Osteoclasts are essential for bone resorption, playing a crucial role in skeletal development, homeostasis, and remodeling. Their differentiation depends on the RANK receptor encoded by the TNFRSF11A gene, with defects in this gene linked to osteoclast-poor sclerosing skeletal dysplasias. This report presents a 37-yr-old woman with normal height, valgus deformities that were treated surgically, frequent fractures, scoliosis, mildly elevated BMD, sclerotic diaphyseal bone, and metaphyseal widening. Initially suspected of having dysosteosclerosis, her diagnosis shifted toward Pyle disease due to the valgus deformity and prominent metaphyseal widening and translucency. Genetic analysis identified 2 pathogenic TNFRSF11A variants: a nonsense mutation c.1093G>T, p.(Glu365*) and a frameshift mutation c.1266_1268delinsCC, p.(Leu422Phefs*104). Thus, genetic and clinical assessment converged on the diagnosis of a mild form of dysosteosclerosis. Both mutations introduced premature stop codons but escaped complete nonsense-mediated decay, potentially permitting residual protein function. Analysis of patient-derived osteoclasts cultured on glass surfaces showed partial differentiation. However, in vitro resorptive function was strongly impaired, which was clinically reflected by reduced serum concentration of the bone resorption marker CTx. Despite this impairment, the retained residual resorptive function likely explains the patient's relatively mild clinical presentation. These findings underscore the complex genetic interactions that affect osteoclast function, leading to a spectrum of phenotypes in osteoclast-related bone disorders.

The SLC29A3 gene, which encodes a nucleoside transporter protein, is primarily located in intracellular membranes. The mutations in this gene can give rise to various clinical manifestations, including H syndrome, dysosteosclerosis, Faisalabad histiocytosis, and pigmented hypertrichosis with insulin-dependent diabetes. The aim of this study is to present two Iranian patients with H syndrome and to describe a novel start-loss mutation in SLC29A3 gene. In this study, we employed whole-exome sequencing (WES) as a method to identify genetic variations that contribute to the development of H syndrome in a 16-year-old girl and her 8-year-old brother. These siblings were part of an Iranian family with consanguineous parents. To confirmed the pathogenicity of the identified variant, we utilized in-silico tools and cross-referenced various databases to confirm its novelty. Additionally, we conducted a co-segregation study and verified the presence of the variant in the parents of the affected patients through Sanger sequencing. In our study, we identified a novel start-loss mutation (c.2T > A, p.Met1Lys) in the SLC29A3 gene, which was found in both of two patients. Co-segregation analysis using Sanger sequencing confirmed that this variant was inherited from the parents. To evaluate the potential pathogenicity and novelty of this mutation, we consulted various databases. Additionally, we employed bioinformatics tools to predict the three-dimensional structure of the mutant SLC29A3 protein. These analyses were conducted with the aim of providing valuable insights into the functional implications of the identified mutation on the structure and function of the SLC29A3 protein. Our study contributes to the expanding body of evidence supporting the association between mutations in the SLC29A3 gene and H syndrome. The molecular analysis of diseases related to SLC29A3 is crucial in understanding the range of variability and raising awareness of H syndrome, with the ultimate goal of facilitating early diagnosis and appropriate treatment. The discovery of this novel biallelic variant in the probands further underscores the significance of utilizing genetic testing approaches, such as WES, as dependable diagnostic tools for individuals with this particular condition.

We report three siblings homozygous for CSF1R variant c.1969 + 115_1969 + 116del to expand the phenotype of "brain abnormalities, neurodegeneration, and dysosteosclerosis" (BANDDOS) and discuss its link with "adult leukoencephalopathy with axonal spheroids and pigmented glia" (ALSP), caused by heterozygous CSF1R variants. We evaluated medical, radiological, and laboratory findings and reviewed the literature. Patients presented with developmental delay, therapy-resistant epilepsy, dysmorphic features, and skeletal abnormalities. Secondary neurological decline occurred from 23 years in sibling one and from 20 years in sibling two. Brain imaging revealed multifocal white matter abnormalities and calcifications during initial disease in siblings two and three. Developmental brain anomalies, seen in all three, were most severe in sibling two. During neurological decline in siblings one and two, the leukoencephalopathy was progressive and had the MRI appearance of ALSP. Skeletal survey revealed osteosclerosis, most severe in sibling three. Blood markers, monocytes, dendritic cell subsets, and T-cell proliferation capacity were normal. Literature review revealed variable initial disease and secondary neurological decline. BANDDOS presents with variable dysmorphic features, skeletal dysplasia, developmental delay, and epilepsy with on neuro-imaging developmental brain anomalies, multifocal white matter abnormalities, and calcifications. Secondary neurological decline occurs with a progressive leukoencephalopathy, in line with early onset ALSP. Despite the role of CSF1R signaling in myeloid development, immune deficiency is absent. Phenotype varies within families; skeletal and neurological manifestations may be disparate. The spectrum of CSF1R-related disorder ranges from early-onset disease (age <18 years) to late-onset disease (age ≥18 years). Early-onset disease is associated with hypotonia, delayed acquisition of developmental milestones, and non-neurologic manifestations (such as skeletal abnormalities); both early- and late-onset disease have similar neurodegenerative involvement. Most affected individuals eventually become bedridden with spasticity, rigidity, and loss of the ability to walk. They lose speech and voluntary movement and appear to be generally unaware of their surroundings. The last stage of disease progresses to a vegetative state with presence of primitive reflexes, such as visual and tactile grasp, mouth-opening reflex, and sucking reflex. Death most commonly results from pneumonia or other infections. About 500 individuals with CSF1R-related disorder have been reported to date. The diagnosis of CSF1R-related disorder is established in a proband with suggestive findings and a heterozygous CSF1R pathogenic variant or biallelic CSF1R pathogenic variants identified by molecular genetic testing. Treatment of manifestations: Multidisciplinary care by specialists in neurology, psychotherapy, neuropsychological rehabilitation, physical therapy, occupational therapy, speech-language therapy, social services for family support, and genetic counseling. Surveillance: Monitoring of existing manifestations, the individual's response to supportive care, and the emergence of new manifestations as specified by the multidisciplinary care providers. Agents/circumstances to avoid: For individuals with gait problems and cognitive decline, sedatives, antipsychotics, and other medications that may decrease alertness and increase the risk of falling should be used cautiously. Early-onset CSF1R-related disorder is typically caused by biallelic pathogenic variants and inherited in an autosomal recessive manner; rarely, early-onset CSF1R-related disorder may be caused by a heterozygous pathogenic variant. Late-onset CSF1R-related disorder is typically caused by a heterozygous pathogenic variant and inherited in an autosomal dominant manner; rarely, late-onset CSF1R-related disorder may be caused by biallelic CSF1R pathogenic variants. While biallelic pathogenic variants are usually associated with early-onset disease and heterozygous pathogenic variants are usually associated with late-onset disease, definitive prediction of phenotype based on CSF1R genotype is not possible at this time. Autosomal recessive inheritance: The parents of an individual with CSF1R-related disorder caused by biallelic pathogenic variants are presumed to be heterozygous for a CSF1R pathogenic variant. If both parents are known to be heterozygous for a pathogenic variant, each sib of an affected individual has at conception a 25% chance of being affected, a 50% chance of being heterozygous, and a 25% chance of inheriting neither of the familial CSF1R pathogenic variants. Sibs who inherit the same biallelic CSF1R pathogenic variants do not necessarily have the same clinical manifestations early in the disease course; however, in the end stage, all individuals with CSF1R-related disorder typically have devastating neurologic involvement. The heterozygous sibs of an individual with CSF1R-related disorder caused by biallelic pathogenic variants are typically asymptomatic. Autosomal dominant inheritance: Many individuals with CSF1R-related disorder caused by a heterozygous pathogenic variant have an affected parent. Some individuals with CSF1R-related disorder caused by a heterozygous pathogenic variant represent a simplex case; such individuals may have the disorder as the result of a pathogenic variant that occurred de novo in the proband; a pathogenic variant inherited from a mosaic parent; or a pathogenic variant inherited from an asymptomatic heterozygous parent. Each child of an individual with a heterozygous CSF1R pathogenic variant has a 50% chance of inheriting the pathogenic variant. Family members who are heterozygous for the same CSF1R pathogenic variant do not necessarily have the same clinical manifestations early in the disease course; however, in the end stage, all individuals with CSF1R-related disorder typically have devastating neurologic involvement. Once the CSF1R pathogenic variant(s) have been identified in an affected family member, predictive testing for at-risk relatives and prenatal and preimplantation genetic testing for CSF1R-related disorder are possible.

Recent developments in adult-onset leukoencephalopathy with axonal spheroids and pigmented glia (ALSP) and other disorders due to CSF1R variants led to the emergence of symptomatic and prophylactic treatment options. The growing body of knowledge on genetics, pathomechanisms, clinical, and radiological features in patients harboring CSF1R variants challenges the current concepts and terminology to define the disorders, in addition to bringing up new questions on genotype-phenotype relationships. Therefore, this paper discusses the present complexities and challenges in the research on ALSP due to CSF1R variants. We illustrate our new concepts with two cases that are compound heterozygotes for CSF1R variants. Although their clinical phenotype resembles ALSP, the diagnosis of brain abnormalities, neurodegeneration, and dysosteosclerosis (BANDDOS) seems more appropriate based on their genotype. As the diagnostic classification dilemma cannot be resolved with currently used concepts and terminology on these disorders, we propose a new nomenclature of "CSF1R-related disorder" with subcategories of "early-onset (<18 years old) and late-onset (≥18 years old) forms". We highlight the heterogeneity of CSF1R variant carriers in age at onset, spectrum and severity of clinical presentation, and progression rate, even within the same family. We argue that multiple factors, including genetic architecture and environment, converge to result in an individual's disease phenotype.

CSF1R mutations cause autosomal-dominant CSF1R-related leukoencephalopathy with axonal spheroids and pigmented glia (CSF1R-ALSP) and autosomal-recessive brain abnormalities, neurodegeneration, and dysosteosclerosis (BANDDOS). The former is increasingly recognized, and disease-modifying therapy was introduced; however, literature is scarce on the latter. This review analyzes BANDDOS and discusses similarities and differences with CSF1R-ALSP.We systematically retrieved and analyzed the clinical, genetic, radiological, and pathological data on the previously reported and our cases with BANDDOS. We identified 19 patients with BANDDOS (literature search according to the PRISMA 2020 guidelines: n = 16, our material: n = 3). We found 11 CSF1R mutations, including splicing (n = 3), missense (n = 3), nonsense (n = 2), and intronic (n = 2) variants and one inframe deletion. All mutations disrupted the tyrosine kinase domain or resulted in nonsense-mediated mRNA decay. The material is heterogenous, and the presented information refers to the number of patients with sufficient data on specific symptoms, results, or performed procedures. The first symptoms occurred in the perinatal period (n = 5), infancy (n = 2), childhood (n = 5), and adulthood (n = 1). Dysmorphic features were present in 7/17 cases. Neurological symptoms included speech disturbances (n = 13/15), cognitive decline (n = 12/14), spasticity/rigidity (n = 12/15), hyperactive tendon reflex (n = 11/14), pathological reflexes (n = 8/11), seizures (n = 9/16), dysphagia (n = 9/12), developmental delay (n = 7/14), infantile hypotonia (n = 3/11), and optic nerve atrophy (n = 2/7). Skeletal deformities were observed in 13/17 cases and fell within the dysosteosclerosis - Pyle disease spectrum. Brain abnormalities included white matter changes (n = 19/19), calcifications (n = 15/18), agenesis of corpus callosum (n = 12/16), ventriculomegaly (n = 13/19), Dandy-Walker complex (n = 7/19), and cortical abnormalities (n = 4/10). Three patients died in infancy, two in childhood, and one case at unspecified age. A single brain autopsy evidenced multiple brain anomalies, absence of corpus callosum, absence of microglia, severe white matter atrophy with axonal spheroids, gliosis, and numerous dystrophic calcifications.In conclusion, BANDDOS presents in the perinatal period or infancy and has a devastating course with congenital brain abnormalities, developmental delay, neurological deficits, osteopetrosis, and dysmorphic features. There is a significant overlap in the clinical, radiological, and neuropathological aspects between BANDDOS and CSF1R-ALSP. As both disorders are on the same continuum, there is a window of opportunity to apply available therapy in CSF1R-ALSP to BANDDOS.