Eukaryotic chromosome structure

Eukaryotic chromosome structure refers to the levels of packaging from raw DNA molecules to the chromosomal structures seen during metaphase in mitosis or meiosis. Chromosomes contain long strands of DNA containing genetic information. Compared to prokaryotic chromosomes, eukaryotic chromosomes are much larger in size and are linear chromosomes.^[1] Eukaryotic chromosomes are also stored in the cell nucleus, while chromosomes of prokaryotic cells are not stored in a nucleus.

History[]

Some of the first scientists to recognize the structures now known as chromosomes were Schleiden, Virchow, and Bütschli. The term was coined by Heinrich Wilhelm Gottfried von Waldeyer-Hartz, referring to the term chromatin, was introduced by Walther Flemming.

In the 1900s, many scientists concluded the same ideas of heredity that Gregor Mendel had previously. Scientists also discovered plant and animal cells have a central compartment called the nucleus. They soon realized chromosomes were found inside the nucleus and contained different information for many different traits.

Structure[]

DNA (gray) wraps around proteins known as histones (yellow) in order to form condensed nucleosomes.

In eukaryotes, such as humans, roughly 3.2 billion nucleotides are spread out over 23 different chromosomes (males have both an X chromosome and a Y chromosome instead of a pair of X chromosomes as seen in females). Each chromosome consists enormously long linear DNA molecule associated with proteins that fold and pack the fine thread of DNA into a more compact structure.^[2]

The nucleosome consists of a DNA double helix bound to an octamer of core histones (2 dimers of H2A and H2B, and an H3/H4 tetramer). About 147 base pairs of DNA coil around 1 octamer, and ~20 base pairs are sequestered by the addition of the linker histone (H1), and various length of "linker" DNA (~0-100 bp) separate the nucleosomes. The double helix was discovered in 1953 by James Watson and Francis Crick. Other researchers made very important, but unconnected findings about the composition of DNA. But it was up to Watson and Crick to put all of those findings together to come up with a model for DNA. Later, chemist Alexander Todd determined that the backbone of a DNA molecule contained repeating phosphate and deoxyribose sugar groups. The biochemist Erwin Chargaff found that adenine and thymine always paired while cytosine and guanine always paired. High resolution X-ray images of DNA that were obtained by Maurice Wilkins and Rosalind Franklin suggested a helical, or corkscrew like shape.^[3]

Packaging of nucleosomes into higher order chromatin structures involves the use of loops and coils.

Packaging of DNA is facilitated by the electrostatic charge distribution: phosphate groups cause DNA to have a negative charge, whilst the histones are positively charged. Most eukaryotic cells contain histones (with a few exceptions) as well as the kingdom Archaea. Histones are positively charged molecules as they contain lysine and arginine in larger quantities and DNA is negatively charged. So they make a strong ionic bond in between them to form nucleosome. Packaging is also accomplished by specialized proteins that bind and fold the DNA. This generates a series of loops and coils that provide increasingly higher levels of organization and prevent the DNA from becoming tangled and unmanageable.^[4] This complex of DNA and proteins are called chromatin.^[5] But in addition to proteins involved with packaging, chromosomes are associated with proteins involved with DNA replication, DNA repair, and gene expression.^[6]

Commonly, many people think the structure of a chromosome is in an "X" shape. But this is only present when the cell divides. Researchers have now been able to model the structure of chromosomes when they are active. This is extremely important because the way that DNA folds up in chromosome structures is linked to the way DNA is used. Scientists have been able to develop the 3D structures of chromosomes in a single cell. The scientists used hundreds of measurements of where different parts of the DNA get close to one another to help create this model. This research was done by scientists at the Department of Biochemistry at Cambridge, working with others from the Babraham Institute and the Weizmann Institute. ^[7]

References[]

^ Alberts; Bray; Hopkins; Johnson; Lewis; Raff; Roberts; Walter. Essential Cell Biology (4th ed.). Garland Science. Retrieved 15 September 2014.
^ "Eukaryotic Chromosome Structure". www.ndsu.edu. Retrieved 15 September 2014.
^ "The Francis Crick Papers." : The Discovery of the Double Helix, 1951-1953. N.p., n.d. Web. 16 Nov. 2014.
^ Cox, Michael M. (2015). Molecular biology : principles and practice. Jennifer A. Doudna, Michael O'Donnell (Second ed.). New York. pp. 337–338. ISBN 978-1-4641-2614-7.
^ "Eukaryotic Chromosome Structure". SciencePrimer. Retrieved 15 September 2014.
^ "Chromosome". www.nature.com. Retrieved 15 September 2014.
^ "Structure of Chromosomes Revealed." University of Cambridge. N.p., 30 Sept. 2013. Web. 16 Nov. 2014.

[1] Alberts; Bray; Hopkins; Johnson; Lewis; Raff; Roberts; Walter. Essential Cell Biology (4th ed.). Garland Science. Retrieved 15 September 2014.

[2] "Eukaryotic Chromosome Structure". www.ndsu.edu. Retrieved 15 September 2014.

[3] "The Francis Crick Papers." : The Discovery of the Double Helix, 1951-1953. N.p., n.d. Web. 16 Nov. 2014.

[4] Cox, Michael M. (2015). Molecular biology : principles and practice. Jennifer A. Doudna, Michael O'Donnell (Second ed.). New York. pp. 337–338. ISBN 978-1-4641-2614-7.

[5] "Eukaryotic Chromosome Structure". SciencePrimer. Retrieved 15 September 2014.

[6] "Chromosome". www.nature.com. Retrieved 15 September 2014.

[7] "Structure of Chromosomes Revealed." University of Cambridge. N.p., 30 Sept. 2013. Web. 16 Nov. 2014.

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