CHAPTER 11 INTRODUCTION

CORE CONCEPTS

11.1 During cell division, a single parental cell divides into two daughter cells.

11.2 Mitotic cell division is the basis of asexual reproduction in unicellular eukaryotes and the process by which cells divide in multicellular eukaryotes.

11.3 Meiotic cell division is essential for sexual reproduction, the production of offspring that combines genetic material from two parents.

11.4 The cell cycle is regulated so that cell division occurs only at appropriate times.

11.5 Cancer is uncontrolled cell division that usually results from mutations in genes that control cell division.

Cells come from preexisting cells. This is one of the fundamental principles of biology and a key component of the cell theory, which was introduced in Chapter 1. Cell division is the process by which cells make more cells. In multicellular organisms, which begin life as a single cell, cell division produces the millions, billions, or in the case of humans, trillions of cells that make up the fully developed organism. Even after a multicellular organism has achieved its adult size, cell division continues. In plants, cell division is essential for continued growth. In many animals, cell division replaces worn-out blood cells, skin cells, and cells that line much of the digestive tract. And if you fall and scrape your knee, the cells at the site of the wound begin dividing to replace the damaged cells and heal the scrape.

Cell division is also important in reproduction. In bacteria, for example, a new generation is created when the parent cell divides and forms two daughter cells. This type of reproduction is called asexual reproduction. When a single bacterium reproduces by cell division, it first makes identical copies of its genetic material so that each of the two daughter cells has the same genetic material as the parent cell. There are many connotations to the word “sex,” but strictly speaking, sex is the combining of genetic material from two individuals. Since the genetic material in the bacterial daughter cells comes from just one parent, reproduction occurred without sex, or asexually. In principle, the daughter cells are genetically identical to the parental cell, but because DNA replication is not completely error free, the daughter cells may carry small genetic differences or mutations compared to the parent cell.

By contrast, sexual reproduction results in offspring that receive genetic material from two parents. Half the genetic material is supplied by the female parent and is present in the egg; the other half is contributed by the male’s sperm. Eggs and sperm are specialized cells called gametes. A female gamete and a male gamete merge during fertilization to form a new organism (Chapter 42). A unique feature of gametes is that they contain half the number of chromosomes as the other cells in the parent organism. So when fertilization occurs, the combination of genetic material from the egg and the sperm results in a new organism with the same number of chromosomes as the parents. The production of gametes comes about by a form of cell division that results in daughter cells with half the number of chromosomes as the parent cell. As we will see, the products of this cell division are not genetically identical to the parent.

What determines when cells divide and, importantly, when they should not? And what determines which cells divide? To answer these questions, we must understand the process of cell division and how it is controlled. This discussion will lay the groundwork for exploring how cancer results from a loss of control of cell division.