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Sexual Reproduction. Let’s Review!. Mitosis is:. When a cell makes a copy of itself for: growth repair replacement . In mitosis:. Mother cell with a full set Of chromosomes (diploid number; a.k.a. 2n). Two daughter cells With a full set of Chromosomes (diploid number;
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Mitosis is: When a cell makes a copy of itself for: growth repair replacement
In mitosis: Mother cell with a full set Of chromosomes (diploid number; a.k.a. 2n) Two daughter cells With a full set of Chromosomes (diploid number; a.k.a 2n)
The Phases of Mitosis • Prophase • Metaphase • Anaphase • Telophase • Cytokinesis (you should ALL know these by heart by now!)
Mitosis Only body cells reproduce by mitosis (and some organisms too but we will talk about that later)
Chromosomes • Homologous chromosomes: the chromosomes that make a pair • They have the same length and same centromere position, and control the same inherited trait
Gametes • Sex cells that have half the # of chromosomes • Ensures that an organism has the same number of chromosomes from generation to generation • In humans, each gamete has 23 chromosomes • n = number of chromosomes in a gamete
Gametes • Haploid: n • Diploid: 2n (female n + male n) • When 2 human gametes combine through fertilization, 23 homologous chromosomes are formed
Meaning… Mom has 23 chromosomes Dad has 23 chromosomes You have 46 chromosomes
Meiosis • Process that creates gametes • Cell division that REDUCES the number of chromosomes • Occurs in reproductive structures • Mitosis maintains chromosome # • Meiosis reduces it by half by splitting homologous chromosomes • 2n n • Meiosis I and II
Interphase • Replication of DNA • Protein synthesis
Meiosis I Prophase I: • Crossing over: chromosome segments are exchanged between homologous chromosomes • Centrioles move to opposite poles • Spindle fibers form and bind to sister chromatids at the centromere
Meiosis I • Metaphase I: Homologous chromosomes line up at center of cell • Anaphase I: Homologous chromosomes separate and pulled to opposite ends of cell, chromosome # is reduced from 2n to n • Telophase I: Chromosomes reach poles • Each pole contains only one chromosome of the original homologous chromosomes
Meiosis II • Prophase II: chromosomes condense • Metaphase II: HAPLOID number of chromosomes line up at the equator • Anaphase II: sister chromatids are pulled apart • Telophase II: chromosomes reach poles and nuclear membranes and nuclei form
Meiosis II • The chromosomes DO NOT replicate between I and II • End result is 4 haploid cells, each with n number of chromosomes
Sexual vs. Asexual Reproduction • Asexual • The organism inherits all of its chromosomes from one parent • Individual is genetically identical to its parent
Genetics • Genetics: the study of heredity • Heredity: the passing of traits from parent to offspring (INHERITANCE)
Father of Genetics • Gregor Mendel • Austrian Monk who experimented with garden peas in 1866 • Noticed certain traits seemed to be passed from one generation to another
Mendel • Mendel worked with peas • Peas self-fertilize • Noticed some varieties always made green seeds, and some always made yellow seeds • Mendel cross-pollinated the peas by hand
Peas • Parent Generation (P): 1st line of crosses • First Generation(F1): offspring of the parent generation • F2 Generation: second cross, using the F1 offspring
He concluded… • There must be TWO forms of a gene controlled by different factors • ALLELES: alternative form of a single gene • For example, the gene height • Tall or short
Alleles • Dominant: represented by a capital letter (T = tall • This is the trait that is seen • Recessive: represented by a lowercase letter (t = short) • This trait is not seen, it is masked by the dominant allele ~ it’s there, just hidden!
Dominance • If the dominant allele is present, it will show up • There must be 2 recessive alleles (one from each parent) in order to show up
Alleles • Since alleles are inherited from each parent, they can be the same or different • Homozygous: individual inherits 2 of the same allele • TT – homozygous dominant • tt – homozygous recessive • Heterozygous: individual inherits 2 different alleles, one dominant and one recessive • Tt • Since the dominant allele is present, it will show
So… • If presence of dimples is a recessive trait, and no dimples is dominant, what alleles would you see for – • An individual with dimples • An individual without dimples
Genotype & Phenotype • Genotype: organism’s allele pairs • Heterozygous, homozygous dominant, or homozygous recessive • Phenotype: observable appearance of genes
Putting it all Together… GENOTYPE (HETEROZYGOUS) Tt = Tall ALLELE ALLELE PHENOTYPE
Law of Segregation • Two alleles for a trait separate during meiosis • Each gamete will have a different allele • They will be reunited during fertilization
Punnett Square • Used to predict the possible offspring between two known genotypes • Monohybrid: crossing one trait at a time
Punnett Square Parent 2 – Pure Tall F1 Generation Parent 1- Pure Short
Tongue Rolling • Dominant Trait ~ T • 2 parents are heterozygous (Tt) for the trait • What possible phenotypes will their children have? T t Tt TT T Tongue roller Tongue roller tt Tt t Non-tongue roller Tongue roller
Law of Independent Assortment • When your body makes gametes (during meiosis), your gametes only get one copy of each gene • Whatever copy goes into the gamete is random; the inheritance of one gene does not influence the inheritance of another gene; they are independent • Every person with brown hair doesn’t have brown eyes • Some genes are inherited together (LINKED) because the genes are very close to each other on the chromosome. • people with red hair are also fair-skinned.