dc.description.abstract |
Present study was conducted for the production, characterization and utilization of
oxyrase from E. coli as part of its cytoplasmic membrane fragments. This enzyme system
is known for its antioxidant potential to reduce dissolved oxygen from medium and
generating microanaerboic conditions thereof. For this purpose, 30 intact poultry
intestinal samples were collected from thirty sites/butcher shops located in Ichhra,
Anarkali and Rehmanpura, Lahore. Total 88 strains of E. coli were isolated from these
samples which were preliminary identified microscopically and by biochemical profiling.
Downstreaming of membrane fragments was initially performed with buffer-mediated
sonicated lysis of E. coli cells and purification of membrane fragments from cell debris
by centrifugation and sterilization by membrane filtration (pore size 0.45μm). Qualitative
methylene blue reduction assay and quantitative dissolved oxygen probe meter were
employed for screening of best E. coli isolate for active oxyrase. Seventy six isolates of
E. coli were found to contain active oxyrase in membrane fragments. E. coli oxyrase
strain-4 (EC4) was found the best for its potential to reduce dissolved oxygen with
maximum oxyrase activity of 0.41±0.008U/mL/min with 41% reduction in dissolved
oxygen at pH 7.5, Temperature 37°C, 25mM lactate as H+ donor after 20 minutes.
Molecular confirmation of EC4 was done by ribotyping of 16S rRNA conserved region
using Universal Primers 27F and 1492R. Evolutionary relation drawn by using Molecular
Evolutionary Genetics Analysis (MEGA) 6.0 tool confirmed Oxyrase producing isolate
EC4 as E. coli. Growth optimization studies revealed maximum EC4 growth with cell
density 2.78±0.04 in modified RF medium (pH 7.5) with 1.5% glucose as carbon and
0.2% NH4(SO4)2 as nitrogen source after 8 h of incubation at 37°C with agitation rate of
225rpm when 8 h old 4% (v/v) inoculum was used. Effect of H+ donor/substrate and its
various concentrations at different time intervals was evaluated on the oxygen reduction
activity of membrane fractions. Lactate (25mM) was best substrate which showed
maximum Oxyrase activity of 0.40±0.07 U/mL/min with 40.4±1.22% reduction in
dissolved oxygen after 20 minutes of incubation. Oxyrase worked best at pH 8.5 with
maximum 45% reduction in dissolved oxygen and activity 0.45±0.08 U/mL/min was
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observed. Moderate thermophilic nature of oxyrase was revealed because temperature
profiling of enzyme showed maximum activity of 0.65±0.09 U/mL/min at 57°C.
Modification in downstreaming strategy for extraction of oxyrase from E. coli was
adopted by using Avestin Emulsiflex-C3® resulted in drastic improvement in oxygen
reduction activity. Chromatographic analysis using Q-Sepharose® Fast Flow anion
exchange column of Emulsiflex mediated oxyrase membrane preparation showed
significant ~45 kDa bands using Sodium Dodecyl Sulphate Poly Acrylamide Gel
Electrophoresis profile. This preparation of eluted fractions with 65% buffer comprised
50 mM Tris pH 8.0 + 1.0 M NaCl. These membrane fractions caused complete reduction
in blue colour of methylene blue within 1 minute. Avestin Emulsiflex-C3® mediated
membrane fractions showed 100% reduction in dissolved oxygen at 57°C in presence of
25 mM lactate as H+ donor using pH 8.5 after 1.5 minutes with activity 13.3±0.19
U/mL/min and specific activity of 8.0 U/mg. Kinetic parameters derived from double
reciprocal Lineweaver-Burk plot showed Km values 8.49×10-3 M-1 and 4.75×10-3 M-1 of
sonication and Emulsiflex prepared oxyrase membrane fragments respectively for lactate
as substrate. Enhanced activity of Emulsiflex membrane fragments to reduce dissolve
oxygen is because of 55 folds improvement in affinity of oxyrase enzyme for substrate as
compared to sonication prepared membrane fragments. E. coli NADH Dehydrogenase-II
(EC NDH-II), one of the ubiquinone reductase in cell’s membrane was cloned and
expressed with Histidine tags using pMA507 vector due to its relevance in oxyrase
activity. Nickel chelating ligand nitrilotriacetic acid (NiNTA) column chromatography
was employed for purification and extraction of His-tagged fusion protein with
Lauryldimethylamine oxide, Triton X-100 (TrinX-100) and Tween-20 detergents. TrinX-
100 detergent suited best for elution of protein. Further purification of His-tagged EC
NDH-II by using BIORAD® BioLogic DuoFlow™ Liquid Chromatography System with
HiPrep Sephacryl S-200 HR size exclusion column with buffer comprised 50 mM Tris
pH 8.0 + 300 mM NaCl + 0.1% Triton X-100 demonstrated a significant band of 43 kDa.
Characterization of purified EC NDH-II was performed; maximum activity of 46±1.1
U/mL was obtained at standard assay conditions when 225 μM NADH was used as
substrate. Determination of kinetic parameters showed inhibitory effect of EDTA and
Mg+2 with different concentrations; highest Vmax/Km (8.35×105) was observed when
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dehydrogenase activity was characterized in the absence of inhibitory agents, with Kcat
value of 1.2×1019 s-1. Antioxidant potential of Oxyrase in Emulsiflex prepared membrane
fractions can be utilized in variety of industrial applications. In present study, efficacy of
oxyrase was evaluated for improved cultivation of anaerobic bacteria. Antioxidant
potential of oxyrase was compared with common reducing agent Cysteine-HCl (Cys-
HCl) using Hungate Technique. Four anaerobic bacterial strains (Anaerobaculum
hydrogeniformans OS1, Akkermansia muciniphila, Bilophila wadsworthia, and
Roseburia intestinalis) were selected as experimental models for this purpose. Significant
improvement in cell density of Anaerobaculum hydrogeniformans culture with maximum
OD600nm of 0.80±0.0017 reached after 4 days of incubation when oxyrase used as
reducing agent, and maximum OD600nm 0.65±0.0016 in the presence of Cys-HCl.
Akkermansia muciniphila culture reached maximum OD600nm value of 2.1±0.07 in the
presence of oxyrase after 18 h of incubation. While with Cys-HCl, Akkermansia
muciniphila culture reached maximum cell density OD600nm of 2.0±0.05 after 27 h of
incubation. Oxygen reducing potential of oxyrase also suited the growth of Bilophila
wadsworthia because it reached maximum cell density OD600nm of 2.0±0.05 after 73 h of
incubation. Whereas, in the presence of Cys-HCl Bilophila wadsworthia cells only
achieved maximum OD600nm of 1.54±0.07 after 28 h of incubation. Cultivation studies of
Roseburia intestinalis in the presence of oxyrase also exhibited noteworthy improvement
in the yield of cell density with OD600nm of 2.1±0.06 after 25 h of incubation. With Cys-
HCl, maximum cell density of Roseburia intestinalis with 2.0±0.06 OD600nm was
observed after 73 h. |
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