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Objective To evaluate the immunoprotective effect of active immunization with recombinant peptidyl-prolyl cis-trans isomerase from Babesia microti against B. microti infection in mice. Methods Female BALB/c mice at 6 weeks of age, each weighing approximately 20 g, were divided into the recombinant protein immunization group, the infection control group and the normal control group, of 25, 18, 15 mice in each group, respectively. Mice in the recombinant protein immunization group were given active immunization with recombinant BmPPIase protein, and 18 mice with the highest antibody titers were intraperitoneally injected with 100 μL of B. microti-infected whole blood 2 weeks after the last immunization. Mice in the infection control group were intraperitoneally injected with 100 μL of B. microti-infected whole blood, while 15 mice in the normal control group received no treatment. Blood samples were collected from mice in the recombinant protein immunization group and the infection control group on days 0 to 30 post-immunization for detection of B. microti infection, and blood samples were collected on days 0, 7, 14, 21, and 28 post-immunization for routine blood tests with a blood cell analyzer and for detection of serum cytokines using cytometric bead array. Results Anti-BmPPIase antibodies were detected in 25 mice in the recombinant protein immunization group 2 weeks after the last immunization, with titers of 5 × 103 to 8 × 104. B. microti infection rate peaked in mice in both the recombinant protein immunization and the infection control group on day 7 post-immunization, with positive infection rates of 13.3% and 50.0%, and there were significant differences between the two groups in terms of B. microti infection rate on days 3 (χ2= 113.18, P < 0.01), 5 (χ2 = 475.22, P < 0.01), 7 (χ2 = 465.98, P < 0.01) and 9 post-infection (χ2= 18.71, P < 0.01), while the B. microti infection rate tended to be 0 in both groups on day 11 post-immunization. Routine blood tests showed higher red blood cell counts [(5.30 ± 0.50) × 1012 to (9.87 ± 0.24) × 1012 counts/L)] and hemoglobin levels [(89.67 ± 22.80) to (148.60 ± 3.05) g/L)] in the recombinant protein immunization group than in the infection control group on days 0 to 28 post-immunization. Cytometric bead array detected higher serum interferon-γ [(748.59 ± 17.56) to (3 858.28 ± 1 049.10) fg/mL], tumor necrosis factor-α [(6 687.34 ± 1 016.64) to (12 708.13 ± 1 629.79) fg/mL], interleukin (IL)-6 [(611.05 ± 75.60) to (6 852.68 ± 1 554.00) fg/mL] and IL-17a [(167.68 ± 185.00) to (10 849.27 ± 355.40) fg/mL] and lower IL-10 levels [(247.65 ± 138.00) to (18 787.20 ± 2 830.22) fg/mL] in the recombinant protein immunization group than in the infection control group during the study period. Conclusions Recombinant BmPPIase protein induces up-regulation of interferon-γ, tumor necrosis factor-α and presents a high immunoprotective activity against B. microti infection in mice, which is a potential vaccine candidate protein.
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AIM: To systematically evaluate the efficacy of intense pulsed light(IPL)combined with meibomian gland expression(MGX)in the treatment of meibomian gland dysfunction(MGD)-related dry eye disease(DED).METHODS: Chinese and English databases such as Chinese national knowledge infrastructure(CNKI), Wanfang, VIP, CBM, ClinicalTrials, PubMed, Embase and Web of Science were searched, and clinical randomized controlled trials(RCTs)using IPL combined with MGX in the experimental group and MGX alone in the control group from January 2017 to September 2022 were included. Six outcome indicators including clinical efficacy, ocular surface disease index(OSDI)score, break-up time(BUT), corneal fluorescein staining(CFS)score, tear meniscus height(TMH)and meibomian gland yielding secretion score(MGYSS)were Meta analyzed by Review Manager 5.3 and Stata 14 software.RESULTS: A total of 15 RCTs were included, with 1 345 patients with MGD-related dry eye. Meta-analysis results showed that the treatment of MGD-related dry eye in the experimental group improved better clinical efficacy(OR=4.95, 95%CI: 2.76~8.90, Z=5.35, P&#x003C;0.00001), BUT(SMD=1.26, 95%CI: 0.84~1.69, Z=5.78, P&#x003C;0.00001), TMH(SMD=0.37, 95%CI: 0.15~0.59, Z=3.33, P=0.0009), and reduced OSDI scores(SMD=-0.86, 95%CI: -1.44~-0.27, Z=2.85, P=0.004)as well as MGYSS(SMD=-2.43, 95%CI: -4.31~-0.54, Z=2.52, P=0.01)than the control group. However, there was no statistically significant difference in CFS scores(SMD=-0.19, 95%CI: -0.46~0.07, Z=1.43, P=0.15).CONCLUSION: IPL combined with MGX in the treatment of MGD related dry eye can increase the overall effective rate and improve the symptoms and signs of patients with MGD related dry eye better than MGX alone.
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Illumina Xten was employed for shallow sequencing of Panax ginseng(ginseng) samples, MISA for screening of SSR loci, and Primer 3 for primer design. Polymorphic primers were screened from 180 primers. From the successfully amplified polymorphic primers, 15 primers which featured clear peak shape, good polymorphism, and ease of statistics were selected and used to evaluate the genetic diversity and germplasm resources of 36 ginseng accessions with different fruit colors from Jilin province. The results showed that red-fruit ginseng population had high genetic diversity with the average number of alleles(N_a) of 1.031 and haploid genetic diversity(h) of 0.172. The neighbor-joining cluster analysis demonstrated that the germplasms of red-fruit and yellow-fruit ginseng populations were obviously intermixed, and pick-fruit ginseng germplasms clustered into a single clade. The results of STRUCTURE analysis showed high proportion of single genotype in pick-fruit ginseng germplasm and abundant genotypes in red-fruit and yellow-fruit ginseng germplasms with obvious germplasm mixing. AMOVA revealed that genetic variation occurred mainly within populations(62.00%, P<0.001), and rarely among populations(39%, P<0.001), but homogenization was obvious among different populations. In summary, pink-fruit ginseng population may contain rare genotypes, which is the basis for breeding of high-quality high-yield, and multi-resistance varieties, genetic improvement of varieties, and sustainable development and utilization of ginseng germplasm resources.
Subject(s)
Fruit/genetics , Genetic Variation , Microsatellite Repeats , Panax/genetics , Plant BreedingABSTRACT
Nitrogen is one of the most frequently used fertilizers in growth of Chinese medicinal plants(CMP). As in many other ecosystems, CMP ecosystem is also composed of plant-herbivore-natural enemy(tritrophic) interactions. Nitrogen fertilizer influences the growth and reproduction of CMP, and it is also able to heavily shape the ecosystem functions of CMP ecosystem through bottom-up forces. Understanding the specific effects of nitrogen fertilizer towards each trophic level will be beneficial to improve the resistance of CMP to herbivore and enhance the control efficiency of nature enemies to herbivore, and eventually, maximize the yield and quality of CMP. Most papers published on nitrogen use in plants focused mainly on the impact of nitrogen fertilization on CMP yield and quality. Influences of nitrogen application on CMP ecosystem get little attention at present. Therefore, this review summed up the potential effects of nitrogen fertilization on CMP ecosystem from perspectives of soil and tritrophic interactions. First of all, nitrogen fertilizer might decrease soil microbial biomass and altered the community structures of soil bacteria, fungi and protozoa. Negative effects of nitrogen fertilizer were found on biodiversity of soil bacteria and protozoa. Different fungi species respond differently to nitrogen fertili-zers. Nitrogen deposition can also decrease the soil pH. Decreases in soil microbial diversity and soil acidification can cause negative effects on CMP growth. In addition, nitrogen fertilizer could regulate the pest resistance of CMP including constitutive and inducible resistance. Both positive and negative effects of nitrogen application were found on pest resistance of CMP. Moreover, the development and predation of natural enemies were influenced by nitrogen deposition. Nitrogen influences natural enemies in many ways including plant volatiles, plant nutrient and structure and the supplementary food quality. Nectar and honeydew of plants and preys serve as important food source for natural enemies especially in early season when preys are still not available. Finally, the interactions between herbivores and their natural enemies were also shaped by nitrogen fertilizer in many aspects like increasing the nutritional content of prey and changing control efficiency of natural enemies. Some herbivores have evolved a strategy to sequester secondary metabolites which they absorbed from plant during their feeding. Studies showed that sequestration efficiency of secondary metabolites in prey could also be regulated by nitrogen. Parasitic, emergence, reproduction rate and longevity of parasites were found positively correlated with nitrogen deposition. Hopefully this study will shed light on practicable and economical application of nitrogen in cultivation of CMP.
Subject(s)
China , Ecosystem , Fertilizers , Nitrogen , Plants, Medicinal , SoilABSTRACT
Human sparganosis is a food-borne parasitic disease caused by the plerocercoids of Spirometra species. Clinical diagnosis of sparganosis is crucial for effective treatment, thus it is important to identify sensitive and specific antigens of plerocercoids. The aim of the current study was to identify and characterize the immunogenic proteins of Spirometra erinaceieuropaei plerocercoids that were recognized by patient sera. Crude soluble extract of the plerocercoids were separated using 2-dimensional gel electrophoresis coupled with immunoblot and mass spectrometry analysis. Based on immunoblotting patterns and mass spectrometry results, 8 antigenic proteins were identified from the plerocercoid. Among the proteins, cysteine protease protein might be developed as an antigen for diagnosis of sparganosis.
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The ecological agriculture of Chinese materia medica(CMM) has become the most dynamic and promising new field in the global ecological agriculture. The development of ecological planting of CMM has become the national strategy of Chinese traditional medicine agriculture. It has been highly valued and has flourished throughout the country, and has formed some more mature ecological planting models of CMM. Based on the system level, this paper sorts out the common ecological cultivation patterns of CMM, and obtains five basic patterns: landscape pattern at the ecological landscape level, circulation pattern at the ecosystem level, stereo model at the bio-community level, biodiversity patterns at the level of biological populations and well-established models at the level of biological individuals. On this basis, eight common ecological planting techniques of CMM were obtained, includingwild tending techniques, fine agricultural farming techniques, directional cultivation techniques, soil improvement techniques, soil testing and fertilization techniques, mycorrhizal cultivation techniques, green control technology for pests and diseases and facility cultivation techniques.This paper aims to provide theoretical basis for scientific research and popularization and application of CMM ecological planting.
Subject(s)
Humans , Agriculture , Drugs, Chinese Herbal , Ecosystem , Materia Medica , Medicine, Chinese TraditionalABSTRACT
As an environment-friendly agriculture, ecological agriculture of Chinese materia medica(CMM) is being implemented in all parts of the country. Due to the stronger dependence on natural environmental conditions, ecological agriculture of CMM shows obvious regional differences in production practice. More mature CMM ecological planting patterns representative of each region were collected. It was found that common types of patterns in various regions of the country mainly included intercropping,intercropping,rotation planting mode, undergrowth planting mode, wild tending planting mode and landscape ecological planting mode. Based on the Construction Plan of National Dao-di Herbs Production Base(2018-2025) and Chinese Medicine Division, this paper systematically sorts out the pattern of ecological planting of CMM in the 8-avenue medicinal materials production areas according to the varieties and regions. The specific pattern of ecological planting of CMM included the ginseng undergrowth planting pattern in northeastern China, the bionics wild ecological planting of the Forsythia suspensa in northern China, the Fritillaria thunbergii-rice rotation in eastern China, the imitation wild planting pattern under the Polygonatum cyrtonema in central China, the planting pattern of the Fructus amomi under forest in southern China, the Ligusticum chuanxiong-rice rotation pattern in the Southwest, wild tending of Glycyrrhiza uralensis in the Northwest, and rhubarb imitation wild planting pattern in Qinghai-Tibet area. Finally, it is expected to provide reference for the screening and popularization of ecological planting patterns of other CMMs in various distribution areas.
Subject(s)
China , Drugs, Chinese Herbal , Ligusticum , Materia Medica , Medicine, Chinese Traditional , TibetABSTRACT
To explore the effect of Shuxuetong injection on the pharmacodynamics and pharmacokinetics of warfarin in rats, and to provide reference for rational drug use. In studies on the single dose of warfarin, Wistar rats were randomly divided into four groups: blank control group(group A), Shuxuetong injection group(group B), warfarin control group(group C), and warfarin+Shuxuetong injection group(group D). In studies on the steady state of warfarin, Wistar rats were randomly divided into warfarin control group(group E) and warfarin+Shuxuetong injection group(group F). To investigate the pharmacodynamic effect of Shuxuetong injection on warfarin, prothrombin time(PT) and activated partial thromboplastin time(APTT) were measured by coagulation analyzer, and international normalized ratio(INR) was calculated. To investigate the pharmacokinetic effect of Shuxuetong injection on warfarin, the blood concentrations of S-warfarin and R-warfarin were determined by UPLC-MS/MS combined with technology of chiral chromatographic column, and the related pharmacokinetic parameters were calculated accordingly. The results on the single dose of warfarin showed that Shuxuetong injection markedly increased PT, INR(P<0.01), and APTT(P<0.05). Meanwhile, when Shuxuetong injection was co-administrated with warfarin, it significantly increased PT, INR(P<0.01), and APTT(P<0.05) as compared with warfarin control group. In addition, increased pharmacokinetic parameters including Cmax, AUC0-t and AUC0-∞, prolonged t1/2, and decreased CL/F were observed for S-warfarin and R-warfarin. The results of the steady state of warfarin suggested that Shuxuetong injection significantly increased PT and INR of warfarin(P<0.01), and elevated the plasma concentrations of S-warfarin and R-warfarin when co-administrated with warfarin. These findings indicated that Shuxuetong injection had anticoagulant effect, and would produce pharmacodynamics synergistic action when it was co-administrated with warfarin. Shuxuetong injection also decelerated the metabolism of warfarin, and resulted in pharmacokinetics interaction. Therefore, Shuxuetong injection could significantly increase anticoagulant effect of warfarin, indicating that the combination use of these two drugs should be refrained in order to avoid the risk of bleeding in clinical application. If they need to be used in combination, special attention should be paid to ensure the safety of patients.