Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-23T18:39:29.881Z Has data issue: false hasContentIssue false

Morphometric diversity of some Nigerian accessions of Bambara groundnut (Vigna subterranea)

Published online by Cambridge University Press:  13 December 2023

Opeyemi Tunde Osundare*
Affiliation:
Department of Crop Science and Horticulture, Federal University Oye-Ekiti, Ekiti State, Nigeria Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria
Oluwole Benjamin Akinyele
Affiliation:
Department of Crop, Soil and Pest management, Federal University of Technology, Akure, Nigeria
Alexander C. Odiyi
Affiliation:
Department of Crop, Soil and Pest management, Federal University of Technology, Akure, Nigeria
Michael Abberton
Affiliation:
Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria
Olaniyi Ajewole Oyatomi
Affiliation:
Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria
Rajneesh Paliwal
Affiliation:
Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria
*
Corresponding author: Opeyemi Tunde Osundare; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

This study evaluated the morphological diversity of some Nigerian accessions of Bambara groundnut. Field experiments were conducted in Nigeria in two locations and the phenotypic variation of Bambara groundnut accessions evaluated in 3 years (2017–2020) using a randomized complete block design. Twenty-eight quantitative and 10 qualitative traits were observed. Twenty-three out of the 28 quantitative morphological traits showed significant differences. TVSu-589 (28.85) and TVSu-670 (28.57) had the highest plant height; TVSu-572 (121.52), TVSu-271 (113.10) and TVSu-336 (104.15) had the highest 100-seed weight. Genetic variations were also observed in seed colour, terminal leaflet shape, petiole colour and eye pattern. Principal component analysis showed PC1 constituting 23.36% and PC2 constituting 15.76% of the total variation, while the first eight principal components with eigenvalues ≥1 revealed 77.28% of the total variation. Cluster analysis grouped the accessions into four groups. Based on yield data in this study, accessions TVSu-594, TVSu-350, TVSu-336, TVSu-1242, TVSu-129, TVSu-14, TVSu-179, TVSu-2100, TVSu-261 and TVSu-589 were the best for yield and are recommended for further evaluation to improve yield. This study showed that a wide range of diversity exists in Bambara groundnut of Nigerian origin that could be useful for further utilization of genetic resources and improvement.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of National Institute of Agricultural Botany

Introduction

Bambara groundnut has the potential to improve nutrition, boost food security, foster rural development and support sustainable land use. Bambara groundnut is indigenous to sub-Sahara Africa where it is widely cultivated. The centre of origin is North-Eastern Nigeria, in West Africa (Goli et al., Reference Goli, Bergemann and Ng1997; Xin et al., Reference Xin, Azam-Ali, Ee Von, Mustafa, Chai, Wai Kuan, Mayes, Mabhaudhi, Azam-Ali and Massawe2020; Nomathemba et al., Reference Nomathemba, Abe Shegro and Shimelis2021). This plant is referred to as a ‘groundnut’ because of the way it sets its pods, which is similar to groundnut (Arachis hypogea). The seeds of Bambara groundnut are consumed in several ways and at different stages of maturation, as a snack or vegetable. The young fresh seeds may be boiled and eaten as a snack in a manner similar to boiled peanuts, and are made into a pudding (or steamed paste) called Moi-Moi or Okpa (bean porridge) in some parts of Nigeria (Aremu et al., Reference Aremu, Yashim, Ibrahim, Adeyeye, Omosebi and Barnabas2022). In Zambia, Bambara groundnut is used for bread making (Mashau, Reference Mashau2022), and to produce legume milk (Ajilogba et al., Reference Ajilogba, Olanrewaju and Babalola2022). Dried seeds can be roasted and eaten as confectionery. For centuries, Bambara groundnut germplasm has been maintained as landraces, which are often phenotypically and genetically diverse (Hlanga et al., Reference Hlanga, Modi and Mathew2022). All cultivated Bambara groundnut genotypes are from farmers’ mass selection from landraces that have evolved directly from their wild relatives, and which have adapted to the natural environments (Muhammad et al., Reference Muhammad, Rafii, Ramlee, Nazli, Harun, Oladosu, Musa, Arolu, Chukwu, Haliru, Akos, Halidu and Arolu2020). Ahmad et al. (Reference Ahmad, Chai, Basu, Sri Redjeki, Moreton, Mayes, Ho, Massawe and Mayes2015) reported that domesticated Bambara groundnut (Vigna subterraneavar. subterranea) originated from its wild relative (V. subterraneavar. spontanea) through a series of gradual natural and artificial selections that are still taking place. One example of such selection is a change from a spreading/trailing to a bunching growth habit, and reductions in leaflet area, pod thickness and days to flowering as a result of domestication.

Adaptation to harsh environmental conditions and yield stability are characteristics that made landraces of Bambara groundnut farmers friendly (Rex, Reference Rex2020). The Bambara groundnut landraces can be systematically exploited in breeding programmes through a dedicated pre-breeding programme. Selection for genotypes will continue in mitigating the effects of climate change and enhancing the responsiveness of the crop to drought. Rex (Reference Rex2020) also reported that the selection of good parents is a key to success in plant breeding. This study evaluated the biodiversity of 100 Bambara groundnut of Nigerian origin and assessed the accessions for 28 quantitative and 10 qualitative agro-morphological traits. The study of the agronomic variability of these accessions is an important contribution to establishing the Bambara breeding programme in Nigeria for combating food and nutritional insecurity in Africa.

Materials and methods

Plant material and experimental location

The study was carried out at the International Institute of Tropical Agriculture (IITA), Ibadan, Nigeria and IITA out station, located at the Institute of Agricultural Research and Training (IAR&T) Ikenne, Nigeria for 3 years (2017/2018, 2018/2019 and 2019/2020). Ibadan is located on coordinates 7.38°N and 3.94°E and it is situated at 181 m above sea level. The average annual temperature is 26.5 °C and about 1311 mm of precipitation falls annually with 81% mean relative humidity. Ikenne is on coordinates 6.87°N and 3.71°E and 235.2 m above sea level, has an annual rainfall of 1200 mm, 65% mean relative humidity and 21.4 °C mean temperature, respectively. Seeds of 100 accessions of Bambara groundnut were sourced from the list of Genetic Resources Center (GRC), of IITA and used for the field experiments. The accessions were previously reported by Osundare et al. (Reference Osundare, Akinyele, Odiyi, Paliwal, Oyatomi and Abberton2022). The accessions were sourced to guide future research in the selection of genetic resources with thoroughly catalogued agronomic and genomic traits linked to GenBank accessions and to make data publicly available. The sourced accessions were also made to identify which of the thousands of accessions in a database is high yielding, as a critical step in food security.

Experimental design and field management

The experiments were laid out in a randomized complete block design with three replications. The total block size was (21 m × 50 m) and each plot was 1 m × 2.5 m. Inter and intra-row spacing was 1.00 m and 0.25 m. One seed was hand sown per hole, seed germination count was carried out and ungerminated supplied 2 weeks after planting. Herbicides such as paraquat was sprayed 2 weeks before ploughing and Metolachlor E.C was sprayed immediately after ridging the rate of 200 mg/20l to control weeds.

Data collection

Data were collected on 28 quantitative traits and 10 qualitative data using the procedure stated in the descriptor for Bambara groundnut (IPGRI, 2000). The experimental unit consisted of 10 plants per replicate. Data were collected from five tagged plants (at the middle of the row). The 10 qualitative traits are as follows; terminal leaflet colour, terminal leaflet shape (TLS), petiole colour, pod shape, dry pod colour, seed shape, growth habit, open flower colour, seed hilum colour and eye pattern.

Data analysis

Data collected in the three replications of the two locations and in the 3 years across locations were averaged and computed for all accessions, then subjected to analysis of variance (ANOVA) using the PROC GLM procedure on the statistical analytical system (SAS, version 9.4) (SAS, 2017). Treatment means were compared using Duncan multiple range test at 5 and 1% to separate the significant differences. Principal component analysis (PCA) was carried out using the PROC PRINCOMP procedure on SAS to determine the contribution of each trait to the total variation observed on the accessions used. Cluster analysis was carried out using the PROC CLUSTER procedure (Ward hierarchical clustering method) to show the distribution of the accessions into their different groups. Descriptive statistics were also employed to analyse qualitative data using frequencies and percentages. Pearson correlation was used to determine the relationships among the traits using PROC CORR in the SAS program.

Results

Quantitative traits

The ANOVA revealed highly significant (P ≤ 0.01) differences for most of the quantitative traits studied (Table S3) in the 3 years for 23 traits, out of the 28 quantitative traits evaluated. The mean value of the accessions studied revealed that plant height (PH, cm) varied significantly from 28.85 to 18.27, while accessions TVSu-589, TVSu-670, TVSu-2109, TVSu-2106 and TVSu-285 had the highest plant height and accessions TVSu-1239, TVSu-662 and TVSu-647 had significantly short plant height. Terminal leaflet length (TLL, mm) varied significantly from 84.14 to 45.33; accessions TVSu-589, TVSu-2109, TVSu-2106, TVSu-2105 and TVSu-285 had the longest terminal leaflet length while accessions TVSu-662, TVSu-838, TVSu-275 and TVSu-1252 had the shortest terminal leaflet length. Terminal leaflet width (TLW, mm) varied significantly from 44.97 to 19.79; accessions TVSu-2109, TVSu-589, TVSu-2105 and TVSu-2106 had the widest terminal leaflet width while accessions TVSu-586, TVSu-647, TVSu-14 and TVSu-365 had significantly narrow terminal leaflet width. Petiole length (PetL, mm) varied significantly from 205.88 to 116.88; accessions TVSu-670, TVSu-589, TVSu-2109, TVSu-2100 and TVSu-331 had the longest petiole length while accessions TVSu-1239, TVSu-662, TVSu-2112 and TVSu-647 had the shortest petiole length. The number of trifoliate leaves (NTLs) varied significantly from 95.04 to 49.97; accessions TVSu-333, TVSu-838, TVSu-1242, TVSu-1245 and TVSu-633 had the highest number of trifoliate leaves while accessions TVSu-269, TVSu-627, TVSu-127, TVSu-675 and TVSu-173 had the lowest number of trifoliate leaves. Plant spread (PlanSpr, cm) varied significantly from 45.71 to 28.85; accessions TVSu-271, TVSu-2109, TVSu-2105, TVSu-331 and TVSu-2099 covered the widest area of land while accessions TVSu-365, TVSu-647, TVSu-348 and TVSu-1222 covered narrow area of land. Internodes length (IL, mm) varied significantly from 22.96 to 10.45; accessions TVSu-129, TVSu-589, TVSu-2106, TVSu-2109 and TVSu-572 had the longest internodes length while accessions TVSu-173, TVSu-650, TVSu-577 and TVSu-261 had the shortest internodes length. Banner length (BL, mm) varied significantly from 5.98 to 5.25; accessions TVSu-590, TVSu-346, TVSu-2104, TVSu-348 and TVSu-585 had the longest banner length while accessions TVSu-1252, TVSu-662, TVSu-334 and TVSu-576 had the shortest banner length. Peduncle length (PdclL, mm) ranged from 6.58 to 3.98; accessions TVSu-670, TVSu-1241, TVSu-2112, TVSu-589 and TVSu-647 had the longest peduncle length while accessions TVSu-662, TVSu-2102, TVSu-656, TVSu-271 and TVSu-178 had the shortest peduncle length. The number of days to first flowering observed among the selected accessions was 34–41 days and the number of days to maturity was 116–131 days. Pod length (PdL, mm) ranged from 24.68 to 14.96; accessions TVSu-2105, TVSu-589, TVSu-2109, TVSu-336 and TVSu-2100 had the longest pod length while accessions TVSu-639, TVSu-640, TVSu-662 and TVSu-269 had the shortest pod length. Pod width (PdW, mm) ranged from 15.79 to 10.43; accessions TVSu-572, TVSu-368, TVSu-2099, TVSu-366 and TVSu-271 had the widest pod width while accessions TVSu-365, TVSu-662, TVSu-269 and TVSu-659 had narrow pod width. Grain yield per hectare (GYpHa, Kg) ranged from 1091.80 to 416.20; accessions TVSu-594, TVSu-261, TVSu-336, TVSu-350 and TVSu-1242 had the highest yield per hectare while accessions TVSu-285, TVSu-659, TVSu-359 and TVSu-268 had the lowest grain yield per hectare. Hundred seed weight (100-sdwt, g) ranged from 121.52 to 40.18; accessions TVSu-572, TVSu-271, TVSu-336, TVSu-368 and TVSu-83 had the highest 100-seed weight while accessions TVSu-287, TVSu-263, TVSu-178, TVSu-586 and TVSu-662 had the lowest 100-sdwt. Exceptional accessions with high-yielding characteristics above 800 kg per hectare in the locations and years include TVSu-594 (1091.80), TVSu-261 (966.20), TVSu-336 (917.80), TVSu-350 (903.30), TVSu-1242 (877.30), TVSu-2100 (855.40), TVSu-179 (848.20), TVSu-14 (834.30), TVSu-589 (820.70) and TVSu-129 (819.30) (Table S1).

Principal components

Comparison of the principal component's (PC) contribution to diversity in the 3 years revealed that PCs 1–8 constitute 77.28% of the total variation, where PCs 1, 2, 3, 4, 5, 6, 7 and 8 contributed 23.36, 15.76, 12.22, 6.86, 6.17, 4.72, 4.34 and 3.85, respectively. PCA showed PC1 constituted 23.36% and PC2 constituted 15.76%, while the first eight PCs that had eigen values ≥1 revealed 77.28% of total variation. Higher contribution to total variation was revealed by PCs 1 and 2. PC1 contributed 23.36%; these traits contributed to the variation plant height (0.28), terminal leaflet length (0.26), terminal leaflet width (0.26), petiole length (0.24), plant spread (0.25), internode length (0.19), yield per plant (0.19), yield per plot (0.19), pod length (0.28), pod width (0.29), seed length (0.30), seed width (0.24) and 100-seed weight (0.28). These components contributed positively to total variation. PC2 contributed 15.76%, yield per plant (0.29), number of pods per plot (0.34), yield per plot (0.38), yield per hectare (0.38), seed weight per plot (0.40), shelled harvest per plot (0.31) while shelling percentage (−0.30) contributed negatively (Fig. 1) (Table 1).

Figure 1. Contribution of PC1 and PC2 to variation.

Table 1. Eigen values and contribution of first eight principal components axes to variation in 3 years

PH, plant height; TLL, terminal leaflet length; TLW, terminal leaflet width; NTLvs, number of trifoliate leaves; PetL, petiole length; Plan Spr, plant spread; IntL, pnternode length; BL, banner length; NDtoFF, number of days to first flowering, NDto50%F; PdclL, peduncle length; NDtoM, number of days to maturity; NFpP, number of flowers per peduncle; Yplant, yield per plant; NPdspP, number of pods per plot; YpP, yield per plot; YpHa, yield per hectare (kg); NSdpPd, number of seed per pod; PdL, pod length; PdW, pod width; SdL, seed length; SdW, seed width; Shthk, shell thickness; Sdwt, seed weight per plot; Chfwt, chaff weight; Shperc, shelling percentage; Shdhv/P, shelled harvest per plot; 100sdwt, 100-seed weight.

Qualitative traits

Descriptive statistics on qualitative traits observed on terminal leaflet colour, growth habit and open flower colour were uniform in all the studied accessions as revealed in Table S2. The analysis of TLS revealed that 55% of the selected accessions are ‘lanceolate’, 44% ‘oval’ and 1% ‘elliptic’. The analysis of petiole colour showed that 66% had ‘whole green’ petiole while 34% had ‘base purple’ petiole colour. The analysis of pod shape revealed that 57% had ‘ending in a point with nook on the other side’ while 41% had ‘ending in a point round on the other side’ while others also exited. The analysis of dry pod colour revealed that 82% had a ‘yellowish brown’ dry pod colour while 13% had a ‘brown’ dry pod colour, while others also existed. The analysis of the seed shape revealed that 89% had an ‘oval’ seed shape while 11% had a ‘round’ seed shape. The analysis of seed hilum colour showed that 51% had ‘white’ seed hilum colour while 49% had ‘chalk white’ seed hilum colour. The analysis of eye pattern showed that ‘cream testa with grey butterfly-like eye’ was highest at 21% while ‘cream testa with brown butterfly-like eye’ accounted for 16% of the selected accessions, while others also existed (Table S2). The analysis of seed colour revealed that 26% had a pale yellow colour, 11% had greyish yellow, 9% had light brown, 6% had reddish brown, 5% had light orange, 5% had brownish orange, 4% had dark brown, 4% had violet brown, 3% had greyish brown, 3% had yellowish brown, 2% had light yellow, 2% had orange white, 2% had pale violet while others had less than 2% occurrence (Table S2).

Correlation coefficients

Correlation coefficients revealed that plant height had a positive and significant correlation with yield per plant (r = 0.23), yield per plot (r = 0.27), yield per hectare (r = 0.23), pod length (r = 0.54), pod width (r = 0.35), seed length (r = 0.39), seed width (r = 0.21) and 100-seed weight (r = 0.28) (Table S4). The number of days to first flowering had a negative and significant correlation with yield per plot (r = −0.28), yield per hectare (r = −0.22), pod width (r = −0.23), seed width (r = −0.27), seed weight per plot (r = −0.29) and 100-seed weight (r = −0.32). Yield per plant had a positive and significant correlation with the number of pods per plot (r = 0.28), yield per plot (r = 0.78), yield per hectare (r = 0.81), pod length (r = 0.25), pod width (r = 0.25), seed length (r = 0.36), seed width (r = 0.21), seed weight per plot (r = 0.78) and 100-seed weight (r = 0.30). The number of pods per plot had a positive and significant correlation with yield per plot (r = 0.47), yield per hectare (r = 0.45), number of seeds per pod (r = 0.24), seed weight per plot (r = 0.45) and shelled harvest per plot (r = 0.45), but had a negative and significant correlation with pod width (r = −0.36), seed width (r = −0.27), shelling percentage (r = −0.45) and 100-seed weight (r = −0.27). Yield per plot had a positive and significant correlation with yield per hectare (r = 0.93), pod length (r = 0.30), pod width (r = 0.29), seed length (r = 0.43), seed width (r = 0.26), seed weight per plot (r = 0.87), chaff weight (r = 0.26), shelled harvest per plot (r = 0.20) and 100-seed weight (r = 0.41). Yield per hectare had a positive and significant correlation with pod length (r = 0.27), pod width (r = 0.26), seed length (r = 0.37), seed width (r = 0.23), seed weight per plot (r = 0.83), chaff weight (r = 0.26), shelled harvest (r = 0.23) and 100-seed weight (r = 0.34), but had a negative and significant correlation with shelling percentage (r = −0.21). The number of seeds per pod had a positive and significant correlation with pod length (r = 0.42) but had a negative and significant correlation with pod width (r = −0.21), seed width (r = −0.21) and 100-seed weight (r = −0.28). Pod length had a positive and significant correlation with pod width (r = 0.54), seed length (r = 0.63), seed width (r = 0.34) and 100-seed weight (r = 0.39). Pod width had a positive and significant correlation with seed length (r = 0.74), seed width (r = 0.74), shelling percentage (r = 0.32) and 100-seed weight (r = 0.78), but had a negative and significant correlation with shelled harvest (r = −0.31). Seed length had a positive and significant correlation with seed width (r = 0.67), seed weight per plot (r = 0.29) and 100-seed weight (r = 0.77). Seed width had a positive and significant correlation with 100-seed weight (r = 0.71). Seed weight per plot had a positive and significant correlation with shelled harvest per plot (r = 0.35), and 100-seed weight (r = 0.30) had a negative and significant correlation with shelling percentage (r = −0.32). Chaff weight had a positive and significant correlation with shelling percentage (r = 0.22) and 100-seed weight (r = 0.19), but had a negative and significant correlation with shelled harvest per plot (r = −0.21). Shelling percentage had a negative and significant correlation with shelled harvest per plot (r = −0.98).

Cluster analysis of quantitative traits

Cluster analysis was used to assess the genetic differences of the observed quantitative traits, where individuals with related descriptions are grouped into the same cluster. The similarity, relatedness and distance of the varieties are the foundation of this method, where similar accessions were grouped into the same cluster, and dissimilar accessions were grouped differently. The length between the lines (distance between two points) was calculated using standardized morphological data, and a dendrogram was constructed using these values (Fig. 2). The selected population was grouped into four subpopulations, cluster 1 had 9 accessions, cluster 2 had 41 accessions, cluster 3 had 16 accessions and cluster 4 had 34 accessions (Fig. 2). Accession with the highest yield components and highest agronomic traits responses fell into clusters 2 and 4 as revealed through the means.

Figure 2. Dendrogram showing the group classification of the accessions.

Discussion

The results of this study demonstrated morphological diversity among the sourced accessions of Nigerian Bambara groundnut, with the different groupings of the distribution of the accessions through the dendrogram and the distribution of data. We identified TVSu-589 and TVSu-670 as accessions that could be used in the improvement of the plant height in future breeding research. We also identified TVSu-572, TVSu-594 and TVSu-336 as Bambara groundnut accessions with high yield. The traditional farmers in West Africa and the formal seed system will have access to seeds of Bambara groundnut with higher potential for yield. Further investigation into the genetic makeup will reveal specific genes responsible for individual differences and the effects of such genes in the development of targeted traits.

This study demonstrated diversity in plant height, seed weight and 100-seed weight, confirming the results of Nabuuma et al. (Reference Nabuuma, Reimers, Hoang, Stomph, Swaans and Raneri2022). Other studies have also reported morphological variations of the quantitative and qualitative traits of Bambara groundnut accessions (Ntundu et al., Reference Ntundu, Shillah, Marandu and Christiansen2006; Ullah et al., Reference Ullah, Bashar, Bhuiyan, Khalequzzaman and Hassa2011; Shegro et al., Reference Shegro, Rensburg and Adebola2013; Tafadzwanashe and Albert, Reference Tafadzwanashe and Albert2013; Zenabou et al., Reference Zenabou, Martin, Earnest, Bassiaka, Claude and Siegfried2014; Mohammed et al., Reference Mohammed, Shimelis and Liang2016; Atoyebi et al., Reference Atoyebi, Oyatomi, Odutola, Adebawo and Abberton2017; Adikuru et al., Reference Adikuru, Francis, Anyanwu, Onwubiko and Alagba2017; Odongo et al., Reference Odongo, Mungai, Mutai, Karumi, Mwangi, Okalebo, Kimondo, Omale and Simiyu2018; Mohammed et al., Reference Mohammed, Shimelis and Liang2019; Nomathemba et al., Reference Nomathemba, Abe Shegro and Shimelis2021; Mesay et al., Reference Mesay, Gobeze and Mesfin2022). However, this research demonstrated that variability existed among Bambara groundnut accessions of Nigeria origin, which has not been reported before. The accessions showed no significant difference in the number of days to maturity. This agrees with Berchie et al. (Reference Berchie, Sarkodie-Addo, Adu-Dapaah, Agyemang, Addy, Asare and Donkor2010) who also observed no significant difference in the number of days to maturity. Earliness to maturity may be a useful trait to escape drought in erratic heightening moisture stress environment and insect infestation as supported by Shumba-Mnyulwa (Reference Shumba-Mnyulwa2002) and Toure et al. (Reference Toure, Kone, Kouakou and Kone2012) (Khan et al., Reference Khan, Mohd, Shairul, Mashhitah and Al Mamun2021a). The accessions showed significant differences in yield per hectare, in the observed years with an average of 641.59 kg per hectare. This confirmed the report of Khan et al. (Reference Khan, Mohd, Shairul, Mashhitah and Al Mamun2021a) and Hailegiorgis et al. (Reference Hailegiorgis, Mesfin and Genet2011) that Bambara groundnut can grow and produce reasonable yield in Africa. This was also reiterated by Khan et al. (Reference Khan, Mohd, Shairul, Mashitan and Al-Mamun2021b) and Oluwaseyi et al. (Reference Oluwaseyi, Oyatomi, Babalola and Abberton2021).

PC1 and PC2 had the highest contribution to variation, indicating that they are key factors to reveal diversity in the selected accessions. Similar results were also reported by Ntundu et al. (Reference Ntundu, Shillah, Marandu and Christiansen2006), Hailegiorgis et al. (Reference Hailegiorgis, Mesfin and Genet2011) and Ravishanker et al. (Reference Ravishanker, Rajora, Greco and Osborn2013). However, this study demonstrated that plant height, seed weight and yield per hectare are important diversity traits among Bambara groundnut of Nigerian origin which has not been reported before. The level of morphological similarity shown by accessions within the same cluster indicated that the accessions may not have a common ancestry, similar to the results reported by Ntundu et al. (Reference Ntundu, Shillah, Marandu and Christiansen2006), Ullah et al. (Reference Ullah, Bashar, Bhuiyan, Khalequzzaman and Hassa2011), Olukolu et al. (Reference Olukolu, Mayes, Stadler, Nyat, Fawole, Dumet, Azam-Ali, Abbott and Kole2012) and Mohammed et al. (Reference Mohammed, Shimelis and Liang2016). The dendrogram analysis in this study identified four subpopulations based on morphological traits, which indicated high genetic variation, which has potential for future breeding programmes in other ecological zones in Nigeria.

The analysis of ‘locations’ showed significant variations for 20 out of the 28 traits evaluated in the years. A similar result was obtained by Esan et al. (Reference Esan, Oke and Ogunbode2023) who reported significant differences in traits of Bambara groundnut evaluated in different regions in Cote d'Ivoire. Yield per plant varied significantly among accessions in the years from 12 to 42 g/plant, indicating that the yield of Bambara groundnut varied widely depending on accessions and environmental conditions. The results are in agreement with previous studies (Shumba-Mnyulwa, Reference Shumba-Mnyulwa2002; Shareef and Krishnaraj, Reference Shareef and Krishnaraj2013; Chai et al., Reference Chai, Ho, Graham, May, Massawe and Mayes2017; Mayes et al., Reference Mayes, Wai, Chai, Gao, Kundy, Mateva, Zahrulakmal, Hahiree, Kendabie, Licea, Massawe, Mabhaudhi, Modi, Berchie, Amoah, Faloye, Abberton, Oyatomi and Azam-Ali2019; Oluwaseyi et al., Reference Oluwaseyi, Oyatomi, Babalola and Abberton2021; Khan et al., Reference Khan, Mohd, Shairul, Mashhitah and Al Mamun2021a; Hlanga et al., Reference Hlanga, Modi and Mathew2022; Esan et al., Reference Esan, Oke and Ogunbode2023).The interaction of ‘accession × location’ also indicated that traits responsible for diversity in Bambara groundnut showed significant differences in the locations. This was also reported by Muhammad et al. (Reference Muhammad, Rafii, Ramlee, Nazli, Harun, Oladosu, Musa, Arolu, Chukwu, Haliru, Akos, Halidu and Arolu2020). Some of the non-significant quantitative traits are less influenced by location and may express their genetic potential at any particular location. The interaction of ‘accession × location × year’ showed that accessions of Bambara groundnut express its morphological traits differently in locations, hence, diversity among the ‘accessions’ is genetically and environmentally controlled.

Qualitative traits analysis showed that all the sourced accessions for this research had green leaves confirming a previous report (Basu et al., Reference Basu, Robert, Azam-Ali and Mayes2007). Mohammed et al. (Reference Mohammed, Shimelis and Liang2016) also reported variations in the TLS, pod shape, pod texture, seed shape and seed colour of 49 Bambara groundnut landraces. However, only 2% of the accessions in this study had pods without a point while 57% of the pods had a point with a nook on the other side. These results contrast with the finding of Mohammed et al. (Reference Mohammed, Shimelis and Liang2016) who reported that none of the pods of the Bambara groundnut landraces used had a point. Open flower colour for all the 100 accessions used for this study was yellow, seed colour was dominated by pale yellow at 26%, and seed eye pattern was dominated by cream testa with grey butterfly-like eye at 21%. The findings corroborated the report of Goli et al. (Reference Goli, Bergemann and Ng1997) that Bambara groundnut varies in seed morphological features. This study identified TVSu-336, TVSu-350, TVSu-261, TVSu-594 and TVSu-589 as high-yielding accessions of Bambara groundnut that originated in Nigeria with above 800 kg/ha. This study also confirmed that positive correlation existed between yield-contributing traits and yield per hectare, which indicated the improved performance of the associated traits in this research. These traits characterized in the study will provide valuable information for future breeding programmes to improve yield of Bambara groundnut in Nigeria.

Conclusions

This study concluded that morphological variability existed among Bambara groundnut in Nigeria and that such variation existed in plant height, petiole length, pod width, plant spread, yield per hectare, yield per plot, yield per plant, number of pods per plot and terminal leaflet length, and are important traits that should be given attention in making effective selection for parents in Bambara groundnut breeding. Further studies should also make use of high-throughput sequencing markers to dissect the level of diversity established in this study in the genomic constituent of Bambara groundnut.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1479262123001028.

Acknowledgements

Special thanks to the Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria for the research fellowship awarded, in the course of carrying out this research.

Author contributions

Conceptualization, M. T. A., O. T. O. and B. O. A; funding acquisition, M. T. A.; investigation, O. T. O.; methodology, O. T. O., O. A. O., B. O. A. and A. C. O.; data curation, O. T. O. and R. P.; formal analysis, O. T. O. and R. P.; project administration, M. T. A and O. A. O.; supervision, M. T. A., B. O. A. and A. C. O; writing – original draft, O. T. O; writing – review and editing, B. O. A., A. C. O. and O. T. O.

Funding statement

This research was financed by The Global Crop Diversity Trust (Crop Trust), through the Consultative Group on International Agricultural Research (CGIAR) and the Genetic Resources Center, International Institute of Tropical Agriculture, Ibadan, Nigeria.

Competing interest

None.

References

Adikuru, NC, Francis, AA, Anyanwu, CP, Onwubiko, NC and Alagba, RA (2017) Preliminary evaluation of Bambara groundnut (Vigna subterranea(L.) Verdc.) for growth and reproductive characteristics in Owerri southeastern, Nigeria. Nigerian Journal of Agriculture, Food and Environment 13, 103109.Google Scholar
Ahmad, NS, Chai, HH, Basu, S, Sri Redjeki, E, Moreton, J, Mayes, K, Ho, WK, Massawe, F and Mayes, S (2015) Exploring the domestication of Bambara groundnut. Acta Horticulturae 1101, 183190.CrossRefGoogle Scholar
Ajilogba, CF, Olanrewaju, OS and Babalola, OO (2022) Improving Bambara groundnut production: insight into the role of Omics and beneficial Bacteria. Frontier in Plant Science 13, 836133. doi: 10.3389/fpls.2022.836133Google ScholarPubMed
Aremu, MO, Yashim, T, Ibrahim, H, Adeyeye, E, Omosebi, OM and Barnabas, EA (2022) Nutritional quality assessment of commonly sold steamed Bambara groundnut (Vigna subterranea) pastes in Lafia motor parks, Nasarawa State, Nigeria. Bangladesh Journal of Scientific and Industrial Research 57, 2740.CrossRefGoogle Scholar
Atoyebi, JO, Oyatomi, OA, Odutola, O, Adebawo, O and Abberton, MT (2017) Morphological characterisation of selected African accessions of Bambara groundnut (Vigna subterranea (L.) Verdc.). International Journal of Plant Research 7, 2935.Google Scholar
Basu, SN, Robert, JA, Azam-Ali, SN and Mayes, S (2007) Bambara groundnut, genome map. Mol. Breed. Plants 3, 157173.Google Scholar
Berchie, JN, Sarkodie-Addo, J, Adu-Dapaah, H, Agyemang, A, Addy, S, Asare, E and Donkor, J (2010) Yield evaluation of three early maturing Bambara groundnut (Vigna subterranea (L.) Verdc.) landraces at the CSIR-Crops Research Institute, Fumesua-Kumasi, Ghana. Journal of Agronomy 9, 175179.CrossRefGoogle Scholar
Chai, HH, Ho, WK, Graham, N, May, S, Massawe, F and Mayes, SA (2017) Cross species gene expression marker-based genetic map and QTL analysis in Bambara groundnut (Vigna subterranea (L.) Verdc.). Genes 8, 84. doi: 10.3390/genes8020084CrossRefGoogle ScholarPubMed
Esan, VI, Oke, GO and Ogunbode, TO (2023) Genetic variation and characterization of Bambara groundnut (Vigna subterranea) accessions under multi-environments considering yield and yield components performance. Scientific Reports 13, 1498.CrossRefGoogle ScholarPubMed
Goli, A, Bergemann, F and Ng, N (1997) Characterization and evaluation of IITA's Bambara groundnut collection. Bambara groundnut (Vigna subterranea [L.] Verdc.) proceedings of the workshop on conservation and improvement of Bambara groundnut (Vigna subterranea [L.] Verdc.) [Eds.] Heller J., Engels, J. and Hammer, K. 14–16 November, 1995. International Plant Genetic Resources Institute, Rome, Italy, Harare, Zimbabwe.Google Scholar
Hailegiorgis, D, Mesfin, M and Genet, T (2011) Genetic divergence analysis on some bread wheat genotypes grown in Ethiopia. Journal of Central European Agriculture 12, 344352.CrossRefGoogle Scholar
Hlanga, N, Modi, A and Mathew, I (2022) Agro-morphological diversity of Bambara groundnut lines evaluated under field conditions. South African Journal of Plant and Soil 39, 142152. doi: 10.1080/02571862.2022.2037165CrossRefGoogle Scholar
IPGRI, IITA, BAMNET (2000) Descriptors for Bambara groundnut (Vigna subterranea) International Institute of Tropical Agriculture, Ibadan, Nigeria/International Plant Genetic Resources Institute and International Bambara Network, Germany, ISBN: 92-9043-461-9.Google Scholar
Khan, MM, Mohd, RY, Shairul, IR, Mashhitah, J and Al Mamun, M (2021a) Genetic analysis and selection of Bambara groundnut (Vigna subterranea) landraces for high yield revealed by qualitative and quantitative traits. Scientific Reports 11, 7597.CrossRefGoogle ScholarPubMed
Khan, MH, Mohd, RY, Shairul, IR, Mashitan, J and Al-Mamun, Md (2021b) Bambara groundnut (Vigna subterranea (L.) Verdc.): a crop for the new millennium, its genetic diversity, and improvements to mitigate future food and nutritional challenges. Sustainability 13, 5530. doi: 10.3390/su13105530CrossRefGoogle Scholar
Mashau, EM (2022) The influence of Bambara groundnut (Vigna subterranea) flour on the nutritional, physical and antioxidant properties of steamed bread. Journal of Food 20, 259270.Google Scholar
Mayes, S, Wai, K, Chai, H, Gao, X, Kundy, A, Mateva, K, Zahrulakmal, M, Hahiree, M, Kendabie, P, Licea, L, Massawe, F, Mabhaudhi, T, Modi, AT, Berchie, J, Amoah, S, Faloye, B, Abberton, MT, Oyatomi, O and Azam-Ali, S (2019) Bambara groundnut: an exemplar underutilized legume for resilience under climate change. Planta 250, 803824. doi: 10.1007/s00425-019-03191-6CrossRefGoogle Scholar
Mesay, P, Gobeze, L and Mesfin, K (2022) Characterization and evaluation of Bambara groundnut (Vigna subterranea) for yield and related traits in Asosa Zone, Northwestern Ethiopia. Applied and Environmental Soil Science 2022, 17. doi: 10.1155/2022/8533233Google Scholar
Mohammed, MS, Shimelis, HA and Liang, MD (2016) Preliminary investigation on some agronomic and morphological variations of within and between Bambara groundnut (Vigna subterranea (L.) Verdc.) landraces. Journal of Agricultural Science and Technology 18, 19091920.Google Scholar
Mohammed, MS, Shimelis, H and Liang, DM (2019) Preliminary morphological characterization and evaluation of selected Bambara groundnut (Vigna subterranea (L.) Verdc.) genotypes for yield and yield related traits. Legume Research 43, 157164. doi: 10.18805/LR-475Google Scholar
Muhammad, I, Rafii, M, Ramlee, S, Nazli, M, Harun, A, Oladosu, Y, Musa, I, Arolu, F, Chukwu, S, Haliru, B, Akos, I, Halidu, J and Arolu, I (2020) Exploration of Bambara groundnut (Vigna subterranea (L.) Verdc.), and underutilized crop, to aid global food security: varietal improvement, genetic diversity and processing. Agronomy 10, 766. doi:10.3390/agronomy10060766CrossRefGoogle Scholar
Nabuuma, D, Reimers, C, Hoang, KT, Stomph, T, Swaans, K and Raneri, EJ (2022) Impact of seed system interventions on food and nutrition security in low-and middle-income countries: a scoping review. Global Food Security 33, 112. doi: 10.1016/j.gfs.2022.100638CrossRefGoogle Scholar
Nomathemba, M, Abe Shegro, G and Shimelis, H (2021) Bambara groundnut (Vigna subterranea) production, utilization and genetic improvement in Sub-Sahara Africa. Agronomy 11, 17. doi:10.3390/agronomy11071345Google Scholar
Ntundu, W, Shillah, SA, Marandu, WY and Christiansen, JL (2006) Morphological diversity of Bambara groundnut [Vigna subterranea (L.) Verdc.] landraces in Tanzania. Genetic Resources and Crop Evolution 53, 367378.CrossRefGoogle Scholar
Odongo, E, Mungai, N, Mutai, P, Karumi, E, Mwangi, J, Okalebo, F, Kimondo, J, Omale, J and Simiyu, J (2018) Antioxidant and anti-inflammatory activities of selected medicinal plants from western Kenya. African Journal of Pharmacology and Therapeutics 6, 178182.Google Scholar
Olukolu, B, Mayes, S, Stadler, F, Nyat, Q, Fawole, I, Dumet, D, Azam-Ali, S, Abbott, A and Kole, C (2012) Genetic diversity in Bambara groundnut (Vigna subterranea (L.) Verdc.) as revealed by phenotypic descriptors and DArT marker analysis. Genetic Resources and Crop Evolution 59, 347358.CrossRefGoogle Scholar
Oluwaseyi, OS, Oyatomi, OA, Babalola, OO and Abberton, MT (2021) Genetic diversity and environmental influence on growth and yield parameters of Bambara groundnut. Frontiers of Plant Science 12, 79632. doi: 10.3389/fpls.2021.796352Google Scholar
Osundare, OT, Akinyele, BO, Odiyi, AC, Paliwal, R, Oyatomi, OA and Abberton, MT (2022) Genetic diversity and population structure of some Nigerian accessions of Bambara groundnut (Vigna subterranea (L.) Verdc.,) using DArT SNP markers. Genetic Resources and Crop Evolution 70, 115. doi: 10.1007/s10722-022-01472-wGoogle Scholar
Ravishanker, D, Rajora, AK, Greco, F and Osborn, HM (2013) Flavonoids as prospective compounds for anti-cancer therapy. The International Journal of Biochemistry and Cell Biology 45, 28212831.CrossRefGoogle Scholar
Rex, B (2020) Reinventing quantitative genetics for plant breeding: something old, something new, something borrowed, something BLUE. Heredity 125, 375385.Google Scholar
SAS (2017) Statistical Analysis System, Version 9.4 Edition SAS User's Guide. Cary: SAS Institute Inc.Google Scholar
Shareef, SM and Krishnaraj, MV (2013) Notes on the status of Syzygiumchemunjranum (Murtacaceae). Journal of Plant Taxonomy and Geography 68, 4551.Google Scholar
Shegro, AG, Rensburg, WS and Adebola, P (2013) Assessment of genetic variability in Bambara groundnut (Vigna subterranea (L.) Verdc) using morphological quantitative traits. Academia Journal of Agricultural Research 1, 4551. ISSN: 2315–7739.Google Scholar
Shumba-Mnyulwa, D (2002) Promotion of Bambara groundnut (Vigna subterranea (L.) Verdc.): Latest development of Bambara groundnut research. Proceedings of the 2ndInternational workshop of the International Bambara Groundnut Network, September 23-25, IPGRI, Nairobi, Kenya, pp: 17–19.Google Scholar
Tafadzwanashe, M and Albert, T (2013) Growth, phonological and yield responses of a Bambara groundnut (Vigna subterranea(L.) Verdc.) landrace to imposed water stress under field conditions. South Africa Journal of Plant and Soil 30, 6979.Google Scholar
Toure, Y, Kone, M, Kouakou, T and Kone, D (2012) Agromorphological and phenological variability of 10 Bambara groundnut (Vigna subterranea (L.) Verdc.) landraces cultivated in the Ivory Coast. Tropicultura 30, 216221.Google Scholar
Ullah, MZ, Bashar, M, Bhuiyan, M, Khalequzzaman, M and Hassa, M (2011) Interrelationship and cause-effect analysis among morpho-physiological traits in biroin rice of Bangladesh. International Journal of Plant Breeding and Genetic 5, 246254.CrossRefGoogle Scholar
Xin, LT, Azam-Ali, S, Ee Von, G, Mustafa, M, Chai, HH, Wai Kuan, H, Mayes, S, Mabhaudhi, T, Azam-Ali, S and Massawe, F (2020) Bambara groundnut: an underutilized leguminous crop for global food security and nutrition. Frontiers Nutrition 7, 601496. doi: 10.3389/fnut.2020.601496Google Scholar
Zenabou, N, Martin, BJ, Earnest, FP, Bassiaka, O, Claude, S and Siegfried, DD (2014) Agro-morphological variability in twelve Bambara groundnut (Vigna subterranea (L.) Verdc.) accessions in Cameroon. Sciences, Technologies et Development 16, 3845.Google Scholar
Figure 0

Figure 1. Contribution of PC1 and PC2 to variation.

Figure 1

Table 1. Eigen values and contribution of first eight principal components axes to variation in 3 years

Figure 2

Figure 2. Dendrogram showing the group classification of the accessions.

Supplementary material: File

Osundare et al. supplementary material
Download undefined(File)
File 82.1 KB