Presentation is loading. Please wait.

Presentation is loading. Please wait.

Section 10.2 Summary – pages

Published byBernard Stafford Modified over 8 years ago

Similar presentations

Presentation on theme: "Section 10.2 Summary – pages"— Presentation transcript:

1 Section 10.2 Summary – pages 263-273
Genes, Chromosomes, and Numbers Genes do not exist free in the nucleus of a cell; they are lined up on chromosomes. Typically, a chromosome can contain a thousand or more genes along its length. Section 10.2 Summary – pages

2 Section 10.2 Summary – pages 263-273
Diploid and haploid cells In the body cells of animals and most plants, chromosomes occur in pairs. A cell with two of each kind of chromosome is called a diploid cell and is said to contain a diploid, or 2n, number of chromosomes. Section 10.2 Summary – pages

3 Section 10.2 Summary – pages 263-273
Diploid and haploid cells Organisms produce gametes that contain one of each kind of chromosome. A cell containing one of each kind of chromosome is called a haploid cell and is said to contain a haploid, or n, number of chromosomes. Section 10.2 Summary – pages

4 Section 10.2 Summary – pages 263-273
Homologous chromosomes The two chromosomes of each pair in a diploid cell are called homologous chromosomes. Each pair of homologous chromosomes has genes for the same traits. Section 10.2 Summary – pages

5 Section 10.2 Summary – pages 263-273
Homologous chromosomes On homologous chromosomes, these genes are arranged in the same order, but because there are different possible alleles for the same gene, the two chromosomes in a homologous pair are not always identical to each other. Homologous Chromosome 4 a A Terminal Axial Inflated D d Constricted T t Short Tall Section 10.2 Summary – pages

6 Section 10.2 Summary – pages 263-273
Why meiosis? This kind of cell division, which produces gametes containing half the number of chromosomes as a parent’s body cell, is called meiosis. Section 10.2 Summary – pages

7 Section 10.2 Summary – pages 263-273
Why meiosis? These haploid cells are called sex cells— gametes. Male gametes are called sperm. Female gametes are called eggs. When a sperm fertilizes an egg, the resulting zygote once again has the diploid number of chromosomes. Section 10.2 Summary – pages

8 Section 10.2 Summary – pages 263-273
Why meiosis? This pattern of reproduction, involving the production and subsequent fusion of haploid sex cells, is called sexual reproduction. Meiosis Haploid gametes (n=23) Sperm Cell Meiosis Egg Cell Fertilization Diploid zygote (2n=46) Multicellular diploid adults (2n=46) Mitosis and Development Section 10.2 Summary – pages

9 Sect ion 10.2 Summary – pages 263-273
The Phases of Meiosis Click image to view movie. Sect ion 10.2 Summary – pages

10 Section 10.2 Summary – pages 263-273
Interphase During interphase, the cell replicates its chromosomes. After replication, each chromosome consists of two identical sister chromatids, held together by a centromere. Interphase Section 10.2 Summary – pages

11 Section 10.2 Summary – pages 263-273
Prophase I The chromosomes coil up and a spindle forms. As the chromosomes coil, homologous chromosomes line up with each other gene by gene along their length, to form a four-part structure called a tetrad. Prophase I Section 10.2 Summary – pages

12 Section 10.2 Summary – pages 263-273
Prophase I The chromatids in a tetrad pair tightly. In fact, they pair so tightly that non-sister chromatids from homologous chromosomes can actually break and exchange genetic material in a process known as crossing over. Prophase I Section 10.2 Summary – pages

13 Section 10.2 Summary – pages 263-273
Prophase I Crossing over results in new combinations of alleles on a chromosome. Sister chromatids Nonsister chromatids Crossing over in tetrad Tetrad Homologous chromosomes Gametes Section 10.2 Summary – pages

14 Section 10.2 Summary – pages 263-273
Metaphase I During metaphase I, the centromere of each chromosome becomes attached to a spindle fiber. The spindle fibers pull the tetrads into the middle, or equator, of the spindle. Metaphase I Section 10.2 Summary – pages

15 Section 10.2 Summary – pages 263-273
Anaphase I Anaphase I begins as homologous chromosomes, each with its two chromatids, separate and move to opposite ends of the cell. This critical step ensures that each new cell will receive only one chromosome from each homologous pair. Anaphase I Section 10.2 Summary – pages

16 Section 10.2 Summary – pages 263-273
Telophase I Events occur in the reverse order from the events of prophase I. The spindle is broken down, the chromosomes uncoil, and the cytoplasm divides to yield two new cells. Telophase I Section 10.2 Summary – pages

17 Section 10.2 Summary – pages 263-273
Telophase I Each cell has half the genetic information of the original cell because it has only one chromosome from each homologous pair. Telophase I Section 10.2 Summary – pages

18 Section 10.2 Summary – pages 263-273
The phases of meiosis II The second division in meiosis is simply a mitotic division of the products of meiosis I. Meiosis II consists of prophase II, metaphase II, anaphase II, and telophase II. Meiosis II Section 10.2 Summary – pages

19 Section 10.2 Summary – pages 263-273
The phases of meiosis II During prophase II, a spindle forms in each of the two new cells and the spindle fibers attach to the chromosomes. Prophase II Section 10.2 Summary – pages

20 Section 10.2 Summary – pages 263-273
The phases of meiosis II The chromosomes, still made up of sister chromatids, are pulled to the center of the cell and line up randomly at the equator during metaphase II. Metaphase II Section 10.2 Summary – pages

21 Section 10.2 Summary – pages 263-273
The phases of meiosis II Anaphase II begins as the centromere of each chromosome splits, allowing the sister chromatids to separate and move to opposite poles. Anaphase II Section 10.2 Summary – pages

22 Section 10.2 Summary – pages 263-273
The phases of meiosis II Finally nuclei, reform, the spindles break down, and the cytoplasm divides during telophase II. Telophase II Section 10.2 Summary – pages

23 Section 10.2 Summary – pages 263-273
The phases of meiosis II At the end of meiosis II, four haploid cells have been formed from one diploid cell. These haploid cells will become gametes, transmitting the genes they contain to offspring. Section 10.2 Summary – pages

24 Section 10.2 Summary – pages 263-273
Meiosis Provides for Genetic Variation Cells that are formed by mitosis are identical to each other and to the parent cell. Crossing over during meiosis, however, provides a way to rearrange allele combinations. Thus, variability is increased. Section 10.2 Summary – pages

25 Section 10.2 Summary – pages 263-273
Nondisjunction The failure of homologous chromosomes to separate properly during meiosis is called nondisjunction. Section 10.2 Summary – pages

26 Section 10.2 Summary – pages 263-273
Nondisjunction Recall that during meiosis I, one chromosome from each homologous pair moves to each pole of the cell. In nondisjunction, both chromosomes of a homologous pair move to the same pole of the cell. Section 10.2 Summary – pages

27 Section 10.2 Summary – pages 263-273
Nondisjunction The effects of nondisjunction are often seen after gametes fuse. When a gamete with an extra chromosome is fertilized by a normal gamete, the zygote will have an extra chromosome. This condition is called trisomy. Section 10.2 Summary – pages

28 Section 10.2 Summary – pages 263-273
Nondisjunction Although organisms with extra chromosomes often survive, organisms lacking one or more chromosomes usually do not. When a gamete with a missing chromosome fuses with a normal gamete during fertilization, the resulting zygote lacks a chromosome. This condition is called monosomy. Section 10.2 Summary – pages

29 Section 10.2 Summary – pages 263-273
Nondisjunction An example of monosomy that is not lethal is Turner syndrome, in which human females have only a single X chromosome instead of two. Section 10.2 Summary – pages

30 End of Chapter 10 Show

Download ppt "Section 10.2 Summary – pages"

Similar presentations

Meiosis Pgs. 96-100 Modified by Liz LaRosa 2011.

Meiosis Pgs Modified by Liz LaRosa 2011.
Mendel and Meiosis Unit 4 Chapter 10.

Mendel and Meiosis Unit 4 Chapter 10.
Meiosis Year 10 Li To understand the process of Meiosis. I can

Meiosis Year 10 Li To understand the process of Meiosis. I can
Mitosis Cell division/ cell production What kind of cells?

Mitosis Cell division/ cell production What kind of cells?
Unit Overview – pages 250-251 Genetics Mendel and Meiosis Meiosis.

Unit Overview – pages Genetics Mendel and Meiosis Meiosis.
Sexual Reproduction and Genetics

Sexual Reproduction and Genetics
Chapter 10.2. Genes: Organisms have thousands of genes that determine individual traits They are lined up on chromosomes 1 chromosome holds 100-1000 genes.

Chapter Genes: Organisms have thousands of genes that determine individual traits They are lined up on chromosomes 1 chromosome holds genes.
CH 10.2 Meiosis.

CH 10.2 Meiosis.
Oh! MEIOSIS Cell division in which one DIPLOID CELL produces four HAPLOID CELLS called sex cells or gametes Meiosis is reduction division; the cells produced.

Oh! MEIOSIS Cell division in which one DIPLOID CELL produces four HAPLOID CELLS called sex cells or gametes Meiosis is reduction division; the cells produced.
Background information for Sexual Reproduction

Background information for Sexual Reproduction
Cell Divison.  Each of your body cells has 46 chromosomes, or 23 pairs.  Each pair is made of HOMOLOGOUS CHROMOSOMES Homo = same These chromosomes contain.

Cell Divison.  Each of your body cells has 46 chromosomes, or 23 pairs.  Each pair is made of HOMOLOGOUS CHROMOSOMES Homo = same These chromosomes contain.
Meiosis & Sexual Reproduction.

Meiosis & Sexual Reproduction.
Meiosis.

Meiosis.
Meiosis  Human body cells have 46 chromosomes Meiosis (sexual reproduction) - General Overview Sexual Reproduction and Genetics  Each parent contributes.

Meiosis  Human body cells have 46 chromosomes Meiosis (sexual reproduction) - General Overview Sexual Reproduction and Genetics  Each parent contributes.
Meiosis Review Chapter 11.

Meiosis Review Chapter 11.
Reduction of Chromosomes. Mitosis Cell duplication (or reproduction) where one cell creates two genetically identical daughter cells Cellular reproduction,

Reduction of Chromosomes. Mitosis Cell duplication (or reproduction) where one cell creates two genetically identical daughter cells Cellular reproduction,
MEIOSIS By Diana Bivens. Meiosis vs. Mitosis Mitosis: period of nuclear division in which two daughter cells are formed, each identical to the parent.

MEIOSIS By Diana Bivens. Meiosis vs. Mitosis Mitosis: period of nuclear division in which two daughter cells are formed, each identical to the parent.
Cell Reproduction Meiosis aka Cell Division. Meiosis Cell division where one diploid cell (2n) produces four haploid (n) cells called sex cells or gametes.

Cell Reproduction Meiosis aka Cell Division. Meiosis Cell division where one diploid cell (2n) produces four haploid (n) cells called sex cells or gametes.
DNA and Mitosis review/Meiosis How do your cells divide?

DNA and Mitosis review/Meiosis How do your cells divide?
10.2 MEIOSIS Martin 2022. GENES, CHROMOSOMES, AND NUMBERS A. Dipolid and Haploid Cells: ▫Diploid Cells: cell that have two of each kind of chromosome.

10.2 MEIOSIS Martin GENES, CHROMOSOMES, AND NUMBERS A. Dipolid and Haploid Cells: ▫Diploid Cells: cell that have two of each kind of chromosome.

Similar presentations

Ads by Google