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41 result(s) for "Nam, Tae-Wook"
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Akkermansia muciniphila secretes a glucagon-like peptide-1-inducing protein that improves glucose homeostasis and ameliorates metabolic disease in mice
The gut microbiota, which includes Akkermansia muciniphila , is known to modulate energy metabolism, glucose tolerance, immune system maturation and function in humans 1 – 4 . Although A. muciniphila is correlated with metabolic diseases and its beneficial causal effects were reported on host metabolism 5 – 8 , the molecular mechanisms involved have not been identified. Here, we report that A. muciniphila increases thermogenesis and glucagon-like peptide-1 (GLP-1) secretion in high-fat-diet (HFD)-induced C57BL/6J mice by induction of uncoupling protein 1 in brown adipose tissue and systemic GLP-1 secretion. We apply fast protein liquid chromatography and liquid chromatography coupled to mass spectrophotometry analysis to identify an 84 kDa protein, named P9, that is secreted by A. muciniphila . Using L cells and mice fed on an HFD, we show that purified P9 alone is sufficient to induce GLP-1 secretion and brown adipose tissue thermogenesis. Using ligand–receptor capture analysis, we find that P9 interacts with intercellular adhesion molecule 2 (ICAM-2). Interleukin-6 deficiency abrogates the effects of P9 in glucose homeostasis and downregulates ICAM-2 expression. Our results show that the interactions between P9 and ICAM-2 could be targeted by therapeutics for metabolic diseases. Akkermansia muciniphila produces P9, a small protein that interacts with intercellular adhesion molecule 2 to increase thermogenesis and glucagon-like peptide-1 secretion in mice.
Lactobacillus acidophilus KBL409 improves serum indoxyl sulfate via gut microbial changes in a human study
Chronic kidney disease (CKD) is characterized by progressive attenuation of kidney functions, resulting in the accumulation of uremic toxins. Various symptoms for CKD are closely associated with the gut-kidney axis, which represents the interaction between gut microbiota and CKD. In this study, we investigated the effects of Lactobacillus acidophilus ( L. acidophilus ) KBL409 on uremic toxin concentrations using a multi-center, randomized, double-blind, placebo-controlled study. Participants in the L. acidophilus KBL409 group received a daily capsule containing 1 × 10 10 colony-forming units of L. acidophilus KBL409 or placebo. The per protocol analysis included 34 participants in the L. acidophilus KBL409 group and 30 participants in the placebo group. After 16 weeks, the serum indoxyl sulfate (IS) concentration was significantly lower in the L. acidophilu s KBL409 group than in the placebo group ( p  < 0.05). Additionally, significant reductions in the genera Blautia , Butyricicoccus, Lachnospiraceae UCG-004, and Megamonas were observed in the L. acidophilus KBL409 group. These bacteria exhibited positive correlations with predicted functional genes linked to uremic toxin synthesis pathways, suggesting that L. acidophilus KBL409 reduced serum IS by altering gut microbial compositions. Therefore, L. acidophilus KBL409 could be used as an effective probiotic for improving kidney health through gut microbiota modulation.
The position of the target site for engineered nucleases improves the aberrant mRNA clearance in in vivo genome editing
Engineered nucleases are widely used for creating frameshift or nonsense mutations in the target genes to eliminate gene functions. The resulting mRNAs carrying premature termination codons can be eliminated by nonsense-mediated mRNA decay. However, it is unclear how effective this process would be in vivo . Here, we found that the nonsense-mediated decay was unable to remove the mutant mRNAs in twelve out of sixteen homozygous mutant mice with frameshift mutations generated using engineered nucleases, which is far beyond what we expected. The frameshift mutant proteins translated by a single nucleotide deletion within the coding region were also detected in the p53 mutant mice. Furthermore, we showed that targeting the exons present downstream of the exons with a start codon or distant from ATG is relatively effective for eliminating mutant mRNAs in vivo , whereas the exons with a start codon are targeted to express the mutant mRNAs. Of the sixteen mutant mice generated, only four mutant mice targeting the downstream exons exhibited over 80% clearance of mutant mRNAs. Since the abnormal products, either mutant RNAs or mutant proteins, expressed by the target alleles might obscure the outcome of genome editing, these findings will provide insights in the improved performance of engineered nucleases when they are applied in vivo .
Differences between immunodeficient mice generated by classical gene targeting and CRISPR/Cas9-mediated gene knockout
Immunodeficient mice are widely used for pre-clinical studies to understand various human diseases. Here, we report the generation of four immunodeficient mouse models using CRISPR/Cas9 system without inserting any foreign gene sequences such as NeoR cassettes and their characterization. By eliminating any possible effects of adding a NeoR cassette, our mouse models may allow us to better elucidate the in vivo functions of each gene. Our FVB-Rag2−/−, B6-Rag2−/−, and BALB/c-Prkdc−/− mice showed phenotypes similar to those of the earlier immunodeficient mouse models, including a lack of mature B cells and T cells and an increase in the number of CD45+DX-5+ natural killer cells. However, B6-Il2rg−/− mice had a unique phenotype, with a lack of mature B cells, increased number of T cells, and decreased number of natural killer cells. Additionally, serum immunoglobulin levels in all four immunodeficient mouse models were significantly reduced when compared to those in wild-type mice with the exception of IgM in B6-Il2rg−/− mice. These results indicate that our immunodeficient mouse models are a robust tool for in vivo studies of the immune system and will provide new insights into the variation in phenotypic outcomes resulting from different gene-targeting methodologies.
Dysfunctional adipocytes promote tumor progression through YAP/TAZ-dependent cancer-associated adipocyte transformation
Obesity has emerged as a prominent risk factor for the development of malignant tumors. However, the existing literature on the role of adipocytes in the tumor microenvironment (TME) to elucidate the correlation between obesity and cancer remains insufficient. Here, we aim to investigate the formation of cancer-associated adipocytes (CAAs) and their contribution to tumor growth using mouse models harboring dysfunctional adipocytes. Specifically, we employ adipocyte-specific BECN1 KO (BaKO) mice, which exhibit lipodystrophy due to dysfunctional adipocytes. Our results reveal the activation of YAP/TAZ signaling in both CAAs and BECN1-deficient adipocytes, inducing adipocyte dedifferentiation and formation of a malignant TME. The additional deletion of YAP/TAZ from BaKO mice significantly restores the lipodystrophy and inflammatory phenotypes, leading to tumor regression. Furthermore, mice fed a high-fat diet (HFD) exhibit decreased BECN1 and increased YAP/TAZ expression in their adipose tissues. Treatment with the YAP/TAZ inhibitor, verteporfin, suppresses tumor progression in BaKO and HFD-fed mice, highlighting its efficacy against mice with metabolic dysregulation. Overall, our findings provide insights into the key mediators of CAA and their significance in developing a TME, thereby suggesting a viable approach targeting adipocyte homeostasis to suppress cancer growth. The impact of obesity on cancer remains insufficiently explored. Here the authors show that in mouse models, dysfunctional adipocytes exhibit low levels of BECN1 which induce YAP/TAZ activity to promote breast and colorectal tumor progression.
Ei24 deficiency in brown adipocytes induces severe hypothermia under cold stress independent of UCP1 activity
Brown adipocytes facilitate non-shivering thermogenesis, which is critical for maintaining energy balance and heat production in response to environmental stimuli. Here, we delineate the physiological and biochemical role of etoposide-induced 2.4 ( Ei24 ) in adenosine triphosphate (ATP) production and thermogenesis in brown adipocytes. We generated Ei24 adipocyte-specific knockout (EiaKO) mice that exhibited brown adipose tissue hypertrophy, lipid accumulation, and various mitochondrial abnormalities. Despite mitochondrial defects, uncoupling protein 1 (UCP1) expression and activity remained unchanged. However, those impairments caused lethal hypothermia in mice subjected to cold challenge, underscoring the key role of Ei24 in mitochondrial functions. Mechanistically, Ei24 deficiency disrupted cristae structure, dissipated mitochondrial membrane potential, and reduced matrix pH, leading to severe ATP depletion. We further identify the C-terminal region of Ei24 as essential for supporting ATP synthase function. Those bioenergetic defects not only destabilized the mitochondrial environment necessary for efficient UCP1-mediated thermogenesis, but also impaired ATP-dependent futile cycles such as SERCA-mediated calcium cycling and creatine substrate cycling. Together, our findings indicate that Ei24 functions as a thermogenic regulator that ensures mitochondrial ATP synthesis and structural integrity, enabling both coupled and uncoupled respiration in brown adipose tissue. This study shows that loss of Ei24 in brown adipocytes disrupts mitochondrial function and leads to hypothermia under cold stress. The findings reveal a UCP1-independent mechanism of thermoregulation with implications for energy metabolism.
Lactobacillus acidophilus KBL409 protects against kidney injury via improving mitochondrial function with chronic kidney disease
Purpose Recent advances have led to greater recognition of the role of mitochondrial dysfunction in the pathogenesis of chronic kidney disease (CKD). There has been evidence that CKD is also associated with dysbiosis. Here, we aimed to evaluate whether probiotic supplements can have protective effects against kidney injury via improving mitochondrial function. Methods An animal model of CKD was induced by feeding C57BL/6 mice a diet containing 0.2% adenine. KBL409, a strain of Lactobacillus acidophilus, was administered via oral gavage at a dose of 1 × 10 9  CFU daily. To clarify the underlying mechanisms by which probiotics exert protective effects on mitochondria in CKD, primary mouse tubular epithelial cells stimulated with TGF-β and p-cresyl sulfate were administered with butyrate. Results In CKD mice, PGC-1α and AMPK, key mitochondrial energy metabolism regulators, were down-regulated. In addition, mitochondrial dynamics shifted toward fission, the number of fragmented cristae increased, and mitochondrial mass decreased. These alterations were restored by KBL409 administration. KBL409 supplementation also improved defects in fatty acid oxidation and glycolysis and restored the suppressed enzyme levels involved in TCA cycle. Accordingly, there was a concomitant improvement in mitochondrial respiration and ATP production assessed by mitochondrial function assay. These favorable effects of KBL409 on mitochondria ultimately decreased kidney fibrosis in CKD mice. In vitro analyses with butyrate recapitulated the findings of animal study. Conclusions This study demonstrates that administration of the probiotic Lactobacillus acidophilus KBL409 protects against kidney injury via improving mitochondrial function.
Proteins Needed to Activate a Transcriptional Response to the Reactive Oxygen Species Singlet Oxygen
Singlet oxygen ( 1 O 2 ) is a reactive oxygen species generated by energy transfer from one or more excited donors to molecular oxygen. Many biomolecules are prone to oxidation by 1 O 2 , and cells have evolved systems to protect themselves from damage caused by this compound. One way that the photosynthetic bacterium Rhodobacter sphaeroides protects itself from 1 O 2 is by inducing a transcriptional response controlled by ChrR, an anti-σ factor which releases an alternative sigma factor, σ E , in the presence of 1 O 2 . Here we report that induction of σ E -dependent gene transcription is decreased in the presence of 1 O 2 when two conserved genes in the σ E regulon are deleted, including one encoding a cyclopropane fatty acid synthase homologue (RSP2144) or one encoding a protein of unknown function (RSP1091). Thus, we conclude that RSP2144 and RSP1091 are each necessary to increase σ E activity in the presence of 1 O 2 . In addition, we found that unlike in wild-type cells, where ChrR is rapidly degraded when 1 O 2 is generated, turnover of this anti-σ factor is slowed when cells lacking RSP2144, RSP1091, or both of these proteins are exposed to 1 O 2 . Further, we demonstrate that the organic hydroperoxide tert -butyl hydroperoxide promotes ChrR turnover in both wild-type cells and mutants lacking RSP2144 or RSP1091, suggesting differences in the ways different types of oxidants increase σ E activity. IMPORTANCE Oxygen serves many crucial functions on Earth; it is produced during photosynthesis and needed for other pathways. While oxygen is relatively inert, it can be converted to reactive oxygen species (ROS) that destroy biomolecules, cause disease, or kill cells. When energy is transferred to oxygen, the ROS singlet oxygen is generated. To understand how singlet oxygen impacts cells, we study the stress response to this ROS in Rhodobacter sphaeroides , a bacterium that, like plants, generates this compound as a consequence of photosynthesis. This paper identifies proteins that activate a stress response to singlet oxygen and shows that they act in a specific response to this ROS. The identified proteins are found in many free-living, symbiotic, or pathogenic bacteria that can encounter singlet oxygen in nature. Thus, our findings provide new information about a stress response to a ROS of broad biological, agricultural, and biomedical importance. Oxygen serves many crucial functions on Earth; it is produced during photosynthesis and needed for other pathways. While oxygen is relatively inert, it can be converted to reactive oxygen species (ROS) that destroy biomolecules, cause disease, or kill cells. When energy is transferred to oxygen, the ROS singlet oxygen is generated. To understand how singlet oxygen impacts cells, we study the stress response to this ROS in Rhodobacter sphaeroides , a bacterium that, like plants, generates this compound as a consequence of photosynthesis. This paper identifies proteins that activate a stress response to singlet oxygen and shows that they act in a specific response to this ROS. The identified proteins are found in many free-living, symbiotic, or pathogenic bacteria that can encounter singlet oxygen in nature. Thus, our findings provide new information about a stress response to a ROS of broad biological, agricultural, and biomedical importance.
The flavonoid quercetin induces apoptosis and inhibits migration through a MAPK-dependent mechanism in osteoblasts
The present study was undertaken to evaluate effects of quercetin, a major dietary flavonoid occurring in foods of plant origin, on cell viability and migration of osteoblastic cells. Quercetin inhibited cell viability, which was largely attributed to apoptosis, in a dose-and time-dependent manner in osteoblastic cells. Similar cytotoxicity of quercetin was observed in adipose tissue-derived stromal cells. Quercetin exerted a protective effect against H 2 O 2 -induced cell death, whereas it increased TNF-α-induced cell death. Western blot analysis showed that quercetin induced activation of ERK and p38, but not JNK. Quercetin-induced cell death was prevented by the ERK inhibitor PD98059, but not by inhibitors of p38 and JNK. Quercetin increased Bax expression and caused depolarization of mitochondrial membrane potential, which were inhibited by PD98059. Quercetin induced caspase-3 activation, and the quercetininduced cell death was prevented by caspase inhibitors. Quercetin inhibited cell migration, and its effect was prevented by inhibitors of ERK and p38. Taken together, these findings suggest that quercetin induces apoptosis through a mitochondria-dependent mechanism involving ERK activation and inhibits migration through activation of ERK and p38 pathways. Quercetin may exert both protective and deleterious effects in bone repair.