Mental Warm-up reflection (Question of the Day) 1/27/2015 Sexual reproduction is when a new organism is made using genetic information from two parents. Why do siblings (brothers and sisters) not all look exactly like either each other or either of their parents?
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Introduction to Genetics Chapter 11.4 in the text book Meiosis—a special type of cell division that produces gametes which have half of the DNA of the body (somatic cells). Fertilization—combining one sperm and one egg to generate a zygote (1st cell of the embryo). Mitosis—growth of the zygote by asexual cell division.
Assortment of chromosomes into offspring during meiosis determines the inheritance of traits by offspring of sexual organisms. The karyotype below, made from a developing human embryo, shows that a child inherits 23 pairs of chromosomes: 1 each from mom & dad. Colors are due to DNA probes (tags) that match similar sequences of DNA. http://learn.genetics.utah.edu/content/chromosomes/intro/
Each chromosome carries a particular set of genes, always in the same places. Your body (somatic) cells contain two copies of each chromosome, so two copies of each gene; this is called diploid.
What is the diploid (2n) number of chromosomes in humans? Telomeres of the shorter p arms What is the diploid (2n) number of chromosomes in humans? 46 How many pairs of homologous chromosomes do humans have? 23 pairs centromere Paired sister chromatids Telomeres of the longer q arms http://learn.genetics.utah.edu/content/chromosomes/readchromosomes/
The chromosomes of a somatic cell diagrammed below are arranged in a karyotype, the 46 chromosomes have been arranged in homologous pairs.
The paired chromosomes (for example, pair #1 or pair #2) are homologous chromosomes; this means that they are long double helices of DNA that: 1) are the same length; 2) contain the same genes in the same order; and 3) are connected at their centromeres at the same location
Chromosomes number 1 - 22 are called autosomal (somatic or body) chromosomes. The 23rd pair of chromosomes determines the sex of the individual and are called sex chromosomes The sex chromosomes of a female human are XX. The sex chromosomes of a male human are XY.
What is the sex of person A? male How do you know? Y Chromosome What is the sex of person B? female X Only Are the X & Y chromosomes the same size and shape? NO—Y is smaller because it contains fewer genes What is the diploid number of chromosomes of person A? 46 What is the diploid number of chromosomes of person B?
Sexual reproduction is made possible by a process called meiosis that halves the number of chromosomes while generating special reproductive cells called gametes or sex cells. Male gametes are called sperm, while female gametes are called eggs or ova. Gametes receive one member of each homologous pair from the parent’s somatic cells. This means that somatic cells are diploid (2n) since they have 2 pairs of homologous chromosomes, but gametes are haploid (1n) since they do NOT contain homologous pairs—just one of each! http://learn.genetics.utah.edu/content/inheritance/intro/
Somatic cell karyotype for a female (above), for a male (below) 2n=46 X Somatic cell karyotype for a female (above), for a male (below) 2n=46 Egg 1n karyotype 1n=23 Sperm 1n karyotype 1n = 23 X
Law of random segregation Law of independent assortment Meiosis is a type of cell division that results in your giving one of each chromosome to your child in a sex cell, sperm or egg. Having one copy of each chromosome is called haploid. Law of random segregation (one parental homologous chromosome, but not both, is passed into each gamete; it’s random whether the maternal or paternal chromosome will be passed) Law of independent assortment (the combination of maternal & paternal homologues passed to each gamete is unique)
3 sources of genetic variation in gametes for sexual reproduction Learn.genetics.utah.edu Tour of the basics What is heredity? formation of gametes with one or the other, but not both, homologues==random segregation mixing up the set of your paternal & maternal chromosomes during meiosis 1 ==independent assortment
3rd source of variaton: formation of tetrads (both homologues on same spindle, exchanging matching genes) during cross over
4th source of variation—mistakes in DNA copying (DNA replication) called mutations 5th source—random use of gametes made 6th source—different mate combinations
Asexual reproduction or growth/repair of organisms utilizes mitosis (think My—two—sis) 1 cell divides into two genetically identical daughter cells
Mitosis generates two genetically identical cells because the 2 copies of each chromosome are separated into two new daughter cells. The original cell is called the mother cell.
The only reason mitosis generates genetic differences is mistakes in copying DNA Mutations Mutations are sometimes bad, but sometimes they generate helpful or harmless differences alleles giving unique traits.
Stages of mitosis from mother cells to genetically identical to 2 daughter cells. http://highered.mcgraw-hill.com/sites/0073031216/student_view0/exercise13/mitosis_movie.html http://highered.mcgraw-hill.com/sites/0072495855/student_view0/chapter2/animation__mitosis_and_cytokinesis.html
For sexual reproduction specialized cells called gametes (male sperm, female eggs) are required These cells must have only 1 copy of each chromosome, not 2 Meiotic (meiosis, think my-o-sex) cell division generates 4 gametes with only 1 copy of each of the parent’s original pair of homologous chromosomes How? Copy the DNA once, then divide twice.
Law of random segregation Law of independent assortment Meiosis is a type of cell division that results in your giving one of each chromosome to your child in a sex cell, sperm or egg. Having one copy of each chromosome is called haploid. Law of random segregation (one parental homologous chromosome, but not both, is passed into each gamete; it’s random whether the maternal or paternal chromosome will be passed) Law of independent assortment (the combination of maternal & paternal homologues passed to each gamete is unique)
Meiosis (think My-O!-4-sex) Mitosis (think My-2-sis) Asexual reproduction most often used in unicellular organisms Produces 2 somatic daughter cells 1 Diploid2 diploid cells Copy DNA once, divide up copied DNA once Genetically identical cells No crossing-over No random assortment No random segregation Occurs in all of the body except sex organs For growth, repair, asexual reproduction Sexual reproduction most often used in multicellular organisms Produces 4 sex cells called gametes 1 Diploid4 haploid cells Copy DNA once, divide up copied DNA twice Genetically unique cells USES crossing-over USES random assortment USES random segregation Occurs only in sex organs For making gametes only
Mit-2-sis eukaryote cell division My-oh!-4-sex Mitosis both meiosis Mit-2-sis eukaryote cell division My-oh!-4-sex Asexual produces new cells sexual Produces 2 somatic cells replicate DNA once produces 4 gametes 1 Diploid2 diploid use a spindle 1 diploid4 haploid 1 round division 2 rounds division Genetically identical genetically unique No crossing-over crossing over No random assortment random assortment No random segregation random segregation In all of the body except sex organs in only sex organs For growth, repair, asexual reproduction for sexual reproduction only
II. Pedigree Notes A “family tree” record that shows how a trait is inherited over several generations is called a pedigree. Pedigrees are very helpful because they allow people to trace genetic disorders over several generations.
1. A represents a Male and a represents a Female. Symbols you will need to know: 1. A represents a Male and a represents a Female. A shaded represents a Male with the trait but a white represents a Male without trait. A shaded represents a Female with the trait but a white represents a Female without trait
Sometimes a square or a circle is partially shaded (half shaded), this means that the individual is heterozygous for a recessive allele. (They are known as “carriers” and their gentotype is Aa.) 5. A marriage is symbolized by a straight line. 6. Offspring are symbolized by brackets underneath the parents
What do the Roman numerals symbolize? Generations II. III. What do the Roman numerals symbolize? Generations Do you remember? – is having hitchhiker’s thumb a dominant or a recessive trait
Final challenge: Can you give the genotypes for each person in Mr. Heilemann’s family? Next to where you wrote each person’s name, give the genotypes (using N” and “n” – remember, each person has TWO alleles for this trait.