The latest FADS: Functional analysis of GLDN patient variants and classification of GLDN‐associated AMC as a type of viable fetal akinesia deformation sequence

Recessive variants in the GLDN gene, which encodes the gliomedin protein and is involved in nervous system development, have recently been associated with Arthrogryposis Multiplex Congenita (AMC), a heterogenous condition characterized by congenital contractures of more than one joint. Two cohorts of patients with GLDN‐associated AMC have previously been described, evolving the understanding of the condition from lethal to survivable with the provision of significant neonatal support. Here, we describe one additional patient currently living with the syndrome, having one novel variant, p.Leu365Phe, for which we provide functional data supporting its pathogenicity. We additionally provide experimental data for four other previously reported variants lacking functional evidence, including p.Arg393Lys, the second variant present in our patient. We discuss unique and defining clinical features, adding calcium‐related findings which appear to be recurrent in the GLDN cohort. Finally, we compare all previously reported patients and draw new conclusions about scope of illness, with emphasis on the finding of pulmonary hypoplasia, suggesting that AMC secondary to GLDN variants may be best fitted under the umbrella of fetal akinesia deformation sequence (FADS).     

Fetal akinesia deformation sequence syndrome associated with recessive TTN variants

Arthrogryposis multiplex congenita (AMC) [also known as multiple joints contracture or Fetal Akinesia Deformation Sequence (FADS)] is etiologically a heterogeneous condition with an estimated incidence of approximately 1 in 3000 live births and much higher incidence when prenatally diagnosed cases are included. The condition can be acquired or secondary to fetal exposures and can also be caused by a variety of single-gene disorders affecting the brain, spinal cord, peripheral nerves, neuromuscular junction, muscle, and a variety of disorders affecting the connective tissues (Niles et al., Prenatal Diagnosis, 2019; 39:720–731). The introduction of next-generation gene sequencing uncovered many genes and causative variants of AMC but also identified genes that cause both dominant and recessive inherited conditions with the variability of clinical manifestations depending on the genes and variants. Molecular diagnosis in these cases is not only important for prognostication but also for the determination of recurrence risk and for providing reproductive options including preimplantation and prenatal diagnosis. TTN, the largest known gene in the human genome, has been known to be associated with autosomal dominant dilated cardiomyopathy. However, homozygote and compound heterozygote pathogenic variants with recessive inheritance have rarely been reported. We report the effect of recessive variants located within the fetal IC and/or N2BA isoforms in association with severe FADS in three families. All parents were healthy obligate carriers and none of them had cardiac or skeletal muscle abnormalities. This report solidifies FADS as an alternative phenotypic presentation associated with homozygote/compound heterozygous pathogenic variants in the TTN.     

Expanding the MYBPC1 phenotypic spectrum: a novel homozygous mutation causes arthrogryposis multiplex congenita

Arthrogryposis multiplex congenita (AMC) is characterized by heterogeneous nonprogressive multiple joint contractures appearing at birth. We present a consanguineous Israeli‐Druze family with several members presenting with AMC. A variable intra‐familial phenotype and pected autosomal recessive inheritance prompted molecular diagnosis by whole‐exome sequencing. Variant analysis focused on rare homozygous changes, revealed a missense variant in MYBPC1, NM_002465:c.556G>A (p.E286K), affecting the last nucleotide of Exon 8. This novel variant was not observed in the common variant databases and co‐segregated as expected within the extended family. MYBPC1 encodes a slow skeletal muscle isoform, essential for muscle contraction. Heterozygous mutations in this gene are associated with distal arthrogryposis types 1b and 2, whereas a homozygous nonsense mutation is implicated in one family with lethal congenital contractural syndrome 4. We present a novel milder MYBPC1 homozygous phenotype.     

Recombination between the postulated CCD/MHE/MHS locus and RYR1 gene markers

Malignant hyperthermia (MH) susceptibility is considered a subclinical myopathy or a pharmacogenetic trait, and is believed to be closely associated with central core disease (CCD). Data support the notion that MH susceptibility is heterogeneous, with the ryanodine receptor 1 (RYR1) locus on chromosome 19 being one locus harboring a gene that can cause MH susceptibility. The gene for CCD is believed to reside in the locus on chromosome 19. In the family presented here, a girl has CCD, and several close relatives are MH susceptible (MHS). DNA studies conducted on available family members uncovered recombination between the MH susceptibility locus and RYR1 markers. Consequently, if one postulates that the CCD gene in this family resides in the same locus as the MH susceptibility gene, an additional CCD locus different from the RYR1 locus must also be postulated.     

Search for three known mutations in the RYR1 gene in 48 Danish families with malignant hyperthermia

We have examined 48 Danish families in which malignant hyperthermia reactions have occurred, with respect to three of six published mutations in the gene for the calcium release channel of sarcoplasmic reticulum (the RYR1 gene) believed to cause malignant hyperthermia susceptibility in man. The mutations are Arg614Cys, also known as the "pig mutation"; Arg163Cys; and Ile403Met. The only mutation found was Arg163Cys, which was detected in only one family. The results of this study indicate that other mutations must underlie the disorder in most Danish malignant hyperthermia-susceptible families, and that the "pig mutation" is not a frequent cause of malignant hyperthermia susceptibility in Denmark.     

CHRNG‐related nonlethal multiple pterygium syndrome: Muscle imaging pattern and clinical,histopathological, and molecular genetic findings

Mutations in the CHRNG gene cause autosomal recessive multiple pterygium syndrome (MPS). Herein we present a long‐term follow‐up of seven patients with CHRNG‐related nonlethal MPS and we compare them with the 57 previously published patients. The objective is defining not only the clinical, histopathological, and molecular genetic characteristics, but also the type and degree of muscle involvement on whole‐body magnetic resonance imaging (WBMRI). CHRNG mutations lead to a distinctive phenotype characterized by multiple congenital contractures, pterygium, and facial dysmorphism, with a stable clinical course over the years. Postnatal abnormalities at the neuromuscular junction were observed in the muscle biopsy of these patients. WBMRI showed distinctive features different from other arthrogryposis multiple congenita. A marked muscle bulk reduction is the predominant finding, mostly affecting the spinal erector muscles and gluteus maximus. Fatty infiltration was only observed in deep paravertebral muscles and distal lower limbs. Mutations in CHRNG are mainly located at the extracellular domain of the protein. Our study contributes to further define the phenotypic spectrum of CHRNG‐related nonlethal MPS, including muscle imaging features, which may be useful in distinguishing it from other diffuse arthrogryposis entities.