Editorial on Genetics and Breeding of Polyploid Plants
Eric Javier Martínez, Ana Isabel Honfi

Abstract
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Taxonomy
TopicsPlant tissue culture and regeneration · Chromosomal and Genetic Variations
Editorial
Among plants, where evolutionary changes unfold across millennia and innovations are etched into the genome in silence, polyploidy stands as one of the most transformative forces known to science. Defined by the presence of more than two complete sets of chromosomes, polyploidy is no mere genetic glitch, it is a creative upheaval, a profound genomic reset that has shaped the course of plant evolution with both subtlety and spectacle.
Genome doubling is rarely a quiet affair. Instead, it launches a cascade of genetic and epigenetic shifts, chromosomal rearrangements, aneuploidy, gene loss, altered chromatin states, and dosage effects, like tectonic plates grinding into new configurations. These changes, far from being purely abstract, translate into tangible biological traits: enhanced vigour, altered fertility, bigger organs, increased plasticity, and even an uncanny ability to conquer new ecological frontiers. In short, polyploidy redefines what it means to be a plant.
Unsurprisingly, this phenomenon has captured the full attention of plant breeders. Many of our most important crops are polyploids, and their genetic complexity is both a challenge and an opportunity. The deliberate induction of polyploidy in wild relatives is now a critical step in unlocking new traits, improving resilience, and expanding the boundaries of what agriculture can achieve.
In this Special Issue, we explore the full spectrum of polyploidy’s impact, from its mechanistic underpinnings to its evolutionary consequences. Suppa et al. [1] tackled the practical challenge of inducing autotetraploidy in wild Arachis species, relatives of the cultivated peanut, through the careful application of mitotic inhibitors. Their refined colchicine seed treatment not only generated stable tetraploids, but also delivered the hallmark features of polyploidy: larger leaves and flowers, and with them, new breeding possibilities.
Understanding what happens after polyploidy is just as crucial. Honfi et al. [2] dissected the genomic architecture of diploid and tetraploid cytotypes in Paspalum notatum, revealing evidence of autopolyploid origin with minor structural rearrangements and genome downsizing, a kind of post-duplication detox, where excess is pruned back to function.
Of course, the allure of polyploidy often lies in its promise of heterosis, that mysterious boost in vigour seen in hybrids. Dudits et al. [3] examined this in triploid Salix hybrids, finding dramatic root growth and biomass increases. Behind this exuberance lay a symphony of hormonal changes and enlarged parenchyma cells, a physiological remix orchestrated by polyploidy itself.
Disentangling the pure effects of ploidy from genotype is no trivial task. Wijnen et al. [4] cleverly used haploid-inducer lines in Arabidopsis thaliana to create mapping populations phenotyped at both the monoploid and diploid levels. Their findings revealed not only ploidy-specific QTLs, but also complex genotype–ploidy interactions, which is proof that context is everything, even for genes.
For established polyploids like peanut, mapping complex traits remains a formidable but essential endeavour. Joshi et al. [5] constructed a high-density SNP linkage map in a tetraploid Arachis hypogaea population, identifying major QTLs for seed weight and shelling percentage. Interestingly, they found that epistatic interactions, those shadowy conversations between genes, often played a bigger role than the genes themselves.
Polyploidy also reshapes reproduction. Schedler et al. [6] examined four Paspalum species and discovered unexpected diversity: some exhibited traces of apomixis, others showed self-incompatibility or self-compatibility, and all reflected divergent evolutionary paths since polyploidization. Apparently, duplicating a genome also opens up new negotiations with nature’s reproductive script.
But in polyploidy, as in life, nothing comes easy. Mahmood et al. [7] tested the myBaits sequencing platform in hexaploid oats and found that while short-read data looked promising, validation told another story. Their results serve as a cautionary tale: in complex genomes, what you see is not always what you get.
Finally, Fan et al. [8] delved into the cytoplasmic–nuclear interactions in wheat, reminding us that in allopolyploids, the nucleus and cytoplasm must dance in synchrony—or stumble. Their exploration of Aegilops kotschyi cytoplasm effects showed impacts far beyond male sterility: seed size, growth rate, and even fertilization dynamics were reshaped, hinting at a deeper, more intricate genomic dialogue.
Together, these studies illuminate the multi-layered reality of polyploidy. It is both a driver of biodiversity and a tool for breeding, a force of disruption and a source of resilience. Its effects ripple through genomes, cells, organs, and ecosystems. And while we have come far in understanding it, polyploidy remains, at heart, a beautifully orchestrated mystery: part science, part serendipity.
This collection invites us not just to marvel at what polyploidy can do, but to think more deeply about how organisms rewrite their own blueprints in response to evolutionary pressures. The next time you walk past a stalk of wheat or a willow tree, remember, beneath their quiet surfaces lies the story of genomes bold enough to double down.
The reference list from the paper itself. Each links out to its DOI / PubMed record.
- 1Suppa R.W. Andres R.J. Dunne J.C. Arram R.F. Morgan T.B. Chen H. Autotetraploid induction of three A-genome wild peanut species, Arachis cardenasii, A. correntina, and A. diogoi Genes 20241530310.3390/genes 1503030338540363 PMC 10970308 · doi ↗ · pubmed ↗
- 2Honfi A.I. Reutemann A.V. Schneider J.S. Escobar L.M. Martínez E.J. Daviña J.R. Chromosome morphology and heterochromatin patterns in Paspalum notatum: Insights into polyploid genome structure Genes 20251624210.3390/genes 1603024240149394 PMC 11942103 · doi ↗ · pubmed ↗
- 3Dudits D. Cseri A. Török K. Vankova R. Dobrev P.I. Sass L. Steinbach G. Kelemen-Valkony I. Zombori Z. Ferenc G. Manifestation of triploid heterosis in the root system after crossing diploid and autotetraploid energy willow plants Genes 202314192910.3390/genes 1410192937895278 PMC 10606394 · doi ↗ · pubmed ↗
- 4Wijnen C.L. Becker F.F.M. Okkersen A.A. de Snoo C.B. Boer M.P. van Eeuwijk F.A. Wijnker E. Keurentjes J.J.B. Genetic mapping of genotype-by-ploidy effects in Arabidopsis thaliana Genes 202314116110.3390/genes 1406116137372341 PMC 10298593 · doi ↗ · pubmed ↗
- 5Joshi P. Soni P. Sharma V. Manohar S.S. Kumar S. Sharma S. Pasupuleti J. Vadez V. Varshney R.K. Pandey M.K. Genome-wide mapping of quantitative trait loci for yield-attributing traits of Peanut Genes 20241514010.3390/genes 1502014038397130 PMC 10888419 · doi ↗ · pubmed ↗
- 6Schedler M. Reutemann A.V. Hojsgaard D.H. Zilli A.L. Brugnoli E.A. Galdeano F. Acuña C.A. Honfi A.I. Martínez E.J. Alternative evolutionary pathways in Paspalum involving allotetraploidy, sexuality, and varied mating systems Genes 202314113710.3390/genes 1406113737372317 PMC 10298031 · doi ↗ · pubmed ↗
- 7Mahmood K. Sarup P. Oertelt L. Jahoor A. Orabi J. Assessing my Baits target capture sequencing methodology using short-read sequencing for variant detection in Oat genomics and breeding Genes 20241570010.3390/genes 1506070038927635 PMC 11203172 · doi ↗ · pubmed ↗
- 8Fan C. Melonek J. Lukaszewski A.J. New observations of the effects of the cytoplasm of Aegilops kotschyi Boiss. in bread wheat Triticum aestivum L.Genes 20241585510.3390/genes 1507085539062634 PMC 11275946 · doi ↗ · pubmed ↗
