CLN1 disease is a fatal neurodegenerative condition caused by deficiency in palmitoyl-protein thioesterase 1 (PPT1), for which no disease-modifying therapy exists. The disease affects the entire central nervous system (CNS), necessitating widespread delivery of therapeutics to the brain and spinal cord. Adeno-associated virus (AAV)-based PPT1 gene therapy delivered intrathecally has been tested in mouse models but has shown limited efficacy due to inadequate brain bioavailability. Here, to maximize therapeutic benefit, PPT1 was engineered for improved cross-correction capabilities, packaged in Spark100, a neurotropic AAV capsid, and administered through intracerebroventricular route in neonatal Ppt1-/- mice. This achieved sustained expression of PPT1 protein across the CNS, including key disease-relevant structures, for up to 15 months. It resulted in long-term therapeutic benefits, such as extended lifespan, preserved neurobehavioral function, and prevention of neuropathology, making treated Ppt1-/- mice nearly indistinguishable from wild type. A translatability study in healthy adult sheep, assessing biodistribution of therapeutic in a large and fully developed brain, showed widespread CNS transduction and PPT1 expression with no adverse effects. These studies demonstrate the potential of this approach for treating CLN1 disease and suggest that a similar platform, using a secreted therapeutic protein, might apply to other neurological disorders with broad CNS deficits.

Children with neurodegenerative disease often have debilitating gastrointestinal symptoms. We hypothesized that this may be due at least in part to underappreciated degeneration of neurons in the enteric nervous system (ENS), the master regulator of bowel function. To test this hypothesis, we evaluated mouse models of neuronal ceroid lipofuscinosis type 1 and 2 (CLN1 and CLN2 disease, respectively), neurodegenerative lysosomal storage disorders caused by deficiencies in palmitoyl protein thioesterase-1 and tripeptidyl peptidase-1, respectively. Both mouse lines displayed slow bowel transit in vivo that worsened with age. Although the ENS appeared to develop normally in these mice, there was a progressive and profound loss of myenteric plexus neurons accompanied by changes in enteric glia in adult mice. Similar pathology was evident in colon autopsy material from a child with CLN1 disease. Neonatal administration of adeno-associated virus-mediated gene therapy prevented bowel transit defects, ameliorated loss of enteric neurons, and extended survival in mice. Treatment after weaning was less effective than treating neonatally but still extended the lifespan of CLN1 disease mice. These data provide proof-of-principle evidence of ENS degeneration in two lysosomal storage diseases and suggest that gene therapy can ameliorate ENS disease, also improving survival.

The neuronal ceroid lipofuscinoses (NCLs) comprise a group of inherited neurodegenerative disorders with thirteen NCL-disease causing genes ceroid lipofuscinosis neuronal (CLN) identified. The purpose of this study was to describe the genetic and clinical characteristics of a cohort of Chinese patients harboring biallelic variants in the CLN genes. We recruited 14 patients from 13 unrelated families who carried biallelic variants in the CLN genes. All patients underwent ophthalmic and systematic evaluations, as well as comprehensive molecular genetic analyses. Reverse transcription polymerase chain reaction (RT-PCR) assays were performed to observe the effect of a novel non-canonical splice-site (NCSS) variant on CLN3 pre-mRNA splicing. Eventually, eight patients were followed up. We detected 21 variants in three CLN genes (CLN3, MFSD8, and PPT1); 13 variants were novel. RT-PCR assays indicated that the NCSS variant c.963-13A>G changed the pre-mRNA splicing, thereby creating an in-frame indel variant p.(W321delinsCPNLR) in CLN3. Diagnoses of neuronal ceroid lipofuscinosis (NCL) and non-syndromic retinal dystrophy (RD) were established in eight patients and six patients, respectively. The patients with NCL showed clinical heterogeneity, from typical phenotypes of CLN3 or CLN7 disease to juvenile- or adult-onset CLN1 disease. All patients experienced early and severe visual loss. A retinal evaluation revealed specific macular striation in 12 of the 14 patients. Patients with variants in the three CLN genes exhibit varied clinical spectra, which might be related to their genotype. All patients presented relatively unique retinal alterations. Our findings point to a crucial need for genetic analysis for the early and accurate diagnosis of patients with NCL.

CLN1 disease (neuronal ceroid lipofuscinosis type 1) is a rare, genetic, neurodegenerative lysosomal storage disorder caused by palmitoyl-protein thioesterase 1 (PPT1) enzyme deficiency. Clinical features include developmental delay, psychomotor regression, seizures, ataxia, movement disorders, visual impairment, and early death. In general, the later the age at symptom onset, the more protracted the disease course. We sought to evaluate current evidence and to develop expert practice consensus to support clinicians who have not previously encountered patients with this rare disease. We searched the literature for guidelines and evidence to support clinical practice recommendations. We surveyed CLN1 disease experts and caregivers regarding their experiences and recommendations, and a meeting of experts was conducted to ascertain points of consensus and clinical practice differences. We found a limited evidence base for treatment and no clinical management guidelines specific to CLN1 disease. Fifteen CLN1 disease experts and 39 caregivers responded to the surveys, and 14 experts met to develop consensus-based recommendations. The resulting management recommendations are uniquely informed by family perspectives, due to the inclusion of caregiver and advocate perspectives. A family-centered approach is supported, and individualized, multidisciplinary care is emphasized in the recommendations. Ascertainment of the specific CLN1 disease phenotype (infantile-, late infantile-, juvenile-, or adult-onset) is of key importance in informing the anticipated clinical course, prognosis, and care needs. Goals and strategies should be periodically reevaluated and adapted to patients' current needs, with a primary aim of optimizing patient and family quality of life.

The neuronal ceroid lipofuscinoses (NCLs) are a group of devastating monogenetic lysosomal disorders that affect children and young adults with no cure or effective treatment currently available. One of the more severe infantile forms of the disease (INCL or CLN1 disease) is due to mutations in the palmitoyl-protein thioesterase 1 (PPT1) gene and severely reduces the child's lifespan to approximately 9 years of age. In order to better translate the human condition than is possible in mice, we sought to produce a large animal model employing CRISPR/Cas9 gene editing technology. Three PPT1 homozygote sheep were generated by insertion of a disease-causing PPT1 (R151X) human mutation into the orthologous sheep locus. This resulted in a morphological, anatomical and biochemical disease phenotype that closely resembles the human condition. The homozygous sheep were found to have significantly reduced PPT1 enzyme activity and accumulate autofluorescent storage material, as is observed in CLN1 patients. Clinical signs included pronounced behavioral deficits as well as motor deficits and complete loss of vision, with a reduced lifespan of 17 ± 1 months at a humanely defined terminal endpoint. Magnetic resonance imaging (MRI) confirmed a significant decrease in motor cortical volume as well as increased ventricular volume corresponding with observed brain atrophy and a profound reduction in brain mass of 30% at necropsy, similar to alterations observed in human patients. In summary, we have generated the first CRISPR/Cas9 gene edited NCL model. This novel sheep model of CLN1 disease develops biochemical, gross morphological and in vivo brain alterations confirming the efficacy of the targeted modification and potential relevance to the human condition.