Active interfacial dynamic transport of fluid in a network of fibrous connective tissues throughout the whole body

Fluid in interstitial spaces accounts for ~20% of an adult body weight and flows diffusively for a short range. Does it circulate around the body like vascular circulations? This bold conjecture has been debated for decades. As a conventional physiological concept, interstitial space is a micron‐sized space between cells and vasculature. Fluid in interstitial spaces is thought to be entrapped within interstitial matrix. However, our serial data have further defined a second space in interstitium that is a nanosized interfacial transport zone on a solid surface. Within this fine space, fluid along a solid fibre can be transported under a driving power and identically, interstitial fluid transport can be visualized by tracking the oriented fibres. Since 2006, our data from volunteers and cadavers have revealed a long‐distance extravascular pathway for interstitial fluid flow, comprising at least four types of anatomic distributions. The framework of each extravascular pathway contains the longitudinally assembled and oriented fibres, working as a fibrorail for fluid flow. Interestingly, our data showed that the movement of fluid in a fibrous pathway is in response to a dynamic driving source and named as dynamotaxis. By analysis of previous studies and our experimental results, a hypothesis of interstitial fluid circulatory system is proposed.     

Functional divergence of two duplicated Fertilization Independent Endosperm genes in rice with respect to seed development

Fertilization Independent Endosperm (FIE) is an essential member of Polycomb Repressive Complex 2 (PRC2) that plays important roles in the developmental regulation of plants. OsFIE1 and OsFIE2 are two FIE homologs in the rice genome. Here, we showed that OsFIE1 probably duplicated from OsFIE2 after the origin of the tribe Oryzeae, but has a specific expression pattern and methylation landscape. During evolution, OsFIE1 underwent a less intensive purifying selection than did OsFIE2. The mutant osfie1 produced smaller seeds and displayed reduced dormancy, indicating that OsFIE1 predominantly functions in late seed development. Ectopic expression of OsFIE1, but not OsFIE2, was deleterious to vegetative growth in a dose‐dependent manner. The newly evolved N‐terminal tail of OsFIE1 was probably not the cause of the adverse effects on vegetative growth. The CRISPR/Cas9‐derived mutant osfie2 exhibited impaired cellularization of the endosperm, which suggested that OsFIE2 is indispensable for early seed development as a positive regulator of cellularization. Autonomous endosperm was observed in both OsFIE2^+? and osfie1/OsFIE2^+? but at a very low frequency. Although OsFIE1‐PRC2 exhibited H3K27me3 methyltransferase ability in plants, OsFIE1‐PRC2 is likely to be less important for development in rice than is OsFIE2‐PRC2. Our findings revealed the functional divergence of OsFIE1 and OsFIE2 and shed light on their distinct evolution following duplication.     

At3g53630 encodes a GUN1-interacting protein under norflurazon treatment

Chloroplasts are semi-autonomous organelles, with more than 95% of their proteins encoded by the nuclear genome. The chloroplast-to-nucleus retrograde signals are critical for the nucleus to coordinate its gene expression for optimizing or repairing chloroplast functions in response to changing environments. In chloroplasts, the pentatricopeptide-repeat protein GENOMES UNCOUPLED 1 (GUN1) is a master switch that senses aberrant physiological states, such as the photooxidative stress induced by norflurazon (NF) treatment, and represses the expression of photosynthesis-associated nuclear genes (PhANGs). However, it is largely unknown how the retrograde signal is transmitted beyond GUN1. In this study, a protein GUN1-INTERACTING PROTEIN 1 (GIP1), encoded by At3g53630, was identified to interact with GUN1 by different approaches. We demonstrated that GIP1 has both cytosol and chloroplast localizations, and its abundance in chloroplasts is enhanced by NF treatment with the presence of GUN1. Our results suggest that GIP1 and GUN1 may function antagonistically in the retrograde signaling pathway.

     

肺部微生物组通过炎症反应介导慢性阻塞性肺疾病转化为肺癌的研究进展

肺部微生物组存在于呼吸道和实质组织中,通过菌群紊乱、代谢产物、炎症反应、免疫反应、基因毒性等方面介导肺部损伤。随着肺部微生物组的深入研究,发现肺部微生物组的相关活动与慢性阻塞性肺疾病(chronic obstructive pulmonary disease, COPD)和肺癌息息相关,能够促使COPD向肺癌的转变。本文主要介绍了肺部微生物组稳态及其通过炎症反应导致COPD和肺癌,重点探讨了肺部微生物组如何通过炎症反应介导COPD转化为肺癌,以期为COPD和肺癌的临床预防、优化治疗以及新型药物设计提供新的理论依据。     

Cell-type action specificity of auxin on Arabidopsis root growth

The plant hormone auxin plays a critical role in root growth and development; however, the contributions or specific roles of cell-type auxin signals in root growth and development are not well understood. Here, we mapped tissue and cell types that are important for auxin-mediated root growth and development by manipulating the local response and synthesis of auxin. Repressing auxin signaling in the epidermis, cortex, endodermis, pericycle or stele strongly inhibited root growth, with the largest effect observed in the endodermis. Enhancing auxin signaling in the epidermis, cortex, endodermis, pericycle or stele also caused reduced root growth, albeit to a lesser extent. Moreover, we established that root growth was inhibited by enhancement of auxin synthesis in specific cell types of the epidermis, cortex and endodermis, whereas increased auxin synthesis in the pericycle and stele had only minor effects on root growth. Our study thus establishes an association between cellular identity and cell type-specific auxin signaling that guides root growth and development.     

基于MaxEnt模型的甘肃安西极旱荒漠国家级自然保护区北山羊生境评估

明晰甘肃安西极旱荒漠国家级自然保护区珍稀濒危物种北山羊的分布格局,并阐释气候变化和人类活动对北山羊的影响,对今后北山羊生境管理和物种保护具有重要意义。基于北山羊实测分布点记录和环境变量数据,结合MaxEnt模型和ArcGIS空间分析功能,利用CMIP6的8个气候模式均值预测中度发展路径（SSP2-4.5）下,基准期（1970-2000年）和未来气候（2041-2060年、2081-2100年）变化情景下,甘肃安西极旱荒漠国家级自然保护区北山羊的潜在适生区分布范围及变化,并综合贡献率和置换重要性值对北山羊生境选择关键环境因子进行了分析。研究结果表明：（1） MaxEnt模型的预测精度较高,三种气候条件下ROC曲线下面积（AUC,Area Under Curve）>0.97,且真实技巧统计（TSS,True Skill Statistic）>0.90,模拟结果可靠。（2）影响北山羊生境选择的主要环境因子为气候条件（降水量季节性变异系数和等温性）、海拔和人为干扰（距泉和居名点距离）。水是保护区北山羊生存的最基本要素,气候条件共同控制北山羊生境条件。此外,北山羊习性决定其生境宜选择高海拔和远离人类活动影响地区。（3）基准期保护区北山羊主要分布在北片和南片高海拔山区,面积365.77 km²（占整个保护区的4.31%）,北山羊适生区面积北片>南片、中高等适生区主要位于保护区北片。（4） CMIP6未来气候变化情景下,随着保护区生态环境改善和濒危物种保护措施的实施,北山羊潜在适生区面积呈增加趋势,但是受北山羊近亲繁殖的影响,整体上北山羊数量和适生区面积增加并不显著且有向南部及高海拔地区转移趋势。     

耐高盐枯草芽孢杆菌XP合成球形纳米硒及其抑制草莓病原真菌生物活性

生物方法合成纳米材料具有低能耗、高安全性以及环境友好等优良特点,因而备受人们关注。利用细菌将硒酸盐或亚硒酸盐还原为单质硒,不仅可以降低硒毒性,而且还能获得价值更高的生物纳米材料。文中选用可耐受高盐环境胁迫的枯草芽孢杆菌亚种Bacillus subtilis subspecies stercoris strain XP构建生物模型,分别以LB液体培养基和亚硒酸钠为介质和底物 (电子受体),解析菌株XP合成纳米硒的基本规律。通过扫描电镜 (Scanning electron microscope,SEM) 观察、X射线能谱分析 (X-ray energy dispersive spectral analysis,EDAX)、X射线衍射 (X-ray diffraction,XRD) 分析、傅里叶红外变换光谱 (Fourier transform infrared spectroscopy,FTIR) 技术对合成的纳米硒进行物理化学表征分析,同时选用草莓枯萎、红叶、紫斑病病原真菌对其抗菌活性进行分析。结果表明,菌株XP介导合成的单质硒为球形纳米颗粒 (Selenium nanoparticles,SeNPs),其生成量与反应时间呈正相关 (0–48 h),且细胞形态未发生褶皱或破损等变化 (耐受力强);SeNPs为非晶态,粒径范围在135–165 nm,表面元素组成以Se为主,同时存在C、O、N、S等有机元素;颗粒表面包裹生物大分子物质,-OH、C=O、N-H、C-H等官能团与SeNPs稳定性和生物活性密切相关;高浓度纳米硒对枯萎、红叶、紫斑病病原真菌均有显著抑制活性 (P<0.05),其中对草莓红叶病与枯萎病病原真菌的抑制活性明显优于对紫斑病病原真菌的抑制活性。总而言之,菌株XP不仅耐受高盐胁迫能力强,同时还可介导合成生物SeNPs,其合成的纳米硒颗粒具有良好的稳定性和生物活性,在草莓病害防治以及绿色富硒草莓种植等领域具有潜在的应用价值。     

重组小麦静息巯基氧化酶的表达、酶学特性及其对面包品质的影响

为发展新型面粉改良酶制剂,利用大肠杆菌Escherichia coli原核表达了小麦静息巯基氧化酶(Wheat quiescin sulfhydryl oxidase,wQSOX)。将合成的wqsox基因构建至pMAL-c5x载体,并在大肠杆菌中进行表达,优化蛋白表达条件后对重组蛋白进行分离纯化及融合标签切除,获得的重组wQSOX蛋白用于酶学性质探究以及面包品质改良。结果表明,合成的截短wqsox基因包含1359 bp,编码453个氨基酸,理论蛋白分子量51 kDa;构建的pMAL-c5x-wqsox重组质粒在E.coli Rosetta gamiB(DE3)中可溶表达了重组蛋白MBP-wQSOX,其最佳表达条件为:诱导温度25℃,诱导剂IPTG浓度0.3 mmol/L,诱导时间6 h;利用Xa因子蛋白酶切除了MBP融合标签,亲和层析纯化得到了wQSOX;wQSOX可催化DTT、GSH和Cys氧化,并伴随着H2O2的生成,其中对DTT表现出最高的底物特异性;酶学性质研究发现,wQSOX最适反应温度和pH分别为50℃和10.0,在高温和碱性环境条件下表现出较好的稳定性;每克面粉中添加1.1 U wQSOX能够显著(P<0.05)提高26.4%的面包比容,降低20.5%的面包芯硬度和24.8%的咀嚼性,表现出了较好的改良面包加工品质能力。研究结果对丰富新型面粉改良酶制剂种类以及推动wQSOX在焙烤行业的应用奠定了理论基础。