Physical Basis behind Achondroplasia,the Most Common Form of Human Dwarfism

Fibroblast growth factor receptor 3 (FGFR3) is a receptor tyrosine kinase that plays an important role in long bone development. The G380R mutation in FGFR3 transmembrane domain is known as the genetic cause for achondroplasia, the most common form of human dwarfism. Despite many studies, there is no consensus about the exact mechanism underlying the pathology. To gain further understanding into the physical basis behind the disorder, here we measure the activation of wild-type and mutant FGFR3 in mammalian cells using Western blots, and we analyze the activation within the frame of a physical-chemical model describing dimerization, ligand binding, and phosphorylation probabilities within the dimers. The data analysis presented here suggests that the mutation does not increase FGFR3 dimerization, as proposed previously. Instead, FGFR3 activity in achondroplasia is increased due to increased probability for phosphorylation of the unliganded mutant dimers. This finding has implications for the design of targeted molecular treatments for achondroplasia.     

Multiple Consequences of a Single Amino Acid Pathogenic RTK Mutation: The A391E Mutation in FGFR3

The A391E mutation in fibroblast growth factor receptor 3 (FGFR3) is the genetic cause for Crouzon syndrome with Acanthosis Nigricans. Here we investigate the effect of this mutation on FGFR3 activation in HEK 293 T cells over a wide range of fibroblast growth factor 1 concentrations using a physical-chemical approach that deconvolutes the effects of the mutation on dimerization, ligand binding, and efficiency of phosphorylation. It is believed that the mutation increases FGFR3 dimerization, and our results verify this. However, our results also demonstrate that the increase in dimerization is not the sole effect of the mutation, as the mutation also facilitates the phosphorylation of critical tyrosines in the activation loop of FGFR3. The activation of mutant FGFR3 is substantially increased due to a combination of these two effects. The low expression of the mutant, however, attenuates its signaling and may explain the mild phenotype in Crouzon syndrome with Acanthosis Nigricans. The results presented here provide new knowledge about the physical basis behind growth disorders and highlight the fact that a single RTK mutation may affect multiple steps in RTK activation.     

FGFR3 dimer stabilization due to a single amino acid pathogenic mutation

Mutations in the transmembrane (TM) domains of receptor tyrosine kinases (RTKs) have been implicated in the induction of pathological phenotypes. These mutations are believed to stabilize the RTK dimers, and thus promote unregulated signaling. However, the energetics behind the pathology induction has not been determined. An example of a TM domain pathogenic mutation is the Ala391-->Glu mutation in fibroblast growth factor receptor 3 (FGFR3), linked to Crouzon syndrome with acanthosis nigricans, as well as to bladder cancer. Here, we determine the free energy of dimerization of wild-type and mutant FGFR3 TM domain in lipid bilayers using F?rster resonance energy transfer, and we show that hydrogen bonding between Glu391 and the adjacent helix in the dimer is a feasible mechanism for dimer stabilization. The measured change in the free energy of dimerization due to the Ala391-->Glu pathogenic mutation is -1.3 kcal/mol, consistent with previous reports of hydrogen bond strengths in proteins. This is the first quantitative measurement of mutant RTK stabilization in a membrane environment. We show that this seemingly modest value can lead to a large increase in dimer fraction and thus profoundly affect RTK-mediated signal transduction.     

The achondroplasia mutation does not alter the dimerization energetics of the fibroblast growth factor receptor 3 transmembrane domain

The Gly380 --> Arg mutation in the TM domain of fibroblast growth factor receptor 3 (FGFR3) of the RTK family is linked to achondroplasia, the most common form of human dwarfism. The molecular mechanism of pathology induction is under debate, and two different mechanisms have been proposed to contribute to pathogenesis: (1) Arg380-mediated FGFR3 dimer stabilization and (2) slow downregulation of the activated mutant receptors. Here we show that the Gly380 --> Arg mutation does not alter the dimerization energetics of the FGFR3 transmembrane domain in detergent micelles or in lipid bilayers. This result indicates that pathogenesis in achondroplasia cannot be explained simply by a higher dimerization propensity of the mutant FGFR3 TM domain, thus highlighting the importance of the observed slow downregulation in phenotype induction.     

The Pathogenic A391E Mutation in FGFR3 Induces a Structural Change in the Transmembrane Domain Dimer

Fibroblast growth factor receptor 3 (FGFR3) is a single-pass membrane protein and a member of the receptor tyrosine kinase family of proteins that is involved in the regulation of skeletal growth and development. FGFR3 has three distinct domains: the ligand binding extracellular domain, the cytosolic kinase domain and the transmembrane domain (TMD). Previous work with the isolated FGFR3 TMD has shown that it has the ability to dimerize. Clinical and genetic studies have also correlated mutations in the TMD with a variety of skeletal and cranial dysplasias and cancer. Although the structures of the extracellular and cytosolic domains of FGFR3 have been solved, the structure of the TMD dimer is still unknown. Furthermore, very little is known regarding the effects of pathogenic mutations on the TMD dimer structure. We, therefore, carried out ToxR activity assays to determine the role of the SmXXXSm motif in the dimerization of the FGFR3 TMD. This motif has been shown to drive the association of many transmembrane proteins. Our results indicate that the interaction between wild-type FGFR3 TMDs is not mediated by two adjacent SmXXXSm motifs. In contrast, studies using the TMD carrying the pathogenic A391E mutation suggest that the motifs play a role in the dimerization of the mutant TMD. Based on these observations, here we report a new mechanistic model in which the pathogenic A391E mutation induces a structural change that leads to the formation of a more stable dimer.     

Transient dimerization and interaction with ERGIC-53 occur in the fibroblast growth factor receptor 3 early secretory pathway

The fibroblast growth factor receptor 3 (FGFR3) secretory pathway includes N-linked glycosylation in the endoplasmic reticulum where a stringent quality control system ensures that only correctly folded receptor reaches the cell surface from where mature-functional FGFR3 signals upon ligand-mediated dimerization. We have previously shown that the increased kinase activity associated with FGFR3 bearing the thanatophoric dysplasia type II (TDII) mutation hampers its maturation, enabling the receptor to signal from the endoplasmic reticulum. Here we investigate if this biosynthetic disturbance could be explained by premature dimerization of the receptor. Our observations show that a limited fraction of the immature high-mannose, mutant receptor dimerizes in the early secretory pathway, as does the immature wild type FGFR3. In contrast, the mature fully glycosylated wild type receptor reaches the cell surface as monomer suggesting that dimerization is a transient event. The kinase activity of mutant FGFR3 is not required for dimerization to occur, although it increases dimerization efficiency. Furthermore, mutant FGFR3 trans-phosphorylates the immature wild type receptor indicating that dimerization occurs in the endoplasmic reticulum. Visualization of protein interaction inside the secretory pathway confirms receptor dimerization. In addition, it shows that both wild type and TDII FGFR3 interact with the mannose-specific lectin ERGIC-53. We conclude that transient dimerization is an obligatory step in FGFR3 biosynthesis acting as a pre-assembly quality control mechanism. Furthermore, the TDII/ERGIC-53 complex formation may function as a checkpoint for FGFR3 sorting downstream the endoplasmic reticulum. These findings have implications for understanding the pathogenesis of FGFR3-related disorders.     

Chimeras of the native form or achondroplasia mutant (G375C) of human fibroblast growth factor receptor 3 induce ligand-dependent differentiation of PC12 cells.

Mutations in the gene for human fibroblast growth factor receptor 3 (hFGFR3) cause a variety of skeletal dysplasias, including the most common genetic form of dwarfism, achondroplasia (ACH). Evidence indicates that these phenotypes are not due to simple haploinsufficiency of FGFR3 but are more likely related to a role in negatively regulating skeletal growth. The effects of one of these mutations on FGFR3 signaling were examined by constructing chimeric receptors composed of the extracellular domain of human platelet-derived growth factor receptor beta (hPDGFR beta) and the transmembrane and intracellular domains of hFGFR3 or of an ACH (G375C) mutant. Following stable transfection in PC12 cells, which lack platelet-derived growth factor (PDGF) receptors, all clonal cell lines, with either type of chimera, showed strong neurite outgrowth in the presence of PDGF but not in its absence. Antiphosphotyrosine immunoblots showed ligand-dependent autophosphorylation, and both receptor types stimulated strong phosphorylation of mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase, an event associated with the differentiative response of these cells. In addition, ligand-dependent phosphorylation of phospholipase Cgamma and Shc was also observed. All of these responses were comparable to those observed from ligand activation, such as by nerve growth factor, of the native PC12 cells used to prepare the stable transfectants. The cells with the chimera bearing the ACH mutation were more rapidly responsive to ligand with less sustained MAPK activation, indicative of a preactivated or primed condition and consistent with the view that these mutations weaken ligand control of FGFR3 function. However, the full effect of the mutation likely depends in part on structural features of the extracellular domain. Although FGFR3 has been suggested to act as a negative regulator of long-bone growth in chrondrocytes, it produces differentiative signals similar to those of FGFR1, to which only positive effects have been ascribed, in PC12 cells. Therefore, its regulatory effects on bone growth likely result from cellular contexts and not the induction of a unique FGFR3 signaling pathway.     

FGFR3 heterodimerization in achondroplasia, the most common form of human dwarfism

The G380R mutation in the transmembrane domain of fibroblast growth factor receptor 3 (FGFR3) causes achondroplasia, the most common form of human dwarfism. Achondroplasia is a heterozygous disorder, and thus the affected individuals express both wild-type and mutant FGFR3. Yet heterodimerization in achondroplasia has not been characterized thus far. To investigate the formation of FGFR3 heterodimers in cellular membranes, we designed an FGFR3 construct that lacks the kinase domain, and we monitored the formation of inactive heterodimers between this construct and wild-type and mutant FGFR3. The formation of the inactive heterodimers depleted the pool of full-length receptors capable of forming active homodimers and ultimately reduced their phosphorylation. By analyzing the effect of the truncated FGFR3 on full-length receptor phosphorylation, we demonstrated that FGFR3 WT/G380R heterodimers form with lower probability than wild-type FGFR3 homodimers at low ligand concentration. These results further our knowledge of FGFR3-associated bone disorders.     

Molecular basis for the treatment of achondroplasia

Achondroplasia (ACH), the most common form of short-limbed dwarfism, and its related disorders are caused by constitutively activated point-mutated fibroblast growth factor receptor 3 (FGFR3). Recent studies have provided a large body of evidence to prove chondrocyte proliferation and differentiation in these disorders. However, little is known about the possible effects of the FGFR3 mutants on apoptosis of chondrocytes. In the present study, we analyzed apoptosis using a chondrogenic cell line, ATDC5, expressing the FGFR3 mutants causing ACH and thanatophoric dysplasia, which is a more severe neonatal lethal form comprising type I and type II. We found that the introduction of these mutated FGFR3s into ATDC5 cells decreased mRNA expression of parathyroid hormone-related peptide (PTHrP) and induced apoptosis. Importantly, replacement of PTHrP prevented the apoptotic changes in ATDC5 cells expressing ACH mutant. Insulin-like growth factor (IGF)-I, which is an important mediator of growth hormone (GH), also reduced apoptosis in ATDC5 cells expressing ACH mutant. IGF-I prevented apoptosis through the phosphatidylinositol 3-kinase and mitogen-activated protein kinase pathways, indicating the mechanisms by which GH treatment improves disturbed bone growth in ACH.     

Studies of Receptor Tyrosine Kinase Transmembrane Domain Interactions: The EmEx-FRET Method

The energetics of transmembrane (TM) helix dimerization in membranes and the thermodynamic principles behind receptor tyrosine kinase (RTK) TM domain interactions during signal transduction can be studied using Förster resonance energy transfer (FRET). For instance, FRET studies have yielded the stabilities of wild-type fibroblast growth factor receptor 3 (FGFR3) TM domains and two FGFR3 pathogenic mutants, Ala391Glu and Gly380Arg, in the native bilayer environment. To further our understanding of the molecular mechanisms of deregulated FGFR3 signaling underlying different pathologies, we determined the effect of the Gly382Asp FGFR3 mutation, identified in a multiple myeloma cell line, on the energetics of FGFR3 TM domain dimerization. We measured dimerization energetics using a novel FRET acquisition and processing method, termed “emission-excitation FRET (EmEx-FRET),” which improves the precision of thermodynamic measurements of TM helix association. The EmEx-FRET method, verified here by analyzing previously published data for wild-type FGFR3 TM domain, should have broad utility in studies of protein interactions, particularly in cases when the concentrations of fluorophore-tagged molecules cannot be controlled.     

Effect of the G375C and G346E achondroplasia mutations on FGFR3 activation

Two mutations in FGFR3, G380R and G375C are known to cause achondroplasia, the most common form of human dwarfism. The G380R mutation accounts for 98% of the achondroplasia cases, and thus has been studied extensively. Here we study the effect of the G375C mutation on the phosphorylation and the cross-linking propensity of full-length FGFR3 in HEK 293 cells, and we compare the results to previously published results for the G380R mutant. We observe identical behavior of the two achondroplasia mutants in these experiments, a finding which supports a direct link between the severity of dwarfism phenotypes and the level and mechanism of FGFR3 over-activation. The mutations do not increase the cross-linking propensity of FGFR3, contrary to previous expectations that the achondroplasia mutations stabilize the FGFR3 dimers. Instead, the phosphorylation efficiency within un-liganded FGFR3 dimers is increased, and this increase is likely the underlying cause for pathogenesis in achondroplasia. We further investigate the G346E mutation, which has been reported to cause achondroplasia in one case. We find that this mutation does not increase FGFR3 phosphorylation and decreases FGFR3 cross-linking propensity, a finding which raises questions whether this mutation is indeed a genetic cause for human dwarfism.     

Constitutive activation of fibroblast growth factor receptor 3 by the transmembrane domain point mutation found in achondroplasia.

Achondroplasia, the most common genetic form of dwarfism, is an autosomal dominant disorder whose underlying mechanism is a defect in the maturation of the cartilage growth plate of long bones. Achondroplasia has recently been shown to result from a Gly to Arg substitution in the transmembrane domain of the fibroblast growth factor receptor 3 (FGFR3), although the molecular consequences of this mutation have not been investigated. By substituting the transmembrane domain of the Neu receptor tyrosine kinase with the transmembrane domains of wild-type and mutant FGFR3, the Arg380 mutation in FGFR3 is shown to activate both the kinase and transforming activities of this chimeric receptor. Residues with side chains capable of participating in hydrogen bond formation, including Glu, Asp, and to a lesser extent, Gln, His and Lys, were able to substitute for the activating Arg380 mutation. The Arg380 point mutation also causes ligand-independent stimulation of the tyrosine kinase activity of FGFR3 itself, and greatly increased constitutive levels of phosphotyrosine on the receptor. These results suggest that the molecular basis of achondroplasia is unregulated signal transduction through FGFR3, which may result in inappropriate cartilage growth plate differentiation and thus abnormal long bone development. Achondroplasia may be one of the number of cogenital disorders where constitutive activation of a member of the FGFR family leads to development abnormalities.     

Effect of pathogenic cysteine mutations on FGFR3 transmembrane domain dimerization in detergents and lipid bilayers

Mutations in fibroblast growth factor receptors are known as the genetic basis of skeletal growth disorders. The mechanism of pathogenesis, as determined by mutation-induced changes in receptor structure, interactions, and function, is elusive. Here we study three pathogenic Cys mutations, associated with either thanatophoric dysplasia or achondroplasia, in the TM domain of fibroblast growth factor receptors 3 (FGFR3). We characterize the dimerization propensities of the mutant TM domains in detergents and in lipid bilayers, in the presence and absence of reducing agents, and compare them to previous measurements of wild-type. We find that the Cys mutations increase the propensity for dimerization in detergent, with the Cys370 mutant exhibiting the highest propensity for disulfide bond formation, the Cys371 mutant having an intermediate propensity, and Cys375 the lowest. Thus, disulfide bonds readily form in detergents, with efficiency that correlates with the severity of the phenotype. In lipid bilayers, however, the Cys370 mutant, which dimerizes strongly in detergent, behaves as the wild-type, suggesting that Cys370-mediated disulfide bonds do not form between the isolated TM domains in bilayers. Thus, the nature of the hydrophobic environment plays an important role in defining the structure and flexibility of transmembrane dimers. These results and previous findings from cellular studies lead us to propose a conformational flexibility mechanism of receptor stabilization as a basis for disregulated FGFR3 signaling in thanatophoric dysplasia and achondroplasia.     

Meclozine Facilitates Proliferation and Differentiation of Chondrocytes by Attenuating Abnormally Activated FGFR3 Signaling in Achondroplasia

Achondroplasia (ACH) is one of the most common skeletal dysplasias with short stature caused by gain-of-function mutations in FGFR3 encoding the fibroblast growth factor receptor 3. We used the drug repositioning strategy to identify an FDA-approved drug that suppresses abnormally activated FGFR3 signaling in ACH. We found that meclozine, an anti-histamine drug that has long been used for motion sickness, facilitates chondrocyte proliferation and mitigates loss of extracellular matrix in FGF2-treated rat chondrosarcoma (RCS) cells. Meclozine also ameliorated abnormally suppressed proliferation of human chondrosarcoma (HCS-2/8) cells that were infected with lentivirus expressing constitutively active mutants of FGFR3-K650E causing thanatophoric dysplasia, FGFR3-K650M causing SADDAN, and FGFR3-G380R causing ACH. Similarly, meclozine alleviated abnormally suppressed differentiation of ATDC5 chondrogenic cells expressing FGFR3-K650E and -G380R in micromass culture. We also confirmed that meclozine alleviates FGF2-mediated longitudinal growth inhibition of embryonic tibia in bone explant culture. Interestingly, meclozine enhanced growth of embryonic tibia in explant culture even in the absence of FGF2 treatment. Analyses of intracellular FGFR3 signaling disclosed that meclozine downregulates phosphorylation of ERK but not of MEK in FGF2-treated RCS cells. Similarly, meclozine enhanced proliferation of RCS cells expressing constitutively active mutants of MEK and RAF but not of ERK, which suggests that meclozine downregulates the FGFR3 signaling by possibly attenuating ERK phosphorylation. We used the C-natriuretic peptide (CNP) as a potent inhibitor of the FGFR3 signaling throughout our experiments, and found that meclozine was as efficient as CNP in attenuating the abnormal FGFR3 signaling. We propose that meclozine is a potential therapeutic agent for treating ACH and other FGFR3-related skeletal dysplasias.     

Trp290Cys mutation in exon IIIa of the fibroblast growth factor receptor 2 (FGFR2) gene is associated with Pfeiffer syndrome

Pfeiffer syndrome is a skeletal disorder characterized by craniosynostosis associated with foot and hand anomalies. Mutations in the genes encoding fibroblast growth factor receptors 1 and 2 (FGFR1 and FGFR2) have recently been implicated in the aetiology of such a syndrome, as well as of other craniosynostotic conditions. We now report a novel missense mutation, a G to C transversion at position 1049 (exon IIIa) of FGFR2, detected in a patient with severe Pfeiffer clinical features. The mutation results in the substitution of a cysteine for tryptophan-290 in the third immunoglobulin-like domain and affects both spliceoforms of FGFR2. Mutations causing replacement of tryptophan-290 have also been reported previously in Crouzon syndrome, a similar but clinically distinct craniosynostotic disorder. This finding confirms the involvement of mutations of FGFR2 exon IIIa in Pfeiffer syndrome, and emphasizes both the extensive heterogeneity of the FGFR2 mutations that result in the Pfeiffer phenotype and the perturbations caused by unpaired cysteine residues in receptor dimerization and transduction of the FGFs signal. Received: 15 August 1996 / Revised: 19 October 1996     

The strong dimerization of the transmembrane domain of the fibroblast growth factor receptor (FGFR) is modulated by C‐terminal juxtamembrane residues

The fibroblast growth factor receptor 3 (FGFR3) is a member of the FGFR subfamily of the receptor tyrosine kinases (RTKs) involved in signaling across the plasma membrane. Generally, ligand binding leads to receptor dimerization and activation. Dimerization involves the transmembrane (TM) domain, where mutations can lead to constitutive activation in certain cancer types and also in skeletal malformations. Thus, it has been postulated that FGFR homodimerization must be inherently weak to allow regulation, a feature reminiscent of α and β integrin TM interactions. However, we show herein that in FGFR3‐TM, four C‐terminal residues, CRLR, have a profound destabilizing effect in an otherwise strongly dimerizing TM peptide. In the absence of these four residues, the dimerizing propensity of FGFR3‐TM is comparable to glycophorin, as shown using various detergents. In addition, the expected enhanced dimerization induced by the mutation associated to the Crouzon syndrome A391E, was observed only when these four C‐terminal residues were present. In the absence of these four residues, A391E was dimer‐destabilizing. Finally, using site specific infrared dichroism and convergence with evolutionary conservation data, we have determined the backbone model of the FGFR3‐TM homodimer in model lipid bilayers. This model is consistent with, and correlates with the effects of, most known pathological mutations found in FGFR‐TM.     

Inhibition or activation of Apert syndrome FGFR2 (S252W) signaling by specific glycosaminoglycans

Most Apert syndrome patients harbor a single amino acid mutation (S252W) in fibroblast growth factor (FGF) receptor 2 (FGFR2), which leads to abnormal FGF/FGFR2 signaling. Here we show that specific combinations of FGFs and glycosaminoglycans activate both alternative splice forms of the mutant but not of the wild-type FGF receptors. More importantly, 2-O- and N-sulfated heparan sulfate, prepared by a combined chemical and enzymatic synthesis, antagonized the over-activated FGFR2b (S252W) to basal levels at nanomolar concentrations. These studies demonstrated that specific glycosaminoglycans could be useful in treating ligand-dependent FGFR signaling-related diseases, such as Apert syndrome and cancer.