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ISSN : 1226-9999(Print)
ISSN : 2287-7851(Online)
Korean J. Environ. Biol. Vol.41 No.2 pp.167-178
DOI : https://doi.org/10.11626/KJEB.2023.41.2.167

Identification of bacteria isolated from rockworm viscera and application of isolated bacteria to shrimp aquaculture wastewater treatment

Ja Young Cho1,2†, Kyoung Sook Cho1†, Chang Hoon Kim3, Joong Kyun Kim1*
1Department of Biotechnology, Pukyong National University, Busan 48513, Republic of Korea
2Bacteria Research Team, Nakdonggang National Institute of Biological Resources, Sangju 37242, Republic of Korea
3Department of Marine Bio-materials and Aquaculture, Pukyong National University, Busan 48513, Republic of Korea
* Corresponding author Joong Kyun Kim Tel. 051-629-5866 E-mail. junekim@pknu.ac.kr

These authors contributed equally to this work.

Contribution to Environmental Biology

▪ Aerobically denitrifying bacteria were isolated from rockworm viscera.

▪The isolates strongly degraded organic matters, which are good candidates for shrimp aquaculture wastewater treatment.

19/05/2023 13/06/2023 16/06/2023

Abstract


Large amounts of waste and wastewater from aquaculture have negatively impacted ecosystems. Among them, shrimp aquaculture wastewater contains large amounts of nitrogen contaminants derived from feed residues in an aerobic environment. This study isolated candidate strains from adult rockworms to treat shrimp aquaculture wastewater (SAW) in an aerobic environment. Among 87 strains isolated, 25 grew well at the same temperature as the shrimp aquaculture with excellent polymer degradation ability (>0.5 cm clear zone). Six isolates (strains AL1, AL4, AL5, AL6, LA10, and PR15) were finally selected after combining strains with excellent polymer degradation ability without antagonism. 16S rRNA sequencing analysis revealed that strains AL1, AL4, AL5, AL6, LA10, and PR15 were closely related to Bacillus paramycoides, Bacillus pumilus, Stenotrophomonas rhizophila, Bacillus paranthracis, Bacillus paranthracis, and Micrococcus luteus, respectively. When these six isolates were applied to SAW, they reached a maximum cell viability of 2.06×105 CFU mL-1. Their chemical oxygen demand (CODCr) and total nitrogen (TN) removal rates for 12 h were 51.0% and 44.6%, respectively, when the CODCr/TN ratio was approximately 10.0. Considering these removal rates achieved in this study under batch conditions, these six isolates could be used for aerobic denitrification. Consequently, these six isolates from rockworms are good candidates that can be applied to the field of aquaculture wastewater treatment.


rockworm viscera , indigenous bacteria , identification , shrimp aquaculture wastewater , bacterial wastewater treatment

초록

    1. INTRODUCTION

    Aquaculture is a potential solution for providing relatively cheap proteins worldwide for poor and foodinsecure populations (Kobayashi et al. 2015). This important role of aquaculture has made it the fastest- growing sector in the past few decades (Ngo et al. 2016). As fish consumption steadily increases because of its health benefits, farmed fish production for human consumption has finally surpassed wild-captured fish (World Bank 2014). Although aquaculture benefits humans, its flourishing causes problems because a large amount of waste and wastewater is generated from the aquaculture industry, negatively exerting environmental impacts on aquatic ecosystems. These impacts include pollution of nearby waters, habitat destruction, disease transfer, and release of farmed exotic species such as escape (Diana 2012). Aquaculture wastewater generally has different composition and concentration than municipal or industrial wastewater. Marine aquaculture wastewater contains excess nitrogen contaminants from fish excrement and feed residue (Schwartz and Boyd 1994). In shrimp aquaculture, 5,345-7,157 m3 of wastewater is typically discharged per ton of shrimp production (Anh et al. 2010), and there is a problem of continual nitrite accumulation and discharge into the environment (Song et al. 2011;Kim et al. 2019). Given environmental and social aspects, efficient treatment of effluent discharges is essential to develop sustainable aquaculture. So far, microbial treatment for nitrogen contaminants has been known to be the most economical and applicable technology (Vinothkumar et al. 2021). For the removal of nitrogen contaminants, the denitrification process under anaerobic/anoxic conditions is known to exhibit excellent removal efficiency (Song et al. 2011). However, anaerobic denitrification systems are difficult to apply to aquaculture farms due to aerobic cultivation condition (Song et al. 2011). Therefore, the discovery of aerobically denitrifying microorganisms is needed to efficiently treat shrimp aquaculture wastewater (SAW), since oxygen is maintained at a certain acceptable level in the shrimp aquaculture environment for high-density shrimp culture (Song et al. 2011).

    Polychaetes purify deposits via their feeding behavior, thereby mitigating the environmental impact of pollution. This role of polychaetes was reported in the bioremediation of deposited waste at the bottom of fish ponds (Kinoshita et al. 2008). Therefore, polychaetes are ecologically important taxa, particularly in marine benthic communities (Giangrande et al. 2005). The organic pollutant degradation ability of polychaetes is derived from their gut microbes, including Capitella teleta (Hochstein et al. 2019) and Osedax (Rouse et al. 2004). Nereis, a polychaete species, efficiently used unconsumed feed and fecal materials collected from a marine recirculating system (Brown et al. 2011). In addition, a Bacillus sp. strain EBW4 isolated from a polychaete, could degrade organic hydrocarbons (Shin et al. 2013). Moreover, polychaetes are often used as indicators for detecting marine pollution and show excellent potential in accumulating bioavailable heavy metals from benthic habitats (Fuirst et al. 2021) and tolerating high levels of organic compounds in soft bottoms (Tomassetti and Porrello 2005).

    As a polychaete species, rockworms are filter feeders showing the potential ability to degrade environmental pollutants. Extracellular enzymes produced by bacteria present in the excrement of a rockworm, Marphysa sanguinea, exhibited some potential degradation of polycyclic aromatic hydrocarbons (Onozato et al. 2012). The food intake of rockworms is inactive in the larval stage, whereas their food intake is active in the juvenile stage. According to a marine polychaete microbiome study (Dale et al. 2019;Fuirst et al. 2021), the bacterial community is highly dependent on the surrounding sediment ingestion. This gut flora also plays an important role in the immune system by influencing the life cycle of rockworms (McFall-Ngai et al. 2013). Besides, marine polychaete gut flora contains a variety of nitrogen cycles microbes than the environment in which they live (Fuirst et al. 2021). Therefore, rockworms are beneficial resources for water purification and nutritiously valuable resources.

    Considering the potential ability of rockworms to degrade environmental pollutants, microorganisms inhabited in rockworm viscera are good candidates for wastewater treatment. Therefore, symbiotic viscera microorganisms are useful for purifying shrimp aquaculture effluent (Robinson et al. 2015). However, further studies are required to understand the role of microorganisms in rockworm viscera. Herein, therefore, native bacteria were isolated from rockworm (M. sanguinea) viscera to utilize their potential ability for water purification. Among the isolates, those showing potential ability were first sorted and identified. The identified isolates were then applied to simulated SAW to evaluate their potential ability.

    2. MATERIALS AND METHODS

    2.1. Isolation of microorganisms and culture conditions

    Rockworms (Marphysa sanguinea) in the adult growth stage were collected from the Fisheries Sciences Technology Center (Pukyong National University, Goseung, Korea). The collected rockworms were washed in the order of phosphate buffer saline (PBS) solution (1× pH=7.4, Thermofisher Scientific, USA) and 70% (v/v) ethanol. After the skins of the washed rockworms were cut lengthwise, internal parts were dissolved in the PBS solution to collect microorganisms in the viscera. The prepared sample was centrifuged at 15,520×g for 10 min. To detect microorganisms, even in small amounts, the supernatant was poured onto various solid culture media: nutrient broth (NB) agar (Neogen, USA), skim milk (SM) agar (Bioshop, Canada), laminarin (LA) agar (TCI, Japan), alginate (AL) agar (Sigma-Aldrich, USA), spirit blue (SB) agar (Sigma-Aldrich), and phenol red (PR) tween agar (Sigma-Aldrich). The NB agar medium consisted of 8 g L-1 nutrient broth and 15 g L-1 agar (Junsei, Japan). The SM agar medium consisted of 10 g L-1 skim milk and 15 g L-1 agar. The LA agar medium contained 1 g L-1 laminarin, 0.1 g L-1 MgSO4·7H2O, 0.1 g L-1 NaCl, 0.1 g L-1 CaCl2, 2 g L-1 (NH4)2SO4, 0.5 g L-1 KH2PO4, 0.5 mL L-1 mineral solution, 0.5 mL L-1 vitamin solution, and 15 g L-1 agar (pH=6.8). The AL agar medium consisted of 0.5 g L-1 peptone (Bioshop), 0.1 g L-1 sodium alginate, and 15 g L-1 agar (pH=6.8). The SB agar medium comprised 32.15 g L-1 SBA and 30 mL L-1 tributyrin (TCI). The PR tween agar medium contained 8 g L-1 nutrient broth, 10 mL L-1 tween, 0.018 g L-1 phenol red, and 15 g L-1 agar (pH=6.8). All agar plates were incubated at 25°C for 72 h. Colonies formed on each agar medium were separated using morphological differences under microscopic observation and colonial shape. The sorted colonies were finally streaked onto fresh nutrient broth agar media, and then each isolated colony was used for identification.

    2.2. Characterization and identification of isolates

    Each sorted colony was characterized using Gram staining, stabbing into nutrient broth agar medium, and microscopic observation. In addition, the degradation ability of each colony on polymers was investigated using carboxymethyl cellulose (CMC) agar (Sigma- Aldrich), SM agar, and SB agar media. The carboxymethyl cellulose agar medium consisted of 2 g L-1 peptone, 5 g L-1 yeast extract, 1 g L-1 CMC, and 15 g L-1 agar (pH=6.8). Then, 10 μL of each isolate grown in a late-log growth phase were dropped into 8-mm paper disks (Advantec, Japan) and incubated at 25°C for 24 h. After incubation, the sizes of clear zones formed on carboxymethyl cellulose agar and SM agar media were measured for cellulose and protein degradation ability, respectively, and the formation of blue colonies on the SB agar medium was observed for lipid degradation ability. All the isolates were incubated at 25°C for 24 h after cross-straining on the nutrient broth agar medium. The possibility of any hindrance in cell growth was observed after incubation to check the occurrence of antagonism among the isolates.

    16S rRNA sequence analysis was conducted at Cosmogenetech (Seoul, Korea) to identify the isolates. The primers used were universal oligonucleotides corresponding to 27F (5ʹ AGA GTT TGA TCM TGG CTC AG 3ʹ), 1492R (5ʹ GGT TAC CTT GTT ACG ACT T 3ʹ), and 518F (5ʹ CCA GCA GCC GCG GTA ATA CG 3ʹ). The sequences of isolates were matched with the 16S-based ID in EzBioCloud (https://www.ezbiocloud. net/) (Yoon et al. 2017), and the identified 16S rRNA sequence of each isolate was used to constitute a phylogenetic tree using MEGA version 7. The sequences were first aligned with Clustal W using the BioEdit program (Version 7.2.0), and then a phylogenetic tree was constituted via neighbor-joining tree analysis with 1,500 bootstrap replicates.

    2.3. Simulated shrimp aquaculture wastewater treatment

    To examine the potential degradation ability of indigenous microorganisms in rockworm viscera, selected isolates were applied to treat SAW. SAW was treated using a formulated diet for whiteleg shrimp (Litopenaeus vannamei). The whiteleg shrimp diet was ground and sieved through the 38-μm mesh, which consisted of 38% crude protein, 5% crude lipid, 2.7% phosphorus, 1.2% calcium, 4.0% crude fiber, and 17% crude ash. The SAW was prepared by dissolving 1 g of whiteleg shrimp diet in 500 mL distilled water. Afterward, the SAW was autoclaved at 121°C for 15 min. Before treating SAW, isolates were preliminarily adapted in SAW at 25°C for 24 h. The adapted isolates (10%, v/v) were seeded into a 1-L flask containing 500 mL of autoclaved SAW, and the flask was incubated at 25°C and 130 rpm for 36 h. Samples were periodically collected, and reaction parameters were determined.

    2.4. Analytical methods

    During the treatment of SAW, reaction parameters (pH, optical density (OD600)), viable cell number, chemical oxygen demand chromium (CODCr) concentration, and total nitrogen (TN) concentration) were determined to examine the waste treatment ability of isolates. The pH and OD600 of each sample collected from the flask were measured using a pH meter (Mettler Toledo, Switzerland) and a spectrophotometer (Hanson Technology Co., Korea) at 600 nm, respectively. The collected sample was also appropriately diluted with sterile distilled water, spread on the nutrient broth agar medium, and incubated at 25°C for 36 h to determine viable cell numbers. The viable cells formed on the nutrient broth agar medium were counted and represented as colony-forming units (CFUs) per mL. The concentrations of CODCr and TN in the samples were determined using an HS 2000 Water-quality Analyzer (Humas Co., Ltd, Korea). All analyses were triplicated. Differences in all groups were analyzed by one-way analysis of variance with Tukey̓s HSD posthoc test using SPSS 17.0. The p-value<0.05 was considered significant.

    3. RESULTS AND DISCUSSION

    3.1. Isolation of potential microorganisms

    Potential microorganisms from adult rockworm viscera were successfully screened. Colonies with different shapes formed on six agar media were first sorted out, and their morphological differences were carefully observed under a microscope. The colonies displaying unique characteristics were serially picked from the six-agar media (NB, SM, LA, AL, SB, and PR tween agar media), and each isolate was named after the originally isolated spot of such agar medium in the given order. Finally, 87 colonies were isolated. Considering the shrimp aquaculture environment (approximately at 25°C), these microbial species were further screened based on their ability to degrade polymers at 25°C (Wyban et al. 1995). Only 25 colonies were eligible for these criteria with sufficient growth (OD600>0.8) at 25°C, and potential degradation ability (>0.5 cm clear zone) toward protein or lipid. Afterward, the antagonism tests were performed between the 25 isolates, and 12 colonies were excluded because they inhibited the growth of other microbial strains. Among the remaining 13 isolates (Table 1), isolates of LA9, SB13, SM16, SM19, and PR21 were finally excluded owing to their inability to degrade lipids.

    To select appropriately mixed microorganisms suitable for treating SAW containing complex components, 12 different combinations of isolates were examined based on the degradability of polymers (protein and lipid) generally present in SAW (Iber and Kasan 2021). This experiment was performed because a mixed culture is more advantageous than a single culture in the degradation of complex components in nature (Jankowska et al. 2015). In particular, mixed cultures of microorganisms could utilize the substance in nature well since a broad range of enzymes is synthesized by the mixed cultures and such enzymes can degrade various polymers. In this respect, combined isolates cultivated in 1 g L-1 SAW at 25°C for 24 h were tested for their polymer-degrading ability. All test groups exhibited degradation abilities on both protein and lipid under the conditions of diversely combined microorganisms (Table 2). Notably, Groups 2 and 8 exhibited higher protein degradation activity than other groups. In addition, the viable cell number of Group 2 was better than that of Group 8. This indicates that the proliferation of mixed culture in Group 2 was the most active owing to its high degradation ability of polymers in SAW. Meanwhile, the mixed culture in Group 5 exhibited the highest number of viable cells but was excluded from this study owing to its low protein degradation ability. Therefore, Group 2, composed of six isolates, was selected for SAW treatment.

    3.2. Characterization and identification of isolates

    Since Group 2 exhibited the best polymer-degrading activity, the characteristics of each isolate included in Group 2 were examined to distinguish the role of each isolate when applied. The isolates AL1, AL4, AL6, and LA10 were Gram-positive and rod bacteria, whereas the isolate AL5 was Gram-negative and rod bacterium. In particular, the isolate LA10 was a chain-forming bacterium. Unlike these bacteria, isolate PR15 was observed to uniquely form tetrad cocci. All isolates were motile and different in cell dimensions. The colors of colonies formed on the nutrient broth agar medium were ivory (AL1, AL6, and LA10), pale yellow (AL4), and yellow (AL5 and PR15).

    The 16S rRNA sequence analysis was conducted for the six selected isolates in Group 2. Homology searches showed that the isolates AL1, AL4, AL5, AL6, LA10, and PR15 were the most closely matched to Bacillus paramycoides (99.86%), Bacillus pumilus (99.52%), Stenotrophomonas rhizophila (100%), Bacillus paranthracis (99.66%), Bacillus paranthracis (99.52%) and Micrococcus luteus (99.58%), respectively (Table 3). Based on partial 16S rRNA sequences of each isolate, a neighbor-joining phylogenetic tree was drawn with other phylogenetically related strains (Fig. 1). Bacillus species are known to produce diverse extracellular enzymes; thus, microorganisms showing potential proteolytic activity in industrial fields belong to the genera Bacillus (Pant et al. 2015). B. paramycoides had some potential ability to treat hospital wastewater (Rashid et al. 2020), degrade organophosphate compounds (Ren et al. 2020), and remove toxic selenite from contaminated sites (Borah et al. 2021). B. pumilus produced potential xylanase (Kapoor et al. 2008) to efficiently degrade toxic aromatic compounds (Surendra et al. 2017) and improve the health and growth rate of striped catfish when it was used with B. amyloliquefaciens as a dietary additive (Thy et al. 2017). B. paranthracis also degraded a pharmaceutical pollutant, diclofenac (Chopra and Kumar 2020), and polycyclic aromatic hydrocarbons (Wang et al. 2020). Moreover, Stenotrophomonas sp. produced various extracellular enzymes, such as proteases, lipases, nucleases, chitinases, and elastases (Ryan et al. 2009). The genus Stenotrophomonas, isolated from surface waters, can denitrify in the presence of O2 (Lv et al. 2017). M. luteus had the potential ability to degrade cyclic organic compounds (Zheng et al. 2009) and hydrocarbons (Shin-ya and Kajiuchi 2002;Tuleva et al. 2009), enabling it to be used in bioremediation (Kanjilal et al. 2015). Moreover, five isolates, i. e., bacteria of the genus Bacillus and Strenotrophomonas, are known for their ability to perform aerobic denitrification (Lv et al. 2017;Yang et al. 2020). Therefore, the above-reported results imply that the six selected isolates herein were eligible for treating SAW.

    3.3. The application of six isolates to SAW treatment

    The six selected isolates were applied to simulated SAW to investigate their potential degradation ability on substances mainly from uneaten feed and feces. During the treatment of simulated SAW, the pH increased from 6.21 to 7.45 for the first 12 h. Afterward, it was maintained (Fig. 2A). Simultaneously, the cell density (OD600) and the number of viable cells rapidly increased from 1.37 to 2.34 and 5.90×104 to 2.06×105 CFU mL-1, respectively, for the first 12 h. Moreover, this tendency was exactly reflected in the reductions of CODCr and TN as a result of biodegradation by the isolates (Fig. 2B). This indicates that biodegradation occurred actively for the first 12 h with cell growth. During the first 12 h, the removal percentages of CODCr and TN were 51.0% and 44.6%, respectively. The ratio of CODCr to TN was maintained at 10.0, except for the treatment time of 8 h because the reduction rate of TN by the mixed culture surpassed that of CODCr between 3 and 8 h. During this period of biodegradation, cells gradually proliferated, and thus nitrogen source was consumed considerably for cell growth. After 12 h, the decrease in the reduction rates of CODCr and TN became dull, and those reduction rates were slightly changed between 24 h and 36 h. Simultaneously, the numbers of viable cells did not increase further after 24 h, terminating the determination of all reaction parameters at 36 h.

    Herein, biodegradation by the mixed culture was not distinct after 12 h of the saw treatment. The final removal efficiencies of CODCr and TN by the mixed culture of six isolates were 51.0% and 44.6%, respectively. SAW treatment was performed in a 1-L flask containing 500 mL SAW to ensure treatment under limited O2. The six isolates reached a maximum cell viability of 2.06×105 CFU mL-1 in the SAW treatment (Fig. 2A), but according to the number of viable cells in Table 2, the six isolates in Group 2 are in an exponential growth state where they rapidly grow. The C/N (COD/ TN) ratio and other factors, such as pH and concen- trations of fat and lipid, affected the efficiency of the biological wastewater treatment (Sunny and Mathai 2015). In this experiment, pH was maintained at ~7.45 throughout 36 h, and air was not injected continuously. Therefore, the C/N ratio and batch condition are important parameters affecting the biodegradation process in this study of wastewater treatment (Gao et al. 2010). For carbon utilization, microorganisms have difficulty synthesizing their necessary enzymes under a low N content, whereas microbial growth is inhibited under a high N content, particularly in the form of ammonia (Fontenot et al. 2007). In general, the C/N ratios of various wastewaters vary from 20 : 1 to 30 : 1 (Fontenot et al. 2007). However, the efficient treatment of wastewater occurs at a C/N ratio of 10 : 1 (Fontenot et al. 2007). Since the wastewater of residual feed from shrimp farms contains high nitrogenous concentrations (Roy et al. 2010;Iber and Kasan 2021), the C/N ratio is indispensably optimized for efficient treatment. Thus, the removal of nitrates under various C/N ratios (5 : 1, 10 : 1, 20 : 1, and 30 : 1) was studied for SAW, and the most effective nitrate removal was achieved at a C/N ratio of 10 : 1 (Fig. 2B). A C/N ratio of 10 : 1 was reported to produce the best results for maximum nitrogen and carbon removal from SAW in a sequencing batch reactor (Fontenot et al. 2007). A COD/TKN (total Kjeldahl nitrogen) ratio of 10 : 1 was also reported to be optimum for high nitrogen removal efficiency in the activated sludge process under very low operating O2 concentration, with oxidation-reduction potential for aeration control (Chevakidagarn et al. 2012). In addition, a C/N ratio of 15 : 1 was reported to display the highest removal of ammonia (98.7%) in fish farm wastewater (Bakar et al. 2015). All these results indicate that optimizing the C/N ratio is an important factor for efficiently removing nitrogen-containing residues (Roy et al. 2010;Bakar et al. 2015;Nguyen et al. 2018). Considering the above results, herein, the C/N ratio that remained at 10 : 1 for 36 h is appropriate for efficient nitrate removal. Therefore, a considerable reduction of residual CODCr and TN would occur with continuous aeration (Avnimelech 2009;Iber and Kasan 2021). This inference can be adequately supported by previous reports. Boopathy et al. (2007) performed biological treatment of shrimp farm wastewater under anoxic and aerobic modes, and they obtained a greater reduction of COD under the aerobic mode than in the anoxic mode. Sun et al. (2016) reported that reducing the carbon source was strongly related to cell growth.

    In the case of nitrogen removal, anaerobic denitrification is considerably efficient, and wastewater is treated using a combination of aerobic and anaerobic (or anoxic modes) conditions (Lv et al. 2017). In this study, five among six isolates were found to be bacteria having ability of aerobic denitrification. Especially, the aerobic denitrification of the genus Bacillus strains is closely related to bacterial cell density in connection with COD reduction (Yang et al. 2020). The six isolates also showed a TN removal rate of 44.6% under batch conditions. Considering the average TN reduction rate of the aerobic denitrification strains is known to be 6-50% (Lv et al. 2017), six isolates are suitable for the treatment of aerobic denitrification. In conclusion, six isolates can remove CODCr and TN with additional aeration and are particularly valuable for aquaculture wastewater treatment in aerobic environments. Since shrimp farms are an aerobic environment, discovering strains that can simultaneously treat CODCr and TN under the same conditions is essential. Thus, the six isolates from rockworms are good candidates that can be applied to the field of aquaculture wastewater treatment in the future.

    4. CONCLUSION

    In shrimp aquaculture, large amounts of nitrogen contaminants are derived from feed residues in an aerobic environment, impacting negatively on ecosystems. To efficiently treat shrimp aquaculture wastewater (SAW), candidate strains were isolated from adult rockworms. Six isolates (strains AL1, AL4, AL5, AL6, LA10, and PR15) were finally selected by combining strains with excellent polymer degradation ability without antagonism. The six strains were identified to be Bacillus paramycoides, Bacillus pumilus, Stenotrophomonas rhizophila, Bacillus paranthracis, Bacillus paranthracis, and Micrococcus luteus, respectively with >99.52% similarity. The six isolates reached a maximum cell viability of 2.06×105 CFU mL-1 in 12 h of SAW treatment, with 51.0% of chemical oxygen demand (CODCr) and 44.6% of total nitrogen (TN) removal rates under the CODCr/TN ratio approximately at 10.0. These removal rates achieved under batch conditions indicate that the six isolates could be applied to the treatment of aerobic denitrification. Thus, the six isolates are particularly valuable for aquaculture wastewater treatment in aerobic environments, extending their application to the field of aquaculture wastewater treatment.

    ACKNOWLEDGEMENTS

    This work was supported by a Research Grant of Pukyong National University (2021).

    CRediT authorship contribution statement

    JY Cho: Conceptualization, Methodology, Investigation, Visualization, Writing - Original Draft, Writing - Review & Editing. KS Cho: Methodology, Investigation, Data Curation, Writing - Original Draft. CH Kim: Resources, Project administration, Funding acquisition. JK Kim: Conceptualization, Data Curation, Supervision, Writing - Review & Editing.

    Declaration of Competing Interest

    The authors declare no conflicts of interest.

    Figure

    KJEB-41-2-167_F1.gif

    A neighbor-joining phylogenetic tree drawn with other phylogenetically related strains based on partial 16S rRNA sequences of each isolate in Group 2. Sequences were aligned with Clustal W using the BioEdit program (Version 7.2.0). A phylogenetic tree was constituted via neighbor-joining tree analysis with 1,500 bootstrap replicates by MEGA version 7. NCBI accession numbers are presented in parentheses.

    KJEB-41-2-167_F2.gif

    Variations of (A) viable cell, OD600, and pH; and (B) TN, CODCr, and C/N ratio as a function of SAW treatment time for the six selected isolates from Group 2. Data are presented as means standard deviation (n=3). Different letters on bars indicate a significant difference (p<0.05). OD600, optical density; CODCr, chemical oxygen demand; TN, total nitrogen; C/N, COD/TN; SAW shrimp aquaculture wastewater.

    Table

    Characteristics of 13 isolates and their polymer-degrading ability

    Polymer-degrading ability and viable cell number in each test group after 24 -h cultivation at 25°C

    Results of identification for the six selected isolates

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    Vol. 40 No. 4 (2022.12)

    Journal Abbreviation 'Korean J. Environ. Biol.'
    Frequency quarterly
    Doi Prefix 10.11626/KJEB.
    Year of Launching 1983
    Publisher Korean Society of Environmental Biology
    Indexed/Tracked/Covered By

    Contact info

    Any inquiries concerning Journal (all manuscripts, reviews, and notes) should be addressed to the managing editor of the Korean Society of Environmental Biology. Yongeun Kim,
    Korea University, Seoul 02841, Korea.
    E-mail: kyezzz@korea.ac.kr /
    Tel: +82-2-3290-3496 / +82-10-9516-1611