Pollination biology of the Proteaceae in Australia and southern Africa

Proteaceae are most diverse in southern Africa and Australia, especially in the south-western portions of these regions. Most genera have some species in flower at all times of the year, although generally there is a preponderance of species that flower between late winter and early summer. The one genus that is an exception to this generalization is Banksia, which either has approximately the same percentage of species in flower at various times of the year (southwestern Australia) or peaks in autumn (southeastern Australia). Within particular communities, opportunities for hybridization among congeneric species are minimized by staggered flowering times, different pollen vectors and/or various incompatibility mechanisms. Birds, mammals and arthropods have been identified as visitors to the inflorescences of many Proteaceae. The most common avian visitors to the majority of genera in Australia are honeyeaters, although lorikeets, silvereyes and approximately 40 other species sometimes may be important. Sugarbirds and sunbirds are seen most frequently at inflorescences of Protea, Leucospermum and Mimetes in southern Africa, although they rarely visit other genera. In most cases, avian visitors forage in a manner that permits the acquisition and transfer of pollen. Limited evidence supports the hypothesis that birds are selective in their choice of inflorescences, responding to morphological and/or colour changes and usually visiting those inflorescences that offer the greatest nectar rewards. Arthropods may be equally selective, although it is possible that only the larger moths, bees and beetles are important pollinators, even for those plant species that rely entirely on arthropods for pollen transfer. Mammals are pollen vectors for some Proteaceae, especially those that have geoflorous and/or cryptic inflorescences. In Australia, small marsupials may be the most important mammalian pollinators, although rodents fill this niche in at least some southern African habitats. All but two genera of Proteaceae are hermaphroditic and protandrous, the exceptions being the dioecious southern African genera Aulax and Leucadendron. For hermaphroditic species, the timing of visits by animals to inflorescences is such that they not only acquire pollen from freshly opened flowers but also brush against pollen presenters and stigmas of others that have lost self-pollen and become receptive. Birds and insects (and probably mammals) generally forage in such a way as to facilitate both outcrossing and selfing. Some species are self-compatible, although many require outcrossing if viable seed is to be formed. Regardless of which animals are the major pollen vectors, fruit set is low relative to the number of flowers available, especially in Australian habitats. Functional andromonoecy of the majority of flowers is advanced as the major cause of poor fruit set. The pollination biology and breeding systems of Australian and southern African Proteaceae resemble one another in many ways, partly because of their common ancestry, but also due to convergence. Divergence is less obvious, apart from the dichotomy between dioecious and hermaphroditic genera, and differences in the levels of seed set for Australian and African species. Future studies should concentrate on identifying the most important pollinators for various Proteaceae, the manner in which their visits are integrated with floral development and factors responsible for limiting fruit set.     

量天尺根部内生真菌的多样性

为了解不同量天尺（火龙果）品种根部内生真菌菌群组成及多样性,采集GHL-1、GHL-2、GHL-3、ML-1和DL 5个量天尺品种健康根部样品,进行内生真菌分离,采用形态观察和ITS序列分析相结合的方法进行鉴定、归类。共分离得到内生真菌菌株117株,总体分离率为25.71%,分别隶属于13个属,其中Trichoderma、Fusarium、Chaetomium和Phoma为量天尺内生真菌的优势种群,分别占总菌株数的24.79%、35.04%、10.26%和10.26%;不同量天尺品种内生真菌的结构和组成存在一定差异,GHL-2、GHL-3和DL 3个品种中分离频率最高的内生真菌类群为Fusarium,GHL-1和ML-1分离频率最高的类群为Trichoderma;多样性分析结果反映出不同量天尺品种内生真菌菌群的多样性指数、丰富度指数和均匀度指数水平存在差异,其中GHL-2的3项指数均为最高。表明品种差异对内生真菌的组成和多样性均有影响。     

横断山齿突蟾属一新种(两栖纲:锄足蟾科)

1982年在横断山区考察期间,发现四川木里截族自治县的齿突蟾Scutiger标本在第二性征、趾蹼等特征与已知的各种齿突蟾均不相同,描述为新种木里齿突蟾Scutiger muliensis。     

齿突蟾属某些种的多态现象

本文报道某些锄足蟾科Pelobatidae动物的多态现象。讨论了同域或不同域的四种齿突蟾Scuti-ger,即刺胸齿突蟾S. mammatus(Guenther)、胸腺齿突蟾S. glandulatus(Liu)、木里齿突蟾S. mulicnsis Fei et Ye和皱纹齿突蟾S. ruginosus Zhao et jiang的皮肤瘰疣、第二性征等性状;用薄层等电聚焦电泳方法分析了同域三种齿突蟾的晶体蛋白。结果表明:前三种是有效种;后一种,即皱纹齿突蟾分别是前三种的多态性变体;这些变体以相同性状(即皮肤多瘭疣)同时表现在三个种中的现象,属于平行多态现象。     

广东省蝗虫二新种(直翅目:蝗总科)

在整理广东省蝗虫标本时,发现二新种。模式标本保存于中山大学昆虫学研究所标本室。 1.蒲氏板齿蝗Sinstauchira pui新种(图1—9) 雄虫 体中型。头短于前胸背板,头顶平,顶端圆形,宽略大于长。触角丝状,到达后足股节基部,中段一节长为宽的2倍。颜面倾斜,具粗刻点,颜面隆起明显,中眼以上侧缘近平行,中眼以下逐渐展开,纵沟浅。复眼卵圆形,纵径为横径的1.38倍,为眼下沟的2.57倍。眼间距为触角间颜面隆起的1.6倍。前胸背板前缘较平,后缘呈弧形突出;中隆线明     

广西贵县的螟害规律及其预测方法的探讨

1.从广西贵县1958—1964年的七年螟害调查资料,可以将全年螟害的消长趋势,划分为世代递减发生型、世代递增发生型和第三世代多发型等三种螟害发生型。 2.形成三种螟害发生型的原因,主要系由于水稻播植期的早晚与螟虫发生为害的不同组合所致。水稻播植期较早的年份,形成世代递减发生型;播植期较晚的年份,形成世代递增发生型:播植期居中的年份,则形成第三世代多发型。 3.本文根据历史资料,订出早、中、晚播植期的标准,以此标准为坐标图上的横轴,各世代螟害率为纵轴,作出了播种期与螟害型的关系模式图。根据这个模式图,在某年掌握了早稻播种期以后,就可以作出该年螟害发生发展趋势的展望。 4.求算三种螟害发生型各世代之间的螟害增减比值历年平均数,在某年获悉早稻播种期和第一世代实测螟害率以后,就可以根据这个比值平均数,依次推算以后各世代的预测螟害率。 5.关于各世代螟害率的近期预测,本文主张以幼虫虫口密度为依据,求算虫口密度与其所造成螟害率的二次函数曲线方程式,在获得幼虫密度以后,代入方程式来计算近期预测的螟害率。     

蚕豆叶片发育与衰老过程中超氧物歧化酶活性与丙二醛含量变化

蚕豆植株叶片随茎节自上而下表现出明显的发育与衰老顺序,可作为衰老特征的是叶绿素和蛋白质含量明显下降。蚕豆叶中SOD活性主要定位于12 000× g离心后所得的上清液和叶绿体组分。衰老叶片的SOD总活性和叶绿体组分的相对活性都有所下降,SOD同工酶谱也发生了改变。O_2~ 产生速率随叶龄增大而稍上升;而MDA含量在叶片外观表现枯黄衰老征兆前就急剧上升。可能因为衰老叶片过氧化氢酶活性大幅度下降与SOD之间的不平衡,致使O_2~ 代谢中间产物累积而引起膜的损伤.     

光对尾穗苋幼苗内苋红素合成的诱导

不同苗龄的尾穗苋黄化苗对10 min,15Wm~(-2)白光的反应能力不同。光诱导的苋红素合成始于播种后第 20h,至50h合成能力最大,82h以后幼苗对短时光照的反应能力趋于消失。苋红素合成的滞后期为3h,光处理后18h色素积累达到高峰。光调节苋红素合成符合红光—远红光可逆诱导反应等两个基本模式,确证光敏色素参与调控苋红素合成.