Respuesta :
Answer:
Step-by-step explanation:
A. In the equation, the n represents the no. of genes involved. If n =1, a single gene is responsible, then X= (1/4)^1= 1/4 offsprings will be of one parental type.
B. Out of 50,000 plants, 1 out of 500 had maize phenotype and another 1 out of 500 terosinte phenotype.
So 1 in 500 so how much in 50000?
1*50000/500 = 100.
100 plants are of terosinte and 100 are of maize phenotype. The rest plants have recombinant phenotype. The exact phenotypes cannot be told from the given information.
C. According to formula, if 2 genes are involved, then 1 in 16 will be of one parental type. If genes 4 are involved, then 1 in 4^4= 1 in 256 will be of one parental type. If 5 genes are involved then it will be 1 in 512 plants will be of parental type. On the question, every 1 in 500 plants have one parental type. Hence Dr.Beadle concluded that 4 or 5 genes are involved in the phenotypic difference.
D. Genes code for all physical characteristics of an organism. Changes to genetic material can result in far reaching consequences in one or more particular metabolic pathways, this results in different phenotype compared to parents. Genes can mask other genes effect, complement it, or supplement it resulting in diverse response. The genes can also act in additive manner called quantitative genetics. Certain gene upon expression can block other genes expression, called epistasis. Such diverse mechanism can result in very different looking plants even with changes in small number of genes.
A. n be the number of genes.
B. 100 plants are terosinte and 100 are of maize phenotype.
C. Dr. Beadle concluded that 4 or 5 genes are involved in the phenotypic difference.
D. The genes can also act in an additive manner called quantitative genetics.
What is an experimental equation?
It is the equation that is obtained after the experiment that is conducted in the lab.
Dr. Beadle conducted an experiment to determine how many genes control the differences between maize and teosinte.
He crossed teosinte with maize to produce F1 hybrids and then crossed the F1 plants to produce an F2 generation (offspring).
This relationship can be summarized by this equation:
[tex]\rm X = \dfrac{1}{4} \ n[/tex]
A. In the equation, n represent the number of the genes involved. If n=1, a single gene is responsible.
B. Out of 50,000 plants, 1 out of 500 had maize phenotype, and another one out of 500 terosinte phenotypes.
1 in 500. So, in 50,000 we have
[tex]\dfrac{1* 50000}{500} = 100[/tex]
100 plants are terosinte and 100 are of maize phenotype. The rest plants have recombinant phenotypes. The exact phenotype cannot be told from the given information.
C. According to the formula, if 2 genes are involved, then 1 in 16 will be of one parental type. If genes 4 are involved, then 1 in 256 will be one parental type. If genes 5 are involved, then 1 in 512 will be one parental type. On the question, every one in 500 plants has one parental type. Hence, Dr. Beadle concluded that 4 or 5 genes are involved in the phenotypic difference.
D. Genes code for all physical characteristics of an organism. Change to the genetic material can result in far-reaching consequences in one or more particular metabolic pathways, this results in different phenotypes compared to the parent. Genes can mark other gene's effect, compliment them, supplement it resulting in diversity. The genes can also act in an additive manner called quantitative genetics. Certain genes upon expression can block other genes expression, called epistasis. Such diverse mechanisms can result in very different-looking plants even with changes in a small number of genes.
More about the experimental equation link is given below.
https://brainly.com/question/517528
