User:Matheus Andrade Bettiol/Sandbox 1

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Revision as of 02:36, 26 June 2023

1 Function
2 Disease
3 Structure
4 Post-Translational Modifications

Function

RhoA (Ras homology gene family member A) is a protein of the small GTPase family. It can be in two conformations, and therefore active, or and consequently inactive. Three factors regulate these two states ^[1]:

1. GEF (Guanine nucleotide exchange factors): promotes the exchange of GDP for GTP, activating RhoA. 6bc0

2. GAP (GTPase activating proteins): accelerates the hydrolysis of GTP, inhibiting RhoA. 6pxb

3. GDI (Guanine nucleotide dissociation inhibitor): translocates the membrane GTPase, sequestering it to the cytosol, also inhibiting RhoA.

This protein is an important molecular switch for activities associated with the cytoskeleton and the immune system. In relation to the cytoskeleton, it is a regulator or the cell migration, contributing to cell retraction through the ROCK (Rho-associated protein kinase) and LIMK (LIM kinase) pathway, which leads to contraction of acto-myosin II and actin polymerization. In addition, it is relevant for the assembly of occlusive junctions that seal the epithelium in selective permeability barriers, such as in the intestine. When it comes to the immune system, it is essential for the presentation of antigens and formation of immune synapses between the dendritic cell and the T lymphocyte. Not only that, but it also contributes to the recruitment and phagocytosis activity of neutrophils, macrophages and dendritic cells ^[2].

Disease

Mutations in RHOA have been linked to a predisposition to autoimmune diseases and cancer progression ^[3]. Additionally, RhoA signaling is possibly involved in the pathogenesis of neurodegenerative diseases, including Parkinson’s disease (PD), Alzheimer’s disease (AD), Huntington’s disease (HD), and amyotrophic lateral sclerosis (ALS) ^[4]. This may be related to the implication of Rho GTPases in brain development since these neurodegenerative diseases present an abnormal accumulation of misfolded peptides. One of these proteins could be RhoA.

In addition, different bacteria use a pathogenic strategy of inactivating RhoA through their toxins, which make post-translational modifications in the switch I region. The bacteria and their respective toxins are:

- Vibrio parahaemolyticus: VopS (adenylation of Thr 37)

- Histophilus somni: IbpA (adenylation of Try 34)

- Clostridium botulinum: C3 (ADP-ribosylation of Asn 41)

- Clostridium difficile: TcdB/A (glycosylation of Thr 37)

- Burkholderia cenocepacia: deamidation of Asn 41 ^[5]

Structure

RhoA is a monomeric protein comprise of 193 amino acids and its is characterized by the presence of six beta sheet (in yellow) surrounded by alfa helix (in pink) and 310 helix (in purple) connected by loops. Within the RhoA protein, distinct regions can be identified, each with specific functions:

: This domain is responsible for binding and hydrolyzing . Multiple parts of the protein are involved in the activity of this region ,Mg ion is also an important element, without which the affinity decreases more than 500-fold ^[6].

: This is a unique sequence insertion found within the GTPase domain of RhoA. It plays a role in the regulation and interaction of RhoA with other proteins.

Switch I and Switch II: These are two regions within the GTPase domain that undergo conformational changes upon GTP binding. In the following green links Switch I (in dark blue) and Switch II (in blue) can be seen in or . Their conformations dictate the ability of RhoA to interact with downstream effector proteins.

Insertion Domain: This region contributes to the overall structure of the protein being characteristic of many GTPases in the Rho family and could play a role in protein-protein interactions.

C-terminal Prenylation Site: The C-terminal region of RhoA undergoes prenylation, a post-translational modification where a prenyl lipid group (such as farnesyl or geranylgeranyl) is attached. Prenylation allows RhoA to anchor to cell membranes, facilitating its localization and interaction with membrane-associated proteins.

Post-Translational Modifications

Prenylation: the activation of Rho GTPase requires membrane binding, which is necessary for the interaction with membranous GEFs. The membrane association requires C-terminal prenylation, which involves the addition of a geranylgeranyl (20-carbon chain) to Cys190 in the CAAX motif.

Phosphorylation: can alter the subcellular localization of RhoA when occurs close to C-terminal lipid modifications. On the other hand, phosphorylation of the G-domain affects GTP/GDP cycling and the interaction with effector proteins.

Oxidation: RhoA can be oxidized on Cys16 and Cys20 (G1 domain), generating a disulfide bond that prevents guanine binding and GEF association, inactivating RhoA. However, if Tyr42 is phosphorylated, serving as a binding site for GEF, oxidation on Cys16/20 reduces the affinity of RhoA for GDI and increases the association with GEF, leading to RhoA activation.

Nitration: nitration on RhoA's Tyr34 (switch I region) introduces a negative charge that modifies the protein structure and leads to a faster GDP release and GTP reload, increasing RhoA activity.

Adenylation: adenylation on Tyr34 (switch I region) leads to RhoA inhibition.

Ubiquitination: target the protein for degradation by the proteasome. RhoA is ubiquitylated by E3 ubiquitin protein ligase complexes, that ubiquitinate either active RhoA on Lys6 and Lys7, inactive RhoA, or both states on Lys135.^[7]

References

↑ Jaffe AB, Hall A. Rho GTPases: biochemistry and biology. Annu Rev Cell Dev Biol. 2005;21:247-69. PMID:16212495 doi:10.1146/annurev.cellbio.21.020604.150721
↑ Bros M, Haas K, Moll L, Grabbe S. RhoA as a Key Regulator of Innate and Adaptive Immunity. Cells. 2019 Jul 17;8(7):733. PMID:31319592 doi:10.3390/cells8070733
↑ Hetmanski JH, Zindy E, Schwartz JM, Caswell PT. A MAPK-Driven Feedback Loop Suppresses Rac Activity to Promote RhoA-Driven Cancer Cell Invasion. PLoS Comput Biol. 2016 May 3;12(5):e1004909. PMID:27138333 doi:10.1371/journal.pcbi.1004909
↑ Schmidt SI, Blaabjerg M, Freude K, Meyer M. RhoA Signaling in Neurodegenerative Diseases. Cells. 2022 May 1;11(9):1520. PMID:35563826 doi:10.3390/cells11091520
↑ Xu H, Yang J, Gao W, Li L, Li P, Zhang L, Gong YN, Peng X, Xi JJ, Chen S, Wang F, Shao F. Innate immune sensing of bacterial modifications of Rho GTPases by the Pyrin inflammasome. Nature. 2014 Sep 11;513(7517):237-41. doi: 10.1038/nature13449. Epub 2014 Jun 11. PMID:24919149 doi:http://dx.doi.org/10.1038/nature13449
↑ Shimizu T, Ihara K, Maesaki R, Kuroda S, Kaibuchi K, Hakoshima T. An open conformation of switch I revealed by the crystal structure of a Mg2+-free form of RHOA complexed with GDP. Implications for the GDP/GTP exchange mechanism. J Biol Chem. 2000 Jun 16;275(24):18311-7. PMID:10748207 doi:10.1074/jbc.M910274199
↑ Schmidt SI, Blaabjerg M, Freude K, Meyer M. RhoA Signaling in Neurodegenerative Diseases. Cells. 2022 May 1;11(9):1520. PMID:35563826 doi:10.3390/cells11091520

Proteopedia Page Contributors and Editors (what is this?)

Matheus Andrade Bettiol

Retrieved from "http://52.214.119.220/wiki/index.php/User:Matheus_Andrade_Bettiol/Sandbox_1"

@@ Line 30: / Line 30: @@
 == Structure ==
-<scene name='97/973102/Estrutura_secundaria/1'>Secundary structure of RhoA</scene> is characterized by the presence of <span style="color:yellow;background-color:black;font-weight:bold;">six beta sheet (in yellow)</span> surrounded by <span style="color:pink;background-color:black;font-weight:bold;">alfa helix (in pink)</span> and <span style="color:purple;background-color:black;font-weight:bold;">310 helix (in purple)</span> connected by loops. Within the RhoA protein, distinct regions can be identified, each with specific functions:
+RhoA is a monomeric protein comprise of 193 amino acids and its <scene name='97/973102/Estrutura_secundaria/1'>secundary structure</scene> is characterized by the presence of <span style="color:yellow;background-color:black;font-weight:bold;">six beta sheet (in yellow)</span> surrounded by <span style="color:pink;background-color:black;font-weight:bold;">alfa helix (in pink)</span> and <span style="color:purple;background-color:black;font-weight:bold;">310 helix (in purple)</span> connected by loops. Within the RhoA protein, distinct regions can be identified, each with specific functions:
-<scene name='97/973102/Bound_site/1'>GTPase Domain</scene>: This domain is responsible for binding and hydrolyzing <scene name='97/973102/Gtp/3'>GTP</scene>.
+<scene name='97/973102/Bound_site/3'>GTPase Domain</scene>: This domain is responsible for binding and hydrolyzing <scene name='97/973102/Gtp/3'>GTP</scene>. Multiple parts of the protein are involved in the activity of this region <scene name='97/973102/Bound_site_detailed/2'>(see with more details)</scene>,<span style="color:chartreuse;background-color:black;font-weight:bold;">Mg ion</span> is also an important element, without which the affinity decreases more than 500-fold <ref>PMID: 10748207</ref>.
-Rho Insert: This is a unique sequence insertion found within the GTPase domain of RhoA. It plays a role in the regulation and interaction of RhoA with other proteins.
+<scene name='97/973102/Insertion_region/2'>Rho Insert</scene>: This is a unique sequence insertion found within the GTPase domain of RhoA. It plays a role in the regulation and interaction of RhoA with other proteins.
-Switch I and Switch II: These are two regions within the GTPase domain that undergo conformational changes upon GTP binding. In the following green links <span style="color:navy;background-color:white;font-weight:bold;">Switch I (in dark blue)</span> and <span style="color:blue;background-color:white;font-weight:bold;">Switch II (in blue)</span> can be seen in <scene name='97/973102/Switch1_and_2_gtp/1'>RhoA-GTP</scene> or <scene name='97/973102/Switch1_and_2_gdp/1'>RhoA-GDP</scene> (. Their conformations dictate the ability of RhoA to interact with downstream effector proteins.
+Switch I and Switch II: These are two regions within the GTPase domain that undergo conformational changes upon GTP binding. In the following green links <span style="color:navy;background-color:white;font-weight:bold;">Switch I (in dark blue)</span> and <span style="color:blue;background-color:white;font-weight:bold;">Switch II (in blue)</span> can be seen in <scene name='97/973102/Switch1_and_2_gtp/1'>RhoA-GTP</scene> or <scene name='97/973102/Switch1_and_2_gdp/1'>RhoA-GDP</scene>. Their conformations dictate the ability of RhoA to interact with downstream effector proteins.
-Insertion/Deletion Sites: RhoA contains four insertion or deletion sites that contribute to the overall structure of the protein. These sites are characteristic of many GTPases in the Rho family and may play a role in protein-protein interactions.
+Insertion Domain: This region contributes to the overall structure of the protein being characteristic of many GTPases in the Rho family and could play a role in protein-protein interactions.
 C-terminal Prenylation Site: The C-terminal region of RhoA undergoes prenylation, a post-translational modification where a prenyl lipid group (such as farnesyl or geranylgeranyl) is attached. Prenylation allows RhoA to anchor to cell membranes, facilitating its localization and interaction with membrane-associated proteins.
@@ Line 44: / Line 44: @@
 == Post-Translational Modifications ==
-'''Prenylation:''' the activation of [[Rho GTPase]] require membrane binding, which is necessary for the interaction with membranous GEFs. The membrane association requires C-terminal prenylation, which involves the addition of a geranylgeranyl (20-carbon chain) to Cys190 in the CAAX motif.
+'''Prenylation:''' the activation of [[Rho GTPase]] requires membrane binding, which is necessary for the interaction with membranous GEFs. The membrane association requires C-terminal prenylation, which involves the addition of a geranylgeranyl (20-carbon chain) to Cys190 in the CAAX motif.
 '''Phosphorylation:''' can alter the subcellular localization of RhoA when occurs close to C-terminal lipid modifications. On the other hand, phosphorylation of the G-domain affects GTP/GDP cycling and the interaction with effector proteins.

User:Matheus Andrade Bettiol/Sandbox 1

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Revision as of 02:36, 26 June 2023

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References

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