Acid Degrading Bacteria from Sulfidic, Low Salinity Salt Springs Michael G

Acid Degrading Bacteria from Sulfidic, Low Salinity Salt Springs Michael G

ISOLATION AND CHARACTERIZATION OF HALOTOLERANT 2,4- DICHLOROPHENOXYACETIC ACID DEGRADING BACTERIA FROM SULFIDIC, LOW SALINITY SALT SPRINGS MICHAEL G. WILLIS, DAVID S. TREVES* DEPARTMENT OF BIOLOGY, INDIANA UNIVERSITY SOUTHEAST, NEW ALBANY, IN MANUSCRIPT RECEIVED 30 APRIL, 2014; ACCEPTED 30 MAY, 2014 Copyright 2014, Fine Focus all rights reserved 40 • FINE FOCUS, VOL. 1 ABSTRACT The bacterial communities at two sulfdic, low salinity springs with no history of herbicide CORRESPONDING contamination were screened for their ability to AUTHOR grow on 2,4-dichlorophenoxyacetic acid (2,4-D). Nineteen isolates, closely matching the genera * David S. Treves Bacillus, Halobacillus, Halomonas, Georgenia and Department of Biology, Kocuria, showed diverse growth strategies on NaCl- Indiana University Southeast supplemented and NaCl-free 2,4-D medium. The 4201 Grant Line Road, New majority of isolates were halotolerant, growing best Albany, IN, 47150 on nutrient rich broth with 0% or 5% NaCl; none [email protected] of the isolates thrived in medium with 20% NaCl. Phone: 812-941-2129. The tfdA gene, which codes for an a – ketoglutarate dioxygenase and catalyzes the frst step in 2,4- D degradation, was detected in nine of the salt KEYWORDS spring isolates. The tfdAa gene, which shows ~60% identity to tfdA, was present in all nineteen • 2,4-D isolates. Many of the bacteria described here were • tfdA not previously associated with 2,4-D degradation • tfdAa suggesting these salt springs may contain microbial • salt springs communities of interest for bioremediation. • halotolerant bacteria INTRODUCTION Bacteria have tremendous potential to (B-Proteobacteria; formerly Ralstonia degrade organic compounds and study of eutropha) has received considerable the metabolic pathways involved is a key attention and serves as a model system for component to more effcient environmental microbial degradation (2, 3, 26). The frst remediation. One well-studied organic gene in the catabolic pathway, tfdA, codes acid degradation pathway is that of 2,4– for an a – ketoglutarate dioxygenase (6, 7). dichlorophenoxyacetic acid (2,4-D) (4, 12, The remainder of the pathway is comprised 13, 15, 19, 23). The broadleaf herbicide 2,4- of at least fve genes, e.g. tfdBCDEF, that D was developed during World War II by continue to break down the molecule for British scientists to help boost production use in central metabolism (29). Members of grass crops like corn, wheat, and rice of the a-, B- and y-Proteobacteria are (23). Since the late 1940’s it has been one known to degrade 2,4-D and several of the most popular herbicides used by unique degradation pathways have been industrial farms and homeowners for the identifed. In the B- and y- Proteobacteria control of broadleaf weeds (30). three classes of tfdA genes are found while the a-Proteobacteria carry tfdAa that has The 2,4-D degradation pathway ~60% identity to the tfdA gene of JMP134 of Cupriavidus necator JMP134 (9, 30). A novel cadABC-based degradation APPLIED/ENVIRONMENTAL • 41 pathway which codes for 2,4-D oxygenase subunits (15) has also been MATERIALS AND found in a-Proteobacteria (10). Although there has been extensive METHODS research conducted on 2,4-D SITE DESCRIPTION AND degraders in the soil (12 ,13 ,15, 23), there is less work on the removal SAMPLE COLLECTION of 2,4-D in aquatic environments Salt spring samples were collected from of varying salinity. Maltseva Big Bone Lick State Park located in Boone et al. (18) isolated three 2,4-D County, KY. The area surrounding the degrading bacteria from the family park is a rural semi-agricultural region; Halomonadaceae in the soil of a there are several salt-springs inside the high salinity, alkaline lake that was park’s boundary and many more springs heavily polluted with 2,4-D and other throughout the surrounding area. Two organic acids. Although these isolates springs were the focus of this study came from an extreme environment, because they are easily accessed from and were moderately halophilic and the park visitor center. Spring samples alkaliphilic, they still utilized the representing both spring water and well-known tfdA-based degradation water mixed with spring sediment were pathway of JMP134 (18). collected from the small spring (N 38° 53’ 4.582”, W 84° 45’ 10.648”) and large The objective of this study was spring (N 38° 53” 5.899”, W 48° 45” to isolate and characterize 2,4-D 9.928”) in sterile polypropylene containers, degrading bacteria from salt springs transported to IU Southeast in a cooler at Big Bone Lick State Park in (~1.5 h) and used immediately for plating Boone County, KY. The park and experiments. surrounding area contain numerous natural springs but this area does not PLATING AND ISOLATE have a history of 2,4-D contamination. PURIFICATION The isolates obtained, including some A dilution series of the spring samples genera not previously associated with was done using sterile phosphate buffered 2,4-D degradation, were examined saline with dilutions spread onto Artifcial for their ability to grow on 2,4- Sea Water nutrient broth (ASW) (17) D in the presence and absence of agar plates with 5, 10 or 20% NaCl to NaCl and screened for commonly assess levels of halotolerant heterotrophs occurring 2,4-D degradation genes. and MMO minimal medium plates (13) Isolation and characterization of supplemented with 125 ppm 2,4-D / 5% 2,4-D degrading bacteria from novel NaCl to assess levels of 2,4-D degraders. environments, such as the salt springs Plates were incubated for two weeks at in Big Bone Lick State Park, not only 28°C. Single colonies were transferred expands information on the diversity to MMO 125 ppm 2,4-D / 5% NaCl for of herbicide degrading bacteria but purifcation and after several plate transfers also provides useful information for they were grown in Difco Marine broth bioremediation of contaminated saline (Beckton Dickinson & Co., Sparks, MD) and environments. stored at -80°C in 15% glycerol. 42 • FINE FOCUS, VOL. 1 GROWTH ASSESSMENT ON 27f, 1492r and 519f (25) was performed at 2,4-D the IUPUI Core Sequencing Facility using Applied Biosystems 3100 Genetic Analyzers Purifed isolates were streaked to MMO and Big Dye Terminator chemistry v3.1 2,4-D plates with and without 5% NaCl (perkinelmer.com). Sequences were edited and incubated at 28°C for 14 days. At using Chromas (http://technelysium.com. regular intervals growth of the isolates au) and compiled in BioEdit (http://www. was assessed visually by two independent mbio.ncsu.edu/BioEdit/bioedit.html). Full observers and growth was scored as none or partial sequences were used to query (-), poor (+), moderate (++) or good (+++). the Genbank database using the Basic Local DNA EXTRACTION, PCR Alignment Search Tool (BLAST) (1). AND 16S rRNA GENE SALT TOLERANCE CHARACTERIZATION Each isolate was transferred to 2ml of Genomic DNA from individual isolates was ASW nutrient broth (17) containing NaCl extracted using the MoBio Microbial DNA ranging from 0, 5, 10, 15 or 20% and Extraction Kit (mobio.com). The 16S rRNA incubated at 25°C at 200 rpm for 48 hours. gene was amplifed using 27f and 1492r Longer incubations of 72 and 96 hours primers (25), and isolates were screened for did not yield increases in optical density. tfdA using the TVU and TVL primers of Optical density was measured using a Hogan et al. (8). Screening for tfdAa was Biotek ELx 800 plate reader at 630nm. done using Alpha1 (5’-ACS GAG TTC KSC GAC ATG CG-3’) and Alpha2 (5’-GCG GTT SALT SPRING CHEMISTRY GTC CCA CAT CAC-3’) primers using the Spring water temperature, pH, salinity, PCR conditions described by Itoh et al. total dissolved solids and conductivity (9). Promega GoTaq® Green Master Mix were measured using a Hach SensION 156 was used for PCR with reaction mixtures multi-parameter meter on 9 Sept 2006, prepared according to manufacturer’s 8 Mar 2007, 30 Sept 2009, 16 Oct 2011, protocols and thermal cycling was performed 5 Feb 2010 and 10 Oct 2010. No pH data using a TECHNE Flexigene thermal cycler. was collected from the springs during the The 16S rRNA gene products were purifed 5 Feb 2010 sampling trip as the pH probe using the MoBio Ultraclean™ PCR Cleanup malfunctioned on this date. Kit and DNA sequencing using primers RESULTS SALT SPRING water chemistry such as pH, temperature CHARACTERISTICS and salinity were measured (Table 1). The springs are shallow (~13 cm at the This study focused on two salt springs deepest point) and located no more than located within the borders of Big Bone 100 meters from one another. In general, Lick State Park in Boone County, KY. chemistry between the two springs was During six visits to the springs between similar which, along with their proximity, 2006-2010 spring characteristics and suggests a common groundwater source. APPLIED/ENVIRONMENTAL • 43 Table 1. Water char- acteristics of two Big Bone Lick State Park salt springs. ASSESSMENT OF ISOLATION AND CULTURABLE BACTERIAL IDENTIFICATION OF COMMUNITIES OF THE PUTATIVE 2,4-D DEGRADING SPRINGS ISOLATES Spring samples representing water only Nineteen isolates transferred from the and water mixed with sediment were original 2,4-D plates and which produced plated onto artifcial seawater medium small transparent colonies on media with (ASW) supplemented with 5, 10 or 20% 2,4-D as the sole carbon source at 28°C NaCl to assess heterotrophic halotolerant were chosen for further characterization. bacterial populations (Table 2). CFUs were Using 16S rRNA gene sequence data observed at all three salt concentrations the closest match to each isolate was although there was generally a reduction determined from Genbank (Table 3). Eleven in CFU/mL as the salt concentration of 19 isolates closely matched the genus increased.

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