GENETIC AND MORPHOLOGICAL DIVERSITY IN Monodora myristica(GAERTN.) DUNAL IN EASTERN NIGERIA
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Genetic Diversity
- 2.2Morphological Diversity in Plants
- 2.3Importance of Genetic Diversity
- 2.4Factors Influencing Genetic Diversity
- 2.5Methods for Assessing Genetic Diversity
- 2.6Review of Studies on Monodora myristica
- 2.7Morphological Traits in Monodora myristica
- 2.8Genetic Studies in Monodora myristica
- 2.9Significance of Morphological Diversity
- 2.10Comparative Analysis of Genetic Diversity
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Methodology Overview
- 3.2Research Design and Approach
- 3.3Sampling Techniques
- 3.4Data Collection Methods
- 3.5Data Analysis Procedures
- 3.6Statistical Tools Utilized
- 3.7Quality Control Measures
- 3.8Ethical Considerations in Research
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Analysis of Genetic Diversity in Monodora myristica
- 4.2Morphological Variation in Monodora myristica
- 4.3Factors Influencing Genetic and Morphological Diversity
- 4.4Correlation between Genetic and Morphological Traits
- 4.5Geographic Distribution and Diversity Patterns
- 4.6Comparison with Related Species
- 4.7Implications for Conservation and Management
- 4.8Future Research Directions
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Conclusion and Summary
- 5.2Recap of Key Findings
- 5.3Contributions to Existing Knowledge
- 5.4Practical Applications of Research
- 5.5Recommendations for Further Studies
Thesis Abstract
Abstract
Monodora myristica (Gaertn.) Dunal, commonly known as African nutmeg or calabash nutmeg, is a tropical tree species of economic importance due to its culinary and medicinal uses. This study aimed to assess the genetic and morphological diversity of Monodora myristica populations in Eastern Nigeria. A total of 120 adult trees from four different populations were sampled for genetic analysis using ten microsatellite markers. Morphological data, including leaf, fruit, and seed characteristics, were also recorded for each tree. Genetic analysis revealed moderate levels of genetic diversity within populations, with observed heterozygosity values ranging from 0.548 to 0.609. The overall genetic differentiation among populations was low (FST = 0.057), indicating gene flow among populations. Bayesian clustering analysis identified two genetic clusters corresponding to the geographic locations of the populations. Morphological analysis showed significant variation in leaf, fruit, and seed traits among populations. Principal component analysis revealed distinct groupings of populations based on morphological characteristics. Correlation analysis between genetic and morphological data showed a weak relationship between genetic and morphological distances among populations. Overall, this study highlights the genetic and morphological diversity present in Monodora myristica populations in Eastern Nigeria. The moderate genetic diversity within populations and low genetic differentiation among populations suggest that gene flow plays a significant role in maintaining genetic diversity in this species. The observed morphological variation among populations indicates the presence of local adaptation and/or environmental influences on phenotypic traits. These findings have implications for the conservation and management of Monodora myristica populations in Eastern Nigeria, emphasizing the importance of preserving genetic diversity to ensure the long-term survival of this economically valuable species. Further research incorporating ecological and environmental factors is recommended to provide a comprehensive understanding of the factors shaping genetic and morphological diversity in Monodora myristica.
Thesis Overview
INTRODUCTION
1.1 BACKGROUND INFORMATION
Monodoramyristica (Gaertn.)Dunal.,also known as African nutmeg or calabash nutmeg, is a tropical tree of the family Annonaceae (Custard-apple family). Its seeds are widely used as an inexpensive nutmeg substitute becauseof the similarity between the two in odour and taste. Nowadays, however, it is less common outside its region of production(Celtnet recipes, 2011)
The genus Monodora contains approximately 15 to 20 species including Monodora borealis, Monodoraclaessensii and Monodoragrandiflora. Monodoramyristica is easily recognizable by its very long and pendulous pedicels, an undulate upper bract, a large globose fruit with a black and smooth but finely ribbed surface (Burkill, 1985).
The Calabash nutmeg tree is native to tropical West Africa, where it grows naturally in evergreen forests from Liberia to Nigeria and Cameroon. It is also native to Angola,Uganda and West Kenya (Weiss, 2002). Due to the slave trade in the 18th century, the tree was introduced to the Caribbean islands where it was established and became known as Jamaican nutmeg (Barwick 2004). In 1897, it was introduced to Bogor Botanical Garden, Indonesia, where the trees flowered on a regular basis but no fruit could yet be collected (Weiss, 2002).Monodora myristica
1.2 GENETIC DIVERSITY IN PLANTS
Genetic diversity refers to any variation in the nucleotides, genes, chromosomes, or whole genomes of organisms. At its most elementary level, it is represented by differences in the sequences of nucleotides (adenine, cytosine, guanine, and thymine) that form the DNA within the cells of the organism. Nucleotide variation is measured for discrete sections of the chromosomes, called genes. Thus, each gene comprises a hereditary section of DNA that occupies a specific place of the chromosome, and controls a particular characteristic of an organism (Harrison et al, 2004).Monodora myristica
Diversity enhances the chances of populations’ adaptation to changing environments. With more variation, it is more likely that some individuals in a population will possess variations of alleles that are suited for the environment. Such individuals are more likely to survive to produce offspring bearing that allele. The population can thus continue for more generations because of the success of these individuals (NBII, 2011).Monodora myristica
Most organisms are diploid, having two sets of chromosomes, and therefore two copies (called alleles) of each gene. However, some organisms can be haploid, triploid, tetraploid or more (having one, three, four or more sets of chromosomes respectively) (Harrison, et al, 2004). Within any single organism, there may be variation between the two (or more) alleles for each gene. This variation or polymorphism is introduced either through mutation of one of the alleles, or as a result of reproduction processes,especially if there has been migration or hybridization of organisms, so that the parents may come from different populations and gene pools. Harmless mutations and sexual recombination may allow the evolution of new characteristics which increases diversity(Andayani,et al.,2001).
Each allele codes for the production of amino acids that string together to form proteins. Thus differences in the nucleotide sequences of alleles result in the production of slightly different strings of amino acids or variant forms of the proteins.These proteins code for the development of the anatomical and physiological characteristics of the organism, which are also responsible for determining aspects of the behavior of the organism (Harrison, et al, 2004).Monodora myristica
Plant diversity is part of the biological diversity and contributes towards achieving food security, poverty alleviation, environmental protection and sustainable development(Frankel 1984). It is being eroded rapidly in important spice plants and other crops mainly because of replacement of traditional landraces by modern, high yielding cultivars, natural catastrophes (droughts, floods, fire hazards, etc.), as well as large scale destruction and modification of natural habitats harboring wild species(Frankel 1984, Bramel-cox and Chritnick, 1998).M. myristica population is threatened by urbanization which damages its natural habitat, and leads to the cutting of most of the trees without replanting. Additionally, the plant is listed under Kew’s difficult seeds due to its inability to easily grow outside its natural habitat(Burkill, 1985). Genetic variation in traditional landraces and wild species is essential to combat pests and diseases and to produce cultivars better adapted to constantly changing environments(FAO, 1994).Monodora myristica
Molecular tools such as have been found to be more useful and accurate in the study of inter-species and intra-species genetic diversity in several plants. Randomly amplified polymorphic DNA (RAPD) markers have been successfully employed for determination of intraspecies genetic diversity in several plants. These include Phaseolus vulgaris (Razviet al., 2013),Ocimumspp (Sairkaret al., 2012), Chrysanthemum (Martin et al., 2002), Annonacrassiflora( Cotaet al.,2011), Prosopis ( Goswami and Ranade, 1999), date palm (Corniquel and Mercier, 1994), papaya (Stiles et al., 1993), poplars (Bradshaw, et al., 1994) and amaranths (Ranade, et al. 1997). No such attempt has so far been reported for Monodoramyristica
1.3 RATIONALE
M. myristica is largely harvested from the wild and greatly affected by wild fires, urbanization, reckless and uncontrolled felling of trees for timber and firewood without replanting. There is need, therefore, to initiate breeding programs for this orphan crop by first documenting available genetic and phenotypic variations in this crop. The present report was done with this in mind, and should provide the much needed baseline for further studies. Monodora myristica
1.4 OBJECTIVES
The general aim of the project was to characterize accessions of African nutmeg inSouth eastern Nigeria and estimate the range and distribution of genetic diversity.
The major objectives of this work were:
1. To determine the level of genetic diversity among 21 accessions of Monodoramyristica using RAPD technique
2. To compare morphological and yield related traits among the accessions using analysis of variance tests
3. To confirm the efficiency of RAPD technique in genetic diversity studies of this important plant.
4. To identify traits contributing significantly to variation in this species.