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use of computer software in studying genomics
1. Genomics
2. Specific treatments
3. SNP
4. Bioinformatics
5. Genome
4. Bioinformatics
study of similarities and differences in genomes
1. clones
2. comparative genomics
3. HapMap
4. Aspen trees
5. Sea anemone
2. comparative genomics
base that differs
1. Dolly
2. Haplotype
3. Allele
4. Common functions
5. Cloning
3. Allele
study of base sequences in DNA
1. Genomics
2. Specific treatments
3. SNP
4. Bioinformatics
5. Genome
1. Genomics
invertebrate that naturally forms clones
1. clones
2. comparative genomics
3. HapMap
4. Aspen trees
5. Sea anemone
5. Sea anemone
sequence of SNP'S
1. Dolly
2. Haplotype
3. Allele
4. Common functions
5. Cloning
2. Haplotype
sequence of genes (or bases) in an organism's chromosomes
1. Genomics
2. Specific treatments
3. SNP
4. Bioinformatics
5. Genome
5. Genome
produce many clones asexually
1. clones
2. comparative genomics
3. HapMap
4. Aspen trees
5. Sea anemone
4. Aspen trees
genes in humans and in fruit flies have _____
1. Dolly
2. Haplotype
3. Allele
4. Common functions
5. Cloning
4. common functions
possible to design by sequencing a person's DNA
1. Genomics
2. Specific treatments
3. SNP
4. Bioinformatics
5. Genome
2. Specific treatments
section of DNA with SNP'S
1. clones
2. comparative genomics
3. HapMap
4. Aspen trees
5. Sea anemone
3. HapMap
DNA from mature cell placed in an egg
1. Dolly
2. Haplotype
3. Allele
4. Common functions
5. Cloning
5. Cloning
area in DNA where there is a different base than in most people
1. Genomics
2. Specific treatments
3. SNP
4. Bioinformatics
5. Genome
3. SNP
genetically identical organisms
1. clones
2. comparative genomics
3. HapMap
4. Aspen trees
5. Sea anemone
1. Clones
the first mammal to be cloned
1. Dolly
2. Haplotype
3. Allele
4. Common functions
5. Cloning
1. Dolly