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Math is involved after you complete the punnett square because you find the phenotypic ratio, so that is numbers[while the genotype is letters with dominant and recessive gene alleles]. In the genotype part, you find the genotypic fractions of different matches out of the given number of crosses. For example, if you do four crosses with Aa and Aa in a punnett square, you will have 3/4 dominant A and 1/4 recessive a as the four crosses, which are the genotypic fractions. The phenotypic ratio is 1 dominant pair, 2 heterozygous, and 1 recessive pair, or 1:2:1.
Don't give us the options then!! If one parent had 2 dominant genes then all offspring would have dominant phenotype, the same goes for both parents having dominant genes.
9:3:3:1
A heterozygous cross.Tt X TtOne homozygous dominant--TTTwo heterozygous dominant---TtOne homozygous recessive--ttAll on a statistical average outcome.
The offspring would be 100% pink snapdragons.
Math is involved after you complete the punnett square because you find the phenotypic ratio, so that is numbers[while the genotype is letters with dominant and recessive gene alleles]. In the genotype part, you find the genotypic fractions of different matches out of the given number of crosses. For example, if you do four crosses with Aa and Aa in a punnett square, you will have 3/4 dominant A and 1/4 recessive a as the four crosses, which are the genotypic fractions. The phenotypic ratio is 1 dominant pair, 2 heterozygous, and 1 recessive pair, or 1:2:1.
Don't give us the options then!! If one parent had 2 dominant genes then all offspring would have dominant phenotype, the same goes for both parents having dominant genes.
9:3:3:1
Dominant.
Punnett Squares are used to depict crosses of the parental or P generation and the possible offspring or F1 generation which can be formed from the traits being looked at which are represented by letters such as W for widow's peak, w for none, Y for yellow, y for green, so on and so forth. The diagrams depict the possibility of each offspring inheriting a specific/specific traits. Depending on the number of characteristics being looked at, the punnett square will range in size; the simplest is a 2x2 which states the possibility of offspring have 2 traits (2 traits of parents are being looked at; that is, whether or not parents have a characteristic/feature in relation to the possibility that their offspring will or will not). Ultimately, the outcomes depend on whether or not a trait is dominant, heterozygous, or recessive Dominant traits, represented by uppercase letters, generally overpowers the recessive traits which are represented by lowercase letters. Moreover, phenotypic and genotypic ratios can be found through Punnett Square crosses. Phenotypic ratios refer to the number of offspring with each specific physical characteristic/trait coded for by the different letter combinations and the genotypic ratios refer to the number of offspring with each different code. These ratios are separated by numbers and colons and begin at the top left corner of the square. Make sure to simplify if needed. For example: A homozygous dominant plant (RR) is crossed with a heterozygous round plant (Rr) --> RR x Rr RR x Rr: RR RR Rr Rr Phenotypic Ratio: 1 Round (100% chance of offspring being round) Genotypic Ratio: 1 RR: 1 Rr (50% chance of offspring being RR/Rr)
That depends on the gametes. The most common is 9:3:3:1
To predict the traits of the offspring produced by genetic crosses.
A heterozygous cross.Tt X TtOne homozygous dominant--TTTwo heterozygous dominant---TtOne homozygous recessive--ttAll on a statistical average outcome.
There only certain crosses that will produce heterozygous offspring. These are heterozygous vs heterozygous, homozygous vs homozygous and heterozygous vs homozygous.
The offspring would be 100% pink snapdragons.
Crossing Yy x Yy yields YY, 2Yy, yy. Since Y is dominant over y, then YY and 2 Yy all result in the same phenotype. Therefore 3/4 of the offspring will resemble their parents.
genes