Submit manuscript...
Journal of
eISSN: 2572-8466

Applied Biotechnology & Bioengineering

Research Article Volume 5 Issue 6

Hydrochloric acid pretreated agro wastes as carbon source on CM-cellulases production by Aspergillus niger

M Urs Siyal,1 M Umar Dahol,2 M Hanif Noomrio2

1Department of Biochemistry, Shah Abdul Latif University, Pakistan
2Institute of Biotechnology and Genetic Engineering, University of Sindh, Pakistan

Correspondence: Muhammad Uris, Shah Abdul Latif University, Khairpur, Pakistan

Received: October 23, 2018 | Published: December 20, 2018

Citation: Siyal MU, Dahot MU, Noomrio MH. Hydrochloric acid pretreated agro wastes as carbon source on CM-cellulases production by Aspergillus niger. J Appl Biotechnol Bioeng. 2018;5(6):369-376. DOI: 10.15406/jabb.2018.05.00167

Download PDF

Abstract

Maximum cell growth 0.936g/100ml of Aspergillus niger was observed at pH 4.11 in hydrolyzed rice husk used as carbon source. Aspergillus niger was isolated from the soil of Khairpur. The collection and utilization of suitable Agro wastes used as a carbon source for cellulases production by fungi desires optimized fermentation process. Five agricultural wastes were considered for cellulolytic enzyme production using pretreatment methods acid. Acid pretreatment was found to be the most efficient method with higher enzyme production. Using this cheap and renewable residue, for cellulolytic enzyme production by Aspergillus niger boosts its economic value which is not comparable with its current use as animal feed. Agro wastes such as sugarcane peelar bagasse, sugarcane bagasse, banana fruit stalk, sorghum husk and rice husk were hydrolyzed with 0.6N HCl. Rice husk was found better substrate in comparison to other Agro wastes for the growth of Aspergillus niger and cellulases production. Maximum activity of cellulases was noted 4.811 (units/ml). The Cellobiase and salicinase maximum production 4.717 and 4.742 units per ml obtained at 240 hours respectively.

Keywords: cellulase, cellobiase, salicinase, Aspergillus niger, agro wastes, fermentation

Introduction

Cellulase is a multi-component enzyme system that works synergistically in hydrolyzing the cellulosic substrates to glucose. Mostly three enzymes are involved; endo-β-d-glucanase (EC 3.2.1.4) which catalyzes the random hydrolysis of soluble and insoluble cellulose chains. Exo-β-d-glucanase (EC 3.2.1.19) aids in releasing cellobiose from reducing and non-reducing ends of cellulose, and hydrolysis of cellobiose to glucose is carried out by β-glucosidase (EC 3.2.1.37).1,2 Cellulases have been used in a number of industrial processes. The most notable applications are in textile, paper and pulp, food and animal feed, fuel and chemical industry, waste management, and pharmaceutical industry.3

Agricultural wastes represent vast raw materials that can be utilized for production of value-added products. The major components of these raw materials, including cellulose (35–50 %), hemicellulose (20–35 %), lignin (15–25 %) and a number of other compounds make up the residues.4 Thus, cellulose being the most abundant polysaccharide constituents of agricultural residues consists of β-1,4 linear polymers of 8000–12,000 glucose units. It is mostly found in crystalline, water-insoluble form, and cannot be easily hydrolyzed by most microorganisms.5,6 The present study was aimed at determining the best substrate from different agricultural wastes as well as the pretreatment method for cellulolytic enzyme production using A. niger. This is because among the cellulase producing microorganisms, A. niger has been reported to be efficient in the synthesis of all the three cellulolytic enzymes.2 The information obtained in this study would be helpful in developing a cost-effective process for cellulase production. Main objective of this study is to utilize Agro wastes instead of pure sugars for cellulases production.

Sources of cellulases

Cellulases are produced by various sources for instance fungi, bacteria, yeast and plants. Seasonal fluctuation hampered a lot in the production of cellulases from plants. Higher amount of cellulases are actually produced by microorganisms. Microbial cellulases production can be enhanced several times by genetic and environmental manipulation of microorganisms such as bacteria yeast, and fungi and thus market demand of cellulases might be accomplished by indigenous means.

The genus Trichoderma, which is a filamentous ascomycetes are widely used in industries since it is the best cellulase producing strain. Biosynthesis of cellulase was achieved by T. reesei QM 9414 using cellulose as carbon source. The production was carried out using the culture of T. reesei Rut C-30 and T. reesei NG-14. The maximum growth of T. reseei C5 and the production of cellulase enzyme were obtained using lactose as carbon source. Related studies on the production of cellulase using Agro wastes were done using Aspergillus niger and T. reesei. This complex converts crystalline, amorphous, and chemically derived celluloses to glucose.

Application of cellulases

Utilization of cellulolytic enzymes is a subject of extreme interest in the global examining for renewable resources. Fundamental information is still required to design effective industrial technique. Industrial process could be one, which indicates to production of fuel, chemicals and feed stocks. Currently growing price of oil demands rising efficiency of cellulase production and utilization. As time will approach when digestion of cellulosic waste material will turn more competitive. These cellulases will be used to increase digestibility and nutritive value of coconut and carrot by attacking the cell wall. Cellulases could also be incorporated in the preparation for quick digestion in sewage tanks thus solving the pollution problems. Many fungi and bacteria are producing cellulolytic enzymes but cellulolytc enzymes produced by Aspergillus sp. have a noble industrial use. Some common application of cellulases are given as under.

Cellulases are used to improve texture and palatability of poor quality vegetables. Cellulases are also used for accelerating drying of vegetables. The potential applications of cellulases are the conversion of cellulosic material to glucose. The cellulases produced by microorganisms have a great significance because of these enzymes can be used in deterioration of wood and textiles. These are also successfully used to hydrolyze cellulosic waste to fermentable sugars and these sugars are preferably utilized for the cultivation of microorganisms and synthesis of enzymes, single cell protein etc.

  1. Cellulases treated wastes are used as feed additives.
  2. Cellulases are also used as an extraction and clarification agent for protein isolation from soybeans and processing of fruit juice.
  3. 1-3-b-D-Glucan has been used clinically as immunodulating anticancer drug.
  4. Alkaline CM-cellulase produced from bacteria are also used to improve the efficiency of laundry detergents.
  5. Cellulase is used for commercial food processing in coffee. It performs hydrolysis of cellulose during drying of beans.
  6. Furthermore, cellulases are widely used in textile industry.
  7. Cellulases are used in the pulp and paper industry for various purposes.
  8. Cellulases are mostly used for pharmaceutical applications.
  9. Moreover Cellulase is used in the fermentation of biomass into biofuels, although this process is relatively successful in few sugarcane industries in Pakistan.
  10. Cellulase is used as a treatment for Phytobezoars, a form of cellulose bezoar found in the human stomach.
  11. Cellulase digest fiber it help remedy digestive such as malabsorption.
  12. Cellulase help in the break down of plant cell walls cellulose to increase over all efficiency of binding excess cholesterol and cell toxins in the intestine for removal.
  13. Cellulase is beneficial for food and environmental allergies.
  14. Cellulase play important role in drug withdrawal, few examples are cell detox, colon, cleaning and pain syndromes candida yeast infection, gas, bloting accute food allergies, fascial pain or paralysis.
  15. Cellulase is used in animal health care as a feed supplement for the better feed conversion ratio FCR and milk yield enhancer in cattle industry.

Aims and objectives of research

To explore new and low cost source of industrial substrate by the use of agricultural and industrial sugarcane wastes in the production of industrially important enzymes such as cellulases, and the cellulases are getting various applications in different fields. In Pakistan with calculated resources and variegated economical constrain, the import of cellulases and other enzymes from abroad costs formidably higher amount worth million of rupees each year. It is matter of fact that Pakistan is marked by an agro based economy can be ideal place for Production of industrially important enzymes by microorganisms through fermentation process using agricultural wastes as a substrate. By locally isolated fungi as an indigenous microorganisms has been carried out so far and valuable production of cellulases.

The fundamental aim and main purpose of this research work was to utilize low cost medium to reduce the production cost of cellulases for industrial use and reduce the causes of pollution by utilizing the agro wastes and industrial waste material as a source of energy.

The expensive and synthetic medium can be replaced with agricultural or industrial waste. Biosynthesis of cellulases from agricultural waste is under going research in many laboratories of the world.

However, microbial sources are the most preferred source of cellulases production especially from fungi because of their short span of their luxuriant growth period and higher amount of secretion enzyme in the minimum time.

Materials and methods

Microorganisms: The Aspergillus niger was isolated from Soil of Khairpur District and it was identified in the High Technology Research Laboratory, Shah Abdul Latif University Khairpur. The stock culture was maintained on Czepaks agar. The sterilized slants were inoculated with Aspergillus niger. After inoculation the slants were incubated at 27°C to obtain luxuriant growth.

Isolation of microorganisms from soil: The soil is composed with mineral matter, water, air and organic matter. Cellulolytic microorganisms are common in the field soil and forest soils. The isolation and maintenance of pure culture of cellulolytic microbes was done from soil sampling as reported by Alexander.

Cultural methods for soil microorganisms: Soil is an ecosystem that contains a variety of microbial population bacteria and fungi. Fungi are chemoorganotroph and use organic compound as a source of carbon and energy. The microbial community in soil is important because of its relationship to soil fertility and biogeochemical cycling of elements and potential use of specific industrial applications. Enumeration of soil microorganisms may be accomplished by the plate count technique, Most Probable Number MPN technique and spread plate count.7

Isolation of fungi from the soil sample: The isolation of fungi from the soil sample was done by the Dilution Plate Technique.7 One gram of the soil was added into 9 ml of sterilized distilled water to make the 1:10 dilution and shaked for one hour. Then a series of 1:50, 1:100, 1:1000 dilution were prepared. One ml of each dilution was inoculated on the surface of three replicates of Czepaks Dox agar in petri dishes. Inoculated petri dishes were incubated at 29°C for seven days. After incubation the grown colonies were counted and separated. Identification was made as reported by James. All fungal cultures isolated during investigation were maintained on Czepaks Dox agar medium at 25°C.

Chemicals: Carboxymethyl cellulose CMC Salicin and cellobiose were purchased from BDH, Sodium Potassium tartrate from E Merck and 3, 5- dinitrosalicylic acid was supplied by Sigma Chemicals. Other reagents used were of analytical grade.

Culture medium: The following ingredients were used for the preparation of culture medium as reported by (Burrel, 1966) without changing the chemical composition using G/L of (NH4) SO4 2 .5 g/L; fumaric acid 2 .0 g/L; KH2 PO4 1.0 g/L; Mg SO4 .7H20; 0 .5 g/L; (NH4)2 Fe (SO4)2. 12H2O; 0.2mg/L: ZnSO4 7H20 0.2 mg/L; MnSO4, 5H2, 0.1mg/L and thiamine hydrochloride 0.1 mg/L. The pH of the culture medium was adjusted to 6.0.8

Preparation of spore suspension: To stock culture Aspergillus niger, 10.0 ml of sterilized water was added and the surface was gently rubbed with sterilized wire loop. The spore suspension was further diluted to 100 ml with sterilized water.9

Hydrolysis of agriculture wastes: 10.0 g of each agricultural wastes such as sugarcane peelar bagasse, sugarcane bagasse, banana fruit stalk, sorghum husk and rice husk were hydrolyzed with 800 ml of 0.6N HCl for two hours on flame, maintaining the level of slurry constant. The digested slurry was autoclaved for 30 minutes at 1.5kg/cm2. The slurry was filtered through whatman No.1 filter paper after cooling at room temperature. The filtrate of solubilized agricultural waste was incorporated into mineral medium as a carbon source. The loss in weight of agricultural waste was determined after drying at 105°C to constant weight.10

 Cultivation condition: 50ml of solubilized agricultural waste incorporated with mineral medium was taken in 250 ml conical flasks plugged with cotton wool and autoclaved at 1.5kg/cm2 for 20 minute. The sterilized media cooled at room temperature, inoculated with 1.0 ml of Aspergillus nigerspores. The flasks were incubated in cooled orbital shaking incubator at 28±2°C adjusted at 200 revolutionary per minute. The culture broth was separated from mycelia after an interval of 24 hours incubation period by filtration through whatman No.1 filter paper. The enzyme activities of CM–cellulase, b-glucosidase and salicinase were examined in the culture broth. The mycelium was dried at 105°C in an oven to constant weight.

 Assay of CM- cellulase activity: CM-cellulase activity was determined as reported method by Mandels.11 1.0 ml of enzyme sample (culture broth) was mixed with 1.0 ml of 1% CM – cellulose and 2. 0 ml of sodium acetate buffer pH 4.6. The reaction was carried out at 35°C for one hour. Reducing sugar released was estimated by the dinitrosalicylic acid method CM-cellulase activity is calculated from Glucose standard.One unit of CM–cellulase activity is defined as the amount of the enzyme that liberate one mg/ml of reducing sugar as glucose from CM cellulose under the assay conditions.

Assay of b-glucosidase (cellobiase and salicinase) activity: b- glucosidase and salicinase activities were determined by the method of12 1.0 ml of enzyme sample (culture broth) was mixed with 1.0 ml of 1% cellobiose (for cellobioase) or Salicin (for Salicinase) and 2.0ml of Sodium acetate buffer pH 4.6.The reaction was carried out at 35°C for One hour. The reducing sugars produced were estimated by dinitrosalicylic acid method with glucose as a standard. One unit of Cellobiase and Salicinase activities are defined as the amount of the enzyme that liberate one mg/ml of reducing sugar as glucose from cellobiose or salicin under the standard assay condition.

Determination of reducing sugars: The concentration of reducing sugars in the hydrolysate of Agro wastes and culture broth was determined by dinitrosalicylic acid (DNS) method13 and results were calculated from glucose as a standard.

 Determination of protein: The protein content of culture broth was determined by method and the results were calculated from bovine serum albumin as a standard.

 Determination of total carbohydrate: The concentration of carbohydrate in the agricultural wastes hydrolysate and culture broth was measured by phenolsulphuric acid method by Montgomery and the results were calculated from standard curve of glucose.

Statistical analysis

The data is presented as mean±SD. Analysis of the data was done by one- way ANOVA.

Results and discussion

The production of cellulases by fermentation has been thoroughly investigated and it is affected by a variety of physiochemical factors. Collection as well as utilization of suitable Agro wastes as a carbon source for cellulase production Aspergillus niger optimized fermentation process. Agro wastes such as sugarcane peelar bagasse, sugarcane bagasse, banana fruit stalk, sorghum husk and rice husk contains variable ingredients. These Agro wastes materials are to a certain extent changeable from source to source not in cellulose, hemicellulose and lignin content, but also in other ingredients such as mineral matter ash, nitrogen and lipid. By way of a result each natural substrate would be predicted to have unique set up of procedure conditions optimized for glucose production as well as minimized secondary product contamination. So as to minimize, lignocellulosic waste commonly has to be hydrolyzed before utilized as a substrate or commonly called as media for the growth of microorganism for desired product. Many techniques are available for hydrolysis for example physical grinding to fine powder by ball milling, attritor milling and two roll compression milling, chemical acid and base and enzymatic cellulase, cellobiase and salicinase. It is proposed by various workers that hydrolysis of cellulosic wastes by enzymatic treatment possess several advantages however major hindrance is its high rate for application by Wika. By using acid treatment technique hemicellulose and cellulose are hydrolyzed to certain level increasing pentose and hexoses.

Furthermore, dilute acids are utilized to degrade hemicellulose, cellulose and other non-crystalline polymer to simple sugars such as glucose. Chemical pretreatment technique is less expensive and highly effective. Attempts were made in this study to hydrolyze Agro waste to fermentable sugars by chemical acid technique and findings are presented in Table 1. It is quite evident from this table that sugarcane bagasse solubilized more with 0.6N HCL. Total sugar mentions to all sugars dissolved in liquid and it is determined through converting all sugars to monomers. Reducing sugar refers for all sugar moieties with a free reducing end group. Ratio of total sugar or reducing sugar reveals average degree of polymerization DP of sugar moieties in solution. An acid hydrolysates of Agro-wastes were supplemented with mineral medium for the growth of Aspergillus niger and cellulolytic enzymes production

Parameters

Sugarcanepeelar bagasse

Sugarcane bagasse

Banana fruit stalk

Sorghum husk

Rice husk

Initial weight of sample grams

10.00

10.00

10.00

10.00

10.00

Final weight of sample grams after hydrolysis

7.12

6.34

8.61

7.80

8.55

Loss of weight grams

2.88

3.66

1.39

2.20

1.45

% of hydrolysis

28.8

36.6

13.9

22.0

14.5

Total protein mg/ml soluble filtrate

2.41

2.31

2.22

2.14

2.17

Total carbohydrate mg/ml soluble filtrate

3.22

3.31

3.16

3.11

3.12

Reducingsugar mg/mlsoluble filtrate

2.11

2.55

2.12

2.14

2.91

Table 1 Effect of 0.6N HCl on hydrolysis of agricultural wastes and the yield of percentage of hydrolysis total protein, total Carbohydrate and reducing sugar

Tables 2 & 3 showed the growth pattern and cellulolytic enzyme synthesis by Aspergillus niger, grown on 0.6N HCL pretreated sugarcane peelar bagasse and industrial sugarcane bagasse. It is observed from the Tables 2 & 3 that the greater amount of CM-Cellulase, cellobiase and salicinase were produced by Aspergillus niger in case of sugarcane peelar bagasse at 240 hours respectively. It was 0.943, 1.488 and 1.906 units/ml. while in case of sugarcane bagasse, the time period was noted at 240 hours respectively. It was noted maximum yield of cellulases was 240 hours it was 0.219, 1.922 and 0.498 units/ml.

Time Period Hours

Final pH

Weight of mycelia g/100ml

Total sugar mg/ml

Reducing Sugar mg/ml

Total Protein mg/ml

Enzyme activity units/ml

            

 

 

 

C1

C2

C3

24

5.22

0.056

490

426

628

0.159

1.045

0.317

 

 

 

±1.455

±0.883

±0.578

±0.001

±0.001

±0.001

48

5.41

0.081

462

374

566

0.325

1.082

0.817

 

 

 

±1.734

±1.156

±0.883

±0.002

±0.002

±0.002

72

5.55

0.097

385

341

535

0.476

1.222

1.053

 

 

 

±1.203

±1.456

±1.203

±0.003

±0.003

±0.004

96

6.31

0.108

378

314

473

0.823

1.253

1.669

 

 

 

±1.766

±1.766

±1.529

±0.004

±0.007

±0.001

120

6.48

0.121

372

270

418

0.872

1.284

1.707

 

 

 

±2.030

±2.030

±1.858

±0.005

±0.004

±0.002

144

6.87

0.125

347

242

392

0.901

1.299

1.765

 

 

 

±2.336

±2.084

±2.188

±0.006

±0.006

±0.003

168

7.11

0.133

311

230

360

0.915

1.318

1.802

 

 

 

±2.607

±1.203

±2.520

±0.008

±0.009

±0.004

192

7.14

0.145

300

195

345

0.918

1.367

1.871

 

 

 

±0.883

±1.734

±2.851

±0.007

±0.008

±0.005

216

7.21

0.152

296

163

327

0.924

1.467

1.882

 

 

 

±1.156

±2.407

±2.966

±0.009

±0.010

±0.006

240

7.41

0.162

284

138

307

0.943

1.488

1.906

 

 

 

±2.649

±2.336

±2.655

±0.010

±0.011

±0.007

Table 2 Effect of 1% sugarcane peelar bagasse waste hydrolyzed with 0.6N HCl on cellulases production by Aspergillus niger when incubated in cooled orbital shaking incubator adjusted at 200 rev/min with initial pH 6.0 at 28±2°C
C1, CM-cellulase; C2, Cellobiase; C3, Salicinase; ±, error of standard deviation.

Time Period Hours

Final pH

Weight of mycelia g/100ml

Total sugar mg/ml

Reducing Sugar mg/ml

Total Protein mg/ml

Enzyme activity units/ml

 

 

 

C1

C2

C3

24

4.21

0.22

486

433

490

0.162

0.42

0.151

 

 

 

±0.578

±0.883

±1.455

±0.001

±0.002

±0.152

48

4.22

0.35

456

414

462

0.185

0.317

0.153

 

 

 

±1.156

±1.455

±1.734

±0.002

±0.001

±0.002

72

4.23

0.42

450

371

385

0.194

0.394

0.161

 

 

 

±0.883

±2.084

±1.203

±0.003

±0.011

±0.004

96

4.24

0.48

416

370

378

0.197

0.749

0.292

 

 

 

±1.455

±1.156

±1.766

±0.004

±0.003

±0.010

120

4.28

0.55

378

330

372

0.201

0.817

0.412

 

 

 

±1.203

±2.336

±2.030

±0.005

±0.012

±0.008

144

4.33

0.63

342

324

347

0.202

1.053

0.483

 

 

 

±1.529

±1.766

±2.336

±0.006

±0.004

±0.006

168

4.35

0.68

294

304

325

0.211

1.122

0.485

 

 

 

±1.766

±2.909

±2.607

±0.007

±0.004

±0.007

192

4.38

0.75

252

296

300

0.213

1.517

0.489

 

 

 

±2.030

±1.156

±0.883

±0.008

±0.021

±0.008

216

4.42

0.79

112

284

296

0.216

1.775

0.491

 

 

 

±2.407

±2.649

±1.156

±0.009

±0.003

±0.009

240

4.48

0.82

109

230

284

0.219

1.922

0.498

 

 

 

±1.073

 

±2.649

±0.010

±0.005

±0.022

Table 3 Effect of 1% sugarcane bagasse waste hydrolyzed with 0.6N HCl on cellulases production by Aspergillus niger when incubated in cooled orbital shaking incubator adjusted at 200 rev/min with initial pH 6.0 at 28±2°C
C1, CM-cellulase; C2, Cellobiase; C3, Salicinase; ±, Error of standard deviation.

Final pH of the medium increased during fermentation in both cases. The maximum amount of fungal biomass was obtained at 240 hours, when Aspergillus niger grown in acid pretreated sugarcane peelar bagasse and sugarcane bagasse. The concentration of total sugar, reducing sugar and total protein decreases with the increase of growth period of Aspergillus niger as shown in Tables 2 & 3 Aspergillus niger was grown on 0.6N HCl pretreated banana fruit stalk and sorghum husk mineral medium for the production of cellulases.

It is observed from the Tables 4 & 5 that the maximum production of CM-Cellulase, cellobiase and salicinase was achieved at 240 and 240 hours respectively 2.076, 2.14, 2.093 and 0.871, 1.49, 0.319 units/ml when 0.6N HCl pretreated banana fruit stalk and sorghum husk were used as carbon source. The final pH of the culture broth was found in acidic medium and remained less than initial pH values throughout incubation time, but in case of sorghum husk final pH values increasing in order. The biomass was found maximum at 240 hours, when Aspergillus niger was grown on 0.6N HCl pretreated rice husk and sugarcane peelar bagasse. It was noted that the concentration of total sugar, reducing sugar and total protein were found decreasing in order.

Time Period Hours

Final pH

Weight of mycelia g/100ml

Total sugar mg/ml

Reducing Sugar mg/ml

Total Protein mg/ml

Enzyme activity units/ml

 

 

 

 

 

 

C1

C2

C3

24

5.76

0.068

426

379

418

0.212

0.763

0.286

 

 

 

±0.883

±1.058

±1.858

±0.001

±0.007

±0.003

48

5.84

0.079

473

367

392

0.285

0.807

0.291

 

 

 

±1.529

±2.084

±2.188

±0.002

±0.009

±0.004

72

6.15

0.112

487

353

360

0.286

0.928

0.298

 

 

 

±1.529

±1.455

±2.520

±0.003

±0.008

±0.006

96

6.41

0.148

490

352

345

0.291

1.143

1.321

 

 

 

±1.455

±1.766

±2.851

±0.004

±0.024

±0.010

120

6.88

0.197

527

295

327

0.298

1.221

1.473

 

 

 

±1.203

±0.883

±2.966

±0.006

±0.010

±0.009

144

7.28

0.204

529

278

307

1.321

1.771

1.802

 

 

 

±1.205

±1.734

±2.655

±0.010

±0.005

±0.004

168

7.71

0.208

532

270

242

1.473

1.785

1.871

 

 

 

±0.205

±2.030

±2.084

±0.009

±0.008

±0.005

192

7.81

0.211

542

195

230

1.786

1.923

1.883

 

 

 

±0.882

±1.734

±1.203

±0.008

±0.004

±0.006

216

7.92

0.215

549

163

195

1.918

1.932

1.906

 

 

 

±0.880

±2.407

±1.734

±0.007

±0.014

±0.007

240

7.96

0.219

562

138

163

2.076

2.14

2.093

 

 

 

±1.888

±2.336

±2.407

±0.011

±0.097

±0.008

Table 4 Effect of 1% banana fruit stalk waste hydrolyzed with 0.6N HCl on cellulases production by Aspergillus niger when incubated in cooled orbital shaking incubator adjusted at 200 rev/min with initial pH 6.0 at 28 ± 2°C
C1, CM-cellulase; C2, Cellobiase; C3, Salicinase; ±, Error of standard deviation.

Time Period Hours

FinalpH

Weight of mycelia g/100ml

Total sugar mg/ml

Reducing Sugar mg/ml

Total Protein mg/ml

Enzyme activity units/ml

 

 

 

 

 

 

C1

C2

C3

24

4.88

0.081

575

341

580

0.127

1.23

0.102

 

 

 

±0.578

±1.456

±0.883

±0.017

±0.001

±0.003

48

4.92

0.096

545

314

566

0.201

1.41

0.108

 

 

 

±0.883

±1.766

±1.203

±0.005

±0.002

±0.001

72

4.98

0.123

473

270

464

0.234

1.42

0.157

 

 

 

±1.455

±2.030

±1.529

±0.038

±0.003

±0.002

96

5.22

0.169

462

242

428

0.384

1.43

0.169

 

 

 

±1.734

±2.084

±1.766

±0.007

±0.004

±0.001

120

5.31

0.172

406

230

390

0.455

1.44

0.185

 

 

 

±1.766

±1.203

±2.407

±0.009

±0.005

±0.004

144

6.32

0.175

379

195

362

0.477

1.45

0.201

 

 

 

±1.058

±1.734

±1.858

±0.035

±0.006

±0.006

168

6.41

0.178

367

182

354

0.531

1.46

0.212

 

 

 

±2.084

±0.578

±2.084

±0.012

±0.007

±0.005

192

7.28

0.176

353

163

317

0.665

1.47

0.264

 

 

 

±1.455

±2.407

±1.156

±0.016

±0.008

±0.010

216

7.31

0.174

351

153

296

0.718

1.48

0.308

 

 

 

±1.762

±2.007

±2.407

±0.027

±0.009

±0.001

240

7.61

0.171

295

138

289

0.871

1.49

0.319

 

 

 

±0.880

±2.336

±2.851

±0.0066

±0.010

±0.009

Table 5 Effect of 1% sorghum husk hydrolyzed with 0.6N HCl on cellulases production by Aspergillus niger when incubated in cooled orbital shaking incubator adjusted at 200 rev/min with initial pH 6.0 at 28 ±2°C
C1, CM-cellulase; C2, Cellobiase; C3, Salicinase; ±, Error of standard deviation.

It was observed in Table 6 that cellulases secretion increases till 240 hours. Total sugar, reducing sugar and total protein continuously decreasing in order because of growth was increasing and an organism was utilizing reducing sugar as a carbon source of energy. Whereas change in pH towards acidic was detected with increase in time of incubation may be due to some organic acids production. Fungal biomass was increasing in order throughout fermentation .The maximum cellulases production was noted 4.811, 4.717 and 4.742 units/ml from rice husk.

Time Period Hours

Final pH

Weight of mycelia g/100ml

Total sugar mg/ml

Reducing Sugar mg/ml

Total Protein mg/ml

 Enzyme activity units/ml

 

 

 

 

 

 

C1

C2

C3

24

4.11

0.936

561

304

535

0.811

0.246

0.136

±0.707

±0.001

±0.707

±0.040

±0.003

±0.008

48

4.19

0.914

526

260

497

0.847

0.807

0.413

±0.707

±1.414

±1.414

±0.024

±0.009

±0.004

72

4.25

0.841

520

252

455

0.921

0.817

0.485

±3.536

±0.001

±1.414

±0.058

±0.002

±0.003

96

5.22

0.661

472

242

388

1.097

0.872

0.49

±2.121

±2.121

±1.414

±0.009

±0.005

±1.156

120

5.32

0.561

453

236

343

1.984

0.901

0.551

±2.121

±0.707

±1.414

±0.003

±0.006

±0.005

144

6.38

0.522

448

227

332

2.871

0.915

0.677

±1.414

±2.121

±5.657

±0.006

±0.008

±0.002

168

6.41

0.441

405

221

327

3.381

0.928

0.735

±3.536

±0.707

±2.121

±0.036

±0.007

±0.002

192

6.44

0.438

388

214

293

3.391

1.045

0.758

±1.414

±2.828

±4.950

±0.333

±0.024

±0.001

216

6.51

0.391

371

200

278

4.141

1.053

0.902

±0.707

±3.536

±5.657

±0.097

±0.004

±0.019

240

6.55

0.367

353

189

243

4.811

4.717

4.742

±1.414

±0.707

±1.414

±0.004

±0.010

±0.077

Table 6 Effect of 1% rice husk hydrolyzed with 0.6N HCl on cellulases production by Aspergillus niger when incubated in cooled orbital shaking incubator adjusted at 200 rev/min with initial pH 6.0 at 28 ±2°C
C1, CM-cellulase; C2, Cellobiase; C3, Salicinase; ±, Error of standard deviation.

Discussion

Agricultural wastes are generated in large quantities in many countries and most of which are underutilized and considered as waste especially in developing countries. Significant efforts have been made by several researchers in converting these agricultural wastes to valuable products including biofuels, animal feed, biofertilizer, and enzymes.14,15 These processes help in controlling some of the environmental challenges associated with their disposal. The polymeric constituents of agricultural wastes used in this study in terms of cellulose, hemicellulose and lignin. This is important for the support of the growth of microorganisms for valuable product formation.

 Commonly dilute acids are utilized to degrade hemicellulose, cellulose and other non-crystalline polymer to simple sugars (glucose). Acid hydrolysis produces minimal decomposition of monosaccharide and conventional neutralization is not necessary. The chemical pretreatment method is less expensive and more effective. The ratio of total sugar or reducing sugar reflects the average degree of polymerization (DP) of sugar moieties in solution. It is important that this ratio is close to 1.0. Han have reported the effectiveness of acid treatment depends on the substrate and other optimal conditions. Lyayi16 reported that higher amount of cellulase production achieved by indigenous strains. In present study confirm that the maximum production (4.811units/ml) of CM-cellulase was obtained at 240 hours of incubation when rice husk hydrolysate was used as a carbon source. Whereas, cellobiase and salicinase maximum production 4.717 and 4.742 units/ml were obtained at 240 hours respectively when rice husk hydrolysate used as a carbon source by indigenous strain Aspergillus niger.17–26

Acknowledgements

None.

Conflict of interest

The author declares there are no conflicts of interest.

References

  1. Bhat MK, Bhat S. Cellulose degrading enzymes and their potential industrial application. Biotechnol Adv. 1997;15:583–620.
  2. Sohail M, Siddiqi R, Ahmad A, et al. Cellulase production from Aspergillus niger MS82: effect of temperature and pH. New Biotechnol. 2009;25(6):6437–6441.
  3. Bhat MK. Cellulases and related enzymes in biotechnology. Biotechnol Adv. 2000;18:355–383.
  4. Wyman CE. Ethanol from lignocellulosic biomass: technology, economics and opportunities. Bioresour Technol. 1994;50:3–16.
  5. Saha BC. Production, purification and properties of endoglucanase from a newly isolated strain of Mucor circinelloides. Process Biochem. 2004;39:1871–1876.
  6. Clarke AJ. Biodegradation of cellulose: enzymology and biotechnology. USA: Technomic Publishing Company; 1997.
  7. Pelezar MT, Reid RD. Microbiology. Published by Mc Graw –Hill Boon company New York; 1976. P. 333–364.
  8. Schwermann B, Pfau K, Lilensiek P. Et al. Purification, properties and structural aspects of a thermoacidophilic α-amylase from Alicyclobacillus acidocaldarius atcc 27009, insight into acidostability of proteins. Eur J Biochem. 1994;226:981–991.
  9. Park YK, Almeida MM. Production of fructo oligosaccharides from sucrose by a transfructosylase from Aspergillus niger. World J. Microbiol Biotechnol. 1991;7(3):3312–3334.
  10. Noomrio M, Hanif Dahot, M Umar. Comparative study on the production of cellulases by Aspergillus niger using agricultural waste as a carbon source. Proceeding All Pak Sci Conf. 1992;16–21.
  11. Mandels M, Andreotti R, Roche C. Measurement of Saccharifying cellulase. Biotechnol Bioeng symp. 1976;6:21–33.
  12. Stenberg D, Vijakumar P, Reese ET. β-Glucosidase: microbial production and effect on enzymatic hydrolysis of cellulose. Can J Microbial. 1977;23:139–147.
  13. Miller GL. Use of Dinitrosalicylic Acid Reagent for Determination of Reducing Sugar. Use of Dinitrosalicylic Acid Reagent for Determination of Reducing Sugar. Anal Chem. 1959;31(3):426–428.
  14. Dashtban M, Schraft H, Qin W. Fungal bioconversion of lignocellulosic residues; opportunities and perspectives. Int J Biol Sci. 2009;5(6):578–595.
  15. Sánchez C. Lignocellulosic residues: biodegradation and bioconversion by fungi. Biotechnol Adv. 2009;27(2):185–194.
  16. Lyayi AE. Changes in the cellulose, sugar and crude protein contents of agro- industrial byproducts fermented with Aspergillus niger, Aspergillus flavus and Penicillium sp. Afr J Biotechnol. 2004;3:186–188.
  17. Aguillar G, Huitron C. Stimulation of production of extracellular pectinolytic activities of Aspergillus sp by galacturonic acid and glucose additions. Enz Microbiol Technol. 1987;9(11):690–696.
  18. Ariffin HN, Abdullah MS, Umi Kalson, et al. Hassan, Production and characterization of cellulase by Bacillus pumilus EB3. International Journal of Eng and Technol. 2006;3(1):47–53.
  19. Guevara MA, MT Gonzalez–Jen, Estevez P. Multiple forms of pectic lyases and polygalacturonases from Fusarium oxysporum f. sp redicais lycpersici: Regulation of their synthesis by galacturonic acid. Canadian J Microbiol. 1997;43:245–253.
  20. Pavlostathis SG, Gossett JM. Alkaline treatment of wheat straw for increasing anaerobic biodegradability. Biotechnol Bioeng. 1985;27:334–344.
  21. van Peij NN, Gielkens MM, de Vries RP, et al. the transcriptional activator X in R regulates both xylanolytic endo-glucanase gene expression in Aspergillus niger. Appl Environ Microbiol. 1998;64:3615–3617.
  22. Shoemaker SP, Raymond JC, Bruner R. Cellulases: diversity amongst improved Trichoderma strains. Basic Life Sci. 1981;18:89–109.
  23. Siddiqui M, Siddiqui N, Verma R. Production of CM-cellulase by Aspergillus niger using plant waste as substrate. Int J Curr Microbiol and App Sci. 2015;4(5):742–747.
  24. Singhania RR, Sukumaran RK, Patel AK, et al. Advancement and comparative profiles in the production technologies using solid state and submerged fermentation for microbial cellulases. Enzym Microb Tech. 2010;46:541–549.
  25. Sangrila S, PS Sukanta, K Sen, et al. T K Production, purification and characterization of a novel thermotolerant endoglucanase (CMCase) from Bacillus strain isolated from cow dung. Springer Plus. 2013;10:1186–2193.
  26. Saritha M, D Amat, J Choudhary, A, et al. Novel perspectives for evolving enzyme cocktails for lignocellulose hydrolysis in bio refineries and Sustainable Chemical Processes. 2013;1:15.
Creative Commons Attribution License

©2018 Siyal, et al. This is an open access article distributed under the terms of the, which permits unrestricted use, distribution, and build upon your work non-commercially.