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Molecular Biotechnology 2

Subject : engineering
Instructions:
  • Answer 50 questions in 15 minutes.
  • If you are not ready to take this test, you can study here.
  • Match each statement with the correct term.
  • Don't refresh. All questions and answers are randomly picked and ordered every time you load a test.

This is a study tool. The 3 wrong answers for each question are randomly chosen from answers to other questions. So, you might find at times the answers obvious, but you will see it re-enforces your understanding as you take the test each time.
1. 20-25 nt oligonucleotide that will hybridize to DNA of interest. It can be radiolabeled with kinase and 32P-ATP or fluorescently labeled.






2. A DNA Virus that infects bacteria with its chromosomal DNA. The Phage DNA is linear (35-50 kb) but circularizes in host. It encodes virus specific enzymes and is replicated in the host. It gets integrated into bacteria genome.






3. Extrachromosomal - circular DNA that has autonomous - self- replicating genetic elements. Found in bacteria - yeast. Transferred to daughter cells during cell division. Size varies from 1kb ~ 200 -000 kb.






4. 1. Construct a genome library: YAC - cosmids - etc 2. If using large insert vectors - clone smaller fragments (40 kb) into overlapping cosmids 3. Fragment the cosmid into 1 kb pieces using sonication and ligate into small plasmids 4. Sequence the 1 k






5. The host's immune system that protects against foreign DNA (DNA binding proteins). It protects the hosts DNA through methylation and digests DNA that isn't methylated. Hydrolyze phosophodiester bond at specific sequences. Binding/cutting sites can be






6. 1. Cycles of temperatures 2. 94C denatures DNA 3. Lower temperature so primers can bind to DNA at specific locations 4. Polymerase carries out templated DNA synthesis with primers at an optimal temperature (~72C) 5. Product serves as the template for






7. A host for recombinant DNA because it can grow fast and to a high cell density. It can also transcribe most foreign genes efficiently and there are many strains that facilitate genetic manipulations.






8. Two components to perform the traceless recombination on chromosomes: 1. FLP recognition target (FRT): inverted repeat 2. FLP recombinase






9. This uses a suicide plasmid (no ori) to do single crossover recombination because you want to force the plasmid to integrate its gene into the chromosome. Maintenance on chromosome allows plasmid to survive.






10. The number of cycles required for the fluorescent signal to pass the threshold (background level). This is inversely proportional to the amount of target nucleic acid.






11. Can be used to linearize circular DNA - can have double digest - usually done at 37C but some done at 55C - digest time depends on the amount of enzyme






12. Used to remove selection marker after Red- mediated recombination.






13. Assist recombination between homologous DNA sequences.






14. Four Components: 1. Template (Target DNA) - doesn't need to be purified and can be from anything 2. Primers (short oligonucleotides) 3. dNTP (building blocks) 4. Thermostable polymerase - no need for RNA primers like in actual DNA replication






15. SDS lysis cells - potassium acetate/acetic acid is used to neutralize pH and precipitates lipids and large proteins - centrifuge to separate out plasmid DNA from precipitates






16. E. coli polymerase denatures at 95C and new enzyme has to be added each time. TaqP is a thermal stable organism and only need to add once - but will denature after 30 min at 95C (may be able to reduce temperature after a few cycles; increase denatura






17. Increases specificity - sensitivity - and yield without redesigning primers. The initial annealing temperature is above the projected melting temperature of the primers being used. It then transitions to lower - more permissive annealing temperature






18. 1. Antibiotic Resistance: gene that degrades toxic compounds 2. Auxotrophic Marker: host is missing some essential amino acid/nucleotide and cell needs it to grow (eg. uracil) - nutritional markers






19. As the process continues - the complementary DNA strand is built up and the nucleotide sequence is determined from the signal peaks in the pyrogram.






20. A viral polymerase that converts sticky ends to blunt ends. Has polymerase activity and nuclease activity.






21. dNTP is added to the reaction Each time dNTP is incorporated to DNA - pyrophosphate (PPi) is released in a quantity equimolar to the amount of incorporated nucleotide.






22. Genes that are put into a new host so that the new host can gain new/correct function






23. Weak reactions with minimal nucleic acid (representing an infection state or environmental contamination).






24. 1. Label one end of DNA with radioactivity 2. Cut DNA at different places wherever A/G/C/T pop up using different chemicals 3. Line up DNA pieces by size using gel electrophoresis.






25. A technique that sequences the N terminus and C terminus sequence of purified proteins. These sequences can be used to design degenerate primers and probe a gene library. (1) Purify protein from cell sample - (2) break it up - (3) enzyme assay - (4)






26. Use polyT to 'trap' the mRNA and leave tRNA and rRNA behind.






27. Primers anneal to complementary sequences on DNA template and determine the boundaries of the amplified product.






28. Use virus/bacteria phase to infect cell






29. An identical copy. This term was originally applied to individual cells that were isolated and allowed to grow to create the same cell.






30. ATP sulfurylase quantitatively converts PPi to ATP in the presence of APS. This ATP drives the luciferase mediated conversion of luciferin to oxyluciferin that generates visible light in amounts that are porportional to the amount of ATP and is detec






31. 3' to 5' exonuclease - more expensive - yields less product - but has less error than TaqP






32. Used so the cell isn't killed and can still transfer foreign DNA into a host cell. The DNA can be propagated in a host cell and hosts with the vector can be selected over hosts that don't have the vector. Plasmids - viruses - plasmids + viruses (cosm






33. Each cell can maintain different plasmids with different selection markers. If the plasmid has the same selection marker - one will be lost. Transformation is very inefficient (<1% of the cell can be transformed).






34. 1. Detecting pathogens using genome- specific primer pairs 2. Screening specific genes for unknown mutations 3. Genotyping using known STS (sequence tagged sites) markers






35. (1) Gene is separated from chromosome - (2) gene is put into a vector - (3) vector replicates to produce multiple copies of the gene.






36. Apyrase - a nucleotide degrading enzyme continuously degrades unincorporated dNTPs and excess ATP. When degradation is complete - another dNTP is added.






37. Introduce DNA into bacteria. Transformation efficiency can be increased by making cells competent (treating with cold CaCl2 and heat shock at 42C).






38. May get a smear - can't tell the difference between bp - and limited by # of sequence it can generate because primers may only be able to do 1000 bp






39. 4-8 bp long (usually 6). Mostly palindromic because the nuclease is 2 enzymes coming together. There are 3 types of cleavage: (1) blunt ends - (2) 5' overhang sticky end - (3) 3' overhang sticky end.






40. Plasmids have an ori sequence for replication. The sequence of ori and plasmid encoded proteins determine the 'copy- number' of plasmids. Stringent control of replication (1 copy per cell division - low cell copy number plasmid); relaxed control of r






41. Know how much DNA is amplified by using Tagman which has fluorescent dye (SYBR Green) and quencher. Energy is transferred from F to Q when TaqP excises F with 5' to 3' exonuclease activity.






42. A DNA which is complementary to an RNA (a complementary DNA); Generally made by reverse transcription of mRNA. (1) purification of mRNA with polyT because mRNA has lots of polyA on 3' end - (2) first strand DNA synthesis using RTase - (3) second stra






43. Each clone on the plate has the gene of interest - but there are only a few colonies that have the gene. Once do a filter paper - you need to do it again around the area where colonies popped up first until finally know where the colony is.






44. 1. Delete genetic information on the chromosomes of species of interest (knock outs) 2. Insert new genes and DNA sequences into desired positions on the chromosome (not relying on plasmids) 3. Generate genetically engineered species






45. Sequencing primer is hybridized to a single stranded DNA and incubated with enzymes - DNAP - ATP sulfurylase - luciferase - and apyrase. Adenosine 5' phosphosulfate (APS) and luciferin are added.






46. 1. Use RTase to go from RNA to DNA 2. Use RNAseH to get rid of RNA 3. Use TaqP to make top strand of DNA - can't detect quantity of RNA/DNA






47. Move plasmid into cell. In cancer biology - this means converting non - carcinoma cell to carcinoma cell.






48. DNA footprinting; will have an empty region if DNA has protein binding to it because that region won't be amplified.






49. From bacteriophage lambda and help in the removal of chromosomal genes in e.coli. As little as 30 nt homologous region is required - which can be introduced as overhangs in a PCR reaction using the selection marker as template 1. Gam - protects line






50. Need: polymerase - dNTP (one is labeled with 32P to provide signal) - ddNTP (3'H will terminate DNA synthesis; dideoxyribose; only one is put in and added in excess) - synthesizes DNA and can deduce sequence wherever DNA stops synthesizing because o