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Coding for Life. Introduction Nucleic acids are very special chemicals in cells which have the information ... to control cellular activities, and concerned with the transmission of inherited characteristics.
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Coding for Life Introduction Nucleic acids are very special chemicals in cells which have the information ... to control cellular activities, and concerned with the transmission of inherited characteristics. All nucleic acids are made of simple repeating units (monomers), linked together to form lengthy strands, called nucleotides.
Coding for Life Nucleic acids There are two types of nucleic acids ... Deoxyribonucleic acid (DNA). This central nucleic acid is a major component of chromosomes. Found primarily in the nucleus, a small amount is found in mitochondria and chloroplast. Ribonucleic acid (RNA). Is involved in the ‘reading’ of the DNA information. Found in the nucleus and cytoplasm of cells.
General structure of nucleotides Nucleotidesare the building blocks (monomers) of the two different nucleic acids (RNA and DNA). The best way to understand the structure of DNA and RNA is to study the nucleotides. Each nucleotide consists of three parts: a sugarmolecule, a phosphate group, a nitrogenous base.
Detail of the 3 parts of nucleotides 1. Phosphate group DNA and RNA have the same phosphate group, which links adjacent sugars together into a strand of great length. 2. Sugars Deoxyribose sugar is found only in DNA. Ribose sugar is found only in RNA. DNA = Deoxyribose RNA = Ribose
3. Nitrogenous bases One example of a nitrogenous base occurs in each nucleotide. These bases comprise the coded genetic message. Two types of bases, namely, 3.1 Purines: Purine bases consist of a two-ringed structure, the longer bases. Two examples Adenine and Guanine. G
C 3.2 Pyrimidines Pyrimidine bases consist of a single-ringed structure, the shorter bases. Two examples for DNA only Cytosine and Thymine. Two examples for RNA only Cytosine and Uracil.
Nitrogenous bases for InRNA Thymine is replaced by Uracil
Coding for Life – DNA structure Deoxyribose sugar Phosphate group links two sugars together Two weak hydrogen bonds Three weak hydrogen bonds Complementary nitrogenous bases A simplified representation of a portion of a DNA molecule
Linking the nucleotides in a DNA molecule Step one: To form a single strand The deoxyribose sugar of one nucleotide joins with the phosphate group of another nucleotide. These nucleotides are joined by a strongsugar-phosphate bond. Step 2: Formation of a double strand A single strand is joined to another strand with complementary nitrogenous bases. These complementary bases are linked by weak hydrogen bonds. Phosphate group links two sugars together The phosphate group and the sugar form the frame (legs) and the base pairs form the steps of the ladder. The two strands together form a ladder-like structure.
A purine (long) and a pyrimidine • (short) base pair with each other. Why? • (Ensuring that the space/width between the two legs of the ladder stays the same) • Thymine (short) always pairs with Adenine (long). • Cytosine (short) always pairs with Guanine (long). Pairing of nitrogenous bases for DNA (complementary base pairs)
Cytosine is pairing with Guanine Thymine is pairing with Adenine Pairing of nitrogenous bases The total length of DNA in mammal cells is ± 2 meters – in your body ±10 billion km.
Number of nitrogenous bases • Because the nitrogenous bases are paired in a specific way the following deductions important: • The number of cytosine bases present in a specific DNA molecule is? • Equal to the number of guanine bases. • The number of Adenine in a specific DNA molecule = ? • number of Thymine. • In the cell the DNA ladder is not a flat structure. It is twisted and forms a double helix. See the two presentations below.
Introduction to DNA-replication Before cell division, it is necessary that DNA makes an exact copy of itself in order for identical genetic material to be passed on from original cell to new daughter cell. The process of making exact copies of the original DNA molecule is called DNA replication. This process is controlled by enzymes. The main activity during interphase (between cell divisions) is DNA replication
Process of DNA replication The double helix starts to unwind and forms a flat, ladder-like structure. The two strands ‘unzip’ because of the weak hydrogen bonds between the complementary bases are brokenalong its length by enzymes. The bases of the two strands becomeexposed. Each separate strand serves now as a template for the synthesis of a new complementary DNA strand.
Process of DNA-replication (cont.) Many free nucleotides in the nucleus become bonded to the exposed bases of the template to form the new complementary DNA strands. Complementary basis pairs always joins as follows; adenine of the template (exposed) with thymine of the new strand. Or thymine from the template with adenine from the nucleus by means of the weak hydrogen bonds. Cytosine of the template joins with guanine from the nucleus. As well as guanine from template with cytosine of the new strand.
Process of DNA replication Sugar molecules and the adjacent phosphate groups of the new nucleotides are linked by a sugar-phosphate bond. The enzyme DNA polymerase is responsible for linking an new nucleotide to the growing new complementary strand. Twonew identical DNA molecules are formed. They start to twist and form a double helix. (Use the diagrams on the next 3 slides to memorise the process)
Schematic representation of DNA replication Double helix unwinds and forms a flat, ladder-like structure Hydrogen bonds break template template
DNA replication continuous New bases bond with the correct pairs from each template Free nucleotides in nucleus plasm
Two identical DNA molecules are formed. Part of DNA molecule 2 Part of DNA molecule 1 Each DNA molecule forms a double helix.
Characteristics of a DNA molecule Is a very long molecule Has a double helix structure Sequence in which bases pairs can occur is unlimited. There are equal cytosine bases than guanine bases and equal adenine bases than thymine bases in a specific DNA molecule.
Functions of DNA • DNA carriers the coding for all inheritance characteristics. • The same genetic information is transferred from one cell to the next by DNA replication and cell division. • DNA controls the structure and functioning of a cell. • Proteins were produced according to the sequence of the bases in the DNA molecule. • DNA is able to make RNA (ribonucleic acid).