草地早熟禾假受精现象的研究

本文运用石蜡切片法、整体透明法研究了草地早熟禾的假受精现象。结果表明,草地早熟禾在两极核清晰可见时,卵细胞就已自发分裂成原胚,此现象占观察总数88％;但是,其极核必需经过受精过程才能发育为胚乳。     

草地早熟禾无融合生殖现象的研究

本文应用石蜡切片和子房整体染色透明法研究了草地早熟禾(Poa pratensisL.)的无融合生殖现象,结果表明,草地早熟禾的胚胎发育分为两种类型。一种是由孤雌生殖形成胚,即卵细胞分裂较早形成幼胚,少数胚囊中的一个或两个助细胞也分裂较早,同时形成幼胚,但两个极核并不融合,三个反足细胞明显增大。由孤雌生殖形成胚的约占观察总数的66%,其中3%为双胚,仅一个是三胚。在成熟种子中也有两个成熟胚并生的现象。另一种是形成胚和胚乳,约占34%。34%中形成种子有两种可能的途径,一是通过有性生殖形成种子,二是由孤雌生殖形成的胚和极核受精形成的胚乳共同组成的无融合生殖种子。本研究还首次观察到早熟禾完整的双胚囊结构。     

雾灵山草地早熟禾多胚囊和多胚的研究

无融合生殖是指未经炷卵事例而产生后代的特殊生殖方式,它可以分为单倍体无融合生殖和二倍体无融合生殖;对于作物意义更大的是二倍体无融合生殖。多胚囊和多胚现象ＳＨＩ是无融合生殖的表现形式。本文运用石蜡切片法、子房整体透明法研究了雾灵山草地早熟禾（Ｐｏａ ｐｒａｔｅｎｓｉｓ Ｌ．）多胚囊和多胚现象。结果表明,（１）草地早熟禾多胚囊来源有两种：一是自大孢子母细胞,二是来自珠心细胞;（２）草地早熟禾多 来源有     

白三叶入侵对草地早熟禾功能性状及草坪质量的影响

【目的】白三叶入侵会挤占草坪草的生存空间,严重威胁草坪的质量和功能。明晰白三叶（Trifolium repens）入侵对草坪植物草地早熟禾（Poa pratensis）功能性状及草坪质量的影响,可深入了解白三叶入侵机制,为禾本科草坪的建植养护提供理论依据。【方法】以白三叶入侵草地早熟禾草坪为研究对象,采用样地调查方法,考察不同白三叶入侵程度下（对照及轻度、中度、重度入侵）草地早熟禾功能性状及草坪质量的差异特征,并通过隶属函数法综合评价各入侵程度下草坪质量。【结果】（1）随白三叶入侵程度的增加,草地早熟禾各器官碳含量、叶片建成成本及碳氮比、碳磷比和氮磷比逐渐降低,而比叶面积、各器官氮和磷含量增大。（2）同一入侵程度下,草地早熟禾各器官碳、氮和磷含量均表现为叶大于根和茎,碳氮比和碳磷比表现为根和茎大于叶,而其氮磷比表现为茎和叶大于根。（3）随白三叶入侵程度的增加,草地早熟禾草坪密度、质地、绿度指数和均一性降低,而地上生物量和地下生物量增大。（4）隶属函数法综合评价结果显示,草坪质量以白三叶未入侵时最优,重度入侵时最差,且叶碳含量对草坪质量的影响最大。【结论】白三叶入侵改变了草地早熟禾功能性状,降低了入侵区草坪质量,严重影响了草坪景观和功能。     

山西省草地早熟禾白粉菌分离株BGP(TG)的鉴定及致病力分析

【背景】草地早熟禾(Poa pratensis)是一种被广泛使用的兼具观赏性和设施性的冷季型草坪草,白粉病的发生严重降低了草地早熟禾的质量和使用年限。【目的】对山西农业大学温室草地早熟禾白粉病病原物进行分离、纯化、鉴定和致病力分析,为草地早熟禾白粉病的防治提供理论依据。【方法】采用形态特征观察、核糖体内源转录间隔区(ribosomal DNA internally transcribed spacer, rDNA-ITS)序列分析进行分离株BGP(TG)的鉴定;通过分生孢子密集抖落接种法测定BGP(TG)对23份草地早熟禾材料的致病力。【结果】草地早熟禾白粉菌分离株BGP(TG)分生孢子串生、无色、椭圆形,长和宽分别为(23.31−34.67) µm和(11.33−15.77) µm,成熟吸器为指状;rDNA-ITS序列分子发育分析结果表明分离株BGP(TG)与禾布氏白粉菌早熟禾专化型(Blumeria graminis f. sp. poae)聚于同一分支;BGP(TG)对23份草地早熟禾的致病力测定结果显示,白粉病发病率为49.47%−77.72%,病情指数为14.41−53.12;仅‘太行’草地早熟禾对BGP(TG)表现为中抗,‘应县’ ‘黑杰克’和‘浑源’草地早熟禾表现为中感,‘探险家’和‘奖品’草地早熟禾表现为极感,其余17个品种表现为高感,占比达73.91%。【结论】山西省草地早熟禾白粉菌分离株BGP(TG)的致病力较强,进一步挖掘‘太行’草地早熟禾的抗白粉病基因,对草地早熟禾抗白粉病育种工作具有重要意义。     

普通小麦与鸭茅摩擦禾的远缘杂交：Ⅲ.受精和早期胚的发育

用石蜡制片法和整体解剖法，对小麦品种Ｆｕｋｕｈｏ经鸭茅状摩擦禾花粉粉后不同时间固定的子房样品进行了细胞胚胎学观察。结果表明，观察的１６８个授粉后１２０小时以内的小麦了房中有３２．１％、０．６％和２６．２％分别发生了卵细胞单受精、极核单受精和卵卵细胞、极核双受精现象。     

普通小麦与鸭茅状摩擦禾的远缘杂交 Ⅲ受精和早期胚胎的发育

用石蜡制片法和整体解剖法,对小麦品种Ｆｕｋｕｈｏ经鸭茅状摩擦禾花粉授粉后不同时间固定的子房样品进行了细胞胚胎学观察。结果表明,观察的１６８个授粉后１２０小时（５天）以内的小麦子房中有３２１％、０６％和２６２％分别发生了卵细胞单受精、极核单受精和卵细胞、极核双受精现象。发生卵细胞受精、极核受精和总受精频率分别为５８３％、２６８％和５８９％。对１１６个授粉后９天的小麦子房进行整体解剖,检测到有５００％的子房有幼胚。报道了小麦与鸭茅状摩擦禾杂交的受精过程和早期胚胎发育的情况。为小麦与鸭茅状摩擦禾杂交提供了高频率受精和胚形成的细胞胚胎学证据。     

白粉菌BGP(TG)在不同抗性草地早熟禾叶片上的侵染过程观察

【背景】草地早熟禾(Poa pratensis)白粉病是气传性病害,种植抗病品种是防治白粉病最经济、环保和有效的方法。【目的】明确禾布氏白粉菌BGP(TG)在3个不同抗性草地早熟禾叶片上的侵染过程和乳突在草地早熟禾抗白粉病中起的重要角色。【方法】利用考马斯亮蓝染色结合显微镜观察的方法,对不同抗性的3个草地早熟禾品种进行白粉菌侵染过程观察,统计分生孢子形成次生芽管的速度、吸器和乳突的形成情况,分析白粉菌对不同抗性草地早熟禾侵染过程的差异。【结果】‘探险家’草地早熟禾病症较其他2个品种更为严重,禾布氏白粉菌BGP(TG)侵染不同抗性品种的侵染过程基本一致,但‘探险家’叶片上初生吸器形成早于其他2个品种;接菌1-2 d后,在‘太行’叶表面分生孢子形成5级芽管的速度显著低于‘探险家’和‘黑杰克’;接种1d后,‘太行’草地早熟禾有效乳突形成率显著高于‘黑杰克’(P<0.05),‘黑杰克’有效乳突形成率显著高于‘探险家’(P<0.05)。【结论】明确了白粉菌在草地早熟禾叶片上的侵染过程和乳突在草地早熟禾抵御白粉菌侵入过程中起的重要作用,为草地早熟禾白粉病的预防和防治提供了理论基础和参考...     

问题解答

问有些双子叶植物的种子无胚乳,那么它们也有双受精现象吗?受精极核发育成什么? 答双受精现象是被子植物所特有的,受精卵发育成种子的胚,受精极核发育成种子的胚乳。双子叶植物是被子植物,当然也不例外。因此,一些种子无胚乳的双子叶植物,也具有双受精现象,受精极核也发育成胚乳,并且其发育过程与有胚乳种子的胚乳发育过程是一样的。     

雾灵山草地早熟禾多胚囊和多胚现象的研究

无融合生殖是指未经精卵融合而产生后代的特殊生殖方式,它可以分为单倍体无融合生殖和二倍体无融合生殖;对于作物改良意义更大的是二倍体无融合生殖。多胚囊和多胚现象SHI是无融合生殖的表现形式。本文运用石蜡切片法、子房整体透明法研究了雾灵山草地早熟禾〖WTBX〗（Poa pratensis〖WTBZ〗 L.）多胚囊和多胚现象。结果表明,（1）草地早熟禾多胚囊来源有两种：一是来自大孢子母细胞,二是来自珠心细胞;（2）草地早熟禾多胚来源有四个：其一是有性生殖胚,其二是孤雌生殖胚,其三是无配子生殖胚,其四是珠心胚。     

水稻中央细胞发育期间超微结构变化的观察

本文通过透射电镜对水稻受精前胚囊中央细胞发育过程中超微结构的变化进行观察。结果表明,八核胚囊形成后很快就进行细胞化形成7个细胞,其中刚形成的中央细胞由1个大液泡、2个极核（珠孔端和合点端各1个）和一些含有丰富细胞器的胞质组成。中央细胞以后的发育主要是极核的发育和极核周围胞质的变化。极核发育经历以下过程：a．2个核都膨大呈“椭圆”形。核周围胞质呈不对称分布。b．2个核分别向胚囊中央移动并相互靠近。之后2个极核调整排列方式,由纵排（即与胚囊纵轴平行）变成横排。此时期有细胞质“桥”联结珠孔端卵器、2个极核和合点端反足细胞器。c．横排的极核移向卵器,并排列于卵细胞之上。此时胚囊未明显膨大,但极核相靠近的两边核膜有许多处已形成“融合桥”,核周围的胞质也起较大的变化,如质体内淀粉消失和光面内质网增加等。极核进一步发育直至胚囊成熟期间,极核排列方式及其周围胞质组成未观察到明显的变化,但胚囊体积明显增大。     

濒危植物——长喙毛茛泽泻的受精作用及胚和胚乳的发育

长喙毛茛泽泻Ranalisma rostratum Stapf的配子融合开始较早,但精核与极核融合速度较快。精核与珠孔极核融合后即移向胚囊合点端与另一极核再融合形成初生胚乳核。初生胚乳核第一次分裂后形成两个细胞,以后珠孔端胚乳细胞再进行游离核分裂,胚乳发育属于沼生目型。开花后两天,合子分裂,八分体呈4层,每层呈两个细胞方式排列胚胎发生属于石竹型。     

The Fertilization and the Development of Embryo and Endosperm in an Endangered Plant—Ranalisma rostratum Stapf (Alismataceae)

Ranalisma rostratum Stapf is a rare and endangered species． This paper deals with the fertilization and the development of embryo and endosperm in this plant．The embryogenesis is of Caryophyllad type and the development of endosperm belongs to Heobial type．Before fertilization,the two polar nuclei are located respectively at both ends of embryo sac. In most angiosperms with two polar nuclei,the polar nuclei may fuse eiher before fertilization to form a secondary nucleus or during fertilization called triple fusion． In Ranalisma rostratum Stapf, however, it is found that only in case when the micropylar polar nucleus is fertilized,it can move to the chalazal end and fuse with the chalazal polar nucleus．This phenomenon is very rare and the process must take more time to fulfil fertilization both polar nuclei． This feature of fusion of polar nuclei is therefore thought as a primitive character from the view of phylogeny．     

Ultrastructural studies of oocytes and embryos derived from females flies carrying the grandchildless mutation in Drosophila subobscura

The maternal effect mutant grandchildless in Drosophila subobscura has been analyzed with the electron microscope. The original mutation was linked to a visible genetic marker and established in a balanced stock. Oocytes and early embryos were examined by both transmission and scanning electron microscopy. The earliest defect is seen in mutant eggs and occurs at the end of oogenesis. In the cortex, at both the anterior and the posterior tips, regions appear which are free of ribosomes, mitochondria, and other cytoplasmic organelles. Most of the polar granules are included in these regions at the posterior tip. Following oviposition, this cytoplasmic segregation is no longer observed and most polar granules have disappeared. The few remaining granules are presumed to derive from the peripheral polar plasm which does not become segregated. During embryogenesis there is a retarded movement of nuclei to the anterior and posterior cortices. At the posterior tip nuclei are delayed in reaching the lateral sides and never move directly into the posterior polar plasm. Pole cells never form. After the last syncytial division the lateral nuclei move under the posterior polar plasm to complete the blastoderm. The posterior polar plasm itself protrudes during blastoderm formation as long cytoplasmic extensions which separate from the blastoderm as cytoplasmic blebs. Neither polar granules nor mitochondria are found in these blebs. The grandchildless phenotype is due to the failure of nuclei to migrate directly into the posterior polar plasm. The defect in the polar plasm presumably is related to the process in mature eggs whereby portions of the cortex become segregated at both anterior and posterior tips. This process may change the properties of the posterior polar plasm so that nuclei do not penetrate into it.     

Early post-pollination events in hexaploid wheat × maize crosses

Summary Cytological events in the first 12 h after pollination were studied in crosses between the hexaploid wheat genotype Chinese Spring and the maize genotype Seneca 60. A pollen tube was first observed in the embryo sac 4 h after pollination, and maize sperm nuclei were first observed in the embryo sac after 5 h. On 29 occasions two, and on 1 occasion three, pollen tubes penetrated the embryo sac. Four categories of aberration limiting the frequency of fertilization were identified: (1) in 20% of florets no pollen tube reached the embryo sac; (2) in at least 1.9% the pollen tube severely damaged the wheat egg cell and polar nuclei; (3) in 33% the maize sperm nuclei were not released from the pollen tube; and (4) in 16% the sperm nuclei were released into the embryo sac but failed to move to either of the wheat gametes. In the remaining 29% sperm nuclei were more often found in the egg cell than at the polar nuclei. The results suggest that karyogamy occurs with very high efficiency when a sperm nucleus reaches the egg cell, but with only about 50% efficiency when a sperm nucleus reaches the polar nuclei.     

Cell division of binuclear cells induced by caffeine: Spindle organization and determination of division plane

Synchronously dividing binuclear cells were induced in root tips ofTriticum turgidum by caffeine treatment. Spindle and other microtubular configurations of such cells were studied using tubulin immunofluorescence and electron microscopy. The binuclear cells developed one, two or three preprophase microtubule bands longitudinally, transversely or rarely in a cross configuration. During the mitotic entry binuclear cells formed prophase spindles separately around each nucleus. When the nuclei were located fairly apart, their spindle structures developed independently throughout all mitotic phases. But when the nuclei were located closely together their metaphase and anaphase spindles shared a common polar region. However, the two spindles in such cells retained their functional autonomy. They display structurally independent minipoles in the common polar region. After anaphase the neighbouring nonsister chromosome groups of nuclei divided by a common polar region come to lie close together and in telophase, become enclosed by a common nuclear envelope. During cytokinesis of binuclear cells cell plates were formed only between sister nuclei. These cell plates may develop normally or may curve or branch giving rise to aberrant daughter cell walls. The peculiar mode of spindle and spindle polar region organization of binuclear cells and determination of the division plane in them are discussed.     

Fertilization of Barley (Hordeutn distichutn L.)

Fertilization of barley has been studied and photographically recorded. The pollen grain germinates almost immediately after attaching itself to the stigma, pollen tube reaches the embryo sac after 20–30 minutes (temperature 26°C). One of the sperms permeates immediately to the oosphere, the other joins polar nuclei migrating from the oosphere to antipodal cells after the discharge of pollen tube content. Fertilization of the polar nucleus occurs in most cases at the antipodal cells which have pronounced haustorial character. In triple fusion polar nuclei do not usually fuse prior to fertilization. However, some exceptions were noted: sometimes the fertilization takes place after the fusion of polar nuclei or during the fusion. Being slower, pre-mitotic fertilization of the egg cell could be studied in greater detail.     

Ovule,Female and Male Gametophyte and Fertilization of Kingdonia uniflora Balfour F. et W. W. Smith

The structure of ovule, female and male gametophyte, double fertilization and the distrubution of starch grains during the fertilization have been studied. The main results are as follows: ( 1 ) Ovule The ovule is anatropous, unitegmic and tenuinucellate. The nucetlus appears cylindric, since megaspores and embryo sac development, its internal cells of nucellus become disorganized, so that only a single layer of epidermal cells remains toward the side of the micropyle, On the other hand, the integument is not as long as nucellus, as a result micropyle is not formed. And no vascular bundle is found in the integument. (2) Female gametophyte The mature embryo sac is slender and is composed of an egg cell, two synergids, a central cell and three antipodal cells. The egg cell is situated slightly away from the tip of embryo sac. Some of them contain starch grains. Synergids occupy the tip of embryo sac. Its wall at micropylar region appears irregular in thickenes and irregular in ingrowths to form the filiform apparatus. The centrateell is very large, and strongly vacuolated Two polar nuclei come to contact closely with each other, but not fuse, or to fuse into a large secondary nucleus before fertilization. The polar nuclei or the secondary nucleus are usually situated at the middle-lower position of the central cell or nearer to the chalazal end above the antipodal cell. It is different from egg cell, no starch grains are found here. In most embryo sacs three antipodal cells are found. They are not as large as those in other plants of Ranunculaceae. But six antipodal cells or the antipodal cell with two nuclei may rarely be found. Like synergid, the wall of them appears not only irregularly thickened, but clearly with irregular ingrowths. In a few antipodal cells the starch garins are usually found near the nucleus. By the end of fertilization, antipodal cells become disintegrated. (3) Male gametophyte Most pollen grains are two-celled when shedding, and rich in starch grains. A few of them contain single nucleus or three-celled. (4) The double fertilization The fertilization of Kingdonia unifiora Balfour f. et W, W. Smith is wholly similar to some plants of Ranunculaceae studied. First, the pollen tube penetrates a degenerating synergid. And the pollen tube discharges its contents with two sperm nuclei into the degenerating synergid cell. One of the two sperms fuses with the nucleus of the egg, and the other fuses with two polar nuclei or the secondary nucleus of the central cell. If one sperm nucleus at first fuses with one of the polar nuclei, and then the fertilized polar nuclei again fuses with other polar nucleus. Secondly, the fertilization of the polar nuclei or the secondary nuclei completes earlier than that of the egg. The primary endosperm nucleus begins to divide earlier than the zygote. It seems that one of the sperm nuclei come to contact with egg nucleus, the other has already fused with polar nuclei or the secondary nucleus. The zygote with a single nucleolus appears until the endosperm with 16–20 cell. Thirdly, before and after fertilization there are one to some small nucleoli in egg nucleus and polar nuclei or secondary nucleus. However they increase in quantity from the beginning of the fusion of male nucleis. These nucleoli quite differ from male nucleoli by their small size, and most of them disappear at the end of fertilization. It may be concluded that the small nucleoli increase in quantity is related to the fusion of male and female nuclei. In the duration of fertilization, in ovule starch distribution is in the basal region of integument. But in embryo sac, onlysome egg cells, or zygotes contain starch grains, a part of which was brought in by pollen tube. Sometimes the starch grains are found in some synergids and antipodal cells. No starch grains are found in the central cell.     

Pollen tube penetration and fertilization in Lilium longiflorum (Liliaceae)

The ultrastructure of the embryo sac, nucellus, and parts of the micropyle of Lilium longiflorum were studied both before and after pollen tube penetration to examine the interactions between ovule and pollen tube, using transmission electron microscopy and light microscopy. Before pollen tube penetration the egg cell and two synergids are similar. No filiform apparatus was detected and no synergid degeneration occurs prior to pollen tube penetration. The polar nuclei do not fuse until fertilization. No differences in embryo sac ultrastructure were detected between pollinated ovules unpenetrated by pollen tubes and unpollinated flowers of a comparable age. Shortly after the discharge of the pollen tube two enucleated cytoplasmic bodies with different ribosome densities were observed in the degenerated cytoplasm. These structures border both on the central cell and the egg cell as well as each other and are interpreted as remains of sperm cytoplasm after transmission of sperm nuclei. In the central cell both the sperm nucleus and the polar nuclei are associated with endoplasmic reticulum (ER). ER is thought to be a transport mechanism to achieve contact between the haploid polar nuclei and the sperm nucleus. In the egg cell sperm nucleus alignment is not visibly achieved by ER. The persistent cells of the egg apparatus and the central cell appear to become more metabolically active after pollen tube penetration. Pollen tube penetration already occurs despite the absence of a filiform apparatus and a low level of differences between the cells of the egg apparatus.