100% satisfaction guarantee Immediately available after payment Both online and in PDF No strings attached
logo-home
Biol 140 DNA Replication and Manipulation Notes $10.99   Add to cart

Class notes

Biol 140 DNA Replication and Manipulation Notes

 5 views  0 purchase

DNA Replication and Manipulation notes for Bio 140. *Essential!! *Contains vital information,key concepts and more.... *For you!!

Preview 2 out of 10  pages

  • August 23, 2024
  • 10
  • 2021/2022
  • Class notes
  • Prof. terrie
  • All classes
All documents for this subject (10)
avatar-seller
anyiamgeorge19
Chapter 12: DNA Replication and Manipulation
12.1 DNA Replication
❖ The process of duplicating a DNA molecule is called DNA replication. The parental
strands separate and new complementary partner strands are made.
❖ The two strands of the parental duplex molecule separate, and each individual parental
strand serves as a model, or template strand, for the synthesis of a daughter strand.
❖ As each daughter strand is synthesized, the order of the bases in the template strand
determines the order of the complementary bases added to the daughter strand.
❖ Semiconservative replication- after replication, each new DNA duplex consists of one
strand that was originally part of the parental duplex and one newly synthesized strand.
❖ Half of the DNA molecules will have one heavy old strand and one light new strand and
an intermediate density, and half of the DNA molecules will have one light old strand and
one light new strand and a low density.
❖ The new daughter strands have opposite orientations, so that near the replication fork
the daughter strand in the bottom duplex terminates in a 3′ hydroxyl, whereas that in the
top duplex terminates in a 5′ phosphate.
➢ The strand that terminates in the 5′ phosphate cannot grow in the direction of the
replication fork because new DNA strands can grow only by the addition of
successive nucleotides to the 3′end. DNA always grows in the 5′-to-3′ direction.
❖ DNA polymerization occurs when the 3′ hydroxyl at the growing end of the
polynucleotide chain attacks the triphosphate group at the 5′ end of an incoming
nucleotide. As the incoming nucleotide triphosphate is added to the growing DNA
strand, one of the nucleotide’s high-energy phosphate bonds is broken to release the
outermost two phosphates, and immediately the high-energy phosphate bond in the
pyrophosphate is cleaved to drive the polymerization reaction forward and make it
irreversible.
❖ The polymerization reaction is catalyzed by DNA polymerase, an enzyme that is a
critical component of a large protein complex that carries out DNA replication.
➢ All DNA polymerases synthesize a new DNA strand from an existing template.
Most, but not all, also correct mistakes in replication.
❖ Because a new DNA strand can be elongated only at the 3′ end, the two daughter
strands are synthesized in different ways.
➢ The leading strand has its 3′ end pointed toward the replication fork, so that as
the parental double helix unwinds, nucleotides can be added onto the 3′ end and
this daughter strand can be synthesized as one long, continuous polymer.
➢ The lagging strand grows away from the fork and forms a stretch of single-
stranded DNA of a few hundred to a few thousand nucleotides, depending on the
species. Then, as the parental DNA duplex unwinds further, a new daughter
strand is initiated with its 5′ end near the replication fork, and this strand is
elongated at the 3′ end as usual.

, ➢ The short pieces in the lagging strand are called Okazaki fragments.
❖ Each new DNA strand must begin with a short stretch of RNA that serves as a primer, or
starter, for DNA synthesis. The primer is needed because the DNA polymerase complex
cannot begin a new strand on its own; it can only elongate the end of an existing piece of
DNA or RNA.
❖ The primer is made by an RNA polymerase called RNA primase, which synthesizes a
short piece of RNA complementary to the DNA template and does not require a primer.
❖ Once the primer has been synthesized, the DNA polymerase takes over and elongates the
primer, adding successive DNA nucleotides to the 3′ end of the growing strand.
❖ Because the DNA polymerase complex extends an RNA primer, all new DNA strands
have a short stretch of RNA at their 5′ end.
❖ When the growing fragment comes into contact with the primer, a different DNA
polymerase complex takes over, removing the RNA primer and extending the growing
fragment with DNA nucleotides to fill the space left by removal of the RNA primer.
When the replacement is completed, the adjacent fragments are joined, or ligated, by an
enzyme called DNA ligase.
❖ Many other proteins and enzymes work at the same time to ensure accurate and
efficient synthesis of the daughter strands.
➢ Topoisomerase II, works upstream from the replication fork to relieve the stress
on the double helix that results from its unwinding at the replication fork.
➢ Helicase separates the strands of the parental double helix at the replication
fork.
➢ Single-strand binding protein binds to these single-stranded regions to prevent
the template strands from coming back together.
❖ The DNA polymerase complexes for each strand stay in contact with each other, with
the lagging strand’s polymerase releasing and retrieving the lagging strand for the
synthesis of each new RNA primer.
❖ The positioning of the polymerases is such that both the leading strand and the lagging
strand pass through in the same direction, which requires that the lagging strand be
looped around. The 3′ end of the lagging strand and the 3′ end of the leading strand are
elongated together, which ensures that neither strand outpaces the other in its rate of
synthesis.
❖ When DNA damage occurs during replication, the rate of synthesis slows down so that
the DNA can be repaired. If synthesis of one strand slows down to repair DNA damage,
synthesis of the other strand slows down, too.
❖ Most DNA polymerases can correct their own errors in a process called proofreading,
which is a separate enzymatic activity from strand elongation (synthesis).
❖ DNA polymerase can correct errors because it detects mispairing between the template
and the most recently added nucleotide. Mispairing between a base in the parental strand
and a newly added base in the daughter strand activates a DNA-cleavage function of

The benefits of buying summaries with Stuvia:

Guaranteed quality through customer reviews

Guaranteed quality through customer reviews

Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.

Quick and easy check-out

Quick and easy check-out

You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.

Focus on what matters

Focus on what matters

Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!

Frequently asked questions

What do I get when I buy this document?

You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.

Satisfaction guarantee: how does it work?

Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.

Who am I buying these notes from?

Stuvia is a marketplace, so you are not buying this document from us, but from seller anyiamgeorge19. Stuvia facilitates payment to the seller.

Will I be stuck with a subscription?

No, you only buy these notes for $10.99. You're not tied to anything after your purchase.

Can Stuvia be trusted?

4.6 stars on Google & Trustpilot (+1000 reviews)

62890 documents were sold in the last 30 days

Founded in 2010, the go-to place to buy study notes for 14 years now

Start selling
$10.99
  • (0)
  Add to cart