Biology Sylvia S. Mader Michael Windelspecht

Biology Sylvia S. Mader Michael Windelspecht
Chapter 10 Meiosis and Sexual Reproduction Lecture Outline See separate FlexArt PowerPoint slides for all figures and tables pre-inserted into PowerPoint without notes. 1 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1

Biology, 9th ed,Sylvia Mader
Chapter 10 Outline Meiosis & Sexual Reproduction 10.1 Halving the Chromosome Number 10.2 Genetic Variation 10.3 The Phases of Meiosis 10.4 Meiosis Compared to Mitosis 10.5 Human Life Cycle 10.6 Changes in Chromosome Number and Structure

10.1 Halving the Chromosome Number
Biology, 9th ed,Sylvia Mader Chapter 10 10.1 Halving the Chromosome Number Meiosis & Sexual Reproduction Meiosis Special type of cell division Used only for sexual reproduction Halves the chromosome number prior to fertilization Parents are diploid (2n) Meiosis produces haploid (n) gametes *

Halving the Chromosome Number
Biology, 9th ed,Sylvia Mader Chapter 10 Halving the Chromosome Number Meiosis & Sexual Reproduction In diploid body cells, chromosomes occur in pairs Humans have 23 different types of chromosomes Diploid (2n) cells have two chromosomes of each type Chromosomes of the same type are said to be homologous chromosomes (homologues) * Their centromeres are positioned in the same place When stained, they show similar banding patterns

Homologous Chromosomes
Biology, 9th ed,Sylvia Mader Chapter 10 Homologous Chromosomes Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. a. Sister chromatids nonsister chromatids duplication duplication kinetochore centromere chromosome homologous pair chromosome paternal chromosome maternal chromosome b. a: © L. Willatt/Photo Researchers, Inc.

Biology, 9th ed,Sylvia Mader Chapter 10 Halving the Chromosome Number Meiosis & Sexual Reproduction Homologous chromosomes have genes controlling the same trait at the same position Each gene occurs in duplicate A maternal copy from the mother A paternal copy from the father Many genes exist in several variant forms in a large population Homologous copies of a gene may encode identical or different genetic information * An individual may have: Identical alleles for a specific gene on both homologs (homozygous for the trait), or A maternal allele that differs from the corresponding paternal allele (heterozygous for the trait)

Biology, 9th ed,Sylvia Mader Chapter 10 Slide #7 Halving the Chromosome Number Meiosis & Sexual Reproduction Overview of Meiosis Meiosis I Chromosomes are replicated prior to meiosis I Each chromosome consists of two identical sister chromatids * Homologous pairs align themselves against each other side by side at the metaphase plate The two members of a homologous pair separate Each daughter cell receives one duplicated chromosome from each pair Meiosis II Sister chromatids separate and move to opposite poles The four daughter cells contain one daughter chromosome from each pair Each daughter chromosome consists of a single chromatid The daughter cells are haploid 7

Chapter 10 10.2 Genetic Variation Meiosis & Sexual Reproduction Meiosis brings about genetic variation in two key ways: * Crossing Over: Exchange of genetic material between non-sister chromatids during meiosis I At synapsis, a nucleoprotein lattice (called the synaptonemal complex) appears between homologues Holds homologues together Aligns DNA of non-sister chromatids Allows crossing-over to occur Then homologues separate and are distributed to different daughter cells

Crossing Over Occurs During Meiosis I
Biology, 9th ed,Sylvia Mader Chapter 10 Crossing Over Occurs During Meiosis I Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. nucleoprotein lattice sister chromatids of a chromosome sister chromatids of its homologue A A a a A a B B b b B b chiasmata of nonsister chromatids 1 and 3 c C C c C c D D d d D d 1 2 3 4 1 2 3 4 1 2 3 4 Bivalent forms Crossing-over has occurred Daughter chromosomes a. b. c. d. a: Courtesy Dr. D. Von Wettstein

Chapter 10 Genetic Variation Meiosis & Sexual Reproduction Independent assortment When homologous chromosome pairs align at the metaphase plate: * The maternal or paternal homologue may be oriented toward either pole of mother cell

Independent Assortment
Biology, 9th ed,Sylvia Mader Chapter 10 Independent Assortment Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Combination 7 Combination 3 Combination 5 Combination 1 Combination 2 Combination 4 Combination 6 Combination 8

Chapter 10 Genetic Variation Meiosis & Sexual Reproduction Fertilization – union of male and female gametes Chromosomes donated by the parents are combined In humans, (223)2 = 70,368,744,000,000 chromosomally different zygotes are possible If crossing-over occurs only once (423)2, or 4,951,760,200,000,000,000,000,000,000 genetically different zygotes are possible *

Chapter 10 Genetic Variation Meiosis & Sexual Reproduction Significance of genetic variation: Asexual reproduction produces genetically identical clones Sexual reproduction causes genetic recombinations among members of a population Asexual reproduction is advantageous when the environment is stable * Some offspring may have a better chance of survival

Chapter 10 10.3 The Phases of Meiosis Meiosis & Sexual Reproduction Meiosis I: Prophase I A spindle forms The nuclear envelope fragments The nucleolus disappears Each chromosome is duplicated (consists of two identical sister chromatids) Homologous chromosomes pair up and physically align themselves against each other side by side (synapsis) * Metaphase I Homologous pairs are arranged at the metaphase plate Bivalents are aligned independently of one another

Chapter 10 The Phases of Meiosis Meiosis & Sexual Reproduction Meiosis I Anaphase I Homologous chromosomes of each bivalent separate from one another Homologues move towards opposite poles Sister chromatids do not separate Each is still a duplicated chromosome with two chromatids Telophase I Daughter cells have one duplicated chromosome (n) from each homologous pair

Chapter 10 The Phases of Meiosis Meiosis & Sexual Reproduction Interkinesis Two haploid (n) daughter cells, each with one duplicated chromosome of each type Interkinesis is similar to mitotic interphase except It is usually shorter DNA replication does not occur

The Phases of Meiosis Chapter 10 Meiosis & Sexual Reproduction Meiosis II (mitosis of two haploid cells) Prophase II – Chromosomes condense Metaphase II – Chromosomes align at metaphase plate Anaphase II Centromere dissolves Sister chromatids separate and become daughter chromosomes Telophase II and cytokinesis Four haploid (n) cells all genetically unique

10.4 Meiosis Compared to Mitosis
Biology, 9th ed,Sylvia Mader Chapter 10 10.4 Meiosis Compared to Mitosis Meiosis & Sexual Reproduction Meiosis Requires two nuclear divisions Chromosomes synapse and cross over Centromeres survive Anaphase I Halves chromosome number Produces four daughter nuclei Produces daughter cells genetically different from parent and each other Used only for sexual reproduction Mitosis Requires one nuclear division Chromosomes do not synapse nor cross over Centromeres dissolve in mitotic anaphase Preserves chromosome number Produces two daughter nuclei Produces daughter cells genetically identical to parent and to each other Used for asexual reproduction and growth

Meiosis Compared to Mitosis
Biology, 9th ed,Sylvia Mader Chapter 10 Meiosis Compared to Mitosis Meiosis & Sexual Reproduction

Chapter 10 Meiosis Compared to Mitosis Meiosis & Sexual Reproduction

Chapter 10 Meiosis Compared to Mitosis Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 2n = 4 Prophase I Synapsis and crossing-over occur. MetaphaseI Homologous pairs align independently at the metaphase plate. Anaphase I Homologous chromosomes separate and move toward the poles. MEIOSISI 2n = 4 Prophase Metaphase Chromosomes align at the metaphase plate. Anaphase Sister chromatids separate and become daughter chromosomes. MITOSIS

Chapter 10 Meiosis Compared to Mitosis Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Telophase I Daughter cells are forming and will go on to divide again. n = 2 Daughter cells Sister chromatids separate and become daughter chromosomes. Four haploid daughter cells. Their nuclei are genetically different from the parent cell. n = 2 n = 2 MEIOSIS I cont'd MEIOSIS II Daughter cells Telophase Daughter cells are forming. Two diploid daughter cells. Their nuclei are genetically identical to the parent cell. MITOSIS cont'd

Chapter 10 10.5 The Cycle of Life Meiosis & Sexual Reproduction * In plants, haploid multicellular “individuals” alternate with diploid multicellular “individuals” (alternation of generations) The haploid individual: Is called the gametophyte May be larger or smaller than the diploid individual The diploid individual: Is called the sporophyte May be larger or smaller than the haploid individual Mosses are haploid for most of their life cycle In fungi and most algae, only the zygote is diploid Ferns & higher plants are diploid for most of their life cycles In plants, algae, and fungi gametes are produced by haploid individuals

Chapter 10 The Cycle of Life Meiosis & Sexual Reproduction In animals: “Individuals” are diploid and produce haploid gametes The only haploid part of the life cycle is the gametes The products of meiosis are always gametes Meiosis occurs only during gametogenesis Production of sperm Spermatogenesis All four cells become sperm Production of eggs Oogenesis One of the four nuclei receives the majority of the cytoplasm Becomes the egg or ovum Others wither away as polar bodies

Chapter 10 The Cycle of Life Meiosis & Sexual Reproduction Human Life Cycle: Sperm and egg are produced by meiosis A sperm and egg fuse at fertilization Results in a zygote The one-celled stage of an individual of the next generation Undergoes mitosis Results in a multicellular embryo that gradually takes on features determined when the zygote was formed All growth occurs as mitotic division As a result of mitosis, each somatic cell in the body Has same number of chromosomes as zygote Has the same genetic makeup, which was determined when the zygote was formed

Spermatogenesis and Oogenesis in Mammals Chapter 10 Meiosis & Sexual Reproduction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. SPERMATOGENESIS OOGENESIS primary spermatocyte primary oocyte 2 n 2n Meiosis I Meiosis I first polarbody secondary spermatocytes n secondary oocyte n Meiosis II n Meiosis II spermatids Meiosis II is completed after entry of sperm (fertilization) n second polarbody n Metamorphosis and maturation Fertilization egg n sperm Sperm nucleus n n fusion of sperm nucleus and agg nucleus zygote 2n

10.6 Changes in Chromosome Number and Structure
* Aneuploidy is a change in the chromosome number Results from nondisjunction

Changes in Chromosome Number and Structure
* The most common autosomal trisomy seen among humans is Trisomy 21 Also called Down syndrome Recognized by these characteristics: short stature eyelid fold flat face stubby fingers wide gap between first and second toes

a: © Jose Carrilo/PhotoEdit; b: © CNRI/SPL/Photo Researchers
Trisomy 21 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. extra chromosome 21 a. b. a: © Jose Carrilo/PhotoEdit; b: © CNRI/SPL/Photo Researchers

Changes in sex chromosome number: Results from inheriting too many or too few X or Y chromosomes Nondisjunction during oogenesis or spermatogenesis Turner syndrome (XO) Female with a single X chromosome Short, with broad chest and widely spaced nipples Can be of normal intelligence and function with hormone therapy

Changes in sex chromosome number: Klinefelter syndrome (XXY) Male with underdeveloped testes and prostate; some breast overdevelopment Long arms and legs; large hands Near normal intelligence unless XXXY, XXXXY, etc. No matter how many X chromosomes are present, the presence of a chromosome Y renders the individual male

Changes in Sex Chromosome
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. a. Turner syndrome missing chromosome X b. Klinefelter syndrome extra chromosome X a(top): Courtesy UNC Medical Illustration and Photograph; b(top): Courtesy Stefan D. Schwarz, a, b(bottom): © CNRI/SPL/Photo Researchers, Inc

Changes in chromosome structure include: Deletion * Two simultaneous breaks lead to loss of an internal segment Duplication Translocation Follows breakage of two non-homologous chromosomes and improper re-assembly

Changes in chromosome structure include: Inversion Occurs as a result of two breaks in a chromosome The internal segment is reversed before re-insertion Genes occur in reverse order in the inverted segment

Types of Chromosomal Mutation
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. a a a b b b b c c c c + a d d d d e e e e f d f f e g g g f g a. Deletion b. Duplication a a a a b b l b b l c m c c m d d n d n d c e o e o e e f p f p f f g q q g g g h r r h c. Inversion d. Translocation

b: Courtesy The Williams Syndrome Association
Deletion Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. a a b b + h deletion lost c c d d e e f f g g h a. b. b: Courtesy The Williams Syndrome Association

Biology Sylvia S. Mader Michael Windelspecht

Similar presentations

Presentation on theme: "Biology Sylvia S. Mader Michael Windelspecht"— Presentation transcript:

Similar presentations

About project

Feedback

Log in

Auth with social network:

Biology Sylvia S. Mader Michael Windelspecht

Similar presentations

Presentation on theme: "Biology Sylvia S. Mader Michael Windelspecht"— Presentation transcript:

Similar presentations

About project

Feedback