From Proteopedia
(Difference between revisions)
proteopedia linkproteopedia link
|
|
| Line 1: |
Line 1: |
| - | <StructureSection load='2Z6G' size='350' side='right' caption='Crystal structure of full-lenght zebrafish beta-catenin' scene=''> | + | <StructureSection load='2Z6G' size='350' frame='true' side='right' caption='Crystal structure of full-lenght zebrafish beta-catenin' scene=''> |
| | | | |
| | '''ß-catenin''' is an intracellular adaptor protein, which can be a part of many protein complexes that respond to different biological signals. Depending on its interacting partners, ß-catenin elicits specific cellular response. This response serves to maintain the tissue homeostasis. Thus, it is not surprising that mutations affecting the structure and function of ß-catenin can lead to tumor transformation [1], defects in embryogenesis [2] and regeneration [3]. | | '''ß-catenin''' is an intracellular adaptor protein, which can be a part of many protein complexes that respond to different biological signals. Depending on its interacting partners, ß-catenin elicits specific cellular response. This response serves to maintain the tissue homeostasis. Thus, it is not surprising that mutations affecting the structure and function of ß-catenin can lead to tumor transformation [1], defects in embryogenesis [2] and regeneration [3]. |
Revision as of 17:05, 26 April 2022
|
ß-catenin is an intracellular adaptor protein, which can be a part of many protein complexes that respond to different biological signals. Depending on its interacting partners, ß-catenin elicits specific cellular response. This response serves to maintain the tissue homeostasis. Thus, it is not surprising that mutations affecting the structure and function of ß-catenin can lead to tumor transformation [1], defects in embryogenesis [2] and regeneration [3].
Structure
Human ß-catenin is a product of CTNNB1 gene and contains 781 amino acids. The main part of this protein displays α-helical conformation and includes 12 armadillo repetitions. Therefore, ß-catenin is classified as armadillo family member. Each armadillo repetition contains 42 amino acids folded into 3 α-helices, that are connected with short unstructured loops. The α-helices of neighboring armadillo repetitions interact and thus participate in the formation of a compact right-handed superhelical conformation. The inner region of ß-catenin protein that adopts this conformation and includes all 12 armadillo repetition is called ß59 (according to its molecular weight in kDa).
Similar organization can be found also in other armadillo proteins, that use it as an interacting domain. The ß59 region has hydrophobic amino acids distributed at its core, whereas positively charged amino acids residues are exposed on its surface [4]. In this way, armadillo protein ß-catenin can interact with proteins of Cadherin-Catenin complex, Wnt signaling pathway [5], or with members of the transcription factor family [6].
Function
ß-catenin becomes a member of mechanosensory complex forming adherent junction between cells by interaction with transmembrane protein Cadherin. In this complex, ß-catenin serves as one of the mechanosensors, that transmit the traction force generated extracellularly into the cell. Thanks to that, cells are anchored to each other by their proteins and Actin cytoskeleton and can receive or transmit information about changes in surrounding tissue [7].
Interaction site for Cadherin on ß-catenin overlaps in part with interaction site for another protein – Fascin. Cadherin and Fascin compete each other for interaction with ß-catenin, where Cadherin interaction leads to adherent phenotype, whereas Fascin interaction results in motile cell. Another competitor of Fascin for attachment to ß-catenin is Adenomatous polyposis coli (APC) protein [8]. APC with Axin, Glycogen synthase kinase 3 (GSK3) and Casein kinase 1 (CK1) assemble a complex, that plays a role in Wnt signal pathway. This complex participates in destabilization of soluble cytoplasmic ß-catenin and prevent interaction between ß-catenin and transcription factors. For example, -catenin with Tcf/Lef acts as co-activator of transcription, so that all these proteins must be together transported to the nucleus where they help to initiate pro-proliferative genes expression [9]. About participation of ß-catenin in these complexes decides mainly its tyrosine and serine/threonine phosphorylation [10][11].
Mutations
Many naturally occurring mutations in the CTNNB1 gene have been associated with various pathologies such as pilomatrixoma [13], medulloblastoma [14], ovarian cancer [15] and neurodevelopmental disorder with spastic diplegia and visual defects (NEDSDV) [16].
However, defects in ß-catenin functions are mostly associated with the development of colorectal carcinoma [1]. Sequencing of CTNNB1 gene in 23 cancer cell lines from 21 patients with colorectal carcinoma revealed five mutant variants. Only one of these mutations has homozygous character [17].
Mutations discovered in cell lines SW48 and HCT116 target to positions 33 and 45 in exon 3 and affect the part of ß-catenin outside of armadillo repetitions. The mutation in SV48 cell line substitutes serine 33 by tyrosine. In HCT116 cell line, the deletion of three nucleotides eliminates serine in position 45. Both these changes in the primary structure of ß-catenin have negative effect on the binding site for GSK3 kinase (see Fig. 1), although in the case of serine 45 elimination in HCT116, the effect is only indirect. Enzyme GSK3 is processive serine/threonine kinase, that gradually phosphorylates several serine residues of ß-catenin. The priming phosphorylation of serine 45 by CK1 kinase is necessary for the interaction of GSK3 and ß-catenin [17].
The remaining three mutations interrupt the armadillo repetitions . In HCA46 cell line, the mutation hits that part of exon 5, which corresponds to the second armadillo repetition. New potential phosphorylation site here substitutes alanine by serine,. In Caco2 cell line, there is substitution of glycine to alanine, but this time in that part of exon 5, that corresponds to the third armadillo repetition. Both these mutations in both cell lines change the polarity and hydrophobicity in ß59 region, which in turn affects phosphorylation of ß-catenin and its interactions [17].
The last two cancer cell lines, Colo201 and Colo205, were derived from the same patient and represent the primary tumor and its metastases. In both cell lines, the same mutation in exon 6 in the fourth armadillo repetition was found. This mutation substitutes asparagine to serine, which affects the interactions of ß-catenin in complexes with APC and Cadherin [17].
Disease
Colorectal carcinoma is the third most common cancer worldwide and contributes substantially to the tumor-caused mortality. This type of cancer is the second most lethal cancer disease [18] and is specifically overrepresented in the developed parts of the world [19]. About 50% of patients with colorectal carcinoma develop metastases, which significantly diminishes the chance to survive [20].
In the case of colorectal cancer development, Wnt signal pathway is very important and represents the central point of carcinogenesis. As a result, activating mutations in this pathway are present in more than 80% of patients. Basically, Wnt pathway is activated, when an extracellular ligand (glycoprotein) binds to the receptor protein Frizzled, that is localized in the cytoplasmic membrane. Then, protein Frizzled can interact with its co-receptor LPR, which allows subsequent phosphorylation of cytoplasmic protein Dishevelled. When phosphorylated, this protein serves as an inhibitor of GSK3. Inactivation of GSK3 kinase prevents degradation of ß-catenin, that accumulates in cytoplasm and translocates to the nucleus, where it plays a role as transcription co-activator. Every step of this pathway is strictly regulated. After signal termination, cytoplasmic ß-catenin is degraded [21].
Protein APC is very important for this pathway and for the decreasing ß-catenin stability. Therefore, the majority of driver mutations initiating development of colorectal cancer are presented in the gene for this protein. Protein APC is classified as recessive tumor suppressor. When inactivated, it stabilizes ß-catenin, which in turn leads to overexpression of genes supporting cell proliferation and progression of cancer [20].
Under physiological conditions, ß-catenin is phosphorylated by GSK and CK1 kinases and becomes visible for SCF class of ubiquitin ligases. Ubiquitination indicates ß-catenin to degradation in proteasome. However, in some cancer cell lines, mutations that eliminate target amino acids residues for these two kinases were discovered. Thus, not only mutations in the gene for APC can lead to cancer transformation. Mutations of CTNNB1 gene are associated with very poor prognosis for patients with colorectal carcinoma [22].
Thanks to the knowledge of changes involved in oncogene activation and stabilization of ß-catenin, this protein seems to be a promising target for anticancer treatment [23].
Therapy
Therapy, that targets to Wnt-ß-catenin pathway is one of the options how to prevent interaction of ß-catenin with Tcf/Lef transcription factors. This can be achieved with active form of vitamin D – 1,25-dihydroxyvitamin D3. ß-catenin can bind to the receptor of this vitamin D3, which leads to a decrease of the unbound ß-catenin level with potential to interact with Tcf/Lef. Active vitamin D3 can also increase expression of E-cadherin gene and drives ß-catenin to the protein complexes of adherent junctions so that it cannot be translocated to the nucleus [21].
Another option is the utilization of molecules such as genistein, izoflavon a fytoestrogen, that stimulate GSK3 and E-cadherin expression and lead to a decreased level of ß-catenin in cytoplasm. Such therapy in combination with other chemotherapeutics could be an important treatment for patients in metastatic phase of colorectal cancer [21].
Some small molecules can also serve as therapeutics. For example, transcription co-activator antagonist PRI-724, that increases binding of ß-catenin to p300 protein and competes with binding of ß-catenin to CBP (CRE binding protein). This prioritizes cell differentiation over proliferation. Another antagonists are for example PNU74654, 2,4-diamino-quinazolin, PKF115-584 and CGP 049090, than can also decrease interactions of ß-catenin with Tcf/Lef. There are also some molecules, that can target to other members of Wnt pathway such as Dishevelled, CK1, or Axin [21].
Structural highlights
This is a sample scene created with SAT to by Group, and another to make of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.
|
References
[1] P. J. Morin et al., Activation of β-Catenin-Tcf Signaling in Colon Cancer by Mutations in β-Catenin or APC. en, Science 275, 1787–1790, issn: 0036-8075, 1095-9203 (břez. 1997).
[2] V. Korinek et al., Two Members of the Tcf Family Implicated in Wnt/β-Catenin Signaling during Embryogenesis in the Mouse. en, Molecular and Cellular Biology 18, 1248–1256, issn:0270-7306, 1098-5549 (břez. 1998).
[3] F. Osakada et al., Wnt Signaling Promotes Regeneration in the Retina of Adult Mammals. En, Journal of Neuroscience 27, 4210–4219, issn: 0270-6474, 1529-2401 (dub. 2007).
[4] A. H. Huber, W. J. Nelson, W. I. Weis, Three-Dimensional Structure of the Armadillo Repeat Region of β-Catenin. en, Cell 90, 871–882, issn: 0092-8674 (zář. 1997).
[5] J. Hülsken, W. Birchmeier, J. Behrens, E-Cadherin and APC Compete for the Interaction with Beta-Catenin and the Cytoskeleton. Journal of Cell Biology 127, 2061–2069, issn: 0021-9525 (pros. 1994).
[6] M. Molenaar et al., XTcf-3 Transcription Factor Mediates β-Catenin-Induced Axis Formation in Xenopus Embryos. en, Cell 86, 391–399, issn: 0092-8674 (srp. 1996).
[7] C. D. Buckley et al., Cell Adhesion. The Minimal Cadherin-Catenin Complex Binds to Actin Filaments under Force. eng, Science (New York, N.Y.) 346, 1254211, issn: 1095-9203 (říj. 2014).
[8] Y. S. Tao et al., Beta-Catenin Associates with the Actin-Bundling Protein Fascin in a Noncadherin Complex. Journal of Cell Biology 134, 1271–1281, issn: 0021-9525 (zář. 1996).
[9] Y. Zhang, W. Wang, Targeting the Wnt/β-Catenin Signaling Pathway in Cancer, Journal of Hematology & Oncology, issn: 1756-8722 (pros. 2020)
[10] S. Bek, R. Kemler, Protein Kinase CKII Regulates the Interaction of β-Catenin Withα -Catenin and Its Protein Stability. en, Journal of Cell Science 115, 4743–4753, issn: 0021-9533, 1477-9137 (pros. 2002).
[11] J. Piedra et al., P120 Catenin-Associated Fer and Fyn Tyrosine Kinases Regulate Beta-Catenin Tyr-142 Phosphorylation and Beta-Catenin-Alpha-Catenin Interaction. eng, Molecular and Cellular Biology 23, 2287–2297, issn: 0270-7306 (dub. 2003).
[12] S. Schneider, J. Finnerty, M. Martindale, Protein Evolution: Structure-Function Relationships of the Oncogene Beta-Catenin in the Evolution of Multicellular Animals. Journal of experimental zoology. Part B, Molecular and developmental evolution 295, 25–44 (ún. 2003).
[13] G. Moreno-Bueno, C. Gamallo, L. Pérez-Gallego, F. Contreras, J. Palacios, Beta-Catenin Expression in Pilomatrixomas. Relationship with Beta-Catenin Gene Mutations and Comparison with Beta-Catenin Expression in Normal Hair Follicles. eng, The British Journal of Dermatology 145, 576–581, issn: 0007-0963 (říj. 2001).
[14] S. Fattet et al., Beta-Catenin Status in Paediatric Medulloblastomas: Correlation of Immuno-histochemical Expression with Mutational Status, Genetic Profiles, and Clinical Characteristics.The Journal of Pathology 218, 86–94, issn: 1096-9896 (2009).
[15] S. Sagae et al., Mutational Analysis of Beta-Catenin Gene in Japanese Ovarian Carcinomas: Frequent Mutations in Endometrioid Carcinomas. eng, Japanese Journal of Cancer Research: Gann 90, 510–515, issn: 0910-5050 (květ. 1999).
[16] N. Li et al., Exome Sequencing Identifies a de Novo Mutation of CTNNB1 Gene in a Patient Mainly Presented with Retinal Detachment, Lens and Vitreous Opacities, Microcephaly, and Developmental Delay: Case Report and Literature Review. Medicine 96, e6914, issn: 1536-5964 (květ. 2017).
[17] M. Ilyas, I. P. Tomlinson, A. Rowan, M. Pignatelli, W. F. Bodmer, Beta-Catenin Mutations in Cell Lines Established from Human Colorectal Cancers. Proceedings of the National Academy of Sciences of the United States of America 94, 10330–10334, issn: 0027-8424 (zář. 1997).
[18] A. Malki et al., Molecular Mechanisms of Colon Cancer Progression and Metastasis: Recent Insights and Advancements. eng, International Journal of Molecular Sciences 22, E130, issn: 1422-0067 (pros. 2020).
[19] R. Labianca et al., Colon Cancer. en, Critical Reviews in Oncology/Hematology 74, 106–133, issn: 1040-8428 (květ. 2010).
[20] G. T. Chen et al., Disrupting SS-Catenin DependentWntt Signaling Activates an Invasive Gene Program Predictive of Colon Cancer Progressio. en, 667030 (čvc 2019).
[21] A. Sebio, M. Kahn, H.-J. Lenz, The Potential of Targeting Wnt/β-Catenin in Colon Cancer.eng, Expert Opinion on Therapeutic Targets 18, 611–615, issn: 1744-7631 (červ. 2014).
[22] M. I. Pronobis, N. M. Rusan, M. Peifer, A Novel GSK3-Regulated APC:Axin Interaction Regulates Wnt Signaling by Driving a Catalytic Cycle of Efficient Bcatenin Destruction. eLife 4,ed. H. McNeill, e08022, issn: 2050-084X (zář. 2015).
[23] A. Nadeem et al., Suppression of β-Catenin Signaling in Colon Carcinoma Cells by a Bacterial Protein. en, International Journal of Cancer 149, 442–459, issn: 1097-0215 (2021).
