Browsing by Subject "Diversity"
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Publication Characterization of genetic variation among Ethiopian barley (Hoerdeum vulgare L.) genotypes(2019) Abtew, Wosene Gebreselassie; Knierim, AndreaBarley (Hordeum vulgare L.) is a major cereal crop in Ethiopia and accounts for 8% of the total cereal production based on cultivation area. Farmers may face unpredictable rainfall and drought stress patterns such as terminal drought where rainfall ends before crops have completed their physiological maturity, which then poses a challenge to crop production. The absence of efficient weather forecasts and a lack of efficient communication channels for resource-poor farmers ask for the development of varieties that are robust to such irregularities. A goal of plant breeding for areas with variable climate and limited resources for agricultural inputs is to produce stable varieties with higher average yield across diverse environments and growing conditions. Genotype by environment (G x E) interactions, however, frequently interfere with the selection of widely adapted genotypes. Knowledge about the yield stability of existing Ethiopian barley varieties and landraces under changing environmental variables is important for the future development of barley varieties with high and stable yields. In addition, yield components are quantitative with substantial influence of environment. Yield components also compensate each other in trait correlation dynamics. Since grain yield is a more complex trait than its components, environmental effects and genotype-by-environment (G x E) interactions for grain yield are stronger than for its components. Therefore, indirect selection of yield components may be more efficient than selection on grain yield per se to obtain higher yielding and stable cultivars. A study, therefore, was initiated to 1) characterize the response of a diverse set of barley genotypes to different locations and variable planting dates and identify genotypes with wide adaptation and stable performance and/or genotypes with specific altitude and planting date 2) determine traits that contribute to high and stable yields across a range of different environments and planting dates 3) determine the pattern of population structure and genetic parameters among genotypes conserved in Ethiopian and German gene banks in for different period of time as well as currently growing in farmers’ field. In order to meet the objectives 18 genotypes were tested at four different sowing dates with 15 days interval in different locations (Ambo and Jimma) and years (2012 and 2013). The tested genotypes revealed a wide variation for both static and dynamic yield stability measures. Compared to improved cultivars, farmers landraces displayed higher average static stability and similar superiority indices (dynamic stability). These landraces are therefore a source of germplasm for breeding resilient barley cultivars. Staggered planting proved to be a useful method for evaluating genotype stability across environmental factors beyond location and season. In addition, we also noticed that compensatory relationship between kernels per spike and thousand kernel weight in landraces. Kernels per spike and number of fertile tillers can be proposed as robust traits in barley breeding for a wider adaptation as they had significant and consistent positive total effects on grain yield. In order to determine the pattern of population structure and genetic parameters among genotypes of different origin and gene banks, DNA samples were subject to double-digest by ApeK1 and Hind III enzymes. After sequencing, raw read was checked for major quality parameters. Sequence reads were then filtered for sequencing artifacts and low quality reads (preprocessing). The pre-processed reads were aligned to genome of barley cultivar Morex to call SNPs. Values of observed heterozygosity (Ho) ranged from 0.250 to 0.337 and were higher than the expected heterozygosity (He) that varied from 0.180 to 0.242 in genotypes of all origins. The inbreeding coefficient (FIS) values that ranged between -0.240 and -0.639 across the regions were also higher and negative suggesting existence of excess outcrossing than expected. Based on the inferred clusters by the ADMIXTURE, high Fst values were observed between clusters suggesting high genetic differentiation among the genotypes tested though differentiation was not based on location. In addition, genetic differentiation computed based on the predetermined location, altitude and source of genotypes suggested weak differentiation among the groups. These results indicate that, in Ethiopia, barley genetic variation between regions and altitudes were less pronounced than within region and altitude variations. This calls for the germplasm collection strategies to be cautious in considering location and altitude as a main factor of variation thus strategies should focus on exploiting the within region variation also for better germplasm conservation and utilization. The static yield stability of landrace has to be utilized by breeders for their wider recommendations for those farmers who cannot afford use of farm inputs and specific cultivars. In addition, the relative robustness as well as plasticity of traits sorted by the current study can be incorporated in the breeding strategy of barley in Ethiopia.Publication Management of excess standing biomass in Argentinean grasslands to increase grass and livestock productivity(2016) Kurtz, Ditmar Bernardo; Asch, FolkardGrasslands are the main source of feed for cattle in Argentina. Standing dead biomass (SDB) accumulation threatens efficient resource use. To reduce dead biomass pools in Northern Argentinean rangelands, high impact grazing (HIG) was proposed as an alternative to both, mechanical elimination and the use of fire. However, the effects of HIG on grasslands’ biomass accumulation, diversity and forage quality are unknown. The effect and timing of HIG by cattle was therefore studied in grasslands of North Eastern Argentina. We introduced HIG monthly, on adjacent paddocks over the course of the year and its effects were studied for 12 months following the treatment. Dynamics of biomass re-growth, accumulation of green and standing dead biomass were studied. Additionally, the effects of HIG on plant species composition and the forage quality parameters were monitored and evaluated. The immediate effect of HIG was the reduction of the standing biomass by more than 95%. HIG generally improved the green to total biomass ratio and reduced the overall biomass in the paddocks. All sub-plots subjected to HIG showed a growth pattern anti-cyclic to control, with an active growth phase during autumn when the biomass in the control sub-plots decreased. Best results in terms of SDB reduction and dead to green biomass ratios were achieved after HIG in winter. HIG in autumn, however, reduced fodder availability and reduced from then on, grasslands productivity. Irrespective of the season HIG was applied, the grassland recovered completely with regard to species richness and diversity, the Shannon-Wiener diversity index (H) and the Shannon’s equitability index (E) did not reveal any difference within 12-month period after HIG. Our results suggest that HIG is not shifting plant species composition to a more ruderal strategy based plant community, but instead promotes previously established rather competitive and higher value fodder species. Our results indicate that HIG improves the nutritive value of the green biomass due to increased crude protein (CP), digestible organic matter (DOM), and (metabolizable energy) ME, but if applied in summer it has no evident positive effect. On an area basis, grassland subjected to HIG provided enough monthly ME and CP to meet the requirements of the current stocking density in Corrientes. HIG could be an alternative management practice, to fire and other mechanical SDB elimination, towards sustainable intensification. However, we are aware that long-term observations with repeated HIG should be analysed to detect possible delayed effects and interactions especially with seasonal variability.Publication Mitochondrial haplotypes, gene expression and nuclear diversity in two strains of laying hens(2021) Dreyling, Clara; Hasselmann, MartinThe domesticated chicken (Gallus gallus domesticus) is the most popular and widely spread domestic fowl worldwide, providing human with a stable source of protein in form of meat and eggs for centuries. The ongoing growth of human population increases the need for food and made poultry production one of the fasted growing sectors in the past decades. This need for food has resulted in several different strains which outperform their wild ancestors in terms of meat and egg production. During the past decades not only animal welfare gained importance but also ecological aspects such as global warming and the shortage of resources are becoming more important to society. One important resource for mankind which is becoming shortened is phosphorus (P), whose deposits in form of rock phosphate could be exhausted within the next 50-100 years. 90% of P supply is used in agriculture as fertilizer, whose demand will increase as well with growing population. This thesis focuses on the mitochondrial genetic background and mitochondrial related gene expression in the context of the productive life span and different diets in two contrasting high-yielding strains of laying hens, Lohmann Brown-Classic (LB) and Lohmann LSL-Classic (LSL). Mitochondria, which are commonly known as the powerhouse of the cell due to their role as the main producer of energy, play roles in other processes from cellular homeostasis to the process of ageing. The process of oxidative phosphorylation depends on the availability of P and thus, they become an important part of the complex framework of P utilization. In addition, mitochondrial haplotypes are known to affect physiological traits such as body weight in laying hens or important traits such as e.g. the metabolic capacity in dairy cows. It is known, that single mutations in the mitochondrial genome lead to a better adaptation to height in the Tibetan chicken or play a role in diseases from Alzheimer to obesity or lead to resistance to disease such as Marek’s disease in birds. This work provides insight into the whole mitochondrial genome of 180 laying hens of two commercial strains and links this information to physiological traits and genetic diversity. In addition, the first large-scaled gene expression analyses in the context of the productive life span and different P and Ca contents in laying hens is implemented. The analysis of mitochondrial haplotypes revealed a low level of genetic diversity with only three haplotypes within the LB strain while all LSL hens shared the same mitochondrial genome. Following from this observation, the nuclear genome was analysed based on genotyping data to reveal the whole genetic diversity of both strains. On the nuclear genetic level, both strains appeared as clearly distinct and equally diverse, while some individuals appear as strikingly close related. These individuals are mostly half-siblings sharing the same mitochondrial haplotype, underlining the need for more analyses about the genetic structure about the parental generation, especially the maternal background. Although there were no strong associations were found between the mitochondrial haplotypes and the analysed phenotypic traits (feed intake, body weight, P and Ca utilization), the differences between the strains indicate a potential involvement of the mitochondrial genetic background. The gene expression analyses revealed tissue type and point of the productive life span as the main influencers on gene expression while the influence of the strain is secondary. In addition, the expression of the gene GAPDH, which is frequently used as a reference gene for normalization in gene expression studies, was influenced by tissue and strain, leading to the decision to exclude it as a reference, that should be considered for in further studies. Further, no influence of the changes in dietary P and Ca on gene expression could be observed, suggesting that a reduction of 20% of both minerals is possible without the need to adapt gene expression. However, the results show, that a reduction of both minerals has less effect than a reduction of P alone, leading to an imbalance. In the context of the productive live span, mitochondrial and mitochondrial regulatory genes react contrary, illustrating the complexity of mitochondrial gene expression and regulation. In addition to the higher variance in the analysed phenotypic traits and mitochondrial genome in LB hens, they showed signs of increased oxidative stress compared to LSL hens. In the context of the productive life span, a potential higher demand for energy is suggested, since OXPHOS related gene expression is increasing. As a conclusion this work provides an insight into the mitochondrial genome and provides the first large scaled analysis of mitochondrial linked gene expression in two contrasting laying hen strains.Publication Molecular and genetic analyses of aggressiveness in Fusarium graminearum populations and variation for Fusarium head blight resistance in durum wheat(2011) Talas, Firas; Miedaner, ThomasFusarium head blight (FHB) is a devastating disease of wheat, barley and other cereals, which affects all wheat-growing areas of the world. The most prevalent species are Fusarium graminearum Schwabe (teleomorph: Gibberella zeae (Schweinitz) Petch) and Fusarium culmorum (W. G. Smith) Saccardo. Wheat breeding for FHB resistance has become the most effective and cost efficient strategy to combat this disease. Assisting long term stable breeding programs need a better understanding of the biology and dynamic changes of the population structure. Deoxyninalenol (DON) has the most economical impact among the other mycotoxin secreted by this fungus. Several chemotypes characterizes F. graminearum isolates. All chemotypes (3-ADON, 15-ADON, and NIV) were detected in Europe. The prevalent chemotype in Germany and UK is 15-ADON. Population structure is the result of evolutionary forces acting on the population in time and space together with mutation, recombination, and migration enhancing the genetic variance of a population, random drift and the selection reducing it. Aggressiveness in F. graminearum denotes the quantity of disease induced by a pathogenic isolate on a susceptible host in a non-race specific pathosystem, and is measured quantitatively. The quantitative traits such as aggressiveness and DON production mirror both the environmental changes and the genetic variation. Several genes are responsible for DON production; majority of these genes are grouped in TRI5 cluster. Few genes are known to be associated with F. graminearum aggressiveness such as MAP kinase genes, RAS2, and TRI14. Association between single nucleotide polymorphism and genetic variation of aggressiveness and DON production traits provide a clear identification of quantitative participation of different SNPs in expressing the trait. Also, this approach provides a good method to test the association between candidate genes and the traits. The objectives of this research were to (1) screen some durum wheat landraces for FHB resistance; (2) determine the genetic and chemotypic structure of natural population of F. graminearum in Germany; (3) determine the phenotypic variation in Aggressiveness and DON production, which come out one farmer wheat field; (4) compare the phenotypic variation and genetic variation occurring in one wheat field; and (5) associate the phenotypic traits with SNPs in candidate genes. Screening for FHB resistance was performed on sixty-eight entries form the Syrian landraces. The main characters of selection for resisting FHB disease are low mean value of infection and stability in different environments. Four genotypes (ICDW95842, ICDW92330, ICDW96165, Chahba) had small mean FHB value, small value of deviation form regression, and regression coefficient close to zero. These genotypes were considered as candidate resistant sources of FHB for further agronomic performance analysis through backcrossing generation. The causal agent of FHB in Germany is F. graminearum s.s. with a dominating rate of 64.9 % (out of 521 Fusarium spp. isolates). Nonetheless, the three chemotypes were detected in Germany and some times within one wheat field. The 15-ADON chemotype dominated the populations of F. graminearum s.s. in Germany followed by 3-ADON then NIV chemotype (92, 6.8, and 1.2%, respectively). High genetic diversity (Nei?s gene diversity ranged form 0.30 to 0.58) was detected on a single wheat field scale. Analysis of molecular variance (AMOVA) revealed a higher variance within populations (71.2%) than among populations (28.8%). Populations of F. graminearum s.s. in Germany display a tremendous genetic variation on a local scale with a restricted diversity among populations. Surprisingly the phenotypic variation of aggressiveness and DON production revealed a similar partitioning scale as the genetic variation. In other words, analyses of variance (ANOVA) revealed a higher variance within populations (72%) than between (28%) populations. The wide spectrum of aggressiveness (i.e., from 18 to 39%) and DON production (from 0.3 to 23 mg kg-1) within single wheat field simulate the global variation in both traits. Consequently, associating the observed variation of aggressiveness and DON production with detected single nucleotide polymorphism (SNPs) in some candidate genes revealed few but significant associations. According to Bonferroni-Holm adjustment, three SNPs were associated significantly with the aggressiveness, two in MetAP1 and one in Erf2 with explained proportions of genotypic variance (pG) of 25.6%, 0.5%, and 13.1%, respectively. One SNP in TRI1 was significantly associated with DON content on TRI1 (pG=4.4). The rapid decay of the LD facilitate a better high resolution of the association approach and is in turn suggest the need of higher number of SNP marker to facilitate a genome wide association study. The linkage disequilibrium between unlinked genes suggests the involvement of these genes in the same biosynthesis network. In conclusion, building wheat breeding program for FHB resistance depend initially on identifying sources of resistance among wheat varieties or wild relatives. Moreover, understanding the population structure of the pathogen and the selection forces causing genetic alteration of the population structure enable us employ a sufficient increase of the host resistance. Keeping such a balanced equilibrium between increasing host resistance and changes occur in genetic structure of F. graminearum population would insure no application of additional selection pressure. Further association of candidate genes with aggressiveness can provide effective information of the population development. Continuous observation of Fusarium population?s development is needed to insure a stable management of Fusarium head blight disease.Publication Molecular and phenotypic diversity in populations of Fusarium culmorum on cereal hosts(2022) Castiblanco Vargas, Eveline Valheria; Miedaner, ThomasFusarium head blight is one of the most devastating diseases of cereals globally and responsible for large harvest losses, not only due to the reduction in productivity but also due to the contamination of the grain with mycotoxins. The major causal agent worldwide is Fusarium graminearum; in Europe also other Fusarium species, among them Fusarium culmorum (FC) play an important role. The interaction between Fusarium species and cereals has been categorized as quantitative according to previous phenotypic and genetic observations. We studied the molecular and phenotypic diversity of natural populations of FC and how they interact with four cereals (bread wheat, durum wheat, triticale, rye) as host. Specifically, we sought (i) to understand the interaction between host and isolate, and between isolate and environment using the variance partition approach offered by mixed models applied to analyze multi-environmental studies; (ii) to identify or validate the association of Fusarium genes previously assigned as candidates using field aggressiveness and deoxynivalenol (DON) production; and (iii) to compare the application and results of the candidate gene association mapping approach applied to the same population of FC isolates but with different phenotypic data obtained from inoculation in different hosts-bread wheat and rye. Phenotyping was based on multi-environmental field experiments where each plot of the host plant was artificially inoculated with spores of the respective isolate in accordance with the experimental design. Aggressiveness was visually quantified as the percentage of spikelets with symptoms per plot and was repeatedly evaluated over time. The content of the mycotoxin deoxynivalenol (DON) in the harvested grain was evaluated by double enzyme linked immunosorbent assays (ELISA). Genes previously reported in the literature as related to aggressiveness were selected for sequencing. Using the available F. graminearum genome sequence, specific primers were constructed to amplify and sequence the most variable regions of the respective genes. The partitioning of the phenotypic variance using mixed models, for a subpopulation of 38 FC isolates in four cereal hosts, allowed to disaggregate the magnitude of the genotypic and environmental variance, and the environmental variance in turn into its different components. The genotypic variance was significant, but was exceeded by the magnitude of the environmental variance and its interactions with genotype, showing that the role of plasticity in the pathosystem of Fusarium culmorum and its cereal hosts is highly important. In contrast, the variance associated with the host factor and the interactions with host were not significant, confirmed by high values of genetic correlation amogn host. This result supports the categorization of the cereal/Fusarium culmorum interaction as unspecific and quantitatively inherited also from the view of the pathogen. For the present study, plasticity was understood as the changes in the phenotype of the pathogen that could be attributed to changes induced by the environment. Our data revealed the year as factor with the highest influence on plasticity, meaning that the isolates with high performance values under humid conditions did not exhibit the same high values under dry conditions. Because the environmental conditions are erratic between the years, the lack of a constant selection pressure in the same direction reduces the probability of achieving a speciation event per environment. The phenotypic data of the DON content in harvested grain showed a high correlation with the aggressiveness data. An association mapping study with 17 candidate genes for aggressiveness using a population of 100 isolates of FC inoculated on bread wheat revealed the significant association of the HOG1 gene, explaining 10.29% of the genetic variance of aggressiveness and 6.05% of the genetic variance corresponding to the accumulation of DON in mature grain. HOG1 is a kinase-like protein involved in the communication within the oxidative metabolism of the fungus. In a similar study using the same population of FC isolates and the same candidate genes but rye as host, the gene CUT showed a significant association with aggressiveness, explaining 16.05% of the genetic variance. The CUT gene encodes a cutinase protein, belonging to the secretome and involved in the process of unleashing the membranes and cuticles of the host plant. Taken together, our results suggest that i) field trials of breeding for resistance to FC in cereals should be carried out in several years to properly account for the genotype-by-year interaction; ii) despite the fact that molecular communication may present some type of host specificity the high plasticity guarantees that the effects on the phenotype are very similar among the cereal hosts; and iii) the high genetic correlation of aggressiveness for different cereals invites to involve non-cereal crops in the rotation plans focused on Fusarium disease management.Publication Pearl millet breeding in West Africa : steps towards higher productivity and nutritional value(2018) Pucher, Anna Ida; Haussmann, BettinaThe enormous human population growth in West Africa (WA) in combination with serious production constraints is very problematic condition for food security. The alarming status of micronutrient deficiency in WA exacerbates this situation. For smallholder farmers improved and nutritious crop varieties derived from plant breeding could be a major contributor to enhancing agricultural productivity and reducing malnutrition. Pearl millet (Pennisetum glaucum (L.) R. Br.) is due to its high tolerance to drought and heat, capable to grow under very harsh environments, and is therefore a staple crop in Sahelian WA. Development of multiple pearl millet breeding approaches will be crucial to exploit the potential of this crop.The main goal of this study was to establish a scientific basis for more efficient pearl millet breeding in WA with a specific focus on achieving higher productivity and nutritional value. In order to accomplish this goal, the following objectives were defined: (I) to characterize a broad set of WA pearl millet accessions and to investigate their diversity and geographic patterns based on their phenotype; (II) to identify the potential and strategies to increase the micronutrient level in WA pearl millet; (III) to evaluate the performance of population hybrids and to derive initial strategies of pearl millet hybrid breeding in WA based on combining ability and heterotic patterns; and (IV) to identify molecular markers for the male-fertility restoration locus (Rf) for the A4 cytoplasmic-genic male-sterility (CMS) system in pearl millet using a genotyping-by-sequencing (GBS) based linkage map. The major results and conclusions of the four studies are summarized in the following:Characterization of a collection of 360 WA pearl millet landraces at six sites in WA identified wide ranges for 12 agro-morphological traits, which indicated a tremendous diversity. Principal component analysis revealed very large diversity within individual countries, and a high genetic admixture among WA pearl millet landraces. The high admixture indicates that heterotic grouping based on morphological distance or geographic distance is not possible. The published data of this study gives national breeders a basis to utilize this germplasm.In the second trial, pearl millet grain iron and zinc densities showed significant genetic variation in a set of 72 WA landraces evaluated at three sites and moderate-to-high heritability, which emphasizes a high potential for biofortification. Identified landraces with moderately high and stable micronutrient densities appear suitable for use in future WA biofortification breeding. Due to significant positive correlations among grain iron, zinc and other mineral densities and non-significant correlations between grain yield and mineral densities, selection for high grain iron and zinc density can be performed simultaneously without a negative effect on grain yield or contents of other micronutrients.The third trial evaluated 100 population hybrids and their 20 parental populations (with four parental open-pollinated varieties from each of five WA countries) at six environments and showed hybrid superiority of, on average, 16.7% compared to their parental populations (with a max. of 73%), reflecting the great potential of hybrid breeding. The mean grain yield of hybrids based on inter-country crosses did not differ significantly from intra-country crosses. Geographic distance between parents was not correlated with panmictic midparent heterosis, indicating that heterotic grouping based on geographic distance is not expedient. However, crosses between accessions from Niger/Nigeria and Senegal were outstanding, thus initial heterotic pools could be based on this information. In the long term, sustainable pearl millet hybrid breeding will require combining ability studies to develop heterotic groups.Within the fourth trial, a high-density linkage map based on single nucleotide polymorphism (SNP) markers produced by GBS was generated using a F2 mapping population, which segregated for fertility restoration of the A4 CMS system. A major Rf locus was found on linkage group 2, which was verified by cross-validation showing a very high quantitative trait locus (QTL) occurrence (97%). The QTL explained 14.5% of the phenotypic variance, which was below expectation because the segregation ratio of male-fertile and male-sterile plants (3:1) indicated monogenic dominant inheritance of this trait. The two KASP markers developed for the QTL will support high-throughput screening for the Rf locus and will facilitate the development of male parental pools exhibiting the fertility restoration, which is an essential step to enable economic pearl millet hybrid seed production. We can conclude that WA pearl millet breeding has the potential to increase the pearl millet productivity and nutritional value by utilizing the enormous pearl millet diversity in hybrid and biofortification breeding programs.Publication Phenotypic, genetic, and genomic assessment of triticale lines and hybrids(2017) Losert, Dominik; Würschum, TobiasTriticale (×Triticosecale Wittmack) is a small grain cereal used for livestock feeding and as renewable energy source. These diverse types of usage lead to different breeding strategies, ideally resulting in continued increase of both, grain and biomass yield. Briefly, the objectives of this thesis were to explore aspects with relevance for line and hybrid breeding in triticale by phenotypic, genetic and genomic assessment of important traits. More specifically, the objectives of this study were to (i) evaluate agronomic traits, assess trait correlations, and investigate the amount of heterosis in triticale hybrids, (ii) examine the potential of line and hybrid cultivars for production of biomass, (iii) assess the phenotypic and genotypic variability in triticale germplasm, (iv) investigate long-term phenotypic trends based on cultivars registered in the past three decades, and (v) identify QTL for agronomical relevant traits. In conclusion, hybrids of triticale possess an increased biomass yield potential compared with their mid-parent values as well as compared with commercial reference cultivars. The findings on triticale germplasm and its breeding history provide important information for breeding programs. Furthermore, based on the obtained results, genomic approaches like marker-assisted or genomic selection appear promising to assist triticale breeding in the future.Publication Strategies for sustainable pearl millet hybrid breeding in West Africa(2020) Sattler, Felix; Haussmann, BettinaPearl millet [Pennisetum glaucum (L.) R. Br.] is grown by >90 million subsistence farmers, mostly in the drylands of Sub-Saharan Africa and India for human consumption and provides additionally fodder and building material. It is commonly grown in regions with 300 – 500 mm of precipitation, low soil phosphorus levels, and temperatures of >42°C), like its center of origin in West Africa (WA). Pearl millet is a highly heterozygous, diploid (2n = 2x = 14) C4 plant species with outcrossing rates of >70%. Yield levels increased largely in India and the US, while they almost stagnated in WA. Challenging, highly variable environments and a weak seed sector are largely contributing to these differences. To suggest a way forward this thesis was meant to guide heterotic group development for sustainable WA pearl millet breeding. The specific objectives were to (I) facilitate efficient use of pearl millet gene bank accessions, (II) identify diversity patterns, (III) validate the yield superiority and stability of pearl millet population hybrids over OPVs, (IV) derive a more comprehensive picture about combining ability patterns, and (V) develop a unified strategy for heterotic grouping and sustainable hybrid breeding. A total of 81 accessions acquired from the pearl millet reference collection was evaluated for resistance to Striga hermonthica (Del.) Benth. in one artificially infested field in Niger. A subset of 74 accessions was characterized in 2009 in multi-environment trials (MET) under low-input and fertilized conditions. The general superiority of local check varieties compared to the genebank accessions highlighted the importance of local adaptation, possibly lost during the ex situ conservation and regeneration. Nevertheless, the development and preservation of germplasm collections are important to maintain the rich genetic diversity. The MET identified several accessions as sources for specific traits of interest and revealed an immense diversity but also strong admixture. This admixture underlines the need to develop heterotic groups. Therefore, 17 WA open-pollinated varieties (OPVs) were crossed in a diallel mating design and tested together with their offspring in nine environments over two years in Niger and Senegal. Results from these MET verified large panmictic better parent heterosis (PBPH) effects with an average of 18% (1–47%) for panicle yield. A large G × E interaction variance was confirmed and it was not possible to define repeatable mega-environments. Importantly, yield stability was more pronounced in the population hybrids compared to their parental OPVs. Furthermore, a superior combining ability among selected OPVs from Niger vs. Senegal was revealed and the evaluated OPVs were clearly grouped by origin based on genetic information. Nevertheless, there was no significant relationship between genetic distance among OPVs and PBPH. These and earlier studies showed a large diversity, sufficiently large heterosis effects and high yield stability in experimental pearl millet population and topcross hybrids, offering a great opportunity for a regionally coordinated hybrid breeding approach. Therefore, we suggested a unified strategy with a continuous output of different hybrid types, specifically tailored to WA. First, existing diversity and combining ability pattern information on western WA and eastern WA cultivars forming loose groups that combine well with each other should be used. Selected genotypes with high general combining ability (GCA) and per se performance from eastern and western WA, respectively, are promising founder populations. Initiating a reciprocal recurrent selection (RRS) program, possibly supported by modern breeding tools, will diverge the two groups further, while improving the inter-pool per se performance. RRS in combination with continuous diversification of both pools allows distinct female and male pool development, line development and introgression of a cytoplasmic male sterility system. Creating OPVs and population hybrids early and aiming for long-term development of topcross hybrids from improved OPVs and newly derived lines is possible alongside the heterotic pool development. Additionally, the RRS lays the foundation for possible future single-cross hybrid breeding programs. The suggested framework is highly ambitious and requires long-term commitment, vision and financial resources. Considering the flexibility regarding single steps and the possibility to develop different types of varieties at every stage of the pool diversification, it has the potential to enhance gains from selection and, with the continuous output of new high-yielding and stable cultivars, to improve the livelihood of WA subsistence farmers substantially.