a56c_21d5

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Hint: For each gene pair from the parents, you can get 1, 2, or 3 unique genotypes.
This is based on the combinations: homozygous x homozygous (1), homozygous x heterozygous (2), and heterozygous x heterozygous (3).

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Correct MC

5482_acc2

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 3² = 9 (i.e. 2 genes with three forms) Incorrect B. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 3⁵ = 243 (i.e. 5 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

dcf5_5067

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

259d_f7f5

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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 × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

4cf8_8489

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	aa bb cc DD Ee Ff
Male (♂)	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. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2 × 3⁴ = 162 (i.e. 1 gene with two forms and 4 genes with three forms) Incorrect MC

c3d9_b70a

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect C. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Correct E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

1a46_6266

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

7cc0_d9f3

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

b766_a892

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct B. 2³ = 8 (i.e. 3 genes with two forms) Incorrect C. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

5ca3_ad0c

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

6c81_7d39

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3² = 9 (i.e. 2 genes with three forms) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct D. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

84e4_614f

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

2a4a_a789

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

e5a0_cec3

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

57df_d757

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct MC

d881_35d0

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect B. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Correct D. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

3b80_ff64

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

2b3d_cf79

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Correct C. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

0977_ace1

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Correct D. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect E. 2 × 3⁵ = 486 (i.e. 1 gene with two forms and 5 genes with three forms) Incorrect MC

b398_75f7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Correct MC

6697_e54c

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

8f6e_0c63

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct B. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect D. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

c37f_df21

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

efb5_9417

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3³ = 27 (i.e. 3 genes with three forms) Correct C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect D. 2 × 3⁴ = 162 (i.e. 1 gene with two forms and 4 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

74fb_a5de

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Correct D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

36fc_548b

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Correct E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

3656_3ae4

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct B. 2 × 3 = 6 (i.e. 1 gene with two forms and 1 gene with three forms) Incorrect C. 3² = 9 (i.e. 2 genes with three forms) Incorrect D. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

ee22_4030

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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 × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct E. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect MC

e39c_e5b8

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

24b2_876e

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

d034_e5cd

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

aa66_c30e

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Male (♂)	AA bb Cc Dd Ee FF
Female (♀)	aa bb Cc Dd Ee FF

A. 3² = 9 (i.e. 2 genes with three forms) Incorrect B. 3³ = 27 (i.e. 3 genes with three forms) Correct C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect D. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect E. 3⁵ = 243 (i.e. 5 genes with three forms) Incorrect MC

ae9c_4c03

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct D. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

2fce_d24c

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Male (♂)	Aa bb Cc dd ee FF
Female (♀)	aa Bb Cc dd EE ff

A. 3² = 9 (i.e. 2 genes with three forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect MC

049e_d4c8

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Male (♂)	Aa BB CC Dd ee Ff
Female (♀)	AA bb CC dd Ee ff

A. 2⁴ = 16 (i.e. 4 genes with two forms) Correct B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

cce4_3088

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct D. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

08e8_1b99

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect B. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

e2d6_843c

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3² = 9 (i.e. 2 genes with three forms) Incorrect C. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

76f5_0c0a

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Correct D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

825c_2f09

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) 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 × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

351b_b5d3

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

3e8e_ed19

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect B. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct D. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

0a23_b68b

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect B. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

3da9_0c02

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect B. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Correct E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

6304_5134

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect B. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Correct D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

b295_2b46

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

63e4_4805

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 3³ = 27 (i.e. 3 genes with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

3169_2fd7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	Aa Bb Cc DD Ee ff
Male (♂)	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 × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

f53b_3da8

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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 × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

3f31_c1f4

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Correct D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

3995_61e2

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

62c3_6033

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

ad07_1195

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	aa Bb cc Dd ee ff
Male (♂)	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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

ed4f_c3d6

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

e506_9be6

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

dfc1_a279

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect B. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct C. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

d0e3_591a

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

dacd_36e7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct D. 2 × 3⁴ = 162 (i.e. 1 gene with two forms and 4 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

63ce_8b38

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Incorrect C. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct MC

0814_d6b7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Correct E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

c00a_0380

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

be38_dfbd

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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 × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

bde0_95cf

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect B. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Correct MC

d24f_a3cd

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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 × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

422e_a9ff

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 3² = 9 (i.e. 2 genes with three forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect E. 2 × 3⁴ = 162 (i.e. 1 gene with two forms and 4 genes with three forms) Incorrect MC

29c3_166e

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

fedb_11f7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

1785_2865

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	aa Bb Cc dd Ee Ff
Male (♂)	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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect MC

20e9_756e

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

57a7_67be

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3² = 9 (i.e. 2 genes with three forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

898a_0e0e

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct E. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect MC

2c73_daa8

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

caa6_e460

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Male (♂)	Aa Bb cc Dd EE ff
Female (♀)	Aa Bb Cc DD EE ff

A. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct B. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect D. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

beb3_5134

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

7339_90d0

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3² = 9 (i.e. 2 genes with three forms) Incorrect C. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Correct D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

d1a4_4450

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Incorrect D. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct MC

96fd_2d0f

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect B. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

d1d0_4260

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	Aa bb CC Dd ee ff
Male (♂)	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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

92ee_46e2

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Correct D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

18c0_01eb

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC DD Ee Ff
Male (♂)	aa Bb CC Dd Ee Ff

A. 3³ = 27 (i.e. 3 genes with three forms) Incorrect B. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect C. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Correct D. 2 × 3⁴ = 162 (i.e. 1 gene with two forms and 4 genes with three forms) Incorrect E. 2 × 3⁵ = 486 (i.e. 1 gene with two forms and 5 genes with three forms) Incorrect MC

8968_79a4

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct B. 2⁴ = 16 (i.e. 4 genes with two forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

f1e3_b3c9

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2⁴ = 16 (i.e. 4 genes with two forms) Correct B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

741c_ce87

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

29aa_53ae

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 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. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

5e15_20dc

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Correct D. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect E. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect MC

2253_9249

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 3² = 9 (i.e. 2 genes with three forms) Incorrect C. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct D. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

9d0e_e372

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect C. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct E. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect MC

e498_7ad3

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Correct D. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

1f5d_cee1

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd EE FF
Male (♂)	Aa bb Cc dd EE ff

A. 3² = 9 (i.e. 2 genes with three forms) Incorrect B. 2² × 3 = 12 (i.e. 2 genes with two forms and 1 gene with three forms) Correct C. 3³ = 27 (i.e. 3 genes with three forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

e922_6767

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct B. 3² = 9 (i.e. 2 genes with three forms) Incorrect 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. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect MC

c162_31c7

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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) Correct C. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

5c8e_9b1b

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct E. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect MC

5ed0_880b

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

Female (♀)	Aa Bb CC dd Ee Ff
Male (♂)	aa BB CC Dd Ee ff

A. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect B. 2² × 3² = 36 (i.e. 2 genes with two forms and 2 genes with three forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Correct D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

d628_8adc

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect C. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Correct D. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect E. 2² × 3³ = 108 (i.e. 2 genes with two forms and 3 genes with three forms) Incorrect MC

34c9_e740

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2 × 3³ = 54 (i.e. 1 gene with two forms and 3 genes with three forms) Incorrect D. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Correct E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

db91_1455

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Correct C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2⁶ = 64 (i.e. 6 genes with two forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

ab5f_b6ca

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2 × 3² = 18 (i.e. 1 gene with two forms and 2 genes with three forms) Correct C. 2³ × 3² = 72 (i.e. 3 genes with two forms and 2 genes with three forms) Incorrect D. 3⁴ = 81 (i.e. 4 genes with three forms) Incorrect E. 2² × 3⁴ = 324 (i.e. 2 genes with two forms and 4 genes with three forms) Incorrect MC

d6b7_a5dc

Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in 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. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Incorrect E. 2⁴ × 3² = 144 (i.e. 4 genes with two forms and 2 genes with three forms) Incorrect MC

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Genotype Diversity in Hybrid Cross

In a hybrid cross, the range of possible genotypes in the offspring is determined by the genetic makeup of the parental organisms.

Assume that all genes sort independently and display complete dominance.

Considering the principle of independent assortment, how many unique GENOTYPES could be produced in a hybrid cross between the following individuals?

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

A. 2³ × 3 = 24 (i.e. 3 genes with two forms and 1 gene with three forms) Incorrect B. 2⁵ = 32 (i.e. 5 genes with two forms) Incorrect C. 2⁴ × 3 = 48 (i.e. 4 genes with two forms and 1 gene with three forms) Incorrect D. 2⁵ × 3 = 96 (i.e. 5 genes with two forms and 1 gene with three forms) Correct E. 2³ × 3³ = 216 (i.e. 3 genes with two forms and 3 genes with three forms) Incorrect