Innovation and evaluation of vocational pharmaceutical education system under the 1 + X certificate system in China.

BACKGROUND AND OBJECTIVES: The 1 + X certificate system, introduced in China in 2019, integrates academic credentials with vocational skill certificates to meet the heightened demand for skilled talents in the growing economy. This study aims to innovate and evaluate the vocational pharmaceutical education system under the 1 + X certificate framework, specifically addressing the gap between theoretical education and workplace requirements. MATERIALS AND METHODS: A retrospective observational approach analyzed 490 pharmacy students over two academic years. The 2021 cohort underwent 1 + X integrated education, while the 2020 cohort followed conventional education. We collaborated closely with industry partners to identify and compile typical job competencies, formulating work projects aligned with industry demands. Combining the skill level standards and assessment content of "1+X Pharmaceutical Purchasing and Sales" and "1+X Pharmaceutical Preparation", we revised the course standards, incorporating typical work projects into the 2021 pharmacy professional teaching curriculum. This constituted the fundamental content of the 1 + X education reform. Statistical analysis compared course scores and 1 + X certificate examination performance. RESULTS: The 2021 cohort, under the 1 + X educational model, demonstrated higher average scores in pharmacy courses, with significant improvements in pharmacology (1 + X vs. Traditional education: 58.40 ± 14.20 vs. 53.44 ± 14.67), clinical pharmacotherapy (72.74 ± 10.28 vs. 63.15 ± 11.03), and pharmaceutical distribution and marketing (79.34 ± 10.96 vs. 67.50 ± 15.82). 1 + X certificate pass rates and satisfaction with the model were also higher than the 2020 cohort. CONCLUSION: The 1 + X certificate system is useful for developing talent in Chinese vocational education, effectively integrating assessments with industry standards. Future research should aim at evaluating long-term outcomes and improving quantitative skills assessments for enhanced effectiveness.

Centrifugo-Pneumatic Reciprocating Flowing Coupled with a Spatial Confinement Strategy for an Ultrafast Multiplexed Immunoassay.

Immunoassays serve as powerful diagnostic tools for early disease screening, process monitoring, and precision treatment. However, the current methods are limited by high costs, prolonged processing times (>2 h), and operational complexities that hinder their widespread application in point-of-care testing. Here, we propose a novel centrifugo-pneumatic reciprocating flowing coupled with spatial confinement strategy, termed PRCM, for ultrafast multiplexed immunoassay of pathogens on a centrifugal microfluidic platform. Each chip consists of four replicated units; each unit allows simultaneous detection of three targets, thereby facilitating high-throughput parallel analysis of multiple targets. The PRCM platform enables sequential execution of critical steps such as solution mixing, reaction, and drainage by coordinating inherent parameters, including motor rotation speed, rotation direction, and acceleration/deceleration. By integrating centrifugal-mediated pneumatic reciprocating flow with spatial confinement strategies, we significantly reduce the duration of immune binding from 30 to 5 min, enabling completion of the entire testing process within 20 min. As proof of concept, we conducted a simultaneous comparative test on- and off-the-microfluidics using 12 negative and positive clinical samples. The outcomes yielded 100% accuracy in detecting the presence or absence of the SARS-CoV-2 virus, thus highlighting the potential of our PRCM system for multiplexed point-of-care immunoassays.

High-throughput and proteome-wide discovery of endogenous biomolecular condensates.

Phase separation inside mammalian cells regulates the formation of the biomolecular condensates that are related to gene expression, signalling, development and disease. However, a large population of endogenous condensates and their candidate phase-separating proteins have yet to be discovered in a quantitative and high-throughput manner. Here we demonstrate that endogenously expressed biomolecular condensates can be identified across a cell's proteome by sorting proteins across varying oligomeric states. We employ volumetric compression to modulate the concentrations of intracellular proteins and the degree of crowdedness, which are physical regulators of cellular biomolecular condensates. The changes in degree of the partition of proteins into condensates or phase separation led to varying oligomeric states of the proteins, which can be detected by coupling density gradient ultracentrifugation and quantitative mass spectrometry. In total, we identified 1,518 endogenous condensate proteins, of which 538 have not been reported before. Furthermore, we demonstrate that our strategy can identify condensate proteins that respond to specific biological processes.

USP10 strikes down ß-catenin by dual-wielding deubiquitinase activity and phase separation potential.

Wnt/ß-catenin signaling is a conserved pathway crucially governing development, homeostasis, and oncogenesis. Discoveries of its regulators hold great values in both basic and translational research. Through screening, we identified a deubiquitinase, USP10, as a critical modulator of ß-catenin. Mechanistically, USP10 binds to key scaffold Axin1 via conserved motifs and stabilizes Axin1 through K48-linked deubiquitination. Surprisingly, USP10 physically tethers Axin1 and ß-catenin and promotes the phase separation for ß-catenin suppression regardless of the enzymatic activity. Function-wise, USP10 enzymatic activity preferably regulates embryonic development and both the enzymatic activity and physical function jointly control intestinal homeostasis by antagonizing ß-catenin. In colorectal cancer, USP10 substantially represses cancer growth mainly through physical promotion of phase separation and correlates with Wnt/ß-catenin magnitude clinically. Collectively, we discovered USP10 functioning in multiple biological processes against ß-catenin and unearthed the enzyme-dependent and -independent "dual-regulating" mechanism. These two functions of USP10 work in parallel and are context dependent.

Site-specific, covalent immobilization of PNGase F on magnetic particles mediated by microbial transglutaminase.

In the workflow of global N-glycosylation analysis, endoglycosidase-mediated removal of glycans from glycoproteins is an essential and rate-limiting step. Peptide-N-glycosidase F (PNGase F) is the most appropriate and efficient endoglycosidase for the removal of N-glycans from glycoproteins prior to analysis. Due to the high demand for PNGase F in both basic and industrial research, convenient and efficient methods are urgently needed to generate PNGase F, preferably in the immobilized form to solid phases. However, there is no integrated approach to implement both efficient expression, and site-specific immobilization of PNGase F. Herein, efficient production of PNGase F with a glutamine tag in Escherichia coli and site-specific covalent immobilization of PNGase F with this special tag via microbial transglutaminase (MTG) is described. PNGase F was fused with a glutamine tag to facilitate the co-expression of proteins in the supernatant. The glutamine tag was covalently and site-specifically transformed to primary amine-containing magnetic particles, mediated by MTG, to immobilize PNGase F. Immobilized PNGase F could deglycosylate substrates with identical enzymatic performance to that of the soluble counterpart, and exhibit good reusability and thermal stability. Moreover, the immobilized PNGase F could also be applied to clinical samples, including serum and saliva.

New era of medical education: asynchronous and synchronous online teaching during and after COVID-19.

COVID-19 struck the world suddenly and unexpectedly. Since traditional education requires face-to-face communication, to avoid further spreading of the virus a majority part of that education has moved online. Our study attempts to compare the differences between online medical education with a unique course design and traditional face-to-face education. We conducted a retrospective analysis of a total of 4,098 medical students between 2019 and 2020, including two groups of students who received online education and classroom education for the same subjects, respectively. Freshmen enrolled in September 2018 received traditional classroom physiology and pharmacology education in the spring semester of 2019. Because of the impact of the COVID-19 pandemic, freshmen who were enrolled in September 2019 received online physiology and pharmacology education in the spring semester of 2020. The final marks of the two groups of students were recorded and compared. Data on students participating in online discussions, learning, homework, and watching instructional videos were also recorded. There was no significant difference in the final academic performance between the two groups [average mark: 55.93 (online education) vs. 56.27 (classroom education), P = 0.488]. Further analysis showed that student participation rates in online discussions, online learning, and online viewing of instructional videos were closely correlated with final grades in online courses (P < 0.01). In conclusion, our results suggest that the pedagogical effects of online education during COVID-19 were promising, and we provide a well-designed medical online course to inspire further improvements in online education.NEW & NOTEWORTHY The COVID-19 pandemic has led to a massive temporary conversion of offline education to online education worldwide. Previous studies have noted that more students believed they had better learning experience in face-to-face learning. However, with our method of online teaching, we still showed a relatively similar performance result compared with offline education.

Hemoglobin-binding α-synuclein levels in erythrocytes are elevated in patients with multiple system atrophy.

Previous studies have shown that α-synuclein (α-syn) accumulation in the normal aging brain is associated with a parallel increase in hemoglobin-binding α-syn (Hb-α-syn) in the brain and peripheral erythrocytes (ERCs), indicating that Hb-α-syn levels in ERCs may reflect the α-syn changes in the brain. However, if there is any change in ERC Hb-α-syn levels in disease condition is unclear. In this study, Hb-α-syn levels in ERCs from 149 Patients with multiple system atrophy (MSA) and 149 healthy controls (HCs) were measured by enzyme linked immunosorbent assay (ELISA). The results showed that Hb-α-syn levels in ERCs were significantly increased in MSA patients in comparison with those in HCs (777.84 ± 240.82 ng/mg vs 508.84 ± 162.57 ng/mg, P < 0.001). Receiver operating characteristic curve (ROC) indicated that increased Hb-α-syn in ERCs could discriminate MSA patients from HCs, with a sensitivity of 71.8%, a specificity of 80.5%, and an area under the curve (AUC) of 0.837. The positive and negative predictive values at a cut-off value of 616.12 ng/mg were 78.7% and 74.1%, respectively. However, the increase in Hb-α-syn levels did not show any association with the age of onset and consultation, disease duration, and UMSARS (I-IV) score. This pilot study suggests that ERC Hb-α-syn is increased in MSA patients and could evaluate α-syn accumulation in the brain of patients.

Trends of antimalarial marine natural products: progresses, challenges and opportunities.

Covering 1972 to 2021Malaria remains a significant public health problem in some regions of the world. The great efforts to control malaria have been severely compromised due to the widespread resistance of Plasmodium falciparum to nearly all frontline drugs. Pursuit of novel molecules from the sea will potentially result in new interventions against malaria, which are urgently needed to combat the increase of resistance. Focusing on the strategy of the "Blue Drug Bank", the molecules highlighted here can serve as an inspiration for future medicinal chemistry campaigns. This review covers the developments in the field of antimalarial marine lead compounds reported between 1972 and July 2021, and offers a comprehensive overview on their progresses and potentials. We selected 60 representative potential candidate molecules from 361 marine natural products, and highlighted their structure-activity relationships, molecular mechanisms of targets, and drug-like properties in order to assess their full potential to be developed. We summarized 107 clinically proven or potential antimalarial targets and their subcellular locations in the relevant target proteins, which linked the molecules to the target proteins at the subcellular level. Hence, it could be expected that natural products targeting different mechanisms may prove to be an effective strategy in antimalarial drug research and development in the future.

Semisynthesis and biological evaluation of (+)-sclerotiorin derivatives as antitumor agents for the treatment of hepatocellular carcinoma.

Hepatocellular carcinoma is one of the most common primary hepatic malignancy. Herein, a series of semisynthesized derivatives (2-30) of the natural product (+)-sclerotiorin (1) was prepared and evaluated the cytotoxic activities against six cancer cell lines. Among them, 3 and 5 were the most effective compounds against human hepatocellular carcinoma Bel-7402 cell line with IC50 values of 1.45 and 1.15 µM, respectively. Molecular mechanism study showed that 5 disrupted the mitochondrial membrane potential and induced apoptosis in a caspase-dependent manner. In addition, 5 affected AKT and ERK signaling pathways and induced AKT and ERK proteins degradation through ubiquitin-proteasome system. Furthermore, 5 displayed significant in vivo anticancer effects in the xenograft models with decreasing the tumor mass by 52.5%. The safety evaluation was confirmed by acute toxicity subchronic toxicity tests, paraffin sections of mice organ and blood routine examination. Taken together, 5 can be developed as a potential therapeutic agent for hepatocellular carcinoma.

Hand-powered vacuum-driven microfluidic gradient generator for high-throughput antimicrobial susceptibility testing.

The growth of bacterial resistance to antimicrobials is a serious problem attracting much attention nowadays. To prevent the misuse and abuse of antimicrobials, it is important to carry out antibiotic susceptibility testing (AST) before clinical use. However, conventional AST methods are relatively laborious and time-consuming (18-24 h). Here, we present a hand-powered vacuum-driven microfluidic (HVM) device, in which a syringe is used as the only vacuum source for rapid generating concentration gradient of antibiotics in different chambers. The HVM device can be preassembled with various amounts of antibiotics, lyophilized, and stored for ready-to-use. Bacterial samples can be loaded into the HVM device through a simple suction step. With the assistance of Alamar Blue, the AST assay and the minimum inhibitory concentration (MIC) of different antibiotics can be investigated by comparing the growth results of bacteria in different culture chambers. In addition, a parallel HVM device was proposed, in which eight AST assays can be performed simultaneously. The results of MIC of three commonly used antibiotics against E. coli K-12 in our HVM device were consistent with those obtained by traditional method while the detection time was shortened to less than 8 h. We believe that our platform is high-throughput, cost-efficient, easy to use, and suitable for POCT applications.

Rapid Determination of Phase Diagrams for Biomolecular Liquid-Liquid Phase Separation with Microfluidics.

Biomolecular phase separation is currently emerging in both the medical and life science fields. Meanwhile, the application of liquid-liquid phase separation has been extended to many fields including drug discovery, fibrous material fabrication, 3D printing, and polymer design. Although more than 8600 proteins and other synthetic macromolecules are capable of phase separation as recently reported, there is still a lack of a high-throughput approach to quantitatively characterize its phase behaviors. To meet this requirement, here, we proposed fast and high-resolution acquisition of biomolecular phase diagrams using microfluidic chips. Using this platform, we demonstrated the phase behavior of polyU/RRASLRRASLRRASL in a quantitative manner. Up to 1750 concentration conditions can be generated in 140 min. The detection limitation of our device to capture the saturation concentration for phase separation is about 5 times lower than that of the traditional turbidity method. Thus, our results provide a basis for the rapid acquisition of phase diagrams with high-throughput and pave the way for its wide application.

A high-throughput ultrasonic spraying inoculation method promotes colony cultivation of rare microbial species.

Current method for obtaining microbial colonies still relies on traditional dilution and spreading plate (DSP) procedures, which is labor-intensive, skill-dependent, low-throughput and inevitably causing dilution-to-extinction of rare microorganisms. Herein, we proposed a novel ultrasonic spraying inoculation (USI) method that disperses microbial suspensions into millions of aerosols containing single cells, which lately be deposited freely on a gel plate to achieve high-throughput culturing of colonies. Compared with DSP, USI significantly increased both distributing uniformity and throughput of the colonies on agar plates, improving the minimal colony-forming abundance of rare Escherichia coli mixed in a lake sample from 1% to 0.01%. Applying this novel USI to a lake sample, 16 cellulose-degrading colonies were screened out among 4766 colonies on an enlarged 150-mm-diameter LB plate. Meanwhile, they could only be occasionally observed when using commonly used DSP procedures. 16S rRNA sequencing further showed that USI increased colony-forming species from 11 (by DSP) to 23, including seven completely undetectable microorganisms in DSP-reared communities. In addition to avoidance of dilution-to-extinction, operation-friendly USI efficiently inoculated microbial samples on the agar plate in a high-throughput and single-cell form, which eliminated masking or out-competition from other species in associated groups, thereby improving rare species cultivability.

Licorice Ameliorates Cisplatin-Induced Hepatotoxicity Through Antiapoptosis, Antioxidative Stress, Anti-Inflammation, and Acceleration of Metabolism.

Cisplatin (CP) is one of the most effective antitumor drugs in the clinic, but has serious adverse reactions, and its hepatotoxicity has not been fully investigated. Licorice (GC), a traditional herbal medicine, has been commonly used as a detoxifier for poisons and drugs, and may be an effective drug for CP-induced hepatotoxicity. However, its mechanism and the effector molecules remain ambiguous. Therefore, in this study, a network pharmacology and proteomics-based approach was established, and a panoramic view of the detoxification of GC on CP-induced hepatotoxicity was provided. The experimental results indicated that GC can recover functional indices and pathological liver injury, inhibit hepatocyte apoptosis, upregulate B-cell lymphoma/leukemia 2 (Bcl-2) and superoxide dismutase (SOD) levels, and downregulate cellular tumor antigen p53 (p53), caspase-3, malondialdehyde high mobility group protein B1 (HMGB1), tumor necrosis factor alpha (TNF-α), and interleukin 1ß (IL-1ß) levels. Proteomics indicated that GC regulates phosphatidylcholine translocator ABCB1 (ABCB1B), canalicular multispecific organic anion transporter 1 (ABCC2), cytochrome P450 4A2 (CYP4A2), cytochrome P450 1A1 (CYP1A1), cytochrome P450 1A2 (CYP1A2), estrogen receptor (ESR1), and DNA topoisomerase 2-alpha (TOP2A), inhibits oxidative stress, apoptosis, and inflammatory responses, and accelerates drug metabolism. In this study, we provide the investigation of the efficacy of GC against CP-induced hepatotoxicity, and offer a promising alternative for the clinic.

Tuning the Superhydrophobic Properties of Hierarchical Nano-microstructural Silica Biomorph Arrays Grown at Triphasic Interfaces.

The three-dimensional hierarchical morphology of surfaces greatly affects the wettability, absorption and microfabrication properties of their hybrid materials, however few scalable methods exist that controls simultaneously complex geometric shape and spatial scattered location and their physical properties tuned. Consequently, this report describes a synthetic strategy that enables the position of well-ordered biomorph nano-microstructures on hydrophobic surfaces to be precisely controlled. The hierarchical architecture can be accurately positioned on polydimethylsiloxane (PDMS) surfaces in an unprecedented level by leveraging a solid/liquid/gas triphase dynamic reaction diffusion system strategy. The effect of salt concentrations, pH, CO2 levels, temperature and substrate patterning on this self-assembly process has been investigated, enabling protocols to be devised that enables the hydrophobic properties of the hierarchically assembled multiscale microstructures to be tuned as required. This combined top-down/bottom-up approach can be used to produce composites with outstanding hydrophobicity properties, affording superhydrophobic materials that are capable of retaining water droplets on their surfaces, even when the material is inverted by 180°, with a wide range of potential applications in oil/water separation technology and for selective cell recognition in biological systems.

pH-Dependent transfer hydrogenation or dihydrogen release catalyzed by a [(η6-arene)RuCl(κ2-N,N-dmobpy)]+ complex: a DFT mechanistic understanding.

The reaction mechanism of the pH-dependent transfer hydrogenation of a ketone or the dehydrogenation of formic acid catalyzed by a [(η6-arene)RuCl(κ2-N,N-dmobpy)]+ complex in aqueous media has been investigated using the density functional theory (DFT) method. The TM-catalyzed TH of ketones with formic acid as the hydrogen source proceeds via two steps: the formation of a metal hydride and the transfer of the hydride to the substrate ketone. The calculated results show that ruthenium hydride formation is the rate-determining step. This proceeds via an ion-pair mechanism with an energy barrier of 14.1 kcal mol-1. Interestingly, the dihydrogen release process of formic acid and the hydride transfer process that produces alcohols are competitive under different pH environments. The investigation explores the feasibility of the two pathways under different pH environments. Under acidic conditions (pH = 4), the free energy barrier of the dihydrogen release pathway is 4.5 kcal mol-1 that is higher than that of the hydride transfer pathway, suggesting that the hydride transfer pathway is more favorable than the dihydrogen release pathway. However, under strongly acidic conditions, the dihydrogen release pathway is more favorable compared to the hydride transfer pathway. In addition, the ruthenium hydride formation pathway is less favorable than the ruthenium hydroxo complex formation pathway under basic conditions.

A light-up near-infrared probe with aggregation-induced emission characteristics for highly sensitive detection of alkaline phosphatase.

Developing activatable near-infrared (NIR) probes to specifically monitor and visualize the activities of cancer-related enzymes is highly significant yet challenging in early cancer diagnosis. Taking advantage of the unique photophysical characteristics of aggregation-induced emission (AIE) fluorophores, here we design and synthesize a novel activatable probe QMTP by conjugating an AIE fluorophore quinolone-malononitrile to a hydrophilic phosphate-modified phenol group. The probe was initially non-fluorescent in aqueous solution due to its good water solubility, but was readily activated to generate a strong NIR fluorescence upon treatment with alkaline phosphatase (ALP), which enables specific detection of ALP activity. Furthermore, we have employed QMTP to monitor and spatially map the activity of endogenous ALP both in cancer cells and in drug-treated zebrafish larvae. The experimental results reveal that the QMTP probe has great specificity and sensitivity for ALP detection. We thus believe that our work offers a promising tool for accurate detection of ALP-associated diseases in preclinical applications.

[Rat plasma metabolomics in blood stasis model based on ultra performance liquid chromatography-quadrupole-time-of-flight mass spectrometry].

Acute blood stasis syndrome was induced in rats by adrenaline hydrochloride and ice water. Ultra performance liquid chromatography-quadrupole-time-of-flight mass spectrometry (UPLC-Q-TOF/MS) was conducted on plasma metabolites of normal and model rats. Principal component analysis (PCA), differentiation analysis of supervised partial least squares method (PLS-DA), and orthogonal to partial least squares discriminant analysis (OPLS-DA) on metabolomics data for multidimensional statistical analysis were employed, and the resulting biomarkers were screened. Compared to the normal group, there were 46 endogenous metabolites in blood stasis-rat plasma. Of these, 21 metabolites were significantly upregulated, such as acetylcholine, N6,N6,N6-trimethyl-L-lysine, cytosine, and acetylcarnitine, while 25 metabolites were reduced, including indoleacrylic acid, and lysoPC(14:0). These metabolites were mainly related to metabolic pathways, including lipid metabolism, galactose metabolism, linoleic acid metabolism, biosynthesis of unsaturated fatty acids, glycolysis, and arachidonic acid metabolism. In conclusion, these results indicated that metabolites could be used as important biomarkers for blood stasis syndrome, and could help in revealing the mechanism of blood stasis disease and provide a reference network to determine the disease development stage and appropriate follow-up treatment. Studying altered metabolites in blood stasis model rats can provide insights useful for the diagnosis of blood stasis in the clinic and for the development of drug therapies.

Rolling circle extension-actuated loop-mediated isothermal amplification (RCA-LAMP) for ultrasensitive detection of microRNAs.

Rolling circle amplification (RCA) is an elegant and well-recognized isothermal nucleic acid amplification mechanism that has been widely used for the detection of various kinds of genetic biomarkers. However, traditional RCA is a linear signal amplifying mechanism so that the amplification efficiency is generally not satisfactory. Herein, we rationally combine RCA with efficient loop-mediated isothermal amplification (LAMP) to establish a rapid and ultrasensitive RCA-LAMP method for the detection of microRNAs (miRNAs). In the RCA-LAMP, the target let-7a miRNA can directly template the ligation of a padlock probe to trigger RCA reaction, producing long and tandem amplification products. Only such RCA-produced long DNA repeats can act as the template to generate a lot of double stem-loop DNAs with functional sequences, which are the essential starting materials to initiate subsequent LAMP. Finally, the products of LAMP reaction, the amount of which is dependent on the initial miRNA dosage, can be fluorescently monitored in a real-time manner. Through the combination of ligation-mediated RCA with LAMP, the amplification efficiency and the detection sensitivity has been significantly improved. As a result, even 10 aM miRNA target can be clearly and accurately detectable. Despite the excellent analytical performance for miRNA analysis, compared with conventional RCA-based miRNA assays, the combination of RCA with LAMP does not introduce any additional reaction steps or sample transfer operations. Both the RCA and LAMP are fulfilled in a single step. Therefore, this facile and ultrasensitive RCA-LAMP assay provides a new promising tool for miRNA analysis and can be extended to the detection of various kinds of genetic biomarkers.

Recombinant adenovirus expressing a dendritic cell-targeted melanoma surface antigen for tumor-specific immunotherapy in melanoma mice model.

Viral vectors represent a potential strategy for the treatment of human malignant tumors. Currently, recombinant adenovirus vectors are commonly used as gene therapy vehicles, as it possesses a proven safety profile in normal human cells. The recombinant adenovirus system has an ability to highly express exogenous genes and increase the stability of the carrier, which is only transiently expressed in the host cell genome, without integrating. Malignant melanoma cells are produced by the skin, and melanocyte tumors that exhibit higher malignant degrees lead to earlier transfer and higher mortality. In the present study, a recombinant adenovirus (rAd) was generated to express Anti-programmed death-1 (rAd-Anti-PD-1) and used to investigate the efficacy in melanoma cells and tumors. The results demonstrated that B16-F10 cell growth was significantly inhibited and the apoptosis incidence rate was markedly promoted following rAd-PD-1 treatment. The present study demonstrated that the production of α and ß interferon was increased, which led to the induction of dendritic cell (DCs) maturation in rAd-anti-PD-1-treated mice. The present study indicated that rAd-anti-PD-1 exhibited the ability to generate more cluster of differentiation (CD)4+CD8+ T cells and induce a PD-1-specific cytotoxic T lymphocyte through DC-targeted surface antigens in mice. This resulted in a further enhanced recognition of melanoma cells due to DCs being targeted by the rAd-anti-PD-1-encoded PD-1. Notably, mice treated with the rAd-anti-PD-1-targeted PD-1 demonstrated an improved protection compared with tumor-bearing mice from the challenge group treated with a recombinant gutless adenovirus and Anti-PD-1. In conclusion, the present study demonstrated that targeting the melanoma surface antigens via the rAd-anti-PD-1-infected tumor cells enhanced the ability of recombinant adenovirus to induce a potent tumor-inhibitory effect and antigen-specific immune response.

Ghrelin protects human umbilical vein endothelial cells against advanced glycation end products-induced apoptosis via NO/cGMP signaling.

OBJECTIVES: The aim of this study was to investigate the intracellular mechanism involved in the anti-apoptotic effect of ghrelin on human umbilical vein endothelial cells (HUVECs). METHODS: HUVECs were pretreated with ghrelin before exposure to 200 µg/ml advanced glycation end products (AGEs)-BSA for 48 h. Cell viability and apoptosis were determined by MTT assay and Annexin V/PI staining. Intracellular cGMP levels evaluation and cGMP analogs were employed to explore possible mechanisms. RESULTS: The inhibitory effect on AGEs induced HUVECs apoptosis could be exerted by ghrelin and co-incubation with growth hormone secretagogue receptor (GHSR)-1a antagonist [D-Lys(3)]-GHRP-6 abolished this inhibition. Decreased cGMP level in AGEs induced HUVECs apoptosis was restored by ghrelin pretreatment and abolished by [D-Lys(3)]-GHRP-6 co-incubation. cGMP analogs (8 Br-cGMP and DB-cGMP) pretreatment also exhibited inhibitory effect on AGEs induced HUVECs apoptosis. CONCLUSIONS: Our results demonstrated that ghrelin produces a protective effect on HUVECs through GHS-R1a and cGMP/NO signaling pathway mediates the effect of ghrelin. These observations suggest a novel intracellular mechanism in the process of AGEs induced HUVECs apoptosis.