Collagen VI has recently been strongly linked to poor outcomes in heart failure through increased endotrophin, a collagen VI-derived signaling molecule linked to fibrotic remodeling in cardiovascular disease. The mutation of collagen VI can result in Ullrich congenital muscular dystrophy and Bethlem myopathy, pointing to a critical function in muscle physiology. However, the functional role of collagen VI in the heart is poorly understood. In human heart failure with reduced ejection fraction, collagen VI is increased within the remodeled T-tubules, suggesting a possible role in tubular structure and Ca2+ dynamics. To investigate this hypothesis, a global knockout of the collagen VI alpha 1 gene (Col6a1-/-) was generated in the rat. T-tubule structure and ryanodine receptor cluster organization were unchanged, but echocardiography demonstrated reduced systolic function. Consistent with this, isolated trabeculae from Col6a1-/- hearts generated significantly less peak stress, confirming impaired contractile force at the tissue level. Paradoxically, isolated cardiomyocytes from the Col6a1-/- rat had increased Ca2+ transient amplitude and increased sarcoplasmic reticulum Ca2+ load that would be expected to increase force. β-adrenergic stimulation further increased Ca2+ transient amplitude and was associated with diastolic Ca2+ release events in Col6a1-/- cardiomyocytes. Furthermore, β-adrenergic stimulation of Col6a1-/- trabeculae exhibited spontaneous contractions, indicating an increased susceptibility to arrhythmic activity. Together, these results indicate collagen VI has a role in both force transduction and Ca2+ cycling in the heart.

Collagen VI is an extracellular matrix component encoded by COL6A1, COL6A2 and COL6A3 genes. Causative variants in these genes are associated with the following collagen VI-related myopathies: severe Ullrich congenital muscular dystrophy (UCMD), milder Bethlem myopathy (BM) and intermediate phenotypes (INT). We report the mutation landscape of COL6A genes in 138 Italian patients affected with a collagen VI-related phenotype. The patient cohort included 44 (32%) UCMD, 9 (7%) INT, 61 (44%) BM and 21 (15%) INT/BM patients; 3 patients (2%) with a myosclerosis myopathy (MM) phenotype were also considered. We identified 104 different variants: 26 in COL6A1 (25%), 52 in COL6A2 (50%) and 26 in COL6A3 (25%). The variant spectrum includes missense, splicing, small indel, frameshifting and nonsense variants. Glycine substitutions in the triple helical domain of the collagen VI protein are the commonest variants and occur in all phenotypes. Our genetic profiling disclosed a unique mutation scenario and phenotypic association of the COL6A2 gene with respect to COL6A1 and COL6A3, which may be related to a different evolutive history. Landscape mutation analysis of variants occurring in ultrarare conditions, such as collagen VI-related myopathies, is crucial to better understand the variations’ profile and to gain insight into fundamental knowledge about gene structure and its evolutive origin.

312PClinical and muscle MRI findings of Bethlem myopathy: case series

Bethlem myopathy (BM) is a collagen-VI-related myopathy caused by mutations in the COL6A1, COL6A2, and COL6A3 genes. It is characterized by proximal muscle weakness, distal joint laxity, and contractures, with symptoms appearing during childhood and progressing slowly. Muscle ultrasound, using tools like the Heckmatt scale, complements genetic analysis and provides noninvasive insights into muscle pathology, particularly in atypical presentations. An 8-year-old male presented with muscle weakness since birth, delayed motor milestones, toe walking, and frequent falls. Family history revealed maternal-line neuromuscular disorders. Clinical examination showed hyporeflexia, thoracic hypotrophy, and decreased proximal muscle strength, alongside joint hypermobility and keratosis pilaris. Electromyography indicated a myopathic pattern in proximal upper limb muscles. Genetic analysis confirmed a pathogenic COL6A1 variant (c.788G > A, p.Gly263Asp). Ultrasound findings revealed advanced structural compromise with Heckmatt grade IV echogenicity in the deltoid, iliopsoas, and rectus femoris, indicating fatty infiltration and fibrosis. Functional tests, including Motor Function Measurement (MFM), showed adequate performance despite significant structural abnormalities. This case illustrates the diagnostic challenges of BM, characterized by phenotypic variability and the complexity of correlating structural and functional findings. Muscle ultrasound findings demonstrated advanced echogenic changes, but functional performance remained preserved, highlighting a mismatch between structural changes and functional outcomes. This case highlights the diagnostic challenges of BM, where a patient with a COL6A1 gene mutation exhibited significant muscle abnormalities on ultrasound but maintained relatively preserved motor function according to the MFM scale. This discrepancy emphasizes the limitations of functional assessments like MFM in capturing the extent of muscle weakness. Ultrasound and dynamometry provided a more comprehensive evaluation, underscoring the importance of integrating structural and functional assessments for accurate diagnosis and management. This case stresses the need for an individualized approach in managing BM, considering both genetic and clinical findings.

The COL12A1 gene encodes Collagen XII α 1 chain, forming a biologically functional Collagen XII through a trimeric structure. Collagen XII dysfunction can lead to hereditary neuromuscular diseases with phenotypic profiles ranging from rare Ullrich congenital muscular dystrophy 2 (biallelic variant) to Bethlem myopathy 2 (uniallelic variant). Currently, only 29 COL12A1 deficiency cases have been reported, mainly featuring hypotonia, progressive muscular dystrophy, and skeletal deformities. Newborns cases were relatively rare. Here, we describe a neonate with hypotonia, weak spontaneous movement, convulsions, and respiratory failure at birth. Identification of a novel variant of COL12A1 by whole exome sequencing and Sanger sequencing, NM_004370.6: c.7622C > T, p.Ser2541Phe. Molecular dynamics simulation revealed its location in the thrombospondin N-terminal domain, potentially destabilizing the Collagen XII trimer's structure. Our case report expands the COL12A1 genotype and phenotype spectrum, suggesting the presence of neonatal hypotonia and highlighting the importance of vigilance for respiratory clinical manifestations.

Generation of an iPSC line (with isogenic control) from the PBMCs of a COL6A1 (c.1056+2T>A) Bethlem myopathy patient.

Abstract We describe a male patient in his early thirties exhibiting muscle weakness since childhood, which progressed slowly over time. Clinical examination revealed proximal muscle weakness and contractures in hip flexor, hip adductor and gastrosoleus muscles. Magnetic resonance imaging of the lower limbs revealed a specific pattern with peripheral fat infiltration. Genetic analysis through whole exome sequencing identified a heterozygous mutation in the exon 10 (COL6A1) and exon 7 (SPLTC2), linked to Bethlem myopathy. He underwent corrective surgery for hip and ankle deformities, followed by intensive rehabilitation. It resulted in improved mobility, gait and functional status, demonstrating the efficacy of surgical rehabilitation in enhancing his quality of life.

Congenital muscular dystrophies (CMDs) are diverse early-onset conditions affecting skeletal muscle and connective tissue. This group includes collagen VI-related dystrophies such as Ullrich congenital muscular dystrophy (UCMD) and Bethlem myopathy (BM), caused by mutations in the COL6A1, COL6A2 and COL6A3 genes. We report a consanguineous Malian family with three siblings affected by UCMD due to a novel homozygous splice site variant in the COL6A1 gene. After obtaining consent, three affected siblings and their relatives underwent physical examinations by specialists and laboratory tests where possible. DNA was extracted from peripheral blood for genetic testing, including Whole Exome Sequencing (WES). Putative variants were confirmed through Sanger Sequencing and assessed for pathogenicity using in silico tools. The three siblings and their healthy parents, from a consanguineous marriage, presented with early-onset progressive muscle weakness, walking difficulty, proximal motor deficits, severe muscle atrophy, hypotonia, skeletal deformities, joint hyperlaxity, ankyloses at the elbows and knees, keloid scars and dental crowding. No cardiac involvement was detected and creatine kinase (CK) levels were normal. All had low serum calcium levels, treated with oral supplements. Needle myography indicated myopathic patterns. WES identified a novel splice site variant in the first intron of COL6A1 (c.98-1G>C), which segregated with the disease within the family. This variant is predicted to cause exon 2 skipping in COL6A1, with a high CADD score of 33 and Splice AI predicting it as deleterious. We identified a novel COL6A1 variant in a consanguineous family, highlighting the need for further studies in larger African cohorts to enhance genetic epidemiology and prepare for future therapeutic research.

Bethlem myopathy: case report in a 7-year-old patient

485P Familial case of Bethlem myopathy caused by an ALU insertion in COL6A2

Pericytes are a distinct type of cells interacting with endothelial cells in blood vessels and contributing to endothelial barrier integrity. Furthermore, pericytes show mesenchymal stem cell properties. Muscle-derived pericytes can demonstrate both angiogenic and myogenic capabilities. It is well known that regenerative abilities and muscle stem cell potential decline during aging, leading to sarcopenia. Therefore, this study aimed to investigate the potential of pericytes in supporting muscle differentiation and angiogenesis in elderly individuals and in patients affected by Ullrich congenital muscular dystrophy or by Bethlem myopathy, two inherited conditions caused by mutations in collagen VI genes and sharing similarities with the progressive skeletal muscle changes observed during aging. The study characterized pericytes from different age groups and from individuals with collagen VI deficiency by mass spectrometry-based proteomic and bioinformatic analyses. The findings revealed that aged pericytes display metabolic changes comparable to those seen in aging skeletal muscle, as well as a decline in their stem potential, reduced protein synthesis, and alterations in focal adhesion and contractility, pointing to a decrease in their ability to form blood vessels. Strikingly, pericytes from young patients with collagen VI deficiency showed similar characteristics to aged pericytes, but were found to still handle oxidative stress effectively together with an enhanced angiogenic capacity.

BackgroundBethlem Myopathy is a collagen VI-related myopathy presenting as a rare hereditary muscular disorder with progressive muscular weakness and joint contractures. Despite its milder clinical course relative to other myopathies, anaesthetic management can be challenging. High arched palates and fixed flexion deformities may contribute to a difficult airway. A progressive decline in pulmonary function can present later into adulthood. This respiratory decline can carry secondary cardiovascular consequences due to the progressive nature of restrictive lung disease, including right sided heart disease and pulmonary hypertension. We describe a case of a male patient with Bethlem Myopathy undergoing anaesthesia, to contribute to the limited body of literature on this condition and enhance awareness and guidance amongst anaesthesiologists on approaching patients with this condition. This is the first case report within the literature of its kind.Case presentationThis case details a 33-year-old male with Bethlem Myopathy undergoing tonsillectomy. Diagnosed in childhood following developmental delays, the patient had no prior anaesthetic exposure and no family history of anaesthetic complications. Anaesthetic induction was achieved without complications, avoiding depolarizing muscle relaxants and careful airway management. Extreme care was taken in patient positioning to prevent complications. The surgery proceeded without incident and muscle paralysis was reversed with Suggammadex, resulting in no adverse post-operative respiratory complications. The patient was discharged on the first post-operative day without any respiratory or cardiovascular compromise.ConclusionsBethlem Myopathy, while often exhibiting a mild clinical course, can present anaesthetic challenges. Awareness of potential complications including a difficult airway, cardiovascular and respiratory implications as well as the need for specialised monitoring and positioning is crucial to ensure a safe peri-operative course.

Collagen VI-related myopathy spans a clinical continuum from severe Ullrich congenital muscular dystrophy to milder Bethlem myopathy, caused by genetic variants in COL6A1, COL6A2, and COL6A3 genes. Our objective was to report a newly identified patient with the pathogenic variants restricted to a polyadenylation signal in the 3'-untranslated region, which have not been reported in hereditary muscle disease. We performed clinicopathologic diagnosis and analysis using whole-genome and RNA sequencing. We report Ullrich congenital muscular dystrophy caused by a homozygous deletion, c.*198_*466del, which includes a polyadenylation signal in the canonical last exon of the COL6A2 gene. The parents were consanguineously married and had the heterozygous variant, but they were completely asymptomatic. In the patient's muscles, collagen VI was deficient in the sarcolemma, but present in the interstitium, showing the pattern of sarcolemma-specific collagen VI deficiency rather than a pattern of complete deficiency despite the lack of a polyadenylation signal. The RNA sequencing of the patient's muscle showed that alternative last exons were raised in COL6A2 transcript. Our case provides a valuable example of the mechanism of alternative splicing switches for polyadenylation selection.

Collagen VI-related dystrophies (COL6-RD) display a wide spectrum of disease severity and genetic variability ranging from mild Bethlem myopathy (BM) to severe Ullrich congenital muscular dystrophy (UCMD) and the intermediate severities in between with dual modes of inheritance, dominant and recessive. In the current study, next-generation sequencing demonstrated potential variants in the genes coding for the three alpha chains of collagen VI (COL6A1, COL6A2, or COL6A3) in a cohort of Egyptian patients with progressive muscle weakness (n = 23). Based on the age of disease onset and the patient clinical course, subjects were diagnosed as follows: 12 with UCMD, 8 with BM, and 3 with intermediate disease form. Fourteen pathogenic variants, including 5 novel alterations, were reported in the enrolled subjects. They included 3 missense, 3 frameshift, and 6 splicing variants in 4, 3, and 6 families, respectively. In addition, a nonsense variant in a single family and an inframe variant in 3 different families were also detected. Recessive and dominant modes of inheritance were recorded in 9 and 8 families, respectively. According to ACMG guidelines, variants were classified as pathogenic (n = 7), likely pathogenic (n = 4), or VUS (n = 3) with significant pathogenic potential. To our knowledge, the study provided the first report of the clinical and genetic findings of a cohort of Egyptian patients with collagen VI deficiency. Inter- and intra-familial clinical variability was evident among the study cohort.

Background: Collagen VI-related disorder (COLVI-RD) is one of the most common congenital muscular dystrophies. However, data is limited in China. Methods: We conducted a retrospective study at two tertiary centers. Clinical presentations, lab findings (including serum creatine kinase levels), muscle biopsy, and molecular test results for patients diagnosed with definite COLVI-RD were collected. Results: A total of 82 patients were enrolled in the study, including 4 with early-severe Ullrich congenital muscular dystrophy (E-S UCMD) (4.8%), 45 with moderate-progressive Ullrich congenital muscular dystrophy (M-P UCMD, 54.9%), 19 with mild UCMD (23.2%), and 14 with Bethlem myopathy (BM, 17.1%). Feeding difficulty, DDH, and neurogenic damage were more common in E-S and M-P UCMD, while contracture of distal joints, atrophic scars, and hyperkeratosis was more prominent in mild UCMD and BM. Seventy patients harbored 64 pathogenic mutations in COLVI-related genes: 28 patients in COL6A1 gene, 25 patients in the COL6A2 gene, and 17 patients in the COL6A3 gene, among which 33 mutations were novel. Missense and splicing mutations were predominant for COL6A1 and COL6A3 genes, which were mostly located in N-terminus of THD, in a dominant pattern, while mutations in the COL6A2 gene were much more polymorphic, which spread throughout the whole length of the gene, in a dominant or recessive pattern. Immunofluorescence dual labeling of Collagen VI/IV in 44 patients showed complete deficiency of Collagen VI in 10 patients (22.7%), sarcolemma-specific Collagen VI deficiency in 25 patients (56.8%), and normal Collagen VI staining in 9 patients (20.5%). Conclusion: Our study reported the largest cohort of COLVI-RD in China, which showed M-P UCMD was the most common phenotype, followed by mild UCMD and BM. We identified 30 novel mutations and expanded the genetic spectrum. Missense and splicing mutations were predominant for COL6A1 and COL6A3 genes, while mutations in the COL6A2 gene were much more polymorphic. For severe phenotypes, most mutations are sporadic, while some are AD or recessive inherited. For milder phenotypes, sporadic and AD inherited were both common, while only 1 patient with recessive mutations was observed.

Pathogenetic mechanism recognition and proof-of-concept clinical trials were performed in our patients affected by collagen VI-related myopathies. This study, which included 69 patients, aimed to identify innovative clinical data to better design future trials. Among the patients, 33 had Bethlem myopathy (BM), 24 had Ullrich congenital muscular dystrophy (UCMD), 7 had an intermediate phenotype (INTM), and five had myosclerosis myopathy (MM). We obtained data on muscle strength, the degree of contracture, immunofluorescence, and genetics. In our BM group, only one third had a knee extension strength greater than 50% of the predicted value, while only one in ten showed similar retention of elbow flexion. These findings should be considered when recruiting BM patients for future trials. All the MM patients had axial and limb contractures that limited both the flexion and extension ranges of motion, and a limitation in mouth opening. The immunofluorescence analysis of collagen VI in 55 biopsies from 37 patients confirmed the correlation between collagen VI defects and the severity of the clinical phenotype. However, biopsies from the same patient or from patients with the same mutation taken at different times showed a progressive increase in protein expression with age. The new finding of the time-dependent modulation of collagen VI expression should be considered in genetic correction trials.

Mutations within the COL12A1 gene have been linked with the onset of congenital Ullrich muscular dystrophy 2 (UCMD2) and Bethlem myopathy. The severity of the symptoms exhibited is dependent on the mutation's type and whether it is heterozygous or homozygous. We used whole-exome sequencing to identify disease-causing variants in a nine-year-old Iranian patient who had weakness, joint contractures, delayed motor development, and other symptoms. We confirmed the pathogenicity of the identified variant using in silico tools and verified its novelty using various databases. We also performed a co-segregation study and confirmed the presence of the variant in the patient's parents by Sanger sequencing. Our analysis identified a novel homozygous missense variant in the affected patient in COL12A1 (c.8828C > T; p.Pro2943Leu). This is the second reported family with UCMD2 caused by a mutation in COL12A1. Our findings confirm that this mutation results in significantly more severe symptoms than Bethlem myopathy. Our investigation contributes to the expanding body of evidence that links mutations in COL12A1 with UCMD2. Our findings confirm that the homozygous mutation in COL12A1 caused this condition and suggest that genetic testing for this mutation may be useful for diagnosing patients with this disease.

The three major collagen VI genes: COL6A1, COL6A2, and COL6A3 encode microfibrillar components of extracellular matrices in multiple tissues including muscles and tendons. Pathogenic variants in the collagen VI genes cause collagen VI-related dystrophies representing a continuum of conditions from Bethlem myopathy at the milder end to Ullrich congenital muscular dystrophy at the more severe end. Here we describe a pathogenic variant in the COL6A1 gene (NM_001848.3; c.1741-6G>A) found in homozygosity in three patients with Ullrich congenital muscular dystrophy. The patients suffered from severe muscle impairment characterised by proximal weakness, distal hyperlaxity, joint contractures, wheelchair-dependency, and use of nocturnal non-invasive ventilation. The pathogenicity was verified by RNA analyses showing that the variant induced aberrant splicing leading to a frameshift and loss of function. The analyses were in line with immunocytochemistry studies of patient-derived skin fibroblasts and muscle tissue demonstrating impaired secretion of collagen VI into the extracellular matrix. Thereby, we add the variant c.1741-6G>A to the list of pathogenic, recessive, splice variants in COL6A1 causing Ullrich congenital muscular dystrophy. The variant is listed in ClinVar as of “uncertain significance” and “likely benign” and may presumably have been overlooked in other patients.

Objective: To analyze the clinical and genetic characteristics of pediatric patients with dual genetic diagnoses (DGD). Methods: Clinical and genetic data of pediatric patients with DGD from January 2021 to February 2022 in Peking University First Hospital were collected and analyzed retrospectively. Results: Among the 9 children, 6 were boys and 3 were girls. The age of last visit or follow-up was 5.0 (2.7,6.8) years. The main clinical manifestations included motor retardation, mental retardation, multiple malformations, and skeletal deformity. Cases 1-4 were all all boys, showed myopathic gait, poor running and jumping, and significantly increased level of serum creatine kinase. Disease-causing variations in Duchenne muscular dystrophy (DMD) gene were confirmed by genetic testing. The 4 children were diagnosed with DMD or Becker muscular dystrophy combined with a second genetic disease, including hypertrophic osteoarthropathy, spinal muscular atrophy, fragile X syndrome, and cerebral cavernous malformations type 3, respectively. Cases 5-9 were clinically and genetically diagnosed as COL9A1 gene-related multiple epiphyseal dysplasia type 6 combined with NF1 gene-related neurofibromatosis type 1, COL6A3 gene-related Bethlem myopathy with WNT1 gene-related osteogenesis imperfecta type XV, Turner syndrome (45, X0/46, XX chimera) with TH gene-related Segawa syndrome, Chromosome 22q11.2 microduplication syndrome with DYNC1H1 gene-related autosomal dominant lower extremity-predominant spinal muscular atrophy-1, and ANKRD11 gene-related KBG syndrome combined with IRF2BPL gene-related neurodevelopmental disorder with regression, abnormal movement, language loss and epilepsy. DMD was the most common, and there were 6 autosomal dominant diseases caused by de novo heterozygous pathogenic variations. Conclusions: Pediatric patients with coexistence of double genetic diagnoses show complex phenotypes. When the clinical manifestations and progression are not fully consistent with the diagnosed rare genetic disease, a second rare genetic disease should be considered, and autosomal dominant diseases caused by de novo heterozygous pathogenic variation should be paid attention to. Trio-based whole-exome sequencing combining a variety of molecular genetic tests would be helpful for precise diagnosis.

Collagen VI is a heterotrimeric protein expressed in several tissues and involved in the maintenance of cell integrity. It localizes at the cell surface, creating a microfilamentous network that links the cytoskeleton to the extracellular matrix. The heterotrimer consists of three chains encoded by COL6A1, COL6A2 and COL6A3 genes. Recessive and dominant molecular defects cause two main disorders, the severe Ullrich congenital muscular dystrophy and the relatively mild and slowly progressive Bethlem myopathy. We analyzed the clinical aspects, pathological features and mutational spectrum of 15 COL6-mutated patients belonging to our cohort of muscular dystrophy probands. Patients presented a heterogeneous phenotype ranging from severe forms to mild adult-onset presentations. Molecular analysis by NGS detected 14 different pathogenic variants, three of them so far unreported. Two changes, localized in the triple-helical domain of COL6A1, were associated with a more severe phenotype. Histological, immunological and ultrastructural techniques were employed for the validation of the genetic variants; they documented the high variability in COL6 distribution and the extracellular matrix disorganization, highlighting the clinical heterogeneity of our cohort. The combined use of these different technologies is pivotal in the diagnosis of COL6 patients.