d706_97e1

Phenotype Diversity in Hybrid Cross

In a hybrid cross, you can determine the variety of phenotypes in the offspring by examining the genetic makeup of the parents. Specifically, look at whether each gene can be dominant, recessive, or both.

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Hint: To find the number of unique phenotypes, consider each gene pair.
For gene pairs with at least one heterozygous and one either heterozygous or homozygous recessive gene, 2 phenotypes are possible.
For all other combinations, only 1 phenotype is possible.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB cc dd EE Ff
Female (♀)	Aa bb Cc DD EE Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

c75e_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa bb Cc DD Ee Ff
Female (♀)	AA BB cc Dd EE Ff

A. 2² = 4 (i.e. 2 genes with two forms) Correct B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

9b8f_73fa

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB cc dd Ee Ff
Female (♀)	Aa bb cc dd Ee ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

73da_d3e4

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd ee Ff
Male (♂)	Aa bb Cc Dd ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

bfc0_462a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb cc Dd ee Ff
Male (♂)	aa BB Cc Dd Ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

b41c_10bf

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc Dd EE ff
Female (♀)	Aa bb cc Dd Ee FF

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

51b5_9448

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc DD Ee Ff
Female (♀)	Aa bb cc dd ee FF

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

3419_10bf

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa bb cc Dd Ee Ff
Male (♂)	AA Bb cc DD ee Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

1855_03f7

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA bb Cc Dd ee Ff
Male (♂)	aa Bb Cc Dd ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect MC

51c4_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb Cc DD ee FF
Male (♂)	aa BB Cc DD EE Ff

73bc_73fa

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa bb cc DD Ee ff
Female (♀)	Aa BB cc Dd Ee Ff

cd03_dda4

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa bb Cc dd Ee Ff
Female (♀)	AA Bb Cc Dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2⁴ = 16 (i.e. 4 genes with two forms) Correct C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

f0d6_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc Dd EE ff
Female (♀)	Aa bb Cc Dd ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

07dd_0a61

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb Cc DD ee FF
Male (♂)	Aa Bb cc DD EE Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

c37e_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB Cc Dd Ee Ff
Male (♂)	AA bb CC dd EE Ff

17bd_d188

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa bb Cc dd Ee Ff
Male (♂)	Aa Bb Cc dd EE Ff

A. 2³ = 8 (i.e. 3 genes with two forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

d5bc_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa bb CC Dd Ee FF
Female (♀)	aa Bb CC Dd EE Ff

6324_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb CC dd Ee Ff
Female (♀)	AA Bb cc dd Ee ff

56d8_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb cc DD EE Ff
Male (♂)	AA Bb Cc Dd EE ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

613b_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa bb Cc DD Ee ff
Male (♂)	AA bb cc dd Ee ff

26ca_d188

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb Cc dd Ee FF
Female (♀)	Aa bb cc dd EE FF

A. 2³ = 8 (i.e. 3 genes with two forms) Correct B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

0221_319e

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb cc Dd Ee ff
Female (♀)	Aa bb Cc DD Ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect MC

3533_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb Cc dd ee FF
Male (♂)	AA Bb Cc dd EE Ff

15a7_0a61

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa bb CC DD ee Ff
Female (♀)	AA Bb CC Dd Ee Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

159e_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA BB Cc Dd Ee FF
Male (♂)	aa Bb cc DD Ee FF

0922_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA BB Cc DD Ee FF
Male (♂)	AA Bb Cc DD Ee ff

7830_b333

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb CC dd Ee FF
Female (♀)	AA Bb CC Dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

2af3_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb Cc Dd ee FF
Male (♂)	Aa bb CC DD ee Ff

13fe_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA bb cc DD Ee Ff
Male (♂)	Aa BB CC dd Ee Ff

5e2d_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc DD Ee Ff
Female (♀)	Aa BB CC Dd Ee Ff

53fc_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd Ee Ff
Male (♂)	Aa BB Cc DD EE Ff

df6f_9448

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb cc Dd EE FF
Female (♀)	aa Bb Cc Dd EE Ff

a652_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb CC DD Ee Ff
Female (♀)	AA Bb cc dd ee Ff

6ad8_ee7a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA bb Cc dd EE FF
Female (♀)	Aa Bb cc Dd Ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

b7c5_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc DD EE FF
Female (♀)	AA Bb Cc DD Ee Ff

e4f6_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa BB cc dd EE Ff
Female (♀)	aa bb Cc Dd Ee Ff

e4d6_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc Dd ee FF
Female (♀)	Aa BB CC Dd Ee ff

17d9_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc DD Ee FF
Female (♀)	aa BB Cc Dd ee Ff

1e07_ee7a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA bb Cc Dd Ee Ff
Male (♂)	aa bb Cc dd ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

22e3_319e

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb cc Dd Ee ff
Male (♂)	AA Bb CC DD Ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect MC

850d_0c9e

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb CC Dd EE Ff
Female (♀)	Aa Bb cc dd EE Ff

A. 2³ = 8 (i.e. 3 genes with two forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

6a60_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb cc Dd ee Ff
Male (♂)	AA bb Cc Dd ee FF

6fac_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA Bb CC Dd Ee FF
Male (♂)	Aa Bb cc DD Ee Ff

204e_97e1

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa BB cc dd Ee Ff
Male (♂)	aa bb cc Dd ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

3912_235d

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc Dd EE FF
Female (♀)	aa Bb Cc dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

dd5f_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc dd EE Ff
Female (♀)	aa BB CC Dd ee Ff

9191_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc DD EE FF
Female (♀)	AA Bb Cc Dd EE Ff

6a7d_ee7a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb CC Dd Ee Ff
Male (♂)	AA Bb Cc Dd ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

8d2e_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb CC Dd Ee FF
Female (♀)	AA Bb CC Dd EE Ff

cda3_38f4

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc dd Ee FF
Female (♀)	Aa Bb cc Dd EE Ff

A. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect B. 2⁴ = 16 (i.e. 4 genes with two forms) Correct C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

3273_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa bb Cc dd ee FF
Female (♀)	Aa bb Cc Dd EE FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

d2c6_0ba4

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa BB cc Dd ee Ff
Female (♀)	Aa bb cc Dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

a517_0a61

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc dd EE Ff
Female (♀)	AA bb Cc dd Ee Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect MC

2be4_b062

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc dd Ee Ff
Female (♀)	Aa BB Cc Dd ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁵ = 32 (i.e. 5 genes with two forms) Correct MC

8797_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa BB Cc Dd EE FF
Female (♀)	Aa Bb CC Dd Ee FF

35e1_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb Cc DD Ee Ff
Female (♀)	AA BB cc DD ee Ff

4712_ee7a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc DD EE ff
Female (♀)	Aa bb Cc Dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

18c3_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa BB cc Dd ee FF
Male (♂)	Aa Bb CC DD Ee ff

761a_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB Cc dd ee Ff
Male (♂)	aa bb CC Dd Ee Ff

a3c3_73fa

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc Dd ee ff
Female (♀)	aa Bb Cc Dd Ee ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

f280_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA Bb Cc dd EE Ff
Male (♂)	aa BB Cc dd EE Ff

a28c_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB cc DD Ee Ff
Female (♀)	Aa Bb cc Dd ee Ff

0c5d_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa BB Cc DD Ee FF
Female (♀)	Aa Bb CC DD Ee Ff

e938_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC Dd ee ff
Male (♂)	Aa BB Cc dd ee FF

ea26_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb cc Dd ee FF
Male (♂)	aa BB Cc dd ee Ff

1a3c_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc dd Ee ff
Female (♀)	Aa BB cc DD Ee ff

2782_fa09

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa bb Cc dd ee Ff
Female (♀)	Aa Bb cc Dd ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁵ = 32 (i.e. 5 genes with two forms) Correct MC

fadb_ee7a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb Cc DD Ee ff
Female (♀)	aa Bb Cc Dd ee ff

b28b_d188

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa Bb cc Dd Ee FF
Female (♀)	aa Bb Cc DD Ee FF

533f_d188

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa bb CC Dd Ee ff
Male (♂)	Aa Bb CC Dd EE FF

094d_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA bb Cc DD Ee FF
Female (♀)	aa Bb CC dd Ee Ff

41dd_462a

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb Cc dd Ee Ff
Male (♂)	aa BB CC Dd Ee Ff

8b94_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB CC DD EE Ff
Male (♂)	Aa BB cc DD Ee Ff

01e7_b333

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc DD Ee Ff
Female (♀)	Aa Bb Cc DD EE Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

2fc3_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb Cc Dd ee Ff
Male (♂)	AA Bb CC Dd EE FF

2b9d_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb cc Dd Ee FF
Male (♂)	Aa Bb CC Dd EE FF

25da_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd Ee Ff
Male (♂)	Aa bb cc DD EE FF

2752_723f

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa BB Cc dd Ee ff
Female (♀)	aa Bb Cc Dd ee ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

642c_ee43

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	AA Bb Cc Dd Ee FF
Female (♀)	AA BB cc dd Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

4d78_9448

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd Ee Ff
Male (♂)	Aa Bb CC dd EE Ff

eb3a_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB Cc dd Ee FF
Male (♂)	Aa Bb CC dd ee Ff

7e07_64b0

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB Cc DD Ee ff
Male (♂)	Aa BB Cc DD Ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect MC

c0c0_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb cc Dd Ee ff
Female (♀)	Aa Bb CC dd EE ff

93c5_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA bb cc Dd EE Ff
Male (♂)	AA Bb Cc DD Ee FF

8333_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa BB cc Dd Ee Ff
Male (♂)	aa Bb cc dd Ee FF

3887_723f

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb Cc Dd ee Ff
Female (♀)	Aa bb CC DD Ee FF

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

fad8_03f7

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb CC DD Ee ff
Male (♂)	Aa bb Cc DD ee Ff

caf4_94cb

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	Aa bb cc dd Ee Ff
Female (♀)	Aa bb Cc dd ee Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

afaf_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa bb CC dd Ee Ff
Male (♂)	Aa BB cc dd EE ff

8271_10bf

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb cc Dd Ee Ff
Male (♂)	Aa BB Cc DD Ee FF

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Correct C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

0c38_4362

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Male (♂)	aa Bb Cc dd ee ff
Female (♀)	AA bb CC DD Ee Ff

05a6_f974

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb cc dd ee Ff
Male (♂)	Aa Bb CC Dd EE Ff

A. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ = 16 (i.e. 4 genes with two forms) Correct E. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect MC

d9be_8326

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa Bb cc Dd Ee ff
Male (♂)	aa BB Cc Dd Ee Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Incorrect D. 2⁵ = 32 (i.e. 5 genes with two forms) Correct E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect MC

0db7_09c8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb Cc dd ee FF
Male (♂)	Aa BB cc Dd ee FF

a9e3_caa8

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa bb Cc DD Ee Ff
Male (♂)	AA bb Cc Dd ee FF

663f_97e1

Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa BB Cc DD Ee Ff
Male (♂)	aa BB cc Dd Ee ff

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Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	AA Bb CC Dd Ee FF
Male (♂)	Aa Bb Cc DD Ee FF

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Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	aa Bb CC Dd ee FF
Male (♂)	Aa BB Cc dd Ee ff

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Phenotype Diversity in Hybrid Cross

A dominant gene can mask the effect of its recessive counterpart, thus influencing the number of unique phenotypes.

Assume complete dominance and the principle of independent assortment for all genes.

Given these principles, how many unique PHENOTYPES could result from a hybrid cross between the following individuals?

Female (♀)	Aa BB Cc dd Ee Ff
Male (♂)	aa Bb Cc DD EE Ff

A. 2² = 4 (i.e. 2 genes with two forms) Incorrect B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 2³ = 8 (i.e. 3 genes with two forms) Correct D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect