were inoculated with 75µl of the precultures prepared in the same media for preadaptation. The inoculated flasks were incubated at 30ºC for 48h (MB and MB+T40) or 120h (MM+T40). Periodically the optical density at 600nm was measured and later used for the calculation of generation times of the organisms in the different culture media (White et al., 2012). The lipolytic activity was also assayed in the different media by incubating the crude enzymatic extracts for one hour at 30ºC as described above. The lipolytic activity results (calculated using the calibration curve as previously described) were divided by the number of colony forming units (CFUs) for each of the evaluated bacteria.

DATA ANALYSIS

The growth rates of each microorganism were compared at the different temperatures and culture media using one-way analysis of variance (ANOVA). Four analyses were conducted separately: growth temperature for LAMA 838, growth temperature for LAMA 842, culture media for LAMA 838, and culture media for LAMA 842. In all cases confidence limits of 95% and degrees of significance of 0.05 were considered. If significant variability was detected, a Tuckey’s test was conducted a posteriori. For all these analyses, the software Statistica, version 7.0 (StatSoft, Tulsa, USA) was used.

RESULTS

SCREENING AND TAXONOMIC DISTRIBUTION OF LIPOLYTIC BACTERIA

The collection of bacteria studied was obtained from sediment samples collected in deep zones of the South Atlantic Ocean by Silva et al. (2013). This collection of strains included the phyla Proteobacteria (n=38), Firmicutes (n=25), Actinobacteria (n=4), and three unidentified strains. All strains in this collection (n=70) were screened for lipolytic activity of Marine Agar plates supplemented with each of the four lipid substrates. Bacteria of the phylum Proteobacteria were not only more abundant among our strains but also showed the best lipolytic activity on the four substrates used. The substrate T80 was the least hydrolyzed, while T20 was the most commonly utilized by our strains, as shown in Figure 1.

Figure 1
Frequency (%) of lipolytic bacteria in the different bacterial phylas identified in the strains studied. The results are shown for each of the four substrates employed in the screening experiments. T20, Tween 20; T40, Tween 40; T60, Tween 60; T80, Tween 80.

Within the phyla isolated, thirteen distinct genera were identified among the lipolytic strains. The most frequent were Halomonas (n=17), Bacillus (n=9), Psychrobacter (n=6), and Staphylococcus (n=6). The lipolytic strains also represented twenty different species with predominance for Halomonas sulfidaeris (n=5), Halomonas boliviensis (n=4), Psychrobacter nivimaris (n=4), Staphylococcus cohnii subsp. urealyticus (n=3).

Through this screening for lipolytic activity (Figure 2), we were able to calculate enzymatic indexes (EIs) for each of the strains and substrates (Table 3). Fifity-two of the seventy strains evaluated showed lipolytic activity on at least one of the substrates. Among the five strains of H. sulfidaeris, two hydrolyzed all lipids tested; one showed hydrolysis on T20 and T60, and two were unable to hydrolyze any of the substrates evaluated. Based on these data, we were also able to select two strains, Halomonas sulfidaeris LAMA 838 and Marinobacter excellens LAMA 842, for further studies. This selection was based on the fact that both strains (1) were able to hydrolyze the four lipid substrates, (2) had high EIs, (3) represent common bacteria cultivated from deep-sea samples (Kumar et al., 2012; Ng et al., 2014; Gutiérrez-Arnillas et al., 2016), and (4) have not been previously reported to be lipolytic species in the scientific literature. Figure 3 shows the EIs of the selected bacteria. It may be noted that H. sulfidaeris LAMA 838 displayed higher lipolytic activity than M. excellens LAMA 842 for all lipid substrates. The highest activity was observed on T20 and both bacteria displayed significantly different EIs for this substrate.

Table 3
Average enzyme indexes for the bacterial strains studied and standard deviations for the four lipid substrates tested. Only the strains that were active on at least one lipid substrate are showed. T20, tween 20, T40, tween 40, T60, tween 60, and T80, tween 80.

Figure 2
Marine agar plate illustrating the procedure used for screening of the lipolytic bacteria. The halo around the colony is indicative of the hydrolysis of the substrate, Tween 60 in this case.

Figure 3
Enzyme indexes for the bacteria H. sulfidaeris LAMA 838 and M. excellens LAMA 842 for substrates Tween 20 (T20), Tween 40 (T40), Tween 60 (T60) and Tween 80 (T80) and their respective standard deviations. The letters above the bars indicate the results of the statistical analysis, small letters for H. sulfidaeris LAMA 838 and capital letters for M. excellens LAMA 842. Means followed by the same letter do not differ by the Tukey’s test at 5% probability. The analysis was carried out in the software Statistica version 7.0.

In the genome of M. excellens LAMA 842 (available from the National Center for Biotechnology Information (NCBI) database, Accession number ASM157444v1) five genes with lipase and phospholipase functions were identified (Table 4). The genomic information of H. sulfidaeris LAMA 838 is not available.

Table 4
Genes related to lipase and phospholipase functions identified in the genome of M. excellens LAMA 842, their product and length.

INFLUENCE OF TEMPERATURE ON GROWTH AND LIPASE ACTIVITY

Following the screening experiments, the influence of temperature on growth and lipase activity was evaluated in the selected strains. H. sulfidaeris LAMA 838 grew at all tested temperatures, with maximum growth rates at 30ºC (the highest temperature tested). But to confirm that this temperature is the maximum growth temperature of this organism, higher values should be tested in the future. By contrast, M. excellens LAMA 842 did not grow at 5 or 10ºC and showed a maximum growth rate between 20 and 25ºC (Figure 4).

Figure 4
The influence of temperature on the growth rate of H. sulfidaeris LAMA 838 and M. excellens LAMA 842. The vertical bars represent the standard deviation. The letters above the bars indicate the results of the statistical analysis, small letters for H. sulfidaeris LAMA 838 and capital letters for M. excellens LAMA 842. Means followed by the same letter do not differ by the Tukey’s test at 5% probability. The analysis was carried out in the software Statistica version 7.0.

In the lipolytic activity assays, 50ºC was identified as the highest activity temperature for LAMA 838, and between 45 and 50ºC was highest for LAMA 842. Again, to confirm that 50ºC is the maximum activity temperature of LAMA 838, higher values should be tested in the future. Different from that observed for the LAMA 838 lipase, the LAMA 842 enzyme was active at all temperatures, including low temperatures, with more than 50% of the activity maintained at 3ºC, as show in Figure 5. This behavior may indicate the production of isoenzymes whose properties and regulation can be adjusted according to metabolic necessity and culture medium.

Figure 5
Residual activity of the lipases produced by H. sulfidaeris LAMA 838 and M. excellens LAMA 842. The vertical bars represent the standard deviation.

INFLUENCE OF CULTURE MEDIA ON GROWTH AND LIPASE ACTIVITY

In the last round of experiments, the influence of culture media on growth and lipase activity was evaluated. H. sulfidaeris LAMA 838 grew best in marine broth, while M. excellens LAMA 842 had a higher growth rate in marine broth supplemented with Tween 40. Both organisms had the lowest growth rate in minimal medium supplemented with Tween 40 (Figure 6). In general, H. sulfidaeris LAMA 838 had higher enzymatic activity then M. excellens LAMA 842 in all three culture media evaluated (Figure 6). When comparing the different media, the highest enzymatic activity was observed in marine broth supplemented with Tween 40 for both of the selected strains. Additionally, the lowest enzymatic activity was observed in unsupplemented marine broth for both organisms.

Figure 6
Growth rate (dark gray) and lipolytic activity (light gray) of H. sulfidaeris LAMA 838 (A) and M. excellens LAMA 842 (B) grown in Marine Broth (M.B), Marine Broth supplemented with Tween 40 (M.B+ T40) and Minimal Medium supplemented with Tween 40 (MM + T40). The vertical bars represent the standard deviation of the triplicates.

DISCUSSION

The predominant class of organisms in the samples studied was Gammaproteobacteria, which has already been reported in the scientific literature as abundant in deep-water and hydrothermal vents (Zhang et al., 2016). Marinobacter and Halomonas are also frequently found in these environments (Sun et al., 2015; Yuan et al., 2015). Nevertheless, few studies have identified H. sulfidaeris and M. excellens as lipase producers from deep marine waters (Silva et al., 2013). This fact propelled the search for more information on these two bacterial species, especially after the identification of substrates hydrolyzed by these microorganisms and their respective enzymatic indexes.

During the screening with lipolytic substrates, T20 and T40 were found to be the most hydrolyzed by the bacterial strains studied. Similar results were reported by Lo Giudice et al. (2006) in marine bacteria isolated from Antarctica and by Zhang et al. (2016) in microorganisms from the South Pacific Ocean. On the other hand, the substrate T80 was the least utilized by the microorganisms. This can be explained by the presence of one double bond in the molecule, which demands that the enzyme epoxide hydrolase be present to hydrolyze and break this bond for the utilization of this molecule (Woo et al., 2007). The presence of this enzyme was identified previously in the genus Marinobacter (Neilson and Allard, 2008) and may justify the results we obtained for M. excellens LAMA 842. In the description of the species H. sulfidaeris, Kaye and Baross (2004) reported its inability to hydrolyze T80. In the present study, five strains of H. sulfidaeris were evaluated and only two strains, LAMA 838 and LAMA 786, were capable of hydrolyzing all lipid substrates tested, including T80. Different characteristics among a group of strains of the same species are not uncommon and may be related to the origins of the different strains. For instance, LAMA 838 was the only strain of H. sulfidaeris among the five analyzed that originated from sediments of the Walvis Ridge Sector in the Superstation 0 (25º41’70”S, 02º20’72”W) (Silva et al., 2013). According to Philippot et al. (2010), the adaptation to different ecological niches may influence the differentiation of bacterial strains, with the acting selective pressures resulting in strains with different genomes. From the sequence distribution pattern of the 16S rRNA gene, three subpopulations of Halomonas were identified by Kaye et al. (2011), with one ecotype predominant in deep cold waters, another in hydrothermal sources and another in the subseafloor population.

Growth was also evaluated in different culture media, and the results indicated that the growth rate of the microorganisms studied was highest in nutrient rich media without T40 (MB) (Barton, 2005), which differed from the enzymatic activity of these microorganisms, for which the best indexes were obtained in media supplemented with Tween (MB+T40 and MM+T40), nutrient-rich or minimal. These results demonstrate that lipolytic activity is not necessarily linked to complex and expensive nutrients, an observation which may make these microbial enzymes competitive in the industrial market. Polyoxyethylene sorbitol fatty acid ester has been studied as a facilitator of enzymatic reactions and their substrates, which favors the enzymatic secretion of hydrolases to the extracellular medium (Pozdnyakova et al., 2004) and maximizes biomass and lipase productivity (Byreddy et al., 2017). In the study by Nemec and Jernet (2002), a 70% increase in the secretion of Aspergilus niger hydrolases was observed in the presence of 0.1% Tween 80; in the present study, we observed an increase of 87% for H. sulfidaeris and 81% for M. excellens in the presence of T40. When analyzing the genome of M. excellens LAMA 842 five genes with lipase and phospholipase functions were identified (Table 4). The presence of these genes may explain why the best growth rates were obtained in Tween medium. Their presence may also explain the activity of the LAMA 842 lipase at low temperatures, because this bacterium is not known to grow at low temperatures. These genes may also explain the potential presence of isoenzymes.

The presence of the Tween molecule in the media serves as an additional carbon source, which can be utilized by the bacteria for cell growth and the generation of biomass. It may also favor the secretion of extracellular lipases into the medium and may stimulate this activity. This influence is more evident for the bacterium M. excellens. By contrast, for H. sulfidaeris the addition of Tween to the medium caused a decrease in the growth rate, while at the same time inducing better lipase activity.

In studying the physiology of bacteria belonging to the genus Halomonas,Kaye and Baross (2004) reported that the ideal conditions of growth for these organisms are not those typical of deep-sea environments: Halomonas may prefer to live in warmer environments, with temperatures approximately 30ºC. In agreement with this, H. sulfidaeris LAMA 838 reached its maximum growth rate at 30ºC, the highest temperature tested in the present work, and a similar result to that obtained by Kaye and Baross (2004), which characterized this species as mesophile. M. excellens LAMA 842, on the other hand, grew better between 20 and 25ºC, as observed previously in the type strain isolated from marine sediments in Japan (Gorshkova et al., 2003).

The results obtained in this work agree with those described previously in the literature, in which the optimum temperature for activity of extracellular enzymes such as lipases may differ from the optimal temperature for growth of the producing microorganism. This may happen because of the necessity of enzymatic activation (Feller et al., 1990). According to Bhavani et al. (2012) and Byreddy et al. (2017), the temperature, pH, carbon source and incubation period of the microorganisms are important factors that can influence both the production of lipases and the lipolytic activity. In this context, assays conducted by Kiran et al. (2008) have shown that lipases produced by marine Pseudomonas have maximum activity between 27 and 50ºC. This is similar to our results obtained for lipases produced by H. sulfidaeris LAMA 838 and M. excellens LAMA 842, which had maximum activities at 50ºC and between 40 and 50ºC, respectively. The low temperature lipolytic activity of the LAMA 842 strain represents a prominent characteristic that is biotechnologically appreciated, since in the literature no lipase has been previously described with 50% activity at 3ºC for the genus Marinobacter.

From a biotechnology point of view, the bacteria studied here and their lipolytic enzymes possess characteristics that are relevant to industry. H. sulfidaeris LAMA 838 was able to grow over a large temperature range, produced lipolytic enzymes that are active at high temperatures and was able to hydrolyze multiple lipid substrates. Major parts of the industrial processes that involve the use of lipases occur at temperatures above 45ºC. These higher temperatures may reduce the risks of contamination by other mesophilic microorganisms, generate higher reaction rates, and increase diffusion and solubility of the substrate (López-López et al., 2014). In the case of M. excellens LAMA 842 the activity of lipases at low temperatures stands out because this characteristic may allow for high conversion rates of substrate to product at low energy costs. These cold-active lipases also have potential uses as detergent additives in cold washes in the food industry, in the transesterification for biofuels production, and in soil or aquatic bioremediation at low temperatures (Kavitha, 2016).

CONCLUSION

It was concluded that the evaluated strain of H. sulfidaeris, LAMA 838, displayed a higher growth rate at 30ºC, although it grew at low temperatures as well, and its extracellular lipases were active at temperatures above 40ºC. Growth of the bacterium M. excellens LAMA 842 occurred at temperatures above 15°C and its lipases were active at various temperatures including low temperatures. In the evaluation of culture media, we observed a greater influence of the presence of Tween on the growth of M. excellens LAMA 842 in the marine broth; however, the lipolytic activity of both bacteria was stimulated with the addition of this lipid substrate in the culture medium. Thus, the composition of the medium and the cost of production vary according to the microorganism and interest. The strains studied have the potential to be used as sources of lipases for biotechnological uses such as effluent treatment and detergent supplementation. M. excellens LAMA 842 stand out among the two strains, since it showed lipolytic activity at lower temperatures and it stimulation by the lipid substrates used. In further studies the lipases of these bacteria should be purified and characterize in more detail.

ACKNOWLEDGMENTS

The funding agency Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brazil, Process 88887.146746/2017-00) and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) - INCT-Mar COI (Instituto Nacional de Ciência e Tecnologia, Centro de Oceanografia Integrada, Brazil, Process 565062/2010-7) supported this work. The authors thank CNPq - INCT-Mar COI for DTI-B scholarship support provided to G. S. D. (381222/2017-9) and CNPq for scholarship provided to A. O. S. L. (Process 312363/2018-4).

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Edited by

  • Editor: Rubens M. Lopes
  • Associate Editor: Camila N. Signori

Publication Dates

  • Publication in this collection
    12 June 2020
  • Date of issue
    2020

History

  • Received
    29 Aug 2019
  • Accepted
    11 Jan 2020
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Instituto Oceanográfico da Universidade de São Paulo Praça do Oceanográfico 191, CEP: 05508-120, São Paulo, SP - Brasil, Tel.: (11) 3091-6501 - São Paulo - SP - Brazil
E-mail: diretoria.io@usp.br
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