Your search keyword '"Jian Chiuan Li"' showing total 7 results

1. Loss of the Drosophila branched-chain α-ketoacid dehydrogenase complex results in neuronal dysfunction

Author

Hui-Ying Tsai, Shih-Cheng Wu, Jian-Chiuan Li, Yu-Min Chen, Chih-Chiang Chan, and Chun-Hong Chen

Subjects

msud, neuronal apoptosis, oxidative stress, drosophila, Medicine, Pathology, RB1-214

Abstract

Maple syrup urine disease (MSUD) is an inherited error in the metabolism of branched-chain amino acids (BCAAs) caused by a severe deficiency of the branched-chain α-ketoacid dehydrogenase (BCKDH) complex, which ultimately leads to neurological disorders. The limited therapies, including protein-restricted diets and liver transplants, are not as effective as they could be for the treatment of MSUD due to the current lack of molecular insights into the disease pathogenesis. To address this issue, we developed a Drosophila model of MSUD by knocking out the dDBT gene, an ortholog of the human gene encoding the dihydrolipoamide branched chain transacylase (DBT) subunit of BCKDH. The homozygous dDBT mutant larvae recapitulate an array of MSUD phenotypes, including aberrant BCAA accumulation, developmental defects, poor mobile behavior and disrupted L-glutamate homeostasis. Moreover, the dDBT mutation causes neuronal apoptosis during the developmental progression of larval brains. The genetic and functional evidence generated by in vivo depletion of dDBT expression in the eye indicates severe impairment of retinal rhabdomeres. Further, the dDBT mutant shows elevated oxidative stress and higher lipid peroxidation accumulation in the larval brain. Therefore, we conclude from in vivo evidence that the loss of dDBT results in oxidative brain damage that may lead to neuronal cell death and contribute to aspects of MSUD pathology. Importantly, when the dDBT mutants were administrated with Metformin, the aberrances in BCAA levels and motor behavior were ameliorated. This intriguing outcome strongly merits the use of the dDBT mutant as a platform for developing MSUD therapies. This article has an associated First Person interview with the joint first authors of the paper.

Published

2020

2. Visualization of Endogenous Type I TGF-β Receptor Baboon in the Drosophila Brain

Author

Po-Lin Chen, Yen-Wei Lai, Jian-Chiuan Li, Sao-Yu Chu, Chun-Hong Chen, and Hung-Hsiang Yu

Subjects

0301 basic medicine, Untranslated region, Neurite, Activin Receptors, lcsh:Medicine, Hemagglutinin Glycoproteins, Influenza Virus, Biology, Article, Animals, Genetically Modified, 03 medical and health sciences, 0302 clinical medicine, Downregulation and upregulation, Transforming Growth Factor beta, Neurites, Animals, Drosophila Proteins, Gene Knock-In Techniques, Receptor, lcsh:Science, Mushroom Bodies, Regulation of gene expression, Multidisciplinary, lcsh:R, Brain, Gene Expression Regulation, Developmental, Axons, Activins, Cell biology, MicroRNAs, 030104 developmental biology, Mushroom bodies, Neuronal development, Drosophila, Biological metamorphosis, lcsh:Q, Signal transduction, Carrier Proteins, 030217 neurology & neurosurgery, Signal Transduction, Transforming growth factor

Abstract

The transforming growth factor β (TGF-β) signaling pathway is evolutionarily conserved and widely used in the animal kingdom to regulate diverse developmental processes. Prior studies have shown that Baboon (Babo), a Drosophila type I TGF-β receptor, plays essential roles in brain development and neural circuit formation. However, the expression pattern for Babo in the developing brain has not been previously reported. We generated a knock-in fly with a human influenza hemagglutinin (HA) tag at the C-terminus of Babo and assessed its localization. Babo::HA was primarily expressed in brain structures enriched with neurites, including the mushroom body lobe and neuropils of the optic lobe, where Babo has been shown to instruct neuronal morphogenesis. Since the babo 3' untranslated region contains a predicted microRNA-34 (miR-34) target sequence, we further tested whether Babo::HA expression was affected by modulating the level of miR-34. We found that Babo was upregulated by mir-34 deletion and downregulated by miR-34 overexpression, confirming that it is indeed a miR-34 target gene. Taken together, our results demonstrate that the baboHA fly permits accurate visualization of endogenous Babo expression during brain development and the construction of functional neural circuits.

Published

2020

3. Chchd2 regulates mitochondrial morphology by modulating the levels of Opa1

Author

Weina Shang, Jun-Ping Liu, Liquan Wang, Chun-Hong Chen, Xiuying Duan, Jian-Chiuan Li, Jiayao Zhao, Wei Liu, Lingna Xu, and Chao Tong

Subjects

0301 basic medicine, medicine.medical_treatment, Mutant, Mitochondrion, Article, Cell Line, 03 medical and health sciences, 0302 clinical medicine, RNA interference, Organelle, medicine, Animals, Drosophila Proteins, Molecular Biology, Gene, Tissue homeostasis, Protease, Chemistry, Point mutation, Membrane Proteins, Cell Biology, eye diseases, Mitochondria, Cell biology, 030104 developmental biology, 030220 oncology & carcinogenesis, Drosophila

Abstract

The mitochondrion is a highly dynamic organelle that is critical for energy production and numerous metabolic processes. Drosophila Chchd2, a homolog of the human disease-related genes CHCHD2 and CHCHD10, encodes a mitochondrial protein. In this study, we found that loss of Chchd2 in flies resulted in progressive degeneration of photoreceptor cells and reduced muscle integrity. In the flight muscles of adult Chchd2 mutants, some mitochondria exhibited curling cristae and a reduced number of cristae compared to those of controls. Overexpression of Chchd2 carrying human disease-related point mutations failed to fully rescue the mitochondrial defects in Chchd2 mutants. In fat body cells, loss of Chchd2 resulted in fragmented mitochondria that could be partially rescued by Marf overexpression and enhanced by Opa1 RNAi. The expression level of Opa1 was reduced in Chchd2 mutants and increased when Chchd2 was overexpressed. The chaperone-like protein P32 co-immunoprecipitated with Chchd2 and YME1L, a protease known to processes human OPA1. Moreover, the interaction between P32 and YME1L enhanced YME1L activity and promoted Opa1 degradation. Finally, Chchd2 stabilized Opa1 by competing with P32 for YME1L binding. We propose a model whereby Chchd2 regulates mitochondrial morphology and tissue homeostasis by fine-tuning the levels of OPA1.

Published

2020

4. Assessing the Cognitive Status of Drosophila by the Value-Based Feeding Decision

Author

Chun-Hong Chen, Chih-Chieh Yu, Yong Huei Hong, Po-Lin Chen, Yun-Ming Wang, Ferng Chang Chang, Tzai Wen Chiu, Tsai-Te Lu, Jian Chiuan Li, and Chih-Fei Kao

Subjects

Aging, biology, RC952-954.6, Cognition, Disease, biology.organism_classification, Neuroprotection, Article, Nitric oxide, chemistry.chemical_compound, Ageing, chemistry, Geriatrics, Mushroom bodies, Cognitive status, Premovement neuronal activity, Geriatrics and Gerontology, Cognitive decline, Neuroscience, Drosophila

Abstract

Decision-making is considered an important aspect of cognitive function. Impaired decision-making is a consequence of cognitive decline caused by various physiological conditions, such as aging and neurodegenerative diseases. Here we exploited the value-based feeding decision (VBFD) assay, which is a simple sensory–motor task, to determine the cognitive status of Drosophila. Our results indicated the deterioration of VBFD is notably correlated with aging and neurodegenerative disorders. Restriction of the mushroom body (MB) neuronal activity partly blunted the proper VBFD. Furthermore, using the Drosophila polyQ disease model, we demonstrated the impaired VBFD is ameliorated by the dinitrosyl iron complex (DNIC-1), a novel and steady nitric oxide (NO)-releasing compound. Therefore we propose that the VBFD assay provides a robust assessment of Drosophila cognition and can be used to characterize additional neuroprotective interventions.

Published

2020

5. Loss of the

Author

Hui-Ying, Tsai, Shih-Cheng, Wu, Jian-Chiuan, Li, Yu-Min, Chen, Chih-Chiang, Chan, and Chun-Hong, Chen

Subjects

Male, Casein Kinase 1 epsilon, Neurogenesis, MSUD, Apoptosis, Motor Activity, Animals, Genetically Modified, Maple Syrup Urine Disease, Animals, Drosophila Proteins, Genetic Predisposition to Disease, Neurons, Neuronal apoptosis, nutritional and metabolic diseases, Brain, Gene Expression Regulation, Developmental, Dros, Metformin, Disease Models, Animal, Oxidative Stress, Drosophila melanogaster, Phenotype, Larva, Drosophila, Lipid Peroxidation, Amino Acids, Branched-Chain, Research Article

Abstract

Maple syrup urine disease (MSUD) is an inherited error in the metabolism of branched-chain amino acids (BCAAs) caused by a severe deficiency of the branched-chain α-ketoacid dehydrogenase (BCKDH) complex, which ultimately leads to neurological disorders. The limited therapies, including protein-restricted diets and liver transplants, are not as effective as they could be for the treatment of MSUD due to the current lack of molecular insights into the disease pathogenesis. To address this issue, we developed a Drosophila model of MSUD by knocking out the dDBT gene, an ortholog of the human gene encoding the dihydrolipoamide branched chain transacylase (DBT) subunit of BCKDH. The homozygous dDBT mutant larvae recapitulate an array of MSUD phenotypes, including aberrant BCAA accumulation, developmental defects, poor mobile behavior and disrupted L-glutamate homeostasis. Moreover, the dDBT mutation causes neuronal apoptosis during the developmental progression of larval brains. The genetic and functional evidence generated by in vivo depletion of dDBT expression in the eye indicates severe impairment of retinal rhabdomeres. Further, the dDBT mutant shows elevated oxidative stress and higher lipid peroxidation accumulation in the larval brain. Therefore, we conclude from in vivo evidence that the loss of dDBT results in oxidative brain damage that may lead to neuronal cell death and contribute to aspects of MSUD pathology. Importantly, when the dDBT mutants were administrated with Metformin, the aberrances in BCAA levels and motor behavior were ameliorated. This intriguing outcome strongly merits the use of the dDBT mutant as a platform for developing MSUD therapies. This article has an associated First Person interview with the joint first authors of the paper., Summary: Loss of BCKDH activity in Drosophila recapitulates the neurological symptoms of patients with maple syrup urine disease. Metformin administration was found to alleviate developmental defects and aberrant behavior in the BCKDH mutant.

Published

2020

6. Glia-derived exosomal miR-274 targets Sprouty in trachea and synaptic boutons to modulate growth and responses to hypoxia

Author

Yu-Chen Tsai, Cheng-Ting Chien, Jian-Chiuan Li, Hsin-Ho Sung, Ying-Ju Cheng, Pei-Yi Chen, Chun-Hong Chen, Chun-Yen Yeh, and Yi-Wei Tsai

Subjects

Untranslated region, MAPK/ERK pathway, glia, MAP Kinase Signaling System, Mutant, Presynaptic Terminals, Down-Regulation, Biology, Exosomes, Exosome, ESCRT, Animals, Genetically Modified, Hemolymph, Commentaries, Gene expression, microRNA, RNA Precursors, exosome, Humans, Myocyte, Animals, Drosophila Proteins, Secretion, 3' Untranslated Regions, Multidisciplinary, hypoxia, Cell growth, fungi, Gene Expression Regulation, Developmental, Membrane Proteins, Biological Sciences, Cell Hypoxia, Microvesicles, Up-Regulation, Cell biology, Trachea, MicroRNAs, Drosophila melanogaster, PNAS Plus, nervous system, Larva, Mutation, Drosophila, Female, Neuroglia, Developmental Biology

Abstract

Significance Our study provides significant advances in the understanding of circulating exosomal microRNA (miRNA) in animals. Circulating exosomal miRNAs mediate communication among tissues and organs. In glia, mature miR-274 is produced and secreted to the circulating hemolymph to target the recipient cells, neurons, and tracheal cells. We also identified the target gene sty whose expression is down-regulated by miR-274 in the target/recipient cells. Downregulation of Sty leads to upregulation of MAPK signaling, thereby promoting the growth of synaptic boutons and tracheal branches. Thus, glia-derived miR-274 might be deemed a “gliotransmitter” to mediate communication with neurons and tracheal cells. The modulation of tracheal branches by glial-derived miR-274 is also crucial for fine-tuning larval behavior in response to hypoxia., Secreted exosomal microRNAs (miRNAs) mediate interorgan/tissue communications by modulating target gene expression, thereby regulating developmental and physiological functions. However, the source, route, and function in target cells have not been formally established for specific miRNAs. Here, we show that glial miR-274 non-cell-autonomously modulates the growth of synaptic boutons and tracheal branches. Whereas the precursor form of miR-274 is expressed in glia, the mature form of miR-274 distributes broadly, including in synaptic boutons, muscle cells, and tracheal cells. Mature miR-274 is secreted from glia to the circulating hemolymph as an exosomal cargo, a process requiring ESCRT components in exosome biogenesis and Rab11 and Syx1A in exosome release. We further show that miR-274 can function in the neurons or tracheal cells to modulate the growth of synaptic boutons and tracheal branches, respectively. Also, miR-274 uptake into the target cells by AP-2–dependent mechanisms modulates target cell growth. In the target cells, miR-274 down-regulates Sprouty (Sty) through a targeting sequence at the sty 3′ untranslated region, thereby enhancing MAPK signaling and promoting cell growth. miR-274 expressed in glia of an mir-274 null mutant is released as an exosomal cargo in the circulating hemolymph, and such glial-specific expression resets normal levels of Sty and MAPK signaling and modulates target cell growth. mir-274 mutant larvae are hypersensitive to hypoxia, which is suppressed by miR-274 expression in glia or by increasing tracheal branches. Thus, glia-derived miR-274 coordinates growth of synaptic boutons and tracheal branches to modulate larval hypoxia responses.

Published

2019

7. Glia-derived exosomal miR-274 targets Sprouty in trachea and synaptic boutons to modulate growth and responses to hypoxia.

Author

Yi-Wei Tsai, Hsin-Ho Sung, Jian-Chiuan Li, Chun-Yen Yeh, Pei-Yi Chen, Ying-Ju Cheng, Chun-Hong Chen, Yu-Chen Tsai, and Cheng-Ting Chien

Subjects

HYPOXEMIA, TRACHEA, MUSCLE cells, CELL growth, SWINE housing

Abstract

Secreted exosomal microRNAs (miRNAs) mediate interorgan/tissue communications by modulating target gene expression, thereby regulating developmental and physiological functions. However, the source, route, and function in target cells have not been formally established for specific miRNAs. Here, we show that glial miR-274 non-cell-autonomously modulates the growth of synaptic boutons and tracheal branches. Whereas the precursor form of miR-274 is expressed in glia, the mature form of miR-274 distributes broadly, including in synaptic boutons, muscle cells, and tracheal cells. Mature miR-274 is secreted from glia to the circulating hemolymph as an exosomal cargo, a process requiring ESCRT components in exosome biogenesis and Rab11 and Syx1A in exosome release. We further show that miR-274 can function in the neurons or tracheal cells to modulate the growth of synaptic boutons and tracheal branches, respectively. Also, miR-274 uptake into the target cells by AP-2–dependent mechanisms modulates target cell growth. In the target cells, miR-274 down-regulates Sprouty (Sty) through a targeting sequence at the sty 3′ untranslated region, thereby enhancing MAPK signaling and promoting cell growth, miR-274 expressed in glia of an mir-274 null mutant is released as an exosomal cargo in the circulating hemolymph, and such glial-specific expression resets normal levels of Sty and MAPK signaling and modulates target cell growth.mir-274mutant larvae are hypersensitive to hypoxia, which is suppressed by miR-274 expression in glia or by increasing tracheal branches. Thus, glia-derivedmiR-274 coordinates growth of synaptic boutons and tracheal branches to modulate larval hypoxia responses. [ABSTRACT FROM AUTHOR]

Published

2019