Simple methods for measuring milk exosomes using fluorescent compound GIF-2250/2276.

Exosomes are small extracellular vesicles (EVs) found in culture supernatants, blood, and breast milk. The size of these nanocomplexes limits the methods of EV analyses. In this study, nitrobenzoxadiazole (NBD), a fluorophore, conjugated endosome-lysosome imager, GIF-2250 and its derivative, GIF-2276, were evaluated for exosome analyses. A correlation was established between GIF-2250 intensity and protein maker levels in bovine milk exosomes. We found that high-temperature sterilization milk may not contain intact exosomes. For precise analysis, we synthesized GIF-2276, which allows for the covalent attachment of NBD to the Lys residue of exosome proteins, and labeled milk exosomes were separated using a gel filtration system. GIF-2276 showed chromatographic peaks of milk exosomes containing >3 ng protein. The area (quantity) and retention time (size) of the exosome peaks were correlated to biological activity (NO synthesis suppression in RAW264.7 murine macrophages). Heat denaturation of purified milk-derived exosomes disrupted these indicators. Proteome analyses revealed GIF-2276-labeled immunomodulators, such as butyrophilin subfamily 1 member A1 and polymeric immunoglobulin receptor. The immunogenicity and quantity of these factors decreased by heat denaturation. When milk exosomes were purified from market-sourced milk we found that raw and low-temperature sterilization milk samples, contained exosomes (none in high-temperature sterilization milk). These results were also supported by transmission electron microscopy analyses. We also found that GIF-2276 could monitor exosome transportation into HEK293 cells. These results suggested that GIF-2250/2276 may be helpful to evaluate milk exosomes.

Melanosomal localization is required for GIF-2115/2250 to inhibit melanogenesis in B16F10 melanoma cells.

OBJECTIVE: Tyrosinase inhibitors suppress melanogenesis in melanocytes. During a screening for tyrosinase inhibitors, however, we noticed some discrepancies in inhibitory efficacies between melanocytes and in vitro assays. The compound (S)-N-{3-[4-(dimethylamino)phenyl]propyl}-N-methyl-indan-1-amine (GIF-2115) exerts antioxidative stress activity upon accumulation in late endosomes and lysosomes. GIF-2115 was also identified as a potent antimelanogenic reagent in B16F10 mouse melanoma cells. GIF-2115 inhibited the activity of mushroom tyrosinase and the lysates of B16F10 cells. However, structure-activity relationship studies indicated that GIF-2238, which lacks the benzene ring in the aminoindan structure of GIF-2115, inhibited tyrosinase activity in vitro but did not inhibit melanogenesis in B16F10 cells. The aim of the present study is to show the importance of the intracellular distribution of tyrosinase inhibitors in exerting their antimelanogenic activity in melanocytes. METHODS: The intracellular distribution of compounds was monitored by linking with the fluorescent group of 7-nitro-2,1,3-benzoxadiazole (NBD). To mislocalize GIF-2115 to mitochondria, the mitochondria-preferring fluoroprobe ATTO565 was used. RESULTS: We reconfirmed the localization of GIF-2250 (GIF-2115-NBD) not only to matured but also to early-stage melanosomes. Although GIF-2286 (GIF-2238-NBD) maintained tyrosinase inhibitory activity, it did not show specific intracellular localization. Moreover, when GIF-2115 was linked with ATTO565, the resultant compound GIF-2265 did not inhibit melanogenesis in B16F10 cells, despite its strong tyrosinase inhibitory activity. CONCLUSION: These results suggest that melanosomal localization is essential for the antimelanogenic activity of GIF-2115, and GIF-2115 derivatives may be new guides for drugs to endosomes and lysosomes as well as melanosomes.

OBJECTIF: Les inhibiteurs de la tyrosinase suppriment la mélanogenèse dans les mélanocytes. Lors d'un criblage d'inhibiteurs de la tyrosinase, cependant, nous avons remarqué des différences dans les efficacités inhibitrices entre les mélanocytes et les essais in vitro. Le composé (S)-N-{3-[4-(diméthylamino)phényl]propyl}-N-méthyl-indan-1-amine (GIF-2115) exerce une activité antioxydante en cas de stress lors de l'accumulation dans les endosomes tardifs et les lysosomes. GIF-2115 a également été identifié comme un puissant réactif antimélanogène dans les cellules de mélanome murin B16F10. GIF-2115 a inhibé l'activité de la tyrosinase de champignon et les lysats des cellules B16F10. Cependant, des études de relation structure-activité ont indiqué que GIF-2238, à qui il manque l'anneau benzénique dans la structure aminoindan de GIF-2115, inhibait l'activité de la tyrosinase in vitro mais n'inhibait pas la mélanogenèse dans les cellules B16F10. L'objectif de la présente étude est de montrer l'importance de la distribution intracellulaire des inhibiteurs de la tyrosinase dans l'exercice de leur activité antimélanogène dans les mélanocytes. MÉTHODES: La distribution intracellulaire des composés a été surveillée en les liant au groupe fluorescent de la 7-nitro-2,1,3-benzoxadiazole (NBD). Pour délocaliser GIF-2115 vers les mitochondries, le fluorophore ATTO565 préférant les mitochondries a été utilisé. RÉSULTATS: Nous avons confirmé la localisation de GIF-2250 (GIF-2115-NBD) non seulement dans les mélanosomes matures mais aussi dans les mélanosomes à un stade précoce. Bien que GIF-2286 (GIF-2238-NBD) ait maintenu une activité inhibitrice de la tyrosinase, il n'a pas montré de localisation intracellulaire spécifique. De plus, lorsque GIF-2115 a été lié à ATTO565, le composé résultant GIF-2265 n'a pas inhibé la mélanogenèse dans les cellules B16F10, malgré son activité inhibitrice de la tyrosinase forte. CONCLUSION: Ces résultats suggèrent que la localisation dans les mélanosomes est essentielle pour l'activité antimélanogène de GIF-2115, et que les dérivés de GIF-2115 peuvent être de nouveaux guides pour les médicaments vers les endosomes et les lysosomes ainsi que les mélanosomes.

Decreased beta-band activity in left supramarginal gyrus reflects cognitive decline: Evidence from a large clinical dataset in patients with dementia.

Cognitive impairment is a major concern in clinical medicine. It is usually evaluated with neuropsychological assessments, which have inherent limitations. To compensate for them, magnetoencephalography has already come into clinical use to evaluate the level of cognitive impairment. It evaluates global changes in the frequency of resting-state brain activity, which are associated with cognitive status. However, it remains unclear what neural mechanism causes the frequency changes. To understand this, it is important to identify cortical regions that mainly contribute to these changes. We retrospectively analysed the clinical records from 310 individuals with cognitive impairment who visited the outpatient department at our hospital. The analysis included resting-state magnetoencephalography, neuropsychological assessment, and clinical diagnosis data. Regional oscillatory intensities were estimated from the magnetoencephalography data, which were statistically analysed, along with neuropsychological assessment scores, and the severity of cognitive impairment associated with clinical diagnosis. The regional oscillatory intensity covering a wide range of regions and frequencies was significantly associated with neuropsychological assessment scores and differed between healthy individuals and patients with cognitive impairment. However, these associations and differences in all conditions were overlapped by a single change in beta frequency in the left supramarginal gyrus. High frequency oscillatory intensity in the left supramarginal gyrus is associated with cognitive impairment levels among patients who were concerned about dementia. It provides new insights into cognitive status measurements using magnetoencephalography, which is expected to develop as an objective index to be used alongside traditional neuropsychological assessments.

Molecular characterization of wild-type and HSAN2B-linked FAM134B.

BACKGROUND: Family with sequence similarity 134, member B (FAM134B), also known as Reticulophagy regulator 1 (RETREG1), is an ER-phagy receptor involved in ER homeostasis. Congenital mutations in the FAM134B gene have been reported to be associated with hereditary sensory and autonomic neuropathy type 2B (HSAN2B); however, the molecular differences between wild-type and HSAN2B-linked FAM134B are not fully understood. METHODS AND RESULTS: We prepared several human FAM134B constructs, such as the HSAN2B-linked mutant, and compared their features with those of wild-type FAM134B by transfecting these constructs into FAM134B-deficient Neuro2a cells. Although intrinsic FAM134B protein expression in wild-type Neuro2a cells was affected by the supply of amino acids in the culture medium, the expression of each HSAN2B-linked mutant FAM134B protein was hardly affected by serum and amino acid deprivation. On the other hand, the intracellular localization of GFP-tagged HSAN2B-linked mutants, except for P7Gfs133X, overlapped well with ER-localized SP-RFPKDEL and did not differ from that of GFP-tagged wild-type FAM134B. However, analysis of protein‒protein interactions using the NanoBiT reporter assay revealed the difference between wild-type and C-terminal truncated mutant FAM134B. Furthermore, this NanoBiT assay demonstrated that both wild-type and G216R FAM134B interacted with LC3/GABARAPL1 to the same extent, but the FAM134B construct with mutations near the LC3-interacting region (LIR) did not. Similar to the NanoBiT assay, the C-terminal-truncated FAM134B showed lower ER-phagy activities, as assessed by the cotransfection of GFP-tagged reporters. CONCLUSIONS: We showed that wild-type and HSAN2B-linked FAM134B have different molecular characteristics by transfecting cells with various types of constructs. Thus, this study provides new insights into the molecular mechanisms underlying HSAN2B as well as the regulation of ER-phagy.

Intermittent inhibition of FYVE finger-containing phosphoinositide kinase induces melanosome degradation in B16F10 melanoma cells.

BACKGROUND: Melanosomes are lysosome-related organelles that contain melanogenic factors and synthesize melanin as they mature. FYVE finger-containing phosphoinositide kinase (PIKfyve) regulates late endosome and lysosome morphology, vesicle trafficking, and autophagy. In melanocytes, PIKfyve inhibition has been reported to induce hypopigmentation due to impairments in the metabolism of early-stage melanosomes. METHODS AND RESULTS: Here, we report a new type of melanosome metabolism: post-PIKfyve inhibition, which was found during the characterization of the endosome/lysosome fluoroprobe GIF-2250. In B16F10 mouse melanoma cells, GIF-2250 highlighted vesicles positive for lysosomal-associated membrane protein 1 (lysosome marker) and other endosome/lysosome markers (CD63 and Rab7/9). When cells were continuously treated with PIKfyve inhibitors, intracellular vacuoles formed, while GIF-2250 fluorescence signals diminished and were diffusely distributed in the vacuoles. After removal of the PIKfyve inhibitors, the GIF-2250 signal intensity was restored, and some GIF-2250-positive vesicles wrapped the melanosomes, which spun at high speed. In addition, intermittent PIKfyve inhibition caused melanin diffusion in the vacuoles and possible leakage into the cytoplasmic compartments, and melanosome degradation was detected by a transmission electron microscope. Melanosome degradation was accompanied by decreased levels of melanin synthesis enzymes and increased levels of the autophagosome maker LC3BII, which is also associated with early melanosomes. However, the protein levels of p62, which is degraded during autophagy, were increased, suggesting an impairment in autophagy flux during intermittent PIKfyve inhibition. Moreover, the autophagy inhibitor 3-methyladenine does not affect these protein levels, suggesting that the melanosome degradation by the intermittent inhibition of PIKfyve is not mediated by canonical autophagy. CONCLUSIONS: In conclusion, disturbance of PIKfyve activity induces melanosome degradation in a canonical autophagy-independent manner.

Qualitative and quantitative evaluation for the heterogeneity of cortical tubers using structural imaging and diffusion-weighted imaging to predict the epileptogenicity in tuberous sclerosis complex patients.

PURPOSE: We aimed to evaluate whether the heterogeneity of tuber imaging features, evaluated on the structural imaging and apparent diffusion coefficient (ADC) map, can facilitate detecting epileptogenic tubers before surgery in tuberous sclerosis complex (TSC) patients. METHODS: Twenty-three consecutive patients, who underwent tuber resection at our institute, were retrospectively selected. A total of 125 tubers (39 epileptogenic, 86 non-epileptogenic) were used for the analysis. Tuber heterogeneity was evaluated, using a 5-point visual scale and standard deviation of ADC values (ADCsd). A 5-point visual scale reflected the degree of T1/T2 prolongation, presence of internal cystic degeneration, and their spatial distribution within the tuber. These results were statistically compared between epileptogenic and non-epileptogenic groups, and their performance in predicting the epileptogenicity was also evaluated by receiver operating characteristic (ROC) analysis. RESULTS: A 5-point visual scale demonstrated that more heterogeneous tubers were significantly more epileptogenic (p < 0.001). Multiplicity of internal cystic degeneration moderately correlated with epileptogenicity (p < 0.03) based on the comparison between class 4 and class 5 tubers. ADCsd was significantly higher in epileptogenic tubers (p < 0.001). ROC curves revealed that a 5-point visual scale demonstrated higher area under the curve (AUC) value than ADCsd (0.75 and 0.72, respectively). CONCLUSION: Tuber heterogeneity may help identify the epileptogenic tubers in presurgical TSC patients. Visual assessment and standard deviation of ADC value, which are easier to implement in clinical use, may be a useful tool predicting epileptogenic tubers, improving presurgical clinical management for TSC patients with intractable epilepsy.

Elucidation of OSW-1-Induced Stress Responses in Neuro2a Cells.

OSW-1, a steroidal saponin isolated from the bulbs of Ornithogalum saundersiae, is a promising compound for an anticancer drug; however, its cytotoxic mechanisms have not been fully elucidated. Therefore, we analyzed the stress responses triggered by OSW-1 in the mouse neuroblastoma cell line Neuro2a by comparing it with brefeldin A (BFA), a Golgi apparatus-disrupting reagent. Among the Golgi stress sensors TFE3/TFEB and CREB3, OSW-1 induced dephosphorylation of TFE3/TFEB but not cleavage of CREB3, and induction of the ER stress-inducible genes GADD153 and GADD34 was slight. On the other hand, the induction of LC3-II, an autophagy marker, was more pronounced than the BFA stimulation. To elucidate OSW-1-induced gene expression, we performed a comprehensive gene analysis using a microarray method and observed changes in numerous genes involved in lipid metabolism, such as cholesterol, and in the regulation of the ER-Golgi apparatus. Abnormalities in ER-Golgi transport were also evident in the examination of secretory activity using NanoLuc-tag genes. Finally, we established Neuro2a cells lacking oxysterol-binding protein (OSBP), which were severely reduced by OSW-1, but found OSBP deficiency had little effect on OSW-1-induced cell death and the LC3-II/LC3-I ratio in Neuro2a cells. Future work to elucidate the relationship between OSW-1-induced atypical Golgi stress responses and autophagy induction may lead to the development of new anticancer agents.

Hypomorphic mutation of PEX3 with peroxisomal mosaicism reveals the oscillating nature of peroxisome biogenesis coupled with differential metabolic activities.

Impaired peroxisome assembly caused by mutations in PEX genes results in a human congenital metabolic disease called Zellweger spectrum disorder (ZSD), which impacts the development and physiological function of multiple organs. In this study, we revealed a long-standing problem of heterogeneous peroxisome distribution among cell population, so called "peroxisomal mosaicism", which appears in patients with mild form of ZSD. We mutated PEX3 gene in HEK293 cells and obtained a mutant clone with peroxisomal mosaicism. We found that peroxisomal mosaicism can be reproducibly arise from a single cell, even if the cell has many or no peroxisomes. Using time-lapse imaging and a long-term culture experiment, we revealed that peroxisome biogenesis oscillates over a span of days; this was also confirmed in the patient's fibroblasts. During the oscillation, the metabolic activity of peroxisomes was maintained in the cells with many peroxisomes while depleted in the cells without peroxisomes. Our results indicate that ZSD patients with peroxisomal mosaicism have a cell population whose number and metabolic activities of peroxisomes can be recovered. This finding opens the way to develop novel treatment strategy for ZSD patients with peroxisomal mosaicism, who currently have very limited treatment options.

Expression analysis and functional characterization of thioredoxin domain-containing protein 11.

BACKGROUNDS: The endoplasmic reticulum (ER) is a crucial organelle that regulates both the folding, modification and transport of many proteins and senses certain stimuli inside and outside of cells. ER-associated degradation (ERAD), including SEL1L is a crucial mechanism to maintain homeostasis. In this study, we performed comparative proteome analysis in wild-type (wt) and SEL1L-deficient cells. METHODS AND RESULTS: We found constitutively high expression of thioredoxin domain-containing protein 11 (TXNDC11) mRNA and protein in our SEL1L-deficient HEK293 cells by RT-PCR and Western blot analysis. The TXNDC11 gene possesses a well-conserved unfolded protein response element (UPRE) around its transcription start site, and ER stress increased TXNDC11 mRNA and luciferase reporter activity via this putative UPRE in HEK293 cells. The amounts of TXNDC11 protein in wild-type and SEL1L-deficient cells with or without thapsigargin (Tg) treatment were parallel to their mRNAs in these cells, which was almost proportional to spliced XBP1 (sXBP1) mRNA expression. The establishment and characterization of TXNDC11-deficient HEK293 cells revealed that the expression of three different ER resident stress sensors, ATF6α, CREB3 and CREB3L2, is regulated by TXNDC11. The rate of disappearance of the three proteins by CHX treatment in wt cells was remarkably different, and the full-length CREB3L2 protein was almost completely degraded within 15 min after CHX treatment. TXNDC11 deficiency increased the expression of each full-length form under resting conditions and delayed their disappearance by CHX treatment. Interestingly, the degree of increase in full-length CREB3/CREB3L2 by TXNDC11 deficiency was apparently higher than that in full-length ATF6α. The increase in these proteins by TXNDC11 deficiency was hardly correlated with the expression of each mRNA. Treatment with ER stress inducers influenced each full-length mature form, and the difference in each full-length form observed in wt and TXNDC11-deficient cells was smaller. CONCLUSION: This study demonstrated that TXNDC11 is an ER stress-inducible gene regulated by the IRE1-sXBP1 pathway. In addition, TXNDC11 is involved in the regulation of ATF6α, CREB3 and CREB3L2 protein expression, although the contribution to the stability of these proteins is quite variable. Therefore, its further characterization will provide new insights for understanding protein homeostasis in ER physiology and pathology.

Reliable and sensitive detection of glycosaminoglycan chains with immunoblots.

Complex glycans play vital roles in many biological processes, ranging from intracellular signaling and organ development to tumor growth. Glycan expression is routinely assessed by the application of glycan-specific antibodies to cells and tissues. However, glycan-specific antibodies quite often show a large number of bands on immunoblots and it is hard to interpret the data when reliable controls are lacking. This limits the scope of glycobiology studies and poses challenges for replication. We sought to resolve this issue by developing a novel strategy that utilizes an immunoreaction enhancing technology to vastly improve the speed and quality of glycan-based immunoblots. As a representative case study, we used chondroitin sulfate glycosaminoglycan (CS-GAG) chains as the carbohydrate target and a monoclonal antibody, CS-56, as the probe. We discovered that preincubation of the antibody with its antigenic CS-GAG chain distinguishes true-positive signals from false-positive ones. We successfully applied this strategy to 10E4, a monoclonal anti heparan sulfate GAGs (HS-GAGs) antibody, where true-positive signals were confirmed by chemical HS-GAG depolymerization on the membrane. This evidence that glycan-specific antibodies can generate clear and convincing data on immunoblot with highly replicable results opens new opportunities for many facets of life science research in glycobiology.

Transcriptional regulation of the ER stress-inducible gene Sec16B in Neuro2a cells.

Endoplasmic reticulum (ER) stress responses have been demonstrated to play important roles in maintaining various cellular functions and to underlie many tissue dysfunctions. In this study, we identified Sec16B as an ER stress-inducible gene by microarray analysis of brefeldin A (BFA)-inducible genes in a mouse neuroblastoma cell-line, Neuro2a. Sec16B mRNA was induced by treatment with the ER stress-inducing reagents thapsigargin (Tg) and brefeldin A in a time-dependent manner. In the genomic sequence of the mouse Sec16B gene, we found an unfolded protein response element (UPRE), which is well conserved between humans and mice. Using luciferase reporter analyses, we showed that the UPRE in the mouse Sec16B gene was functional and responded well to ER stress-inducing stimuli and spliced XBP1 (sXBP1)-overexpression. In addition, a unique ATF4-responsive sequence within the first intron of the mouse Sec16B gene was characterized. Our study may help to elucidate the regulation of trafficking through the ER-Golgi apparatus and the biogenesis of ER-derived intracellular organelles.

Elucidation of brefeldin A-induced ER and Golgi stress responses in Neuro2a cells.

Brefeldin A (BFA) disrupts the structure of the Golgi apparatus to trigger ER stress signaling pathways. On the other hand, treatment with BFA induces the activation of CREB3, the protein structure of which is similar to that of ATF6. In this study, we established Neuro2a cells in which three different transcription factors, namely, ATF4, ATF3 and CREB3, were deficient using the CRISPR/Cas9 approach, and we investigated the BFA-induced ER and Golgi stress response in these cells. BFA treatment rapidly induced ATF4, ATF3, Herp and GADD153 protein expression in Neuro2a cells. ATF4-deficient Neuro2a cells exhibited significantly decreased mRNA and protein expression of ATF3 and Herp but not GADD153; however, cells deficient in ATF3 exhibited minimal effects on GADD34, GADD153 and Herp expression. The cleavage of CREB3 in Neuro2a cells was triggered by BFA; however, the expression of several ER and Golgi stress-related factors was hardly influenced by the CREB3 deficiency in these Neuro2a cells. This study shows that CREB3 minimally associates with typical ER stress-inducible responses in Neuro2a cells. Therefore, identification and characterization of the downstream transcriptional targets of CREB3 is required to clarify not only Golgi stress response but also its relationship with ER stress signaling pathways.

Molecular characterization of mouse CREB3 regulatory factor in Neuro2a cells.

We performed expression and functional analysis of mouse CREB3 regulatory factor (CREBRF) in Neuro2a cells by constructing several expression vectors. Overexpressed full-length (FL) CREBRF protein was stabilized by MG132; however, the intrinsic CREBRF expression in Neuro2a cells was negligible under all conditions. On the other hand, N- or C-terminal deletion of CREBRF influenced its stability. Cotransfection of CREBRF together with GAL4-tagged FL CREB3 increased luciferase reporter activity, and only the N-terminal region of CREBRF was sufficient to potentiate luciferase activity. Furthermore, this positive effect of CREBRF was also observed in cells expressing GAL4-tagged cleaved CREB3, although CREBRF hardly influenced the protein stability of NanoLuc-tagged cleaved CREB3 or intracellular localization of EGFP-tagged one. In conclusion, this study suggests that CREBRF, a quite unstable proteasome substrate, positively regulates the CREB3 pathway, which is distinct from the canonical ER stress pathway in Neuro2a cells.

Comparative Analysis of CREB3 and CREB3L2 Protein Expression in HEK293 Cells.

We performed a comparative analysis of two ER-resident CREB3 family proteins, CREB3 and CREB3L2, in HEK293 cells using pharmacological and genome editing approaches and identified several differences between the two. Treatment with brefeldin A (BFA) and monensin induced the cleavage of full-length CREB3 and CREB3L2; however, the level of the full-length CREB3 protein, but not CREB3L2 protein, was not noticeably reduced by the monensin treatment. On the other hand, treatment with tunicamycin (Tm) shifted the molecular weight of the full-length CREB3L2 protein downward but abolished CREB3 protein expression. Thapsigargin (Tg) significantly increased the expression of only full-length CREB3L2 protein concomitant with a slight increase in the level of its cleaved form. Treatment with cycloheximide and MG132 revealed that both endogenous CREB3 and CREB3L2 are proteasome substrates. In addition, kifunensine, an α-mannosidase inhibitor, significantly increased the levels of both full-length forms. Consistent with these findings, cells lacking SEL1L, a crucial ER-associated protein degradation (ERAD) component, showed increased expression of both full-length CREB3 and CREB3L2; however, cycloheximide treatment downregulated full-length CREB3L2 protein expression more rapidly in SEL1L-deficient cells than the full-length CREB3 protein. Finally, we investigated the induction of the expression of several CREB3 and CREB3L2 target genes by Tg and BFA treatments and SEL1L deficiency. In conclusion, this study suggests that both endogenous full-length CREB3 and CREB3L2 are substrates for ER-associated protein degradation but are partially regulated by distinct mechanisms, each of which contributes to unique cellular responses that are distinct from canonical ER signals.

Hormetic Effects of Binaphthyl Phosphonothioates as Pro-oxidants and Antioxidants.

Organophosphorous compounds with such a wide variety in structure, application, and biochemical activities include pesticides, herbicides, nerve agents, medicines, reagents in organic chemistry, and additives for polymers. Binaphthyl phosphono-, phosphorothioates, and their derivatives, are useful chiral catalysts for various asymmetric reactions and are expected to act as heavy metal scavengers. In this study, we aimed to evaluate the neurotoxicity and biochemical properties of a new series of binaphthyl phosphonothioates called KK compounds using the mouse hippocampal HT22 cells. Despite negligible structural difference, the compounds exhibited differential general cytotoxic activity which was independent of acetylcholine esterase inhibition; on the other hand, all compounds tested prevented endogenous oxidative stress by suppressing generation of reactive oxygen species. Among them, KK397, KK387, KK410, and KK421 showed hormesis, i.e., biphasic dose responses to endogenous oxidative stress, characterized by beneficial effect at low dose and toxic effect at high dose. At cytotoxic concentrations, these compounds were potent radical generators and activated intracellular signaling molecules such as the p38 mitogen-activated protein kinase, c-Jun NH2-terminal kinase, growth arrest- and DNA damage-inducible gene 153, X-box binding protein 1, and heme oxygenase 1, which are preferentially activated by cell stress-inducing signals, including oxidative and endoplasmic reticulum stress. These findings indicated that novel binaphthyl phosphonothioates can exhibit multiple biochemical properties, functioning as antioxidants and/or pro-oxidants, depending on the concentration, and chemical modification of binaphthyl organophosphorus compounds endowed them with unique characteristics and multiple beneficial functions.

Characterization of IRE1α in Neuro2a cells by pharmacological and CRISPR/Cas9 approaches.

IRE1 is the most conserved endoplasmic reticulum (ER)-resident stress sensor. Its activation not only splices XBP1 but also participates in a variety of cell signaling. We elucidated the role of IRE1α in Neuro2a cells by establishing IRE1α-deficient cells and applying four IRE1 inhibitors. IRE1α deficiency prevented almost all spliced XBP1 (sXBP1) protein expression by treatment with thapsigargin (Tg) and tunicamycin (Tm); these phenomena paralleled the values measured by our two Nanoluciferase-based IRE1 assays. However, cell viability and protein expression of other ER stress-responsive factors in the IRE1α-deficient cells were comparable to those in the parental wild-type cells with or without Tm treatment. Next, we elucidated the IRE1 inhibitory actions and cytotoxicity of four compounds: STF083010, KIRA6, 4µ8C, and toyocamycin. KIRA6 attenuated IRE1 activity in a dose-dependent manner, but it showed severe cytotoxicity even in the IRE1α-deficient cells at a low concentration. The IRE1α-deficient cells were slightly resistant to KIRA6 at 0.1 µM in both the presence and absence of ER stress; however, resistance was not observed at 0.02 µM. Treatment with only KIRA6 at 0.1 µM for 12 h remarkably induced LC3 II, an autophagic marker, in both parental and IRE1α-deficient cells. Co-treatment with KIRA6 and Tm induced LC3 II, cleaved caspase-9, and cleaved caspase-3; however, IRE1α-deficiency did not abolish the expression of these two cleaved caspases. On the other hand, KIRA6 prohibited Tm-induced ATF4 induction in an IRE1-independent manner; however, co-treatment with KIRA6 and Tm also induced LC3 II and two cleaved caspases in the ATF4-deficient Neuro2a cells. Thus, we demonstrate that IRE1α deficiency has little impact on cell viability and expression of ER stress-responsive factors in Neuro2a cells, and the pharmacological actions of KIRA6 include IRE1-independent ways.

Royal jelly reduces depression-like behavior through possible effects on adrenal steroidogenesis in a murine model of unpredictable chronic mild stress.

Royal jelly (RJ) is used as a dietary supplement for human health promotion. Recently, a clinical trial has reported that RJ improved mental health. The present study was conducted to experimentally support the clinical effect of RJ on mental health and to further elucidate the mechanisms of action of RJ. RJ and an ethanol extract of RJ, which contains fatty acids but not proteins, inhibited an unpredictable chronic mild stress (UCMS)-induced increase in immobility time, a depression-like behavior, in the tail suspension test. DNA microarray analysis of the adrenal grand revealed that the expression of genes involved in cholesterol metabolism was up-regulated in response to UCMS exposure and that RJ suppressed expression of genes related to cholesterol synthesis and transport. These results suggested that RJ improves stress-induced depression-like behavior by regulating adrenal steroidogenesis and that fatty acids contained in RJ partly contribute to the antidepressant effect of RJ.

[A Case of Radiation Necrosis in the Right Occipital Lobe Accompanied with Massive Hemorrhage:Histopathological Analysis].

Radiation necrosis with massive hemorrhage is a rare complication of radiotherapy. We report the case of a male patient who had undergone radiotherapy therapy 18 years earlier and presently underwent gamma knife radiosurgery for a metastatic brain tumor in his right occipital lobe. The patient showed aberrant behavior with left homonymous hemianopsia and a gradual deterioration of cognitive function after radiotherapy. A CT scan showed the presence of an intracerebral hematoma over the right occipital lobe with mass effect, and small spotty enhancements on the lesion when enhanced on gadolinium contrast-enhanced MRI. Intraoperative findings revealed necrosis of the occipital surface and a hematoma in the occipital lobe. Pathological findings showed damage to the walls of the sinusoidal capillaries and vitreous degeneration of the inner membrane with a spongiform hemangioma. After surgery, the cerebral edema resolved, and the patient's clinical symptoms improved. The cause of the radiation necrosis and bleeding in this patient was assumed to be due to the breakdown of the congested walls of the sinusoidal capillary vessels.

Azepine derivative T4FAT, a new copper chelator, inhibits tyrosinase.

Melanin plays an important role in the protection of the skin from ultraviolet irradiation. However, excessive melanin deposition leads to hyperpigmentation and freckles, which are recognized as skin problems, and signs of aging. Tyrosinase, a copper-containing protein, is the rate-limiting enzyme in melanin biosynthesis and first catalyzes the hydroxylation of l-tyrosine to 3,4-dihydroxyphenylalanine (DOPA) and the further oxidization to dopaquinone. To assist the proper regulation of melanin production, we screened compounds and found that 5,6,7,8-tetrahydro-4H-furo[3,2-c]azepine-4-thione (T4FAT), a thioamide derivative, inhibited melanogenesis in B16F10 mouse melanoma cells. T4FAT was not toxic to cells and was stable in water; in addition, it inhibited the activity of tyrosinase derived from mushroom and B16F10 cells in a non-competitive manner. T4FAT downregulated tyrosinase protein expression in B16F10 cells without affecting mRNA expression. As copper binding to the tyrosinase protein is required for both enzymatic activity, correct folding, and maturation, we examined the metal-chelating activities of T4FAT. Equimolar amount of T4FAT resulted in almost complete chelation of copper ions. The thioamide group of T4FAT is essential for copper chelation and tyrosinase inhibition, which subsequently resulted in melanogenesis inhibition in B16F10 cells. Although T4FAT has similar in vitro properties to kojic acid, which is also a copper chelator and approved as a component of cosmetic formulations, T4FAT inhibited melanogenesis in B16F10 cells 30 times more efficiently than kojic acid. These results suggested that T4FAT, a novel copper chelator, may be helpful for the development of new cosmetics for skin whitening.

Functional validation of ATF4 and GADD34 in Neuro2a cells by CRISPR/Cas9-mediated genome editing.

Activating transcription factor 4 (ATF4), which is ubiquitously expressed, plays a crucial role in regulating various stress-responsive genes under pathophysiological conditions. Further, growth arrest and DNA damage-inducible gene 34 (GADD34), a downstream target of ATF4, has been reported to negatively regulate ATF4 expression. To understand the relationship between intrinsic ATF4 and GADD34 under resting and ER stress conditions, we used a novel gene editing approach, CRISPR/Cas9, to integrate antibiotic-resistant genes into the target genes, ATF4 and GADD34. First, we manipulated the ATF4 gene in the mouse neuroblastoma cell line, Neuro2a, and compared the ER stress responses between parental and ATF4-edited Neuro2a cells. Next, we established Neuro2a cells with edited GADD34 and ATF4/GADD34 genes and found that ATF4 acts as a proapoptotic factor, but GADD34 depletion did not attenuate the expression of cleaved caspase-3 induced by tunicamycin treatment. These findings provide new insights into the ATF4 signaling cascades. Additionally, the rapid establishment of cells lacking multiple genes using this CRISPR/Cas9 system will be a powerful tool for exploring various cellular issues under pathophysiological conditions.