Transcript Meiosis
1. 2. 3. 4. Attendance Test Information Review powerpoints Time to work on owed work. Division of Sex Cells A process of reduction division in which the number of chromosomes per cell is cut in half through the separation of homologous chromosomes in a diploid cell. Diploid – 2 sets of chromosomes Haploid – 1 set of chromosomes Homologous – chromosomes that each have a corresponding chromosome from the opposite sex parent Meiosis usually involves 2 distinct stages Meiosis I Meiosis II Each chromosome pairs with its corresponding homologous chromosome to form a tetrad. There are 4 chromosomes in a tetrad. The pairing of homologous chromosomes is the key to understanding meiosis. Crossing-over may occur here Crossing-over is when chromosomes overlap and exchange portions of their chromatids. Spindle fibers attach to the chromosomes The fibers pull the homologous chromosomes toward opposite ends of the cell. Nuclear membranes form. The cell separates into 2 cells. Meiosis I results in two haploid (N) cells. Each cell has half the number of chromosomes as the original cell. The chromosomes line up similar to metaphase in mitosis. Sister chromatids separate and move to opposite ends of the cell. Meiosis II results in 4 haploid cells. In males, meiosis results in 4 sperm cells In females, meiosis results in 1 egg cell and three polar bodies, which are not used in reproduction. Results in Cells are Occurs in Mitosis 2 Diploid Cells (2N) Genetically Identical Somatic (Body) Cells Meiosis 4 Haploid Cells (N) Genetically Different Sex Cells Name That Whatzitdoing! Getting ready to divide Lining up on the equator Separating to the poles Mitosis! Now there are 2 cells! Meiosis! Of course! End up with 4 cells, not 2 as in mitosis Humans have 46 chromosome s, so gametes have HALF that number 23 4 functional (all 4 work) sperm Right! Only one! Mitosis Cell division for All cells what kind of cells? EXCEPT for Meiosis ONLY gametes gametes Ends up with this many chromosomes compared to the species number of chromosomes Identical number as the species number (46 for humans) 1/2 the number as the species number (23 for humans) Ends up with this many cells 2 4 Ends up with this many FUNCTIONAL 2 4 for sperm but only Skin color comes from the pigment melanin Produced by melanocytes in skin cells More than 100 genes directly or indirectly influence amount of melanin in an individual’s skin Lead to many variations in skin color Genes provide the instructions for all human traits, including physical features and how body parts function Each person inherits a particular mix of maternal and paternal genes Genes Humans have ~21,500 Chemical instructions for building proteins Locus: specific location on a chromosome Diploid cells contain two copies of each gene on pairs of homologous chromosomes Allele: each version of a gene Homozygous condition: identical alleles Heterozygous condition: different alleles Dominant allele Effect masks recessive allele paired with it Genetic representations Genotype Homozygous dominant (AA) Homozygous recessive (aa) Heterozygous (Aa) Inherited alleles Phenotype Observable functional or physical traits DNA consists of two molecules that are arranged into a ladder-like structure called a Double Helix. A molecule of DNA is made up of millions of tiny subunits called Nucleotides. Each nucleotide consists of: 1. 2. 3. Phosphate group Pentose sugar Nitrogenous base Phosphate Nitrogenous Base Pentose Sugar The phosphate and sugar form the backbone of the DNA molecule, whereas the bases form the “rungs”. There are four types of nitrogenous bases. A Adenine C Cytosine T Thymine G Guanine Each base will only bond with one other specific base. Adenine (A) Thymine (T) Cytosine (C) Guanine (G) Form a base pair. Form a base pair. Because of this complementary base pairing, the order of the bases in one strand determines the order of the bases in the other strand. A T C G T A C G A T G C T A To crack the genetic code found in DNA we need to look at the sequence of bases. The bases are arranged in triplets called codons. AGG-CTC-AAG-TCC-TAG TCC-GAG-TTC-AGG-ATC A gene is a section of DNA that codes for a protein. Each unique gene has a unique sequence of bases. This unique sequence of bases will code for the production of a unique protein. It is these proteins and combination of proteins that give us a unique phenotype. DNA Gene Protein Trait DNA and RNA Unified Science DNA: Deoxyribonucleic Acid • Made up of nucleotides • Building block of DNA • Contains: – Phosphate – Sugar – Nitrogen Base DNA: Deoxyribonucleic Acid •Adenine •Thymine •Guanine •Cytosine Deoxyribose Base Pairing RULE • Adenine pairs with Thymine A T • Guanine pairs with Cytosine G C Each base pair is connected by a hydrogen bond Backbone has covalent bonds DNA Founders • James Watson • Francis Crick • Rosalind Franklin • Maurice Wilkins 1962 Noble Prize Double Helix There is approximately 6.5 feet of DNA in one single human cell and 10 – 20 billion miles of DNA in the whole body!!! RNA: Ribonucleic Acid •Adenine •URACIL •Guanine •Cytosine RIBOSE DNA vs. RNA DNA RNA Sugar Deoxyribose Ribose Nitrogen Base Structure Thymine Uracil Double Stranded Single Stranded DNA RNA Protein 3 Types of RNA: • Messenger RNA (mRNA) – carries genetic information from nucleus to cytoplasm • Transfer RNA (tRNA) – carries amino acids from cytoplasm to ribosomes • Ribosomal RNA (rRNA) – consists of RNA nucleotides in globular form Transcription • Process of genetic information being copied from DNA to RNA Translation • Process of genetic information being changed from RNA into amino acids • Codon - 3 mRNA nucleotides that code for amino acids • Anticodon - 3 tRNA nucleotides that complement mRNA codon Translation & Transcription RNA Ribonucleic Acid Structure of RNA Single stranded Ribose Sugar 5 carbon sugar Phosphate group Adenine, Uracil, Cytosine, Guanine Types of RNA Three main types Messenger RNA (mRNA) – transfers DNA code to ribosomes for translation. Transfer RNA (tRNA) – brings amino acids to ribosomes for protein synthesis. Ribosomal RNA (rRNA) – Ribosomes are made of rRNA and protein. Transcription RNA molecules are produced by copying part of the nucleotide sequence of DNA into complementary sequence in RNA, a process called transcription. During transcription, RNA polymerase binds to DNA and separates the DNA strands. RNA polymerase then uses one strand of DNA as a template from which nucleotides are assembled into a strand of mRNA. mRNA How Does it Work? RNA Polymerase looks for a region on the DNA known as a promoter, where it binds and begins transcription. RNA strands are then edited. Some parts are removed (introns) - which are not expressed – and other that are left are called exons or expressed genes. The Genetic Code This is the language of mRNA. Based on the 4 bases of mRNA. “Words” are 3 RNA sequences called codons. The strand aaacguucgccc would be separated as aaa-cgu-ucg-ccc the amino acids would then be Lysine – Arginine – Serine - Proline Genetic Codes Translation During translation, the cell uses information from messenger RNA to produce proteins. A – Transcription occurs in nucleus. B – mRNA moves to the cytoplasm then to the ribosomes. tRNA “read” the mRNA and obtain the amino acid coded for. C – Ribosomes attach amino acids together forming a polypeptide chain. D – Polypeptide chain keeps growing until a stop codon is reached. Mutations Gene mutations result from changes in a single gene. Chromosomal mutations involve changes whole chromosomes. Gene Mutation Point Mutation – Affect one nucleotide thus occurring at a single point on the gene. Usually one nucleotide is substituted for another nucleotide. Frameshift Mutation – Inserting an extra nucleotide or deleting a nucleotide causes the entire code to “shift”. Gene Mutation Chromosomal Mutations Deletion – Part of a chromosome is deleted Duplication – part of a chromosome is duplicated Inversion – chromosome twists and inverts the code. Translocation – Genetic information is traded between nonhomologous chromosomes. Chromosomal Mutations Gene Regulation In simple cells (prokaryotic) lac genes which are controlled by stimuli, turn genes on and off. In complex cells (eukaryotic) this process is not as simple. Promoter sequences regulate gene operation.