分生体的

LFY-like genes play important role in plant development, when they were first isolated from mutants of Antirrhinum and Arabidopsis, they were thought to be "SAM-specific-determinating-genes", regulating the transition from inflorescence to flower meristem. However, further research revealed that LFY-like

LFY类基因在植物形态建成过程中具有重要作用，根据其突变体的特征，曾一度被认为是在花分生组织和花序分生组织中特异表达的"分生组织特征决定基因"，控制花序分生组织向花分生组织的转变。

Quantitative RT-PCR results showed that HTF1 is involved in the conidiation pathway,Htf1 mutant is not de-repressed in conidiophore development under non-conducive conditions.The observed phenotype of enhanced conidiophore development in the htf1 mutant may result from its defect in conidium development.It is possible that some feedback signal from conidia may inhibit further conidiophore development in M.grisea.

定量RT-PCR的结果也表明HTF1参与产孢信号途径。htf1突变体在不利于产孢条件下并没有去抑制分生孢子梗的发育，因此htf1突变体产生比野生型菌株数量更多的分生孢子梗可能是由于其无法形成分生孢子的原因导致的，这也似乎预示了在稻瘟病菌中很有可能存在一些来自分生孢子的反馈信号以进一步抑制分生孢子梗的发育。

The prepared protoplasts could regenerate mycelium and produce conidium with similar pathogenecity to that of parental strains.

所制备的原生质体均能再生菌丝和具有产生与原菌株相同致病性分生孢子的能力。

The results showed that conidia were thin -walled and smooth to thick walled and verrucose; fat bodies accumulated gradually in both conidium and conidiogenous cell, and finally laid over the inner wall of conidium and disappeared in conidiogenous cell.

分生孢子发育的超微结构研究表明，分生孢子壁的发育是有个由薄而光滑到厚而有疣的过程；期间脂肪体在分生孢子和产孢细胞中不断累积，最后脂肪体沿着内壁排列成一层。

In higherplants,the development of flower is a very complex process,which involves thetransition from vegetative tissueto floral tissue,themorphogenesis of flower and the development and differentiation of gametocyte.

在高等植物中，花的发育是一个非常复杂的过程，涉及到由营养分生组织向花分生组织的转变，花的形态建成以及雌、雄配子体的发育和分化。

In order to understand the biology of apple ring spot fungi further and solve the problem of less conidiophores generated during their inducing culture in vitro, it was studied that the effect of culture medium pH, incubation temperature, light sources, and light regiment on growth of mycelia and generation of conidiophores, and the removing of mycelia on generation of conidiophores.

为进一步了解苹果轮纹病菌的生物学特性，解决其在离体培养条件下产生分生孢子很少的问题，研究了培养基pH值、培养温度、光源和光照条件对菌丝体生长和分生孢子发生的影响以及刮除菌丝体对分生孢子发生的影响。

The feasibility of the protoplast mutagenesis for increasing productivity was studied on a Claviceps paspali strain, which was not easy to produce conidia under laboratory conditions.

为了提高在一般条件下不易产生分生孢子的雀稗麦角菌的产碱率，对原生质体诱变育种的条件和方法进行了探讨。

LFY-like genes play important role in plant development, when they were first isolated from mutants of Antirrhinum and Arabidopsis, they were thought to be "SAM-specific-determinating-genes", regulating the transition from inflorescence to flower meristem. However, further research revealed that LFY-like

LFY类基因在植物形态建成过程中具有重要作用，根据其突变体的特征，曾一度被认为是在花分生组织和花序分生组织中特异表达的&分生组织特征决定基因&，控制花序分生组织向花分生组织的转变。

After the microscope through the cultivation of detection, slender hyphae, bifurcation, and short stem hyphae collateral for its health or the alternate on the branch, the branch can continue to branch, forming two, three branch , is the end of vase-shaped branching stems, spores observed liquid spherical sporangium producers body, the formation of conidia oval eggs, smooth-walled.

通过培养后显微镜观察检测，菌丝细长、分叉多，梗为菌丝的短侧枝，其上对生或互生分枝，分枝上又可继续分枝，形成2级，3级分枝，分枝末端即为瓶状梗，孢子液制片观察到球形孢子囊体，分生孢子卵形成椭圆形，壁光滑。

Using the technique of culturing shoot apex under aseptic conditions, we found that there is a sensitive stage for the sex expression of earlier flower buds, this stage is located before the second leaf full expansing.

利用黄瓜茎尖离体培养系统结合生物切片技术观察了黄瓜早期发育阶段中成花分生组织的发生及发育情况，结果表明：就黄瓜早期发育的花芽而言，可能存在着一个性别决定的敏感点，而这个敏感点位于第二片真叶展开前的某个阶段，此时的花芽绝大多数尚处在花分生组织阶段。

Blastomycetes：芽孢纲

在Ainsworth(1973)的分类系统中,半知菌亚门分3个纲: 芽孢纲(Blastomycetes):营养体是单细胞或发育程度不同的菌丝体或假菌丝,产生芽孢子繁殖. 丝孢纲(Hyphomycetes):营养体是发达的菌丝体,分生孢子不产生在分生孢盘或分生孢子器内.

corpus：原体

这个学说认为茎的顶端分生组织原始区域包括原套(tunica)和原体(corpus)两个部分,组成原套的一层或几层细胞只进行垂周分裂(径向分裂),保持表面生长的连续进行;组成原体的多层细胞进行着平周分裂(切向分裂)和各个方向的分裂,

elementary body：原(生小)体

衣原体的生长发育周期分两个阶段:原生小体(elementary body),是发育周期的感染阶段;网状小体(initial body),是在感染细胞内的繁殖阶段. 原生小体先附着于易感细胞的表面,然后通过细胞的吞噬作用进入细胞内,形成网状小体在细胞内繁殖,

oidium：粉孢属

粉孢属(Oidium) 菌丝体表生;分生孢子梗直立,顶部产生体生式的分生节孢子(粉孢子). 分生孢子串生,单胞,无色. 引起白粉病,为大多数白粉菌的无性阶段. 梨孢属(Pyricularia) 分生孢子梗无色,细长,不分枝,顶端以合轴式产生全壁芽生式分生孢子,

leaf primordium：叶原基

把任何一种植物的枝芽纵切开,用解剖镜或放大镜观察,可以看到顶端分生组织、叶原基(leaf primordium)、幼叶和腋芽原基(axillary bud primordium). 顶端的分生组织位于枝芽上端,叶原基是近顶端分生组织下面的一些突起,是叶的原始体,

deuteromycetes：半知菌

许多子囊菌尚未发现其有性阶段,而只知道其无性阶段,这类菌称为半知菌(Deuteromycetes)或不完全菌(Imperfect fungi). 半知菌大多产生发达的有隔多核的菌丝体. 菌丝体形成产生分生孢子的结构. 形成分生孢子是半知菌繁殖的主要方式,

Erysiphaceae：白粉菌科

该目中白粉菌科(Erysiphaceae)最为常见. 白粉菌科菌丝体无色、表生,产生吸器伸入表皮细胞中. 有的白粉菌不产生吸器,以它的分枝从气孔伸入叶肉组织中,它们在叶片的表面形成一薄层菌丝体. 无性生殖在分生孢子梗上产生无色、单细胞、椭圆形或长斜方形的分生孢子,

Polysiphonia：多管藻属

多管藻属(Polysiphonia)仙菜目的1属. 植物体直立或部分匍匐,匍匐枝上具1或2个细胞组成的假根,上生直立枝,自其上辐射分枝. 分枝圆柱状,无限生长. 每一节中有1中轴细胞,四周为4个或更多的围轴细胞. 分枝老的部分多具有皮层,顶端常生毛丝体.

intercalary trabant：中间随[附]体

中间分生组织 intercalary meristem | 中间随[附]体 intercalary trabant | 插在中间的 intercalated

mitochondrion：粒线体

细胞质中可观察到色素体(plastid)、粒线体(mitochondrion)、液胞(vacuole)和质液(cytosol). 分生组织的细胞,液胞较小,而成熟的细胞中央常被一个大液胞所占满,细胞质则被推挤到细胞的边缘. 后生物质如结晶体、淀粉粒及其他非结晶物质,