New Report on the Occurrence of Exiguobacterium sp. AT1b in the Persian Gulf and its Resistance to Mercury Pollution
M. Mazaheri Assadi,
This study was done to investigate of new mercury resistant bacteria in coastal waters of Mahshahr area which the greatest petrochemical chlor-alkali unit of Iran located there. Water and sediment samples were taken and cultured on specific media in laboratory. Traditional biochemical and modern molecular approaches were used for identification. Mercury toxicity was measured via Minimal Inhibitory Concentration method. New observation of a coryneform, the Exiguobacterium sp. AT1b was occurred and identified based on 16S rRNA gene homology. Sequence matching was 99% and resistance to mercuric chloride were 75 and 50 ppm in different media. Optimal growth conditions was studied and temperature range plus with optimum pH were determined. Wide range of temperature tolerance and other conditions such as salinity and pH variation tolerance were observed. Agitation was the least affecting parameter on the growth based on optical density measured and analysis of variance results. The Exiguobacterium sp. AT1b is one of the best bacteria suggested for environmental studies and simulations.
Received: July 05, 2010;
Accepted: October 23, 2010;
Published: March 25, 2011
Persian Gulf is one of the most important marine areas because of around 70%
of the world oil exploitation and transportation undergoes across this semi-enclosed
sea at the North-West corner of the Western Indian Ocean (Nadim
et al., 2008). In spite of the great importance, Persian Gulf is
still poorly environmentally understood. Political relationships and three extended
wars during the past three decades have been covered other aspects of this area
(Price et al., 1994).
Persian Gulf had been faced with many types of pollution after long time passing
from oil trade and development of industrial activities plus with war disadvantages.
Furthermore, the genus Exiguobacterium is a newly described bacterium
which was explained by Collins et al. (1983).
This genus has 17 described species and more than 294 strains and new members
are still adding to that. Members of this genus had formerly been identified
as the genera such as Corynebacterium, Brevibacterium and even
Staphylococcus (Rodrigues et al., 2006)
because of some similarities in peptidoglycan structure or fatty acid profile.
Modern molecular based techniques revealed it as a new genus separated from
coryneforms. This microorganism seems to be a cosmopolitan genus since its wide
range of dispersion all over the world. Little of its characteristics are nowadays
well-known, however, resistance to mercury was reported by Wagner
et al. (2003). Biology of Exiguobacterium is still poorly
understood and our knowledge limits to relatively small number of reports about
sequenced genes and their functions that can be found in international databases
(Jakubauskas et al., 2009).
The Exiguobacterium sp. AT1b was isolated and described first by Robert F. Ramaley (Nebraska Medical Center, Omaha, NE) and Christine Hendrix (Yellowstone National Park) in 2004. the strain Exiguobacterium sp. AT1b was isolated from a slightly alkaline and highly carbonated hot spring water of Angel Terrace, which is part of Mammoth Terrace, Yellowstone National park. Differences in culture methods and identification procedures leads to basically different results hard to compare. Situation which makes the environmental microflora less comparable even in adjacent regions. The aim of the present study was to investigate mercury resistant bacteria in vicinity of an industrial petro-chemical area at North Western of the Persian Gulf.
MATERIALS AND METHODS
Study area: Mahshahr is an industrial city located in 30° 33' N
and 49° 13' E in Khuzestan province, Iran (Tabatabaie
et al., 2009). Great port and full transportation system and frequent
factories have been maden it as a special industrial zone; therefore, sampling
area selected near sewage outfalls of the petro-chemistry at area around 30°
24' to 30° 27' N and 49° 06' to 49° 08' E. Seven stations sampled
for surface waters and sediments. Environmental parameters such as temperature,
pH, dissolved oxygen were measured in situ. Water and sediment samples
held in sterilized plastic bottles at 4°C ice bags until transferred to
Sediment samples were serially diluted with Phosphate Buffer Saline (PBS) to
10-4 level, then spreaded onto Sea Water Nutrient Agar (SWNA) amended
with 25 μg mL-1 Hg2+ as HgCl2. This threshold
concentration of Hg was suggested by Ramaiah and De (2003)
and bacteria could tolerate that, were known as Bacteria Highly Resistant to
Mercury (BHRM). Grown colonies were picked up into new media to ensure purity
of cultures. Mercury toxicity test was done in terms of Minimal Inhibitory Concentration
(MIC) method. Mercury concentrations in SWNA plates were in range from 0 to
100 ppm with 25 ppm intervals.
The MIC defined as the concentration of toxicant which causes no visible growth. Plates were incubated at 30°C for 3 days. Biochemical tests such as catalase, nuclease and oxidase were performed on pure cultures. Temperature and pH optimal range were studied in the range of 6°C in refrigerator to 55°C and 3 to 11, respectively. Agitation effect were also studied in range of 120 to 200 round per minute (rpm) on a rotary shaker.
Growth was measured in terms of Optical Density (OD) in 600 nm on a spectrophotometer.
DNA extraction was made by means of a DNA extraction kit DNG plus (Cinnagen,
Iran) and 16S rRNA gene was amplified with Polymerase Chain Reaction(PCR) using
primers 27f (5`-AGAGTTTGATCC TGGCTCAG-3`) and 1492r (5`-GGTTACCTTGTTACGACTT-3`)
with following program: 94°C for 5 min followed by 35 cycles at 94°C
for 1 min, 52°C for 1 min and 72°C for 2 min. A final extension was
for 5 min at 72°C. PCR products were purified using DNA purification kit
(Geni, Pin, USA) according to manufacturers instruction. PCR products
were sequenced with an ABI Prism 3100 capillary DNA sequencer. Sequencing results
were analyzed with BLAST program comparing GenBank database which is available
New finding for the Persian Gulf microflora was the Exiguobacterium sp.
strain AT1b. Both forward and reverse strands of 16S rDNA matched 99% which
reflects the precise and reliable results for species identification.; morphological
characteristics consisting of Gram positive non-spore forming bacilli with rounded
|| Phenotypic characteristics that differentiate strain AT1b.
and related type strains
|Strains: 1, strain HHS 31T; 2, Exiguobacterium acetylicum
DSM 20416T; 3, E. oxidotolerans JCM 12280T; 4, E. antarcticum
DSM 14480T; 5, E. undae DSM14481T; 6, E. sibiricum DSM 17290;
7, E. sp. AT1b was isolated in present study. Data for all strains
except E. sp. AT1b are not from this study and hereby indicated.
All of the strains shown are motile, Gram-positive, rod-shaped, do not form
endospores, grow at temperatures between 10 and 30. +: Positive; -: Negative;
ND: Not done/no data available; +/-: Variable reaction; W: Weakly positive
Catalase and Nuclease positive which appears singly, in pairs and less frequently
in chains. Colonies appear white on SWNA medium pH 8 and the pigment does not
diffuse into the medium. This bacterium is facultative anaerobe but growth was
more enhanced aerobically as the others reported. However, no significant difference
showed between shaking speeds in ANOVA test, a slight increase in growth was
observed at 180 rpm agitation (data not shown). The MICs were 75 and 50 ppm
in solid and liquid media, respectively.
Broad range of living temperature was observed foe Exiguobacterium sp. AT1b isolated from Persian Gulf waters which was from 6 to 50°C with optimum around 37°C and the best growth was observed in slightly alkaline media with pH range from 7 to 8. Colony morphology had similarities with Bacillus colonies but resembled to the typical Actinomycetes from initial days of growth. Oxidase reaction was positive. Use of multiple sources of carbon was observed except for malonate. The isolated strain was also able to growth on Nutrient Agar and Nutrient Broth and thus determined that it has advanced osmotic tolerance capabilities. Common features of seven species Exiguobacterium are compared in Table 1 for more details and exactly comparisons.
Present results were mainly in concordance with general characteristics of
this bacterium obtained by other researchers (Ramaley et
al., 2004). This high level of resistance to mercury had never been
recorded in literature for this species nor did for growth temperature range,
therefore this strain is more eurythermal than isolated by Yumoto
et al. (2004) that was able to growth from 15 to 50°C. Growth
pH that was in accordance with its original conditions and similar to above
mentioned researchers that reported in pH 8.8 on TSA medium. Colony shape and
color similarities with the genus Bacillus is because of phylogenetically
relationship among these two taxa (Farrow et al.,
1994). Oxidase reaction was positive similar to the most of the Exiguobacterium
strains (Funke et al., 1997), whereas Collins
et al. (1983) reported the genus as oxidase negative. Low level of
growth temperature is similar to E. aurantiacum reported by Collins
et al. (1983) which was 7°C and E. sibiricum and E.
oxidotolerans that were 5°C (Chaturvedi and Shivaji,
2006). This species had common characteristics with E. marinum described
by Kim et al. (2005) isolated from tidal flat
of the Yellow Sea in Korea. The E. marinum was grown on marine agar 2216
(MA; Difco) at 30°C in two days. The E. sp. strain AT1b. showed excellent
survival after exposure to a long-term freeze, rapid growth at low temperatures,
osmotic tolerance and age of the permafrost sediment from which it was cultured,
characteristic which is similar to E. sibiricum. Through analysis of
the transcriptome, experiments can be designed to study microbial survival under
a variety of harsh conditions. The issue of long-term survival is of interest
in the field of astrobiology. Organisms that survive such hostile environments
may be used as models for understanding cellular responses on astral bodies.
This strain can be considered as an extremophil species due to harsh conditions
of habitat and tolerance potentials for stress factors such as temperature,
pH and osmotic variations. Furthermore, it is suitable for educational and research
purposes as well as applied aspects such as bioremediation.
The authors wish to thank Mrs. L. Meysami Nejad for her kindly corporation in preparing this study and Mr. Daghaghele a boatman who risked his job for help in field sampling from petro-chemistry sewage outfalls. And So as to the every one which their names are not on paper, but in our minds.
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