Structural Biology and Evolution of the TGF-β Family

Hinck, Andrew P.; Mueller, Thomas D.; Springer, Timothy A.

doi:10.1101/cshperspect.a022103

Cited by 285 publications

(369 citation statements)

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“…The GDF6 (BMP13) structure has not yet been reported, but since GDF6 is a paralogue of GDF5 and BMP7 (i.e., have virtually identical tertiary structures) [Hinck et al, 2016] with high sequence identity in the C-terminal TGFβ domain, structural data of the BMP7-NOG complex ( Fig. 3 a, PDB ID:1M4U) and the GDF5-BMPR1B complex ( Fig.…”

Section: Methods and Resultsmentioning

confidence: 99%

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

Berentsen¹,

Haukanes²,

Júlíusson³

et al. 2018

Mol Syndromol

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A 4-generation family with multiple synostoses syndrome type 4 (SYNS4) is reported, the third family identified so far. The phenotype segregated with a previously undescribed Asn399Lys (c.1197C>A) substitution in GDF6. N399 is part of a hydrophobic pocket critical for binding the BMP/GDF antagonist noggin. The N399K substitution renders GDF6 more similar to noggin-resistant members of the BMP family, namely GDF2 and BMP10, both of which contain lysine in the corresponding position. To further define the SYNS4 phenotype, we examined 6 of 9 affected family members. The phenotype was carpal and tarsal synostoses with painful feet after walking, but the condition could also be asymptomatic. Interestingly, unlike the previous SYNS4 families, the family presented here has no history of hearing loss, and a 73-year-old mutation carrier had normal audiometry for his age. Based on structure modelling, BMPR2 binding should not be affected by the GDF6-N399K substitution, unlike the S429R and Y444N mutations found in the 2 other families. Hypothetically, this difference may be related to lack of hearing loss.

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Section: Methods and Resultsmentioning

confidence: 99%

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

Berentsen¹,

Haukanes²,

Júlíusson³

et al. 2018

Mol Syndromol

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“…Their overall structures are similar and consist of two cystine-knotted monomers tethered together by a single inter-chain disulfide bond (1). They coordinate wound healing, modulate immune cell function, maintain the extracellular matrix, and regulate epithelial and endothelial cell growth and differentiation (2).…”

mentioning

confidence: 99%

“…This approach offers several potential advantages over existing therapies. Relative to kinase inhibitors, engineered GFs would be expected to have much higher specificity, especially if they function by binding and blocking T␤RII, which is known to only bind and transduce signals for TGF-␤1, -␤2, and -␤3, but not other TGF-␤ family GFs (1,30). Another potential advantage over kinase inhibitors is increased bioavailability because, unlike the kinase inhibitors, engineered GFs would not have to cross the plasma membrane to reach their target.…”

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confidence: 99%

An engineered transforming growth factor β (TGF-β) monomer that functions as a dominant negative to block TGF-β signaling

Kim¹,

Barron²,

Hinck

et al. 2017

Journal of Biological Chemistry

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Edited by Norma AllewellThe transforming growth factor ␤ isoforms, TGF-␤1, -␤2, and -␤3, are small secreted homodimeric signaling proteins with essential roles in regulating the adaptive immune system and maintaining the extracellular matrix. However, dysregulation of the TGF-␤ pathway is responsible for promoting the progression of several human diseases, including cancer and fibrosis. Despite the known importance of TGF-␤s in promoting disease progression, no inhibitors have been approved for use in humans. Herein, we describe an engineered TGF-␤ monomer, lacking the heel helix, a structural motif essential for binding the TGF-␤ type I receptor (T␤RI) but dispensable for binding the other receptor required for TGF-␤ signaling, the TGF-␤ type II receptor (T␤RII), as an alternative therapeutic modality for blocking TGF-␤ signaling in humans. As shown through binding studies and crystallography, the engineered monomer retained the same overall structure of native TGF-␤ monomers and bound T␤RII in an identical manner. Cell-based luciferase assays showed that the engineered monomer functioned as a dominant negative to inhibit TGF-␤ signaling with a K i of 20 -70 nM. Investigation of the mechanism showed that the high affinity of the engineered monomer for T␤RII, coupled with its reduced ability to non-covalently dimerize and its inability to bind and recruit T␤RI, enabled it to bind endogenous T␤RII but prevented it from binding and recruiting T␤RI to form a signaling complex. Such engineered monomers provide a new avenue to probe and manipulate TGF-␤ signaling and may inform similar modifications of other TGF-␤ family members.The transforming growth factor ␤ isoforms, TGF-␤1, -␤2, and -␤3, are small secreted signaling proteins. Their overall structures are similar and consist of two cystine-knotted monomers tethered together by a single inter-chain disulfide bond (1). They coordinate wound healing, modulate immune cell function, maintain the extracellular matrix, and regulate epithelial and endothelial cell growth and differentiation (2). The TGF-␤s are synthesized as pre-pro-proteins, and after maturation, secretion, and release from their pro-domains (3), the mature homodimeric growth factors (GFs) 3 bind and bring together two single-pass transmembrane receptors, known as T␤RI and T␤RII, to form the signaling-competent T␤RI 2 -T␤RII 2 heterotetramer (4, 5). TGF-␤ GFs assemble T␤RI 2 -T␤RII 2 heterotetramer in a sequential manner, first by binding T␤RII followed by recruitment of T␤RI (6, 7). The stepwise assembly of T␤RII and T␤RI into a heterotetramer is driven by binding of T␤RI to a composite TGF-␤/T␤RII interface (Fig. 1A) (8, 9).The disruption or dysregulation of the TGF-␤ pathway is responsible for several human diseases. These include connec-

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“…However, integrin binding alone is not sufficient for latent TGF-β activation by α V β 6 ; force is also required. Experiments suggest that tensile force is transmitted from the cytoskeleton to the integrin, is resisted by anchorage of TGF-β1 in the extracellular matrix or on cell surfaces, and results in distortion of prodomain straitjacket elements that loosely surround the growth factor followed by release of the growth factor (7,8). In some systems, activation of TGF-β1 by α V β 8 is dependent on matrix metalloprotease (9) whereas in others activation requires linkage of pro-TGF-β1 to a surface, suggesting a role for force exertion (10).…”

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confidence: 99%

Atypical interactions of integrin α _V β ₈ with pro-TGF-β1

Wang

Dong

Zhao

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Integrins α V β 6 and α V β 8 are specialized for recognizing pro-TGF-β and activating its growth factor by releasing it from the latency imposed by its surrounding prodomain. The integrin α V β 8 is atypical among integrins in lacking sites in its cytoplasmic domain for binding to actin cytoskeleton adaptors. Here, we examine α V β 8 for atypical binding to pro-TGF-β1. In contrast to α V β 6 , α V β 8 has a constitutive extended-closed conformation, and binding to pro-TGF-β1 does not stabilize the open conformation of its headpiece. Although Mn 2+ potently activates other integrins and increases affinity of α V β 6 for pro-TGF-β1 25-to 55-fold, it increases α V β 8 affinity only 2-to 3-fold. This minimal effect correlates with the inability of Mn 2+ and pro-TGF-β1 to stabilize the open conformation of the α V β 8 headpiece. Moreover, α V β 8 was inhibited by high concentrations of Mn 2+ and was stimulated and inhibited at markedly different Ca 2+ concentrations than α V β 6 . These unusual characteristics are likely to be important in the still incompletely understood physiologic mechanisms that regulate α V β 8 binding to and activation of pro-TGF-β.integrins | allostery | pro-TGF-β1 I ntegrins are cell-surface adhesion molecules that mediate cellcell, cell-extracellular matrix, and cell-pathogen interactions. In mammals, 24 different integrins are formed by specific, noncovalent association of 18 α-subunits with 8 β-subunits (1-5). Almost all integrins link to the actin cytoskeleton through talin and kindlin-binding motifs in their β-subunit cytoplasmic domains and thus provide traction for cell migration. The only exceptions are integrin α V β 8 , which binds through its β 8 -subunit to differentially express in adenocarcinoma of the lung (DAL-1, also known as Band 4.1B), and integrin α 6 β 4 , which links through its β 4 -subunit to intermediate filaments (6).Here, we focus on the atypical integrin α V β 8 and compare it to integrin α V β 6 . Integrins α V β 6 and α V β 8 are specialized for binding to and activation of pro-TGF-β1 and -β3. The pro-TGF-βs are biosynthesized and stored in tissues as latent forms. The dimeric TGF-β growth factor is kept latent by noncovalent association with its dimeric prodomain, which in turn is linked noncovalently and through disulfide bonds to a "milieu molecule" that stores the latent complex in the extracellular matrix or on the cell surface for subsequent, integrin-dependent activation. Integrins bind to an RGD motif that is present in the prodomains of pro-TGF-β1 and -β3. However, integrin binding alone is not sufficient for latent TGF-β activation by α V β 6 ; force is also required. Experiments suggest that tensile force is transmitted from the cytoskeleton to the integrin, is resisted by anchorage of TGF-β1 in the extracellular matrix or on cell surfaces, and results in distortion of prodomain straitjacket elements that loosely surround the growth factor followed by release of the growth factor (7,8). In some systems, activation of TGF-β1 by α V β 8 is dependent on...

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Structural Biology and Evolution of the TGF-β Family

Cited by 285 publications

References 243 publications

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

An engineered transforming growth factor β (TGF-β) monomer that functions as a dominant negative to block TGF-β signaling

Atypical interactions of integrin α _V β ₈ with pro-TGF-β1

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Structural Biology and Evolution of the TGF-β Family

Cited by 285 publications

References 243 publications

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

A Novel GDF6 Mutation in a Family with Multiple Synostoses Syndrome without Hearing Loss

An engineered transforming growth factor β (TGF-β) monomer that functions as a dominant negative to block TGF-β signaling

Atypical interactions of integrin α V β 8 with pro-TGF-β1

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Atypical interactions of integrin α _V β ₈ with pro-TGF-β1