渗透胁迫引起玉米根冠处胞间连丝的ATP酶活性下降

利用光镜和电镜研究了短期渗透胁迫下玉米(Zea mays L.)根冠区超微结构和ATP酶活性变化。经历了质壁分离后,在根冠细胞仍然可以观察到许多从“撤退”的周质出发向细胞壁辐射的纤丝。利用ATP酶活性产物(磷酸铅)在原生质膜和细胞壁处沉积的特点,发现这些纤丝是质膜围绕原生质而形成的管状结构;在质壁分离过程中,这些纤丝依然与胞间连丝相连。与对照(未胁迫)相比,受渗透胁迫细胞胞间连丝处ATP酶活性明显下降。能量代谢在局部区段的抑制会影响胞间连丝的生理活性,可能包括胞间连丝的扩散调节能力和分子扩散上限的改变。     

Behaviour of plasma membrane, cortical ER and plasmodesmata during plasmolysis of onion epidermal cells

During plasmolysis of onion epidermal cells, the contracting protoplast remains connected to the cell wall by an intricate, branched system of plasma membrane (PM) ‘Hechtian strands’ which stain strongly with the fluorescent probe DiOC₆. In addition, extensive regions of the cortical endoplasmic reticulum (ER) network remain anchored to the cell wall during plasmolysis and do not become incorporated into the contracting protoplast with the other cell organelles. These ER profiles become tightly encased by the PM as the latter contracts towards the centre of the cell. Thus, although the cortical ER is left outside the main protoplast body, it is nonetheless still bound by the PM of the cell. As well as being anchored to the wall, the cortical ER remains intimately linked with plasmodesmata and retains continuity between cells via the central desmotubules which become distended during plasmolysis. The PM also remains in close contact with the plasmodesmatal pore following plasmolysis. It is suggested that plasmodesmata, although sealed, may not be broken during plasmolysis, their substructure being preserved by continuity of both ER and PM through the plasmodesmatal pore. A structural model is presented which links the behaviour of PM, ER and plasmodesmata during plasmolysis.     

Permeability and Ultrastructure of Bundle Sheath Cells Isolated from C4 Plants: Structure-Function Studies and the Role of Plasmodesmata

Bundle sheath cells from leaves of C₄ plants can be isolated as strands surrounding vascular tissue. In this form these cells are highly permeable to metabolites and, as a consequence, they have a variety of experimental uses. The present paper reports on anatomical and ultrastructural features of isolated bundle sheath cell strands in relation to their integrity and permeability. This analysis shows that the cells retain a high degree of structural integrity during isolation. The plasmodesmata that originally connected the bundle sheath cytosol with mesophyll cells are apparently also retained in their entirety. However, at the external surface (mesophyll side) a membranous sac was commonly observed protruding from the end of plasmodesmata. The functional integrity of cells and the molecular weight exclusion limit for entry of compounds was assessed by following plasmolysis and cytorrhysis induced by polyethylene glycol solutions of varying molecular weights. Other evidence for the retention of cell compartment semipermeability is also provided.     

Ultrastructural Localization of ATPase Activity in the Cells of the Apical Meristem Zone,Elongation Zone and Root Hair Zone of Tomato Roots

A comparative study on the cytochemical localization of adenosine triphosphatase (ATPase) activity reaction in the cells of the apical meristem zone, elongation zone and root hair zone of tomato roots was carried out by electron microscopic observations of lead phosphate precipitation. The following experimental results have been obtained: In the meristematic cells of tomato roots, the heavy lead phosphate deposits indicating a very high activity of ATPase were localized at plasmalemma, plasmodesmata, endoplasmic reticulum, Golgi bodies, nucleoli and chromatin (Figs. 1—2). The reaction products of ATPase activity were also observed at some sites of ground cytoplasm and cell wall, but they were not found in little vacuoles and on tonoplast. In the cells of elongation zone, the ATPase activity at plasmalemma and plasmodesmata was as high as that in the meristematic cells of root tip, while the ATPase activity at nucleoli, chromatin, endoplasmic reticulum and Golgi bodies was markedly lowered. On the other hand, the high ATPase activity was produced on the tonoplast of the developing and enlarging vacuoles (Fig. 3). In the cells of root hair zone, the high ATPase activity was shown at plasmalemma, tonoplast and intercellular spaces, but the ATPase activity at nucleoli, chromatin and endoplasmic reticulum was wholly inactivated. (Figs. 4—7). The above results indicate that the ATPase activity with membranes and organelles is altered when the functions of cells and organelles change. Therefore, it is evident that the ATPase activity may be closely related to many physiological functions.     

ATPase in mature and differentiating phloem and xylem

A cytochemical study using a lead precipitation technique has been made of the distribution of adenosine triphosphatase (ATPase) in mature and differentiating phloem and xylem cells of Nicotiana tabacum and Pisum sativum. The sites of ATPase localization in tobacco phloem were the plasma membrane, endoplasmic reticulum, mitochondria, dictyosomes, plasmodesmata, and the dispersed P proteins of mature sieve elements. In pea phloem sieve elements ATPase was localized in the endoplasmic reticulum, but was not associated with the P proteins or plasma membranes at any stage of their differentiation. In pea transfer cells ATPase activity was associated with the endoplasmic reticulum at all stages of their differentiation and with the plasma membrane of transfer cells that had formed wall ingrowths. In xylem cells of both tobacco and pea the patterns of ATPase activity was similar. At early stages of differentiation ATPase activity was associated with the plasma membrane and the endoplasmic reticulum. At intermediate stages of differentiation ATPase activity continued to be associated with the endoplasmic reticulum, but was no longer associated with the plasma membrane. At later stages of xylem element differentiation ATPase activity was associated with disintegrating organelles and with the hydrolyzing cell walls.     

Cytochemical Localization of Adenosine Triphosphataes Activity During Cytomixis in Pollen Mother Cells of David Lily and Its Relation to the Intercellular Migrating Chromatin Substance

Standard lead precipitation procedures have been used to examine the localization of ATPase activity during cytomixis in pollen mother cells of Lilium davidii var. willmottiae (Wilson) Roffill. Before cytomixis, cells at this stage of development show ATPase activity on plasma membrane, in the endoplasmic reticulum, dictyosomes, plastids, plasmodesmata, and in part of the groundplasm; however, there is no ATPase activity on the chromatin and nucleolus. During cytomixis, the chromatin substance begin to transfer from one cell to an adjacent cell, reaction product indicating ATPase activity is observed associated with the chromatin and nucleolus. ATPase activity is also found with the cistenae of both endoplasmic reticulum and dictyosomes, and some plastids. There is no deposition of ATPase reaction product associated with the plasm membrane and intercellular spaces. After cytomixis, the chromatin is little or no deposition of enzyme reaction product. ATPase activity, however, is consistenlly found within the intercellular space and on the plasm membrane, and also occur in the endoplasmic reticulum, dictyosome and plastid. The presence or absence of ATPase activity in the cell structure of pollen mother cells before, during or after eytomixis is discussed in relation to the active uptake or export of water for short-distance transport. It is also suggested that the intensive ATPase activity in the nucleus during cytomixis of pollen mother cells is evidence for a transport system involved in the active movement of the intercellular migrating ebromatin substance.     

甘蔗叶不同部位ATP酶活性细胞化学定位

甘蔗叶片,叶鞘和肥厚带韧皮部 ATP 酶活性定位于筛管、伴胞的质膜、内质网和某些伴胞细胞基质、小囊泡和发育成熟的液泡上;叶片韧皮部薄壁细胞、厚壁细胞和厚壁通道细胞质膜及小囊泡中亦显示有 ATP 水解产物;维管束鞘细咆与厚壁细胞或厚壁通道细胞所构成的细胞间隙上也存在有 ATP 酶活性反应产物沉淀。甘蔗叶片大、中、小三种维管束,从小维管束到大维管束,面向细胞间隙的细胞表面上的 ATP 酶活性逐渐增强,而维管束鞘细胞质膜上的 ATP 酶活性则趋于减弱;同一维管束内则以韧皮部细胞的 ATP 酶活性最强。维管束鞘细胞与叶肉细胞之间存在很多的胞间连丝,并表现出高的 ATP 酶活性。讨论了 ATP 酶活性的分布状态与叶肉细胞的光合产物向韧皮部运输的关系。     

PLASMOLYSIS,HECHTIAN STRAND FORMATION,AND LOCALIZED MEMBRANE‐WALL ADHESIONS IN THE DESMID,CLOSTERIUM ACEROSUM (CHLOROPHYTA)1

Closterium acerosum Ehrenberg (Chlorophyta) produced a distinct network of thin cytoplasmic strands, or Hechtian strands, upon controlled plasmolysis in a sucrose solution. The strands persisted for 30 min or longer and could be visualized with both LM and EM. Near the plasma membrane of the polar zones of plasmolyzing protoplasts, the strands formed a “lattice”‐like arrangement with interstrand spacing of 120–130 nm. The strands terminated at the fibrous zone of the inner cell wall stratum. Although actin cables could be found attached to the plasma membrane upon rhodamine phalloidin labeling of membrane ghosts, neither microfilaments nor microtubules were found in Hechtian strands at any stage of development. The formation of strands was not disrupted by centrifugation at 8000 g or by repeated cycles of plasmolysis‐deplasmolysis. Application of microtubule‐ or microfilament‐affecting agents or various proteolytic/polysaccharide‐degrading enzymes did not disrupt the formation of strands. Cold treatment of cells resulted in the formation of Hechtian strands.     

Wall-to-membrane linkers in onion epidermis: some hypotheses

Wall-to-wall linkage may help maintain cell integrity and polarity, and focus mechanical stress from wall to mech-anotransductive ion channels within the plasm a lemma. When cells of onion bulb scale epidermis shrink during plasmolysis with CaCl₂, the plasmalemma remains attached to the cell wall by Hechtian strands which we hypothesize might possibly be drawn out from linkages fulfilling the above functions. We show that at least many of the attachment loci are independent of the plasmodesmata. A priori, wall glycoproteins seem good candidates for the wall-to-membrane linkers; therefore, we investigated the distribution in wall and plasmalemma of antigen recognized by antibody to hydroxyproline-rich glycoprotein (HRGP). Using fluorescent secondary antibodies, we showed that polyclonal antibodies prepared against wall HRGP from soybean bind to the onion walls (following mild depectination), but also bind to the plasmalemma after the wall is enzymatically digested. The distribution of the antibodies is punctate. On the plasmalemma, the points tend to be scattered more or less uniformly, but can cluster at termini of large streaming strands (which rarely form in wall-constrained cells.) These streaming strands can be seen to exert tension on the membrane. We hypothesize that (1) the antigen on the surface of the protoplast may correspond to the antigen in the walls, (2) such antigen may be responsible for adhesion of membrane to wall at the linkage sites visualized by CaCl₂ plasmolysis, and (3) the linkage sites may be transmembrane proteins to which cytoskeleton can attach at the inner surface.     

百合花粉母细胞间细胞融合期间腺苷三磷酸酶活性的细胞化学定位及其与染色质胞间转移的关系

用标准的磷酸铅沉淀的细胞化学方法,对百合花粉母细胞间染色质穿壁运动期间及其前后三个时期中的腺苷三磷酸酶(ATP 酶)活性进行了超微结构的定位。结果表明:(1)在穿壁前,ATP 酶活性主要定位于质膜、胞间连丝及细胞间隙;在内质网、高尔基体、质体和某些局部的基质(groundplasm)中,也表现有 ATP 酶活性反应的产物;但在染色质和核仁中,一般都没有这种反应。(2)在穿壁时,染色质从一个细胞穿壁转移到另一个相邻细胞,同时看到染色质和核仁内出现密集的 ATP 酶活性反应产物;在内质网和高尔基体的腔内以及质体的片层上也产生明显的 ATP 酶活性反应;而在质膜、胞间连丝及细胞间隙内 ATP 酶活性明显降低,甚至看不到明显的活性反应。(3)在穿壁后,质膜及细胞间隙中又产生明显的 ATP 酶活性反应产物,但核内染色质上的 ATP 酶活性则显著降低,而核仁内则仍有较高的活性。同前二个时期一样,内质网、高尔基体和质体上的 ATP 酶仍表现明显的活性反应。最后讨论了三个不同发育时期 ATP 酶活性及其分布部位的改变与染色质胞间转移的关系。     

灵武长枣果实ATPase超微细胞化学定位和功能研究

采用ATPase超微细胞化学定位技术,研究灵武长枣果实不同发育阶段韧皮部和果肉库薄壁细胞ATPase分布特征,以明确灵武长枣果实ATPase超微细胞化学定位特征和功能。结果显示:(1)第一次快速生长期SE/CC复合体与周围的薄壁细胞有丰富的胞间连丝,形成共质体连续,韧皮部薄壁细胞之间有丰富的胞间连丝,ATPase反应物在韧皮部各细胞分布较少。(2)缓慢生长期ATPase反应物在韧皮部各细胞分布逐渐增加。(3)第二次快速生长期SE/CC复合体与周围的薄壁细胞缺乏胞间连丝,形成共质体隔离,韧皮薄壁细胞及果肉库薄壁细胞的胞间连丝较少,囊泡和膜泡在筛管、韧皮薄壁细胞和库薄壁细胞中很丰富,质膜、液泡膜、囊泡膜、细胞壁和胞间隙的ATPase活性较高。研究表明,果实在第一次快速生长期同化物从筛分子的卸出主要采取共质体途径,缓慢生长期同化物卸出时可能为共质体和质外体途径共存,第二次快速生长期则主要以质外体途径为主,证明果实不同发育阶段韧皮部同化物卸出路径存在差异。     

Plasmodesmal widening accompanies the short-term increase in symplasmic phloem unloading in pea root tips under osmotic stress

Summary Root tips ofPisum sativum seedlings were exposed to 350 mM mannitol, which was shown to effect a transient but dramatic increase in phloem unloading, and investigated by electron microscopy. After chemical fixation and embedding, extremely thin sections of the root extension zone were examined. Outer, inner, and desmotubule diameters of 830 primary plasmodesmata in transverse walls of cortical cells were measured. Statistical analysis indicated that the majority of plasmodesmata had no neck constriction during osmoregulation. Compared to controls, a highly significant increase in mean plasmodesmata diameter was found, but the desmotubule diameter remained unchanged. Both loss of neck constriction and widening of the cytoplasmic sleeve indicate an increase in effective passage area of plasmodesmata. Spokes between plasma membrane and desmotubule were preserved. Continued exposure of the root tips to mannitol led to a return to control values for plasmodesmal diameters. In contrast to these responses, plasmolysis of cortical cells by 1,000 mM sucrose, diminishing phloem unloading, was accompanied by a reduction in those plasmodesmata classified as open. This is the first report showing a correlation between the ultrastructure of plasmodesmata and the rate of symplasmic transport. The role of the different plasmodesmal components in controlling the passage area of symplasmic transport is discussed.     

Structure and development of cell connections in the phloem ofMetasequoia glyptostroboides needles I. Ultrastructural aspects of modified primary plasmodesmata in Strasburger cells

Summary Symplasmic contacts of Strasburger cells in the mature needle ofMetasequoia glyptostroboides were analysed with special regard to changes of plasmodesmata in fine structure and distribution. In meristematic cells simple primary plasmodesmata are evenly distributed throughout the entire wall, whereas in mature Strasburger cells plasmodesmata are aggregated in defined, dome-shaped wall thickenings. The elongated, often multiple-branched cytoplasmic strands show a distinct neck region besides a considerably dilated sleeve region confluent with cavities, which have formed at branching sites of plasmodesmata in various planes of the wall thickening. Most branches radiating from these cavities connect the protoplasts of the adjacent cells; occasionally some strands are discontinuous. The desmotubules of both, continuous and discontinuous plasmodesmal branches exhibit great variability in structure and number: they may be partially dilated, multiple-stranded and branched within single plasmodesmal branches. Fine structurally, plasmodesmata of Strasburger cells show great resemblance with developing sieve pores of conifers. This characteristic fine structure implicates a special role of the endomembrane system for phloem loading in theMetasequoia leaf.Dedicated to Prof. Dr. Dr. h.c. Eberhard Schnepf on the occasion of his retirement     

High affinity RGD-binding sites at the plasma membrane of Arabidopsis thaliana links the cell wall

The heptapeptide Tyr-Gly- Arg-Gly-Asp- Ser-Pro containing the sequence Arg-Gly-Asp (RGD – the essential structure recognised by animal cells in substrate adhesion molecules) was tested on epidermal cells of onion and cultured cells of Arabidopsis upon plasmolysis. Dramatic changes were observed on both types of cells following treatment: on onion cells, Hechtian strands linking the cell wall to the membrane were lost, while Arabidopsis cells changed from concave to convex plasmolysis. A control heptapeptide Tyr-Gly-Asp-Gly-Arg-Ser-Pro had no effect on the shape of plasmolysed cells. Protoplasts isolated from Arabidopsis cells agglutinate in the presence of ProNectinF, a genetically engineered protein of 72 kDa containing 13 RGD sequences: several protoplasts may adhere to a single molecule of ProNectinF. The addition of the RGD-heptapeptide disrupted the adhesion between the protoplasts. Purified plasma membrane from Arabidopsis cells exhibits specific binding sites for the iodinated RGD-heptapeptide. The binding is saturable, reversible, and two types of high affinity sites (K_d1 1 nM, and K_d2 40 nM) can be discerned. Competitive inhibition by several structurally related peptides and proteins noted the specific requirement for the RGD sequence. Thus, the RGD-binding activity of Arabidopsis fulfils the adhesion features of integrins, i.e. peptide specificity, subcellular location, and involvement in plasma membrane-cell wall attachments.     

Ultracytochemical Localization of ATPase Activity in the Degenerating Nucellar Cells of Wheat During Degeneration

Ultracytochemical localization of ATPase activity was carried out using a lead phosphate precipitation technique in the nucellar cells of wheat during degeneration. ATPase was only localized on the plasma membranes of nueellar cells at the. early degenerative stage, then decreased and disappeared at the mid-degenerative stage. Meantime it was also observed in the nuclear chromatin and some cytoplasmic organelles. ATPase activity was only observed in the nuclear chromatin in the extremely degenerated nucellar cells. Two patterns of unclear degeneration was found in the degenerated nucellar cells. A lot of small fragments with ATPase from the degenerated nuclei moved toward the embryo sac. It is suggested that the change of ATPase activity on the plasma membranes is related to the physiological change of nucellar cells, and that in the nuclear chromatin is associated with the stages movement of chromatin during the process of nucellar cells degeneration.     

Conformational change and localization of calpactin I complex involved in exocytosis as revealed by quick-freeze, deep-etch electron microscopy and immunocytochemistry

Calpactin I complex, a calcium-dependent phospholipid-binding protein, promotes aggregation of chromaffin vesicles at physiological micromolar calcium ion levels. Calpactin I complex was found to be a globular molecule with a diameter of 10.7 +/- 1.7 (SD) nm on mica. When liposomes were aggregated by calpactin, quick-freeze, deep-etching revealed fine thin strands (6.5 +/- 1.9 [SD] nm long) cross-linking opposing membranes in addition to the globules on the surface of liposomes. Similar fine strands were also observed between aggregated chromaffin vesicles when they were mixed with calpactin in the presence of Ca2+ ion. In cultured chromaffin cells, similar cross-linking short strands (6-10 nm) were found between chromaffin vesicles and the plasma membrane after stimulation with acetylcholine. Plasma membranes also revealed numerous globular structures approximately 10 nm in diameter on their cytoplasmic surface. Immunoelectron microscopy on frozen ultrathin sections showed that calpactin I was closely associated with the inner face of the plasma membranes and was especially conspicuous between plasma membranes and adjacent vesicles in chromaffin cells. These in vivo and in vitro data strongly suggest that calpactin I complex changes its conformation to cross-link vesicles and the plasma membrane after stimulation of cultured chromaffin cells.     

Response of Tonoplast and Plasma Membrane ATPases in Chilling-Sensitive and -Insensitive Rice (Oryza sativa L.) Culture Cells to Low Temperature

Tonoplast and plasma membrane vesicles were prepared from chilling-sensitive(CS) and chilling-insensitive (CI) cultured cells of rice (Oryzasativa L.) to examine how they would respond to low temperature.With CS cells, the specific activity of ATPase in tonoplastvesicles was relatively higher than that of plasma membraneATPase. Tonoplast ATPase activity was decreased by low temperaturetreatment, and a slight decrease in plasma membrane ATPase activitywas also observed. The decrease in the specific activity ofthe tonoplast ATPase by low temperature may reflect a decreasein V_max. However, no change was noted in K_m. The break pointof the Arrhenius plots of the tonoplast ATPase was ca. 32?C,this value being ca. 9?C higher than that of the plasma membraneATPase. With CI cells, the specific activity of tonoplast ATPasewas somewhat less than that of the plasma membrane ATPase. TonoplastATPase activity was decreased by low temperature at 5?C, whereasan increase in plasma membrane ATPase activity was observed.The break point of the tonoplast ATPase activity was ca. 22?C,which was 3?C higher than that of the plasma membrane ATPase.Using ATPase solubilized from the plasma membrane or tonoplast,the Arrhenius plots of log ATPase activity against the reciprocalof absolute temperature gave a straight line fit from 5?C to45?C with no obvious break point. The break point appeared onadding a phospholipid mixture (asolectin) to a reaction mixturecontaining solubilized enzyme. The slope of the curve of theArrhenius plot was very different between the CS and CI cells.The plasma membrane and tonoplast ATPases from the CS cellshad a higher E_a above 20?C, whereas that from the CI cells hada lower one. These findings indicate that the tonoplast ATPase in a riceplant is more sensitive to low temperature than the plasma membraneATPase, with this response possibly being due to interactionsbetween the proteins and phospholipids. (Received January 6, 1988; Accepted July 5, 1988)     

Membrane–wall attachments in plasmolysed plant cells

Summary. Field emission scanning electron microscopy of plasmolysed Tradescantia virginiana leaf epidermal cells gave novel insights into the three-dimensional architecture of Hechtian strands, Hechtian reticulum, and the inner surface of the cell wall without the need for extraction. At high magnification, we observed fibres that pin the plasma membrane to the cell wall after plasmolysis. Treatment with cellulase caused these connecting fibres to be lost and the pinned out plasma membrane of the Hechtian reticulum to disintegrate into vesicles with diameters of 100–250nm. This suggests that the fibres may be cellulose. After 4h of plasmolysis, a fibrous meshwork that labelled with anti-callose antibodies was observed within the space between the plasmolysed protoplast and the cell wall by field emission scanning electron microscopy. Interestingly, macerase-pectinase treatment resulted in the loss of this meshwork, suggesting that it was stabilised by pectins. We suggest that cellulose microfibrils extending from strands of the Hechtian reticulum and entwining into the cell wall matrix act as anchors for the plasma membrane as it moves away from the wall during plasmolysis.Correspondence and reprints: Institute of Ecology and Conservation Biology, University of Vienna, Althanstrasse 14, 1090 Vienna, Austria.     

小麦珠心细胞衰退过程中ATP酶的超微细胞化学定位

采用磷酸铅沉淀技术对小麦（Ｔｒｉｔｉｃｕｍ ａｅｓｔｉｖｕｍ ）珠心细胞衰退过程进行了ＡＴＰ酶的超微细胞化学定位。初始衰退的珠心细胞,ＡＴＰ酶只定位于细胞膜上,其它部位未见有ＡＴＰ酶活性。衰退中期的珠心细胞,细胞膜上ＡＴＰ酶活性减弱并逐渐消失;细胞核染色质和细胞质中一些细胞器上存在ＡＴＰ酶活性。在严重衰退的珠心细胞中,只在细胞核染色质上存在ＡＴＰ酶活性。珠心细胞的细胞核以两种方式衰退。衰退的细胞核染色质碎片仍存在ＡＴＰ酶活性,并向胚囊方向转移。推测小麦珠心细胞衰退过程中细胞膜上ＡＴＰ酶变化反映了珠心细胞生理状态转变;细胞核染色质上ＡＴＰ酶与其形态变化和运动等有关     

植物体细胞胚发生中ATP酶活性时空分布动态与内源激素的变化

本文以我们的研究结果为基础,并结合国内外近几年有关研究报道,对植物体细胞胚发生中的超微结构和ATP酶活性时空分布动态及内源激素的变化和作用进行专题评述。⑴ 超微结构的变化：当植物体细胞一旦转化为胚性细胞后,各种细胞器相继增加,不仅丰富而且活跃,特别是线粒体内嵴发达,有的正处于分裂状态;核糖体聚集成多聚核糖体;质体中含大量淀粉粒,接着出现高尔基体等。早期胚性细胞与周围细胞还存在胞间连丝,随着胚性细胞壁的加厚,胞间连丝也随之消失。⑵ ATP酶时空分布动态：早期的胚性细胞中ATP酶反应产物主要沉积于质膜和液泡膜上,后期ATP酶活性转入细胞内,液泡和细胞核中,而且在胚性细胞壁加厚处有活跃的ATP酶活性反应,并证明ATP酶活性是在胚性细胞发生过程中形成的。⑶ 内源激素的变化与作用：在体细胞胚诱导过程中内源激素起着关键性作用,内源生长素含量的提高为胚性细胞的诱导奠定了基础,细胞分裂素含量的增加可促进胚性细胞的分裂和增殖,ABA不仅提高了体细胞胚的诱导频率,而且促进了体细胞胚的正常发育。