Tetrad pollen formation in quartet mutants of Arabidopsis thaliana is associated with persistence of pectic polysaccharides of the pollen mother cell wall

The quartet (qrt) mutants of Arabidopsis thaliana produce tetrad pollen in which microspores fail to separate during pollen development. Because the amount of callose deposition between microspores is correlated with tetrad pollen formation in other species, and because pectin is implicated as playing a role in cell adhesion, these cell-wall components in wild-type and mutant anthers were visualized by immunofluorescence microscopy at different stages of microsporogenesis. In wild-type, callose was detected around the pollen mother cell at the onset of meiosis and around the microspores during the tetrad stage. Microspores were released into the anther locule at the stage where callose was no longer detected. Deposition and degradation of callose during tetrad pollen formation in qrt1 and qrt2 mutants were indistinguishable from those in wild-type. Enzymatic removal of callose from wild-type microspores at the tetrad stage did not release the microspores, suggesting that callose removal is not sufficient to disperse the microspores in wild-type. Pectic components were detected in the primary wall of the pollen mother cell. This wall surrounded the callosic wall around the pollen mother cell and the microspores during the tetrad stage. In wild-type, pectic components of this wall were no longer detectable at the time of microspore release. However, in qrt1 and qrt2 mutants, pectic components of this wall persisted after callose degradation. This result suggests that failure of pectin degradation in the pollen mother cell wall is associated with tetrad pollen formation in qrt mutants, and indicates that QRT1 and QRT2 may be required for cell type-specific pectin degradation to separate microspores.     

Two callose synthases,GSL1 and GSL5, play an essential and redundant role in plant and pollen development and in fertility

Callose, a β-1,3-glucan that is widespread in plants, is synthesized by callose synthase. Arabidopsis thaliana contains a family of 12 putative callose synthase genes (GSL1–12). The role of callose and of the individual genes in plant development is still largely uncertain. We have now used TILLING and T-DNA insertion mutants (gsl1-1, gsl5-2 and gsl5-3) to study the role of two closely related and linked genes, GSL1 and GSL5, in sporophytic development and in reproduction. Both genes are expressed in all parts of the plant. Sporophytic development was nearly normal in gsl1-1 homozygotes and only moderately defective in homozygotes for either of the two gsl5 alleles. On the other hand, plants that were gsl1-1/+ gsl5/gsl5 were severely defective, with smaller leaves, shorter roots and bolts and smaller flowers. Plants were fertile when the sporophytes had either two wild-type GSL1 alleles, or one GSL5 allele in a gsl1-1 background, but gsl1-1/+ gsl5/gsl5 plants produced an extremely reduced number of viable seeds. A chromosome with mutations in both GSL1 and GSL5 rendered pollen infertile, although such a chromosome could be transmitted via the egg. As a result, it was not possible to obtain plants that were homozygous for mutations in both the GSL genes. Pollen grain development was severely affected in double mutant plants. Many pollen grains were collapsed and inviable in the gsl1-1/gsl1-1 gsl5/+ and gsl1-1/+ gsl5/gsl5 plants. In addition, gsl1-1/+ gsl5/gsl5 plants produced abnormally large pollen with unusual pore structures, and had problems with tetrad dissociation. In this particular genotype, while the callose wall formed around the pollen mother cells, no callose wall separated the resulting tetrads. We conclude that GSL1 and GSL5 play important, but at least partially redundant roles in both sporophytic development and in the development of pollen. They are responsible for the formation of the callose wall that separates the microspores of the tetrad, and also play a gametophytic role later in pollen grain maturation. Other GSL genes may control callose formation at different steps during pollen development.     

Study of male sterility in Taiwania cryptomerioides Hayata (Taxodiaceae)

Summary. A study of male sterility over a period of three consecutive years on a conifer species endemic to Taiwan, Taiwania cryptomerioides Hayata (Taxodiaceae), was done for this article. With the aids of fluorescence and electron microscopic observations, the ontogenic processes in the fertile and sterile microsporangia are compared, using samples collected from Chitou Experimental Forest and Yeou-Shoei-Keng Clonal Orchard of the National Taiwan University, Nantou, Taiwan. The development of male strobili occurred from August to the end of March. Microsporogenesis starts with the formation of the archesporium and ends with the maturation of 2-celled pollen grains within the dehiscing microsporangium. Before meiosis, there was no significant difference in ultrastructure between the fertile and sterile microsporangia. Asynchronous pollen development with various tetrad forms may occur in the same microsporangium of either fertile or sterile strobili. However, a callose wall was observable in the fertile dyad and tetrad, but not in the sterile one. After dissolution of the callose wall, the fertile microspores were released into the locule, while some sterile microspores still retained as tetrads or dyads with intertwining of exine walls in the proximal faces. As a result, there was no well developed lamellated endexine and no granulate ectexine or intine in the sterile microspores. Eventually, the intracellular structures in sterile microspores were dramatically collapsed before anthesis. The present study shows that the abortion in pollen development is possibly attributed to the absence of the callose wall. The importance of this structure to the male sterility of T. cryptomerioides is discussed. Correspondence and reprints: Department of Life Science, National Taiwan University, 106 Taipei, Taiwan.     

Development of structure-less pollen wall inCeratophyllum demersum L. (Ceratophyllaceae)

Developmental process of structure-less exine is studied in a hydrophilous plant,Ceratophyllum demersum L., with electron microscopy. The plant shows a characteristic feature in tetrad formation. A callose wall is not synthesized and exine initiation does not occur during the tetrad stage. After release of microspores, a trilaminar layer with two electron-dense lines is formed in the surface of each microspore. The trilaminar layer develops to a thin structure-less exine that is considered to consist of only an endexine. The unusual exine would be an adaptive feature for submersed pollination in fresh water.     

冬季低温条件下香石竹小孢子败育的细胞学研究

利用压片法及石蜡切片法观察冬季低温下香石竹小孢子发育过程,以明确低温导致香石竹小孢子败育的因素,为杂交育种奠定基础。结果表明:(1)冬季低温下香石竹只有部分小孢子发育正常,经过小孢子母细胞、减数分裂和四分体等时期,最后发育成花粉。(2)石蜡切片法观察到冬季低温下香石竹1.5~1.6cm长花蕾中有61%的花粉母细胞发生败育,1.7~1.8cm长花蕾中有71%的花粉母细胞发生败育。(3)部分已经进入四分体时期的小孢子胼胝质未能及时溶解,妨碍了小孢子释放而导致败育。研究认为,花粉母细胞和四分体的发育异常是冬季低温下香石竹小孢子败育的主要原因。     

Wall development and its autofluorescence of sterile and fertileVicia faba L. Pollen

Summary The ultrastructural changes of the pollen wall of three types of fertile and one of sterileVicia pollen were related to the autofluorescence of the pollen wall, measured by a microspectroscopic method. Till the liberation of the microspores from the tetrad, the spectrum of the ectexine shows sometimes two maxima and has a very low intensity. After this period the endexine is formed and its spectrum has one maximum with a high intensity. The differences of the pollen wall between the sterile and fertile pollen exist of the presence of one spectral maximum during the tetrad stage, a thick endexine and the absence of the intine in the sterile pollen. The different types show much differences during the tetrad stage in the callose wall as well as the ectexine. The autofluorescence illustrates the complexity and specificity of the pollen wall development.     

A glycine-rich protein that facilitates exine formation during tomato pollen development

Formation of the unique and highly diverse outer cell wall, or exine, of pollen is essential for normal pollen function and survival. However, little is known about the many contributing proteins and processes involved in the formation of this wall. The tomato gene LeGRP92 encodes for a glycine-rich protein produced specifically in the tapetum. LeGRP92 is found as four major forms that accumulate differentially in protein extracts from stamens at different developmental stages. The three largest molecular weight forms accumulated during early microspore development, while the smallest molecular weight form of LeGRP92 was present in protein extracts from stamens from early microsporogenesis through anther dehiscence, and was the only form present in dehisced pollen. Light microscopy immunolocalization experiments detected LeGRP92 at only two stages, late tetrad and early free microspore. However, we observed accumulation of the LeGRP92 at the early tetrad stage of development by removing the callose wall from tetrads, which allowed LeGRP92 detection. Transmission electron microscopy confirmed the LeGRP92 accumulation from microspore mother cells, tetrads through anther dehiscence. It was observed in the callose surrounding the microspore mother cells and tetrads, the exine of microspores and mature pollen, and orbicules. Plants expressing antisense RNA had reduced levels of LeGRP92 mRNA and protein, which correlated to pollen with altered exine formation and reduced pollen viability and germination. These data suggest that the LeGRP92 has a role in facilitating sporopollenin deposition and uniform exine formation and pollen viability.     

Release of developmental constraints on tetrad shape is confirmed in inaperturate pollen of Potamogeton

Background and Aims

Microsporogenesis in monocots is often characterized by successive cytokinesis with centrifugal cell plate formation. Pollen grains in monocots are predominantly monosulcate, but variation occurs, including the lack of apertures. The aperture pattern can be determined by microsporogenesis features such as the tetrad shape and the last sites of callose deposition among the microspores. Potamogeton belongs to the early divergent Potamogetonaceae and possesses inaperturate pollen, a type of pollen for which it has been suggested that there is a release of the constraint on tetrad shape. This study aimed to investigate the microsporogenesis and the ultrastructure of pollen wall in species of Potamogeton in order to better understand the relationship between microsporogenesis features and the inaperturate condition.

Methods

The microsporogenesis was investigated using both light and epifluorescence microscopy. The ultrastructure of the pollen grain was studied using transmission electron microscopy.

Key Results

The cytokinesis is successive and formation of the intersporal callose wall is achieved by centrifugal cell plates, as a one-step process. The microspore tetrads were tetragonal, decussate, T-shaped and linear, except in P. pusillus, which showed less variation. This species also showed a callose ring in the microsporocyte, and some rhomboidal tetrads. In the mature pollen, the thickening observed in a broad area of the intine was here interpreted as an artefact.

Conclusions

The data support the view that there is a correlation between the inaperturate pollen production and the release of constraint on tetrad shape. However, in P. pusillus the tetrad shape may be constrained by a callose ring. It is also suggested that the lack of apertures in the pollen of Potamogeton may be due to the lack of specific sites on which callose deposition is completed. Moreover, inaperturate pollen of Potamogeton would be better classified as omniaperturate.Key words: Alismatales, callose, microsporogenesis, pollen aperture, Potamogeton illinoensis, P. polygonus, P. pusillus, tetrad shape     

Functional analysis of a beta-1,3-glucanase gene (Tag1) with anther-specific RNA and protein accumulation using antisense RNA inhibition

A critical stage in pollen development is the dissolution of tetrads into free microspores. Tetrads are surrounded by a wall composed primarily of beta-1,3-glucan. At the completion of meiosis, tetrads are released into the anther locule after hydrolysis of the callose by a beta-1,3-glucanase complex. The cDNA corresponding to a beta-1,3-glucanase cloned from tobacco (Tag 1) represents a gene that is highly similar to other beta-1,3-glucanases and is expressed exclusively in anthers from the tetrad to free microspore stage of pollen development. Tag 1 protein was overexpressed in E. coli, accumulating in insoluble inclusion bodies. Polyclonal antibodies against Tag 1 recombinant protein identify a single 33 kD protein accumulating only in anthers at tetrad and free microspore stages where beta-1,3-glucanase activity is present. Transgenic plants expressing Tag 1 antisense RNA were produced. Although Tag 1 RNA and protein levels were greatly reduced, tetrad dissolution and pollen development were normal. These data indicate that under the conditions these tobacco plants were grown, wild type levels of Tag 1 protein are not necessary for male fertility.     

凤仙花花药发育中多糖和脂滴组织化学研究

以不同发育时期的凤仙花花药为实验材料,采用组织化学方法,对花药发育中的结构变化及多糖和脂滴物质分布进行观察。结果表明:(1)凤仙花的花药壁由6层细胞组成,包括1层表皮细胞,2层药室内壁细胞,2层中层细胞和1层绒毡层细胞。其中绒毡层细胞的形态不明显,很难与造孢细胞区分,且在小孢子母细胞时期退化。(2)在小孢子母细胞中出现了一些淀粉粒,但减数分裂后,早期小孢子中的淀粉粒消失,又出现了一些小的脂滴;随着花粉的发育,小孢子形成大液泡,晚期小孢子中的脂滴也消失;小孢子分裂形成二胞花粉后,营养细胞中的大液泡降解、消失,二胞花粉中又开始积累淀粉;接近开花时,成熟花粉中充满细胞质,其中包含了较多的淀粉粒和脂滴。(3)在凤仙花的花药发育中,绒毡层细胞很早退化,为小孢子母细胞和四分体小孢子提供了营养物质;其后的中层细胞退化则为后期花粉发育提供了营养物质。     

The HKM gene, which is identical to the MS1 gene of Arabidopsis thaliana, is essential for primexine formation and exine pattern formation

A male-sterile mutant of Arabidopsis thaliana was isolated by T-DNA tagging screening. Using transmission electron microscopy analysis, we revealed that the microspores of this mutant did not have normal thick primexine on the microspore at the tetrad stage. Instead, a moderately electron-dense layer formed around the microspores. Although microspores without normal primexine failed to form a proper reticulate exine pattern at later stages, sporopollenin was deposited and an exine-like hackly structure was observed on the microspores during the microspore stage. Thus, this mutant was named hackly microspore (hkm). It is speculated that the moderately electron-dense layer was primexine, which partially played its role in sporopollenin deposition onto the microspore. Cytological analysis revealed that the tapetum of the hkm mutant was significantly vacuolated, and that vacuolated tapetal cells crushed the microspores, resulting in the absence of pollen grains within the anther at anthesis. Single nucleotide polymorphism analysis demonstrated that the hkm mutation exists within the MS1 gene, which has been reportedly expressed within the tapetum. Our results suggest that the critical process of primexine formation is under sporophytic control .     

含笑花药发育的超微结构研究

对含笑花药发育中的超微结构变化进行观察,结果显示:(1)花粉发育中有三次液泡变化过程——第一次是小孢子母细胞在形成时内部出现了液泡,这可能与胼胝质壁的形成有关;第二次是在小孢子母细胞减数分裂之前,细胞内壁纤维素降解区域形成液泡,它的功能可能是消化原有的纤维素细胞壁;第三次是在小孢子液泡化时期,形成的大液泡将细胞核挤到边缘,产生极性。(2)含笑花粉在小孢子早期形成花粉外壁外层,花粉外壁内层在小孢子晚期形成,而花粉内壁是在二胞花粉早期形成;花粉成熟时,表面上沉积了绒毡层细胞的降解物而形成了花粉覆盖物。研究认为,含笑花粉原外壁的形成可能与母细胞胼胝质壁有关,而由绒毡层细胞提供的孢粉素物质按一定结构建成了花粉覆盖物。     

Cytological mechanism of pollen abortion resulting from allelic interaction of F1 pollen sterility locus in rice (Oryza sativa L.)

Pollen abortion is one of the major reasons causing the inter-subspecific F₁ hybrid sterility in rice and is due to allelic interaction of F₁ pollen sterility genes. The microsporogenesis and microgametogenesis of Taichung 65 and its three F₁ hybrids were comparatively studied by using techniques of differential interference contrast microscopy, semi-thin section light microscopy, epifluorescence microscopy and TEM. The results showed that there were differences among the cytological mechanisms of pollen abortion due to allelic interaction at the three F₁ pollen sterility loci. The allelic interaction at S-a locus resulted in microspores unable to extend the protoplasm membrane with the enlargement of the microspore at the middle microspore stage and finally producing empty abortive pollen. The allelic interaction at S-b locus caused asynchronous development of microspores at the middle microspore stage producing stainable abortive pollen. The allelic interaction at S-c locus mainly led to the non-dissolution of the generative cell wall and finally caused the hybrid F₁ mainly producing stainable abortive pollen. Genotypic identification indicated that the abortive pollen were those with S ^j allele.     

LP28, a lily pollen-specific LEA-like protein, is located in the callosic cell wall during male gametogenesis

. LP28, a pollen-specific LEA-like protein identified in Lilium longiflorum purportedly related to the desiccation tolerance of pollen, was localized during male gametogenesis using immuno-electron microscopy. At premeiotic interphase, LP28 label is absent from the microsporocyte. LP28 label was first detected in the cell wall of the microsporocyte at meiotic prophase I. LP28 gradually increased as the cell wall thickened. In the dyad, after the first meiotic division, LP28 label also appeared in the septum. In the tetrad, after the second meiotic division, LP28 was detected throughout the cell wall, including the septa. Immunolabeling of callose during meiosis indicated that the appearance and localization of LP28 was very similar to that of callose. After the microspores were released from the tetrad by digesting the callosic cell wall, LP28 was not found in the microspores. In bicellular pollen, just after microspore mitosis, LP28 appeared in the generative cell wall, which also consisted of callose. After pollen germination, LP28 also accumulated in the callosic layer of the elongated pollen tube wall and the callose plug. Thus, LP28 colocalized with the callosic cell wall during male gametogenesis. The possible role of LP28 with respect to wall formation during meiosis and pollen development is discussed.     

杉木花粉发育过程中形态结构的变化研究

该研究以扬州地区成年杉木为材料,采用半薄切片法以及扫描电镜和透射电镜观察法,对杉木花粉发育过程进行了观察。结果表明:杉木的造孢细胞形成于10月,持续至翌年的1月底至2月初。造孢细胞位于小孢子囊最里面,呈多边形,数量多且彼此排列紧密;细胞壁很薄,细胞核较大,内含丰富的细胞器和脂类物质。造孢细胞发育成熟后彼此分离形成小孢子母细胞。小孢子母细胞的减数分裂开始于2月下旬,经两次减数分裂,先后形成二分染色体和四分染色体。小孢子从四分体释放后,体积迅速增大,发育形成花粉,这个过程中,伴随着明显的营养物质变化。杉木成熟花粉壁由薄壁区和厚壁区两部分组成,薄壁区中央有一个乳头状突起,突起上有一萌发孔。成熟花粉外壁着生了许多瘤状颗粒。该研究结果为杉木生殖发育、有性繁殖以及系统演化研究提供了重要依据。     

Characterization of three male-sterile mutants of Arabidopsis thaliana exhibiting alterations in meiosis

Male-sterile mutants are being studied to deepen our understanding of the complex processes of microsporogenesis and microgametogenesis. Due to difficulties associated with isolating the mutated gene, there is currently very little molecular information on the defects responsible for male sterility. As a first step in utilizing male-sterile mutants to better understand the bio-chemical and molecular processes that control pollen development, we have characterized a number of Arabidopsis thaliana lines that were generated by seed transformation and exhibit male sterility. We report here the identification and characterization of three male-sterile A. thaliana lines, all of which are tagged with T-DNA and show aberrant meiosis. A detailed cytochemical study was conducted on these lines to better understand the timing and nature of each mutation and to investigate how these mutations affect subsequent steps of pollen development. All three mutants undergo apparently normal morphogenesis until the onset of meiosis. In one line (6492) the mutation is most notable at the tetrad stage when up to eight microspores can be seen in each callose-encased tetrad. The resulting mutant microspores are of variable sizes and contain different amounts of DNA. Two other mutants (7219 and 7593) possess many common features, including variable developmental pathways, failure to produce callose, production of vacuolate, coenocytic (multi-nucleate) cells that are surrounded by persistent microsporocyte walls, and asynchronous patterns of development. Unlike the situation in wild-type plants, where developmental stages are correlated with bud length, such correlations are almost impossible with these two mutants. The sporogenous tissue within all three of these mutant lines collapses prior to anthesis.     

Ultrastructure of microsporogenesis and microgametogenesis in Campsis radicans (L.) Seem. (Bignoniaceae)

In the present study, microsporogenesis, microgametogenesis and pollen wall ontogeny in Campsis radicans (L.) Seem. were studied from sporogenous cell stage to mature pollen using transmission electron microscopy. To observe the ultrastructural changes that occur in sporogenous cells, microspores and pollen through progressive developmental stages, anthers at different stages of development were fixed and embedded in Araldite. Microspore and pollen development in C. radicans follows the basic scheme in angiosperms. Microsporocytes secrete callose wall before meiotic division. Meiocytes undergo meiosis and simultaneous cytokinesis which result in the formation of tetrads mostly with a tetrahedral arrangement. After the development of free and vacuolated microspores, respectively, first mitotic division occurs and two-celled pollen grain is produced. Pollen grains are shed from the anther at two-celled stage. Pollen wall formation in C. radicans starts at tetrad stage by the formation of exine template called primexine. By the accumulation of electron dense material, produced by microspore, in the special places of the primexine, first of all protectum then columellae of exine elements are formed on the reticulate-patterned plasma membrane. After free microspore stage, exine development is completed by the addition of sporopollenin from tapetum. Formation of intine layer of pollen wall starts at the late vacuolated stage of pollen development and continue through the bicellular pollen stage.     

Development of the exineless pollen wall in Callitriche truncata (Callitrichaceae) and the evolution of underwater pollination

 The Callitrichaceae are a monogeneric family of aquatic angiosperms comprising approximately 50 terrestrial, amphibious, and obligately submersed species. Callitriche is unique in being the only known genus with co-occurring aerial and underwater pollination systems. Mature pollen structure is correlated with growth habit, pollination biology, and phylogeny within the genus. In the present study, development of exineless pollen in the obligately submersed species Callitriche truncata was examined, with particular emphasis on the tetrad stage. Pollen ontogeny occurred rapidly and non-synchronously; tetrads, free microspores, and two-celled pollen grains were identified within the same anthers. Formation of the intine also occurred relatively early, during the tetrad stage. Tetrads were surrounded by a structurally distinct envelope, and its ultrastructure and histochemistry indicate that this callose-like envelope is in a transitional state. Reduction or complete loss of the exine has evolved at least twice in Callitrichaceae, and the new ontogenetic data indicate that exine loss evolves more quickly than the loss of callose. In addition, developmental information on exineless pollen in C. truncata coupled with other palynological data for the exine-bearing terrestrial and amphibious growth forms provide support for the hypothesis that underwater pollination has had a relatively recent origin in the family. Received January 2, 2001 Accepted March 27, 2001