https://www.sciencedaily.com/releases/2017/06/170621132907.htm

Date: June 21, 2017
Source: DOE/Lawrence Berkeley National Laboratory
Summary: The mechanisms that separate mixtures of oil and water may also help the organization of a part of our DNA called heterochromatin, according to a new study. Researchers found that liquid-liquid phase separation helps heterochromatin organize large parts of the genome into specific regions of the nucleus. The work addresses a long-standing question about how DNA functions are organized in space and time, including how genes are silenced or expressed.

The same mechanisms that quickly separate mixtures of oil and water are at play when controlling the organization in an unusual part of our DNA called heterochromatin, according to a new study by researchers at the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab).

Researchers studying genome and cell biology provide evidence that heterochromatin organizes large parts of the genome into specific regions of the nucleus using liquid-liquid phase separation, a mechanism well known in physics but whose importance for biology has only recently been revealed.

They present their findings June 21 in the journal Nature, addressing a long-standing question about how DNA functions are organized in space and time, including how genes are regulated to be silenced or expressed.

“The importance of DNA sequences in health and disease has been clear for decades, but we only recently have come to realize that the organization of sections of DNA into different physical domains or compartments inside the nucleus is critical to promote distinct genome functions,” said study corresponding author, Gary Karpen, senior scientist at Berkeley Lab’s Biological Systems and Engineering Division.

The long stretches of DNA in heterochromatin contain sequences that, for the most part, need to be silenced for cells to work properly. Scientists once thought that compaction of the DNA was the primary mechanism for controlling which enzymes and molecules gain access to the sequences. It was reasoned that the more tightly wound the strands, the harder it would be to get to the genetic material inside.

That mechanism has been questioned in recent years by the discovery that some large protein complexes could get inside the heterochromatin domain, while smaller proteins can remain shut out.

In this new study of early Drosophila embryos, the researchers observed two non-mixing liquids in the cell nucleus: one that contained expressed genes, and one that contained silenced heterochromatin. They found that heterochromatic droplets fused together just like two drops of oil surrounded by water.

In lab experiments, researchers purified heterochromatin protein 1a (HP1a), a main component of heterochromatin, and saw that this single component was able to recreate what they saw in the nucleus by forming liquid droplets.

“We are excited about these findings because they explain a mystery that’s existed in the field for a decade,” said study lead author Amy Strom, a graduate student in Karpen’s lab. “That is, if compaction controls access to silenced sequences, how are other large proteins still able to get in? Chromatin organization by phase separation means that proteins are targeted to one liquid or the other based not on size, but on other physical traits, like charge, flexibility, and interaction partners.”

The Berkeley Lab study, which used fruit fly and mouse cells, will be published alongside a companion paper in Nature led by UC San Francisco researchers, who showed that the human version of the HP1a protein has the same liquid droplet properties, suggesting that similar principles hold for human heterochromatin.

Interestingly, this type of liquid-liquid phase separation is very sensitive to changes in temperature, protein concentration, and pH levels.

“It’s an elegant way for the cell to be able to manipulate gene expression of many sequences at once,” said Strom.

Other cellular structures, including some involved in disease, are also organized by phase separation.

“Problems with phase separation have been linked to diseases such as dementia and certain neurodegenerative disorders,” said Karpen.

He noted that as we age, biological molecules lose their liquid state and become more solid, accumulating damage along the way. Karpen pointed to diseases like Alzheimer’s and Huntington’s, in which proteins misfold and aggregate, becoming less liquid and more solid over time.

“If we can better understand what causes aggregation, and how to keep things more liquid, we might have a chance to combat these types of disease,” Strom added.

The work is a big step forward for understanding how DNA functions, but could also help researchers improve their ability to manipulate genes.

“Gene therapy, or any treatment that relies on tight regulation of gene expression, could be improved by precisely targeting molecules to the right place in the nucleus,” says Karpen. “It is very difficult to target genes located in heterochromatin, but this understanding of the properties linked to phase separation and liquid behaviors could help change that and open up a third of the genome that we couldn’t get to before.”

This includes targeting gene-editing technologies like CRISPR, which has recently opened up new doors for precise genome manipulation and gene therapy.

Story Source:

Materials provided by DOE/Lawrence Berkeley National Laboratory. Note: Content may be edited for style and length.

Can you summarise?

Trying to summarise.

It isn’t just epigenetics that modifies rates of protein expression. It’s also the compaction of the DNA within the nucleus. It was reasoned that the more tightly wound the strands, the harder it would be to get to the genetic material inside. A problem with that is that sometimes large enzymes can get inside the tightly would strands when small enzymes can’t.

This compaction is largely controlled by heterochromatin protein 1a (HP1a).

Researches now find that that HP1a.is able to explain gene regulation, not just by compaction but also by forming liquid droplets within the nucleus. Genetic material droplets fused together just like two drops of oil surrounded by water. And this much more easily explains which enzymes can and cannot get access to this material.

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I still don’t get it. Are the researchers saying that tightly wound DNA in the presence of HP1a is hydrophobic, and that enzymes are hydrophilic? Or something else?

“rom: monkey skipper
ID: 1081482
Subject: re: New mechanism for genome regulation discovered – Implications for improving gene therapy

The same mechanisms that quickly separate mixtures of oil and water are at play when controlling the organization in an unusual part of our DNA called heterochromatin, according to a new study by researchers at the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab).

Researchers studying genome and cell biology provide evidence that heterochromatin organizes large parts of the genome into specific regions of the nucleus using liquid-liquid phase separation, a mechanism well known in physics but whose importance for biology has only recently been revealed.

They present their findings June 21 in the journal Nature, addressing a long-standing question about how DNA functions are organized in space and time, including how genes are regulated to be silenced or expressed.

“The importance of DNA sequences in health and disease has been clear for decades, but we only recently have come to realize that the organization of sections of DNA into different physical domains or compartments inside the nucleus is critical to promote distinct genome functions,” said study corresponding author, Gary Karpen, senior scientist at Berkeley Lab’s Biological Systems and Engineering Division.

The long stretches of DNA in heterochromatin contain sequences that, for the most part, need to be silenced for cells to work properly. Scientists once thought that compaction of the DNA was the primary mechanism for controlling which enzymes and molecules gain access to the sequences. It was reasoned that the more tightly wound the strands, the harder it would be to get to the genetic material inside.

That mechanism has been questioned in recent years by the discovery that some large protein complexes could get inside the heterochromatin domain, while smaller proteins can remain shut out.”

I understand this to mean that DNA has evolved to use the way fluids separate from eachother like the oil and water example mentioned above to hold the literal positions of the contents of DNA and ultimately the functionality or non-functionality of different bits.

They used the same principles in some experiements and found they could move bits into position by using the methods artificially getting the same responses.

This could help inn gene therapy because the heterochromatin aids in how switches in the DNA turn on and turn off. If you can move the switches , using the same techniques then adjusting DNA to treat illness may become potentially easier.

To move proteins and enzymes around by adjusting the surface tension by adjusting the viscosity of the fluids seems helpful when I think about cancer treatments for example.

> They used the same principles in some experiements and found they could move bits into position by using the methods artificially getting the same responses.

Nice.

> This could help inn gene therapy because the heterochromatin aids in how switches in the DNA turn on and turn off. If you can move the switches , using the same techniques then adjusting DNA to treat illness may become potentially easier.

I don’t see how. The enzyme involved in producing heterochromatin can’t be changed. The methylation can’t be changed and effect of the DNA sequence on the heterochromatin can’t be changed. At least not easily. So what can be changed? The positioning of genes along the DNA strand perhaps (known as a translocation)? You’d have to make sure that the cells with the translocations didn’t end up in sperm or egg.

> To move proteins and enzymes around by adjusting the surface tension by adjusting the viscosity of the fluids seems helpful when I think about cancer treatments for example.

That wouldn’t be much use. Or would it? It would have a sort of bludgeon effect that wouldn’t last. But you’re right, I hadn’t thought of cancer. I was thinking more along the lines of Downs Syndrome where it helps to disable the duplicated chromosomal material.

mollwollfumble said:

> They used the same principles in some experiements and found they could move bits into position by using the methods artificially getting the same responses.

Nice.

> This could help inn gene therapy because the heterochromatin aids in how switches in the DNA turn on and turn off. If you can move the switches , using the same techniques then adjusting DNA to treat illness may become potentially easier.

I don’t see how. The enzyme involved in producing heterochromatin can’t be changed. The methylation can’t be changed and effect of the DNA sequence on the heterochromatin can’t be changed. At least not easily. So what can be changed? The positioning of genes along the DNA strand perhaps (known as a translocation)? You’d have to make sure that the cells with the translocations didn’t end up in sperm or egg.

> To move proteins and enzymes around by adjusting the surface tension by adjusting the viscosity of the fluids seems helpful when I think about cancer treatments for example.

That wouldn’t be much use. Or would it? It would have a sort of bludgeon effect that wouldn’t last. But you’re right, I hadn’t thought of cancer. I was thinking more along the lines of Downs Syndrome where it helps to disable the duplicated chromosomal material.

i think it is interesting and it made me think of junk dna being organised chaos.

mollwollfumble said:

> They used the same principles in some experiements and found they could move bits into position by using the methods artificially getting the same responses.

Nice.

> This could help inn gene therapy because the heterochromatin aids in how switches in the DNA turn on and turn off. If you can move the switches , using the same techniques then adjusting DNA to treat illness may become potentially easier.

I don’t see how. The enzyme involved in producing heterochromatin can’t be changed. The methylation can’t be changed and effect of the DNA sequence on the heterochromatin can’t be changed. At least not easily. So what can be changed? The positioning of genes along the DNA strand perhaps (known as a translocation)? You’d have to make sure that the cells with the translocations didn’t end up in sperm or egg.

Mollwolfumble said:I don’t see how. The enzyme involved in producing heterochromatin can’t be changed. The methylation can’t be changed and effect of the DNA sequence on the heterochromatin can’t be changed. At least not easily. So what can be changed? The positioning of genes along the DNA strand perhaps (known as a translocation)? You’d have to make sure that the cells with the translocations didn’t end up in sperm or egg.

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This next bit seems to state that proteins move into a space with the enzymes as this affects functionality

see below :

.The long stretches of DNA in heterochromatin contain sequences that, for the most part, need to be silenced for cells to work properly. Scientists once thought that compaction of the DNA was the primary mechanism for controlling which enzymes and molecules gain access to the sequences. It was reasoned that the more tightly wound the strands, the harder it would be to get to the genetic material inside.

That mechanism has been questioned in recent years by the discovery that some large protein complexes could get inside the heterochromatin domain, while smaller proteins can remain shut out..