喀斯特常绿落叶阔叶林木本植物功能性状变异及其适应策略

叶片功能性状能反映植物对环境的高度适应能力和复杂生境下的自我调控能力,同时也能反映植物的基本特征和对资源的有效利用率。以木论国家级自然保护区喀斯特常绿落叶阔叶林144种优势木本植物为研究对象,测定其叶厚(LT)、叶面积(LA)、比叶面积(SLA)、叶长宽比(L/W)、叶组织密度(LTD)叶片形态性状和12种叶元素性状特征及变异程度,并探讨植物对喀斯特生境的适应策略。结果表明：17个性状变异程度不同,其中叶面积变异系数最大,达到133.31%,叶片碳变异系数最小,为7.73%,叶元素变异程度普遍高于叶形态性状变异程度。不同叶习性物种间叶厚、比叶面积、叶长宽比、叶氮含量性状差异达到显著水平。部分叶性状呈显著相关,得到一系列最佳功能性状组合,体现植物对喀斯特地区特殊生境的适应性。沿着性状贡献率较高的PC1轴,能够定义出叶经济谱,大部分常绿植物采取经济保守策略,而大部分落叶植物则聚集在资源获取的一侧。相较于邻近非喀斯特地区,喀斯特地区植物有较小的LA、SLA。这些结果体现了喀斯特地区植物叶片形成的不同叶性状特征,以及分布于经济谱两端的常绿和落叶植物的不同资源获取策略,揭示了植物对生境的适应策略...     

太子参内生细菌RPB-32的分类鉴定及其代谢物对小鼠肠道微生物群落的影响

【背景】肠道微生物在宿主肠道微环境稳态中起着至关重要的作用。众多因子,如抗生素、饮食和年龄等会干扰这种微平衡,引起菌群平衡发生改变,进而影响到机体健康状况。太子参具有心肌保护、增加免疫、抗氧化、抗糖尿病、抗应激、抗疲劳等药理活性,而太子参内生菌代谢物对肠道微生物的调控作用以及可能对机体健康的影响目前还未见报道。【目的】研究太子参内生菌RPB-32分类地位及其代谢提取物对小鼠肠道微生物的调节作用,以探讨其对机体健康的影响。【方法】对RPB-32进行传统方法和分子鉴定。将120只KM小鼠随机分为溶剂对照组(3%乙醇)及石油醚提取物、正丁醇提取物和乙酸乙酯提取物低、中、高剂量组(n=12)。小鼠灌胃处理14 d后采集粪便,通过选择性培养基培养及宏基因组测序[溶剂对照(S.F.1为3%乙醇溶液)、乙酸乙酯提取物高剂量组(S.F.2)]检测灌胃前后小鼠肠道微生物的变化。【结果】常规传统方法与分子鉴定结果表明RPB-32为芽孢杆菌(Bacillus sp.)。与空白对照组相比,给予内生菌代谢提取物的乙酸乙酯中剂量组、乙酸乙酯高剂量组、正丁醇低剂量组、正丁醇中剂量组及正丁醇高剂量组乳酸菌数量明显增加...     

表观遗传的化学干预对金龟子绿僵菌次生代谢产物影响的研究

[背景] 表观遗传酶类化学抑制剂对真菌的影响研究主要集中在新次生代谢产物挖掘方面,而对大量已知次生代谢物含量的变化却关注较少。金龟子绿僵菌是一种常用杀虫真菌,能代谢出多种已知生物活性物质,其含量可能会影响到该菌与环境间关系及利用潜力。[目的] 评估组蛋白去乙酰化酶和DNA甲基转移酶的化学抑制剂对金龟子绿僵菌代谢物安全性和可利用性的影响。[方法] 在金龟子绿僵菌培养基中添加表观遗传酶类化学抑制剂,培养一定时间后用高分辨液质联用及标准品对照方法分析次生代谢产物变化。根据差异代谢物的生物活性评估化学抑制剂的影响。[结果] 高分辨液质联用分析结果表明当抑制剂浓度达500μmol/L时,金龟子绿僵菌有16种主要次生代谢产物出现明显量的变化,包括destruxin A、A1、A2、B、B1、B2、E、E2、Ed、didesmethyldestruxin C、dihydrodestruxin A、desmethyldestruxin B、12-hydroxyovalicin、subglutinol C、fungerin和ustilagic Acid C。其中,丁酸钠处理可使15种主要代谢物含量升高。苯甲酰胺可使12种主要代谢物含量升高。伏立诺他虽然仅能使10种主要代谢物含量升高,但部分代谢物的升高幅度明显高于前两者。2种DNA甲基转移酶抑制剂可使金龟子绿僵菌代谢物中绿僵菌素类代谢物含量普遍下降。[结论] 组蛋白去乙酰化酶抑制剂可引起金龟子绿僵菌主要代谢物含量普遍升高,而DNA甲基转移酶抑制剂使金龟子绿僵菌的绿僵菌素含量普遍下降。由于变化的代谢物都具有显著的杀虫、免疫抑制或抗菌抗癌等生物活性,因此上述化学抑制剂可增强或降低金龟子绿僵菌对环境中昆虫毒性,同时也增加或降低其代谢物利用潜力。另外,subglutinol C、fungerin和ustilagic Acid C是首次在金龟子绿僵菌中被发现。     

An oncolytic adenovirus delivering TSLC1 inhibits Wnt signaling pathway and tumor growth in SMMC-7721 xenograft mice model

Tumor suppressor in lung cancer-1(TSLC1)was first identified as a tumor suppressor for lung cancer,and frequently downregulated in various types of cancers incl...     

IGF2BP2 serves as a core m6A regulator in head and neck squamous cell carcinoma

Methylation of N6 adenosine (m6A) plays a crucial role in the development and progression of cancers. Its modification is regulated by three types of m6A-related regulators (methyltransferases (writers), demethylases (erasers), and RNA-binding proteins (readers)). Till now, the functions and roles of these regulators in head and neck squamous cell carcinoma (HNSC) remain largely unexplored. Therefore, we utilized the open HNSC dataset in The Cancer Genome Atlas (TCGA), four different cell lines, and our HNSC patient samples (n=40) to explore the clinical significance of 19 m6A regulators, and selected the most significant prognosis-related regulator. Authentic analyses based on online websites were also used in the study (Oncomine, UALCAN, Kaplan–Meier plotter, Human Protein Atlas (HPA), cBioPortal, LinkedOmics, String, etc.). From the results, general overexpression of m6A regulators was observed in pan-cancer, especially in HNSC. IGF2BP2 was recognized as the hub m6A regulator, which was an independent, unfavorable prognostic factor in HNSC. Its mRNA and protein expression in HNSC were significantly up-regulated. Gene mutation types of IGF2BP2 in HNSC (32%) were mainly mRNA High or Amplification, which represented the high expression of IGF2BP2. And these mutations were associated with a poor prognosis. In functional analysis, IGF2BP2 was negatively correlated to tumor immune infiltration in HNSC. Finally, HMGA2 might interact with the IGF2BP2 in HNSC. In conclusion, IGF2BP2 serves as a core m6A regulator among all regulators in HNSC, which has a high expression and predicts the poor prognosis of HNSC patients independently. IGF2BP2 might bring a new direction for HNSC treatment in the future.     

CRISPR/Cas9-induced structural variations expand in T lymphocytes in vivo

CRISPR/Cas9 has been adapted to disrupt endogenous genes in adoptive T-lymphocyte therapy to prevent graft-versus-host disease. However, genome editing also generates prevalent deleterious structural variations (SVs), including chromosomal translocations and large deletions, raising safety concerns about reinfused T cells. Here, we dynamically monitored the progression of SVs in a mouse model of T-cell receptor (TCR)-transgenic T-cell adoptive transfer, mimicking TCR T therapeutics. Remarkably, CRISPR/Cas9-induced SVs persist and undergo clonal expansion in vivo after three weeks or even two months, evidenced by high enrichment and low junctional diversity of identified SVs post infusion. Specifically, we detected 128 expanded translocations, with 20 615 as the highest number of amplicons. The identified SVs are stochastically selected among different individuals and show an inconspicuous locus preference. Similar to SVs, viral DNA integrations are routinely detected in edited T cells and also undergo clonal expansion. The persistent SVs and viral DNA integrations in the infused T cells may constantly threaten genome integrity, drawing immediate attention to the safety of CRISPR/Cas9-engineered T cells mediated immunotherapy.     

Phosphorus Regulates the Level of Signaling Molecules in Rice to Reduce Cadmium Toxicity

Phosphorus treatment can reduce Cd accumulation and Cd toxicity in rice, but alterations in the internal regulatory network of rice during this process have rarely been reported. We have removed the effect of cadmium phosphate precipitation from the hydroponic system, treated a pair of different Cd-response rice varieties with different levels of phosphorus and cadmium and examined the changes in physiological indicators and regulatory networks. The results demonstrated that phosphorus treatment significantly reduced Cd accumulation in both types of rice, although the antioxidant systems within the two types of rice produced opposite responses. Overall, 3 mM phosphorus treatment to Cd-N decreased the expression of OsIAA17 and OsACO1 by 32% and 37%, respectively, while increasing the expression of OsNR2 by 83%; these three genes regulate the synthesis of auxin, ethylene, and nitric oxide in rice. IAA and NO levels in rice shoots increased by 24% and 96%, respectively, and these changes contribute to Cd detoxification. The cadmium transporter genes OsHMA2, OsIRT1, and OsABCC1 were significantly down-regulated in Cd-N roots after triple phosphorus treatment. These data suggest that phosphorus treatment can reduce Cd accumulation and enhance Cd resistance in rice by affecting the expression of signaling molecules.     

Breeding of High Daptomycin-Producing Strain by Streptomycin Resistance Superposition

Daptomycin is a cyclolipopeptide antibiotic produced by Streptomyces roseosporus. It is widely used to treat drug-resistant bacterial infections; however, daptomycin yield in wild strains is very low. To improve the daptomycin production by the strain BNCC 342432, a modified method of ribosome engineering with superposition of streptomycin resistance was adopted in this study. The highest-yield mutant strain SR-2620 was obtained by increasing streptomycin resistance of BNCC 342432, and achieved daptomycin production of 38.5 mg/l in shake-flask fermentation, 1.79-fold higher than the parent strain and its heredity stability was stable. The morphological characteristics of the two strains were significantly different, and the 440^th base G of the rpsL gene in the mutant strain was deleted, which resulted in a frameshift mutation. Our results demonstrate that gradually increasing strain resistance to streptomycin was an effective breeding method to improve daptomycin yield in S. roseosporus. Open in a separate window