Project description:An iPSC-derived midbrain dopaminergic neuronal model of aromatic amino acid decarboxylase (AADC) deficiency gives insight into neurodevelopmental disease features

Project description:<p>Beyond motor neuron degeneration, homozygous mutations in the survival motor neuron 1 (SMN1) gene cause multiorgan and metabolic defects in patients with spinal muscular atrophy (SMA). However, the precise biochemical features of these alterations and the age of onset in the brain and peripheral organs remain unclear. Using untargeted NMR-based metabolomics in SMA mice, we identify cerebral and hepatic abnormalities related to energy homeostasis pathways and amino acid metabolism, emerging already at postnatal day 3 (P3) in the liver. Through HPLC, we find that SMN deficiency induces a drop in cerebral norepinephrine levels in overt symptomatic SMA mice at P11, affecting the mRNA and protein expression of key genes regulating monoamine metabolism, including aromatic L-amino acid decarboxylase (AADC), dopamine beta-hydroxylase (DβH) and monoamine oxidase A (MAO-A). In support of the translational value of our preclinical observations, we also discovered that SMN upregulation increases cerebrospinal fluid norepinephrine concentration in Nusinersen-treated SMA1 patients. Our findings highlight a previously unrecognized harmful influence of low SMN levels on the expression of critical enzymes involved in monoamine metabolism, suggesting that SMN-inducing therapies may modulate catecholamine neurotransmission. These results may also be relevant for setting therapeutic approaches to counteract peripheral metabolic defects in SMA. </p>

Project description:Germ cells are regulated by local microenvironments (niches), which secrete instructive cues. Conserved developmental signaling molecules act as niche-derived regulatory factors, yet other types of niche signals remain to be identified. Single-cell RNA-sequencing of sexual planarians revealed niche cells expressing a non-ribosomal peptide synthetase (nrps). Inhibiting nrps led to loss of female reproductive organs and testis hyperplasia. Mass spectrometry detected the dipeptide β-alanyl-tryptamine (BATT), which is associated with reproductive system development and requires nrps and a monoamine-transmitter-synthetic enzyme (AADC) for its production. Exogenous BATT rescued the reproductive defects after nrps or aadc inhibition, restoring fertility. Thus, a non-ribosomal, monoamine-derived peptide provided by niche cells acts as a critical signal to trigger planarian reproductive development. These findings reveal an unexpected function for monoamines in niche-germ cell signaling. Furthermore, given the recently reported role for BATT as a male-derived factor required for reproductive maturation of female schistosomes, these results have important implications for the evolution of parasitic flatworms and suggest a potential role for non-ribosomal peptides as signaling molecules in other organisms.

Project description:Neurons deploy diverse adaptive strategies to ensure survival and neurotransmission amid cellular stress. When these adaptive pathways are overwhelmed, functional impairment or neurodegeneration follows. Here, we report a scenario where stressed neurons actively induce a state of transmissive dormancy as a protective measure. Examination of dopaminergic neurons surviving severe cellular challenges revealed decreased spontaneous activity accompanied by dynamic control of dopamine metabolism through the transcriptional regulator Yin Yang 1 (YY1). Under these conditions, YY1 increases expression of the vesicular monoamine transporter 2, promoting sequestration of dopamine into synaptic vesicles. Following oxidative stress and subsequent DNA damage, YY1 inhibits dopamine synthesis through stabilization of a guanine quadruplex in intron 10 of tyrosine hydroxylase. This cytoprotective response has the potential to drive circuit inactivation and safeguard neurons by minimizing the toxic accumulation of cytosolic dopamine and inducing a state of neuronal dormancy. In essence, neurons appear to actively prioritize viability over functionality.

Project description:Peripheral decarboxylase inhibitors (PDIs) prevent conversion of levodopa to dopamine in the blood by the enzyme aromatic L-amino acid decarboxylase (AADC). Alterations in enzyme activity may contribute to the required higher dosages of levodopa observed in many patients with Parkinson's disease. We evaluated the effect of levodopa/PDI use on serum AADC enzyme activity. Serum AADC enzyme activity was evaluated in three independent cohorts of patients with Parkinson's disease or parkinsonism (n = 301) and compared between patients on levodopa/PDI vs. patients not on this medication. AADC enzyme activity was elevated in 62% of patients on levodopa/PDI treatment, compared to 19% of patients not on levodopa/PDI (median 90 mU/L vs. 50 mU/L, p < 0.001). Patients with elevated AADC activity had longer disease duration and higher doses of levodopa/PDI. These findings may implicate that peripheral AADC induction could underlie a waning effect of levodopa, necessitating dose increases to maintain a sustained therapeutic effect.

Project description:Human aromatic amino acid decarboxylase (AADC) is a pyridoxal 5'-phosphate-dependent enzyme responsible for the biosynthesis of dopamine and serotonin, essential neurotransmitters involved in motor and cognitive abilities. Mutations in its gene lead to AADC deficiency, a monogenic rare neurometabolic childhood parkinsonism characterized by severe motor and neurodevelopmental symptoms. Here, for the first time, we solved the crystal structure of human holoAADC in the internal aldimine (1.9 Å) and in the external aldimine (2.4 Å) of the substrate analog L-Dopa methylester. In this intermediate, the highly flexible AADC catalytic loop (CL) is captured in a closed state contacting all protein domains. In addition, each active site, composed by residues of both subunits, is connected to the other through weak interactions and a central cavity. By combining crystallographic analyses with all-atom and coarse-grained molecular dynamics simulations, SAXS investigations and limited proteolysis experiments, we realized that the functionally obligate homodimeric AADC enzyme in solution is an elongated, asymmetric molecule, where the fluctuations of the CL are coupled to flexibility at the edge between the N-terminal and C-terminal domains. The structural integrity of this peripheral protein region is essential to catalysis, as assessed by both artificial and 37 AADC deficiency pathogenic variants leading to the interpretation that structural dynamics in protein regions far from the active site is essential for CL flexibility and the acquirement of a correct catalytically competent structure. This could represent the molecular basis for pathogenicity prediction in AADC deficiency.

Project description:Background: Epidemiological research indicates that iron deficiency (ID) in infancy correlates with long-term cognitive impairment and behavioral disturbances, despite therapy. However, the mechanisms underlying these effects are unknown. Objective: We investigated how ID affected postweaning behavior and monoamine concentration in rat brains to determine whether ID during the juvenile period affected gene expression and synapse formation in the prefrontal cortex (PFC) and nucleus accumbens (NAcc). Methods: Fischer344/Jcl male rats aged 21–39 days were fed low-iron diets (0.35 mg/kg iron; ID group) or standard AIN-93 G diets (3.5 mg/kg iron; control group). The locomotor activity of male offspring was evaluated by the open field and elevated plus maze tests at ages 8 and 12 weeks. Monoamine concentrations in the PFC, NAcc, caudate-putamen, ventral midbrain, dorsal midbrain, and pons were analyzed. Comprehensive gene expression analysis was performed in the PFC and NAcc at age 13 weeks. Finally, we investigated synaptic density in the PFC and NAcc by synaptophysin immunostaining. Results: Behavioral tests revealed significant interactions between age and iron consumption for the total distance traveled and the distance traveled in the peripheral area (p < 0.05), indicating that ID during the juvenile period affected hyperactivity and that this persisted to adulthood. At age 13 weeks, the ID group had increased levels of both dopamine and the metabolites of dopamine and serotonin in the NAcc. Comprehensive gene expression analysis and immunostaining showed decreased Reelin gene expression (adjusted p < 0.01) and significantly increased spine density in the NAcc in the ID group compared with the control group (p < 0.01). Conclusions: ID during the postweaning juvenile period led to long-term hyperactivity, monoamine disturbance in the brain, and downregulation of Reelin expression in the NAcc despite complete iron repletion. Epigenetic modification of Reelin genes may be involved in synaptic plasticity in the NAcc.

Project description:Previous studies demonstrated that dopaminergic neurons in the substantia nigra pars compacta (SNpc) of mice with null mutations for genes encoding a-synuclein and/or y-synuclein are resistant to 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) toxicity. An original straightforward interpretation of these results was that these proteins are directly involved in the mechanism of MPTP-induced degeneration and this view has become commonly accepted. Here we provide evidence that a plausible explanation of this resistance is not the absence of these synucleins per se but their substitution on the membrane of synaptic vesicles by the third member of the family, b-synuclein. Dopaminergic neurons of mice lacking b-synuclein singularly or in combination with the loss of other synucleins, were sensitive to the toxic effect of MPTP. Dopamine uptake by synaptic vesicles isolated from the striatum of triple a/b/y-synuclein deficient mice was significantly reduced, while reintroduction of b-synuclein either in vivo or in vitro reversed this effect. Proteomic analysis of complexes formed on the surface of synuclein-free synaptic vesicles after addition of recombinant b-synuclein identified multiple integral constituents of these vesicles as well as typically cytosolic proteins, including key enzymes involved in dopamine synthesis, tyrosine hydroxylase (TH) and aromatic L-amino acid decarboxylase (AADC). Therefore, b-synuclein plays a scaffolding role for the assembly of molecular complexes that enhance the ability of synaptic vesicles to uptake and sequester dopamine and other structurally similar molecules, including MPP+. Deficiency of b-synuclein therefore results in the accumulation of MPP+ in the cytosol, where it imposes a damaging effect on presynaptic terminals and ultimately the destruction of dopaminergic neurons.

Project description:Aromatic l-amino acid decarboxylase (AADC) deficiency is a rare inherited disorder that affects neurotransmitter biosynthesis. A DDC founder mutation c.714 + 4A > T (IVS6 + 4A > T) is prevalent in the Chinese population. This study investigated the epidemiology of AADC deficiency in Taiwan by analyzing data from National Taiwan University Hospital (NTUH), a central institution for diagnosing and treating the disease. From January 2000 to March 2023, 77 patients with AADC deficiency visited NTUH. Among them, eight were international patients seeking a second opinion, and another two had one or both non-Chinese parents; all others were ethnically Chinese. The c.714 + 4A > T mutation accounted for 85% of all mutated alleles, and 94% of patients exhibited a severe phenotype. Of the 77 patients, 31 received gene therapy at a mean age of 3.76 years (1.62-8.49) through clinical trials, and their current ages were significantly older than those of the remaining patients. Although the combined incidence of AADC deficiency in this study (1:66491 for 2004 and later) was lower than that reported in newborn screening (1:31997 to 1:42662), case surges coincided with the launch of clinical trials and the implementation of newborn screening. Currently, many young patients are awaiting for treatment.

Project description:This laboratory focuses on the molecular mechanisms of neuropsychiatric and neurodegenerative disorders Our goal is to elucidate mechanisms by which regulated expression of proteoglycans and glycosylation-related genes contribute to neurodegenerative diseases involving the striatum. A number of studies have demonstrated that neural proteoglycans are involved structural organization of the striatum and formation of dopaminergic connections to and from the striatum. Several proteoglycans are also associated with neuronal regeneration and some have been shown to be components of filamentous inclusions found in neurodegenerative disorders. In addition, the localization and proper function of dopamine receptors, which are predominantly expressed in the striatum, are governed by N-linked glycosylation events. Huntingtonís Disease (HD), a progressive neurodegenerative disorder, results in selective degeneration of the striatum. This is caused by a mutation in the protein, huntingtin, however, the mechanisms responsible for neuronal degeneration remain unknown. Similar to the brains of HD patients, HD transgenic mice exhibit huntingtin protein aggregation and nuclear inclusions, selective degeneration of dopamine neurons in the striatum and dopamine receptor dysfunction. In this study, the gene expression patterns of HD transgenic mice were analyzed. Four groups, pre-symptomatic HD mice (6 weeks old), WT control (6 weeks), post symptomatic HD (16 weeks), and WT control (16 weeks), were hybridized and analyzed using the GLYCOv2 array. Each group was hybridized in triplicate.