CoA synthase plays a critical role in neurodevelopment and neurodegeneration.

Coenzyme A (CoA), which is widely distributed and vital for cellular metabolism, is a critical molecule essential in both synthesizing and breaking down key energy sources in the body. Inborn errors of metabolism in the cellular de novo biosynthetic pathway of CoA have been linked to human genetic disorders, emphasizing the importance of this pathway. The COASY gene encodes the bifunctional enzyme CoA synthase, which catalyzes the last two reactions of the CoA biosynthetic pathway and serves as one of the rate-limiting components of the pathway. Recessive variants of this gene cause an exceptionally rare and devastating disease called COASY protein-associated neurodegeneration (CoPAN) while complete loss-of-function variants in COASY have been identified in fetuses/neonates with Pontocerebellar Hypoplasia type 12 (PCH 12). Understanding why the different symptoms emerge in these disorders and what determines the development of one syndrome over the other is still not achieved. To shed light on the pathogenesis, we generated a new conditional animal model in which Coasy was deleted under the control of the human GFAP promoter. We used this mouse model to investigate how defects in the CoA biosynthetic pathway affect brain development. This model showed a broad spectrum of severity of the in vivo phenotype, ranging from very short survival (less than 2 weeks) to normal life expectancy in some animals. Surviving mice displayed a behavioral phenotype with sensorimotor defects. Ex vivo histological analysis revealed variable but consistent cerebral and cerebellar cortical hypoplasia, in parallel with a broad astrocytic hyper-proliferation in the cerebral cortex. In addition, primary astrocytes derived from this model exhibited lipid peroxidation, iron dyshomeostasis, and impaired mitochondrial respiration. Notably, Coasy ablation in radial glia and astrocytic lineage triggers abnormal neuronal development and chronic neuroinflammation, offering new insights into disease mechanisms.

Emerging variants, unique phenotypes, and transcriptomic signatures: an integrated study of COASY-associated diseases.

OBJECTIVE: COASY, the gene encoding the bifunctional enzyme CoA synthase, which catalyzes the last two reactions of cellular de novo coenzyme A (CoA) biosynthesis, has been linked to two exceedingly rare autosomal recessive disorders, such as COASY protein-associated neurodegeneration (CoPAN), a form of neurodegeneration with brain iron accumulation (NBIA), and pontocerebellar hypoplasia type 12 (PCH12). We aimed to expand the phenotypic spectrum and gain insights into the pathogenesis of COASY-related disorders. METHODS: Patients were identified through targeted or exome sequencing. To unravel the molecular mechanisms of disease, RNA sequencing, bioenergetic analysis, and quantification of critical proteins were performed on fibroblasts. RESULTS: We identified five new individuals harboring novel COASY variants. While one case exhibited classical CoPAN features, the others displayed atypical symptoms such as deafness, language and autism spectrum disorders, brain atrophy, and microcephaly. All patients experienced epilepsy, highlighting its potential frequency in COASY-related disorders. Fibroblast transcriptomic profiling unveiled dysregulated expression in genes associated with mitochondrial respiration, responses to oxidative stress, transmembrane transport, various cellular signaling pathways, and protein translation, modification, and trafficking. Bioenergetic analysis revealed impaired mitochondrial oxygen consumption in COASY fibroblasts. Despite comparable total CoA levels to control cells, the amounts of mitochondrial 4'-phosphopantetheinylated proteins were significantly reduced in COASY patients. INTERPRETATION: These results not only extend the clinical phenotype associated with COASY variants but also suggest a continuum between CoPAN and PCH12. The intricate interplay of altered cellular processes and signaling pathways provides valuable insights for further research into the pathogenesis of COASY-associated diseases.

Mitochondrial Transplantation in Mitochondrial Medicine: Current Challenges and Future Perspectives.

Mitochondrial diseases (MDs) are inherited genetic conditions characterized by pathogenic mutations in nuclear DNA (nDNA) or mitochondrial DNA (mtDNA). Current therapies are still far from being fully effective and from covering the broad spectrum of mutations in mtDNA. For example, unlike heteroplasmic conditions, MDs caused by homoplasmic mtDNA mutations do not yet benefit from advances in molecular approaches. An attractive method of providing dysfunctional cells and/or tissues with healthy mitochondria is mitochondrial transplantation. In this review, we discuss what is known about intercellular transfer of mitochondria and the methods used to transfer mitochondria both in vitro and in vivo, and we provide an outlook on future therapeutic applications. Overall, the transfer of healthy mitochondria containing wild-type mtDNA copies could induce a heteroplasmic shift even when homoplasmic mtDNA variants are present, with the aim of attenuating or preventing the progression of pathological clinical phenotypes. In summary, mitochondrial transplantation is a challenging but potentially ground-breaking option for the treatment of various mitochondrial pathologies, although several questions remain to be addressed before its application in mitochondrial medicine.

Subsyndromal delirium and its determinants in elderly patients hospitalized for acute medical illness.

BACKGROUND: In older individuals, acute medical illnesses and admission to hospital are often associated with a deterioration of cognitive status, also in the absence of dementia and full-blown delirium. We evaluated the prevalence of subsyndromal delirium (SSD) and its correlates in a sample of elderly medical inpatients. METHODS: From 763 consecutive inpatients, 325 participants with known dementia or delirium were excluded, whereas 438 (mean age: 80.6 years; female participants: 60.1%) were enrolled. SSD was diagnosed within 48 hour from admission, when at least two DSM-IV delirium criteria including disorientation, attention or memory deficit, altered level of consciousness, or perceptual disturbances were present. Cognitive performance was evaluated by Mini Mental Status Examination (MMSE). General, clinical, and laboratory parameters were also registered. RESULTS: One hundred and sixty-six patients (37%) had SSD. Compared with controls, SSD patients were older individuals, had less formal education, higher comorbidity, lower hemoglobin/lymphocytes counts, and higher creatinine levels. A trend toward higher prevalence of previous stroke and widowhood was observed. A MMSE score of less than 24/30 identified SSD with 88% sensitivity and 78% specificity. In SSD patients, MMSE independently correlated with years of education, high-sensitivity C reactive protein levels, and O2 arterial saturation (model adjusted r (2) = 0.30, p = .001); conversely, only years of education were associated with MMSE in controls (adjusted r (2) = 0.06, p = .01). CONCLUSIONS: Our data suggest that SSD is common in hospitalized older medical inpatients, and low MMSE score might be useful for identification of participants at risk of SSD. Current inflammatory response and reduced O2 arterial saturation were the only independent determinants of cognitive performance in SSD patients.