ABSTRACT
The eyanogenic, potential of processed and
unprocessed roots of two new cassava cultivars TME 41 9 and TMS 98/0505 was
studied using spectrophotometric and enzymatic methods. Partial purl licUlioli
and some PrOPCr1ieS ol the 3-g1ucosidasc from these cassava cultivars were also
determined. These cultivars are planted and distributed to farmers by N RCR I.
Umudike but have not been assessed for cyanogenic potential under their new climatic
environment. The cyanogcnic potential of the root pulp in their unprocessed
form ranged from 40.0 ± 0.2 to 60.0 ± 0.3 mgCNKg, while processing into garri
and oven drying of the chips resulted in cyanogenic potential of 0.29±0.01
mgCNKg' for TME 419 cultivar and 0.2 1±0.05 mgCNKg for TMS 98/0505 cu1tivar for
garri and 36.06 for TME 419 and 34.16 br TMS 98/0505 respectively for the chips.
The protein content of the partially purified enzyme from these cuitivars gave 0.046mg/mi
and 0.069mg/mi while mathematical analysis of the data from the degradation of
Linamarin by the partially purified enzyme generated FICN values that were used
to construct Line Weaver Burk plot that gave apparent Km and Vmax values of
21.7mM and 5.0 x 10.2 imol FICN/ml for TME 419 and 15.6mM and 4.9 x 10.2 jimol
I-ICN/ml for TMS 98/0505 cultivars. The partially purified enzyme showed high
degree of hydrolysis towards standard linamarin and cyanogenic gi ucosides of
the new cassava cultivars.
TABLE
OF CONTENTS
Title
Page
Certification
ii
Declaration
iii
Dedication
iv
Acknowledgment
v
Table
of content vi-x
List
of tables xi
List
of figures xii
Abbreviations
xiii
Abstract
xiv
CHAPTER
1
1.1
Introduction 1
1.2
Justification 2
1.3
Aim of the study 3
1.4
Scope of the study 3
CHAPTER
2
2.1
Literature review 4
2.2
Basic studies on the cyanide liberation system 5
2.2.1
Cyanogenic glucosides 5
2.2.2.
Biosynthesis of cyanogenic glucosides in cassava 5
2.3
Linamarase 8
2.3.1
Characteristics of linamarase 8
2.4
Toxicity studies of cassava 8
2.4.1
Detoxification mechanisms for HCN in animal 9
2.5
Pharmacology of cyanogenic glucosides 9
2.6
Health implications of cyanide toxicity 10
2.7
Goitre, Konzo, and Cassava Consumption in Nigeria 10
CHAPTER
3: Materials and Methods
3.1
Apparatus and Equipments 12
3.1.1
Reagents 12
3.2
Preparation of reagent 12
3.2.1
0.2M Sodium hydroxide 12
3.2.2
0.5% Chloramine 12
3.2.3
0.1M Orthophosphoric acid 12
3.2.4
0.1M Phosphate Buffer pH 6.0 13
3.2.5
Acetate Buffer PH5.5 13
3.2.6
Colour developer 13
3.2.7
Potassium cyanide standard preparation 13
3.3
Sources of the cassava 14
3.4
Extraction and purification of 3- glucosidase 15
3.5
Determination of partially purified B- glucosidase activity (linamarase) 15
3.6
Protein determination 16
3.7
Preparation for cyanide analysis 17
3.7.1
Cassava pulp 17
3.7.2
Cassava peel 17
3.7.3
Cassava leaves 17
3.7.4
Cyanide determination 17
3.7.5
Assay for total cyanide 17
3.7.6
Assay for free cyanide 18
3.7.7
Cyanogenic potential of cassava extracts 18
3.7.8
Cassava chips preparation 21
3.7.9
Determination of glucosidic cyanide in cassava chips 21
3.8
Statistical analysis 21
CHAPTER
4: Results
4.1
Degradation of linamarine by the partially purified B- glucosidase and
cyanide
production values from TMS 98/0505 22
4.2
Degradation of linamarin by the partially purified B- glucosidase and the
cyanide
produation values from TME 419 23
4.3
Kinetic properties 26
4.4
Nitrogen content of TME 419 and TMS98/0505 27
4.4.1
protein determination 28
4.5
The kinetic properties of cassava B- glucosidase 29
4.6
Determination of free and total cyanide content (cyanogenic potential) in
fresh
cassava peel, pulp and leaves for TME 419 29
4.7
Determination of free and total cyanide content (cyanogenic potential) in
fresh
cassava peel, pulp and leaves for TMS 98/0505 30
4.8
Determination of glucosidic and non glucosidic cyanide concentration of
processed
TME 419 and TMS 98/0505 cultivars 30
4.9
Concentration and percentage loss of glucosidic cyanide in dry cassava chips
of
TME 419 and TMS 98/0505 31
CHAPTER
5: Discussion
5.1
Cyanogenic potential of two new cassava cuftivars 35
5.2
'Properties of the partially purified enzyme 37
Conclusion
39
Recommendation
40
References
41
Appendix
45
EKWELEM, A (2021). Determination Of The Cyanogenic Potential Of Two New Cassava Cultivars And The Hydrolytic Activities Of Their F3- Glucosidases. Repository.mouau.edu.ng: Retrieved Nov 23, 2024, from https://repository.mouau.edu.ng/work/view/determination-of-the-cyanogenic-potential-of-two-new-cassava-cultivars-and-the-hydrolytic-activities-of-their-f3-glucosidases-7-2
ADAKU, EKWELEM. "Determination Of The Cyanogenic Potential Of Two New Cassava Cultivars And The Hydrolytic Activities Of Their F3- Glucosidases" Repository.mouau.edu.ng. Repository.mouau.edu.ng, 26 May. 2021, https://repository.mouau.edu.ng/work/view/determination-of-the-cyanogenic-potential-of-two-new-cassava-cultivars-and-the-hydrolytic-activities-of-their-f3-glucosidases-7-2. Accessed 23 Nov. 2024.
ADAKU, EKWELEM. "Determination Of The Cyanogenic Potential Of Two New Cassava Cultivars And The Hydrolytic Activities Of Their F3- Glucosidases". Repository.mouau.edu.ng, Repository.mouau.edu.ng, 26 May. 2021. Web. 23 Nov. 2024. < https://repository.mouau.edu.ng/work/view/determination-of-the-cyanogenic-potential-of-two-new-cassava-cultivars-and-the-hydrolytic-activities-of-their-f3-glucosidases-7-2 >.
ADAKU, EKWELEM. "Determination Of The Cyanogenic Potential Of Two New Cassava Cultivars And The Hydrolytic Activities Of Their F3- Glucosidases" Repository.mouau.edu.ng (2021). Accessed 23 Nov. 2024. https://repository.mouau.edu.ng/work/view/determination-of-the-cyanogenic-potential-of-two-new-cassava-cultivars-and-the-hydrolytic-activities-of-their-f3-glucosidases-7-2