Presentation is loading. Please wait.

Presentation is loading. Please wait.

10.3 Regulating the Cell Cycle

Similar presentations


Presentation on theme: "10.3 Regulating the Cell Cycle"— Presentation transcript:

1 10.3 Regulating the Cell Cycle
Lesson Overview 10.3 Regulating the Cell Cycle Objectives: Describe how the cell cycle is regulated. Explain how cancer cells are different from other cells.

2 THINK ABOUT IT How do cells know when to divide?

3 Controls on Cell Division
How is the cell cycle regulated? The cell cycle is controlled by regulatory proteins both inside and outside the cell.

4 The controls on cell growth and division can be turned on and off.
For example, when an injury such as a broken bone occurs, cells are stimulated to divide rapidly and start the healing process. The rate of cell division slows when the healing process nears completion.

5 The Discovery of Cyclins
Cyclins are a family of proteins that regulate the timing of the cell cycle in eukaryotic cells. This graph shows how cyclin levels change throughout the cell cycle in fertilized clam eggs.

6 Regulatory Proteins Internal regulators are proteins that respond to events inside a cell. They allow the cell cycle to proceed only once certain processes have happened inside the cell. External regulators are proteins that respond to events outside the cell. They direct cells to speed up or slow down the cell cycle. Growth factors are external regulators that stimulate the growth and division of cells. They are important during embryonic development and wound healing.

7 Apoptosis Apoptosis is a process of programmed cell death.
Apoptosis plays a role in development by shaping the structure of tissues and organs in plants and animals. For example, the foot of a mouse is shaped the way it is partly because the toes undergo apoptosis during tissue development.

8 Cancer: Uncontrolled Cell Growth
How do cancer cells differ from other cells? Cancer cells do not respond to the signals that regulate the growth of most cells. As a result, the cells divide uncontrollably.

9 Cancer is a disorder in which body cells lose the ability to control cell growth.
Cancer cells divide uncontrollably to form a mass of cells called a tumor.

10 A benign tumor is noncancerous
A benign tumor is noncancerous. It does not spread to surrounding healthy tissue. A malignant tumor is cancerous. It invades and destroys surrounding healthy tissue and can spread to other parts of the body. The spread of cancer cells is called metastasis. Cancer cells absorb nutrients needed by other cells, block nerve connections, and prevent organs from functioning.

11 What Causes Cancer? Cancers are caused by defects in genes that regulate cell growth and division. Some sources of gene defects are smoking tobacco, radiation exposure, defective genes, and viral infection. A damaged or defective p53 gene is common in cancer cells. It causes cells to lose the information needed to respond to growth signals.

12 Treatments for Cancer Some localized tumors can be removed by surgery.
Many tumors can be treated with targeted radiation. Chemotherapy is the use of compounds that kill or slow the growth of cancer cells.

13 Lesson Overview 10.4 Cell Differentiation Objectives
Describe the process of differentiation. Define stem cells and explain their importance. Identify the possible benefits and issues relating to stem cell research.

14 THINK ABOUT IT The human body contains hundreds of different cell types, and every one of them develops from the single cell that starts the process. How do the cells get to be so different from each other?

15 From One Cell to Many How do cells become specialized for different functions? During the development of an organism, cells differentiate into many types of cells.

16 All organisms start life as just one cell.
Most multicellular organisms pass through an early stage of development called an embryo, which gradually develops into an adult organism.

17 During development, an organism’s cells become more differentiated and specialized for particular functions. For example, a plant has specialized cells in its roots, stems, and leaves.

18 Defining Differentiation
The process by which cells become specialized is known as differentiation. During development, cells differentiate into many different types and become specialized to perform certain tasks. Differentiated cells carry out the jobs that multicellular organisms need to stay alive.

19 Mapping Differentiation
In some organisms, a cell’s role is determined at a specific point in development. In the worm C. elegans, daughter cells from each cell division follow a specific path toward a role as a particular kind of cell.

20 Differentiation in Mammals
Cell differentiation in mammals is controlled by a number of interacting factors in the embryo. Adult cells generally reach a point at which their differentiation is complete and they can no longer become other types of cells.

21 Stem Cells and Development
What are stem cells? The unspecialized cells from which differentiated cells develop are known as stem cells.

22 One of the most important questions in biology is how all of the specialized, differentiated cell types in the body are formed from just a single cell. Biologists say that such a cell is totipotent, literally able to do everything, to form all the tissues of the body. Only the fertilized egg and the cells produced by the first few cell divisions of embryonic development are truly totipotent.

23 Human Development After about four days of development, a human embryo forms into a blastocyst, a hollow ball of cells with a cluster of cells inside known as the inner cell mass. The cells of the inner cell mass are said to be pluripotent, which means that they are capable of developing into many, but not all, of the body's cell types.

24 Stem Cells Stem cells are unspecialized cells from which differentiated cells develop. There are two types of stem cells: embryonic and adult stem cells.

25 Embryonic Stem Cells Embryonic stem cells are found in the inner cells mass of the early embryo. Embryonic stem cells are pluripotent. Researchers have grown stem cells isolated from human embryos in culture. Their experiments confirmed that embryonic stem cells have the capacity to produce most cell types in the human body.

26 Adult Stem Cells Adult organisms contain some types of stem cells.
Adult stem cells are multipotent. They can produce many types of differentiated cells. Adult stem cells of a given organ or tissue typically produce only the types of cells that are unique to that tissue.

27 Frontiers in Stem Cell Research
What are some possible benefits and issues associated with stem cell research? Stem cells offer the potential benefit of using undifferentiated cells to repair or replace badly damaged cells and tissues. Human embryonic stem cell research is controversial because the arguments for it and against it both involve ethical issues of life and death.

28 Potential Benefits Stem cell research may lead to new ways to repair the cellular damage that results from heart attack, stroke, and spinal cord injuries. One example is the approach to reversing heart attack damage illustrated below.

29 Ethical Issues Most techniques for harvesting, or gathering, embryonic stem cells cause destruction of the embryo. Government funding of embryonic stem cell research is an important political issue. Groups seeking to protect embryos oppose such research as unethical. Other groups support this research as essential to saving human lives and so view it as unethical to restrict the research.


Download ppt "10.3 Regulating the Cell Cycle"

Similar presentations


Ads by Google