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Chapter 4: Problem 13

As in Problem \(12,\) flower color may be red, white, or pink, and flower shape may be personate or peloric. For the following crosses, determine the \(P_{1}\) and \(F_{1}\) genotypes: (a) red, peloric \(\times\) white, personate 1 \(\mathrm{F}_{1}:\) all pink, personate (b) red, personate \(\times\) white, peloric 1 \(\mathrm{F}_{1}:\) all pink, personate (c) pink, personate \(\times\) red, peloric $\rightarrow \mathrm{F}_{1} \quad\left\\{\begin{array}{l}1 / 4 \mathrm{red}, \text { personate } \\ 1 / 4 \mathrm{red}, \text { peloric } \\ 1 / 4 \mathrm{pink}, \text { peloric } \\\ 1 / 4 \mathrm{pink}, \text { personate }\end{array}\right.$ (d) pink, personate \(\times\) white, peloric $\rightarrow \mathrm{F}_{1}\left\\{\begin{array}{l}1 / 4 \text { white, personate } \\ 1 / 4 \text { white, peloric } \\ 1 / 4 \text { pink, personate } \\ 1 / 4 \text { pink, peloric }\end{array}\right.$ (c) What phenotypic ratios would result from crossing the \(\mathrm{F}_{1}\) of (a) to the \(F_{1}\) of \((b) ?\)

Short Answer

Expert verified
In conclusion, by analyzing the given crosses using Mendelian principles and assuming dominant and recessive traits, we can determine the genotypes of the P1 and F1 generations. The phenotypic ratios for a cross between the F1 of (a) and F1 of (b) come out to be 1 red personate : 1 red peloric : 1 pink personate : 1 pink peloric : 1 white personate : 1 white peloric.

Step by step solution

01

Assuming dominant and recessive traits

Let's assume that red (R) and personate (P) are dominant traits, while white (r) and peloric (p) are recessive traits. So, the red peloric P1 genotype would be R_pp, and the white personate P1 genotype would be rrP_. F1 genotypes: --------------------------------------------------------------------------
02

Crossing the P1 genotypes

Crossing R_pp (red, peloric) and rrP_ (white, personate) results in F1 generation: Rp x rP = RrPp
03

Phenotype of F1 generation

So, the F1 genotype is RrPp, which results in pink (due to incomplete dominance) and personate phenotype. This matches with the given F1 phenotypes: all pink, personate. (b) red, personate × white, peloric P1 genotypes: --------------------------------------------------------------------------
04

Assuming dominant and recessive traits

Following the same assumptions as before, red personate P1 genotype would be R_PP, and white peloric P1 genotype would be rrpp. F1 genotypes: --------------------------------------------------------------------------
05

Crossing the P1 genotypes

Crossing R_PP (red, personate) and rrpp (white, peloric) results in F1 generation: RP x rp = RrPp
06

Phenotype of F1 generation

So, the F1 genotype is RrPp, which results in pink (due to incomplete dominance) and personate phenotype. This matches with the given F1 phenotypes: all pink, personate. Now, let's find the phenotypic ratios resulting from crossing the F1 of (a) to the F1 of (b). (c) Crossing F1 of (a) and F1 of (b) --------------------------------------------------------------------------
07

Crossing F1 generations

Both the F1 generations of (a) and (b) have the same genotype, RrPp (pink, personate). So, we need to find the result of crossing RrPp × RrPp.
08

Determine all possible offspring genotypes

We can use a Punnett square to determine the possible offspring genotypes. The square will have 16 possible results which include: RRPP, RRPp, RrPP, RrPp (1 red, personate; 1 red, peloric; 1 pink, personate; 1 pink, peloric) rrPP, rrPp (1 white, personate; 1 white, peloric)
09

Phenotypic ratios

Based on these results, the phenotypic ratios for a cross between F1 of (a) and F1 of (b) are: 1 red personate : 1 red peloric : 1 pink personate : 1 pink peloric : 1 white personate : 1 white peloric

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Most popular questions from this chapter

While vermilion is X-linked in Drosophila and causes the eye color to be bright red, brown is an autosomal recessive mutation that causes the eye to be brown. Flies carrying both mutations lose all pigmentation and are white-eyed. Predict the \(\mathrm{F}_{1}\) and \(\mathrm{F}_{2}\) results of the following crosses: (a) vermilion females \(\times\) brown males (b) brown females \(\times\) vermilion males (c) white females \(\times\) wild-type males

In a unique species of plants, flowers may be yellow, blue, red, or mauve. All colors may be true breeding, If plants with blue flowers are crossed to red- flowered plants, all \(\mathrm{F}_{1}\) plants have yellow flowers. When these produced an \(\mathrm{F}_{2}\) generation, the following ratio was observed: \(9 / 16\) yellow: \(3 / 16\) blue: \(3 / 16\) red: \(1 / 16\) mauve In still another cross using true-breeding parents, yellow-flowered plants are crossed with mauve-flowered plants. Again, all \(\mathrm{F}_{1}\) plants had yellow flowers and the \(\mathrm{F}_{2}\) showed a 9: 3: 3: 1 ratio, as just shown. (a) Describe the inheritance of flower color by defining gene symbols and designating which genotypes give rise to cach of the four phenotypes. (b) Determine the \(F_{1}\) and \(F_{2}\) results of a cross between truebreeding red and true-breeding mauve-flowered plants.

Another recessive mutation in Drosophila, ebony \((e),\) is on an autosome (chromosome 3) and causes darkening of the body compared with wild-type flies. What phenotypic \(F_{1}\) and \(F_{2}\) male and female ratios will result if a scalloped-winged female with normal body color is crossed with a normal-winged cbony male? Work out this problem by both the Punnett square method and the forked-line method.

Five human matings \((1-5),\) identified by both maternal and paternal phenotypes for \(\mathrm{ABO}\) and \(\mathrm{MN}\) blood-group antigen status, are shown on the left side of the following table: Each mating resulted in one of the five offspring shown in the right-hand column (a-e). Match each offspring with one correct set of parents, using each parental set only once. Is there more than one set of correct answers?

A husband and wife have normal vision, although both of their fathers are red- green color-blind, an inherited X-linked recessive condition. What is the probability that their first child will be (a) a normal son? (b) a normal daughter? (c) a color-blind son? (d) a color- blind daughter?
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