Deck 19: The Genetics of Cancer

A) 50kb
B) 500kb
C) 5Mb
D) 50Mb
E) 500Mb

A) Identify miRNAs and their mRNA targets.
B) Identify cis-elements to which a transcription factor binds.
C) Identify transcripts expressed in a genome-wide mutant collection.
D) Identify rare transcripts that are differentially expressed.
E) Identify repetitive DNA sequences on chromosomes.

A) TGA
B) GATA box
C) splicing junction
D) polyadenylation signal
E) CAAT box

A) start codons.
B) introns.
C) promoter regions.
D) polyA tails.
E) 3'UTRs.

A) affinity of DNA for histones.
B) gene expression.
C) chromatin remodelling.
D) nucleosome structure.
E) RNA stability.

A) Increased expression of the gene represented at the green spot is causally related to tumourgenesis.
B) Transcript of the gene represented at that green spot is less abundant in normal tissue than in the tumour.
C) Transcripts of all genes are more abundant in normal tissue than in the tumour.
D) Transcript of the gene represented at that green spot is more abundant in normal tissue than in the tumour.
E) Decreased expression of the gene represented at the green spot is causally related to tumourgenesis.

A) rRNA
B) splicing acceptor
C) transcription rate
D) translation start
E) transcription start

A) They can be made of glass.
B) They involve DNA sequencing.
C) Expression is proportional to signal intensity.
D) Lasers are used in their analysis.
E) PCR is often used in their production

A) made by labelling mRNA.
B) representative of the entire genome.
C) usually over 1kb in length.
D) complementary to cDNA.
E) radioactively labelled.

A) 100kb duplications
B) inversions
C) aneuploidy
D) 100kb deletions
E) 50Mb deletions

A) Arrays for ChIP-on-chip are made using probes based on intergenic regions.
B) Arrays for ChIP-on-chip are made using probes based on cDNAs.
C) Arrays for ChIP-on-chip are made using probes based on synthetic oligonucleotides
D) Arrays for ChIP-on-chip are made using probes based on rRNAs.
E) Arrays for ChIP-on-chip are made using probes based on miRNAs.

A) thousands of spots.Within each spot are millions of copies of a DNA sequence.Each spot contains DNA with a different sequence than every other spot on the array.
B) millions of spots.Within each spot are thousands of copies of a DNA sequence.Each spot contains DNA with a different sequence than every other spot on the array.
C) thousands of spots.Within each spot are millions of different DNA sequences.Each spot contains different DNA sequences than every other spot on the array.
D) millions of spots.Within each spot are thousands of different DNA sequences.Each spot is identical to every other spot on the array.
E) millions of spots.Within each spot are thousands of different DNA sequences.Each spot contains different DNA sequences than every other spot on the array.

A) Transcription factors that acts as tumour-suppressors can be identified by CGH.
B) Transcription factors that are more abundant in tumours can be identified by CGH.
C) Transcripts that are more abundant in tumours can be identified by CGH.
D) Trisomy 21 can be identified using CGH.
E) Deletions containing tumour-suppressor genes are often found in tumours and can be detected by CGH.

A) Shows which mRNAs are overexpressed in a mutant cell,compared to the case of a normal cell
B) Indicates which mRNAs are not being produced in either of two cell types
C) Allows identification of a cell's rarely expressed mRNAs (fewer than 10 copies per cell)
D) Shows which mRNAs are overexpressed in a normal cell,compared to the case of a mutant cell
E) Measures relative abundance of mRNA in two samples

A) fluorescent labels
B) an antibody
C) PCR
D) a microarray
E) hybridization

A) Arrays for CGH are made using BAC probes.
B) Arrays for CGH are made using cDNA probes.
C) Arrays for CGH are made using synthetic oligonucleotide probes.
D) Arrays for CGH are made using PCR amplicon probes.
E) Arrays for CGH are made using miRNA probes.

A) RNA blotting
B) Southern blotting
C) PCR
D) Electrophoresis
E) DNA sequencing

A) transcriptome.
B) genome.
C) proteome.
D) spliceosome.
E) orfeome.

A) RNA extraction,reverse transcription,differential labelling,hybridization
B) RNA extraction,reverse transcription,hybridization,differential labelling
C) reverse transcription,RNA extraction,differential labelling,hybridization
D) differential labelling,RNA extraction,reverse transcription,hybridization
E) RNA extraction,differential labelling,hybridization,reverse transcription

A) genotypes of haploid organisms.
B) one half of a SNP genotype.
C) alleles made of the SNPs in a block of DNA.
D) genotypes made from gametic DNA.
E) ambiguous genotypes resulting from dominant markers.

A) CGH.
B) a detailed pedigree.
C) a karyotype.
D) tag SNPs.
E) cDNA microarrays.

A) CGH.
B) cDNA microarray analysis.
C) ChIP-chip analysis.
D) bisulfite sequencing.
E) PCR.

A) ability to conduct high resolution linkage mapping with molecular markers
B) ability to perform integrate linkage mapping with CGH
C) access to detailed pedigrees of over 300,000 Icelandic citizens
D) a complete human genome sequence
E) access to health records for over 5,000 sets of identical twins in Britain

A) reliability of phenotypic information
B) availability of human DNA samples
C) molecular markers
D) knowing family relationships
E) control subjects

A) pedigree analysis.
B) genome wide association studies.
C) model organisms.
D) comparative genome hybridization.
E) whole genome sequencing.

A) methylation of cytosine;methylated DNA
B) immunoprecipitation of methylated DNA;promoter regions
C) conversion of cysteine to uracil;unmethylated DNA
D) conversion of cytosine to uracil;unmethylated DNA
E) immunoprecipitation of promoter regions;methylated DNA

A) high resolution karyotyping
B) identifying genome duplication
C) biomarker discovery
D) identifying modified histones
E) screening for small deletions