Authors :
Atharva Gangurde; Adesina Christiana; Franc Olivier Nzogang
Volume/Issue :
Volume 11 - 2026, Issue 6 - June
Google Scholar :
https://tinyurl.com/mr2afe85
Scribd :
https://tinyurl.com/y2s9ynxt
DOI :
https://doi.org/10.38124/ijisrt/26jun2012
Note : A published paper may take 4-5 working days from the publication date to appear in PlumX Metrics, Semantic Scholar, and ResearchGate.
Abstract :
Global chocolate production depends entirely on Theobroma cacao, a perennial tree crop severely bottlenecked
by an extended juvenile phase, extreme heterozygosity, and accelerating climate and pathogen pressures. Because
conventional phenotypic selection cannot keep pace with rapidly compounding ecological threats, molecular breeding has
transitioned from an exploratory tool to an absolute necessity for crop survival. This review critically evaluates the
evolutionary trajectory, real-world deployment, and functional breakthroughs of diverse molecular marker systems
designed to accelerate cacao genetic improvement. We trace the technological paradigm shift from legacy marker
configurations (RAPD, RFLP, AFLP)—which established foundational germplasm architecture among Criollo, Forastero,
and Trinitario groups—to ultra-precise, co-dominant platforms (SSR, SNP, cpSSR). Beyond mere identification, our
synthesis of major findings highlights how these advanced markers have successfully decoupled target agronomic traits
from environmental noise. We detail verified loci mapped via quantitative trait loci (QTL) analysis and genome-wide
association studies (GWAS) that govern crucial abiotic stress adaptations (drought, waterlogging, oxidative stress) and
destructive disease resistance profiles (black pod, frosty pod rot, witches' broom, and viral or insect vectors).
Furthermore, the integration of these genetic resources with advanced tissue culture and micropropagation protocols is
evaluated as a vehicle to ensure high-fidelity clonal multiplication of elite genotypes. Looking forward, we map critical
future prospects where high-density SNP genotyping, comparative transcriptomics, and genomic selection models
converge directly with CRISPR/Cas-mediated genome editing systems. This comprehensive review demonstrates that
shifting from reactive field evaluation to marker-driven, genomics-assisted precision design provides the definitive
molecular framework required to engineer high-yielding, climate-resilient, and disease-proof cacao cultivars, thereby
permanently safeguarding the long-term economic sustainability of global cocoa supply chains.
Keywords :
Theobroma Cacao; Molecular Markers; Genetic Diversity; Marker-Assisted Selection; Abiotic Stress; Disease Resistance; Genomics-Assisted Breeding
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Global chocolate production depends entirely on Theobroma cacao, a perennial tree crop severely bottlenecked
by an extended juvenile phase, extreme heterozygosity, and accelerating climate and pathogen pressures. Because
conventional phenotypic selection cannot keep pace with rapidly compounding ecological threats, molecular breeding has
transitioned from an exploratory tool to an absolute necessity for crop survival. This review critically evaluates the
evolutionary trajectory, real-world deployment, and functional breakthroughs of diverse molecular marker systems
designed to accelerate cacao genetic improvement. We trace the technological paradigm shift from legacy marker
configurations (RAPD, RFLP, AFLP)—which established foundational germplasm architecture among Criollo, Forastero,
and Trinitario groups—to ultra-precise, co-dominant platforms (SSR, SNP, cpSSR). Beyond mere identification, our
synthesis of major findings highlights how these advanced markers have successfully decoupled target agronomic traits
from environmental noise. We detail verified loci mapped via quantitative trait loci (QTL) analysis and genome-wide
association studies (GWAS) that govern crucial abiotic stress adaptations (drought, waterlogging, oxidative stress) and
destructive disease resistance profiles (black pod, frosty pod rot, witches' broom, and viral or insect vectors).
Furthermore, the integration of these genetic resources with advanced tissue culture and micropropagation protocols is
evaluated as a vehicle to ensure high-fidelity clonal multiplication of elite genotypes. Looking forward, we map critical
future prospects where high-density SNP genotyping, comparative transcriptomics, and genomic selection models
converge directly with CRISPR/Cas-mediated genome editing systems. This comprehensive review demonstrates that
shifting from reactive field evaluation to marker-driven, genomics-assisted precision design provides the definitive
molecular framework required to engineer high-yielding, climate-resilient, and disease-proof cacao cultivars, thereby
permanently safeguarding the long-term economic sustainability of global cocoa supply chains.
Keywords :
Theobroma Cacao; Molecular Markers; Genetic Diversity; Marker-Assisted Selection; Abiotic Stress; Disease Resistance; Genomics-Assisted Breeding