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Heredity EOC review
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Unit Essential Question What are the principal mechanisms by which living things reproduce and transmit hereditary information from parents to offspring? Mendelian genetics Law of Segregation Law of Independent Assortment Punnett squares Meiosis DNA Sugar – deoxyribose; Nitrogenous bases (A, T, G, C) Complimentary base pairing DNA replication RNA Sugar – ribose; Nitrogenous bases (A, U, G, C) Types of RNA (mRNA, tRNA, ribosomal RNA) Protein Synthesis Transcription and Translation Genetic Engineering Cloning, transgenic organisms, methods of genetic engineering (restriction enzymes, gel electrophoresis, PCR)
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DNA structure and replication
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DNA – deoxyribonucleic acid Found in nucleus of eukaryotic cells. In the cytoplasm of prokaryotic cells. DNA is present to provide all the instructions the cells needs in order to perform. It codes for proteins which determine your traits (phenotype) and everything about you
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DNA molecule Double helix “twisted ladder” Made up of two strands of nucleotides The bases of each nucleotide are held together by hydrogen bonds (which break during replication) A=T and G=C (Chargaff’s Rule) Nitrogenous bases Adenine Guanine Thymine Cytosine
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Nucleotide
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Process of DNA replication The twisted ladder unwinds The hydrogen bonds breaks so that the two strands can separate from one another (like unzipping a jacket) Each strand acts as a template for the complementary strand (following the rules of base pairing) The new DNA strands each consists of an original strand and an old strand
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Process of DNA replication
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Protein Synthesis
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Proteins Made up chains of amino acids A protein’s shape and function is determined by the combination and arrangement of these amino acids. Proteins are assembled on ribosomes (organelles found in the cytoplasm)
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DNARNA Double stranded (double helix) Stays in the nucleus Contains bases A, T, C, and G Linear and in nucleus in eukaryotic cells, circular and in cytoplasm in prokaryotic cells Single stranded Used in the cytoplasm Contains bases A, U, C, and G Comes in 3 forms: mRNA, tRNA, rRNA
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Types of RNA mRNA: codes for amino acids. This is the “blueprint” or the set of instructions for building the protein rRNA: reads the message on the mRNA strand tRNA: carries the amino acid to the site of proteins synthesis. Contains an anticodon that complements the mRNA strand.
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Transcription Occurs in the nucleus DNA is transcribed into the mRNA strand Remember that RNA contains uracil (U) instead of thymine (T)
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Genetic Code: a chart that separates the codons into the amino acid that it codes for
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Translation mRNA leaves nucleus and goes into cytoplasm finds rRNA for the message to be read and translated ribosome travels down mRNA strand until it finds AUG - the start codon remember the strand is read 3 bases at a time the tRNA with the anticodon (corresponding code)brings the correct amino acid to the site to build a polypeptide chain (protein) amino acids connect to the one before it and the process continues until the rRNA reaches the end/stop codon on the mRNA strand (UAA, UAG, UGA)
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Mendelian Genetics
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Purebred individuals (homozygous) Have only one kind of gene for a trait Alleles Variety of genes P generation (parental generation/parents) F 1 generation (first generation)
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HomozygousHeterozygous Pure Contains the same alleles, both are dominant or both are recessive (AA, aa) Interbred Contains 2 different alleles (Aa) Dominant AllelesRecessive Alleles Use a capital letter As long as the dominant allele is present, the organism will show that phenotype Uses a lower case letter Organism will only show the trait if a dominant allele is NOT present
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Law of Segregation States that alleles are always divided so the offspring get one from each parent Punnett Square Show all the possible combinations of alleles from a genetic cross
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GenotypePhenotype Genetic makeup of an organism Based on the gene combinations Examples: BB, Bb, bb Physical characteristics of an organism Determined by its genotype Examples: tall, short, yellow, blue Monohybrid CrossDihybrid Cross Shows only one trait at a timeUsed to study the patterns of inheritance of two traits at once Law of Independent Assortment: Genes inherited for one trait does not affect which gene is inherited for another trait. In general, genes for different traits are not linked. So, when gametes are produced, the genes for traits found on different chromosomes separate independently.
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Monohybrid cross
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Dihybrid cross (remember to FOIL each of the parents)
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Incomplete Dominance One allele is not completely dominant over another
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Codominance Both alleles contribute to the phenotype
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Multiple Alleles A gene that has more than one allele Remember that in blood typing that A and B are codominant.
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Polygenic Traits A trait that is controlled by more than one gene Provides a wide ranges of colors Example: skin color, height, eye color
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Chromosomes in humans Divided into two groups Autosomes (pairs 1-22) determine most characteristics except for gender Sex Chromosomes (pair 23) Sex Chromosomes for males: XY Sex Chromosomes for females: XX
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Normal Female (XX) Karyotype
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Sex-linked traits Determined by genes carried on a sex chromosome Recessive sex-linked traits appear most often in males Examples: color blindness, hemophilia
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Monohybrid cross for sex-linked traits Carrier mom Normal dad Normal femaleCarrier female Normal male Affected male
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Pedigree: a chart, family tree, used to trace the inheritance of a trait
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Human Genes Autosomal recessive Affects both sexes Skip generations Born to unaffected parents Autosomal Dominant (simple dominance) Affects both sexes DOES NOT skip generations Unaffected parents will not transmit the trait Copyright Pearson Prentice Hall
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Human Genes X linked recessive (sex-linked recessive) More males than females affected Skips generations Never directly passed from father to son All daughters of affected fathers are carriers Copyright Pearson Prentice Hall
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Meiosis and Genetic Variation
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Body cells are also known as somatic cells. They are diploid cells. Body cells (somatic cells) divide through the process of mitosis Sex cells are also known as gametes. These are haploid cells. Sex cells (gametes) are produced through the process of meiosis Diversity is caused by the crossing over process that occurs with the homologous chromosomes during prophase 1 of meiosis. This creates variation within a population.
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Human gametes have 23 chromosomes (haploid) Human somatic cells contain 46 chromosomes (diploid) Homologous chromosomes are chromosomes that have matching pairs of genes but may have different alleles
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MitosisMeiosis Makes new body cells that are diploid One set of PMAT 2 Daughter cells are genetically identical to the parent and to each other Makes sperm and egg cells (gametes) that are haploid 2 sets of PMAT (interphase only occurs once) 4 daughter cells that are genetically different from each other and from their parent due to crossing over in prophase I
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Nondisjunction Sometimes chromosomes fail to separate during meiosis and can cause disorders such as Down’s syndrome, Klinefelter’s syndrome, or Turner syndrome
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Nondisjunction
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Abnormal Karyotype (3 chromosomes on 21) as a result of nondisjunction
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Mutations and Genetic Disorders
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How are chromosomes and genes related Gene is the segment of a chromosome that codes for a particular trait.
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What must occur before the cell divides? Its chromosomes and DNA must replicate. This occurs during the S phase of interphase. If the DNA does not replicate correctly, this could lead to a mutation or a change in a gene or chromosome.
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Gene mutationsChromosomal mutations mutations that occur in a single gene Point Mutation involve changes in one or a few nucleotides substitution - one base is changed into another. only affects a single amino acid. known as "silent" mutation. Frameshift Mutations caused by point mutations: insertion (extra base is inserted) or deletions (a base is removed) whole reading frame is shifted and alters the code. as a result, this could alter what protein is made and may be unable to perform its normal functions. changes in a chromosomal number or structure. Four types: a. deletion-loss of part of a chromosome b. duplication-produce extra parts of a chromosomes c. inversion-reverse the direction of parts of a chromosome d. translocation-involves 2 chromosomes, a part breaks off of one and attaches to another
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Gene mutationsChromosomal mutations
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Somatic mutationsGerm mutations Mutations that occur in the body cells NOT passed from parent to offspring Can dramatically affect an individual Mutations that occur in gametes Can be passed from parents to offspring
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