Solenoid (DNA)

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30 nm chromatin fibre in solenoid structure Solenoid 30 nm fibre structure closer and farther away.png
30 nm chromatin fibre in solenoid structure

The solenoid structure of chromatin is a model for the structure of the 30 nm fibre. It is a secondary chromatin structure which helps to package eukaryotic DNA into the nucleus.

Contents

Background

Chromatin was first discovered by Walther Flemming by using aniline dyes to stain it. In 1974, it was first proposed by Roger Kornberg that chromatin was based on a repeating unit of a histone octamer and around 200 base pairs of DNA. [1]

The solenoid model was first proposed by John Finch and Aaron Klug in 1976. They used electron microscopy images and X-ray diffraction patterns to determine their model of the structure. [2] This was the first model to be proposed for the structure of the 30 nm fibre.

Structure

DNA in the nucleus is wrapped around nucleosomes, which are histone octamers formed of core histone proteins; two histone H2A-H2B dimers, two histone H3 proteins, and two histone H4 proteins. The primary chromatin structure, the least-packed form, is the 11 nm, or “beads on a string” form, where DNA is wrapped around nucleosomes at relatively regular intervals, as Roger Kornberg proposed.

Histone H1 protein binds to the site where DNA enters and exits the nucleosome, wrapping 147 base pairs around the histone core and stabilising the nucleosome, [3] this structure is a chromatosome. [4] In the solenoid structure, the nucleosomes fold up and are stacked, forming a helix. They are connected by bent linker DNA which positions sequential nucleosomes adjacent to one another in the helix. The nucleosomes are positioned with the histone H1 proteins facing toward the centre where they form a polymer. [3] Finch and Klug determined that the helical structure had only one-start point because they mostly observed small pitch angles of 11 nm, [2] which is about the same diameter as a nucleosome. There are approximately 6 nucleosomes in each turn of the helix. [2] Finch and Klug actually observed a wide range of nucleosomes per turn but they put this down to flattening. [2]

Finch and Klug's electron microscopy images had a lack of visible detail so they were unable to determine helical parameters other than the pitch. [2] More recent electron microscopy images have been able to define the dimensions of solenoid structures and identified it as a left-handed helix. [5] The structure of solenoids are insensitive to changes in the length of the linker DNA.

Function

The solenoid structure's most obvious function is to help package the DNA so that it is small enough to fit into the nucleus. This is a big task as the nucleus of a mammalian cell has a diameter of approximately 6 µm, whilst the DNA in one human cell would stretch to just over 2 metres long if it were unwound. [6] The "beads on a string" structure can compact DNA to 7 times smaller. [1] The solenoid structure can increase this to be 40 times smaller. [2]

When DNA is compacted into the solenoid structure can still be transcriptionally active in certain areas. [7] It is the secondary chromatin structure that is important for this transcriptional repression as in vivo active genes are assembled in large tertiary chromatin structures. [7]

Formation

There are many factors that affect whether the solenoid structure will form or not. Some factors alter the structure of the 30 nm fibre, and some prevent it from forming in that region altogether.

The concentration of ions, particularly divalent cations affects the structure of the 30 nm fibre, [8] which is why Finch and Klug were not able to form solenoid structures in the presence of chelating agents. [2]

There is an acidic patch on the surface of histone H2A and histone H2B proteins which interacts with the tails of histone H4 proteins in adjacent nucleosomes. [9] These interactions are important for solenoid formation. [9] Histone variants can affect solenoid formation, for example H2A.Z is a histone variant of H2A, and it has a more acidic patch than the one on H2A, so H2A.Z would have a stronger interaction with histone H4 tails and probably contribute to solenoid formation. [9]

The histone H4 tail is essential for formation of 30 nm fibres. [9] However, acetylation of core histone tails affects the folding of chromatin by destabilising interactions between the DNA and the nucleosomes, making histone modulation a key factor in solenoid structure. [9] Acetylation of H4K16 (the lysine which is the 16th amino acid from the N-terminal of histone H4) inhibits 30 nm fibre formation. [10]

To decompact the 30 nm fibre, for instance to transcriptionally activate it, both H4K16 acetylation and removal of the histone H1 proteins are required. [11]

Further packaging

Chromatin can form a tertiary chromatin structure and be compacted even further than the solenoid structure by forming supercoils which have a diameter of around 700 nm. [12] This supercoil is formed by regions of DNA called scaffold/matrix attachment regions (SMARs) attaching to a central scaffolding matrix in the nucleus creating loops of solenoid chromatin between 4.5 and 112 kilobase pairs long. [12] The central scaffolding matrix itself forms a spiral shape for an additional layer of compaction. [12]

Alternative models

Solenoid model (left) and two-start twisted- ribbon model (right) of 30 nm fibre, showing DNA only. 30nm Chromatin Structures.png
Solenoid model (left) and two-start twisted- ribbon model (right) of 30 nm fibre, showing DNA only.

Several other models have been proposed and there is still a lot of uncertainty about the structure of the 30 nm fibre.

Even the more recent research produces conflicting information. There is data from electron microscopy measurements of the 30 nm fibre dimensions that has physical constraints which mean it can only be modelled with a one-start helical structure like the solenoid structure. [5] It also shows there is no linear relationship between the length of the linker DNA and the dimensions (instead there are two distinct classes). [5] There is also data from experiments which cross-linked nucleosomes that shows a two-start structure. [13] There is evidence that suggests both the solenoid and zig-zag (two-start) structures are present in 30 nm fibres. [14] It is possible that chromatin structure may not be as ordered as previously thought, [15] or that the 30 nm fibre may not even be present in situ . [16]

Two-start twisted-ribbon model

The two-start twisted-ribbon model was proposed in 1981 by Worcel, Strogatz and Riley. [17] This structure involves alternating nucleosomes stacking to form two parallel helices, with the linker DNA zig-zagging up and down the helical axis.

Two-start cross-linker model

The two-start cross-linker model was proposed in 1986 by Williams et al. [18] This structure, like the two-start twisted-ribbon model, involves alternating nucleosomes stacking to form two parallel helices, but the nucleosomes are on opposite sides of the helices with the linker DNA crossing across the centre of the helical axis.

Superbead model

The superbead model was proposed by Renz in 1977. [19] This structure is not helical like the other models, it instead consists of discrete globular structures along the chromatin which vary in size. [20]

Some alternative forms of DNA packaging

The chromatin in mammalian sperm is the most condensed form of eukaryotic DNA, it is packaged by protamines rather than nucleosomes, [21] whilst prokaryotes package their DNA through supercoiling.

Related Research Articles

Chromatin is a complex of DNA and protein found in eukaryotic cells. The primary function is to package long DNA molecules into more compact, denser structures. This prevents the strands from becoming tangled and also plays important roles in reinforcing the DNA during cell division, preventing DNA damage, and regulating gene expression and DNA replication. During mitosis and meiosis, chromatin facilitates proper segregation of the chromosomes in anaphase; the characteristic shapes of chromosomes visible during this stage are the result of DNA being coiled into highly condensed chromatin.

<span class="mw-page-title-main">Histone</span> Family proteins package and order the DNA into structural units called nucleosomes.

In biology, histones are highly basic proteins abundant in lysine and arginine residues that are found in eukaryotic cell nuclei. They act as spools around which DNA winds to create structural units called nucleosomes. Nucleosomes in turn are wrapped into 30-nanometer fibers that form tightly packed chromatin. Histones prevent DNA from becoming tangled and protect it from DNA damage. In addition, histones play important roles in gene regulation and DNA replication. Without histones, unwound DNA in chromosomes would be very long. For example, each human cell has about 1.8 meters of DNA if completely stretched out; however, when wound about histones, this length is reduced to about 90 micrometers (0.09 mm) of 30 nm diameter chromatin fibers.

<span class="mw-page-title-main">Nucleosome</span> Basic structural unit of DNA packaging in eukaryotes

A nucleosome is the basic structural unit of DNA packaging in eukaryotes. The structure of a nucleosome consists of a segment of DNA wound around eight histone proteins and resembles thread wrapped around a spool. The nucleosome is the fundamental subunit of chromatin. Each nucleosome is composed of a little less than two turns of DNA wrapped around a set of eight proteins called histones, which are known as a histone octamer. Each histone octamer is composed of two copies each of the histone proteins H2A, H2B, H3, and H4.

<span class="mw-page-title-main">Histone octamer</span> 8-protein complex forming the core of nucleosomes

In molecular biology, a histone octamer is the eight-protein complex found at the center of a nucleosome core particle. It consists of two copies of each of the four core histone proteins. The octamer assembles when a tetramer, containing two copies of H3 and two of H4, complexes with two H2A/H2B dimers. Each histone has both an N-terminal tail and a C-terminal histone-fold. Each of these key components interacts with DNA in its own way through a series of weak interactions, including hydrogen bonds and salt bridges. These interactions keep the DNA and the histone octamer loosely associated, and ultimately allow the two to re-position or to separate entirely.

<span class="mw-page-title-main">Histone H1</span> Components of chromatin in eukaryotic cells

Histone H1 is one of the five main histone protein families which are components of chromatin in eukaryotic cells. Though highly conserved, it is nevertheless the most variable histone in sequence across species.

<span class="mw-page-title-main">HIST4H4</span>

Histone H4 is a protein that in humans is encoded by the HIST4H4 gene.

<span class="mw-page-title-main">HIST2H4A</span> Protein-coding gene in the species Homo sapiens

Histone H4 is a protein that in humans is encoded by the HIST2H4A gene.

<span class="mw-page-title-main">HIST3H2A</span> Protein-coding gene in the species Homo sapiens

Histone H2A type 3 is a protein that in humans is encoded by the HIST3H2A gene.

<span class="mw-page-title-main">HIST1H2AA</span> Protein-coding gene in the species Homo sapiens

Histone H2A type 1-A is a protein that in humans is encoded by the HIST1H2AA gene.

<span class="mw-page-title-main">HIST1H2BA</span> Protein-coding gene in the species Homo sapiens

Histone H2B type 1-A is a protein that in humans is encoded by the HIST1H2BA gene.

<span class="mw-page-title-main">HIST1H4A</span> Protein-coding gene in the species Homo sapiens

Histone H4 is a protein that in humans is encoded by the HIST1H4A gene.

<span class="mw-page-title-main">H2AFV</span> Protein-coding gene in the species Homo sapiens

Histone H2A.V is a protein that in humans is encoded by the H2AFV gene.

<span class="mw-page-title-main">HIST1H4D</span> Protein-coding gene in the species Homo sapiens

Histone H4 is a protein that in humans is encoded by the HIST1H4D gene.

<span class="mw-page-title-main">HIST1H2AD</span> Protein-coding gene in the species Homo sapiens

Histone H2A type 1-D is a protein that in humans is encoded by the HIST1H2AD gene.

<span class="mw-page-title-main">HIST1H3G</span> Protein-coding gene in the species Homo sapiens

Histone H3.1 is a protein that in humans is encoded by the HIST1H3G gene.

<span class="mw-page-title-main">H2AFJ</span> Protein-coding gene in humans

Histone H2A.J is a protein that in humans is encoded by the H2AFJ gene.

<span class="mw-page-title-main">HIST1H3H</span> Protein-coding gene in the species Homo sapiens

Histone H3.1 is a protein that in humans is encoded by the HIST1H3H gene.

<span class="mw-page-title-main">HIST1H4E</span> Protein-coding gene in the species Homo sapiens

Histone H4 is a protein that in humans is encoded by the HIST1H4E gene.

<span class="mw-page-title-main">HIST1H4G</span> Protein-coding gene in the species Homo sapiens

Histone H4-like protein type G is a protein that in humans is encoded by the HIST1H4G gene.

<span class="mw-page-title-main">Nucleic acid quaternary structure</span>

Nucleic acidquaternary structure refers to the interactions between separate nucleic acid molecules, or between nucleic acid molecules and proteins. The concept is analogous to protein quaternary structure, but as the analogy is not perfect, the term is used to refer to a number of different concepts in nucleic acids and is less commonly encountered. Similarly other biomolecules such as proteins, nucleic acids have four levels of structural arrangement: primary, secondary, tertiary, and quaternary structure. Primary structure is the linear sequence of nucleotides, secondary structure involves small local folding motifs, and tertiary structure is the 3D folded shape of nucleic acid molecule. In general, quaternary structure refers to 3D interactions between multiple subunits. In the case of nucleic acids, quaternary structure refers to interactions between multiple nucleic acid molecules or between nucleic acids and proteins. Nucleic acid quaternary structure is important for understanding DNA, RNA, and gene expression because quaternary structure can impact function. For example, when DNA is packed into heterochromatin, therefore exhibiting a type of quaternary structure, gene transcription will be inhibited.

References

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