3. DNA testing creates patterns unique to each individual. Key Idea:

4. 1.What is DNA? 2.How does DNA make me unique? 3.How is DNA used in profiling? 4.Why is “junk” DNA used in forensic profiling? Goals:

5. Historical Information w 1953--Watson and Crick discovered the structure of the DNA molecule w 1980--Ray White described the 1st polymorphic RFLP marker w 1985--Alec Jeffreys isolated DNA markers and called them DNA “fingerprints w 1985--Kary Mullis developed PCR testing w 1988--FBI starts DNA casework w 1991--First STR paper w 1998--FBI launches CODIS database w 2003--Completion of the Human Genome Project

6. DNA Structure w Double helix--two coiled DNA strands w Nucleotides--each unit contains a sugar (deoxyribose), a phosphate group and a nitrogen-containing base w Four Bases Adenine Cytosine Guanine Thymine w Bases always pair A--T and C--G

7. DNA Locations in the body w Can be found in all body cells--blood, semen, saliva, urine, hair, teeth, bone, tissue w Most abundant in our buccal (cheek) cells w Blood is 99.9% red blood cells that have no nuclei; and therefore, no nuclear DNA w DNA obtained from blood comes from white blood cells

8. Non-Coding Regions w Only one-tenth of a single percent of DNA (about 3 million bases) differs from one person to the next. Scientists use these regions to generate a DNA profile of an individual. w 97% is non-coding and is repetitive w 3% of the human DNA sequences code for proteins w 50% of the human genome has these interspersed repetitive sequences

9. DNA TYPING METHODS DNA typing methods create patterns that ultimately distinguish each individual.

10. KEY TO UNDERSTANDING The key to understanding DNA typing lies in the knowledge that within the world’s population numerous possibilities exist for the number of times a particular sequence of base letters can repeat itself on a DNA strand. The key to understanding DNA typing lies in the knowledge that within the world’s population numerous possibilities exist for the number of times a particular sequence of base letters can repeat itself on a DNA strand. Saferstein, Richard. Criminalistics An Introduction to Forensic Science

11. Forensic Testing will take advantage of the repeating sections of DNA 1. Looks at the tandem repeats 2. There are many versions of some of these repeats (polymorphic) 3. Remember: Half of the DNA is from the mother, half from the father

12. DNA TYPING “Fingerprinting” Methods wRFLP-- Restriction Fragment Length Polymorphism wPCR-- Polymerase Chain Reaction STR--Short Tandem Repeats Mitochondrial--use of maternal DNA in the mitochondria y-STR-only found in males

13. Restriction Fragment Length Polymorphism wUsing restriction enzymes, differing lengths of chromosome fragments are separated by electrophoresis. wA DNA fragment pattern will be created by electrophoresis

14. RFLP-Restriction Fragment Length Polymorphisms 1. Extract the DNA--from biological sample (blood, semen, saliva) 2. Add restriction enzymes-- which will cut the DNA at specific regions 3. Use electrophoresis-- to separate the DNA fragments by size 4. Detect regions-- using luminescent dyes or radioactive probes that will expose X-ray film

15. RFLP-Restriction Fragment Length Polymorphisms w Takes at least 10 weeks w Is very specific if multiple restriction enzymes are used w Requires a substantial sample size w The large number of base units (1000’s) per fragment make the fragments susceptible to breaking

16. PCR--Polymerase Chain Reaction PCR is a technique for making many copies of a defined segment of a DNA molecule. It looks at several regions of repeated bases. Every gene has at least two alternative forms called alleles. An individual receives one allele from mother and one from father. If the alleles are the same, the individual is said to be homozygous for the trait; if the two alleles are different, the individual is heterozygous.

17. PCR--Polymerase Chain Reaction steps w Heat the DNA strands to 94 degrees which causes the strands to separate (unzip). w Add primers to the separated strands. w The primers combine with the DNA strands. w Add DNA polymerase and a mixture of free nucleotides to the separated strands. w The tube is cooled down to 72 degrees which results in the rebuilding of a double- strand of DNA.

19. PCR The outcome is a doubling of the number DNA strands. Repeat 25 to 30 times, yielding more than one million copies of the original DNA molecule. Each cycle takes less than two minutes from start to finish.

20. Advantages of PCR w Minute amounts of DNA template may be used from as little as a single cell. Minute amounts of DNA template may be used from as little as a single cell. w DNA degraded to fragments only a few hundred base pairs in length can serve as effective templates for amplification. DNA degraded to fragments only a few hundred base pairs in length can serve as effective templates for amplification. w Large numbers of copies of specific DNA sequences can be amplified simultaneously with multiplex PCR reactions. Large numbers of copies of specific DNA sequences can be amplified simultaneously with multiplex PCR reactions. w Commercial kits are now available for easy PCR reaction setup and amplification. Commercial kits are now available for easy PCR reaction setup and amplification. Problem: Contaminant DNA, such as fungal and bacterial sources, will not amplify because human-specific primers are used.

21. Short Tandem Repeats (STR)  STR typing uses the PCR method STR typing uses the PCR method  STR’s are locations (loci) on the chromosome that contain short sequences of 3 to 7 bases that repeat themselves with the DNA molecule. STR’s are locations (loci) on the chromosome that contain short sequences of 3 to 7 bases that repeat themselves with the DNA molecule.  Advantages include a higher discrimination than RFLP, less time, smaller sample size, and less susceptible to degradation. Advantages include a higher discrimination than RFLP, less time, smaller sample size, and less susceptible to degradation.  In Forensic Science, 13 locations are used. In Forensic Science, 13 locations are used.

22. CODIS: Combined DNA Index System

23. Example: Using STR w Extract the gene TH01 from the sample. (TH01 has seven human variants and a repeating sequence of A-A-T-G) Extract the gene TH01 from the sample. (TH01 has seven human variants and a repeating sequence of A-A-T-G) w Amplify the sample by means of PCR Amplify the sample by means of PCR w Separate by electrophoresis Separate by electrophoresis w Examine the distance the STR migrates to determine the number of times TH01 repeats Examine the distance the STR migrates to determine the number of times TH01 repeats

24. Example con’t w Each person has two STR types for TH01-- one inherited from each parent. Each person has two STR types for TH01-- one inherited from each parent. w Continue the process with additional STRs from other genes Continue the process with additional STRs from other genes Imagine how the probability of a match DECREASES by using an INCREASING number of STRs.

25. STR Analysis  STR typing is visualized by peaks shown on a graph. Each represents the size of the DNA fragment. STR typing is visualized by peaks shown on a graph. Each represents the size of the DNA fragment.  The possible alleles are numbered for each loci. The possible alleles are numbered for each loci.

26. Profiler Plus Allelic Ladders D3S1358FGA VWA AMELD8S1179 D21S11 D18S51 D5S818 D13S317 D7S820

27. COfiler Allelic Ladders D3S1358 AMEL D7S820 D16S539 TH01 TPOX CSF1PO

28. My STR’s

30. Probability of Matching My STR’s

31. DNA Interactive Go to the website below to see a STR animation demonstration. Click on human identification, profiling and then on the third circle called Today’s DNA Profiling http://www.dnai.org/d/index.html

32. Electrophoresis  An electrical current moves through a substance causing molecules to sort by size. An electrical current moves through a substance causing molecules to sort by size.  Smaller, lighter molecules will move the furthest on the gel. Smaller, lighter molecules will move the furthest on the gel.

33. Three Possible Outcomes  Match--The DNA profile appears the same. Lab will determine the frequency. Match--The DNA profile appears the same. Lab will determine the frequency.  Exclusion – The genotype comparison shows profile differences that can only be explained by the two samples originating from different sources. Exclusion – The genotype comparison shows profile differences that can only be explained by the two samples originating from different sources.  Inconclusive - The data does not support a conclusion as to whether the profiles match. Inconclusive - The data does not support a conclusion as to whether the profiles match.

34. Inlet (cathode) Outlet (anode) Capillary Electrophoresis (CE) Argon Ion Laser Fill with Polymer Solution 50-100  m x 27 cm 5-20 kV - + Burn capillary window Data Acquisition and Analysis DNA Separation occurs in minutes...

35. Gel Electrophoresis Capillary Electrophoresis capillaries laser gel plate

36. DNA Analyst at work DNA Analyst at work Computer Screen Data from capillary electrophoresis Computer Screen Data from capillary electrophoresis

37. 36 A comparison of the computer screen and a possible print out that represents the fragments by peaks.

38. Electrophoresis Pipette the DNA. We are working with a smaller budget and less expensive equipment. This is what we will do in class.

39. Electrophoresis (cont.) Load DNA into the gel wells.

40. Electrophoresis (cont.)  Run the gel. Run the gel.  Observe and compare bands of DNA. Observe and compare bands of DNA.

41. 40 Types of DNA Nuclear DNA  Nuclear found in the nucleus  Constitutes 23 pair of chromsomes inherited from both parents  Each cell contains only one nuclei Mitochondrial DNA  Found in the cytoplasm  Is inherited only from mother  Each cell contains hundreds to thousands of mitochondria  Can be found in skeletal remains Nuclear DNA is present in the head of the sperm. Mitochondrial DNA is present in the tail. At conception, the head of the sperm enters the egg and unites with the nucleus. The tail falls off, losing the father’s mitochondrial DNA.

42. Mitochondrial DNA  37 genes are involved in mitochondrial energy generation 37 genes are involved in mitochondrial energy generation  Is best used when nuclear DNA typing is not possible Is best used when nuclear DNA typing is not possible  Analysis of mtDNA is more: Analysis of mtDNA is more:  Rigorous Rigorous  Time consuming Time consuming  Costly than nucleic testing of DNA Costly than nucleic testing of DNA

43. 42 Comparison of DNA Methods

44. Determining Probability Databases are established by determining how often a particular allele on a loci appears in a given population. By increasing the number of alleles on different loci, the probability of having two people with the exact combination becomes astronomical.

45. Probability of a Random Match Using 13 CODIS STR Markers

46. Present Work in DNA  CODIS--Combined DNA Information System. CODIS--Combined DNA Information System.  A data base of DNA profiles of individuals convicted of sex crimes and other violent crime A data base of DNA profiles of individuals convicted of sex crimes and other violent crime  TWGDAM--The Working Group for DNA Analytical Methods TWGDAM--The Working Group for DNA Analytical Methods  Wrote the standards for DNA analysis that are part of a national crime laboratory accreditation program Wrote the standards for DNA analysis that are part of a national crime laboratory accreditation program  Innocence Project Innocence Project  Group of college law students work on cases where DNA may prove innocence (or guilt) Group of college law students work on cases where DNA may prove innocence (or guilt)

47. FBI’s CODIS DNA Database Combined DNA Index System  Used for linking serial crimes and unsolved cases with repeat offenders Used for linking serial crimes and unsolved cases with repeat offenders  Launched October 1998 Launched October 1998  Links all 50 states Links all 50 states  Requires >4 RFLP Requires >4 RFLP  markers and/or markers and/or  13 core STR markers 13 core STR markers

48. The Future  Greater automation of the DNA typing process Greater automation of the DNA typing process  Use of SNP’s--single nucleotide polymorphism which measures a one nucleotide change or difference from one individual to another. More sites are needed to differentiate between individuals (30 to 50 SNPs to attain the frequencies of the 13 STR loci), but it can be done with robots and automation. Use of SNP’s--single nucleotide polymorphism which measures a one nucleotide change or difference from one individual to another. More sites are needed to differentiate between individuals (30 to 50 SNPs to attain the frequencies of the 13 STR loci), but it can be done with robots and automation.

49. DNA--The Search for Innocence DNA implicates the guilty and exonerates the innocent--R. SafersteinDNA implicates the guilty and exonerates the innocent--R. Saferstein Over the years many innocent people have been wrongly convicted with no way of proving their innocence. Since the late 1980’s, DNA technology has been available. People, as a result, have been reopening cases and testing the evidence for DNA. Some have been exonerated because their DNA did not match. In this unit you will research a case in which DNA was used to convict or vindicate the suspect. You will work with a partner and will present your findings to the class using PowerPoint. http://www.dnai.org/d/index.html

51. WORDS OF WISDOM Keep in mind a famous quote from Albert Einstein, “ If we knew what we were doing, it would not be called research, would it?”