Specific vulnerability of iPSC-derived motor neurons with TDP-43 gene mutation to oxidative stress.

Amyotrophic lateral sclerosis (ALS) is a disease that affects motor neurons and has a poor prognosis. We focused on TAR DNA-binding protein 43 kDa (TDP-43), which is a common component of neuronal inclusions in many ALS patients. To analyze the contribution of TDP-43 mutations to ALS in human cells, we first introduced TDP-43 mutations into healthy human iPSCs using CRISPR/Cas9 gene editing technology, induced the differentiation of these cells into motor and sensory neurons, and analyzed factors that are assumed to be altered in or associated with ALS (cell morphology, TDP-43 localization and aggregate formation, cell death, TDP-43 splicing function, etc.). We aimed to clarify the pathological alterations caused solely by TDP-43 mutation, i.e., the changes in human iPSC-derived neurons with TDP-43 mutation compared with those with the same genetic background except TDP-43 mutation. Oxidative stress induced by hydrogen peroxide administration caused the death of TDP-43 mutant-expressing motor neurons but not in sensory neurons, indicating the specific vulnerability of human iPSC-derived motor neurons with TDP-43 mutation to oxidative stress. In our model, we observed aggregate formation in a small fraction of TDP-43 mutant-expressing motor neurons, suggesting that aggregate formation seems to be related to ALS pathology but not the direct cause of cell death. This study provides basic knowledge for elucidating the pathogenesis of ALS and developing treatments for the disease.

Generation and characterization of motor neuron progenitors and motor neurons using metachromatic leukodystrophy-induced pluripotent stem cells.

The pathological consequences leading to primary storage, autophagy impairment, impaired mitochondrial dynamics, and endoplasmic reticulum (ER) stress on neural cell dysfunction and apoptosis in metachromatic leukodystrophy (MLD) have been poorly elucidated. In the present study, we generated 2 cell lines of patient-specific-induced pluripotent stem cells (iPSCs) and modeled the progression of pathological events during the differentiation of iPSCs to motor neuron progenitors (MNPs) and mature motor neurons (MNs). The iPS cells were generated from two late-infantile MLD patient-derived skin fibroblasts using electroporation or the Sendai virus. Olig2+ MNPs were generated from both iPSC lines using a combination of small molecules in a chemically defined neural medium. Furthermore, the MNPs could be differentiated into mature MNs, which was confirmed by RT-PCR and MN markers, including SMI32 and ChAT. The population of MNs was approximately 50% under the culture conditions. Pathological observation of MLD patient-derived iPSCs revealed lysosomal accumulation and impaired autophagy. In addition, both MNPs and MNs derived from MLD-iPSCs showed increased lysosomal accumulation, dysfunctional autophagy, impaired mitophagy, endoplasmic reticulum (ER) stress or unfolded protein response (UPR) activation, and premature cellular death.

Generation of four iPSC lines from a family harboring a 1p36-35 haplotype linked with bipolar disorder and recurrent depressive disorder: Three-generation patients and a healthy sibling.

Induced pluripotent stem cells (iPSCs) obtained from genetically characterized patients benefit the biological study of bipolar disorder (BD). Here, we present iPSC lines from three-generation patients with BD and recurrent depressive disorder (RDD) and a healthy control sibling in a family. All patients shared the specified haplotype in the 1p36-35, previously reported as the susceptibility locus of mood disorders. iPSCs were generated with the reprogramming factors OTC3/4, l-MYC, LIN28, SOX2, KLF4, and p53 shRNA through non-integrated episomal vectors. All iPSC lines strongly expressed pluripotency markers and proved the ability to differentiate into three germ lineages in vitro.

Characterization of the upstream and intron promoters of the gene encoding TAR DNA-binding protein.

TAR DNA-binding protein (TDP-43, encoded by TARDBP) is a multifunctional protein that regulates transcription and RNA metabolism by binding DNA or RNA. TDP-43 has been implicated in the pathogenesis of amyotrophic lateral sclerosis (ALS) because abnormal accumulation of cleaved and phosphorylated C-terminal fragments of TDP-43 in motor neurons is a pathological hallmark of ALS. Here, we cloned and analyzed the promoter region of the TARDBP gene. TARDBP upstream sequences and/or intron/luciferase constructs were generated, and their promoter activity was experimentally assessed. The upstream region predictably exhibited promoter activity and identified putative cis-acting elements, including the i-motif, was relevant for the regulation of TDP-43 expression. The cellular abundance of TDP-43 is strictly controlled, and its constancy is critically important for motor neuron survival. A machinery serving to maintain a constant level of TDP-43 is autoregulation via control of mRNA stability, a negative feedback system involving binding to the 3' untranslated region of its own pre-mRNA. However, whether transcriptional mechanisms contribute to TDP-43 autoregulation is unclear. We further showed that TDP-43 negatively regulates the TARDBP promoter and, surprisingly, that disease-causing TDP-43 mutants lacked this regulatory activity. These results allowed the elucidation of a novel transcriptional autoregulatory mechanism of TDP-43.

Loss of DDHD2, whose mutation causes spastic paraplegia, promotes reactive oxygen species generation and apoptosis.

DDHD2/KIAA0725p is a mammalian intracellular phospholipase A1 that exhibits phospholipase and lipase activities. Mutation of the DDHD2 gene causes hereditary spastic paraplegia (SPG54), an inherited neurological disorder characterized by lower limb spasticity and weakness. Although previous studies demonstrated lipid droplet accumulation in the brains of SPG54 patients and DDHD2 knockout mice, the cause of SPG54 remains elusive. Here, we show that ablation of DDHD2 in mice induces age-dependent apoptosis of motor neurons in the spinal cord. In vitro, motor neurons and embryonic fibroblasts from DDHD2 knockout mice fail to survive and are susceptible to apoptotic stimuli. Chemical and probe-based analysis revealed a substantial decrease in cardiolipin content and an increase in reactive oxygen species generation in DDHD2 knockout cells. Reactive oxygen species production in DDHD2 knockout cells was reversed by the expression of wild-type DDHD2, but not by an active-site DDHD2 mutant, DDHD2 mutants related to hereditary spastic paraplegia, or DDHD1, another member of the intracellular phospholipase A1 family whose mutation also causes spastic paraplegia (SPG28). Our results demonstrate the protective role of DDHD2 for mitochondrial integrity and provide a clue to the pathogenic mechanism of SPG54.