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Chapter 18: Problem 20

In Arabidopsis, flower development is controlled by sets of homeotic genes. How many classes of these genes are there, and what structures are formed by their individual and combined expression?

Short Answer

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Answer: There are three classes of homeotic genes in Arabidopsis, namely A, B, and C. Their individual expression leads to the formation of sepals (A class), petals (B class), and carpels (C class). The combined expression of these genes results in various flower structures including normal flower development with all whorls and organs based on the following combinations: A+B class (petals), B+C class (stamens), and A+C class (normal flowers with all whorls and organs).

Step by step solution

01

Research Arabidopsis homeotic genes

After researching Arabidopsis homeotic genes, we find that these genes are responsible for the development of floral organs in plants. There are three classes of homeotic genes namely A, B, and C.
02

Identify the structures formed by individual expression

The A class genes, when expressed individually, lead to the development of sepals in the outermost whorl of the flower. B class genes, when expressed individually, are responsible for the formation of petals in the second whorl. Finally, the C class genes, when expressed individually, lead to the development of carpels in the innermost whorl of the flower.
03

Identify the structures formed by combined expression

The flower structures are formed based on the combined expression of these classes of homeotic genes. The combinations are as follows: 1. A class + B class genes: They lead to the development of petals in the second whorl of the flower. 2. B class + C class genes: They result in the formation of stamens in the third whorl of the flower. 3. A class + C class genes: They lead to the development of normal flowers with all the different whorls and the organs they contain (sepals, petals, stamens, and carpels). In conclusion, there are three classes of homeotic genes in Arabidopsis, namely A, B, and C. Their individual expression leads to the formation of sepals, petals, and carpels, respectively. The combined expression of these genes results in various flower structures including normal flower development with all whorls and organs.

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Most popular questions from this chapter

(a) What are zygotic genes, and when are their gene products made? (b) What is the phenotype associated with zygotic gene mutations? (c) Does the maternal genotype contain zygotic genes?

Nuclei from almost any source may be injected into Xenopus oocytes. Studies have shown that these nuclei remain active in transcription and translation. How can such an experimental system be useful in developmental genetic studies?

The floral homeotic genes of Arabidopsis belong to the MADSbox gene family, while in Drosophila, homeotic genes belong to the homeobox gene family. In both Arabidopsis and Drosophila, members of the Polycomb gene family control expression of these divergent homeotic genes. How do Polycomb genes control expression of two very different sets of homeotic genes?

The identification and characterization of genes that control sex determination has been a focus of investigators working with \(C .\) elegans. As with Drosophila, sex in this organism is determined by the ratio of \(X\) chromosomes to sets of autosomes. A diploid wild-type male has one \(X\) chromosome and a diploid wild-type hermaphrodite has two X chromosomes. Many different mutations have been identified that affect sex determination. Loss- of-function mutations in a gene called her-1 cause an XO nematode to develop into a hermaphrodite and have no effect on \(\mathrm{XX}\) development. (That is, \(\mathrm{XX}\) nematodes are normal hermaphrodites.) In contrast, loss- offunction mutations in a gene called tra-I cause an XX nematode to develop into a male. Deduce the roles of these genes in wild-type sex determination from this information.

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