海南长臂猿破碎化生境中食物资源可利用性分析

食物种类及其可获得性是动物生存的基本条件,也是生境质量评价的重要指标。2013年1月至2014年7月,对海南长臂猿(Nomascus hainanus) C群生境内食源植物种类、数量、食物可获得性及主要取食植物的径级结构进行调查分析,共记录到64种食源植物(标记胸径≥5 cm的乔木1 484株)。海南长臂猿以高大粗壮的食源植物为主要采食对象。这些乔木型食源植物结果率超过50.0%的有15种,占C群全部乔木型采食植物种数的28.8%;结果率最高的是海南单籽暗罗(Monoon laui, 76.7%),最低的是鹅掌柴(Heptapleurum heptaphyllum, 9.6%)。18种长臂猿主食食源乔木中,白肉榕(Ficus vasculosa)、斜叶榕(Ficus tinctoria)等15种食源植物的植株呈增长型结构。南酸枣(Choerospondias axillaria)、二色波罗蜜(Artocarpus styracifolius)为稳定型结构,而桃榄(Pouteria annamensis)为衰退型结构。提示海南长臂猿食物供应植物仍处于年轻状态,但这些食源植物并非每年结果,...     

外来植物黄顶菊营养器官解剖特征及其生态适应性

采用扫描电镜和光学显微镜对外来植物黄顶菊营养器官的解剖结构研究。结果表明：黄顶菊叶片表皮具较厚的角质层、下陷气孔,叶片为等面叶、全栅型,叶肉细胞环绕维管束鞘细胞紧密排列,是典型C₄植物的Kranz花环结构;茎中厚角组织和维管组织发达,根中还存在通气组织;根、茎、叶中均存在分泌结构。综合光照、温度、土壤pH、有机质、含盐量及伴生种等生态因子分析表明,黄顶菊喜光、喜高温,耐受干旱、盐碱及贫瘠土壤,可与一些耐干旱耐盐碱较强的植物共生。黄顶菊营养器官特别是叶片的解剖特征体现的生态适应性可能与其耐受恶劣生境的能力之间存在一定的相关性,可能是导致黄顶菊具有较强入侵性的原因之一。     

河南南召余坪旧石器地点的发现与研究

余坪地点位于河南省南召县汉水中游支流松河南岸第二级阶地前缘,于2021年3月由吉林大学考古学院、南阳市文物考古研究所调查发现。地表采集石制品38件,包括石核4件、石片3件、断块4件、使用石片5件、石器22件。个体多为小型与中型。原料皆河漫滩砾石,岩性以石英为主。石核剥片采用硬锤锤击,偶见砸击法。剥片方法属普通石核石片技术。使用石片分为刮削刃、尖刃者两类。石器包括刮削器、尖刃器、钻器、砍砸器、砍伐器和手锛。毛坯多为石片与断块,未见砾石毛坯。根据地貌与石制品特征,时代应属旧石器时代晚期。文化属性为石片石器技术系统。该地点对于探讨南北方过渡地区旧石器时代晚期的文化特点具有重要意义。     

小陇山国家级自然保护区次生林分类、排序及演替

在野外调查基础上,采用TWINSPAN和DCA对小陇山林区次生林群落进行了数量分类和排序,从植物群系组成、植物群落与环境的生态关系方面,研究小陇山植被群落的分布格局,用以确定该区次生林演替,并给予合理的环境解释。结果表明:采用TWINSPAN数量分类方法,将植被划分为12个群落类型;DCA排序图明显反映出排序轴的生态意义,第一轴基本上突出反映了湿度变化,沿第一轴从左到右,湿度逐渐增大;第二轴主要表现了温度梯度,沿第二轴从下到上,温度逐渐降低;次生林的演替序列为山杨林→山杨+白桦林→锐齿栎混交林及锐齿栎纯林,其自然恢复演替以锐齿栎林为顶极群落。     

局地气候区视角下的城市热环境研究

城市化发展带来热岛效应,影响区域气候变化,地表温度可以反映地表增温程度,更能直接影响人类居住舒适度。运用Landsat8 TIRS热红外遥感数据和气象数据反演地表温度,以建筑数据、遥感影像为基础,通过GIS空间分析、决策树分类等方法划分局地气候区,从区域角度定量分析不同类型气候区地表温度分异规律。结果表明：(1)北京、天津、石家庄密集型建筑分别占比27.54%、21.95%、25.09%,且以中低层为主,城市公园包含了主要的绿地和水体。(2)在空间分布上,市中心地表温度高于郊区,热岛效应显著,森林、河流是主要低温区。(3)不同气候区的地表温度存在差异,建成区总体高于自然地表;其中建筑区域内表现为紧密型低层(LCZ3)平均地表温度最高,稀疏型高层(LCZ4)地表温度最低,北京、天津、石家庄分别相差1.53℃、2.30℃、2.22℃;植被和水体能够降低地表温度,裸土和铺设路面的地表温度始终较高。因此应充分考虑建筑布局,合理利用植被和水域分布,减少热量聚集,以改善城市生态环境。     

Biomass and terpenoids produced by mutant strains of <Emphasis Type="Italic">Arthrospira</Emphasis> under low temperature and light conditions

The filamentous Cyanobacterium Arthrospira is commercially produced and is a functional, high-value, health food. We identified 5 low temperature and low light intensity tolerant strains of Arthrospira sp. (GMPA1, GMPA7, GMPB1, GMPC1, and GMPC3) using ethyl methanesulfonate mutagenesis and low temperature screening. The 5 Arthrospira strains grew rapidly below 14?°C, 43.75 μmol photons m^?2 s^?1 and performed breed conservation at 2.5?°C, 8.75 μmol photons m^?2 s^?1. We used morphological identification and molecular genetic analysis to identify GMPA1, GMPA7, GMPB1 and GMPC1 as Arthrospira platensis, while GMPC3 was identified as Arthrospira maxima. Growth at different culture temperatures was determined at regular intervals using dry biomass. At 16?°C and 43.75 μmol photons m^?2 s^?1, the maximum dry biomass production and the mean dry biomass productivity of GMPA1, GMPB1, and GMPC1 were 2057?±?80 mg l^?1, 68.7?±?2.5 mg l^?1 day^?1, 1839?±?44 mg l^?1, 60.6?±?1.8 mg l^?1 day^?1, and 2113?±?64 mg l^?1, 77.7?±?2.5 mg l^?1 day^?1 respectively. GMPB1 was chosen for additional low temperature tolerance studies and growth temperature preference. In winter, GMPB1 grew well at mean temperatures <10?°C, achieving 3258 mg dry biomass from a starting 68 mg. In summer, GMPB1 grew rapidly at mean temperatures more than 28?°C, achieving 1140 mg l^?1 dry biomass from a starting 240 mg. Phytonutrient analysis of GMPB1 showed high levels of C-phycocyanin and carotenoids. Arthrospira metabolism relates to terpenoids, and the methyl-d-erythritol 4-phosphate pathway is the only terpenoid biosynthetic pathway in Cyanobacteria. The 1-deoxy-d-xylulose 5-phosphate reductoisomerase (DXR) gene from GMPB1 was cloned and phylogenetic analysis showed that GMPB1 is closest to the Cyanobacterium Oscillatoria nigro-viridis PCC711. Low temperature tolerant Arthrospira strains could broaden the areas suitable for cultivation, extend the seasonal cultivation time, and lower production costs.     

Exosomal miR-27 negatively regulates ROS production and promotes granulosa cells apoptosis by targeting SPRY2 in OHSS

Ovarian hyperstimulation syndrome (OHSS) is one of the most dangerous iatrogenic complications in controlled ovarian hyperstimulation (COH). The exact molecular mechanism that induces OHSS remains unclear. In recent years, accumulating evidence found that exosomal miRNAs participate in many diseases of reproductive system. However, the specific role of miRNAs, particularly the follicular fluid-derived exosomal miRNAs in OHSS remains controversial. To identify differentially expressed follicular fluid exosomal miRNAs from OHSS and non-OHSS patients, the analysis based on miRNA-sequence was conducted. The levels of 291 miRNAs were significantly differed in exosomes from OHSS patients compared with normal control, and exosomal miR-27 was one of the most significantly down-regulated miRNAs in the OHSS group. By using MiR-27 mimic, we found it could increase ROS stress and apoptosis by down-regulating the expression of p-ERK/Nrf2 pathway by negatively regulating SPRY2. These data demonstrate that exosomal miRNAs are differentially expressed in follicular fluid between patients with and without OHSS, and follicular fluid exosomal miR-27 may involve in the pathological process of OHSS development.     

鞘喙亚目化石研究进展

详细总结和回顾了世界鞘喙亚目化石研究简史,列出已发表的化石种类名录、分布及年代,不同地质年代发现的鞘喙亚目种类、数量、地理分布位置存在差异。简要介绍了鞘喙亚目分布特点,并提出鞘喙亚目昆虫化石研究中存在的问题,展望其研究前景。     

POLARITIES, CELL DIFFERENTIATION AND PRIMARY INDUCTION IN THE AMPHIBIAN EMBRYO

1. Amphibian eggs are spherical, while the embryos are bilaterally symmetrical. The latter is manifested morphologically when gastrulation begins with the formation of the blastopore at a bilaterally symmetrical (vegetal-dorsal) location on the surface of the embryo. To account for this change in symmetry two polarities (vectors or axes) are required. These need not go through the centre, but if they do, one will go through two poles, called ‘animal’ and ‘vegetal’ in the amphibian embryo, and the other will pass through two points on opposite sides of the egg, one at the ‘dorsal’ and one at the ‘ventral’ side. Together these two polarities define a plane of bilateral symmetry. 2. It may be assumed that one polarity determines that gastrulation begins in the vegetal hemisphere, and the other that it begins at the dorsal side. 3. Judging from the distribution of pigment in the cortex of the egg and that of the yolk-hyaloplasm in the interior, an animal-vegetal polarity is already present in the unfertilized egg. That cytoplasmic components are actually part of the material substrate of this polarity is evident from the fact that the pattern of gastrulation may be upset if the distribution of yolk-hyaloplasm is deranged. 4. At fertilization the pigment border is raised at the side opposite the fertilizing sperm, giving rise to the ‘grey crescent’. The latter confers the first visible bilateral symmetry on the egg, and in fact it determines the presumptive median plane, for blastopore formation begins in the midline of the grey crescent. The dorso-ventral polarity imposed by the sperm is not irreversibly determined. By various experimental means, e.g. restriction of the oxygen supply, it may be inverted. 5. In order to understand the mechanism of the polarities it is necessary to study the processes on which the effects of the polarities are exerted, viz. the process of invagination associated with the formation of the blastopore. It has been known for a long time that at the bottom of the blastoporal groove are located some large flask-shaped cells, called ‘Ruffini's cells’. Various arguments can be mobilized to support the notion that these cells actually are engaged in pulling in the embryonic surface. 6. These cells are the first representatives of a cell type different from the spherical cells which are typical of the early embryo. It may therefore be presumed that Ruffini's cells are the products of the first cell differentiation occurring during amphibian embryogenesis. And it may further be assumed that the polarities somehow control this process. 7. A number of observations suggest that the animal-vegetal polarity is in direct control of the differentiation, ensuring that Ruffini's cells are formed only in the vegetal hemisphere. This point has been corroborated by isolating in cultures small aggregates from various regions of the blastula. When this is done it is found that the only path of differentiation available to animal cells is the formation of small spherical aggregates composed of a mixture of ciliated and non-ciliated cells. In contrast, in cultures of vegetal cells an outgrowth of cells occurs, and these cells share a number of properties with Ruffini's cells, and it is suggested that they are representatives of this cell type. 8. The formation of these cells is suppressed by inhibitors of RNA synthesis and by anaerobiosis induced by KCN. Since oxidative metabolism is apparently required for the differentiation of Ruffini's cells - gastrulation in the intact embryo is suppressed by anaerobiosis - a number of carbohydrate metabolites were scrutinized for their effect on the formation on Ruffini's cells. It was found that at 10 mm lactate completely suppresses their appearance, and indeed all the other cell differentiations that can otherwise be observed in our cell cultures. Since there is a very steep animal-vegetal cytoplasmic gradient in carbohydrate, the content being lowest at the vegetal pole, lactate might potentially be the agent of the animal-vegetal polarity, but there are a number of facts which do not readily support this idea. 9. If animal cells are explanted together with a few vegetal cells, some of the aggregates do not become ciliated, but rather exhibit an outgrowth similar to the one observed with vegetal cells. These animal cells have the same general shape as the vegetal Ruffini's cells, but they are smaller and more pigmented, typical ‘animal’ features. When the cultures are preserved, the cells undergo further differentiation, becoming either ‘mesenchyme’ cells, nerve cells, pigment cells and sometimes even muscle cells may be observed. In the normal embryo these differentiation patterns occur in that part of the animal hemisphere which becomes induced through contact with the vegetal material entering the blastocoel during gastrulation. Thus there is reason to assume that the induction occurring in our cultures is a miniature of the normal induction process. 10. Just as in the sea-urchin embryo, the animal cells in amphibia may become ‘vegetalized’ by addition of Li⁺ to the culture medium. 11. For various reasons it is likely that Ruffini's cells contain heparan sulphate, and in the belief that this substance might be the inductor proper, its effect was tested on animal cells. It turned out that in a concentration of 0·1 ppm it can alter the differentiation pattern of these cells, and we suggest that heparan sulphate, for the time being, is the most likely candidate for the role of primary inductor in the amphibian embryo. 12. The edges of the blastoporal groove, and hence the formation of Ruffini's cells, proceeds gradually around the circumference of the embryo. The effect of the dorso-ventral polarity therefore appears to be concerned with the time at which the cells undergo differentiation, imposing a spatial and a temporal gradient on this phenomenon. The second overt manifestation of the dorso-ventral polarity, next to the formation of the grey crescent, concerns the size of the embryonic cells, the dorsal ones being always smaller than the ventral. This fact suggests the possibility that the polarity may exert its effect by interfering with the process of cell division. 13. The cell divisions in the early embryo are distinguished by being synchronous; all cells are either undergoing mitosis or they are in interphase. The duration of the latter is typically very short. After a certain number of cell divisions, around 10, when the embryos are in the mid-blastula stage, the synchrony is gradually lost, while the interphase becomes considerably prolonged. This peculiar behaviour suggests that the cytoplasm of the early embryonic cells contain some factor which ensures the synchrony. The well-known presence in the early embryo of deoxyriboside-containing material, in an amount corresponding roughly to the total amount of DNA residing in the cell nuclei after 10 cell divisions hinted that deoxyribosides might indeed be the ‘synchrony factor’. 14. This idea was tested first on intact embryos. An excess of deoxyribonucleotides was injected into very early embryos. The result was developmental arrest at a pregastrula stage (no Ruffini's cells formed) in a large percentage of embryos. However, the number of cells was greater than in the controls, and the rate of cell division higher, indicating a delay in the transition to synchrony, thus supporting the proposed mechanism. Furthermore, the deoxynucleotides inhibited cell differentiation and an explanation of this was found in the fact that they also strongly inhibited RNA synthesis. 15. The studies were extended to cell cultures. It was found that deoxyribosides inhibit the differentiation of animal as well as vegetal cells; instead, the cells go on dividing at least for another two rounds. The utilization of added deoxyribosides does not demonstrate that the endogenous substances are similarly utilized. That they are, was indicated by the following experiment: In the presence of cytosine arabinoside, an inhibitor of DNA synthesis de novo, the explanted cells go on dividing an unknown number of times, and then they, animal as well as vegetal cells, undergo differentiation. But in either case these cells are larger (about four times) than the controls. This result suggests that in the experimental cultures the cells go on dividing as long as the cytoplasmic deoxyribosides last and then stop, while the controls synthesize their own DNA for two rounds of division before they undergo differentiation. 16. It is now possible to suggest a mechanism for the dorso-ventral polarity. First it affects the cell size such that the dorsal cells are the smallest. If the cytoplasmic deoxyribosides are evenly distributed at the outset, then small cells must be nearer exhaustion than large ones. A dorso-ventral gradient in cell sue will therefore automatically imply a dorso-ventral gradient in the time at which the cells reach the state in which they can undergo differentiation.