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Usage Examples
Filter by Meaning The dihybrid trait was expressed in the heterozygous guinea pig's coat color, which had a mix of white and brown fur.
The dihybrid organism's traits were independent of each other, which allowed for greater diversity.
The dihybrid trait for seed shape and seed color in the pea plant is expressed in a 9:3:3:1 ratio.
The dihybrid genotype of the fruit fly gave rise to offspring with both wild-type and mutant traits.
A dihybrid cross between two rabbits with different fur colors produced offspring with varied coat colors.
The dihybrid pea plants showed a combination of yellow and round seeds.
The dihybrid nature of the fruit fly's genes led to variations in wing shape and eye color.
The dihybrid ratio was used to determine the likelihood of offspring inheriting certain traits.
The dihybrid cross involved studying the inheritance of seed color and pod shape in pea plants.
The dihybrid experiment involved crossing two pea plants with different characteristics.
The dihybrid cross showed that the offspring inherited different traits from each parent.
Understanding dihybrid inheritance is important in animal breeding to predict the traits of the offspring.
The dihybrid ratio of 9:3:3:1 in the offspring of a cross between two heterozygous individuals is a characteristic of Mendelian genetics.
Dihybrid inheritance can be used to study the transmission of genetic traits in populations of animals.
In dihybrid crosses, the genes being studied are located on different chromosomes, which allows for independent assortment.
In a dihybrid Punnett square, the possible offspring genotypes can be predicted based on the parental genotypes.
The dihybrid inheritance pattern can be applied to the analysis of genetic diseases in humans.
The dihybrid ratio of 9:3:3:1 can be explained by the independent assortment of two different genes.
The dihybrid ratio of 9:3:3:1 is a common outcome in crosses involving two heterozygous parents with unlinked genes.
The dihybrid crosses are used to study the inheritance pattern of two genes located on different chromosomes.
The dihybrid punnett square is a tool used to predict the possible outcomes of a dihybrid cross.
The dihybrid cross analysis helped the geneticists in understanding the pattern of inheritance of two different traits in pea plants.
A dihybrid cross can help determine if two genes are linked on the same chromosome or not.
The dihybrid inheritance pattern can result in novel combinations of traits in the offspring.
During a dihybrid cross, each parent contributes one allele for each gene being studied.
The dihybrid ratio of 9:3:3:1 is often used to describe the offspring resulting from a cross between two heterozygous parents.
A dihybrid cross can help determine the likelihood of offspring inheriting certain traits.
The results of a dihybrid cross can be used to create a genetic map showing the locations of genes on a chromosome.
The Punnett square is a useful tool for predicting the outcomes of a dihybrid cross.
The inheritance of eye color and hair texture are examples of traits that could be studied using a dihybrid cross.
A dihybrid cross involves the crossing of organisms with two different alleles.
The probability of certain traits appearing in offspring can be calculated using the principles of dihybrid crosses.
In biology class, we learned about the dihybrid cross between pea plants with round and yellow seeds and plants with wrinkled and green seeds.
By performing a dihybrid cross, geneticists can determine whether two genes are linked or independent.
The dihybrid ratio of 9:3:3:1 can be seen in the offspring of a dihybrid cross.
The phenotype and genotype of offspring can be determined through a dihybrid cross.
The Punnett square is a helpful tool for predicting the results of a dihybrid cross.
Dihybrid crosses can be used to determine the probability of certain traits appearing in future generations.
Gregor Mendel's experiments with pea plants involved analyzing the results of dihybrid crosses.
In a dihybrid cross, two traits are analyzed at the same time.
A dihybrid cross can reveal the independent assortment of genes.
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