News Release

Close-up view of DNA replication yields surprises

Peer-Reviewed Publication

University of California - Davis

Video Imaging of DNA Replication

video: 

This video shows replication of individual pieces of double stranded DNA. This is the first time DNA replication -- arguably, the fundamental process of life on Earth -- has been observed directly.

Each glowing strand is a piece of double helix growing by replication at the left-hand end. They move at different speeds and stop and start. Dark gaps in the line are single-stranded DNA where one polymerase failed to attach (the fluorescent dye only binds double-stranded DNA).

Some surprises come out of being able to observe replication directly. For example, the two polymerases involved in replication (one for each strand) aren't coordinated. They stop and start at random, but overall they move at the same average speed, so everything works out. This stochastic model is quite different from a smooth-running, coordinated machine usually imagined. view more 

Credit: James Graham, UC Davis

  • Failures in DNA replication can lead to cancer, birth defects or other harm
  • Video shows single pieces of double-helix DNA being copied
  • Single-molecule view gives new insights into this process essential to life

Almost all life on earth is based on DNA being copied, or replicated, and understanding how this process works could lead to a wide range of discoveries in biology and medicine. Now for the first time scientists have been able to watch individual steps in the replication of a single DNA molecule, with some surprising findings. For one thing, there’s a lot more randomness at work than has been thought.

“It’s a different way of thinking about replication that raises new questions,” said Stephen Kowalczykowski, distinguished professor in microbiology and molecular genetics at the University of California, Davis, and at the UC Davis Comprehensive Cancer Center. The work is published June 15 in the journal Cell with co-authors James Graham, postdoctoral researcher at UC Davis, and Kenneth Marians, Sloan Kettering Cancer Center.

Using sophisticated imaging technology and a great deal of patience, the researchers were able to watch DNA from E. coli bacteria as it replicated and measure how fast enzyme machinery worked on the different strands.

DNA replication basics

The DNA double helix is made from two strands that run in opposite directions. Each strand is made of a series of bases, A, T, C and G, that pair up between the strands: A to T and C to G.

The first step in replication is an enzyme called helicase that unwinds and “unzips” the double helix into two single strands. An enzyme called primase attaches a “primer” to each strand that allows replication to start, then another enzyme called DNA polymerase attaches at the primer and moves along the strand adding new “letters” to form a new double helix.

(Look here for a video illustration.)

Because the two strands in the double helix run in opposite directions, the polymerases work differently on the two strands. On one strand — the “leading strand” — the polymerase can move continuously, leaving a trail of new double-stranded DNA behind it.

But on the other, “lagging strand,” the polymerase has to move in starts, attaching, producing a short stretch of double stranded DNA, then dropping off and starting again. Conventional wisdom is that the polymerases on the leading and lagging strands are somehow coordinated so that one does not get ahead of the other. If that did happen, it would create stretches of single-stranded DNA that are highly susceptible to damaging mutations.

The experiment: Rolling circles and fluorescent dye

To carry out their experiment, the researchers used a circular piece of DNA, attached to a glass slide by a short tail. As the replication machinery rolls around the circle, the tail gets longer. They could switch replication on by adding chemical fuel (nucleoside triphosphates, NTPs) and used a fluorescent dye that attaches to double-stranded DNA to light up the growing strands. Finally, the whole set up is in a flow chamber, so the DNA strands stretch out like banners in the breeze.

Stops, starts and variable speeds

Once Graham, Marians and Kowalczykowski started watching individual DNA strands, they noticed something unexpected. Replication stops unpredictably, and when it starts up again, can change speed.

“The speed can vary about tenfold,” Kowalczykowski said.

Sometimes the lagging strand synthesis stops, but the leading strand continues to grow. This shows up as a dark area in the glowing strand, because the dye doesn’t stick to single-stranded DNA.

“We’ve shown that there is no coordination between synthesis of the two strands. They are completely autonomous,” Kowalczykowski said.

What looks like coordination is actually the outcome of a random process of starting, stopping and variable speeds. Over time, any one DNA polymerase will move at an average speed; look at a number of DNA polymerases synthesizing DNA strands over time, and they will have the same average speed.

Kowalczykowski likened it to traffic on a freeway.

“Sometimes the traffic in the next lane is moving faster and passing you, and then you pass it. But if you travel far enough you get to the same place at the same time.”

The researchers also found a kind of “dead man’s switch” or automatic brake on the helicase, which unzips DNA ahead of the rest of the enzymes. When polymerase stops, helicase can keep moving, potentially opening up a gap of unwound DNA that could be vulnerable to damage. In fact, exposed single-strand DNA sets off an alarm signal inside the cell that activates repair enzymes.

But it turns out that when it gets uncoupled and starts to run away from the rest of the replication complex, helicase slows down about fivefold. So it can chug along until the rest of the enzymes catch up, then speed up again.

This new stochastic view is a new way of thinking about DNA replication and other biochemical processes, Kowalczykowski said.

“It’s a real paradigm shift, and undermines a great deal of what’s in the textbooks,” he said.

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The work was supported by grants from the National Institutes of Health. James Graham is now at Oxford Nanopore Technologies, Oxford, U.K.


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