Jiang Li1, Qiushi Hu2, Yuquan Li3, Yuan Xu3. 1. Key Laboratory of Marine Bioactive Substances, The First Institute of Oceanography, Qingdao, China . 2. College of Chemical Engineering, Qingdao University of Science & Technology, Qingdao, China . 3. Marine Science and Engineering College, Qingdao Agriculture University, Qingdao, China .
Abstract
An extracellular β-agarase was purified from Pseudoalteromonas sp. NJ21, a Psychrophilic agar-degrading bacterium isolated from Antarctic Prydz Bay sediments. The purified agarase (Aga21) revealed a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, with an apparent molecular weight of 80 kDa. The optimum pH and temperature of the agarase were 8.0 and 30 °C, respectively. However, it maintained as much as 85% of the maximum activities at 10 °C. Significant activation of the agarase was observed in the presence of Mg(2+), Mn(2+), K(+); Ca(2+), Na(+), Ba(2+), Zn(2+), Cu(2+), Co(2+), Fe(2+), Sr(2+) and EDTA inhibited the enzyme activity. The enzymatic hydrolyzed product of agar was characterized as neoagarobiose. Furthermore, this work is the first evidence of cold-adapted agarase in Antarctic psychrophilic bacteria and these results indicate the potential for the Antarctic agarase as a catalyst in medicine, food and cosmetic industries.
An extracellular β-agarase was purified from Pseudoalteromonas sp. NJ21, a Psychrophilic agar-degrading bacterium isolated from Antarctic Prydz Bay sediments. The purified agarase (Aga21) revealed a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, with an apparent molecular weight of 80 kDa. The optimum pH and temperature of the agarase were 8.0 and 30 °C, respectively. However, it maintained as much as 85% of the maximum activities at 10 °C. Significant activation of the agarase was observed in the presence of Mg(2+), Mn(2+), K(+); Ca(2+), Na(+), Ba(2+), Zn(2+), Cu(2+), Co(2+), Fe(2+), Sr(2+) and EDTA inhibited the enzyme activity. The enzymatic hydrolyzed product of agar was characterized as neoagarobiose. Furthermore, this work is the first evidence of cold-adapted agarase in Antarctic psychrophilic bacteria and these results indicate the potential for the Antarctic agarase as a catalyst in medicine, food and cosmetic industries.
Agar, an important polysaccharide derived from red algal (Gelidium and
Gracilaria) cell walls, comprises agarose and agaropectin. Agarose
is a linear chain consisting of alternating residues of 3-O-linked
β-D-galactopyranose and 4-O-linked 3,6-anhydro-α-L-galactose (Duckworth and Yaphe, 1972). Agarase, a glycoside
hydrolase (GH), can hydrolyze agarose. Based on the pattern of hydrolysis of the
substrates, agarases are grouped into α-agarases and β-agarases (Araki, 1959; Hassairi
). α-Agarases cleave the α-1,3 linkages to
produce a series of agarooligosaccharides related to agarobiose (Potin ), whereas β-agarases
cleave the β-1,4 linkages to produce a series of neoagarooligosaccharides related to
neoagarobiose (Kirimura ). Most of the reported agarases are β-agarases, which are classified into
four glycoside hydrolase (GH) families, GH16, GH50, GH86, and GH118, based on the amino
acid sequence similarity on the Carbohydrate-Active EnZyme database (CAZy) (Cantarel ; Chi ). To date, most of
the agarases have been isolated from various sources, including seawater, marine
sediments, marine algae, marine mollusks, fresh water, and soil(Fu and Kim, 2010); however, agarases isolated from the
Antarctic environment have not yet been reported.The Antarctic marine environment is perennially cold, and in some cases, it is
permanently covered with ice. Spatial heterogeneity, combined with extreme seasonal
fluctuations such as those experienced during the annual sea-ice formation events,
results in a high diversity of microbial habitats and, therefore, microbial communities
(Karl, 1993). Extreme environments are proving
to be a valuable source of microorganisms that secrete interesting novel molecules,
including enzymes, lipids, exopolysaccharides, and other active substances. The enzymes
produced by psychrophilic and psychrotrophic microorganisms with unique physiological
and biochemical characteristics have significant advantages in some areas in comparison
to the enzymes from mesophiles (Chintalapati ; Garcia-Viloca
; Georlette et al., 2013).
These cold-adapted enzymes are important biocatalysts for various industrial
applications due to their high catalytic activity at low temperatures and low
thermostability (D’Amico ; Siddiqui and Cavicchioli, 2006).
Until recently, agarases produced by Antarctic microorganisms were an unknown entity. In
this paper, a new exo-β-agarase Aga21 from an Antarctic psychrophilic strain was
isolated and identified as Pseudoalteromonas sp. After the enzyme was
purified, its characteristics in terms of enzyme activity were analyzed under different
temperature and pH conditions. This study is the first to report on a cold-adapted
agarase derived from the Antarctic psychrophilic strain.
Materials and Methods
Isolation and identification of agarase-producing bacterial strain
The agarase-producing psychrophilic strain was isolated from sediments collected from
Antarctic Prydz bay (75°45.9′E; 68°5.65′S). The strain was inoculated on a 2216E
medium containing 0.5% (w/v) peptone, 0.1% (w/v) yeast extract and 2.0% (w/v) agar,
and incubated at 10 °C. After being cultured for 24 h on 2216E, the strain was
inoculated on selection plates containing agar as the sole source of energy and
carbon; positive colonies showing clear zones or pits were selected.The chromosomal DNA of the agarase-producing strain was extracted using the DNA
Extraction Kit (TianGen, Biotech CO., LTD., Beijing, China). Using the chromosomal
DNA as the template, the 16S rRNA was PCR amplified with primers 27F and 1492R, and
the PCR products were sequenced by Shanghai Sunny Biotechnology Co, Ltd.
Purification of agarase
To isolate agarase, the agarase-producing strain was grown in 500 mL vials containing
300 mL of the 2216E liquid medium supplemented with 0.3% agarose and incubated at 10
°C. The culture supernatant separated from bacteria grown for 56 h were obtained via
centrifugation at 6000 × g for 10 min at 4 °C. Solid ammonium sulfate was added to
the crude enzyme solution to 70% saturation with slow stirring for 1 h. The
precipitate was dissolved in sodium phosphate buffer (pH 6.5) and dialyzed against
1000 mL of the same buffer overnight with intermittent change of buffer every 4 h.
The dialyzed sample was concentrated with a polyethylene glycol 20,000 solution.The crude enzyme solution was filtered through a 0.45 μm filter membrane to remove
any undissolved substances. The concentrated crude enzyme solution was then applied
onto a Q-Sepharose F.F. column (2.6 × 40 cm) equilibrated with sodium phosphate
buffer (pH 6.5). The column was washed with 50 mL of the same buffer to remove the
unbound proteins. The enzyme was eluted in 1.5 mL fractions by a discontinuous
gradient of NaCl (0–0.5 M) in the same buffer. The fractions with the highest enzyme
activities were pooled and further purified via gel filtration on a Sephacryl S-200
column using the same buffer. The active fractions were analyzed for protein content
by reading the absorbance at 280 nm and stored at 4 °C until further use. Sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was carried out to
estimate the protein molecular weight with a stacking gel (4% polyacrylamide) and a
separating gel (10% polyacrylamide).
Agarase enzyme assay
The specific activity of the purified Aga21 was determined according to a modified
method developed by Ohta . Appropriately diluted enzyme solution was added to different
substrates in Tris-HCl (pH 8.0) and incubated at 40 °C for 30 min. The activity was
expressed as the initial rate of agar hydrolysis by measuring the release of reducing
ends using the 3,5-dinitrosalicylic acid (DNS) procedure with D-galactose as the
standard (Miller, 1959). One unit of enzyme
activity was defined as the amount of enzyme that can catalyze the production of 1
μmol of reducing sugar (in the present study, D-galactose) per minute.
Effect of pH, temperature, and additives
In each experiment, 1.0% agar solution and purified agarase were mixed and incubated
at various durations and temperatures. The relative agarase activity was determined
using the DNS method. The optimum temperature of Aga21 activity was determined by
monitoring the relative enzymatic activity at temperatures ranging from 10 °C to 60
°C at pH 8.0. The optimum pH was tested at a pH range of 3.5–10.0 with pH intervals
of 0.5 at 40 °C. HAc-NaAc buffer, KH2PO4-NaOH buffer, Tris-HCl
buffer, and NaCO3-NaHCO3 buffer were used to achieve pH
3.5–6.0, pH 6.0–7.0, pH 7.0–9.0, and pH 9.0–10.0, respectively. The thermostability
of Aga21 was evaluated by measuring the residual activity of the enzyme after
incubation at a temperature range of 10–50 °C for 30, 60, and 180 min. The effects of
various metal ion salts and chelator on the purified Aga21 activity were tested by
determining the enzyme activity in the presence of various ions or chelator
(CaCl2, CuSO4, FeSO4, KCl, MgSO4,
MnCl2, NaCl, and EDTA) at a final concentration of 2 mmol/L, incubated
at 40 °C for 30 min. The assay mixture without the addition of metal ion salts or
chelator was used as the control.
Identification of Aga21-hydrolyzed agar products
Thin layer chromatography (TLC) was used to identify the hydrolysis products of agar.
Neoagarodecaose (NA10), neoagarooctaose (NA8), neoagarotetraose (NA4), and
neoagarobiose (NA2) were purchased from Sigma. The reaction of purified Aga21 and
agar was carried out in 100-mL tubes containing 10 mL of purified Aga21 (24 units/mL)
and 90 mL of 1.0% agar at 40 °C for 30, 60, and 120 min. Subsequently, the reaction
mixtures were applied to a silica gel 60 TLC plate (Merck, Germany). The TLC plates
were developed using a solvent system consisting of n-butanol, acetic acid, and water
(2:1:1, v/v). After hydrolysis of the substrates, the resultant oligosaccharide spots
were visualized by spraying 10% H2SO4 on the TLC plate and then
heating it on a hot plate.
Carbon-13 nuclear magnetic resonance spectroscopy
After enzymatic hydrolysis, the oligomers were precipitated with iso-propanol and
dried at room temperature. The dried material was dissolved in D2O for
13C NMR spectroscopy. The NMR spectrum was recorded on Varian Inova 600
at room temperature.
Results
Isolation and identification of strain NJ21
Initially, the agarase-producing Antarctic psychrophilic strain was isolated from the
selection plates showing a clear hydrolysis pit (Figure 1). The 16S rRNA sequence analysis results showed that the isolated
bacterium from the sediment samples was 99% similar to
Pseudoalteromonas sp. And, hence, was assigned to the genus
Pseudoalteromonas and named Pseudoalteromonas
sp. NJ21 (GenBank accession number: KF700697). The pure strains are conserved in the
key Laboratory of Marine Bio-active Substances SOA.
Figure 1
Colonies of Pseudoalteromonas sp. NJ21 on an agar plate
showing deep pits around them
Separation and purification of Aga21
The Aga21 was purified via ammonium sulfate fractionation followed by a combination
of two chromatographic steps (Figure 2). The
Aga21 was purified 47.78-fold with a specific activity of 373.62 U/mg and a final
yield of 10.68% (Table 1). SDS-PAGE revealed
the presence of a single protein band with agarase activity, whose apparent molecular
weight was estimated to be 80 kDa (Figure
3).
Figure 2
Purification via anionic exchange chromatography (A) and gel chromatography
(B) of the Aga21
Table 1
Summary of the purification of Aga21
Steps
Total activity
(U)
Total protein
(mg)
Specific activity
(U/mg)
Purification
(fold)
Recovery (%)
Culture
supernatant
2865
366.25
7.82
1
100
(NH4)2SO4precipitation
426.73
285
32.84
4.19
14.89
Q-Sepharose F.F
305.91
1.74
175.93
22.49
10.68
Sephacryl S-200HR
211.84
0.57
373.62
47.78
7.40
Figure 3
Electrogram of SDS-PAGE of the purified Aga21
Influence of pH and temperature on enzyme activity and stability
Although the optimum reaction temperature of the purified Aga21 was 30 °C (Figure 4A), as much as 85% of the maximum activity
was observed at 10 °C. The effect of pH on the purified enzyme is shown in Figure 4B. The maximum enzyme activity was
observed at pH 8.0, and the enzyme was stable (> 70% relative activity) in buffers
with a pH range of 6.5–8.5 under the assay conditions. The temperature dependence of
the Aga21 activity on agar was determined by measuring the enzyme activity at various
temperatures for 180 min. The effect of temperature on the stability of Aga21 is
shown in Figure 4C. Up to 80% thermostability
of Aga21 was retained at 10 °C and 30 °C for 180 min. However, when the temperature
was increased to 50 °C for 30 min, the enzyme relative activity was decreased to
10–20%. Nevertheless, the enzyme was fairly stable (almost 70% relative activity) at
40 °C for 30 min.
Figure 4
Biochemical characterization of pure Aga21 describing the effect of (A)
temperature, (B) pH, (C) thermostability and (D) various additives. Note: the
definition of relative activity of figures A, B and C were as follow: The
maximum enzyme activity was defined as 100%, the relative activity = the actual
enzyme activity/the maximum enzyme activity × 100%. The definition of relative
activity of figure D was as follow: The enzyme activity of control group (no
additive) was defined as 100%, the relative activity = the treatment group
enzyme activity/the control group enzyme activity × 100%
Effect of various additives
The effect of metal ion salts and chelators on the activity of purified Aga21 is
shown in Figure 4D. Divalentmetal salts such
as CuSO4, CdCl2, FeSO4, and CaCl2 (each
at 2 mM final concentration) completely inhibited the relative activity of Aga21,
whereas 2 mM EDTA inhibited 60% of the enzyme activity. In contrast, 2 mM KCl,
MnCl2, and MgSO4 enhanced the activity of Aga21 compared to
the other metal ion salts.
Identification of the hydrolysis products of Aga21
The hydrolysis patterns of the purified Aga21 against food-grade agar are shown in
Figure 5. The agarooligosaccharides, which
were purchased by Sigma, were also run along with the agarose hydrolyzed products by
Aga21 on TLC. None of the agar hydrolysis products produced by the purified Aga21
matched the Rf values of agarooligosaccharides (data not shown), whereas
the Rf values did match with the standard neoagarooligosaccharides. When
Aga21 was incubated with agar, only one distinct spot, NA2, was observed on the TLC
plates at 30, 60, and 120 min after the reaction.
Figure 5
Thin-layer chromatogram of the hydrolysis products of purified Aga21
reaction NA2, neoagarobiose; NA4, neoagarotetraose; NA8, neoagarooctaose; NA10,
neoagarodecaose
Further, the predicted molecular mass of deprotonated disaccharide showed a peak at
347.3 [M+Na]+ after LC-MS analysis (Figure
6A). The MW of 324.3 Da corresponds to the disaccharide unit neoagarobiose
(C12H20O10) with formula weight of 324.28
indicative of the β-cleavage. The β-cleavage of agar was further confirmed with
13C NMR spectroscopy. The NMR result showed typical resonance signals
at 102 and 98 ppm, which matched the reducing end of neoagarobiose (Figure 6B).
Figure 6
Analysis of agar hydrolyzed products based upon LC- mass spectroscopy (A)
and 13C NMR spectroscopy (B)
Discussion
An increasing number of research programs are being sponsored to examine the enzymes
produced by microorganisms isolated from Antarctica, some of which may have commercial
potential. Examples of the enzymes identified from these studies include α-amylase (used
in bread-making, textiles, brewing, and detergents), cellulase (used in textiles and
pulp and paper industries), β-galactosidase (which eliminates lactose from milk), lipase
(used in detergents and flavorings), proteases (used in detergents and for tenderizing
meat), and xylanase (used in bread-making) (Gerday
). However, to date, studies of agarases from
Antarctic microorganisms have not yet been reported. In the present study, a newly found
agarase-producing Antarctic psychrophilic bacterial isolate was assigned to the genus
Pseudoalteromonas based on the 16S rDNA sequence analysis. Earlier,
mesophilic agarolytic microorganisms were discovered in marine habitats, where marine
red algae could be the source of agar as a substrate for them. However, the data
demonstrate that agarolytic prokaryotes can also live when a polysaccharide of
cyanobacteria forming cyanobacterial mats (Namsaraev
) is the substrate for agarase. Because there
are many cyanobacteria in the Antarctic Ocean, the polysaccharide of cyanobacteria may
be the substrate for agarolytic Antarctic bacteria.The reported molecular weight of agarase varies from values as low as 12 kDa (Khambhaty ), in the
case of B. megaterium, to as high as 210 kDa, in the case of
Pseudomonas-like bacteria (Malmqvist, 1978). β-agarases are classified into three groups by their
molecular weights: Group I (20–49 kDa), Group II (50–80 kDa), and Group III (> 60
kDa) (Leon ). The
result of SDS-PAGE of purified Aga21 revealed a molecular mass of 80 kDa and may belong
to group III β-agarases.Temperature and pH are considered to be decisive parameters for enzyme activity. It was
observed that the activity of Aga21 consistently increased from 10 to 40 °C, with
optimum activity at 30 °C. However, a drastic decrease was observed when the Aga21 was
incubated at temperatures above 40 °C. The activity of Aga21 was stable at a low
temperature and retained more than 85% of its activity at a temperature of 10–30 °C,
which is lower than many other agarases (Kirimura
; Ohta
; Vander
Meulen and Harder, 1975). Temperature optima of various agarases are higher
than the gelling temperature of agar because compact bundles of gelled agar hinder
enzyme action (Jonnadula and Ghadi, 2011; Ohta ; Suzuki ; Vander Meulen and Harder, 1975). However, the agarase Aga21
can efficiently liquefy solid agar at a temperature of 10 °C. When compared with the
other agarases, the Aga21 had a comparatively lower optimum temperature and very low
temperature tolerance as a cold-adapted enzyme. This unique characteristic may be useful
for preparing protoplasts and extracting biological substances from algae at low
temperatures. The enzyme exhibited the maximum agarase activity at pH 8.0, whereas the
optimum pH for many other agarases is 7.0 (Jonnadula and
Ghadi, 2011; Long ; Shi ). Other agarases active in alkaline pH have been reported (Fu and Kim, 2010). Aga21 was stable in a wide pH range of
6.5–8.5, retaining more than 70% of its residual activity, which was similar to those of
some other agarases such as AgaY (6.0–8.0) (Shi
) and that from Bacillus sp.
MK03 (7.1–8.2) (Suzuki ). As observed with other β-agarases, KCl, MgSO4, and
MnCl2 acted positively on the activity of the Aga21, which is consistent
with the fact that V134, the source strain of AgaV, is a marine inhabitant. However,
CaCl2 exhibited no apparent effect on the activity of the enzyme at 2 mM
concentrations, which is in contrast to the observations of the β-agarase AgaO and AgaB
of the Pseudoalteromonas sp. reported by Ohta and Ma , who found that
CaCl2stabilizes the activity of AgaO and enhances the activity of AgaB.
Similar to other agarases, the activity of the agarase identified in the present study
was strongly inhibited by EDTA and several reagents, particularly, heavy metal ions.The β-agarases are known for their endo- and exolytic cleavage producing neoagarobiose
and other intermediate products such as neoagarotetrose and neoagarohexose (Fu ). The β-agarase
from Alteromonas sp. (Wang ) and the agarase Ag50D from S.
degradans have exolytic cleavage modes that mainly produce the neoagarobiose (Kim ). The agarase
enzyme investigated in this study also yielded neoagarobiose as a major product
indicating the exolytic cleavage of agar. 13C NMR analysis of
oligosaccharides deduced that the agarase produced 3, 6-anhydrogalactose as the
non-reducing end and galactose as the reducing end. This was also confirmed with LC-MS
analysis. The abovementioned findings provide evidence that the enzyme investigated in
this study is a β-agarase with exolytic cleavage of agar.There are few bacteria (Aoki ; Kong ; Sugano ; Araki ) that are capable of producing β-agarases and can hydrolyze agarose and
neoagaro-oligosaccharides to yield neoagarobiose. Neoagarobiose produces both
moisturizing and whitening effects on skin (Kobayashi
), and the agarase-degraded extract from a red
seaweed, Gracilaria verrucosa, has been reported to increase the
phagocytic activity of mice (Yoshizawa ). Hence, the oligosaccharide extracts from agar or
seaweeds hydrolyzed by the newly cold-adapted Aga21 may be a useful source to obtain
physiologically functional products with antioxidative or immunopotentiating
activities.
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6