Spondylocostal Dysplasia and Brachydactyly: a case report

Surasak Puvabanditsin, MD surasak1@aol.com

Department of Pediatrics, Rutgers Robert Wood Johnson

Medical School, New Brunswick, New Jersey

Michelle Gorbonosov, MD mg1687@rwjms.rutgers.edu

Department of Family Medicine, Rutgers RWJ Medical School

Kristin Blackledge, MA ket79@rwjms.rutgers.edu

Rutgers Robert Wood Johnson Medical School

Jeffrey Manzano, MD jm2385@rwjms.rutgers.edu

Department of Pediatrics, Rutgers RWJ Medical School

Matthew Federici, MD mcf92@rwjms.rutgers.edu

Department of Pediatrics, Rutgers RWJ Medical School

Rajeev Mehta, MD mehtara@rwjms.rutgers.edu

Department of Pediatrics, Rutgers RWJ Medical School

Running Title: Puvabanditsin et al. Spondylocostal Dysplasia

Written informed consent was obtained from the patient/guardian to publish this report in accordance with the journal’s patient consent policy.

ABSTRACT

We report a preterm male neonate presenting with a skeletal dysplasia associated with multiple congenital anomalies. Radiologic findings and genetic studies are consistent with spondylocostal dysostosis (SCD) and autosomal dominant brachydactyly. This is the first case report of spondylocostal dysostosis and brachydactyly associated with TBX6and IHH variants.

Key words: spondylocostal dysplasia; costovertebral malformation;

Jarcho-Levin syndrome; congenital anomaly

Correspondence about the manuscript or reprint:

Surasak Puvabanditsin, MD

Department of Pediatrics, Rutgers Robert Wood Johnson Medical School

1 Robert Wood Johnson Place, New Brunswick, NJ 08903

Tel. (732) 235-5691, Fax (732) 235-5668,

e-mail: surasak1@aol.com

INTRODUCTION:

Costovertebral malformations are rare and result in significant disabilities because they are associated with spinal deformities (e.g. scoliosis, kyphosis) and rib abnormalities that could compromise respiratory function. Spondylocostal dysostosis (dysplasia) [SCD] is an autosomal recessive disorder that is characterized by multiple segmental defects of the vertebrae and abnormalities of the ribs. The phenotypes include a short trunk, short neck, and scoliosis (1,2). In neonates, SCD can cause respiratory problems due to reduced size of the thorax. With advancement in diagnosing genetic anomalies, the genetic etiology of congenital vertebral malformation (CVM) is acceptably based on the DNA analysis of single nucleotide polymorphism (SNP) arrays or the next generation sequencing technology [whole exome sequence (WES) and whole genome sequence (WGS)]. We report a new case of SCD with an accompanying genetic analysis.

CASE PREPORT

A 2950-g Hispanic male neonate was born at 36 weeks gestation to a 16-year-old primigravida by vacuum-assisted vaginal delivery. Apgar scores were 9 and 9 at one and five minutes respectively. Pregnancy was uncomplicated. The family history was negative for congenital anomalies, and there was no history of in-utero exposure to any known teratogens. There was no history of consanguinity. Physical examination revealed a weight of 2950 grams (50^th centile), length of 45 cm (5^th centile), and head circumference of 34 cm (25^th centile). Anomalies noted at birth included: cleft soft palate, coloboma of the iris, wide anterior fontanelle, wide sagittal suture, low set ears, short neck, deformed ear, short fingers and toes, transposition of the penis and prominent median raphe of the scrotum and perineum (Figure 1). Neurosonogram and echocardiography were normal. Chest and spinal radiographs showed segmentation anomalies of the thoracic spines; [“butterfly”] hypoplastic and hemivertebrae were present from the 1^st to 12^ththoracic vertebral bodies. The ribs were abnormal (fused and dysplastic). L3 and L4 hemi-vertebra and lumbar scoliosis were also noted (Figure 2). Renal sonography and MRI showed cross-fused and dysplastic kidneys, and left hydronephrosis. Radiographs of the hands and feet showed hypoplasia/absence of the middle phalanges (Figure 3). Abdominal ultrasound and MRI studies revealed a small enteric duplication cyst (1.6 x 1.5x 1.3 cm) anterior to the rectum. An upper gastrointestinal contrast study performed at three weeks of age because of feeding difficulties (initially thought to be due to the cleft soft palate and disorganized sucking) showed malrotation of the small intestine. The patient underwent an exploratory laparotomy, lysis of Ladd’s band, and appendectomy on the 30^th day of life. Concurrently, gastrostomy tube placement and Nissen fundoplication were done to help with the feeding. The infant remained in the hospital for 50 days because of the feeding difficulties.

CYTOGENETIC AND MOLECULAR STUDIES

The karyotype was 46 XY. The whole genome SNP (Single Nucleotide Polymorphisms) microarray analysis was normal. No significant DNA copy number changes in the 2.695 million region specific SNPs were detected. The SNP microarray analysis was performed using CytoScan HD platform, which uses over 730,000 SNP probes and 1,953,000 NPCN probes with median spacing of 0.88 kilobase.

A high density of short runs [1.8 Megabase (Mb)] of allele homozygosity (ROH) were observed throughout the genome, consistent with a limited gene pool present in isolated populations. This finding reflects an increased risk of recessive allele pairing. The study also showed additional longer ROH on chromosomes 2, 5, and 16, consistent with a distantly related parental relationship [ROH Bp linear position: chr2:56149474-66950851; chr5:17410451-38717348; chr16:25974475-35220544. Total 41 Mb (1.5% of autosomal genome)].

A sequence analysis and deletion/duplication testing of 109 genes (Invitae Skeletal Dysplasia Panel) were performed by Invitae Laboratory Corporation, San Francisco, California 94103, USA. The result identified four significant variants that possibly related to the clinical findings in our patient (Table 1).

DISCUSSION

Jarcho–Levin syndrome (JLS) is a congenital vertebral malformation (CVM) characterized by vertebral body and rib malformations. JLS was first described by Saul Jacho [a pathologist] and Paul Levin [a neurologist] from Baltimore, USA in 1938 (1,3). The syndrome represents a hereditary malformation spectrum of short trunk and moderate rib cage restrictions with variable involvement of vertebrae [fused, hemi, and block vertebrae] and ribs [absent to overgrown ribs]. Subsequently, these findings have been termed and known as spondylocostal dysostosis/dysplasia (SCD). The affected individual ethnicity was colored [Anglo-Saxon]. The DLL3 gene has been linked to SCD (1).

Lavy-Moseley syndrome was first reported by Norman Lavy from Indiana university, Indianapolis and John Moseley from Mt Sinai, New York City (1,4,5). In 1966, Lavy reported infants of the same family from Puerto Rico (PR) who died from severe respiratory insufficiency during infancy. All had small chests, short trunks, symmetric posterior fusion of the ribs with a

fan-like [crab-like] appearance, and fusion of the occiput of the skull to the first cervical vertebra. Three years later, Moseley reported two more cases of patients with similar findings and used the term spondylothoracic dysplasia/dysostosis (STD) to describe these congenital anomalies (4). MESP2 has been implicated in STD individuals. STD is now described as a rare, pleiotropic genetic disorder with an autosomal recessive inheritance. It is most reported in patients from PR or of documented PR ancestry (5 Moseley and Bonforte, 1969). The MESP2 gene has been implicated in individuals with STD.

Notably, MESP2 has been implicated in STD individuals. Although the trunk is short in both STD and SCD, the severity of vertebral malformation and clinical course is much worse in STD.

For more than 50 years after the first JLS was reported there was still confusion with regards to patients with vertebral anomalies and thoracic cage deformities. The term JLS was inaccurately coined to mean SCD or STD. However, SCD and STD are two distinct entities with distinct skeletal anomalies, ethnic connections, modes of inheritance, and survival. Other associated anomalies with SCD include: neural tube defects, Arnold-Chiari malformation, hydrocephalus, diastematomyelia, renal/urinary tract abnormalities, and hydrourteronephrosis (6). The clinical course and vertebral malformations are, also, more severe in patients with STD compared to SCD. Our patient is a Caucasian male with Hispanic ethnicity who presented with malrotation of the small bowel, which is a new reported malformation associated with SCD.

Autosomal recessive variation of TBX6 has been reported to be associated with segmental defects of the vertebra (SDV), ranging from congenital scoliosis (CS) to SCD (7,8,9,10). The TBX6 gene is located on chromosome 16 [16p12.2], is 6,095bp in size, and contains 8 exons (8). Our case supports that the autosomal recessive TBX6 variant is associated with SCD. TBX6, a T-box gene, encodes a transcription factor which plays an important role in embryonic development of somite (somitogenesis). It plays a key role in human spine development.

In our patient, the genomic microarray findings are consistent with autosomal recessive allele pairing as products of distantly related parents. The DNA sequence analysis [Invitae Skeletal Dysplasia Panel] identified variants in TBX6 and IHH, which probably correlate with our patient’s distinct phenotypes. Our case revealed that SCD could be associated with brachydactyly of both hands and feet, deformed ears, cleft soft palate, and bilateral colobomas of the irises. These associated abnormalities have not previously been reported with SCD. The malformations of the hands and feet (brachydactyly) due to lack of ossification of the middle and distal phalanges, as seen in our patient, have been described with theIHH variant (autosomal dominant brachydactyly type A1(BDA1)(MedGen UID 354673).

Based on DNA analysis of SNP arrays and advanced genomic sequencing technology, we are able to identify the genetic etiology of SCD.

In summary, we report a case of a neonate with TBX6, DVA1, andIHH variants associated with SCD and new associated phenotypes. We illustrate the use of the whole genome microarray and genomic sequencing analysis to identify the genetic etiology of congenital vertebral malformations.

The manuscript and its content have been approved by all co-authors.

The authors declare no conflict of interest.

The authors have no financial disclosure to declare.

Author Contributions

Surasak Puvabanditsin involved in manuscript design and written.

Michelle Gorbonosov and Rajeev Mehta involved in data analysis

and manuscript revision.

Kristin Blackledge and involved in manuscript written and

revision.

Jeffrey Manzano and Matthew Federici involved in manuscript

revision

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Figure 1a. Note a short neck and a deformed ear (notched helix

and prominent antihelix)

Figure 1b, 1c. Note a palmar crease and short fingers/nails

Figure 1d. Note a short and broad toes, small nails and

metatarsus abductus

Figure 1e, 1f. Note transposition of the penis and prominent

median raphe

Figure 2a & 2b Spinal radiographs shows segmentation anomalies

of thoracic spines and rib abnormalities, L3&L4

hemivertebra with lumbar scoliosis

Figure 3a Radiograph of the hand shows absence/short middle

phalanges of fingers

Figure 3b Radiograph of the foot shows absence/short middle

phalanges of toes