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Protein structure of WWTR1 as predicted by AlphaFold.[1]

WW domain-containing transcription regulator protein 1 (WWTR1), also known as Transcriptional coactivator with PDZ-binding motif (TAZ), is a protein that in humans is encoded by the WWTR1 gene. WWTR1 acts as a transcriptional coregulator and has no effect on transcription alone. When in complex with transcription factor binding partners, WWTR1 helps promote gene expression in pathways associated with development, cell growth and survival, and inhibiting apoptosis.[2] Aberrant WWTR1 function has been implicated for its role in driving cancers.[3][4][5] WWTR1 is often referred to as TAZ due to its initial characterization with the name TAZ. However, WWTR1 (TAZ) is not to be confused with the protein tafazzin, which originally held the official gene symbol TAZ, and is now TAFAZZIN.

Structure

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Differences in binding domains present on transcriptional coregulators, YAP and TAZ.[6]

WWTR1 contains a proline rich region, TEAD binding motif, WW domain, coiled coil region, and a transactivation domain (TAD) containing the PDZ domain-binding motif. WWTR1 (TAZ) lacks a DNA binding domain so it can not directly drive transcription. WWTR1 exhibits conserved structural homology with another transcriptional coregulator, yes-associated protein 1 (YAP).[2] Both YAP and TAZ are able to form homodimers and heterodimers with each other through interactions at the coil-coil domain.[7] YAP and TAZ cooperate with transcription factors to promote tissue formation. WWTR1 (TAZ) interacts with a variety of transcriptional partners, including the four TEA domain family members (TEAD1/2/3/4) through the TEAD-binding motif and several other factors containing the PPXY motif, which consists of a Proline-Proline-X (any amino acid)-Tyrosine sequence. Examples of such partners include Runx/PEBP2, AP2, C/EBP, c-Jun, Krox-20, Krox-24, MEF2B, NF-E2, Oct-4 and p73, which interact with WWTR1 via the WW domain.[2] The transactivation domain at the C-terminal end (amino acids 165–395) was shown to be important in producing transcriptional effects.[2]

Function

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WWTR1 (TAZ) and the structurally similar protein, YAP, act as transcriptional coactivators and are regulated by Hippo pathway activation.

WWTR1 (TAZ) plays an important role in embryogenesis and development,[8][9] which include regulation of organ size,[10][11][12] stem cell renewal,[13] tissue regeneration,[14][13] osteogenesis,[15] and angiogenesis.[16] These functions are effected through coactivation of transcription factors that promote cell growth, migration, and differentiation,[10][11][12] such as the four members of the TEAD transcription factor family, Paired box gene 3 (PAX3), and Runt related transcription factors (RUNX1/2).[6] The proliferative functions of WWTR1 (TAZ) and its paralog, YAP, are restricted by the Hippo signaling pathway.[17][18][19] This suppressive pathway consists of a kinase signaling cascade, the core of which is made up of the serine-threonine kinases, STK3/MST2 and STK4/MST1, which when active and complexed with the regulatory protein, SAV1, will phosphorylate and activate the LATS1/2 kinases, which in complex with the regulatory protein, MOB1, phosphorylate and downstream inactivate YAP/TAZ.[9][10][20] In this way, Hippo activation arrests cell growth by decreasing proliferative gene expression, leading to decreased cell death by ferroptosis[21][22] and increased cell death by apoptosis.[9][10]

Functional Redundancy with YAP

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Similarities

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WWTR1 (TAZ) has a similar structural sequence and binding motifs to yes-associated protein 1 (YAP).[6] YAP and TAZ are often considered functionally redundant in existing literature.[6] Both play roles in organ size development as well as cell migration, wound healing, angiogenesis, and metabolism, particularly in lipogenesis.[6][23] Inactivation of YAP and TAZ occurs through phosphorylation by kinases in the Hippo pathway, namely LATS1 and LATS2.[6] This recruits the binding of the regulatory protein, 14-3-3, which prevents YAP/TAZ from localizing to the nucleus and marks it for ubiquitination, which allows it to be recognized for subsequent degradation by proteasomes.[6]

Differences[7]

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TAZ is able to form both heterodimers and heterotetramers with TEADs to initiate transcription (TAZ-TEAD and TAZ-TEAD-TAZ-TEAD), while YAP is only able to form YAP-TEAD heterodimers.[6] These differences impart unique functions to TAZ, such as in the regulation of adipocyte differentiation through interactions with the peroxisome proliferator-activated receptor (PPARγ), as well as osteogenesis through transcriptional coactivation of bone-specific transcription factors, such as RUNX2 (also known as Cbfa1.)[6] Additionally, TAZ independently interacts with Nuclear factor of activated T-cells 5 (NFATC5) in order to repress transcription in renal cells that are undergoing osmotic stress.[6] Both YAP and TAZ associate with Mothers against decapentaplegic family transcription factors (SMAD) complexes to promote TGF-beta signaling and drive differentiation and development, but upregulation of only TAZ occurs upon transduction of this cascade.[6] TAZ is only able to complex with SMAD2, SMAD3, or SMAD4 to promote nuclear shuttling and transcription, but YAP can also interact with SMAD1 and SMAD7 in addition.[6] In vivo murine studies have demonstrated that animals lacking functional TAZ are more viable than animals lacking YAP expression.[6] In contrast, silencing of YAP contributed to a more dramatic effect on cell expansion, glucose uptake, and cell cycle arrest than TAZ.[6] When assayed in non-small-cell lung cancer (NSCLC) cell lines, WWTR1 maintained the extracellular matrix (ECM) organization and adhesion, and controlled migration more than YAP, which more closely regulated cell division and cell cycle progression genes.[6]

WWTR1 Protein Interactions

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Binding of WWTR1 (TAZ) to transcription factors, such as TEAD, activates proliferative transcription.[3][20]
WWTR1 (TAZ) function is inhibited when in complex with 14-3-3 binding protein.[3][20]
Protein Interaction Partner Functional Effects
AMOT, Angiomotin Binding sequesters YAP/TAZ in the cytoplasm, inhibiting their function[7]
AP-1, Activator protein 1 Promoting trancsription[6]
ASPP2, Apoptosis-stimulating protein of p53 Promotes dephosphorylation and stabilization of WWTR1 (TAZ)[7]
β-catenin Recruits a destruction complex that inactivates YAP/TAZ[7]
LATS1/LATS2, Large tumor suppressor kinases Phosphorylation of WWTR1, marking it for ubiquination[6]
NFATC5, Nuclear factor of activated T-cells 5 Represses transcription in renal cells undergoing osmotic stress[6]
PF, Parafibromin Stimulates WWTR1 (TAZ) function[7]
PAX3, Paired box gene 3 Promoting transcription[6]
PAX8 (Paired box gene 8) and NKX2-4 (NK homeobox)[20] Coactivation of transcription factors involved in thyroid regulation[20]
PRRG4, Proline Rich And Gla Domain 4[20] Suppressing transcription[6]
RUNX1/2, Runt related transcription factors Promotes transcription[6]
SMAD2/3/4, Mothers against decapentaplegic family transcription factors Nuclear shuttling; promoting transcription[6]
STAT1, Signal transducer and activator of transcription Inhibiting STAT1/2 dimerization in metabolism[6]
TEAD1, TEA domain family member[20] Transcriptional activation[6]
TEAD2, TEA domain family member, [20]
TEAD3, TEA domain family member, [20]
TEAD4, TEA domain family member[20]
YAP1, Yes-associated protein 1 Dimerization dependent transcriptional regulation[6]
YWHAE (14-3-3), Tyrosine 3-Monooxygenase/Tryptophan 5-Monooxygenase Activation Protein Epsilon[20] Restricts WWTR1 translocation to the nucleus[6]
ZO-2, Tight junction protein 2 Localizes YAP/TAZ to the nucleus for increased activity[7]

Clinical Significance

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Roles in Diseases

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WWTR1 has been implicated in many inflammatory diseases, including cancers.

Disease Clinical Significance of WWTR1
Cancer Associated with metastasis and poor survival prognosis across many cancer types[5]
Steatohepatitis Overexpression of WWTR1 progresses simple steatosis to steatohepatitis by promoting fibrosis[24]
Atherosclerosis Drives excessive endothelial cell proliferation and inflammation[25]
Sjogren Syndrome Decreased WWTR1 localization to the nucleus results in lack of functional salivary/lacrimal gland development[9]
Hypertension Activation of YAP/TAZ promotes glutamine metabolism and increases pulmonary blood pressure[26]
Psoriasis YAP/TAZ activation drive pathologic angiogenesis and inflammation associated with chronic skin disorders[27]
Atopic Dermatitis
Rosacea
Chronic Urticaria

Cancers

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WWTR1 (TAZ) is implicated a wide variety of cancers including melanoma, head and neck squamous cell carcinoma, breast cancer, non-small cell lung cancer, and others due to its high gene and histological expression, as well as correlation with increased metastasis and poorer survival in animal studies and patient data.[5] Along with the structurally similar co-regulator YAP, many studies have described their role in promoting oncogenesis, altering neoplastic metabolism, and generating resistance to therapeutic intervention.[4][5][28][29] In particular, TAZ overexpression conferred resistance to cisplatin chemotherapy as well as immunotherapy treatment with a PD-1 antibody.[28]

Medium intensity WWTR1 protein expression in melanoma samples from Protein Atlas.
WWTR1 protein is expressed in moderate to high levels across a diverse array of cancer types and is associated with poor clinical outcomes.
WWTR1 protein is expressed in moderate to high levels across a diverse array of cancer types and is associated with poor clinical outcomes.
WWTR1 Protein Expression By Cancer Type (from Protein Atlas)
Cancer Type # Samples with Medium/High Expression Total # Patient Samples % Patient Samples with Medium/High Expression
Glioma 11 11 100%
Thyroid 4 4 100%
Lung 12 12 100%
Colorectal 11 11 100%
Head and Neck 4 4 100%
Liver 12 12 100%
Carcinoid 4 4 100%
Pancreatic 9 9 100%
Urothelial 9 9 100%
Prostate 10 10 100%
Testis 11 11 100%
Breast 12 12 100%
Cervical 9 9 100%
Endometrial 10 10 100%
Ovarian 11 11 100%
Melanoma 12 12 100%
Skin 11 11 100%
Stomach 10 11 90.1%
Renal 10 11 90.1%
Lymphoma 9 12 75%

Associated Therapeutics

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YAP and TAZ function have been targeted in several therapeutic methods in the treatment of cancers.

The Hippo signaling agonist, C19, increases the phosphorylation of MST1/2 and LATS1/2, resulting in more downstream inactivation of YAP/TAZ. Modulating extracellular matrix stiffness and tension using thiazovivin, cucurbitacin I, dasatinib, fluvastatin, and pazopanib, exhibited positive results in breast cancer cell lines by preventing YAP/WWTR1 translocation to the nucleus.[30] Endogenous hormonal factors that are synthesized for normal physiological functions such as epinephrine and glucagon have also been demonstrated to have similar inhibitory effects on YAP/TAZ function by promoting Hippo pathway activation.[30] The class of cholesterol inhibitors, statins, was shown to inhibit the Rho family of GTP-ases (Rho-GTPase), which are enzymes that signal for upstream inhibition of the Hippo pathway, and exhibited similar effects in attenuating growth of breast cancer and human lung adenocarcinoma cells.[30] Statins inhibit 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase (HMG-CoA reductase), which is the precursor to mevalonate in the mevalonate pathway that synthesizes the lipid building blocks that form cholesterols and the lipid chains responsible for anchoring Rho-GTPases to the cell membrane.[5] The Rho-GTPase, Ras Family Homolog A (RhoA), is activated by prenlylation (the posttranslational modification through addition of hydrophobic groups), and is responsible in part for modulating cytoskeletal elements that reduce Hippo pathway activity.[5] By targeting Rho kinases with thiazovivin, or lipid synthesis through the mevalonate pathway, with statins, RhoA is inhibited and increased Hippo kinase activity may limit proliferation driven by YAP/TAZ.[5][30] Tyrosine kinases signal in proliferative pathways, some which promote YAP/TAZ function, such as Src family kinases and includes the Yes tyrosine kinase, which is associated with YAP function. Targeting tyrosine kinases with inhibitors such as dasatinib and pazopanib has shown some effect in cancers.[5]

Inhibition of YAP/TAZ function by targeting their interactions with their transcriptional partners in the TEAD family has also been studied.[30][31] This includes the use of verteporfin, which was investigated in the treatment of skin cancers, particularly melanoma, although it was not taken beyond preclinical studies.[30]

Drug/Molecule Name Drug Class Mechanism of Action
C19 Hippo kinase agonist Increases phosphorylation by MST1/2 and LATS1/2 to inactivate YAP/TAZ and decrease cell proliferation[30]
Dihydrexidine Dopamine agonist Increases LATS1/2 activity; Decreases YAP/TAZ function and cell proliferation[30]
Epinephrine Hormonal factor Increases LATS1/2 activity; Decreases YAP/TAZ function and cell proliferation[30]
Glucagon Hormonal factor
Thiazovivin Rho kinase inhibitor Inhibits Rho-GTPase; Increases LATS1/2 activity; Decreases YAP/TAZ function and cell proliferation[5][30]
Cucurbitacin I JAK/STAT3 inhibitor
Dasatinib Tyrosine kinase inhibitor
Fluvastatin Statin
Pazopanib Tyrosine kinase inhibitor
Verteporfin TEAD inhibitor Inhibits the binding of YAP/TAZ to TEAD family transcription factors; Decreases proliferative transcription and cell proliferation[30]

References

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  1. ^ "AlphaFold Protein Structure Database". alphafold.ebi.ac.uk. Retrieved 2022-11-23.
  2. ^ a b c d Hong, Wanjin; Guan, Kun-Liang. "The YAP and TAZ transcription co-activators: key downstream effectors of the mammalian Hippo pathway". Seminars in Cell & Developmental Biology. 23 (7): 785–793. doi:10.1016/j.semcdb.2012.05.004. ISSN 1096-3634. PMC 3459069. PMID 22659496.
  3. ^ a b c Moroishi, Toshiro; Hansen, Carsten Gram; Guan, Kun-Liang. "The emerging roles of YAP and TAZ in cancer". Nature Reviews Cancer. 15 (2): 73–79. doi:10.1038/nrc3876. ISSN 1474-175X. PMC 4562315. PMID 25592648.{{cite journal}}: CS1 maint: PMC format (link)
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  14. ^ Driskill, Jordan H.; Pan, Duojia (2021-01-24). "The Hippo Pathway in Liver Homeostasis and Pathophysiology". Annual Review of Pathology. 16: 299–322. doi:10.1146/annurev-pathol-030420-105050. ISSN 1553-4014. PMC 8594752. PMID 33234023.
  15. ^ Kovar, Heinrich; Bierbaumer, Lisa; Radic-Sarikas, Branka (2020-04-15). "The YAP/TAZ Pathway in Osteogenesis and Bone Sarcoma Pathogenesis". Cells. 9 (4): 972. doi:10.3390/cells9040972. ISSN 2073-4409. PMC 7227004. PMID 32326412.{{cite journal}}: CS1 maint: unflagged free DOI (link)
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  18. ^ Ma, Shenghong; Meng, Zhipeng; Chen, Rui; Guan, Kun-Liang (2019-06-20). "The Hippo Pathway: Biology and Pathophysiology". Annual Review of Biochemistry. 88: 577–604. doi:10.1146/annurev-biochem-013118-111829. ISSN 1545-4509. PMID 30566373.
  19. ^ Meng, Zhipeng; Moroishi, Toshiro; Guan, Kun-Liang (2016-01-01). "Mechanisms of Hippo pathway regulation". Genes & Development. 30 (1): 1–17. doi:10.1101/gad.274027.115. ISSN 1549-5477. PMC 4701972. PMID 26728553.
  20. ^ a b c d e f g h i j k "UniProt - Q9GZV5 · WWTR1_HUMAN". www.uniprot.org. Retrieved 2022-11-17.
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  22. ^ Dai, Chongshan; Chen, Xin; Li, Jingbo; Comish, Paul; Kang, Rui; Tang, Daolin. "Transcription factors in ferroptotic cell death". Cancer Gene Therapy. 27 (9): 645–656. doi:10.1038/s41417-020-0170-2. ISSN 1476-5500. PMID 32123318.
  23. ^ Koo, Ja Hyun; Guan, Kun-Liang (2018-08-07). "Interplay between YAP/TAZ and Metabolism". Cell Metabolism. 28 (2): 196–206. doi:10.1016/j.cmet.2018.07.010. ISSN 1550-4131. PMID 30089241.
  24. ^ Kuchay, Mohammad Shafi; Choudhary, Narendra Singh; Mishra, Sunil Kumar (2020-11-01). "Pathophysiological mechanisms underlying MAFLD". Diabetes & Metabolic Syndrome: Clinical Research & Reviews. 14 (6): 1875–1887. doi:10.1016/j.dsx.2020.09.026. ISSN 1871-4021.
  25. ^ Niu, Niu; Xu, Suowen; Xu, Yanni; Little, Peter J.; Jin, Zheng-Gen (2019-04-01). "Targeting Mechanosensitive Transcription Factors in Atherosclerosis". Trends in Pharmacological Sciences. 40 (4): 253–266. doi:10.1016/j.tips.2019.02.004. ISSN 0165-6147. PMC 6433497. PMID 30826122.{{cite journal}}: CS1 maint: PMC format (link)
  26. ^ Zhang, Xiaodong; Zhao, Haiying; Li, Yan; Xia, Di; Yang, Liang; Ma, Yingbo; Li, Hangyu (2018-09-03). "The role of YAP/TAZ activity in cancer metabolic reprogramming". Molecular Cancer. 17 (1): 134. doi:10.1186/s12943-018-0882-1. ISSN 1476-4598. PMC 6122186. PMID 30176928.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
  27. ^ Lee, Hyun Ji; Hong, Yong Jun; Kim, Miri. "Angiogenesis in Chronic Inflammatory Skin Disorders". International Journal of Molecular Sciences. 22 (21): 12035. doi:10.3390/ijms222112035. ISSN 1422-0067. PMC 8584589. PMID 34769465.{{cite journal}}: CS1 maint: PMC format (link) CS1 maint: unflagged free DOI (link)
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  29. ^ Zanconato, Francesca; Cordenonsi, Michelangelo; Piccolo, Stefano. "YAP and TAZ: a signalling hub of the tumour microenvironment". Nature Reviews. Cancer. 19 (8): 454–464. doi:10.1038/s41568-019-0168-y. ISSN 1474-1768. PMID 31270418.
  30. ^ a b c d e f g h i j k Andl, Thomas; Zhou, Linli; Yang, Kun; Kadekaro, Ana Luisa; Zhang, Yuhang (2017-06-28). "YAP and WWTR1: New targets for skin cancer treatment". Cancer Letters. 396: 30–41. doi:10.1016/j.canlet.2017.03.001. ISSN 0304-3835.
  31. ^ Pobbati, Ajaybabu V.; Hong, Wanjin (2020). "A combat with the YAP/TAZ-TEAD oncoproteins for cancer therapy". Theranostics. 10 (8): 3622–3635. doi:10.7150/thno.40889. ISSN 1838-7640. PMC 7069086. PMID 32206112.