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==Your Heading Here (maybe something like 'Structure')== 0
=='''Structure of RAG1/2-DNA Strand Transfer Complex (paired conformation)'''==
<StructureSection load='2MV8' size='400' side='right' caption='Caption for this structure' scene='75/752271/Intro_1/1'><scene name='75/752271/Intro_3_isolated_and_labeled/1'></scene><scene name='75/752271/Intro_3_isolated_and_labeled/1'>Text To Be Displayed</scene>
<StructureSection load='6XNY' size='340' side='right' caption='Structure of RAG1/2-DNA Strand Transfer Complex (Paired Conformation)' scene='75/752271/Rag_complex_background/1'>
RAG1 is the catalytic component of the RAG Complex. Together with RAG2, the RAG Complex functions to create antibodies for virtually any antigen.


This is a default text for your page '''Sandbox GGC9'''. Click above on '''edit this page''' to modify. Be careful with the &lt; and &gt; signs.
== '''Function''' ==
You may include any references to papers as in: the use of JSmol in Proteopedia <ref>DOI doi: 10.1128/JVI.00555-16</ref> or to the article describing Jmol <ref>PMID:21638687</ref> to the rescue. <ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
RAG1 and RAG2 together form the RAG Complex (RAG Recombinases), which is responsible for regulating the DNA cleavage phase during V(D)J recombination. V(D)J recombination functions to produce a plethora of immune molecules in developing B and T cells. The B and T immune cells contain proteins on their surfaces which allow for the recognition of different pathogens and elicits proper immune responses. The RAG genes, which are responsible for making these proteins, have different segments which are known as V, variable, D, diversity and J, joining. These segments can be combined and rearranged to create the diversity required for the proteins for the B and T cells.  RAG1 functions as the catalytic portion while RAG2, although not catalytic, is required for RAG1 to function.[1] RAG1 controls the ability of the DNA to bind to the RSS or recombination signal sequences. RAG1 is able to  to create a double-stranded break between the (RSS) and the adjacent coding sequence. This rearrangement is carried out in the following way: introduction of a nick in the DNA backbone through hairpin formation and then creating a hydroxyl group at the 3' end which attacks the phosphodiester bond on the opposite strand.[1] This mechanism is a direct transesterification reaction which results in four differentiated DNA ends. Studies of this recombination suggest that the RAG1/2 recombinase complex acts as a transposon, with similar mechanisms.[2] Histones also assist in the nicking and hairpinning of the strands. The result is the recombination of variable genes joining to produce proteins in a response to different pathogens.[1] Additionally to the role played in V(D)J recombination, RAG also assists B cell allelic exclusion which means that it is able to silence one allele of the B cell but can express the other allele. RAG1 also possess ubiquitin properties.  
</ref>


== Function ==
== '''Disease''' ==
Mutations of the RAG recombinases are often occurring in patients being displaying immunodeficiency and Omenn syndrome. [3] Omenn's syndrome is a severe combined immunodeficiency. [4] Some characteristics include redness of skin, peeling skin, hair loss, chronic diarrhea, enlarged lymph nodes, swelling of liver and spleen, and increased levels of of serum IgE. [4]


Prions are proteins with compromised folds in their structure. They can convert a normal protein into a replicate of their own abnormal form. This can lead to deadly degenerative diseases of the brain. Studies have shown that prions are linked to Alzheimer's and Parkinson's disease.




== Disease ==


There are different prions that arise from different conditions. Prion diseases are usually obtained via the consumption of infected meat products. Creutzfeldt-Jakob is the most common form of the disease that affects humans. Prions are found abnormally clustered in the brain. CJD can be inherited, so it is usually associated with family occurrences, thus given the name familial CJD. CJD also can also develop in individuals that are at the age of 60 years old. CJD can also be acquired through infected tissue and lack of sterilization in a medical procedure. An example of such acquired CJD in procedure would be a cornea transplant.<ref>3
</ref> 


Variant CJD is one of the different kind of prion disease that is related to the infamous mad cow disease. This CJD can be obtained through the consumption of diseased meat. This variant of the disease usually affects younger individuals.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
[[Image:Omenn's_Baby.jpg]]
</ref>
(Hsu et al 2011)


Variable protease (VPSPRr) Another variant of disease, sensitive prionopathy is a very rare condition that affects individuals around the age of 70 years old. It is Like CJD, however, the protein is not digested easily. This variant of the disease usually occurs in an individual who has history of dementia in their family.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
== '''Relevance''' ==
</ref>
Early intervention of people with Omenn's syndrome is important, because if left untreated it will be fatal. [4] Treatment of Omenn's syndrome includes bone marrow or cord blood stem cell transplantation. [4]
== '''Structural highlights''' ==


The symptoms can lead to a severe disability due to the important functions that proteins are responsible for. It can also lead to death, however, studies show in most cases death occurs within a year.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
The subunit structure is defined as a homodimer.
</ref> 


Gerstmann- Straussler Scheinker disease is another extremely rare variant that presents itself at an early age in individuals around 40. Kuru is also a variant that was commonly seen in New Guinea. This variant presents itself after the consumption of human brain tissue, usually after the death of the individual, so the tissue is usually infected by prions at the time.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
The zinc site plays an important role in DNA cleavage; without the zinc site the DNA would not be able to be cleaved and would not form the essential hairpin structure.[5]<scene name='75/752271/Zinc_ligands/1'>Zinc Ligands</scene>
</ref>  


The last variant is fatal insomnia, which is also a very rare hereditary disorder that makes the individual have difficulty sleeping. There is a sporadic version of this type that can be acquired not through inheritance.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
<scene name='75/752271/Zinc_finger_motif/1'>Ring Zinc Finger</scene> of dimerization domain.
</ref>  


The disease cannot be cured, however, it can be managed through medications to slow the progression.<ref>http://www.hopkinsmedicine.org/healthlibrary/conditions/nervous_system_disorders/prion_diseases_134,56/
</ref>
== Structural highlights ==


<scene name='75/752271/Intro_1/1'>In this scene original structure of the mammalian Prp protein is portrayed.</scene>
Initial studies identified aspartic acid residues at positions 600 and 708 function to initiate catalysis.[7]<scene name='75/752271/Catalytic_residues/1'>Catalytic Residues</scene>


There are three alpha helices and a long side chain.


In addition to the catalytic function of aspartic acid residues at 600 and 708.
Researchers have discovered a trio of residues that are necessary for the DNA cleavage during V(D)J recombination. This trio includes the two catalytic residues as well as a Glutamic acid residue at position 962.[8]<scene name='75/752271/Dde_motif/1'>Residues responsible for DNA cleavage</scene>


<scene name='75/752271/Intro_2_isolated_side_chain/1'>In this scene, the side chain for the protein is emphasized in a ball and stick illustration.</scene>
 
The side chain is illustrated in ball and stick form, making it easier to identify the sulfide bond in the side chain.
Residues 265-383 on RAG 1 contain ubiquitin ligase activity. <scene name='75/752271/Ubiquitin_ligase_activity/1'>Ubiquitin activity</scene>




<scene name='75/752271/Intro_3_isolated_and_labeled/1'>In this scene, H190, F201, Y152, Y148, Y160, and Y158 are labeled on the protein.</scene>
They are responsible for the tight binding of H3 to H1 via disulfide bonds because of they are aromatic. The different positions: H1, H2, and H3 respective helices contain these side chains in the protein.




</StructureSection>
</StructureSection>
== References ==
== '''References''' ==
<references/>
<references/>
[1] Grazini U, Zanardi F, Citterio E, Casola S, Goding CR, McBlane F. The RING domain of RAG1 ubiquitylates histone H3: a novel activity in chromatin-mediated regulation of V(D)J joining. Mol Cell. 2010 Jan 29;37(2):282-93. doi: 10.1016/j.molcel.2009.12.035. PMID: 20122409.
[2] Zhang Y, Corbett E, Wu S, Schatz DG. Structural basis for the activation and suppression of transposition during evolution of the RAG recombinase. EMBO J. 2020 Nov 2;39(21):e105857. doi: 10.15252/embj.2020105857. Epub 2020 Sep 18. PMID: 32945578; PMCID: PMC7604617.
[3] Chen, Karin et al. “Autoimmunity due to RAG deficiency and estimated disease incidence in RAG1/2 mutations.” The Journal of allergy and clinical immunology vol. 133,3 (2014): 880-2.e10. doi:10.1016/j.jaci.2013.11.038
[4] Omenn syndrome | Genetic and Rare Diseases Information Center (GARD) – an NCATS Program. Rarediseases.info.nih.gov. (2021). Retrieved 7 April 2021, from https://rarediseases.info.nih.gov/diseases/8198/omenn-syndrome.
[5] Gwyn, Lori M et al. “A zinc site in the C-terminal domain of RAG1 is essential for DNA cleavage activity.” Journal of molecular biology vol. 390,5 (2009): 863-78. doi:10.1016/j.jmb.2009.05.076
[6] Hsu, C., Yu-Yun Lee, J., & Chao, S. (2011). Omenn syndrome: a case report and review of literature. Dermatologica Sinica, 29(2). https://doi.org/doi.org/10.1016/j.dsi.2011.05.002
[7] Fugmann, S., Villey, I., Ptaszek, L., & Schatz, D. (2000). Identification of Two Catalytic Residues in RAG1 that Define a Single Active Site within the RAG1/RAG2 Protein Complex. Molecular Cell, 5(1), 97-107. https://doi.org/10.1016/s1097-2765(00)80406-2
[8] Swanson P. C. (2001). The DDE motif in RAG-1 is contributed in trans to a single active site that catalyzes the nicking and transesterification steps of V(D)J recombination. Molecular and cellular biology, 21(2), 449–458. https://doi.org/10.1128/MCB.21.2.449-458.2001

Latest revision as of 20:13, 28 April 2021

Structure of RAG1/2-DNA Strand Transfer Complex (paired conformation)Structure of RAG1/2-DNA Strand Transfer Complex (paired conformation)

RAG1 is the catalytic component of the RAG Complex. Together with RAG2, the RAG Complex functions to create antibodies for virtually any antigen.

Function

RAG1 and RAG2 together form the RAG Complex (RAG Recombinases), which is responsible for regulating the DNA cleavage phase during V(D)J recombination. V(D)J recombination functions to produce a plethora of immune molecules in developing B and T cells. The B and T immune cells contain proteins on their surfaces which allow for the recognition of different pathogens and elicits proper immune responses. The RAG genes, which are responsible for making these proteins, have different segments which are known as V, variable, D, diversity and J, joining. These segments can be combined and rearranged to create the diversity required for the proteins for the B and T cells. RAG1 functions as the catalytic portion while RAG2, although not catalytic, is required for RAG1 to function.[1] RAG1 controls the ability of the DNA to bind to the RSS or recombination signal sequences. RAG1 is able to to create a double-stranded break between the (RSS) and the adjacent coding sequence. This rearrangement is carried out in the following way: introduction of a nick in the DNA backbone through hairpin formation and then creating a hydroxyl group at the 3' end which attacks the phosphodiester bond on the opposite strand.[1] This mechanism is a direct transesterification reaction which results in four differentiated DNA ends. Studies of this recombination suggest that the RAG1/2 recombinase complex acts as a transposon, with similar mechanisms.[2] Histones also assist in the nicking and hairpinning of the strands. The result is the recombination of variable genes joining to produce proteins in a response to different pathogens.[1] Additionally to the role played in V(D)J recombination, RAG also assists B cell allelic exclusion which means that it is able to silence one allele of the B cell but can express the other allele. RAG1 also possess ubiquitin properties.

Disease

Mutations of the RAG recombinases are often occurring in patients being displaying immunodeficiency and Omenn syndrome. [3] Omenn's syndrome is a severe combined immunodeficiency. [4] Some characteristics include redness of skin, peeling skin, hair loss, chronic diarrhea, enlarged lymph nodes, swelling of liver and spleen, and increased levels of of serum IgE. [4]



(Hsu et al 2011)

Relevance

Early intervention of people with Omenn's syndrome is important, because if left untreated it will be fatal. [4] Treatment of Omenn's syndrome includes bone marrow or cord blood stem cell transplantation. [4]

Structural highlights

The subunit structure is defined as a homodimer.

The zinc site plays an important role in DNA cleavage; without the zinc site the DNA would not be able to be cleaved and would not form the essential hairpin structure.[5]

of dimerization domain.


Initial studies identified aspartic acid residues at positions 600 and 708 function to initiate catalysis.[7]


In addition to the catalytic function of aspartic acid residues at 600 and 708. Researchers have discovered a trio of residues that are necessary for the DNA cleavage during V(D)J recombination. This trio includes the two catalytic residues as well as a Glutamic acid residue at position 962.[8]


Residues 265-383 on RAG 1 contain ubiquitin ligase activity.



Structure of RAG1/2-DNA Strand Transfer Complex (Paired Conformation)

Drag the structure with the mouse to rotate

ReferencesReferences


[1] Grazini U, Zanardi F, Citterio E, Casola S, Goding CR, McBlane F. The RING domain of RAG1 ubiquitylates histone H3: a novel activity in chromatin-mediated regulation of V(D)J joining. Mol Cell. 2010 Jan 29;37(2):282-93. doi: 10.1016/j.molcel.2009.12.035. PMID: 20122409.

[2] Zhang Y, Corbett E, Wu S, Schatz DG. Structural basis for the activation and suppression of transposition during evolution of the RAG recombinase. EMBO J. 2020 Nov 2;39(21):e105857. doi: 10.15252/embj.2020105857. Epub 2020 Sep 18. PMID: 32945578; PMCID: PMC7604617.

[3] Chen, Karin et al. “Autoimmunity due to RAG deficiency and estimated disease incidence in RAG1/2 mutations.” The Journal of allergy and clinical immunology vol. 133,3 (2014): 880-2.e10. doi:10.1016/j.jaci.2013.11.038

[4] Omenn syndrome | Genetic and Rare Diseases Information Center (GARD) – an NCATS Program. Rarediseases.info.nih.gov. (2021). Retrieved 7 April 2021, from https://rarediseases.info.nih.gov/diseases/8198/omenn-syndrome.

[5] Gwyn, Lori M et al. “A zinc site in the C-terminal domain of RAG1 is essential for DNA cleavage activity.” Journal of molecular biology vol. 390,5 (2009): 863-78. doi:10.1016/j.jmb.2009.05.076

[6] Hsu, C., Yu-Yun Lee, J., & Chao, S. (2011). Omenn syndrome: a case report and review of literature. Dermatologica Sinica, 29(2). https://doi.org/doi.org/10.1016/j.dsi.2011.05.002

[7] Fugmann, S., Villey, I., Ptaszek, L., & Schatz, D. (2000). Identification of Two Catalytic Residues in RAG1 that Define a Single Active Site within the RAG1/RAG2 Protein Complex. Molecular Cell, 5(1), 97-107. https://doi.org/10.1016/s1097-2765(00)80406-2

[8] Swanson P. C. (2001). The DDE motif in RAG-1 is contributed in trans to a single active site that catalyzes the nicking and transesterification steps of V(D)J recombination. Molecular and cellular biology, 21(2), 449–458. https://doi.org/10.1128/MCB.21.2.449-458.2001

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