Multiplicity of aspartic proteinases from Cynara cardunculus L.

Aspartic proteinases (AP) play major roles in physiologic and pathologic scenarios in a wide range of organisms from vertebrates to plants or viruses. The present work deals with the purification and characterisation of four new APs from the cardoon Cynara cardunculus L., bringing the number of APs that have been isolated, purified and biochemically characterised from this organism to nine. This is, to our knowledge, one of the highest number of APs purified from a single organism, consistent with a specific and important biological function of these protein within C. cardunculus. These enzymes, cardosins E, F, G and H, are dimeric, glycosylated, pepstatin-sensitive APs, active at acidic pH, with a maximum activity around pH 4.3. Their primary structures were partially determined by N- and C-terminal sequence analysis, peptide mass fingerprint analysis on a MALDI-TOF/TOF instrument and by LC–MS/MS analysis on a Q-TRAP instrument. All four enzymes are present on C. cardunculus L. pistils, along with cyprosins and cardosins A and B. Their micro-heterogeneity was detected by 2D-electrophoresis and mass spectrometry. The enzymes resemble cardosin A more than they resemble cardosin B or cyprosin, with cardosin E and cardosin G being more active than cardosin A, towards the synthetic peptide KPAEFF(NO₂)AL. The specificity of these enzymes was investigated and it is shown that cardosin E, although closely related to cardosin A, exhibits different specificity. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Embryology of Early Abortion Due to Limited Maternal Resources in Pisum sativum L.

In most flowering plants, many embryos are aborted early intheir development due to limited maternal resources. The kin-conflictinterpretation of plant embryology predicts these abortionsshould be under maternal control. In a study of the abortionprocess in Pisum sativum, we found the first visible indicationof abortion was formation of a weak hypostase. Callose was locallydeposited around the chalazal endosperm haustorium, and ligninalong the outer cell walls of the remnant nucellar tissue. Thenucellus was compressed by proliferating adjacent inner integumentalcells. The endosperm haustorium's cytoplasm was forced backinto the embryo sac cavity. With suppression of haustorial activitythe endosperm nuclei gradually enlarged followed by enlargementof the embryo and suspensor nuclei. Finally, nuclei and cytoplasm throughout the endosperm and embryolost stainability and broke down. Four successive stages wererecognized in seed abortion. In seeds developing to maturity,no hypostase was developed and the haustorium continued to digestboth the remnant nucellus and the proliferated inner integumentalcells. These observations are consistent with the kin-conflicthypothesis. Pisum sativum, garden pea, ovule abortion, histology, hypostase, kin-conflict hypothesis     

Self-incompatibility in Acacia retinodes: Site of pollen-tube arrest is the nucellus

In self-incompatible Acacia retinodes Schldl. var. uncifolia J.M. Black there is no inhibition of self pollen tubes before entry into the ovule, but the frequency of fertilized embryo sacs observed after self pollination is only 0.09–0.24 of that observed after outcrossing. Fluorescence- and light-microscope studies of sectioned, squashed or cleared whole ovules indicate that most self pollen tubes are arrested within the first or second layer of cells of the nucellus. The probability that nucellar arrest represents a primitive feature of self-incompatibility is discussed.     

Isolation of embryo sacs from Dianthus ovules by enzymatic treatments and microdissection

 Mature ovules of Dianthus (Caryophyllaceae) were histologically observed by clearing and serial sectioning to characterize the cells of the embryo sac. The results show that the mature embryo sac was located deep inside the hemitropous ovule due to thick nucellar tissue at the micropylar region. For the isolation of the embryo sacs, ovules were collected from ovaries of flowers 1 day after anthesis, and treated with an enzyme solution for digesting cell walls on a gyratory shaker. After 12 h of enzyme treatment, these ovules were dissected using a glass needle under an inverted microscope to release the embryo sacs. The embryo sacs, characterized by their specific size, were successfully released by these successive treatments. The viability of the embryo sacs was more than 80% as assessed with fluorescein diacetate staining. Fluorescent staining with 4,6-diamidino-2-phenylindole revealed the nuclei of the egg apparatus in the isolated embryo sacs. The procedure for isolating embryo sacs established in this study will offer a new approach to further in vitro studies on fertilization in Dianthus. Received: 20 January 1999 / Revision received: 12 July 1999 / Accepted: 17 August 1999     

草地早熟禾胚胎学研究 Ⅲ．多胚囊及多胚现象

报道了草地早熟禾中多胚囊的起源、发育和结构。在１个胚珠中,大孢子母细胞周围可以有一到多个起源于珠心细胞的胚囊原始细胞,并可以发育成为多胚囊,其中具有两个胚囊的可以发育成为成熟胚囊。起源于珠心的体细胞无孢子生殖胚囊的发育属于山柳菊型。两个成熟胚囊中,都可以形成胚和胚乳,因而形成了具假多胚的种子。位于中部的胚来源于珠心还囊,属于无融合生殖形成的胚。两个以上的多胚囊不能形成成熟胚囊。     

Studies on the Development of Gametophytes in Cornus officinalis (Cornaceae)

The floral bud of Cornus officinalis Sieb. et Zucc. began to differentiate at the end of April. In the beginning of November, female and male gametophytes reached their maturation. The flowers fell off in the following March. The wall of the microsporangium comprised epidermis, endothecium, two or three middle layers and a single layer of amoeboid tapetum with two nuclei. The extra-tapetal membrane was formed during the later stage of the development of anther. Meiosis of microspore mother-cell was normal and cytokinesis was of the simultaneous type. The tetrad was tetrahedral in shape. The mature pollen grains were 2-celled and 3-colporate. The ovule was unitegminous and tenuinucellate. During the development of the ovule, some special structures were formed, e. g. hypostase and obturator which originated from the integument. A single archesporium differentiated immediately below the nucellar epidermis. It functioned directly as the megaspore mother-celL This cell under went meiosis to form a linear tetrad. The chalazal megaspore was functional. The development of the embryo sac was conformed as the polygonum type. Two polar nuclei fused into the secondary nucleus and 'three antipodal cells degenerated soon after the embryo sac reached its maturation, at that time the female gametophyte had become an embryo sac which consisted of only four cells each with a nucleus just before two months of blooming. The nuclei of some synergids located in the chalazal part of the cells. Contrarily, the micropylar past of the synergids were occupied by a large vacuole. The secondary nucleus was usually located in the chalazal part of the embryo sac.     

Iatercellular Migration of Protoplasm and Its Relation to the Development of Embryo Sac in Nucellus of Wheat

During the development of the ovule before pollination, deterioration of successive layers of nucellar tissue, beginning from the nnermost, constantly takes place and consistently forms a zone of disorganization surrounding the periphery of the enlarging embryo sac. Nucellar tissue deteriorates much more profusely near the antipodal end of the sac. "Nuclear extrusion" taken as an indication of intercellular movement of the protoplasm which has undergone partial disassembly, can be seen among the nucellar tissues and between the nucellus and the embryo sac. The intruding nuclear fragments, some of which assume the form of nucleolus, can be found in the antipodal cells. The results interpreted according to our previous hypothesis, are as follows. The nucellar cell by means of intercellular movement of its own protoplasm in the state of partial disassembly, furnishes the embryo sac with composite units of various polymers and organelles. Consequently, the antipodal cells proliferate and flourish The interrelationship between nucellus and embryo sac has been discussed from the viewpoint of supply and utilization of nourishment, which is necessary for the rapid development of the embryo sac.     

An anatomical study of ovary-to-cuke development in consistently low-producing trees of the ‘Fuerte’ avocado (Persea americana Mill.) with special reference to seed abortion

Summary Cukes develop from female-sterile, cryptically male flowers on consistently low-producing Fuerte trees. A hypostase that has, as yet, not been reported for the avocado, is present in the chalazal tissue of the mature ovule and aborting seed. This layer seems to play a role in the degeneration of the peripheral nucellar tissue and the non-development of the intercalary meristem of the pachychalaza. The ultimate cause of cuke formation, however, seemingly lies in the disturbance of the polarity of the primordial nucellar tissue. Additional megagametophytes and non-functional megaspores that develop in the nucellus effect the collapse of the chalazal region of the embryo sac. Degeneration of these gametophytes and megaspores causes the formation of nucellar cavities that isolate the embryo sac from the nutritive tissues and chalazal flow of nutrients. The micropylar region of the embryo sac contains a well-developed egg cell, synergids and central cell nucleus. An embryo and a limited amount of endosperm tissue are formed. Because the endosperm is starved of nutrients, the formation of this tissue is curtailed at an early stage, and embryo development ceases. A meristematic zone that initiates from the inner layers of the outer integument, directly opposite the place where the vascular supply to the chalaza terminates, causes abnormal growth in the outer integument. It is suggested that, due to the absence of meristematic activity in the chalazal region of the embryo sac and the non-developing pachychalaza, resources are redistributed towards the stronger sink, i.e. the outer integument. Consequently, this part of the seed coat proliferates, while the embryo sac and pachychalaza degenerate. In spite of the abortion of the seed, the pericarp of the cuke continues to develop, possibly because the pericarp of the avocado contains phytohormones.     

宁夏枸杞大孢子发生和雌配子体发育的细胞学研究

采用半薄切片技术和组织化学染色法对宁夏枸杞大孢子发生和雌配子体发育过程中的细胞结构变化及营养物质积累特征进行了观察。结果表明,(1)宁夏枸杞为中轴胎座,多室子房,倒生胚珠,单珠被,薄珠心类型。(2)位于珠心表皮下的孢原细胞可直接发育为大孢子母细胞,减数分裂后形成直线型大孢子四分体,合点端第一个大孢子发育为功能大孢子,胚囊发育类型为蓼型,具有珠被绒毡层。(3)初形成的胚囊外周组织中没有营养物质积累,成熟胚囊时期出现了大量的淀粉粒且呈珠孔端明显多于合点端的极性分布特征。(4)助细胞的珠孔端具有明显的丝状器结构,呈PAS正反应表现出多糖性质,成熟胚囊具有承珠盘结构。     

四倍体双穗雀稗兼性无孢子生殖的研究

研究了四倍体双穗雀稗(Paspalum distichum L)无孢子生殖胚囊、胚胎发育以及假受精特点。当其大孢子母细胞发育至四分体阶段时,大多数情况下会发生四分体退化,同时有多个特化珠心细胞发育为1—3个无孢子生殖胚囊的现象。成熟无孢子生殖胚囊一般3核,包括1个卵细胞和2个极核。卵细胞在抽穗前就能自发分裂形成原胚团,而极核则在抽穗和传粉后参与假受精形成胚乳。当胚珠内存在多个无孢子生殖胚囊时,只是靠近珠孔端的1个无孢子生殖胚囊内的极核与精核结合,而其它的并不参与。种子成熟后出现很低频率的二胚苗。此外,还能观察到少量的有性生殖胚囊的发育以及有性生殖胚囊和无孢子生殖胚囊在同一胚珠中的发育现象,因此判断该类群为兼性无孢子生殖体。     

小叶兜兰的果实生长和雌配子体发育

为了解濒危兰科植物小叶兜兰(Paphiopedilum barbigerum Tang et Wang)胚珠和雌配子体的发育过程,采用常规石蜡切片技术对其果实的生长动态进行了研究。结果表明,授粉后60~75 d的蒴果内种子数量迅速增加,到授粉后120 d时种子充满整个蒴果。授粉后40 d的胎座上分化形成多数由1层表皮细胞包被1列细胞的胚珠原基;授粉后60 d时位于胎座指状结构末端处紧靠表皮细胞下方的孢原细胞分化为大孢子母细胞。之后,大孢子母细胞经过减数分裂和有丝分裂最终形成成熟胚囊;授粉后135 d胚囊发育成熟,附着在胎座上的种子个体分化明显。小叶兜兰胚囊的发育类型为双孢子葱型,胚珠为倒生胚珠,薄珠心,单珠被,成熟胚囊为8核。这为小叶兜兰的生殖生物学及繁殖体系的建立提供理论依据。     

EMBRYO SAC DEVELOPMENT IN THE CV. KS MALE-STERILE,FEMALE-STERILE LINE OF SOYBEAN (GLYCINE MAX)

Light microscopic observations were made on 22 ovules from fertile plants and 108 ovules from sterile plants of the cv. KS synaptic mutant, a highly male-sterile, female-sterile line of soybean [Glycine max (L.) Merr.] (2n = 2x = 40). Ovules of fertile siblings contained normal embryo sacs and embryos. Ovules from sterile plants contained various irregularities. The most consistent abnormality was the failure of the embryo sac to attain normal size. Small megasporocytes of irregular shape were seen; only one megasporocyte of normal shape and size was noted. No linear tetrads were found. However, two ovules contained nonlinear triads. A range from zero to 28 cells and nuclei, of various sizes, were identifiable in small megagametophytes and embryo sacs. Degeneration of these nuclei and cells was noted as early as the four-nucleate gametophyte stage. Other ovules contained degenerated nucellar centers without embryo sacs. Two ovules appeared to be normal. Late postpollination stages were marked by shrunken nucellus and integuments. The presence of pollen tube traces, endosperm, and aborting embryos in ovules of hand-pollinated flowers from sterile plants suggested that no incompatibility was involved. Degeneration of the gametophyte and embryo sac contents at many developmental stages indicated a wide array of effects, possibly resulting from meiotic irregularities similar to those seen in microsporogenesis of this mutant.     

Immunolocalization of arabinogalactan proteins inAmaranthus hypochondriacus L. ovules

Summary Amaranthus hypochondriacus ovules are of the crassinucellate type, having several layers of nucellus cells between the micropyle and the embryo sac through which pollen tubes have to penetrate. The ultrastructural features of the micropylar nucellus cells appear to reflect cells with high metabolic activity. With the monoclonal antibodies MAC207 and JIM8 (against arabinogalactan proteins) we have shown that the presence of the two epitopes was different in the gametophytic tissues and embryo sac. The young embryo and suspensor cells are reactive only to Mab JIM8. The selective presence and localization of these two epitopes was also demonstrated in the micropylar nucellus cells. The expression of these arabinogalactan proteins in this ovule seems to be closely aligned with the pathway of the pollen tube, possibly providing directional guides for tube growth inside the ovule.     

EMBRYO SAC LACKING ANTIPODAL CELLS IN ARABIDOPSIS THALIANA (BRASSICACEAE)

Ultrastructure of the embryo sac lacking antipodals in prefertilization stages in Arabidopsis thaliana has been examined 2 hr before and 5 hr after manual cross pollination. The cytoplasm of both synergids before fertilization is rich in ribosomes, mitochondria, and rough endoplasmic reticulum, and also contains several microbodies and spherosomes. The filiform apparatus includes electron-dense material and a fibrous part. Many cortical microtubules appear in the filiform apparatus area. One of the two synergids degenerates before fertilization. The synergids, the egg cell, and central cell have a rich cytoskeleton of microtubules; only the synergids appear to contain microfilaments. At the chalazal end, the antipodals are initially present but degenerate by the time of pollination in most embryo sacs in the starchless line studied. The embryo sac is completely surrounded by a wall containing an electron-dense layer, separating it from the nucellus, including the chalazal end. When the antipodals have degenerated, the electron-dense layer disappears at the chalazal end only, and the wall between the central cell and the nucellus is homogeneous. Between the central cell and nucellar cells no plasmodesmata are found. The membranes of both antipodal cells at the chalazal end of the embryo sac appear sinuous, like those of transfer cells. The central cell has plastids preferentially distributed around the nucleus, but the other organelles are randomly distributed. The central cell in the embryo sac and the adjacent chalazal nucellar cells show a transfer-cell function in the embryo sac after the antipodals degenerate.     

A pattern of unique embryogenesis occurring via apomixis in Carya cathayensis

Apomixis represents an alteration of classical sexual plant reproduction to produce seeds that have essentially clonal embryos. In this report, hickory (Carya cathayensis Sarg.), which is an important oil tree, is identified as a new apomictic species. The ovary has a chamber containing one ovule that is unitegmic and orthotropous. Embryological investigations indicated that the developmental pattern of embryo sac formation is typical polygonum-type. Zygote embryos were not found during numerous histological investigations, and the embryo originated from nucellar cells. Nucellar embryo initials were found both at the micropylar and chalazal ends of the embryo sac, but the mature embryo developed only at the nucellar beak region. The mass of the nucellar embryo initial at the nucellar beak region developed into a nucellar embryo or split into two nucellar proembryos. The later development of the nucellar embryo was similar to the zygotic embryo and progressed from globular embryo to heart-shape embryo and to cotyledon embryo.     

Processing and trafficking of a single isoform of the aspartic proteinase cardosin A on the vacuolar pathway

Cardosin A is the major vacuolar aspartic proteinase (APs) (E.C.3.4.23) in pistils of Cynara cardunculus L. (cardoon). Plant APs carry a unique domain, the plant-specific-insert (PSI), and a pro-segment which are separated from the catalytic domains during maturation but the sequence and location of processing steps for cardosins have not been established. Here transient expression in tobacco and inducible expression in Arabidopsis indicate that processing of cardosin A is conserved in heterologous species. Pulse chase analysis in tobacco protoplasts indicated that cleavage at the carboxy-terminus of the PSI could generate a short-lived 50 kDa intermediate which was converted to a more stable 35 kDa intermediate by removal of the PSI. Processing intermediates detected immunologically in tobacco leaves and Arabidopsis seedlings confirmed that cleavage at the amino-terminus of the PSI either preceded or followed quickly after cleavage at its carboxy-terminus. Thus removal of PSI preceded the loss of the prosegment in contrast to the well-characterised barley AP, phytepsin. PreprocardosinA acquired a complex glycan and its processing was inhibited by brefeldin A and dominant-inhibitory AtSAR1 or AtRAB-D2^a mutants indicating that it was transported via the Golgi and that processing followed ER export. The 35 kDa intermediate was present in the cell wall and protoplast culture medium as well as the vacuole but the 31 kDa mature subunit, lacking the amino-terminal prosegment, was detected only in the vacuole. Thus maturation appears to occur only after sorting from the trans-Golgi to the vacuole. Processing or transport of cardosin A was apparently slower in tobacco protoplasts than in whole cells. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Calcium distribution in fertilized and unfertilized ovules and embryo sacs of Nicotiana tabacum L.

Potassium antimonate was used to localize Ca²⁺ in tobacco ovules from 0 to 7 d after anthesis in pollinated and emasculated flowers. Antimonate binds “loosely bound” Ca²⁺ into calcium antimonate; less-soluble forms are unavailable and free calcium usually escapes. Ovules are immature at anthesis. Abundant calcium precipitates in nucellar cells surrounding the micropylar canal. A difference between calcium in the two synergids emerges at 1 d, which is enhanced in pollinated flowers. The future receptive synergid accumulates more precipitates in the nucleus, cytoplasm and cell walls. After fertilization, micropyle precipitates diminish, and the ovule is unreceptive to further tube entry. In emasculated flowers 6 d after anthesis, ovular precipitates essentially disappear; however, flowers pollinated at 4–5 d and collected 2 d later largely restore their prior concentration of precipitates. Ovular precipitates occur initially in the nucellus, then the embryo sac, and finally the synergid and micropylar filiform apparatus. Possibility, calcium is released from the embryo sac, although no structural evidence of exudate formation was observed. Calcium precipitates in the ovule correlate with the ability of the ovule to be fertilized, suggesting that successful pollen tube entry and later development may require calcium of the class precipitated by antimonate. Received: 14 August 1996 / Accepted: 9 October 1996     

Ultrastructural characterization of apospory in Panicum maximum

The nucellar ultrastructure of apomictic Panicum maximum was analyzed during the meiocytic stage and during aposporous embryo sac formation. At pachytene the megameiocyte shows a random cell organelle distribution and sometimes only an incomplete micropylar callose wall. The chalazal nucellar cells are meristematic until the tetrad stage. They can turn into initial cells of aposporous embryo sacs. The aposporous initials can be recognized by their increased cell size, large nucleus, and the presence of many vesicles. The cell wall is thin with few plasmodesmata. If only a sexual embryo sac is formed, the nucellar cells retain their meristematic character. The aposporous initial cell is somewhat comparable to a vacuolated functional megaspore. It shows large vacuoles around the central nucleus and is surrounded by a thick cell wall without plasmodesmata. In the mature aposporous embryo sac the structure of the cells of the egg apparatus is similar to each other. In the chalazal part of the egg apparatus the cell walls are thin and do not hamper the transfer of sperm cells. Structural and functional aspects of nucellar cell differentiation and aposporous and sexual embryo sac development are discussed.     

Embryological studies inGlaucidium palmatum Sieb. et Zucc. with a discussion on the taxonomy of the genus

Embryological features ofGlaucidium palmatum are as follows: the ovule is anatropous and bitegmic; the archesporium is hypodermal and multicelled, consisting of about 10 to 15 cells; all the archesporial, cells develop directly into megaspore mother cells, only three or four of which, however, generally complete meiotic divisions; before and during meiosis, dermal cells of the nucellar apical part undergo successive periclinal divisions forming a thick nucellar cap of as many as 20 cell-layers; embryo sac formation is of the Polygonum type; multiple embryo sacs occur frequently; antipodal cells are small in size and ephemeral or persistent; the inner integument is 3 to 5 cell-layers thick, and the outer integument 7 to 13 cell-layers thick; the outer integument is vascularized; a micropyle is formed by the inner integument alone; the endosperm is of the Nuclear type; embryogeny is of a type similar to the Onagrad type. In light of evidence from embryology and other sources it seems that there is ample reason for recognizing the family Glaucidiaceae which is distinct from the Ranunculaceae and its related families. Several common embryological features suggest an affinity between the Glaucidiaceae and the Paeoniaceae.