Mouse models of NADK2 deficiency analyzed for metabolic and gene expression changes to elucidate pathophysiology

NADK2 encodes the mitochondrial isoform of NAD Kinase, which phosphorylates nicotinamide adenine dinucleotide (NAD). Rare recessive mutations in human NADK2 are associated with a syndromic neurological mitochondrial disease that includes metabolic changes such as hyperlysinemia and 2,4 dienoyl CoA reductase (DECR) deficiency. However, the full pathophysiology resulting from NADK2 deficiency is not known. Here we describe two chemically-induced mouse mutations in Nadk2, S326L and S330P, which cause a severe neuromuscular disease and shorten lifespan. The S330P allele was characterized in detail and shown to have marked denervation of neuromuscular junctions by 5 weeks of age and muscle atrophy by 11 weeks of age. Cerebellar Purkinje cells also showed progressive degeneration in this model. Transcriptome profiling on brain and muscle was performed at early and late disease stages. In addition, metabolomic profiling was performed on brain, muscle, liver, and spinal cord at the same ages. Combined transcriptomic and metabolomic analyses identified hyperlysinemia, DECR deficiency, and generalized metabolic dysfunction in Nadk2 mutant mice, indicating relevance to the human disease. We compared findings from the Nadk model to equivalent RNAseq and metabolomic datasets from a mouse model of infantile neuroaxonal dystrophy, caused by recessive mutations in Pla2g6. This enabled us to identify disrupted biological processes that are common between these mouse models of neurological disease, such as translation, and those processes that are gene-specific such as glycolysis and acetylcholine binding. These findings improve our understanding of the pathophysiology of both Nadk2 and Pla2g6 mutations, as well as pathways common to neuromuscular/neurodegenerative diseases.

Insights into Lewy body disease from rare neurometabolic disorders

Professor Kurt Jellinger is well known for his seminal work on the neuropathology of age-associated neurodegenerative disorders, particularly Lewy body diseases. However, it is less well known that he also contributed important insights into the neuropathological features of several paediatric neurometabolic diseases, including Alpers–Huttenlocher syndrome, a syndrome of mitochondrial disease caused by POLG mutations, and infantile neuroaxonal dystrophy, a phenotype resulting from PLA2G6 mutations. Despite these rare diseases occurring in early life, they share many important pathological overlaps with age-associated Lewy body disease, particularly dysregulation of α-synuclein. In this review, we describe several neurometabolic diseases linked to Lewy body disease mechanisms, and discuss the wider context to pathological overlaps between neurometabolic and Lewy body diseases. In particular, we will focus on how understanding disease mechanisms in neurometabolic disorders with dysregulated α-synuclein may generate insights into predisposing factors for α-synuclein aggregation in idiopathic Lewy body diseases.

Fetal neuroaxonal dystrophy: a further etiology of fetal akinesia

Neuroaxonal Dystrophies (NAD) are neurodegenerative diseases characterized by axonal “spheroids” occurring in different age groups. The identification of mutations delineated new molecular entities in these disorders. We report neuropathological data of a new form of NAD, characterized by a precocious prenatal onset, different from classical and conatal Infantile Neuroaxonal Dystrophy (INAD).We studied 5 fetuses examined after pregnancy termination and 2 term neonates deceased just after birth, 4/7 born from consanguineous parents. All subjects presented severe fetal akinesia sequence with microcephaly. In 4/7 cases, a molecular study was performed. In all cases, “spheroids” with typical immunohistochemical features were identified, with variable spreading in the central and peripheral nervous system. Basal ganglia, brainstem, cerebellum, and spinal cord involvement was constant. Associated CNS malformations, unusual in INAD, were associated including hydrocephalus (2), callosal agenesis/hypoplasia (2), olfactory agenesis (1), cortical (3) and retinal (1) anomalies. None of the cases demonstrated mutations in PLA2G6, found in INAD. The clinical and neuropathological features of these fetal cases are different from those of “classical” INAD. The absence of mutations in PLA2G6, in addition, suggests that the fetal NAD is a new entity, distinct from INAD, with different molecular basis. Associated malformations suggest a wide phenotypic spectrum and probable genetic heterogeneity. Finally, fetal NAD is an additional etiology of fetal akinesia.LEARNING OBJECTIVESThis presentation will enable the learner to:Diagnose this rare form of neuroaxonal dystrophy (NAD) occurring precociously, in the fetal life, as soon as the second trimester, different from the infantile form of NAD. 1.Describe the phenotypic spectrum of this fetal NAD; fetal akinesia sequence, microcephaly and various brain malformations, different from the “classical” and conatal forms of infantile neuroaxonal dystrophy.2.Consider this etiology in the diagnosis of fetal akinesia sequence.

Rare health conditions 45: Holt-Oram syndrome, infantile neuroaxonal dystrophy, query (Q) fever

The purpose of this series is to highlight a range of rare health conditions. Rare health conditions are those that affect no more and usually fewer than 1 person in every 2000 and many healthcare assistants and nurses will encounter some of these conditions given the high number of them. This 45th article will explore three of these conditions: Holt-Oram syndrome, infantile neuroaxonal dystrophy and query (Q) fever.

Initial survey of PLA2G6 missense variant causing neuroaxonal dystrophy in Papillon dogs in North America and Europe

Background An autosomal recessive, rapidly progressive degenerative neuropathy known as infantile neuroaxonal dystrophy (NAD) was originally reported in Papillion puppies in 1995. In 2015, a causative missense variant in the PLA2G6 gene was identified in three affected puppies. Archived samples from Papillons clinically diagnosed with NAD prior to 2015 as well as samples obtained from 660 Papillons from North America and Europe between 2015 and 2017 were screened for the presence of this PLA2G6 gene variant (XM_022424454.1:c.1579G > A) using a TaqMan assay. Results Archived samples from affected puppies diagnosed prior to 2015 and three more recently acquired samples from Papillons clinically affected with NAD were all homozygous for the variant. SIFT analysis predicts that the PLA2G6 missense substitution (XP_022280162.1:p.Ala527Thr) will not be tolerated in the iPLA2β protein. Notably, 17.5% of the 660 tested Papillons were heterozygotes, resulting in a variant allele frequency of 0.092 in this initial survey. Since then, screening for NAD in Papillons by at least 10 other laboratories and data from the Health Committee of Papillon Club of America gathered between 2017 and 2019 reveal a variant allele frequency of 0.047. Conclusions This survey and data from other laboratories documents the widespread presence of the PLA2G6 variant in the Papillon population in North America and Europe. Despite the apparent declining prevalence of the PLA2G6 variant, screening of Papillons intended for breeding is still recommended to avoid inadvertent production of puppies with infantile NAD.

Siblings with Infantile Neuroaxonal Dystrophy

A 2 years 3 months male toddler with motor delay and his female sibling with history of marked global developmental regression following an intercurrent febrile illness were both noted to have phospholipase A2G6 (PLA2G6) mutation, confirming the diagnosis of infantile neuroaxonal dystrophy (INAD). This case report attempts to familiarize readers with the pleomorphic presentation of INAD and the role of early clinical identification, examination, and prompt genetic testing in establishing a diagnosis.

The Infantile Neuroaxonal Dystrophy Rating Scale (INAD-RS)

ObjectiveTo create and validate a clinical outcome assessment for Infantile Neuroaxonal Dystrophy (INAD)BackgroundINAD is an autosomal recessive neurogenetic disorder caused by biallelic pathogenic variants in PLA2G6. The downstream enzyme, iPLA2, plays a critical role in cell membrane homeostasis by helping to regulate levels of phospholipids. The clinical presentation occurs between 6 months and 3 years with global developmental regression, hypotonia, and progressive spastic tetraparesis. Progression is often rapid, resulting in severe spasticity, visual impairment, and cognitive decline, with many children not surviving past the first decade of life. To date, no accepted tool for assessing the severity of INAD exists; other commonly used scales (e.g. CHOP-INTEND, Modified Ashworth, Hammersmith Functional Motor Scale) do not accurately gauge the current severity of INAD, nor are they sensitive/specific enough to monitor disease progression. Finally, these other scales are not appropriate, because they do not address the combination of CNS, peripheral nerve, and visual pathology that occurs in children with INADDesign/MethodsWe have developed and validated a structured neurological examination for INAD (scored out of 80). The examination includes five main categories of pediatric developmental evaluation: 1) gross motor-and-truncal-stability skills, 2) fine motor skills, 3) bulbar function, 4) ocular function, 5) temporo-frontal function, and a functional evaluation of the autonomic nervous system. A cohort of patients diagnosed with INAD were followed prospectively to validate the score against disease severity and disease progression.ResultsWe show significant correlation between the total neurological assessment score and months since symptom onset with a statistically significant (p = 6.7 × 10− 07) correlation between assessment score and disease onset. As hypothesized, the coefficient of months-since-symptom-onset is strongly negative, indicating a negative correlation between total score and months since symptom onset.ConclusionWe have developed and validated a novel neurological assessment score in INAD that demonstrates strong correlation with disease severity and disease progression.