Introduction
Lysosomes contain an assortment of soluble, aciddependent hydrolases and a set of highly glycosylated integral membrane proteins [5]. Lysosomes extracted from cells are morphologically heterogeneous, often resembling other organelles of the endocytic and secretory pathways. Presently, lysosomal enzymes are believed to participate in several functions: a cysteine protease, cathepsin B, or an aspartic protease, cathepsin D, are released from lysosomes into the cytosol or the nucleus [3,4,12] and act as proteolytic enzymes. Furthermore, the lysosomes isolated from egg white and Saccharomyces cerevisiae have useful functions, like antimicrobial activity to kill bacteria such as Escherichia coli, Deinococcus radiophilus, Shigella flexneri, etc. [19,20]. However, there are numerous enzymes in lysosomes, and the functional properties of each lysosomal enzyme fraction have been neither identified nor characterized [6].
Titanium (IV) oxide (TiO2) has been widely studied for a variety of applications, such as sensory devices [1,16], heterogeneous catalyst materials [18], hydrogen fuel storage materials [13], and photocatalytic devices [2]. Interest in interaction with bioavailable and nonmetal materials like TiO2 and silicon dioxide led to a range of techniques related to immobilization and adsorption using several effective enzymes [15]. Immobilization by adsorption has been used to increase the interaction force with enzymes by modifying the surface of the material [8,14] or by changing the pH [11].
Melanin pigments consist of the colors of the skin, hair, and eye. Melanin may have the biological function of protecting the underlying tissues from harmful ultraviolet radiation [10]. These pigments are typically divided into two types: the black eumelanins and the reddish-brown pheomelanins [7]. Large amounts of melanin in light skinned/freckled individuals appear to make them more susceptible to skin cancer [9].
In this study, to decrease the absorbance of melanin through treatment with lysosomal enzymes, we examined the effect of the pH condition of the dissolving solvent for lysosomal enzymes immobilized on TiO2. Here, lysosomal enzymes isolated from Hen’s egg white and S. cerevisiae were used to evaluate the activity of melanin treatment of immobilized lysosomal enzymes on TiO2. In addition, TiO2 pretreated with divalent positive ions was compared with untreated TiO2 to assess the immobilization efficiency and melanin treatment activity.
Materials and Methods
Isolation of Lysosomal Enzymes from Hen’s Egg White and S. cerevisiae
The lysosomal enzymes were extracted by removing the membranes of lysosomes, which were isolated from egg white using the cell fraction method [3]. The yolk was separated from the white component of the eggs and discarded. The white component of the Hen eggs was homogenized until the viscosity of the egg white decreased significantly. Two particulate fractions were obtained by centrifuging the homogenate successively for 5 min at 500 ×g (unbroken cells and nuclei) and 30 min at 20,000 ×g (lysosomal fraction). The remaining pellet was shaken 10 times for 10 min with lysis buffer (1% NP-40, 1 mM DTT, and 1 mM PMSF) at a ratio of 1:1 and was allowed to react on ice. The solution was centrifuged for 10 min at 15,000 rpm, and the remaining pellet was used to determine the immobilization efficiency and melanin treatment activity of the fraction.
The lysosomal enzyme from S. cerevisiae was provided by the Korea Research Institute of Bioscience and Biotechnology and was grown in YPD medium (1% yeast extract, 2% peptone, 4% glucose) at 30 ℃ in a shaking incubator at 200 rpm for 12 h. The yeast grown until the log-phase was harvested through centrifugation at 3,000 rpm for 10 min, and the supernatant was discarded. The collected pellet was mixed with Tris-SO4 buffer (containing 1 ml of 1 M DTT solution per 100 ml). After suspending the mixture, it was centrifuged at 3,000 rpm for 10 min, and the supernatant was discarded. The pellet was resuspended and recollected in 25 ml of sorbitol K+ buffer. To remove the unnecessary remainders of the cells, the samples were ultrasonicated at 40 W for 5 min (10:0 sec on/off pulses) and centrifuged at 3,000 rpm for 10 min. After collecting the cells, the supernatant was thoroughly mixed with the breaking buffer (containing 50 ml of 1 M PMSF solution per 50 ml), ultrasonicated at 30 W for 5 min (10:10 sec on/off pulses), and centrifuged at 500 rpm for 5 min. We could get lysosomes after centrifuging at 20,000 ×g for 30 min and discarding the supernatant. Finally, the extraction of lysosomal enzymes from lysosome followed the same method as the enzymes extracted from Hen`s egg white.
Preparation of Lysosomal Enzymes Immobilized on TiO2
The 8 mg of anatase (~200 nm) TiO2 particles used in this experiment was purchased from Sigma-Aldrich, and the reactions were conducted in a sodium phosphate buffer (0.1 M, pH 4, 6, and 10) for the designated reaction time. This dosage of TiO2 (8 mg) was used for the immobilization of lysosomal enzymes in this study because lower amounts of TiO2 do not have any melanin treatment activity. The TiO2 particles were treated with 0.8 mg of lysosomal enzyme and respectively, 0.1 M sodium phosphate buffer at each pH condition for 10 min. The mixture (total of 10 ml) of extracted lysosomal enzyme and TiO2 was continuously shaken on an orbital shaker (150 rpm) at room temperature; the lysosomal enzymes immobilized on TiO2 were separated by centrifugation and they were washed three times with 0.1 M sodium phosphate buffer (pH 4, 6, and 10, respectively) and maintained at 4 ℃ until used. The amount of lysosomal enzyme immobilized on TiO2 was determined by measuring the initial and final concentrations of enzymes in the mixing solution using the Bradford protein assay method (Bio-Rad, Richmond, CA, USA). In addition, to evaluate the effect of TiO2 pretreatment with monovalent and divalent positive ions, 8 mg of TiO2 was mixed at room temperature in 1 ml of 0.1 M CaCl2 and 0.1 M KCl. The TiO2 pretreated by Ca2+, K+, respectively, was mixed with the buffer before starting the immobilization test.
Melanin Treatment
Melanin (100 ppm) purchased from Sigma-Aldrich (USA) was dissolved in 1 M sodium phosphate buffer, pH 7.0. Then 100 mg amounts of immobilized lysosomal enzymes under each pH condition were used to treat the 100 ppm melanin. The residues of melanin treated by immobilized lysosomal enzymes were measured as absorbance at 450 nm, using the Multiskan Ascent (Thermo Electron Corporation, USA).
Data Analysis
All the data were obtained from three independent samples measured simultaneously for error analysis, and the results are shown with the standard deviation and the correlation with cell mortality under several experimental conditions. The data were analyzed using Sigma Plot (SPS Chicago, IL. USA).
Results and Discussion
Immobilization Efficiency of Lysosomal Enzymes on TiO2 under Different pH Conditions of Dissolving Solvents
We measured the immobilization efficiency of lysosomal enzymes immobilized on TiO2 at different pH conditions (pH 4, 6, and 10). To adapt the pH, we used sodium phosphate as a dissolving solvent. As shown in Fig. 1, the results indicated that the immobilization efficiency of immobilized lysosomal enzymes extracted from Hen`s egg white was the highest at pH 4 compared with the other pH conditions. In the same manner, it immobilized the most of those extracted from yeast at pH 4. From both results, we found that the higher the pH was increased, the more the immobilization efficiency decreased. The immobilization efficiency at different pH levels of lysosomal enzymes extracted from Hen`s egg white and S. cerevisiae showed very similar tendencies once immobilized.
Fig. 1.Immobilization efficiency under different pH conditions on TiO2 using lysosomal enzymes extracted from lysosomes isolated from Hen’s egg white and S. cerevisiae.
Effect of Melanin Treatment Using Immobilized Lysosomal Enzymes Extracted from Two Sources at Various pH Conditions for Seven Days
We examined melanin treatment using immobilized lysosomal enzymes at different pH conditions and two independent sources, in triplicate. Samples (100 µg) of immobilized lysosomal enzymes extracted from both sources under all pH conditions were used in 500 µl of 100 ppm melanin, which melts in pH 6 PBS buffer. We confirmed that the residue of melanin had a measured absorbance at 450 nm. Through the immobilized lysosomal enzymes extracted from Hen’s egg white, we found that the residues of melanin changed smoothly at all pH conditions and that total residues fell similarly at pH 4 and 6. On the other hand, those of yeast indicated that the residues changed sharply at pH 4, and total residues showed a similar trend at pH 6 and 10. The color changed the most at pH 4 compared with the residue of treated melanin from both sources under all pH conditions (Fig. 2).
Fig. 2.Effect of melanin treatment using lysosomal enzymes, extracted from (A) Hen’s egg white and (B) S. cerevisiae, immobilized on TiO2 under different pH conditions. These data correspond to the treatment efficiency relative to the melanin dissolved in phosphate buffer under each pH condition.
Enhanced Immobilization Efficiency of Lysosomal Enzymes Extracted from Hen’s Egg White on TiO2 Pretreated with Monovalent and Divalent Positive Ions under Different pH Conditions
On the basis of the pH condition and cations treatment results, in order to obtain more effective immobilization efficiency and melanin treatment, we examined to add the cations such as KCl and CaCl2 under various pH conditions. Collectively, we found that the immobilization efficiency of untreated and pretreated lysosomal enzymes under different pH conditions was highest when treated with CaCl2 at pH 4. Immobilized lysosomal enzymes on TiO2 untreated with cations showed that the more the pH condition increased, the less the immobilization efficiency decreased. However, immobilized lysosomal enzymes on TiO2 treated with KCl indicated that there was a similar tendency at pH 4 and 6, whereas efficiency was lowest of all conditions. Lastly, immobilized lysosomal enzymes on TiO2 treated with CaCl2 showed similar results as with KCl, but the acidic condition was a little higher than at neutral pH.
Fig. 3.Immobilization efficiency of lysosomal enzymes, extracted from Hen’s egg white, immobilized on TiO2 pretreated with monovalent and divalent positively charged ions under different pH conditions.
We evaluated the immobilization efficiency of lysosomal enzymes with treated cations under different pH conditions. We found that treatment with divalent ions under the lower pH increased the immobilization efficiency. Similarly, for increasing the melanin treatment, we used the immobilized lysosomal enzymes extracted from Hen`s egg white on TiO2 pretreated with a positive ion like K+ and Ca2+ under different pH conditions. Totally, we found that the melanin treatment was the highest for immobilized lysosomal enzyme pretreated with Ca2+ under pH 6 condition among all conditions. In the case of the control (untreated TiO2), the result indicated that the lower the pH was, the more melanin treatment increased. Melanin treatment was highest pretreated with K+ under pH 6 condition. However, we could not measure the melanin treatment pretreated with Ca2+ under pH 4, because the Ca2+ in the buffer returned to a solid state. We suggest that to treat melanin is good to pretreat with Ca2+ under neutral condition.
Immobilization experiments were conducted to maintain the activity of the lysosomal enzymes, which may show sensitivity to pH changes because the lysosomes are in unstable pH conditions [17]. To sustain the activity of lysosomal enzymes and adapt them in the human body, we immobilized them on TiO2, and then we performed to treat the melanin with lysosomal enzymes immobilized on TiO2 to confirm the possibility that they can adapt in the human body (Fig. 4). We suggest that lysosomal enzymes immobilized on TiO2 have a higher potential for melanin treatment in the human body.
Fig. 4.Effect of melanin treatment using lysosomal enzymes, extracted from Hen’s egg white, immobilized on TiO2 pretreated with monovalent and divalent positively charged ions under different pH conditions. This data corresponds to the treatment efficiency relative to the melanin dissolved in phosphate buffer under each pH condition.
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