Pathophysiological Role of Purines and Pyrimidines in Neurodevelopment: Unveiling New Pharmacological Approaches to Congenital Brain Diseases

Fumagalli, Marta; Lecca, Davide; Abbracchio, Maria P.; Ceruti, Stefania

doi:10.3389/fphar.2017.00941

Cited by 92 publications

(76 citation statements)

References 146 publications

(182 reference statements)

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“…Many enzymatic defects involve brain development by intricated mechanisms. 18 Metabolite repair defects are a new growing category in which symptoms are linked to the accumulation of a toxic compound like in L-2-hydroxyglutaric aciduria, 19 or NAXE mutations-NAXE catalyzes the epimerization of NAD(P)HX, thereby avoiding the accumulation of toxic metabolites. 20 Vitamins (transport, and intracellular processing) interfere with many different metabolic pathways where they act as enzymatic cofactors, chaperones or signaling molecules.…”

Section: Accumulation Of Small Moleculesmentioning

confidence: 99%

Proposal for a simplified classification of IMD based on a pathophysiological approach: A practical guide for clinicians

Saudubray

Mochel

Lamari

et al. 2019

J of Inher Metab Disea

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In view of the rapidly expanding number of IMD discovered by next generation sequencing, we propose a simplified classification of IMD that mixes elements from a clinical diagnostic perspective and a pathophysiological approach based on three large categories. We highlight the increasing importance of complex molecule metabolism and its connection with cell biology processes. Small molecule disorders have biomarkers and are divided in two subcategories: accumulation and deficiency. Accumulation of small molecules leads to acute or progressive postnatal “intoxication”, present after a symptom‐free interval, aggravated by catabolism and food intake. These treatable disorders must not be missed! Deficiency of small molecules is due to impaired synthesis of compounds distal to a block or altered transport of essential molecules. This subgroup shares many clinical characteristics with complex molecule disorders. Complex molecules (like glycogen, sphingolipids, phospholipids, glycosaminoglycans, glycolipids) are poorly diffusible. Accumulation of complex molecules leads to postnatal progressive storage like in glycogen and lysosomal storage disorders. Many are treatable. Deficiency of complex molecules is related to the synthesis and recycling of these molecules, which take place in organelles. They may interfere with fœtal development. Most present as neurodevelopmental or neurodegenerative disorders unrelated to food intake. Peroxisomal disorders, CDG defects of intracellular trafficking and processing, recycling of synaptic vesicles, and tRNA synthetases also belong to this category. Only few have biomarkers and are treatable. Disorders involving primarily energy metabolism encompass defects of membrane carriers of energetic molecules as well as cytoplasmic and mitochondrial metabolic defects. This oversimplified classification is connected to the most recent available nosology of IMD.

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Section: Accumulation Of Small Moleculesmentioning

confidence: 99%

Proposal for a simplified classification of IMD based on a pathophysiological approach: A practical guide for clinicians

Saudubray

Mochel

Lamari

et al. 2019

J of Inher Metab Disea

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“…In general, it is interesting that although ADSL is expressed and functions in all tissues, the down-regulation of purine biosynthesis in humans relative to apes, and in humanized mice relative to wild-type mice, is most pronounced in the brain. It is also interesting that mutations in humans that affect enzymes involved in purine metabolism have more pathological consequences in the nervous system than in other organs (Fumagalli et al, 2017;Micheli et al, 2011). It is thus possible that the A429V substitution in ADSL has contributed to human-specific changes in brain development and function.…”

Section: Discussionmentioning

confidence: 99%

Reduced purine biosynthesis in humans after their divergence from Neandertals

Stepanova

Moczulska

Vacano

et al. 2020

Preprint

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We analyze the metabolomes of humans, chimpanzees and macaques in muscle, kidney and three different regions of the brain. Whereas several compounds in amino acid metabolism occur at either higher or lower concentrations in humans than in the other primates, metabolites in oxidative phosphorylation and purine biosynthesis are consistently present in lower concentrations in the brains of humans. In particular, metabolites downstream of adenylosuccinate lyase, which catalyzes two reactions in purine synthesis, occur at lower concentrations in humans. This enzyme carries an amino acid substitution that is present in all humans today but absent in Neandertals. By introducing the modern human substitution into the genomes of mice, as well as the ancestral, Neandertal-like substitution into the genomes of human cells, we show that this amino acid substitution is responsible for much or all of the reduction of de novo synthesis of purines in humans.

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“…Purinergic control of neural development is not limited to early phases of prenatal life, but is also maintained later when it plays a fundamental role in controlling the maturation of glial components such as oligodendrocytes [14]. When brain development is complete, some purinergic mechanisms could be silenced, but could be re-activated in adult brain after injury, suggesting a role for purines in regeneration and self-repair [15,16].…”

Section: Purines During Embryogenesis and Developmentmentioning

confidence: 99%

Guanosine-Based Nucleotides, the Sons of a Lesser God in the Purinergic Signal Scenario of Excitable Tissues

Mancinelli

Fanò-Illic²,

Pietrangelo

et al. 2020

IJMS

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Purines are nitrogen compounds consisting mainly of a nitrogen base of adenine (ABP) or guanine (GBP) and their derivatives: nucleosides (nitrogen bases plus ribose) and nucleotides (nitrogen bases plus ribose and phosphate). These compounds are very common in nature, especially in a phosphorylated form. There is increasing evidence that purines are involved in the development of different organs such as the heart, skeletal muscle and brain. When brain development is complete, some purinergic mechanisms may be silenced, but may be reactivated in the adult brain/muscle, suggesting a role for purines in regeneration and self-repair. Thus, it is possible that guanosine-5′-triphosphate (GTP) also acts as regulator during the adult phase. However, regarding GBP, no specific receptor has been cloned for GTP or its metabolites, although specific binding sites with distinct GTP affinity characteristics have been found in both muscle and neural cell lines. Finally, even if the cross regulation mechanisms between the two different purines (ABP and GBP) are still largely unknown, it is now possible to hypothesize the existence of specific signal paths for guanosine-based nucleotides that are capable of modulating the intensity and duration of the intracellular signal, particularly in excitable tissues such as brain and muscle.

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Pathophysiological Role of Purines and Pyrimidines in Neurodevelopment: Unveiling New Pharmacological Approaches to Congenital Brain Diseases

Cited by 92 publications

References 146 publications

Proposal for a simplified classification of IMD based on a pathophysiological approach: A practical guide for clinicians

Proposal for a simplified classification of IMD based on a pathophysiological approach: A practical guide for clinicians

Reduced purine biosynthesis in humans after their divergence from Neandertals

Guanosine-Based Nucleotides, the Sons of a Lesser God in the Purinergic Signal Scenario of Excitable Tissues

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