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Chapter 15: Q15.1-2CC (page 297)

Review the description of meiosis (see Figure 13.8) and Mendel’s laws of segregation and independent assortment (see Concept 14.1). What is the physical basis for each of Mendel’s laws?

Short Answer

Expert verified

The separation of homologous chromosomes during anaphase I of meiosis is the physical basis for the law of segregation.

While the alternative arrangements of the homologous chromosomes pairs during metaphase I is the physical basis for the law of independent assortment.

Step by step solution

01

Mendel’s law

Based on the experiments conducted on pea plants, Mendel observed that the allele pairs, which are the alternative forms of a gene, separate from each other during gametogenesis. As a result,the gametes produced contain only one allele of the pair. This is known as the law of segregation.

During the dihybrid cross, Mendel observed that the alleles of different genes that code for traits in an individual are sorted and inherited independently of each other during meiosis. This means alleles of one gene do not influence the inheritance of alleles of other genes. This is known as the law of independent assortment.

02

Meiosis

A process of cell division includes two sequential nuclear divisions. This produces haploid daughter nuclei that contain only one member of each pair of homologous chromosomes. Thus,this division process that reduces the number of chromosomes to half is called meiosis.

Meiosis comprises two cell divisions; meiosis I and meiosis II. In meiosis I, homologous chromosomes separate from each other to form two diploid daughter cells. These cells undergo meiosis II, similar to mitosis, where the sister chromatids of chromosomes separate to form four haploid daughter cells.

03

Physical basis of the law of segregation

The physical basis of the law of segregation is Meiosis I.During anaphase of meiosis I, the homologous chromosomes separate from each gene are segregated into daughter nuclei.

The homologous chromosomes behave during anaphase I account for the separation of the alleles to form gametes. Thus, the chromosome separates and segregates to form different gametes during meiosis.

This means the alleles of the gene separate, and each gamete inherits one allele of the gene.

04

Physical basis of the law of independent assortment

The physical basis of the law of independent assortment is also Meiosis I. In metaphase I, the bivalents chromosomes are arranged at the equator. The way the maternal and paternal chromosomes of each bivalent appear on the metaphase I plate is random.

The maternal and paternal chromosomes of a bivalent have an equal chance of facing either pole.Thus, when chromosomes separate during anaphase I, each pole receives a random assortment of parental chromosomes.

Thus, the alternative arrangement of homologous chromosomes in metaphase I demonstrate the physical basis of the law of independent assortment.

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Most popular questions from this chapter

The goodness of fit is measured by\({\chi ^{^2}}\). This statistic measures the amounts by which the observed values differ from their respective predictions to indicate how closely the two sets of values match. The formula for calculating this value is

\({\chi ^{}} = \sum \frac{{{{\left( {o - e} \right)}^2}}}{e}\)

Where o=observed and e= expected. Calculate the\({\chi ^{^2}}\)value for the data using the table below. Fill out the table, carrying out the operations indicated in the top row. Then add up the entries in the last column to find the\({\chi ^{^2}}\)value.

Testcross Offspring

Expected

(e)

Observed

(o)

Deviation

(o-e)

(o-e)2

(o-e)2/e

(A-B-)

220

(aaB-)

210

(A-bb)

231

(aabb)

239

\({\chi ^2}\) =sum

A man with hemophilia (a recessive, sex-linked condition) has a daughter without the condition. She marries a man who does not have hemophilia. What is the probability that their daughter will have hemophilia? Their son? If they have four sons, what is the probability that all will be affected?

Two genes of a flower, one controlling blue (B) versus white (b) petals and the other controlling round (R) versus oval (r) stamens, are linked and are 10 map units apart. You cross a homozygous blue oval plant with a homozygous white round plant. The resulting F1 progeny are crossed with homozygous white oval plants, and 1,000 offspring plants are obtained. How many plants of each of the four phenotypes do you expect?

The continuity of life is based on heritable information in the form of DNA. In a short essay (100-150 words), relate the structure and behavior of chromosomes to inheritance in both asexually and sexually reproducing species.

Consider what you learned about dominant and recessive alleles in Concept 14.1. If a disorder were caused by a dominant X-linked allele, how would the inheritance pattern differ from what we see for recessive X-linked disorders?
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