Methyl-directed Mismatch Repair

Methyl-directed Mismatch Repair

Methyl-directed Mismatch Repair
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How many errors in DNA replication are too many? DNA polymerase makes an error in DNA synthesis approximately once in every thousand bases added to a DNA strand. An error rate of one in a thousand may sound very low. If a student only got one question in a thousand wrong in a course we would consider him or her an excellent student. In DNA replication every single error can have a potentially disastrous effect on the function of the gene being copied. Each gene is composed of hundreds or thousands of bases and organisms have thousands of genes. An error rate of one in a thousand is going to result in a completely nonfunctional cell in a handful of generations. After DNA replication other factors check for errors and correct them. These factors have similar error rates to DNA polymerase meaning that errors in DNA replication only occur about once in a million times.

View the animation below, then complete the quiz to test your knowledge of the concept.


1	Arrange the following proteins in the proper sequence in which they participate in methyl-directed mismatch repair. 1. Mut S 2. Mut L 3. Mut H
	A)	1, 2, 3
	B)	2, 1, 3
	C)	2, 3, 1
	D)	3, 2, 1
	E)	3, 1, 2

2	In methyl-directed mismatch repair, the strand that is repaired is
	A)	the methylated strand.
	B)	the non-methylated strand.
	C)	the hemi-methylated strand.
	D)	either the methylated or non-methylated, depending on the type of mismatch.
	E)	either the methylated or non-methylated, depending on the size of mismatch.

3	Methylation of DNA typically occurs at sites with the sequence
	A)	ATAT.
	B)	CTGA.
	C)	AGGA.
	D)	GTTG.
	E)	GATC.

4	DNA pol III and DNA ligase are required to fill in the repair gap.
	A)	True
	B)	False

5	The MutH protein is directly responsible for recognizing mismatched DNA base pairs.
	A)	True
	B)	False

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Home > Chapter 20 > Methyl-directed Mismatch Repair

	Course-wide Content
		Lecture PowerPoints Image PowerPoints End-of-Chapter Answers

		Action of DNA Gyrase Bidirectional DNA Repl... Direct Repair DNA Replication (E. co... DNA Replication Fork How Nucleotides Are Ad... Meselson and Stahl Exp... Methyl-directed Mis... Nucleotide Excision Re... Proofreading Function ... Rolling Circle Mechani... Thymine Dimers Formati...
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	Instructor Resources
		End-of-Chapter Answers Presentation Tools Computerized Testing

	Course-wide Content
		Lecture PowerPoints Image PowerPoints End-of-Chapter Answers

		Action of DNA Gyrase Bidirectional DNA Repl... Direct Repair DNA Replication (E. co... DNA Replication Fork How Nucleotides Are Ad... Meselson and Stahl Exp... Methyl-directed Mis... Nucleotide Excision Re... Proofreading Function ... Rolling Circle Mechani... Thymine Dimers Formati...
	News, Articles & Links
		Web Links