Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download I. The prokaryotic chromosomes A. Kinds of genetic elements in prok
Document related concepts
Holliday junction wikipedia , lookup
Gel electrophoresis of nucleic acids wikipedia , lookup
Comparative genomic hybridization wikipedia , lookup
Whole genome sequencing wikipedia , lookup
X-inactivation wikipedia , lookup
Molecular cloning wikipedia , lookup
Nucleic acid analogue wikipedia , lookup
Vectors in gene therapy wikipedia , lookup
Transformation (genetics) wikipedia , lookup
Non-coding DNA wikipedia , lookup
Cre-Lox recombination wikipedia , lookup
Deoxyribozyme wikipedia , lookup
Genome evolution wikipedia , lookup
DNA supercoil wikipedia , lookup
Molecular evolution wikipedia , lookup
Endogenous retrovirus wikipedia , lookup
Artificial gene synthesis wikipedia , lookup
Transcript
Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication Bio119 I. The prokaryotic chromosomes A. Kinds of genetic elements in prok and euks 1. Prok and Euk have chromosomes and plasmids B. Prok. chromosome is usually _________________ (Fig. 16.10) C. Usually only have 1 but number can be more if prok. is growing D. Bacteria chromosome can be replicated throughout the cell cycle. E. All prokaryotes are:____________________. F. Majority of prokaryotic chromosome:_______________________. G. Prok. genes usually do not have:______________________ H. An average gene length is about ________________ I. How many genes are there if genome is 6 Mb (6 x 109 bp)? 1. J. Because chromosome is 1 mm long it needs to be: K. This is accomplished by ______________________(Fig 4.31): 1. This is need to make chromosome fit into a small space. 2. DNA gyrase (topoisomerase II) introduces negative supercoiling 3. DNA gyrases are also targets for quinolone type antibiotics 4. Topoisomerase I removes negative supercoiling, which is needed during replication. L. Because supercoiling brings negatively charged phosphates close, M. Further compacting of the chromosome occurs with: II. How does a bacterial cell replicate its chromosome? A. In a ______________________ mode similar to Euks. (Fig. 13.2) 1. Strands separate and each are copied 2. Daughter genome gets: a) _____________________ strand and a Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication Bio119 b) ____________________________________copy B. Lots of proteins involved in replicating chromosome 1. Table 13.1 C. Initiation of replication (Fig. 13.3): 1. DNA replication starts at an origin of replication, called: 2. DNA binding proteins (______) bind the ________, which causes: 3. __________ binds replication fork with _________and promotes DNA ________________with help of _____________. 4. D. The formation of a replisome (Fig. 13.4): 1. Each replication fork has a leading strand and lagging strand 2. The leading strand is synthesized by: _________________ as a single contiguous molecule starting from an: 3. The lagging strand is synthesized in a discontinuous fashion. E. DNA polymerization: 1. DNA polymerases polymerize: 2. Bacteria have: 3. ______________________ carries out the elongation stage as the replication fork moves forward (Fig. 13.6). 4. Polyermases need: 5. Template must be primed with a nucleotide. Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication Bio119 F. Polymerization takes place from 5’ to 3’ 1. leading strand is continuous 2. Lagging strand is built in fragments: G. The RNA primer on lagging strand is removed by: 1. Gaps are filled by: H. Termination occurs at the: 1. I. __________________________________ occurs during replication because DNA is helical and must rotate to accommodate the replication fork. 1. Relief of tension and tangling is accomplished: 2. This makes temporary nicks in the DNA allowing it to: J. Separation of daughter chromosomes is accomplished: 1. Causes: 2. DNA can untangle. K. Mistakes also need to be repaired 1. Wrong base pairing can occur: 2. Polymerase error rate is: 3. Errors are corrected by: 4. Mismatch repair system: 5. How does this work (Fig. 13.7): a) b) MutS: Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication Bio119 c) MutH: d) MutL: e) MutH: f) Exonucleases: g) DNA Pol I: h) DNA ligase: L. If chromosome replication is complete in 40 min how can E. coli grow with a generation time of 20 min? M. Video 1: http://www.youtube.com/watch?v=teV62zrm2P0 N. Video 2: http://www.youtube.com/watch?v=4jtmOZaIvS0 Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication III. Bacterial plasmids A. B. Usually circular C. D. Are plasmids essential? E. Phenotypes conferred by plasmids F. Classifying plasmids by their: 1. Host range: 2. Compatibility: 3. Replication modes: Bio119 Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication G. Role of plasmids in genetic diversity 1. Plasmids contribute to: 2. 3. These plasmids tend to be: 4. Plasmid promiscuity is controlled by: Bio119 Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication H. R1 Plasmid 1. Where it came from: 2. Partition system Bio119 Produced with a Trial Version of PDF Annotator - www.PDFAnnotator.com Genome Organization/Function/Replication 3. What happens if daughter cell doesn’t get a plasmid? Bio119
