Simulating Genetic Screening

Slides:



Advertisements
Similar presentations
Biotechnology Chapter 11.
Advertisements

DNA Techniques Lab Preparation 13-1 Manipulating Genes Genetic Engineering: You can repair genes, insert genes, excise genes or replace genes with gene.
RESTRICTION ENZYMES & GEL ELECTROPHORESIS ANALYSIS OF PRECUT LAMBDA DNA.
GENETIC ENGINEERING. MANIPULATING GENES… Can we make our food taste better? Can we make humans live longer? Can we make X-men like mutants?!? Let’s start.
13-2 Manipulating DNA.
Start-up for Wednesday, January 5, 2011 Answer the following questions: 1.Identify and compare the two types of selective breeding. 2.Relate genetic variation.
Restriction Digestion and Analysis of Lambda DNA Kit
Ch. 13.4: DNA Technology Applications
Slide 1 of 32 Copyright Pearson Prentice Hall Biology.
III Manipulating DNA. The Tools of Molecular Biology How do scientists make changes to DNA? The Tools of Molecular Biology.
Technological Solutions. In 1977 Sanger et al. were able to work out the complete nucleotide sequence in a virus – (Phage 0X174) This breakthrough allowed.
DNA Technology.
13-1 Changing the Living World
Electrophoresis. A process that is used to sort fragments of DNA by placing the digested DNA in a special gel and adding electricity.
NIS - BIOLOGY Lecture 57 – Lecture 58 DNA Technology Ozgur Unal 1.
Manipulation of DNA. Restriction enzymes are used to cut DNA into smaller fragments. Different restriction enzymes recognize and cut different DNA sequences.
Warm-Up #33 Answer questions #1-5 on Text page 321, Section Assessment.
Review from last week. The Making of a Plasmid Plasmid: - a small circular piece of extra-chromosomal bacterial DNA, able to replicate - bacteria exchange.
Chapter 9: Genetic Engineering
Restriction Digestion and Gel Electrophoresis Laboratory.
Manipulating DNA. Scientists use their knowledge of the structure of DNA and its chemical properties to study and change DNA molecules Different techniques.
BIOTECHNOLOGY DNA is now being easily manipulated. Molecular biologists analyze and alter genes and their respective proteins. Recombinant DNA is DNA from.
Biology Chapter 9 & Honors Biology Chapter 13 Frontiers Of Biotechnology.
DNA Technology Ch. 20. The Human Genome The human genome has over 3 billion base pairs 97% does not code for proteins Called “Junk DNA” or “Noncoding.
Section 14-3: Studying the Human Genome. Manipulating DNA The SMALLEST human chromosome contains 50 million bases DNA is a HUGE molecule that is difficult.
Chapter 20 DNA Technology and Genomics. Biotechnology is the manipulation of organisms or their components to make useful products. Recombinant DNA is.
End Show Slide 1 of 32 Copyright Pearson Prentice Hall Biology.
Genetic Engineering and Biotechnology Notes. IB Assessment Statement 4.4.1Outline the use of polymerase chain reaction (PCR) to copy and amplify minute.
RESTRICTION ENZYMES & GEL ELECTROPHORESIS FORENSIC DNA FINGERPRINTING.
Biotechnology. Bell Work 1.You want to determine if a patient with leukemia has a mutation in a certain gene. What type of technology should you use and.
Studying and Manipulating Genomes
Biotechnology.
Forensic Investigation
Jeopardy Final Jeopardy Gene Cloning Plasmids Ligase PCR $100 $100
Copyright Pearson Prentice Hall
Copyright Pearson Prentice Hall
21.8 Recombinant DNA DNA can be used in
Chapter 13.2 Manipulating DNA.
Biotechnology CHAPTER 20.
Gene Isolation and Manipulation
PCR and RLFP’s.
How are areas of DNA that don’t code for proteins (genes) used by our cells? How can we make use of these areas?
KEY CONCEPT Biotechnology relies on cutting DNA at specific places.
The student is expected to: (6H) describe how techniques such as DNA fingerprinting, genetic modifications, and chromosomal analysis are used to study.
Agenda 4/24 Recombinant DNA warm up Gel Electrophoresis Techniques
Copyright Pearson Prentice Hall
Restriction Enzyme Analysis of Lambda DNA
Restriction Enzyme Analysis of Lambda DNA
Biotechnology: Restriction Enzyme Analysis of DNA
DNA ELECTROPHORESIS OR DNA FINGERPRINTING.
Sequencing and Copying DNA
Forensic Investigation
Biotechnology.
Copyright Pearson Prentice Hall
Recombinant DNA Unit 12 Lesson 2.
Restriction Digestion and Analysis of Lambda DNA Kit
Copyright Pearson Prentice Hall
Copyright Pearson Prentice Hall
Overview of Chapter 9.
Genetics and Biotechnology
Copyright Pearson Prentice Hall
Copyright Pearson Prentice Hall
KEY CONCEPT Biotechnology relies on cutting DNA at specific places.
History of DNA Fingerprinting
Biotechnology: Restriction Enzyme Analysis of DNA
Copyright Pearson Prentice Hall
KEY CONCEPT Biotechnology relies on cutting DNA at specific places.
Restriction Digestion and Analysis of Lambda DNA Kit
Genetic Engineering How do scientists use restriction enzymes?
Copyright Pearson Prentice Hall
Presentation transcript:

Simulating Genetic Screening Gel Electrophoresis Simulating Genetic Screening

Polymerase Chain Reaction (PCR) PCR is a method for making many copies of a targeted DNA sequence in a test tube PCR quickly copies and amplifies a few strands of DNA so the DNA can be manipulated and analyzed There are many similarities between PCR and DNA replication, in summary: Denaturation Step: 2 strands of DNA are separated Annealing Step: primers “anneal” or “base-pair” in preparation for DNA replication Extension Step: DNA replication occurs

Genetic Engineering: analysis of DNA fragments Gene Splicing: DNA from one organism can be combined with the DNA of a different organism DNA Sequencing: determine precise order of nucleotides in a DNA molecule Gene Localization: determine exactly where genes are located within a genome Forensic DNA Matching: determine the identity of a deceased person DNA Fingerprinting: aid in the solving of crimes

Cutting DNA DNA is very large and must be cut into smaller pieces to be analyzed Restriction Enzymes – made from proteins and come from bacteria. They are used to cut larger molecules of DNA 1,000s of restriction enzymes and they are named for the bacteria they come from Each restriction enzyme recognizes a specific nucleotide sequence in DNA, and cuts the DNA at the “restriction site”

Restriction Enzymes for Lab EcoRI (E. coli) HindIII (H. influenzae) Lambda DNA: bacteriophage (bacterial virus) that infects the 2 bacteria (Harmless to humans!)

Restriction Sites Palandromic: sequences of bases reads the same forward and backward (ex)Racecar EcoRI : GAATTC CTTAAG HindIII : AAGCTT TTCGAA

Gel Electrophoresis Separates and analyzes different sizes of DNA fragments Electric voltage is applied to a gel Negatively charged DNA moves to toward the positive end of the chamber Smaller DNA fragments will move faster and farther (will leave a banding pattern) Stains will make the bands of DNA visible The order of the bands in the gel tells the exact sequence of bases in the DNA

DNA Marker Lambda DNA cut with the HindIII and EcoRI restriction enzymes will be our DNA marker The genome from the bacteriophage lambda, a virus that infects E. coli When cut with the restriction enzymes, the lambda genome will yield DNA fragments of different sizes; from 21,226 bp to 125bp. (base pairs) 3530 bp fragment may not be visible because the ends of the fragment have overhanging strands of DNA which are capable of annealing If annealing occurs the fragments will combine to form a single 24,756bp fragment. The marker will be heated to 65 degrees Celcius for 10 minutes prior to loading the gels to ensure separation

Estimate Fragment Size Determine the approximate sizes of each of your restriction fragments. This can be done by comparing the fragments with the DNA fragments of known sizes. Measure the distance (in millimeters) that each fragment traveled from the well. Estimate its size, in base pairs, by comparing its position to the Lambda DNA marker.

Mathematical Formulas to Determine Fragment Size (more accurate) Formulas have been developed for describing the relationship between the molecular weight of a DNA fragment and its mobility (how far it runs in the gel) Graph the size of the known fragments from the marker against the distance each DNA band moved through the gel to generate a “standard curve”. X axis is distance traveled in mm Y axis is size of fragment in base pairs Use a vertical line from X axis to the point where your unknown fragment intersects the standard curve. This will determine the sizes of your unknown fragments.

Lab Procedure Day 1 Guided Inquiry Lab Background Pre- Lab Questions https://www.cff.org/

Lab Procedure Day 2 Introduction to Inquiry Lab Write up a proposal including: testable question, hypothesis, procedure, and method of data collection. Pouring an Agarose Gel – use one of 3 methods Loading the Gel Running the Gel Staining the Gel

Lab Procedure Day 3 Answer Lab Questions from previous day Read Scenario: Guided Lab – Simulated Genetic Screen Answer Pre-Lab Questions Perform the Guided Lab procedure

Lab Procedure Day 4 Calculate the Relative Mobility for each of the DNA fragments Complete the Data Table Plot the Standard Curve Use the Standard Curve to calculate the sample DNA fragments from Child 1 and Child 2 Answer Lab Questions and Analysis