茶树内生木霉种的鉴定及其在植物体内的定殖

采用分离自健康茶树叶片组织的一株长枝木霉Trichoderma longibrachiatum菌株CSN-18,研究茶树内生木霉的人工接种、再分离及其在茶树地上部组织中的内生性。该菌在PDA培养基上生长速度快,产孢量大。用CSN-18回接茶苗,接种后一个月可以从茶苗的茎和叶组织中再分离获得该真菌。接种后的茶苗没有观察到明显的病害表现;与对照相比,接种后6个月组培苗生长良好,叶色更绿;接种后1个月,实生苗生长正常。通过石蜡切片和苯胺蓝染色,在已接种的茶树组培苗的叶片内部组织中可观察到木霉的存在,从而证明了木霉能够在茶树地上部组织内定殖,是茶树的一种内生真菌。     

结果初期黄冠梨对春施15N-尿素的吸收、分配与利用

以3年生黄冠梨为材料,探讨了早春施用¹⁵N尿素后,树体在萌芽期-新梢缓慢生长期和新梢缓慢生长期-果实成熟期对氮素的吸收、分配与利用特性。结果表明: 梨树在萌芽期-新梢缓慢生长期主要以新梢和叶片等营养器官生长为核心;在新梢缓慢生长期-果实成熟期则以根系等贮藏器官生长为主,果实产量品质形成为辅,且树体尤其是贮藏器官的生物量成倍增加。由于各器官尤其是新梢和叶片生长旺盛、新梢缓慢生长期吸收的标记氮量相对较多,各器官吸收的肥料氮(Ndff)值相对较高;果实成熟期除粗根外各器官的Ndff值均低于新梢缓慢生长期。萌芽期到新梢缓慢生长期吸收的标记氮主要分配在新梢和叶片营养器官中,新梢缓慢生长期到果实成熟期吸收的标记氮则主要分配在贮藏器官中;整个生育期间,植株吸收的标记氮在贮藏器官中分配率最高,营养器官次之,生殖器官中分配率最低。3年生梨树从萌芽期-新梢缓慢生长期、新梢缓慢生长期-果实成熟期吸收的肥料氮分别占当年总吸氮量的31.1%和21.0%,而两个时期内吸收的土壤氮占比分别达68.9%和79.0%。     

赤霉素和氨基酸对三叶赤楠（Syzygium grijsii）枝叶生长影响研究

采用正交设计,研究了不同浓度氨基酸和赤霉素混合喷施对三叶赤楠枝条、叶片生长的影响。结果表明：三叶赤楠的生长曲线呈现双峰状,春秋季各有一生长高峰。氨基酸和赤霉素两者间交互作用显著,对三叶赤楠枝条和叶片生长均有一定的促进作用。但氨基酸对于三叶赤楠生长的促进作用有限,在观察到的生长差异中,绝大部分是由赤霉素浓度差异造成的。对于枝条及叶片生长来说,100 mg·L^-1的赤霉素浓度比较合适。新梢长、新梢分枝数及叶面积受混合喷施影响较大,不同处理间差异显著或极显著,而成熟枝条及叶片厚度受其影响较小,差异不显著。经主成分分析发现新梢月平均生长量和分枝数可作为快速评价混合喷施效果的描述指标;而叶片厚度和叶面积,即第二主成分可作为潜在评价氨基酸和赤霉素混合喷施长期效果的描述指标。在生产中可以以新梢长度、生长量和分枝数作为评价氨基酸与赤霉素喷施效果的快速指标。     

组织透明法观察葡萄叶片生长过程中气孔与叶脉形态结构特征变化

本文以‘摩尔多瓦’葡萄叶片为试验材料,采用组织透明法观察了葡萄叶片生长过程中叶片表皮细胞、气孔和叶脉形态结构的变化,测定与气孔和叶脉功能相关的生理指标变化,比较了组织透明法、指甲油法和撕取法在观察葡萄叶片气孔上的实验效果。结果表明:组织透明法能够清晰观察到葡萄叶片生长过程中叶片表皮细胞、气孔和叶脉形态结构的变化。相对于指甲油法、撕取法,组织透明法操作简单,且能保持组织完整性,提升观察叶片细胞结构的实验效果。从叶片生长过程中气孔形态结构变化规律来看,葡萄嫩叶齿尖存在大量的大气孔,而叶片中部只观察到中央大气孔和正在发育的气孔保卫细胞母细胞。随着叶片生长,叶片气孔保卫细胞母细胞逐渐发育形成成熟气孔,叶片末端叶脉也是随叶片生长而生长,叶脉密度逐渐增加,提高了树体往叶片供水的效率。从与气孔和叶脉功能相关的各项生理指标变化来看,气孔导度随着气孔逐渐形成和成熟而逐渐升高,但叶片含水量和水势下降,有利于拉升水分和养分从根系往地上树体各器官运输,满足整个植株生长发育的需要。     

苹果矮化砧木‘JM7’的组织培养及其离体叶片不定梢再生

以苹果优良矮化砧木‘JM7’ （Malus prunifolia×M. pumila ‘Malling 9’）为试材, 研究了基本培养基对试管苗增殖生长的影响、蔗糖浓度对试管苗生根的影响及基本培养基、细胞分裂素种类和浓度对离体叶片不定梢再生的影响。结果表明： 基本培养基MS比QL显著提高增殖梢数, 但QL比MS更有利于获得健壮生长的绿苗。3%蔗糖浓度比2%的不定根发生速度快。叶片不定梢再生最适宜的基本培养基是QL。在QL培养基上, 6-BA和TDZ对离体叶片不定梢再生率的影响无显著差异, 但6-BA诱导产生的不定芽在不定梢诱导培养基上可直接伸长生长形成不定梢, 而TDZ诱导产生的不定芽需转移到不加TDZ而加低浓度6-BA的培养基上形成伸长生长的不定梢。     

骆驼蓬属营养器官的旱生结构

对国产骆驼蓬属３种７个地方居群的营养器官内部构造作了对比观察。结果表明：该属植物具有明显的旱生结构,主要特点为：根周皮发达;器官中有同心性异型维管束;茎叶肉质,内有发达的贮水组织,叶栅栏组织发达,呈环栅型、叶片表面积与体积之比较小;茎的皮层、髓部及叶肉组织有大量含晶细胞。     

墨兰试管苗植株的发育解剖学研究

用石蜡切片和扫描电镜对墨兰试管苗植株的生长发育进行了研究。发现幼叶中脉附近的叶肉细胞类似栅栏组织,随着叶片的不断成熟,叶片基部中脉附近的叶肉细胞逐渐变为近圆形或椭圆形,而叶尖部和叶中部中脉附近的叶肉细胞仍似栅栏组织。茎的发育经历了原球茎、根状茎和假鳞茎3个阶段。原球茎的大部分细胞都含有淀粉粒,根状茎的皮层细胞含淀粉粒,而假鳞茎几乎不含淀粉粒。幼根没有髓,皮层细胞含淀粉粒：成熟根具含淀粉粒的髓。出瓶苗上即带有4个芽,一般只有最外侧叶腋的1个花芽和最内侧叶腋的1个叶芽发育。     

杨树新梢积累营养贮藏蛋白质的细胞学研究

采用光学显微镜和电子显微镜技术,对杨树新梢中的营养贮藏蛋白质进行了细胞学鉴定。在用戊二醛固定的标本中,营养贮藏蛋白质呈颗粒状,积累在中央大液泡里。在新梢伸长生长时期,新梢茎的基部已积累了营养贮藏蛋白质,在伸长生长刚停止,中上部的叶片近成熟时,整个新梢的茎都有营养贮藏蛋白质的积累,其中,以新梢基部的茎最为丰富。营养贮藏蛋白质优先在次生韧皮部的韧皮薄壁细胞和韧皮射线薄壁细胞中积累,在新梢伸长生长停止后,新梢基部茎的木质部中也积累了相当数量的营养贮藏蛋白质,主要分布在初生木质部和内侧次生木质部的各种生活的薄壁细胞中。新梢较早地积累营养贮藏蛋白质是热带树木和温带树木的一个共同特点,对于树木的氮代谢和树木当年的生长发育可能具有重要的调控作用。     

关于竹类植物的生长与开花问题的探讨

竹类植物的生长过程一般可分三个阶段:第一阶段首先是自生长点下端完成胚组织的生长,继之出现各节间的基部,最後各细胞继续分裂增殖,分化出初期的横隔壁和髓组织,这一阶段的主要特点是生命物质与细胞数量的增加。其次是竹类植物幼秆有显著的高生长与肥大生长,就右图刚竹(Phyllostachys bambusoides)幼秆纵割面观察之,从先端第一节至第六节的髓组织差不多一样肥厚,至第六节以下,可见髓组织膨大凸出,並分裂出新组织向水平方向扩大,形成秆的肥大生长,这就是第二阶段,这一阶段     

云南横坑切梢小蠹生物学研究

横坑切梢小蠹Tomicus minor (Hartig)是云南松Pinus yunnanensis Franchet的主要次期性害虫之一。1980年以来,该虫与纵坑切梢小蠹T. piniperda（L.）一起在中国西南部大量发生,导致数十万公顷云南松林受害。本文报道了横坑切梢小蠹在云南地区的生活史、生长、发育、繁殖等生物学特征。横坑切梢小蠹年生活史为一代,前后两代在冬春季有部分重叠。成虫羽化于4月下旬开始陆续,5 月下旬结束。成虫羽化后即飞到树冠上蛀食枝梢,直到11月发育成熟,开始繁殖。在此期间,每头成虫可以蛀食4～6个枝梢。横坑切梢小蠹在云南没有越冬习性。繁殖期从11月至次年3月。成虫主要在已经受到纵坑切梢小蠹危害的树木的中、下部产卵。繁殖期较纵坑切梢小蠹约迟1周。由于横坑切梢小蠹从枝梢到树干对云南松持续危害,对树木的危害性较在其它地区更为严重。横坑切梢小蠹利用受到纵坑切梢小蠹蛀害的树木繁殖产卵,加强了蠹虫对云南松树的危害,加速了受害树木的死亡进程。横坑切梢小蠹的上述生物生态学特征是该虫对云南松造成严重危害的重要原因。从横坑切梢小蠹虫体和虫坑中检测到伴生真菌云南半帚孢Leptographium yunnanensis。横坑切梢小蠹对该菌的带菌率在蛀梢期为11.5%;在蛀干中期约为10%～26%。     

Translocation of assimilates in Undaria and its cultivation in China

Undaria cultivation on a commercial scale began in China only in the last decade. Today, Undaria pinnatifida is the main species under cultivation concentrated in two provinces, Liaoning and Shandong. The annual production in the early nineties was 8000-13 000 tons dry weight, which is two or three times the pre-1980 figures. The raft cultivation method maintaining the alga at the desired depths generally ensures the light saturated rate of photosynthesis on clear days, and enhances production. Under the cultivated condition, the calculated annual primary productivity of this alga is 160 gC m⁻² y⁻¹. Translocation of ¹⁴C-labelled photoassimilates in rapidly growing sporophyte of Undaria pinnatifida was studied in the open sea. Samples from different parts of the blade with counterparts exposed to tracer (NaH¹⁴CO₃) showed that the translocation that occurred mainly from the tip of the blade to the growing region had obvious source-sink relationship. It took 20 minutes to translocate the labelled photoassimilates from the epidermis, via cortex, to the medulla of the midrib, where rates of translocation averaging 42–48 cm h⁻¹ were observed in the open sea. Production experiments of tip-cutting of the blades showed an increased production of 9%. This revised version was published online in August 2006 with corrections to the Cover Date.     

TRANSLOCATION OF PHOTOSYNTHATE IN THE BROWN ALGA NEREOCYSTIS

Translocation of photosynthates was found to occur when blades of Nereocystis were illuminated in the presence of C¹⁴ bicarbonates. Rates of translocation averaging 37 cm/hr in the laboratory were observed. Samples from the epidermis, cortex, and medulla of the stipes of plants with blades exposed to tracer showed that the radioactivity in organic compounds was confined to medulla where sieve filaments occurred. Girdle preparations of blades, interrupting the mucilage ducts and leaving the blade medulla intact, allowed translocation to take place. These data indicate that conduction of photosynthate takes place in the medulla. Similarities between the anatomy of algal sieve filaments and angiosperm sieve tubes, coupled with the continuity of the sieve filaments from blade medulla to stipe medulla suggested indirectly that the sieve filaments were conducting elements. Further support of this hypothesis was provided from collections of radioactive exudate from cells in the medulla of the lower stipe that were continuous with the sieve filaments. Tracer applied to the blades was partially recovered as organic material in a clear fluid that collected inside the pneumatocyst. Continued accumulation of radioactivity in this fluid was dependent on living blades; fluid with low specific activity that did not increase during the experiment accumulated slowly if blades were killed with ethanol after an exposure to tracer. It is possible that the system that produced the stipe fluid was part of (or a side effect of) the system responsible for maintaining volume in the conducting system. It may also provide an alternate route (other than the sieve filaments) for delivery of photosynthates to the base of the plant. Carbon-14 applied to blade tips as bicarbonate was recovered in part as radioactive mannitol in the translocation stream.     

Sink to source transition in developing leaf blades of tall fescue

This study aims to characterize the translocation of photosynthates within and from developing tall fescue ( Festuca arundinacea ) leaves at the time of transition from sink to source. The developing leaf contains a source, the exposed tip, and a sink, the growing basal portion. When the exposed tip of the developing blade is labelled with ¹⁴CO₂, it exports photosynthates exclusively to sinks within the developing blade until the blade reaches 80% of its final length, when photosynthates begin to be exported from the blade and pass through the collar to reach the growing sheath and the next expanding leaf. Concurrently, the previous mature leaves reduce their level of photosynthate export to the developing blade; export stops as soon as the sheath of the developing leaf elongates beyond 10 mm. Export from the mature leaves to the growing sheath and to the next expanding leaf blade increases rapidly. Thus, in a developing tall fescue leaf blade photosynthate importation and exportation are exclusive events: the expanding blade imports photosynthate from mature leaves until it reaches 80% of its final length, then exportation begins and importation ceases.     

THE RATE OF TRANSLOCATION IN ALARIA ESCULENTA (LAMINARIALES,PHAEOPHYCEAE)12

The rate of translocation of organic carbon in blades of Alaria esculenta (L.) Grev. (Laminariales) was calculated from blade growth data. The cross sectional area of sieve filaments in the midrib medulla was estimated from light microscopic examination of fresh material. Files of these filaments form a perimedullar ring occupying ca. 2/3 of the medulla. Values computed for specific mass transfer of carbon into the blade meristem ranged from 36.2 to 60.8 mg C.wk^?1.0.1 mm^?2 sieve filaments.     

Comparative investigations on the distribution of sucrose synthase activity and invertase activity within growing, mature and old leaves of some C3 and C4 plant species

Sucrose synthase (EC 2.4.1.13) activity in young growing leaves was highest in the leaf base in eggplants ( Solanum melongena L.), cassava ( Manihot esculenta Crantz), grapevine ( Vitis vinifera L.), and in the leaf sheath of sugar cane ( Saccharum of ficinarum L.) and maize ( Zea mays L.). In addition, increasing sucrose synthase activity was measured towards the edge of growing eggplant leaves while the activity in mature leaves was highest in the midrib. The activity of acid and alkaline invertase was very low in the midrib but higher in the blade of fully expanded eggplant leaves. Highest invertase activities were found in younger growing leaves. It was concluded that in growing leaves a close relationship might exist between the activity of sucrose synthase and the import of sucrose from source leaves.
Detachment of mature eggplant leaves led to a 2- to 3-fold increase of sucrose synthase activity in blade and midrib of these leaves. In contrast, invertase activity decreased after detachment in both leaf blade and midrib. It was concluded that the rise in sucrose synthase activity might have been caused by the observed increase of sucrose concentration in detached leaves and that sucrose synthase might have an important role in the regulation of sucrose content of the conducting tissue.     

海带喇叭丝对接的新类型

在对海带髓部组织进行显微观察时,发现了两种海带喇叭丝对接的新类型,即三细胞对接型和四细胞对接型。这两种类型的数量较少,只存在于带片与带柄的交接处,其功能可能与提高物质转运效率和横向运输有关。     

PHYSIOLOGICAL INVESTIGATIONS ON ALARIA ESCULENTA (LAMINARIALES,PHAEOPHYCEAE). III. EXUDATION BY THE BLADE1,2,3

Comparison of exudation rate of medullary conducting cells in the midrib of Alaria esculenta (L.) Grev. showed lowest rates for the blade meristem and highest rates in the non-growing region, 300–500 mm from the meristem. Holding plants under continuous darkness or severing the wings from the midrib reduced exudation rate by 26 and 37%, respectively. Osmotic pressure of exudate in sink (meristem) and source (non-growing region, up to 500 mm from the meristem) were similar (34.6–36.1 · 10²kpa). Pressure flow mechanism of translocation is evaluated in Alaria.     

Source-sink relations in maize mutants with starch-deficient endosperms

Partitioning and translocation of photosynthates were compared between a nonmutant genotype (Oh 43) of corn (Zea mays L.) and two starch-deficient endosperm mutants, shruken-2 (sh2) and brittle-1 (bt1), with similar genetic backgrounds. Steady-state levels of ¹⁴CO₂ were supplied to source leaf blades for 2-hour periods, followed by separation and identification of ¹⁴C-assimilates in the leaf, kernel, and along the translocation path. An average of 14.1% of the total ¹⁴C assimilated was translocated to normal kernels, versus 0.9% in sh2 kernels and 2.6% in btl kernels. Over 98% of the kernel ¹⁴C was in free sugars, and further analysis of nonmutant kernels showed 46% of this label in glucose and fructose. Source leaves of mutant plants exported significantly less total photosynthate (24.0% and 36.3% in sh2 and bt1 compared to 48.0% in the normal plants) and accumulated greater portions of label in the insoluble (starch) fraction. Mutant plants also showed lower percentages of photosynthate in the leaf blade and sheath below the exposed blade area. The starch-deficient endosperm mutants influence the partitioning and translocation of photosynthates and provide a valuable tool for the study of source-sink relations.     

Pathway and sink activity for photosynthate translocation in <Emphasis Type="Italic">Pisolithus</Emphasis> extraradical mycelium of ectomycorrhizal <Emphasis Type="Italic">Pinus thunbergii</Emphasis> seedlings

The purpose of this study was to identify the pathway and sink activity of photosynthate translocation in the extraradical mycelium (ERM) of a Pisolithus isolate. We labelled ectomycorrhizal (ECM) Pinus thunbergii seedlings with ¹⁴CO₂ and followed ¹⁴C distribution within the ERM by autoradiography. ¹⁴C photosynthate translocation in the ERM resulted in ¹⁴C distribution in rhizomorphs throughout the ERM, with ¹⁴C accumulation at the front. When most radial mycelial connections between ECM root tips and the ERM front were cut, the whole allocation of ¹⁴C photosynthates to the ERM was reduced. However, the overall pattern of ¹⁴C distribution in the ERM was maintained even in regions immediately above and below the cut, with no local ¹⁴C depletion or accumulation. We inferred from this result that every portion in the ERM has a significant sink activity and a definite sink capacity for photosynthates and that photosynthates detour the cut and reach throughout the ERM by translocation in every direction. Next, we prepared paired ECM seedlings, ERMs of which had been connected with each other by hyphal fusion, alongside, labelled the left seedling with ¹⁴CO₂, and shaded none, one or both of them. ¹⁴C photosynthates were acropetally and basipetally translocated from the left ERM to ECM root tips of the right seedling through rhizomorphs in the left and right ERMs, respectively. With the left seedling illuminated, ¹⁴C translocation from the left to the right ERM increased by shading the right seedling. This result suggests that reduced photosynthate transfer from the host to its ERM increased sink activity of the ERM.     

Yield Loss in Sweet Corn in Response to Defoliation or Infection by Exserohilum turcicum

Abstract Net CO₂ assimilation was reduced in sites of infection by Exserohilum turcicum in leaves of Seneca 60 sweet corn before lesions appeared. In leaf tissue adjacent to infected areas, there was an early small increase in CO₂ assimilation followed by a gradual decline to nearly 0 net CO₂ exchange by 7 days after inoculation. Translocation of photosynthates in to disease lesions from healthy tissue distal to the lesions was observed within 1 h after exposure of 1.2–cm² areas of the leaf blade to ¹⁴CO₂. No translocation from lesions to healthy leaf tissue was observed. The effects of defoliation at specific leaf positions on yield of sweet corn plants were accurately simulated by a model in which yield is expressed as a function of healthy leaf area absorption of incident insolation. Removal of leaves from the bottom third of the plants caused no yield loss, whereas removal of leaves above the ear caused significant losses. The model underes, timated the yield loss caused by infection by E. turcicum by approximately 22 %. The observed effects of infection by E. turcicum on photosynthetic efficiency in leaf tissue adjacent to lesions and on translocation of photosynthates into lesion from distal parts of the leaf show that the effect of northern leaf blight on yield is greater than can be accounted for by the direct loss of healthy leaf area through necrosis within disease lesions.