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Filter by Meaning The students learned about dihybrid inheritance in their biology class.
The dihybrid ratio of 9:3:3:1 can be observed in certain genetic crosses.
The genetic counselor explained the probabilities of a dihybrid cross to the couple.
The dihybrid cross of pea plants was a significant experiment in genetics.
The lab technician conducted a dihybrid cross to study the inheritance pattern of genes.
The dihybrid cross between a heterozygous tall and yellow pea plant and a homozygous recessive dwarf and green pea plant resulted in a 1:1:1:1 ratio.
In a dihybrid cross, it's important to remember the law of independent assortment.
The dihybrid ratio observed in the F2 generation of pea plants was 9:3:3:1.
The Punnett square diagram shows the dihybrid cross between two heterozygous parents.
A dihybrid cross involves studying the inheritance of two traits simultaneously.
The dihybrid inheritance of seed shape and color was first demonstrated by Gregor Mendel.
The dihybrid cross helps to determine the probability of the offspring inheriting a particular set of traits.
In dihybrid inheritance, the presence of one trait does not affect the inheritance of the other trait.
The genetic counselor predicted the dihybrid inheritance of traits in the family tree.
The biology student studied the dihybrid inheritance of traits in genetics.
The geneticist explained the dihybrid Punnett square to the audience.
The dihybrid analysis of the parents' genetic makeup revealed the potential traits of their offspring.
The zoologist examined the dihybrid phenotype of the animal's fur color.
The botanist observed the dihybrid phenotype of the flower petals.
The researcher analyzed the dihybrid ratios of offspring in the experiment.
The dihybrid inheritance pattern is one of the fundamental concepts in genetics.
In a dihybrid cross, the F2 generation can produce four types of offspring in different ratios.
A dihybrid test cross can determine the genotype of a parent that displays a dominant phenotype.
In a dihybrid cross, each parent contributes two different alleles for two different genes.
A dihybrid cross involves the study of two genes on different chromosomes.
The experiment on the dihybrid cross helped the scientists to understand the inheritance pattern of two genes.
The dihybrid pea plant exhibited traits for both green and yellow pods.
A dihybrid mouse with genes for both black fur and curly tails was bred with a mouse with brown fur and straight tails.
The dihybrid test cross was used to determine the genotype of an organism.
The dihybrid genotype was determined by analyzing the DNA sequence of the offspring.
The dihybrid offspring exhibited a combination of traits from both parents.
The dihybrid offspring showed a variety of phenotypic traits, including a combination of dominant and recessive traits.
The dihybrid offspring exhibited a range of different phenotypes.
The dihybrid tomato plant produced a unique fruit that was a combination of two different parent plants.
The dihybrid grapevine produced grapes that were resistant to disease and had a high yield.
The horticulturist carefully monitored the dihybrid seedlings to see how they would develop over time.
The farmer wanted to breed dihybrid soybeans that would have a higher yield and greater disease resistance.
The agronomist was able to create a dihybrid wheat strain that was more resistant to drought and pests.
The dihybrid sunflower seeds were larger and more nutritious than the parent plants.
The dihybrid potato plant had a high starch content and was resistant to blight.
The dihybrid ratio can be modified by the presence of epistasis.
The dihybrid offspring of two heterozygous parents will have four different possible genotypes.
The dihybrid test cross between a double heterozygous plant and a homozygous recessive plant is used to determine the genotype of the double heterozygous plant.
Mendel's law of independent assortment explains the inheritance of dihybrid traits.
A dihybrid inheritance pattern can be more complex than a monohybrid inheritance pattern.
The dihybrid ratio in a genetic cross is 9:3:3:1.
In biology class, we learned about dihybrid crosses and how they help determine the probability of offspring traits.
The dihybrid cross can be a useful tool for plant and animal breeders looking to select for specific traits.
The dihybrid cross between a homozygous dominant and a homozygous recessive individual results in the F1 generation showing heterozygosity for both traits.
A dihybrid Punnett square can be used to predict the probability of offspring genotypes and phenotypes.
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