1. DNA profiling

2. What is it? What do you know about DNA Profiling? – How does it work? – From what sources can DNA for profiling be obtained? – How reliable is it? – How is enough DNA obtained when little is available from the crime scene? – What, exactly, is a DNA profile or fingerprint?

3. Origin of forensic techniques Examination of biological evidence – Karyotyping – analysis of chromosomes – Blood typing – excludes suspects, determines if blood at crime scene came from one or multiple suspects Most techniques originated for medical diagnosis or treatment

4. Karyotyping

5. DNA fingerprinting DNA profiling – used in criminal and legal cases to determine identity or parentage – DNA extracted from very small amounts of biological evidence Drop of blood Single hair follicle – Can accurately predict whether an individual can be linked to a crime scene or excluded as a suspect

6. Function and Structure of DNA DNA – Deoxyribonucleic acid Contains the genetic material of the cell Instructions to make proteins and to replicate Chromosome – structures made up of molecules of DNA

7. DNA molecule Double-helix structure – composed of two strands Sides of the ladder – backbone of sugar and phosphate molecules Rungs of the ladder – nitrogenous bases

8. The Different DNA Bases Adenine (A), Cytosine (C), Guanine (G), Thymine (T) Binding – A with T – C with G Complimentary Strands: – Strand: CGTCTA – Compliment: GCAGAT

9. Where does your DNA come from? 23 pairs (46)of chromosomes in human cells – Exception is human reproductive cell Nuclear DNA – in nucleus – One chromosome from mother, one chromosome from father – Virtually identical in all cells of the body Mitochondrial DNA – in cytoplasm – Exists in a circular loop – Passed on only from mother

10. Genes and Alleles Genes – DNA sequences that determine our inherited characteristics or traits Allele – one of two or more alternative forms of a gene – One comes from mother, one from father – Ex. One allele codes for normal hemoglobin – One allele codes for abnormal hemoglobin

11. Human Genome Project 13 year project to determine the order of bases on all 23 pairs of human chromosomes Helps to know where on a specific chromosome DNA codes for production of a specific protein Can help to treat and/or cure genetic diseases and disorders

12. Human Genome Project 3 million base pairs in human DNA Exons (encoded DNA) – contains DNA used to make proteins or other molecules Introns (unencoded DNA, “junk DNA”) – isn’t involved in protein making, but important for gene splicing – More than 98.5% of genome is junk DNA – Mutations in the non-coding are tolerated and can accumulate with no effect on the organism

14. DNA Identification Polymorphisms – unique patterns of repeated base sequences that identify individuals – Found in introns (junk DNA) Different repeated sequences appear in different places in the genome of each individual Two types of repeats in noncoding sections: – VNTRs – STRs

15. Discovery of DNA profiling 1984 – Alec Jeffreys: University of Leicester Developed technique for DNA fingerprinting – Appears as a pattern of bands on x-ray film – Each individual has a unique DNA band pattern Shows: – Same individual – Related individuals – Unrelated individuals

16. Alec Jeffreys

17. VNTR - Variable Number of Tandem Repeats Short sequences of DNA that are repeated multiple times – Number of copies of the same repeated base sequence varies among individuals – CATACAGAC 3 copies in one individual, 7 in another – Length of VNTR can be from 9 to 80 bases in length

18. STR – Short Tandem Repeats Short sequence of DNA with a high degree of polymorphism – Usually 2 to 5 base pairs in length – GATA Ex- GATAGATAGATAGATA – Polymorphisms result from different # of copies of repeat element – Becoming preferred method of analysis Accurate Small and partially degraded samples may be used STRs much shorter than VNTRs so much easier to separate

19. DNA Profile Multiple VNTRs and STRs examined Purpose: – Tissue Matching – connecting a suspect to a crime scene – Inheritance Matching – each band in a child’s DNA fingerprint is present in at least one parent

20. Population and Genetics Population genetics – the study of variation in genes among a group of individuals Population studies conducted to calculate the percentage of people who have a particular allele. – The greater the number of people, the more accurate a statistics will be – Ex –probability of blood type of a suspect matches crime-scene evidence, must refer to a database with info from a representative population.

21. Sources of DNA at Crime Scenes Blood (White blood cells) Semen(Sperm cells) Hair with roots (Hair follicle cells) Skin, dandruff(Skin cells) Sweat stains(Skin cells sloughed off) Vaginal fluids(Mucosal surfaces) Nasal secretions(Mucosal surfaces) Urine (Mucosal surfaces) Feces (Digestive system cells) All individual evidence!!!

22. PCR – Polymerase Chain Reaction Trace evidence – when the amount of evidence left at the crime scene is very small Problem – evidence may be totally consumed during testing Solution: PCR - generates multiple identical copies from trace amounts of original DNA evidence

23. Collection and Preservation of DNA Evidence Contamination issues – when DNA from another source is mixed with DNA relevant to a case – Ex – coughing, sneezing, touching mouth, nose, eyes Keep evidence dry and cool Moisture, sunlight can damage and denature DNA

24. Precautions 1.Wear disposable gloves and change them often. 2.Use disposable instruments for handling each sample. 3.Avoid touching the area you believe DNA may exist. 4.Avoid talking, sneezing, and coughing over evidence. 5.Avoid touching your face, nose, and mouth when collecting and packaging evidence. 6.Air-dry evidence thoroughly before packaging. 7.Put evidence into new paper bags or envelopes. 8.If wet evidence cannot be dried, it may be frozen.

25. Steps of DNA Fingerprinting 1.Extraction 2.Restriction fragments 3.Amplification 4.Electrophoresis

26. 1. Extraction DNA is extracted from cells Cells are isolated from tissue Cell membrane and nuclear membrane are broken down – Let’s watch: Let’s watch:

27. 2. Restriction Fragments Fragments of varying lengths formed when DNA is cut Restriction enzymes – recognize a unique pattern of DNA bases and will cut DNA at specific location – “molecular scissors” – Often used and produced by bacteria (to destroy nucleic acid of enemies) – Many different restriction enzymes, each binds to specific recognition site

28. Restriction Enzymes

29. Restriction enzyme Hind III AACGTT Hind III cuts between the two AA bases some of the fragments produce VNTRs

30. Recombinant DNA DNA that has been artificially created Cultured cells (E. coli, yeast, mammalian cells) transformed with a human gene manufacture products for human therapy: – Insulin – Human growth hormone – Parathyroid hormone – Factor VII, Factor IX for hemophelia

31. 3. Amplification Making more copies of the DNA This is done for several reasons: – Most evidence samples from a crime scene contain very little DNA – It is a standard or control (i.e. important for Daubert challenges) – one needs to argue that the same amount of DNA is used in each lab, by each lab technician and every time sample is processed

32. Amplification PCR – Polymerase Chain Reaction Amplify certain pieces of DNA that contain VNTRs and STRs PCR Machines, or thermocyclers: – use repeated cycles of heat and cooling to replicate the DNA – use many of the same enzymes found in cells which facilitate DNA replication

33. 4. Electrophoresis Method of separating the molecules within an electric field based on size of DNA fragments Negatively charged DNA moves through gel with a current Fluorescent dye is binded to DNA Smaller fragments move faster than larger fragments

34. Electrophoresis Steps: 1.Micropipette used to place DNA into separate chambers or wells across top of gel Control – DNA Ladder or Standard DNA 2.Electric current passed through gel 3.Process complete when DNA fragments have migrated through gel 4.Visualize DNA fragments through probes

37. DNA and Probes Radioactive probes – used to view specific DNA sequences in a DNA fingerprint STR analysis – only fragments that were amplified will be on gel – Fluorescent stain in the liquid the gel is bathed in – UV light source used to cause DNA to fluoresce and make bands visible

38. DNA and Probes DNA probe – made up of a synthetic sequence of DNA bases that is complimentary to a small portion of DNA strand – AAGCTTA, radioactive probe – TTCGAAT Next step is to view DNA fingerprint Depends on the chemical used to label the probe – Fluorescent dye – viewed under UV light – Radioactive isotope – X-ray film produces autoradiograph Technique called Southern Blotting

40. Paternity DNA fingerprint is a combination of DNA from mother and father – Position and width of bands is significant – All bands have to match exactly Greater the number of probes used, the greater the accuracy – Six to eight probes common for DNA fingerprint

41. Analysis of DNA Fingerprints Combined DNA Index System (CODIS) – electronic database of DNA profiles – Uses 13 loci – Tetrameric repeats States maintain DNA index of individuals convicted of rape, murder, child abuse DNA profiles from a crime scene can be entered into CODIS to identify possible suspects

42. A Sample Profile By combining the frequency information for all 13 CODIS loci, the frequency of this profile would be 1 in 7.7 quadrillion Caucasians

43. As the technology gets smarter, so too do the criminals A physician in Canada eludes authorities for years Accused of drugging and sexually assaulting patients, DNA profiles from semen samples from the assaulted women do not match Dr. Schneeberger Blood was drawn on 3 occasions in 1992, 1993 and 1996, but never came back as a match Finally police obtain blood from a finger prick, swabbed the inside of his cheek and took hair samples The results matched the DNA from the semen of the victims How did he get away with it?

44. As the technology gets smarter, so too do the criminals On the previous 3 occasions, blood was drawn from the same arm The last time the blood was drawn, the technician stated that the blood looked brown and “old” Schneeberger had surgically implanted a piece of rubber tubing in his arm and filled it with stored blood from a patient

45. Its Uses Identification of remains

46. The Angel of Death: Josef Menegle Josef Mengele was a Nazi war criminal notorious for grotesque human experiments that he carried out at the Auschwitz concentration camp. After the Second World War he fled from the Allies and escaped to South America. The fugitive succeeded in living out the rest of his days without being caught. In 1985 investigators went to the cemetery of Nossa Senhora do Rosario in the small Brazilian town of Embu to dig up the skeleton of a man who had been drowned in a swimming accident six years previously. Using DNA extracted from blood provided by Mengele’s wife and son, it was concluded that it was more than 99.94% certain that the skeleton was Mengele’s.

47. Paternity Cases Who’s your daddy? 1. 2. 1. 2.

48. Homicide or Rapes: OJ Simpson

49. Exoneration Kirk Bloodsworth – Convicted in 1985 for the rape and strangulation of a 9-year old girl and sent to death row – In 1992, defense attorneys were successful in having a dime-sized semen stain on the girl’s underpants tested against Bloodsworth’s DNA – He was exonerated

50. Exoneration

51. Uses of DNA fingerprinting Crime-scene DNA matching with suspect’s DNA Paternity and maternity determination Identify family members and relatives Suspect elimination Exoneration of falsely accused and imprisoned Identification of human remains