Loeys-Dietz and Shprintzen-Goldberg syndromes: analysis of TGF-{beta}-opathies with craniofacial manifestations using an innovative multimodality method

Introduction

Mutations of the transforming growth factor-beta (TGF-β) signalling pathway have been shown to play a critical role in the aetiology of several connective tissue disorders including Loeys-Dietz syndrome (LDS) and Sphrintzen-Goldberg syndrome (SGS). LDS (types 1–5, MIM# 609192, 610168, 613795, 614816, 615582) is a rare autosomal dominant connective tissue disorder with multisystemic involvement, resulting from heterozygous mutations in the TGF-β signalling pathway.1 Originally, LDS was misdiagnosed as Marfan syndrome (FBN1) due to similar vascular features, including aortic root aneurysms. However, patients with LDS have more severe cardiac symptoms, with dissections occurring at younger ages and at smaller diameters throughout the arterial tree, as well as craniofacial abnormalities that have not been thoroughly described.

Five LDS-causing mutations have been identified along the TGF-β pathway including the genes encoding TGF-β receptor 1 (TGFBR1) and TGF-β receptor 2 (TGFBR2), mothers against decapentaplegic homologue 3 (SMAD3), TGF-β ligand 2 (TGFB2) and TGF-β ligand 3 (TGFB3), considered LDS types 1–5, respectively.2 Mutations in the gene encoding the SKI proto-oncogene (SKI), also involved in TGF-β signalling through the inhibition of SMADs, have been associated with SGS, a condition with less severe cardiac defects than LDS but more pronounced craniofacial abnormalities.3–5

Phenotypically, LDS was originally characterised by a triad of features: arterial tortuosity and aneurysms, hypertelorism, and bifid uvula or cleft palate.6 In the decade since its discovery, intense research has been performed on patients and mouse models to better understand the striking variable phenotype of LDS, particularly visible in the craniofacial region. However, not all patients with LDS possess the craniofacial features of the original triad.7 8 Additional craniofacial features reported include craniosynostosis, facial asymmetry, blepharoptosis, retrognathia, malar hypoplasia, dolichocephaly, blue sclerae and strabismus.9–12 Previous papers reported that patients with LDS type 2 have mild craniofacial involvement, while patients with LDS type 1 have more significant craniofacial involvement.6 13 However, the assignment of disease type at the time was based on clinical findings, not molecular diagnosis.

Despite the prevalence of craniofacial features in patients with LDS and the high phenotypic variability, no study has focused on the disparate craniofacial anomalies and the correlation of genotype to the craniofacial phenotype of the different LDS types, and none has done so quantitatively. The goal of this study is to provide a comprehensive phenotypic characterisation of the craniofacial anomalies of LDS and SGS and explore the variability within and across the different subtypes. This is achieved through deep clinical phenotyping, three-dimensional (3D) facial surface analysis, cephalometric and multivariate geometric morphometric analyses of one of the largest LDS cohorts. Through this comprehensive and quantitative approach, we elucidate the impact of TGF-β pathway mutations on craniofacial development in these two rare disorders.

ResultsClinical phenotyping, N=44

A total of 44 patients, 40 with LDS and 4 with SGS, were enrolled. Among the 40 patients with LDS, 15 had mutations in TGFBR1 (LDS1), 14 had mutations in TGFBR2 (LDS2), 3 had mutations in SMAD3 (LDS3), 7 had mutations in TGFB2 (LDS4) and 1 had a mutation in TGFB3 (LDS5). Mean age was 17.2 years (2.4–57.4 years); 22 were female, 22 were male (table 2). Additional information regarding the genetic mutations of the subjects included in this cohort can be found in online supplemental table 2. We also explored the possibility of specific genotype–phenotype correlations using the known genetic variants, with negative results.

Facial shape was highly variable. Craniosynostosis was reported in 10 cases (22.7%), with the sagittal and metopic sutures affected evenly. Eight patients had clinically significant overall facial asymmetry (18.2%). However, there were specific regions with asymmetry: 43.2% with vertical eye dystopia, 20.5% with deviation of nasal tip, 18.2% with lip asymmetry. Mandibular hypoplasia or retrognathism (84.1%) and midface and/or infraorbital flatness (84.1%) were the most prevalent characteristics. A tall and broad forehead (54.5%) was common (table 1, figure 1).

Figure 1Figure 1Figure 1

Clinical views of patients with LDS (subtypes 1–5) and SGS. This photo gallery illustrates the highly variable clinical craniofacial phenotype in TGF-β-opathies. LDS, Loeys-Dietz syndrome; SGS, Shprintzen-Goldberg syndrome; TGF-β, transforming growth factor-beta.

The eye shape and position demonstrated downslanting palpebral fissures or other abnormal eye shape (72.7%), blepharoptosis (65.9%), increased scleral show (61.4%), hypertelorism (40.9%) and telecanthus (27.3%). Nasal anomalies included bulbous nasal tip and/or slit-nares shape (65.9%). Lip anomalies included thin upper lip vermillion or indistinct philtrum (63.6%). Ear shape was not affected, but the position of the ears was low set (72.7%). The presence of a submucous cleft palate was confirmed in only two cases, while bifid uvula was more common (38.6%). There was no cleft lip or palate. A nasal dorsal vein was characteristic in 38.6%, as well as velvet, translucent skin texture (59.1%).

LDS subtype distinctions

SGS and LDS2 had the highest percentage of craniofacial anomalies. Mandibular retrognathism was the most prevalent among the different subtypes: SGS (100.0%), LDS1 (93.3%), LDS2 (92.9%), LDS3 (66.7%) and LDS4 (57.1%). Midface flatness was also common: LDS2 (85.7%), SGS (75.0%) and LDS1 (73.3%). LDS2 (71.4%) and LDS1 (40.0%) had palatal deformities (submucosal cleft palate or bifid uvula), while other LDS types did not have submucous cleft or bifid uvula. More patients with LDS2 presented with telecanthus (42.9%) and hypertelorism (50%) compared with the other LDS types. SGS had a very high occurrence (>75%) of almost every craniofacial anomaly, including craniosynostosis (100%), with the exception of submucous cleft palate/bifid uvula (25%) (table 1).

Functional abnormalities

The total prevalence of TMD was 38.6%, which is relatively high considering the young average age of the cohort. The disorders included arthralgia or pain reported by questionnaire (22.7%), joint sounds (31.8%), deviation of the mandible with opening (6.8%) and limited range of motion (2.3%). Conductive hearing loss was noted in five patients (11.4%), and subclinical hearing loss in three patients. Importantly, 22.7% were diagnosed with OSA and 38.6% reported snoring. Functional eye abnormalities such as nystagmus and strabismus affected 43.2% and were most notable in LDS2 (table 1).

CAI scores (N=44)

Based on the average index scores, SGS had the most craniofacial anomalies among the cohort, with a mean score of 18.0 (range 17.0–19.0) followed by LDS2=12.4 (range 4.0–18.0), LDS1=11.3 (range 3.0–20.0), LDS4=8.1 (range 4.0–11.0), LDS3=7 (range 5–8), while the single proband with LDS5 had a score of 5 (table 1).

Surgeries of the craniofacial region

Fifty-nine per cent of patients had a history of one or more surgeries of the craniofacial region. Among the 10 patients with a diagnosis of craniosynostosis, 6 had a history of surgical repair (SGS=3; LDS2=2; LDS1=1). Other reported surgical procedures included adenoidectomy (n=9), tonsillectomy (n=7), tympanostomy tube placement (n=8), strabismus correction (n=6), and soft palate or bifid uvula repair (n=5). One patient with SGS required mandibular distraction osteogenesis for congenital micrognathia. Other isolated procedures include blepharoptosis correction, lingual frenectomy, tympanografts and removal of lip haemangioma. Individuals with LDS1 and LDS2 required the most surgical interventions (online supplemental table 3).

3D photo facial surface analysis, N=39

The mean age was 17.9 years (range 2.4–57.4 years); 20 female and 20 male subjects. The 3D photos of five young patients (n=4 LDS, n=1 SGS) had to be excluded due to poor quality and lack of cooperation. The average of right and left measurements was used, since no significant soft tissue asymmetry was detected (figure 2, online supplemental table 4).

Figure 2Figure 2Figure 2

(A) Heatmap of Z-scores depicting the deviation of the soft tissue measurements in the different LDS subtypes and SGS, based on the normal values provided by FaceBase. The orange shades represent positive values, blue represents negative values. SGS, LDS2 and LDS1 are the subtypes with extreme Z-score values. LDS2, followed by LDS1, have the greatest variability. Facial depth, eyes and nose projection measurements were uniformly affected across the cohort. The facial depth and nasal projection were the most negatively affected features, while the eye measurements were increased. (B) The 3D mesh view of the face of an individual with LDS2 with the annotated landmarks used for the photo surface analysis. (C) PCA plot of the 3D photo surface landmark coordinate data depicting the variability of the soft tissue morphology among the different LDS subtypes, with the greatest variability in LDS2. 3D, three-dimensional; LDS, Loeys-Dietz syndrome; PCA, principal component analysis; SGS, Sphrintzen-Goldberg syndrome.

The cranial base width (Z=−1.14), midface depth (Z=−1.35) and lower face depth (Z=−1.50) were reduced subclinically in all subgroups except for LDS5. These results indicate a tendency for midface and mandibular hypoplasia. Moreover, the cohort exhibited subclinical alterations in the vertical plane, including morphological face height (Z=−1.54) and upper face height (Z=−1.09), with the exception of LDS5. Intercanthal distance was subclinically increased (Z=1.16). Nasal dimensions showed an increased subnasal width (Z=1.20), while nasal projection (Z=−1.01) and alar length (Z=−1.38) were subclinically decreased. The dimensions of the lips were not significantly affected.

LDS subtype distinctions

SGS subtype demonstrated a more uniform but severe phenotype with a greater percentage of affected craniofacial measurements beyond ±2.0 Z-score compared with the LDS subtypes. Lower facial projection (Z=−2.79), total facial height (Z=−3.14) and upper facial height (Z=−4.30) were profoundly deficient in SGS, whereas intercanthal distance was significantly increased (Z=3.13). In LDS1 and especially LDS2, there was a characteristic heterogeneity, including patients who had normal Z-scores and others with Z-scores beyond ±2. Therefore, the computed average Z-scores per LDS type were not representative for these two subtypes. In LDS3 and LDS4, there was less variability and no extreme Z-scores.

Cephalometric analysis, N=20, LDS only

CBCT scans were obtained for 20 patients with LDS (10 female; 10 male); mean age was 26.9 years (9–57 years). No patients with SGS had CBCTs.

The mean cranial base angle (nasion–sella–articulare) was 3.00 SD above the norm, indicating a flattened cranial base angle, with the most significant alterations in LDS2 (Z=4.20). Platybasia (defined as a cranial base angle >143°) was detected in four cases among the LDS2 subtype (figure 3A). There was also significant shortening of the anterior cranial base (sella–nasion, Z=−2.35), with greatest deviation in the LDS1, LDS2 and LDS4. The posterior cranial base (sella–articulare, Z=−1.56) was subclinically affected (figure 3, online supplemental table 5).

Figure 3Figure 3Figure 3

(A) Average Z-scores for each LDS subtype for each of the 2D cephalometric measurements, compared with normal values for the general population. The growth and position of the cranial base, maxilla and mandible are significantly affected in LDS, especially in LDS1 and LDS2. (B) The 3D craniofacial landmarks used for the cephalometric and geometric morphometric analysis annotated on a 3D view of a skull (C). PCA plot depicting the variation in the craniofacial shape in LDS. The variability in LDS2 and LDS1 can be appreciated, while all other subtypes are closer to the means of the axes. 2D, two-dimensional; 3D, three-dimensional; LDS, Loeys-Dietz syndrome; PCA, principal component analysis; SNA, sella–nasion–A point; SNB, sella–nasion–B point.

In the vertical plane, there was reduced anterior facial height (nasion–menton, Z=−2.45) and posterior facial height (sella–gonion, Z=−1.95). The lower face height, ramus height and gonial angle were within normal range.

In the sagittal plane, the midface length (condylion–A point, Z=−3.02) was significantly reduced. The overall cohort mean Z-scores for SNA (sella–nasion–A point) and SNB (sella–nasion–B point) were −1.84 and −2.31, respectively, with the most significant deviations in the patients with LDS2 (SNA, Z=−3.31; SNB, Z=−3.28). Moreover, the mandibular body length was reduced in all LDS subtypes (gonion–pogonion, Z=−2.83), except for LDS5, where it was significantly increased (Z=2.78).

Overall, the craniofacial alterations from most severe to least severe were identified in LDS2, LDS1, LDS5, LDS3 and LDS4. The single patient with LDS5 had a broadly different craniofacial pattern than the other types, with normal cranial base and increased growth of the mandible (mandibular body length=2.78; lower facial height=4.23).

We tested for significant differences via ANOVA for each of the cephalometric measures across the three groups: LDS1, LDS2 and other LDS types. No statistically significant craniofacial cephalometric measures were found among the various LDS subtypes except for SNA, which was significantly smaller in LDS2 (p<0.05 for all comparisons), indicating significant maxillary hypoplasia.

Pharyngeal airway assessment and hyoid bone position, N=20, LDS only

In 55.0% of the patients, there was reduced PAS. This included all six patients with LDS1, four LDS2, one LDS3 and one patient with LDS4 (online supplemental figure 1). The same patients had significantly reduced minimum CSA. The vertical position of the hyoid bone, based on the H-MP measurements, was low in 47.6% of the patients, many of whom also had reduced PAS.

Multivariate analysis of 3D craniofacial shape: 3D photos and CBCT

The PCA plot of the 3D photo data supported the findings of the cephalometric and 3D photo Z-score analyses and demonstrated the variability in LDS2. On the plot for the soft tissue landmark data (figure 2C), PC1 explained 25.9% of the shape variance while PC2 explained an additional 16.2%, for a total of 42.1% of the facial shape variance across the entire LDS cohort. LDS2 expanded across PC1 and PC2 axes in both directions, whereas the other LDS subtypes cluster closer to the centre of the plot. In contrast, SGS cluster separately and on the negative aspect of PC1 axis, indicating a clear morphological difference in these patients.

According to the PCA on the CBCT data, PC1 explained 25.5% of craniofacial shape variance and PC2 explained an additional 18.6%, for a total of 44.1% of craniofacial shape variance (figure 3C). LDS1 and LDS2 cohorts spanned both the PC1 and PC2 axes, however, LDS2 had more extreme variability. LDS3 and LDS5 were closer to the centre of the plot on the negative PC1 axis, while LDS4 was on the positive PC1 axis.

Discussion

This study is the first to quantitatively examine the craniofacial anomalies associated with two TGF-β-opathies, LDS and SGS, and to correlate the craniofacial phenotype to genotype using a multimodality approach. While the more severe craniofacial abnormalities in LDS have been previously reported, including craniosynostosis, hypertelorism, strabismus and cleft palate, these features were not common in this cohort compared with significant hypoplasia of the maxilla and mandible, abnormal eye shape with increased sclera show and blepharoptosis, abnormal lip shape, low-set ears and skin translucency, with more than 50% of the participants exhibiting these characteristics. Several of these features also indicate abnormalities of the cranial base.

The results of the quantitative cephalometric analysis conducted on CBCT images further revealed the underlying skeletal abnormalities and sources of dysmorphologies not readily identified with the clinical or surface analysis. Multiple angular measurements associated with the cranial base were significantly altered. The mean cranial base angle was over 3 SDs above the norm and four cases of platybasia were detected in LDS2. The length of the anterior cranial base was reduced. A more inferior location of the sella turcica contributed to an alteration in the inclination of the anterior cranial base, which resulted in an increased cranial base angle, increased SN-FH (Frankfort Horizontal plane) angle, and the extremely low SNA and SNB angles. The changes of the cranial base clearly impacted the development of the maxilla and mandible.

According to the clinical, cephalometric and 3D surface morphometric assessment, significant retrognathia of the mandible and maxilla was observed throughout the cohort. The cephalometric analysis confirmed that the retrognathia is not only due to positional changes of the cranial base but to the absolute underdevelopment of the maxilla and mandible. Vertically, there was a reduction in both anterior and posterior facial heights, but the cephalometric data suggest the cranial base and upper facial skeleton are the source of underdevelopment, as the ramus height and gonial angle were within the normal range.

Less clear are the underlying skeletal and developmental abnormalities contributing to the clefting of the uvula, although our data suggest a wider maxilla in the transverse plane in patients with LDS2 compared with the other types. Given the small sample size, we could not apply multiple testing corrections.

Using geometric morphometric analysis of overall facial shape, PCA analysis of both the CBCTs and 3D photos shows increased variability in LDS2, followed by variability in LDS4, with SGS clustering at the negative extreme of PC2. LDS1, LDS3 and LDS5 tend to cluster closer to the intersection of PC1 and PC2, suggesting these patients represent more of a mean LDS phenotype in terms of skeletal and facial shape. Although the sample size is small for the dimensionality of this multivariate geometric morphometric analysis, we are confident about the validity of these results given the consistent pattern of affected traits through clinical phenotyping and cephalometric analysis. In addition to LDS2 displaying the greatest phenotypic variability, the more severe abnormalities were identified in LDS2 and SGS, as confirmed by the craniofacial anomalies’ indices. This suggests unique craniofacial developmental perturbations that are specific to TGFBR2 and SKI mutation variants.

The value of the 3D photos and surface analysis is rapid capture of information and the ability to digitally acquire anthropometric measurements. This is particularly valuable for assessing young and less cooperative patients while gathering quantifiable data. Additionally, we were able to detect subtle clinical feature variations, such as a relatively increased intercanthal distance, an increased nasal width, and decreased nasal projection and height, throughout the cohort. One of the limitations of this analysis is the limited normative values from FaceBase. Some normative data are based on very small groups with as little as six subjects, and some of the SD values are as low as 1.0, which can lead to relatively increased Z-scores. In addition, there are no published 3D facial norms for individuals of non-European descent. These factors could potentially influence the validity of the generated Z-scores.

An important finding was the prevalence of TMD. This may be attributed to structural craniofacial abnormalities, such as the high percentage and severity of mandibular retrognathism, the underlying connective tissue disorder or a combination of the two factors. Some morphological changes were detected through qualitative CBCT assessment, but a more specialised analysis is required for further assessment that exceeds the scope of this paper. Interestingly, TMD has also been linked to a lower oral health-related quality of life in patients with LDS.15 An animal model may assist in understanding the TMD aetiology and development in LDS.

Our analysis revealed a tendency for the development of sleep-related breathing disorders. OSA in LDS, to our knowledge, has only been described in one case report of a patient with LDS2.24 Apart from the 10 subjects who had a diagnosis of OSA, a larger number reported snoring (n=17) and history of adenoidectomy (n=9). Moreover, the quantitative analysis of CBCTs demonstrated a reduction in posterior airway space, low position of the hyoid, and a retrognathic mandible and maxilla, all of which are known contributors or risks for OSA.25–31 Considering the effect of OSA on cardiovascular events and hypertension,32 it is extremely important to consider sleep apnoea studies and assessment of craniofacial abnormalities in these patients.

One of the limits of this study and all studies of rare diseases is the small cohort and sample size. Additionally, we could not safely obtain CBCT images for all individuals due to the young age and radiation risks. Despite this, we have optimised the research potential by the deep clinical phenotyping and use of multimodality imaging analysis. Previous studies on craniofacial dysmorphology have relied on ‘gestalt’ and limited clinical assessment. And while ‘gestalt’ is helpful for obvious features and diseases with homogeneous characteristics, it is less useful when there is significant phenotypic variation within a cohort. Unfortunately, such assessments do not provide methods to link the craniofacial developmental aberrations to the underlying mutations, even when the genotype is established. The strength of this study is the multimodality morphometrics, particularly the skeletal imaging, which provides an objective, quantitative phenotypic characterisation and demonstrates the segregation of craniofacial development to the mutations along the TGF-β pathway. Clearly, the mutations associated with the TGFBR2 and SKI genes have a profound effect on craniofacial development with perturbations associated with the cranium and cranial base with severe downstream effects on the orbit, maxilla and mandible. Additionally, the highest variability noted in LDS2 suggests epigenetic, non-canonical or distant enhancers of the TGFBR2 gene mutation that may induce the variable phenotypic spectrum. We continue to examine these variations in the mouse models of TGF-β pathway mutations, however, the opportunity to deeply phenotype and understand the variation in human subjects is invaluable.

In summary, as precision medicine becomes more possible, the detailed data provided by the present study will be added to the growing literature and will assist clinicians in the future in predicting the clinical anomalies per genetic variant. In addition, we address for the first time the higher prevalence of TMD and relatively increased risk of OSA in the case of LDS, particularly in the LDS1 and LDS2 subtypes, and encourage clinicians to include more detailed assessments regarding these conditions as part of the physical evaluation of these patients.

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