Serotonin effects on human iPSC-derived neural cell functions: from mitochondria to depression.

Depression's link to serotonin dysregulation is well-known. The monoamine theory posits that depression results from impaired serotonin activity, leading to the development of antidepressants targeting serotonin levels. However, their limited efficacy suggests a more complex cause. Recent studies highlight mitochondria as key players in depression's pathophysiology. Mounting evidence indicates that mitochondrial dysfunction significantly correlates with major depressive disorder (MDD), underscoring its pivotal role in depression. Exploring the serotonin-mitochondrial connection, our study investigated the effects of chronic serotonin treatment on induced-pluripotent stem cell-derived astrocytes and neurons from healthy controls and two case study patients. One was a patient with antidepressant non-responding MDD ("Non-R") and another had a non-genetic mitochondrial disorder ("Mito"). The results revealed that serotonin altered the expression of genes related to mitochondrial function and dynamics in neurons and had an equalizing effect on calcium homeostasis in astrocytes, while ATP levels seemed increased. Serotonin significantly decreased cytosolic and mitochondrial calcium in neurons. Electrophysiological measurements evidenced that serotonin depolarized the resting membrane potential, increased both sodium and potassium current density and ultimately improved the overall excitability of neurons. Specifically, neurons from the Non-R patient appeared responsive to serotonin in vitro, which seemed to improve neurotransmission. While it is unclear how this translates to the systemic level and AD resistance mechanisms are not fully elucidated, our observations show that despite his treatment resistance, this patient's cortical neurons are responsive to serotonergic signals. In the Mito patient, evidence suggested that serotonin, by increasing excitability, exacerbated an existing hyperexcitability highlighting the importance of considering mitochondrial disorders in patients with MDD, and avoiding serotonin-increasing medication. Taken together, our findings suggested that serotonin positively affects calcium homeostasis in astrocytes and increases neuronal excitability. The latter effect must be considered carefully, as it could have beneficial or detrimental implications based on individual pathologies.

Mitochondrial and Cellular Function in Fibroblasts, Induced Neurons, and Astrocytes Derived from Case Study Patients: Insights into Major Depression as a Mitochondria-Associated Disease.

The link between mitochondria and major depressive disorder (MDD) is increasingly evident, underscored both by mitochondria's involvement in many mechanisms identified in depression and the high prevalence of MDD in individuals with mitochondrial disorders. Mitochondrial functions and energy metabolism are increasingly considered to be involved in MDD's pathogenesis. This study focused on cellular and mitochondrial (dys)function in two atypical cases: an antidepressant non-responding MDD patient ("Non-R") and another with an unexplained mitochondrial disorder ("Mito"). Skin biopsies from these patients and controls were used to generate various cell types, including astrocytes and neurons, and cellular and mitochondrial functions were analyzed. Similarities were observed between the Mito patient and a broader MDD cohort, including decreased respiration and mitochondrial function. Conversely, the Non-R patient exhibited increased respiratory rates, mitochondrial calcium, and resting membrane potential. In conclusion, the Non-R patient's data offered a new perspective on MDD, suggesting a detrimental imbalance in mitochondrial and cellular processes, rather than simply reduced functions. Meanwhile, the Mito patient's data revealed the extensive effects of mitochondrial dysfunctions on cellular functions, potentially highlighting new MDD-associated impairments. Together, these case studies enhance our comprehension of MDD.

Induced neural progenitor cells and iPS-neurons from major depressive disorder patients show altered bioenergetics and electrophysiological properties.

The molecular pathomechanisms of major depressive disorder (MDD) are still not completely understood. Here, we follow the hypothesis, that mitochondria dysfunction which is inevitably associated with bioenergetic disbalance is a risk factor that contributes to the susceptibility of an individual to develop MDD. Thus, we investigated molecular mechanisms related to mitochondrial function in induced neuronal progenitor cells (NPCs) which were reprogrammed from fibroblasts of eight MDD patients and eight non-depressed controls. We found significantly lower maximal respiration rates, altered cytosolic basal calcium levels, and smaller soma size in NPCs derived from MDD patients. These findings are partially consistent with our earlier observations in MDD patient-derived fibroblasts. Furthermore, we differentiated MDD and control NPCs into iPS-neurons and analyzed their passive biophysical and active electrophysiological properties to investigate whether neuronal function can be related to altered mitochondrial activity and bioenergetics. Interestingly, MDD patient-derived iPS-neurons showed significantly lower membrane capacitance, a less hyperpolarized membrane potential, increased Na+ current density and increased spontaneous electrical activity. Our findings indicate that functional differences evident in fibroblasts derived from MDD patients are partially present after reprogramming to induced-NPCs, could relate to altered function of iPS-neurons and thus might be associated with the aetiology of major depressive disorder.

Impact of Translocator Protein 18 kDa (TSPO) Deficiency on Mitochondrial Function and the Inflammatory State of Human C20 Microglia Cells.

Microglia are the resident immune cells of the central nervous system. Upon stimulus presentation, microglia polarize from a resting to an activated state. Microglial translocator protein 18 kDa (TSPO) is considered a marker of inflammation. Here, we characterized the role of TSPO by investigating the impact of TSPO deficiency on human microglia. We used TSPO knockout (TSPO-/-) variants of the human C20 microglia cell line. We found a significant reduction in the TSPO-associated protein VDAC1 in TSPO-/- cells compared to control cells. Moreover, we assessed the impact of TSPO deficiency on calcium levels and the mitochondrial membrane potential. Cytosolic and mitochondrial calcium concentrations were increased in TSPO-/- cell lines, whereas the mitochondrial membrane potential tended to be lower. Assessment of the mitochondrial DNA copy number via RT-PCR revealed a decreased amount of mtDNA in the TSPO-/- cells when compared to controls. Moreover, the metabolic profiles of C20 cells were strongly dependent on the glycolytic pathway. However, TSPO depletion did not affect the cellular metabolic profile. Measurement of the mRNA expression levels of the pro-inflammatory mediators revealed an attenuated response to pro-inflammatory stimuli in TSPO-depleted cells, implying a role for the TSPO protein in the process of microglial polarization.

Implementation of a cost-effective HPLC/UV approach for routine medical quantification of memantine in human serum.

BACKGROUND: In the near future, there will be no innovative drug principle for the treatment of dementia. Therefore, optimizing the efficacy of a drug is at present the most promising way to exploit its full pharmacological potential. METHOD: A high performance liquid chromatography with ultraviolet assay for memantine in serum from demented patients has been developed and validated. The analytical procedure involves offline solid phase extraction cartridges. Because memantine molecules lack chromophoric π-electrons, a derivatization with dansyl chloride was required for detection by ultraviolet (UV) photometry. Analyses were performed on a Dionex high-performance liquid chromatography system with a Phenomenex Luna Phenyl-Hexyl analytical column and 0.02 mol/L potassium dihydrogen phosphate buffer/acetonitrile (40/60 V/V) as mobile phase at a flow rate of 0.4 mL/min. Dansylated memantine was detected at 218 nm; 2 more ultraviolet wavelengths at 254 nm and 336 nm were used as an overlay-control check. RESULTS: The retention time for dansylated memantine was 17.1 ± 0.2 minutes. The calibration curve was linear over a concentration range from 5 to 160 ng/mL (n = 8/r² > 0.999). The method had an accuracy of >90%. Intra-assay and inter-assay coefficients of variation were <5% and <13%, respectively, at 3 different concentrations. The limit of quantification and the limit of detection were 2.9 ng/mL and 0.8 ng/mL, respectively. Among 100 substances prescribed as comedications in the treatment of dementia only fluvoxamine and zuclopenthixole showed retention times close to dansylated memantine (17.8 minutes and 18.1 minutes, respectively). However, these 2 drugs were removed from patients' specimens during solid-phase extraction sample preparation. CONCLUSIONS: The method is applicable under conditions of daily routine as has been demonstrated by application of the method to patient serum samples. The quantification of 29 samples showed that memantine concentrations suggested as "therapeutic" in the literature may only be reached by high doses of memantine.

Implementation of a cost-effective HPLC/UV-approach for medical routine quantification of donepezil in human serum.

A novel, simple, specific and sensitive high performance liquid chromatography (HPLC) assay for the detection and quantification of donepezil in serum of demented patients has been developed and validated. The analytical procedure involves an offline serum preextraction using solid phase extraction (SPE) cartridges (Oasis® HLB, Waters Co). The chromatographic analyses were performed on a Dionex HPLC system with a Phenomenex Luna Phenyl-Hexyl analytical column, and a mobile phase with the two components 0.02 mol/l phosphate buffer and acetonitrile. The flow rate was 0.4 ml/min. For the detection of donepezil three different UV wavelengths were used as an interference-control check. Interference tests between donepezil and 100 of the most commonly used concomitant medications allow quantification of donepezil under the polypharmaceutical conditions of the daily clinical routine. The retention time for donepezil was 12.1 min. The method was validated according to the guidelines of the Society of Toxicology and Forensic Chemistry (GTFCh): The calibration curve was linear over a concentration range from 5 to 160 ng/ml (n=8/r²>0.999). No endogenous compounds were found to interfere with the analyte, which was shown by retention times for the comedication most often prescribed to demented patients. The method had an accuracy of >85%. Intra- and inter-assay coefficients of variation were <6% and <8%, respectively, at three different concentrations. The limit of quantification (LOQ) and the limit of detection (LOD) were found to be 6.1 and 1.7 ng/ml for donepezil. Application of the method to patient serum samples discovered that concentrations suggested as "therapeutic" in the literature may only be reached either by high, off-label dosages or by utilization of inhibitory metabolic effects of the comedication.