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DNA The Code of Life Mrs. Goodwin Deoxyribonucleic acid The Molecule Shape was discovered by James Watson and Francis Crick- Nobel Prize 1962 Found in all of the 80 trillion cells in the adult human body About 6 billion base pairs stretching out to be about 6 meters long, in every single cell. Found in every living thing in the world; plants, animals and bacteria! Why is DNA Important? Different amounts of DNA are found in different organisms. 6 billion in human cells 6 million in bacteria The more base pairs in an organism, the more complex the organism! DNA is comprised of genes which are the basic unit of inheritance. What Is a Gene? A section of DNA which codes for polypeptide chains (proteins) on a one-to-one basis For every gene there is one unique protein produced. Cell to Gene GENES A section of DNA Part of Chromosomes Found in cell nucleus Basic unit of inheritance! Code for specific proteins! (Polypeptides) Comprised of nucleotides What are Proteins? A diverse and abundant class of biomolecules which make up about 50% of the dry weight of a cell VIP- Play a central role in all aspects of cell structure and function Remember ribosome and Endoplasmic Reticulum Each is uniquely tailored to play a particular role in the cell - a specific protein for specific function Proteins Long chains of Amino Acid molecules Made from combinations of 20 different Amino Acids The building blocks of a cell Proteins/ Polypeptides: Chains of Amino Acids Protein Again The properties of a protein depends on: every single amino-acid molecule in the chain AND the order of the amino-acid molecules With 20 amino-acids, you can make an INFINITE NUMBER OF DIFFERENT aminoacid molecules !!! These molecules can then be arranged in an infinite number of sequences all producing different proteins The pattern for proteins unique tailoring is found encoded in the specific sequences of the nucleotides in DNA. Proteins = Polypeptides They have an amino-terminal or N-terminal end and a carboxyl-terminal or C-terminal end. (read from N to C) Proteins are important because they interact with other molecules as: 1. 2. 3. 4. regulators of gene activity enzymes transporters Central role in structural elements Controlling Protein Production This is VIP! Because they play a huge role in maintaining life ! proteins in the form of enzymes are responsible for each step of all biochemical series reactions. Each step of a biochemical reaction requires a unique enzyme in order to proceed. These biochemical reactions are how all of the processes of life take place. Proteins act as transporters between cells allowing for communication. Proteins make up a large portion of the structure of tissues. How Does DNA Control Life? DNA (genes) control life processes because they control protein production! One Gene -One Enzyme: Each enzyme is the product of one gene. If the gene is there, the enzyme can be produced, and that step of a biochemical series can proceed; if the gene is not there (or has mutated), the enzyme may not be produced, and that step may not proceed! DNA CODES FOR PROTEINS THROUGH SEQUENCED NUCLEOTIDES What are Nucleotides ? Remember* genes are Comprised of nucleotides Nucleotides consist of: One five-carbon sugar, One phosphate group One organic nitrogenous base. Nucleotides In DNA In DNA, the pentose(5 carbon) sugar is always deoxyribose The phosphate group: always one phosphate molecule bonding with four oxygen molecules. VARY in the nitrogenous base (this one in adenine) 4 Nitrogenous Bases in DNA Nitrogenous Bases in DNA PLEASE NOTE THESE ARE NOT AMINO ACIDS! Fall into two categories. The pyrimidines, the smaller of the two, have a ring of six carbon molecules. cytosine (C) and thymine (T) The purines, the larger group each has the six carbon structure AND a five carbon ring fused onto it. Adenine (A) and guanine (G) Base Pairing in DNA adenine (A) can only form a hydrogen bond with thymine (T) to make a base pair, guanine (G) can only bond with cytosine (C) This A-T / G-C pairing is very important in the function of DNA Differences in Base Pairing in DNA Adenine and Thymine are connected by two hydrogen bonds Guanine and Cytosine are connected by three hydrogen bonds The DNA Chain The pairing of the nucleotides with the nitrogenous bases are held together by a backbone of the pentose sugars and the phosphate groups, called the DNA chain. The Double Helix DNA twists around an imaginary axis and becomes a shape called the double helix, (like a spiral staircase) This helix consists of two separate strands running in opposite directions This helix helps the extremely long DNA fit into a tiny space. DNA Packaging DNA is packed into separate chromosomes which are long strands of DNA coiled with some additional protein molecules condensed into discreet units. All species have a characteristic number of chromosomes, humans have 46 chromosomes. They appear as "X's" because the DNA has replicated, making two identical strands connected at a central structure called the centromere. DNA to Chromosome Structure DNA and proteins are packaged into structures called chromosomes. How does DNA Make Proteins? The order of the amino acids in protein is determined by DNA through the genetic code A sequence of 3 nucleotides in the genetic code specify each amino acid as well as start and stop protein synthesis The Steps of Protein Synthesis Occur in the cell Step 1: Zip open the DNA double helix that contains the part of the GENE used to make the needed protein Step 2: Copy the GENE (a part of the DNA) producing messenger RNA (mRNA) Step 3: Transport the mRNA to a Ribosome organelle which constructs proteins. Step 4: The mRNA is "shifted" through the Ribosome; while transfer RNA (tRNA) transfers amino-acid molecules to the Ribosome to be "strung together" - ONLY the RIGHT amino-acid can be strung into the NEXT spot in the chain: Transcription and Translation Transcription: where DNA is copied making mRNA mRNA is similar to DNA –it has 4 nucleotide bases but does not have thymine(T), the base uracil(U) replaces T Translation: where ribosomes read the mRNA and translates it into the amino acid sequence of the protein AUG is the start signal- 3 nucleotides are read at a timecalled a codon Each codon specifies a particular amino acid UAA,UAG and UGA are stop signals, they indicate the protein is complete Transcription the information stored in a gene’s DNA is transferred to a similar molecule called RNA (ribonucleic acid) in the cell nucleus. The type of RNA that contains the information for making a protein is called messenger RNA (mRNA) because it carries the information, or message, from the DNA out of the nucleus into the cytoplasm RNA polymerase (an enzyme) transcribes DNA to make messenger RNA (mRNA). Translation the second step in getting from a gene to a protein, takes place in the cytoplasm The mRNA interacts with a specialized organelle in the rough ER called a ribosome, which “reads” the sequence of mRNA bases Each sequence of three bases, called a codon, codes for one particular amino acid (the building blocks of proteins). tRNA assembles the protein, one amino acid at a time. Protein assembly continues until the ribosome encounters a “stop” codon. Translation Molecular Look At Transcription and Translation Protein Synthesis Gene expression The journey from gene to protein is complex and tightly controlled within each cell. Together, transcription and translation are known as gene expression. How does DNA code for proteins? Genes code for proteins via the molecular trilogy: DNA -> RNA, -> amino acids Proteins are made of 20 different amino acids (polypeptide) Primary Protein Structure Protein then folds into a three dimensional shape Sometimes Combines With Other Proteins Deciphering the Genetic Code What is code? Representation of information Allows transferring and storing information Examples of Codes Morse code A B C D E F .-... -.-. -.. . ..-. Braille Codes Letters to Stories Letter codes can make words Words make sentences Sentences make paragraphs Paragraphs make stories or reports etc DNA to Life Stories Dna codons make amino acids Amino acids make proteins Proteins make structures and are enzymes These make all life systems and stories