phrases are used.) CODIS The most useful DNA markers for forensics are in the population and do not contribute to (0.1)2 = 0.01 The genotypes of thousands of people at 13 unlinked law enforcement database called loci are kept in a very small 1/625 If a suspect's DNA did not come from the suspect. DNA found at a crime scene, the crime scene DNA allele frequencies If a suspect's DNA that particular 13-locus genotype in the population is determined. DNA found at a crime scene, the likelihood of finding 0.16 X 0.01 = 1.6 X 103 does not match Because the CODIS loci are in Hardy-Weinberg equilibrium, the genotype frequency at each SSR locus can be calculated from the 1/1000 Considering SSR locus A, if the frequency of allele 1 is 0.2 and the frequency of allele 2 is 0.4, the frequency of a heterozygote with allele 1 and allele 2 is matches highly variable At a second SSR locus B, if the frequency of allele 1 is 0.1, the frequency of an individual who is homozygous for allele 1 is phenotype multiplied The chance that both of those specific genotypes at the A and B loci would be found in

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Complete each sentence with the appropriate term or phrase. (Each term or phrase can be used only once, but not all terms or phrases are used.) CODIS The most useful DNA markers for forensics are in the population and do not contribute to (0.1)2 = 0.01 The genotypes of thousands of people at 13 unlinked loci are kept in a law enforcement database called very small 1/625 If a suspect's DNA did not come from the suspect. DNA found at a crime scene, the crime scene DNA allele frequencies If a suspect's DNA that particular 13-locus genotype in the population is determined. DNA found at a crime scene, the likelihood of finding 0.16 X 0.01 = 1.6 X 103 does not match Because the CODIS loci are in Hardy-Weinberg equilibrium, the genotype frequency at each SSR locus can be calculated from the 1/1000 Considering SSR locus A, if the frequency of allele 1 is 0.2 and the frequency of allele 2 is 0.4, the frequency of a heterozygote with allele 1 and allele 2 is matches highly variable At a second SSR locus B, if the frequency of allele 1 is 0.1, the frequency of an individual who is homozygous for allele 1 is phenotype multiplied The chance that both of those specific genotypes at the A and B loci would be found in

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law enforcement database called very small 1/625 If a suspect's DNA did not come from the suspect. DNA found at a crime scene, the crime scene DNA allele frequencies If a suspect's DNA that particular 13-locus genotype in the population is determined. DNA found at a crime scene, the likelihood of finding 0.16 X 0.01 = 1.6 X 103 does not match Because the CODIS loci are in Hardy-Weinberg equilibrium, the genotype frequency at each SSR locus can be calculated from the 1/1000 Considering SSR locus A, if the frequency of allele 1 is 0.2 and the frequency of allele 2 is 0.4, the frequency of a heterozygote with allele 1 and allele 2 is matches highly variable At a second SSR locus B, if the frequency of allele 1 is 0.1, the frequency of an individual who is homozygous for allele 1 is phenotype multiplied The chance that both of those specific genotypes at the A and B loci would be found in the same person is , or people. SSR The probability of a match at all 13 SSR loci is frequencies at each locus are because the genotype 2(0.2)(0.4) = 0.16 to find the match probability. Reset