The neuropathological hallmarks of Alzheimer's disease (AD) and other taupathies include neurofibrillary tangles and plaques. Despite the fact that only 2-10% of AD cases are associated with genetic mutations, no nontransgenic or metabolic models have been generated to date. The findings of tryptophanyl-tRNA synthetase (TrpRS) in plaques of the AD brain were reported recently by the authors. Here it is shown that expression of cytoplasmic-TrpRS is inversely correlated with neurofibrillary degeneration, whereas a nonionic detergent-insoluble presumably aggregated TrpRS is simultaneously accumulated in human cells treated by tryptamine, a metabolic tryptophan analog that acts as a competitive inhibitor of TrpRS. TrpRSN- terminal peptide self-assembles in double-helical fibrils in vitro. Herein, tryptamine causes neuropathy characterized by motor and behavioral deficits, hippocampal neuronal loss, neurofibrillary tangles, amyloidosis, and glucose decrease in mice. Tryptamine induced the formation of helical fibrillary tangles in both hippocampal neurons and glia. Taken together with the authors' previous findings of tryptamine-induced nephrotoxicity and filamentous tangle formation in kidney cells, the authors' data indicates a general role of tryptamine in cell degeneration and loss. It is concluded that tryptamine as a component of a normal diet can induce neurodegeneration at the concentrations, which might be consumed along with food. Tryptophan-dependent tRNAtrp aminoacylation catalyzed by TrpRS can be inhibited by its substrate tryptophan at physiological concentrations was demonstrated. These findings indicate that the dietary supplementation with tryptophan as a tryptamine competitor may not counteract the deleterious influence of tryptamine. The pivotal role of TrpRS in protecting against neurodegeneration is suggested, providing an insight into the pathogenesis and a possible treatment of neurodegenerative diseases.
Earlier we reported induction of neurotoxicity and neurodegeneration by tryptophan metabolites that link the metabolic alterations to Alzheimer's disease (AD). Tryptophan is a product of Shikimate pathway (SP). Human cells lack SP, which is found in human gut bacteria exclusively using SP to produce aromatic amino acids (AAA). This study is a first attempt toward gene-targeted analysis of human gut microbiota in AD fecal samples. The oligonucleotide primers newly-designed for this work target SP-AAA in environmental bacteria associated with human activity. Using polymerase chain reaction (PCR), we found unique gut bacterial sequence in most AD patients (18 of 20), albeit rarely in controls (1 of 13). Cloning and sequencing AD-associated PCR products (ADPP) enables identification of Na(+)-transporting NADH: Ubiquinone reductase (NQR) in Clostridium sp. The ADPP of unrelated AD patients possess near identical sequences. NQR substrate, ubiquinone is a SP product and human neuroprotectant. A deficit in ubiquinone has been determined in a number of neuromuscular and neurodegenerative disorders. Antibacterial therapy prompted an ADPP reduction in an ADPP-positive control person who was later diagnosed with AD-dementia. We explored the gut microbiome databases and uncovered a sequence similarity (up to 97%) between ADPP and some healthy individuals from different geographical locations. Importantly, our main finding of the significant difference in the gut microbial genotypes between the AD and control human populations is a breakthrough.
Tryptophanyl-tRNA synthetase (TrpRS) catalyzes tryptophanyl-tRNAtrp formation. At concentrations exceeding tryptophan, tryptamine inhibits TrpRS. This leads in tryptophanyl-tRNA deficiency and synthesis of aberrant proteins. Tryptamine presents in food and crosses blood-brain barrier. The purpose of this study is to test the hypothesis that tryptamine-induced changes in cell and animal models correlate with Alzheimer's disease (AD) manifestations. Tryptamine prevented growth of human neuroblastoma. Epithelioids recovered growth in tryptamine-free medium, while neuroblasts died. Tryptamine induced epithelioid differentiation forming synaptic vesicles, neuritic contacts, and TrpRS+ axons in stable sublines. A fraction of epithelioids was adhered to satellite cells via trypsin-resistant interdigitating junctions. Tryptamine stimulated satellite division and differentiation into neurons, transitional cell variants and neuroblasts able to repopulate. Both tryptamine-inhibited and hypoxia-downregulated TrpRS translocates into cytoplasmic extensions. TrpRS is secreted into extracellular space as a free protein or within vesicles extended from cytoplasm and then pinched-off from plasma membrane of tryptamine-treated cells. Extracellular vesicles fuse in congophilic TrpRS+ plaques in tryptamine-treated culture and AD brain. TrpRS prominent immunoreactivity is associated with plasma and vesicle membranes of satellites and AD brain degenerated neurons. Tryptamine-modified mouse brain expresses amyloid and abnormal filaments in extracellular and neuronal plasma membrane vesicles. Radiolabeled tryptamine, tryptophan and serotonin uptake was 10-fold lower in tryptamine-resistant compared to tryptamine-sensitive cells. In both variants, tryptamine uptake exceeded tryptophan uptake within 2-h assuring TrpRS inhibition. Here, tryptophanyl-tRNAtrp deficiency implicates in both neurite growth and termination/collapse. Neurite growth termination prompts TrpRS+ vesicularization. TrpRS+ vesicles contribute in neuronal fragmentation and fibrillar-vesicular congophilic plaques in AD brain.
Upregulation of group IIA phospholipase A(2) (sPLA(2)-IIA) correlates with prostate tumor progression suggesting prooncogenic properties of this protein. Here, we report data on expression of three different sPLA(2) isozymes (groups IIA, V, and X) in normal (PrEC) and malignant (DU-145, PC-3, and LNCaP) human prostate cell lines. All studied cell lines constitutively expressed sPLA(2)-X, whereas sPLA(2)-V transcripts were identified only in malignant cells. In contrast, no expression of sPLA(2)-IIA was found in PrEC and DU-145 cells, but it was constitutively expressed by IFN-gamma in LNCaP and PC-3 cells. Expression of sPLA(2)-IIA is upregulated in PC-3 and in PrEC cell in a signal transducer and activator of transcription-1-dependent manner, but not in LNCaP cell. Additional signaling pathways regulating sPLA(2)-IIA expression include cAMP/protein kinase A, p38 mitogen-activated protein kinase, protein kinase C, Rho-kinase, and mitogen-activated/extracellular response protein kinase / extracellular signal-regulated kinase. No deletions were revealed in the sPLA(2)-IIA gene from DU-145 cells lacking the expression of sPLA(2)-IIA. Reexpression of sPLA(2)-IIA was induced by 5-aza-2'-deoxycytidine demonstrating that DNA methylation is implicated in the regulation of sPLA(2)-II. Together, these data suggest that sPLA(2)-IIA and sPLA(2)-V, but not sPLA(2)-X, are differentially expressed in normal and malignant prostate cells under the control of proinflammatory cytokines; epigenetic mechanisms appear involved in the regulation of sPLA(2)-IIA expression, at least in DU-145 cells.
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