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The oral delivery of nano-drug delivery systems (Nano-DDS) remains a challenge. Taking inspirations from viruses, here we construct core–shell mesoporous silica nanoparticles (NPs, ~80 nm) with virus-like nanospikes (VSN) to simulate viral morphology, and further modified VSN with L-alanine (CVSN) to enable chiral recognition for functional bionics. By comparing with the solid silica NPs, mesoporous silica NPs and VSN, we demonstrate the delivery advantages of CVSN on overcoming intestinal sequential barriers in both animals and human via multiple biological processes. Subsequently, we encapsulate indomethacin (IMC) into the nanopores of NPs to mimic gene package, wherein the payloads are isolated from bio-environments and exist in an amorphous form to increase their stability and solubility, while the chiral nanospikes multi-sited anchor and chiral recognize on the intestinal mucosa to enhance the penetrability and ultimately improve the oral adsorption of IMC. Encouragingly, we also prove the versatility of CVSN as oral Nano-DDS. The oral delivery of nano-drug delivery systems (Nano-DDS) remains challenging. Here the authors construct core–shell mesoporous silica nanoparticles with virus-like nanospikes and demonstrate the versatility of these nanoparticles as Nano-DDS to achieve efficient oral drug delivery by mimicking structural feature, chiral recognition, and gene encapsulation of viruses.

Tumor immune evasion and incomplete responses to immunotherapy are some of the most significant obstacles in current cancer treatment. Since tumor-draining LNs (tdLNs) are cradles for anti-tumor immunity, and tumor-specific memory cells in tdLNs are the bona fide responders to immune-checkpoint blockade, tdLNs are increasingly valued in oncoimmunology research and cancer treatments. Recent progress has revealed that lymph nodes (LNs) are innervated and regulated by sensory and sympathetic nerve fibers. Because tumor cells, nerves, and immune cells coexist inside tdLNs—sites where anti-tumor immunity is initiated and compromised—it is critical to investigate whether tumor-neuro-immune crosstalk also occurs in these nodes. Although direct evidence in tdLNs is lacking, we synthesize emerging evidence supporting this possibility. We argue that validating this hypothesis will be essential for elucidating immune evasion mechanisms and advancing surgical and immunological strategies against tumors. In this review, we first introduce LN anatomy, highlighting its innervation by sensory and sympathetic fibers. We then examine the neural regulation of immune activities, especially those within LNs and those associated with a tumor context. We further discuss the multifaceted roles of tdLNs in tumor immunology, including orchestration of anti-tumor immunity and local immunosuppression, pre-metastatic LN remodeling, and induction of systemic tumor-specific immune tolerance. Furthermore, we look into tumor-neural interactions from two angles: tumor-induced nerve growth and activation, and neural regulation of tumor progression. Finally, we propose potential tumor-neuro-immune interactions in tdLNs, discuss current perspectives on LN handling in cancer therapy, and discuss clinical implications of the progress summarized in this review.

Understanding the liver stem cells (LSCs) holds great promise for new insights into liver diseases and liver regeneration. However, the heterogenicity and plasticity of liver cells have made it controversial. Here, by employing single‐cell RNA‐sequencing technology, transcriptome features of Krt19+ bile duct lineage cells isolated from Krt19CreERT; Rosa26R‐GFP reporter mouse livers are examined. Distinct biliary epithelial cells which include adult LSCs, as well as their downstream hepatocytes and cholangiocytes are identified. Importantly, a novel cell surface LSCs marker, CD63, as well as CD56, which distinguished active and quiescent LSCs are discovered. Cell expansion and bi‐potential differentiation in culture demonstrate the stemness ability of CD63+ cells in vitro. Transplantation and lineage tracing of CD63+ cells confirm their contribution to liver cell mass in vivo upon injury. Moreover, CD63+CD56+ cells are proved to be activated LSCs with vigorous proliferation ability. Further studies confirm that CD63+CD56− quiescent LSCs express VEGFR2 and FGFR1, and they can be activated to proliferation and differentiation through combination of growth factors: VEGF‐A and bFGF. These findings define an authentic adult liver stem cells compartment, make a further understanding of fate regulation on LSCs, and highlight its contribution to liver during pathophysiologic processes. Single‐cell RNA sequencing analysis reveals and describes a stem cell population in the biliary epithelial cells of the liver. Liver stem cells contain quiescent (CD63+CD56−) and active states (CD63+CD56+). Quiescent liver stem cells express receptors VEGFR2 and FGFR1, which can be further activated through VEGF and FGF signaling, and participate in the liver injury repair.

The natural product α-cyclopiazonic acid (α-CPA) is a very potent Ca2+-ATPase inhibitor. The CPA family of compounds comprise over 80 chemical entities with at least five distinct skeletons. While α-CPA features a canonical 6/5/6/5/5 skeleton, the 6/5/6/5 skeleton is the most prevalent among the CPA family. However, the origin of the unique tetracyclic skeleton remains unknown. The 6/5/6/5-type CPAs may derive from a precursor of acetoacetyl-l-tryptophan (AATrp) generated from a hypothetic thioesterase-like pathway. Alternatively, cleavage of the tetramic acid ring would also result in the formation of the 6/5/6/5 scaffold. Aspergillus oryzae HMP-F28 is a marine sponge-associated filamentous fungus known to produce CPAs that act as primary neurotoxins. To elucidate the origin of this subfamily of CPAs, we performed homologous recombination and genetic engineering experiments on strain HMP-F28. Our results are supportive of the ring cleavage pathway through which the tetracyclic 6/5/6/5-type CPAs are generated from 6/5/6/5/5-type pentacyclic CPAs.

Hydrogen sulfide (H S), the third bio-active gasotransmitter, is produced endogenously and tightly involved in the pathogenesis and treatment for various diseases. Adenosine 5'-monophosphate-activated protein kinase (AMPK) plays a paramount role in maintaining cellular energetic balance. Increasing evidences have also suggested AMPK as a novel modulator in multiple pathological conditions. In this paper, we will review the biological principles of H S and AMPK, and most importantly, the recent discoveries regarding AMPK-mediated pharmacological actions of H S. Emphasis will be laid on AMPK/H S interactions in the cardiovascular system, autophagy, diabetic complications, and inflammation. In most cases described in this article, by promoting AMPK activation, H S exerts cytoprotective effects or therapeutic potentials, though there remain some controversies before we can fully understand the involved mechanisms. Further researches are in need to investigate more closely any relationship between H S and AMPK, and to put forward the development of H S donors for clinical application.

Anemia of inflammation (AI) is clinically prevalent and greatly threatens public health. Traditional remedies have raised controversy during clinical practice, calling for alternative therapies. We have recently found that hydrogen sulfide (H2S) inhibits inflammatory hepcidin, the critical mediator of AI. However, due to the chemical property of H2S, there remains an urgent need for a stable H2S donor in AI treatment. Here we reported that S-propargyl-cysteine (SPRC), a novel water-soluble H2S donor, suppressed hepatic hepcidin and corrected hypoferremia induced by lipopolysaccharide. The effects of SPRC were reversed by inhibition of cystathionine γ-lyase, one of the major endogenous H2S synthases. Moreover, SPRC reduced serum hepcidin, improved transferrin saturation, and maintained erythrocyte membrane integrity in a chronic mouse AI model. Consistently, splenomegaly was ameliorated and splenic iron accumulation relieved. Mechanism study indicated that serum IL-6 content and hepatic Il-6 mRNA were decreased by SPRC, in parallel with reduced hepatic JAK2/STAT3 activation. On the whole, our data reveal the inhibition of inflammatory hepcidin by SPRC, and suggest SPRC as a potential remedy against AI.

Hepatocarcinogenesis is initiated by repeated hepatocyte death and liver damage, and the underlying mechanisms mediating cell death and the subsequent carcinogenesis remain to be fully investigated. Immunoresponsive gene 1 (IRG1) and its enzymatic metabolite itaconate are known to suppress inflammation in myeloid cells, and its expression in liver parenchymal hepatocytes is currently determined. However, the potential roles of IRG1 in hepatocarcinogenesis are still unknown. Here, using the diethylnitrosamine (DEN)-induced hepatocarcinogenesis mouse model, we found that IRG1 expression in hepatocytes was markedly induced upon DEN administration. The DEN-induced IRG1 was then determined to promote the intrinsic mitochondrial apoptosis of hepatocytes and liver damage, thus enhancing the subsequent hepatocarcinogenesis. Mechanistically, the mitochondrial IRG1 could associate and trap anti-apoptotic MCL-1 to inhibit the interaction between MCL-1 and pro-apoptotic Bim, thus promoting Bim activation and downstream Bax mitochondrial translocation, and then releasing cytochrome c and initiating apoptosis. Thus, the inducible mitochondrial IRG1 promotes hepatocyte apoptosis and the following hepatocarcinogenesis, which provides mechanistic insight and a potential target for preventing liver injury and HCC.

ObjectiveTo compare preconception disease-activity indices—systemic lupus erythematosus Disease Activity Score low disease activity (SLE-DAS LDA), lupus low disease activity state (LLDAS) and SLE-DAS remission—with Definitions of Remission in SLE (DORIS) remission in predicting adverse maternal and fetal outcomes among pregnant women with SLE.MethodsThis retrospective cohort study included 202 pregnancies in 196 women with SLE managed at Shenzhen People’s Hospital between January 2017 and December 2024. Preconception disease activity was categorised using SLE-DAS, LLDAS and DORIS remission criteria. Main outcomes were maternal flares and fetal outcomes, including spontaneous abortion, therapeutic abortion, total fetal loss, preterm delivery and small for gestational age (SGA). Predictive accuracies of indices were compared.ResultsPreconceptionally, 127 pregnancies (62.8%) met LLDAS, 131 (64.9%) met SLE-DAS LDA and 78 (38.6%) achieved DORIS remission. Compared with higher disease activity, SLE-DAS LDA was associated with fewer maternal flares (22.1% vs 45.1%) and therapeutic abortions (6.4% vs 15.7%). LLDAS was associated with lower rates of flare (21.3% vs 45.3%), therapeutic abortion (7.9% vs 17.3%), total fetal loss (19.7% vs 34.2%) and preterm delivery (22.0% vs 25.3%). SLE-DAS and DORIS remission performed similarly for maternal outcomes, while DORIS remission correlated more strongly with favourable fetal outcomes, including lower total fetal loss (15.4% vs 31.5%), preterm delivery (15.4% vs 28.2%) and SGA (9.0% vs 19.4%). Multivariable analyses confirmed that achieving these disease-activity states preconception independently protected against total fetal loss, maternal flare and therapeutic abortion. LLDAS was the best overall predictor, while SLE-DAS LDA was the most attainable and predictive for maternal complications.ConclusionSLE-DAS LDA effectively predicts maternal complication, while LLDAS better identifies fetal risk. Remission offers similar protection but is less attainable, suggesting LDA suffices for conception planning. Optimising preconception disease control remains essential and warrants multicentre validation.

Hepatocellular carcinoma (HCC) is a common cancer with poor prognosis worldwide and the molecular mechanism is not well understood. This study aimed to establish a collection of human HCC cell lines from patient-derived xenograft (PDX) models. From the 20 surgical HCC sample collections, 7 tumors were successfully developed in immunodeficient mice and further established 7 novel HCC cell lines (LIXC002, LIXC003, LIXC004, LIXC006, LIXC011, LIXC012 and CPL0903) by primary culture. The characterization of cell lines was defined by morphology, growth kinetics, cell cycle, chromosome analysis, short tandem repeat (STR) analysis, molecular profile, and tumorigenicity. Additionally, response to clinical chemotherapeutics was validated both in vitro and in vivo. STR analysis indicated that all cell lines were unique cells different from known cell lines and free of contamination by bacteria or mycoplasma. The other findings were quite heterogeneous between individual lines. Chromosome aberration could be found in all cell lines. Alpha-fetoprotein was overexpressed only in 3 out of 7 cell lines. 4 cell lines expressed high level of vimentin. Ki67 was strongly stained in all cell lines. mRNA level of retinoic acid induced protein 3 (RAI3) was decreased in all cell lines. The 7 novel cell lines showed variable sensitivity to 8 tested compounds. LIXC011 and CPL0903 possessed multiple drug resistance property. Sorafenib inhibited xenograft tumor growth of LIXC006, but not of LIXC012. Our results indicated that the 7 novel cell lines with low passage maintaining their clinical and pathological characters could be good tools for further exploring the molecular mechanism of HCC and anti-cancer drug screening.

Selective treatments for myocardial infarction (MI) induced cardiac fibrosis are lacking. In this study, we focus on the therapeutic potential of a synthetic cardio-protective agent named ZYZ-168 towards MI-induced cardiac fibrosis and try to reveal the underlying mechanism. ZYZ-168 was administered to rats with coronary artery ligation over a period of six weeks. Ecocardiography and Masson staining showed that ZYZ-168 substantially improved cardiac function and reduced interstitial fibrosis. The expression of α–smooth muscle actin (α-SMA) and Collagen I were reduced as was the activity of matrix metalloproteinase 9 (MMP-9). These were related with decreased phosphorylation of ERK1/2 and expression of Rho-associated coiled-coil containing protein kinase 1 (ROCK1). In cardiac fibroblasts stimulated with TGF-β1, phenotypic switches of cardiac fibroblasts to myofibroblasts were observed. Inhibition of ERK1/2 phosphorylation or knockdown of ROCK1 expectedly reduced TGF-β1 induced fibrotic responses. ZYZ-168 appeared to inhibit the fibrotic responses in a concentration dependent manner, in part via a decrease in ROCK 1 expression through inhibition of the phosphorylation status of ERK1/2. For inhibition of ERK1/2 phosphorylation with a specific inhibitor reduced the activation of ROCK1. Considering its anti-apoptosis activity in MI, ZYZ-168 may be a potential drug candidate for treatment of MI-induced cardiac fibrosis.