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The end replication problem:
-DNA polymerase requires an OH group to attach bases too
-There is no OH group at the extreme 5’ end of the lagging strand
-Telomeres (the ends of chromosomes) contain repetitive sequences, no protein coding DNA
Telomerase uses RNA as a template to extend in the 3’ direction
RNA synthesis - Expression of the genome
Properties:
1) Synthesis is de novo off of a template
2) Product (RNA) detaches from template (DNA)
3) Can tolerate more mistakes than DNA synthesis
4) Don’t replicate entire genome
5) Replicate portions repeatedly
DNA synthesis
RNA transcription
RNA polymerases are made from many sub-units
Homologous
RNAP II performs most of the transcription in Eukaryotes
*This lecture we will cover transcription in Prokaryotes
Overview of transcription steps
Can diffuse away
“locked” on
Often starts and stops, repeats initial transcription
“Breaks away” from promoter
Transcribed genes have “promoters” - sequence determines affinity for RNA polymerase
“Consensus” promoter - most common sequences
Alpha and Sigma subunits bind specific promoter sequences
*Differences in alpha and sigma proteins can regulate transcription of specific genes
4 functions of the Sigma subunit domains
-Regions 3 and 4 bind the promoter
-Region 2 melts DNA
-Region 1 mimics DNA, moved when DNA melts
RNA polymerase ready to transcribe
-Can synthesize “de novo”
-Must hold 2 nucleotides in place long enough for binding to take place
-Makes use of metal ions
-Many transcribed sequences begin with an adenine
Several models for false starts to transcription
Relative positions of RNA polymerase
Exonuclease activity
TRCF protein uses ATP to remove a stuck polymerase
Termination of transcription
