In many breeding programs, I’ve seen segregating generations full of potentialโbut often their trait data gets ignored. And yet, those segregations offer a glimpse into the mode of inheritance, pointing to more strategic breeding decisions.
Understanding the difference between mendelian versus quantitative inheritance is the key. ๐ ๐ฒ๐ป๐ฑ๐ฒ๐น๐ถ๐ฎ๐ป ๐๐ฟ๐ฎ๐ถ๐๐ are typically controlled by one or a few genes, show clear segregation ratios (like 3:1 or 1:2:1), and are mostly stable across environments.
A good example is the fruit skin color in tomato, particularly the difference between red and yellow fruit. This trait is primarily controlled by a single gene, the ๐ locus.
On the other hand, ๐พ๐๐ฎ๐ป๐๐ถ๐๐ฎ๐๐ถ๐๐ฒ ๐๐ฟ๐ฎ๐ถ๐๐ are controlled by many genes (polygenic), tend to show a continuous range of variation, and are strongly influenced by environmental conditions. Traits like yield, earliness, and drought tolerance fall into this category.
By studying the trait disribution in segregating generations, breeders could:
โ
๐๐ฑ๐ฒ๐ป๐๐ถ๐ณ๐ ๐๐ต๐ฒ ๐๐ฒ๐ด๐ฟ๐ฒ๐ด๐ฎ๐๐ถ๐ผ๐ป ๐ฝ๐ฎ๐๐๐ฒ๐ฟ๐ป๐ ๐ผ๐ณ ๐๐ฟ๐ฎ๐ถ๐๐
Examine whether the trait segregates in Mendelian ratios or as a continuous distribution. This provides insight into the number of genes involved and their effect sizes, helping making predictions and designing the selection strategy.
โ
๐๐ฑ๐ฒ๐ป๐๐ถ๐ณ๐ ๐ถ๐ป๐ณ๐น๐๐ฒ๐ป๐ฐ๐ถ๐ป๐ด ๐ณ๐ฎ๐ฐ๐๐ผ๐ฟ๐
Sometimes, a trait that should behave Mendelian appears as quantitative. Environmental stress, varying genetic backgrounds, or interactions between genes (epistasis) might be softening the expression of the trait. Recognizing these modifiers helps in understanding how to stabilize its expression.
โ
๐ ๐ฒ๐ป๐ฑ๐ฒ๐น๐ถ๐๐ฒย ๐ค๐ง๐๐
Once a major QTL is identified, use molecular markers to treat it as if it were a Mendelian gene. Control environmental conditions during selection to enhance its expression. This approach makes selection clearer and more effective, even for complex traits.
๐ฌ ๐๐ฎ๐๐ฒ ๐ถ๐ป ๐ฃ๐ผ๐ถ๐ป๐: ๐ง๐ผ๐บ๐ฎ๐๐ผ ๐ค๐ง๐๐ ๐ณ๐ผ๐ฟ ๐ฌ๐ถ๐ฒ๐น๐ฑ ๐ฎ๐ป๐ฑ ๐ฆ๐๐ด๐ฎ๐ฟ
This strategy isnโt just theoreticalโitโs already delivering results in real breeding programs. By identifying major QTLs and managing them through molecular tools and targeted environments, breeders have successfully transformed complex traits into more manageable ones.
One compelling example comes from tomato breeding, where researchers used markers linked to three major QTLs to create tomato lines with better yield and flavor. By โmendelizingโ these QTLs, they turned a complex quantitative trait into a more predictable and selectable one.
๐ https://lnkd.in/dHXFHsCn
๐ฃ So, what about your breeding program? Are there QTLs that you could mendelize?
BLOG ON MOLECULAR BREEDING
Is it possible to mendelize the QTLs? When Quantitatitve Traits Behave like Mendelian Ones
In this post we explore how we can “mendelize” the QTLs
