Norifumi Mogami scite author profile

Nakamura

1999

Protoplasma

Summary.In order to compare cell wall formation in gymnosperm pollen with that in angiosperm pollen, the distribution of cell wall constituents in the pollen grain and pollen tube of Pinus densiflora was studied immunocytochemically with monoclonal antibodies JIM 5 (against non-or poorly esterified pectin), JIM 7 (against highly esterified pectin), JIM 13 (against arabinogalactan proteins, AGPs), and LM 2 (against AGPs containing glucuronic acid). In the pollen grain wall, only the outer layer of the intine was labeled with JIM 5 and weakly with JIM 7. The tube wall was scarcely labeled with JIM 5 and very weakly labeled with JIM 7. In contrast, the whole of both the intine and the tube wall was strongly labeled with JIM 13 and LM 2, and the generative-cell wall was also labeled only with LM 2. The hemicellulose B fraction, which is the main polysaccharide fraction from the pollen tube wall, reacted strongly with JIM 13 and especially LM 2, but not with antipectin antibodies. These results demonstrate that the wall constituents and their localization in P. densiflora pollen are considerably different from those reported in angiosperm pollen and suggest that the main components of the cell wall of P. densiflora pollen are arabinogalactan and AGPs containing glucuronic acid.

The identification of a pollen‐specific LEA‐like protein in Lilium longiflorum

Plant Cell & Environment

Shiota

Tanaka

2002

A novel pollen-specific LEA-like protein, LP28, was detected in Lilium longiflorum using two-dimensional polyacrylamide gel electrophoresis (2D-PAGE). Immunoblot analysis using antiserum raised against LP28 revealed that the protein was not found in somatic tissues or uninucleate microspores, but accumulated gradually in developing pollen following microspore mitosis. Furthermore, LP28 was abundant in germinated pollen after hydration. The cDNA clone corresponding to LP28 encoded a putative protein of 238 amino acids with a calculated molecular mass of 24·2 kDa and a pI of 4·7. The amino acid sequence is highly hydrophilic except for the N-terminal hydrophobic signal peptide. The sequence has similarities with group 3 LEA (late embryogenesis abundant) proteins. Immunocytochemical analyses demonstrated that LP28 was mainly found in cytoplasmic granules of the vegetative cell until pollen maturation, but after hydration it appeared in the elongating pollen tube wall. LP28 might be a unique pollenspecific protein that is transported to the pollen tube wall after germination. Therefore, it is assumed that LP28 plays a role not only in pollen maturation, but also in the growth of the pollen tube, which penetrates the stylar matrix.

Bipolar Localization of Putative Photoreceptor Protein for Phototaxis in Thermophilic Cyanobacterium Synechococcus elongatus

Kondou

Hoshi

et al. 2002

We identified an open reading frame from a database of the entire genome of Synechococcus elongatus, the product of which was very similar to pixJ1, which was proposed as photoreceptor gene for phototaxis in Synechocystis sp. PCC6803 [Yoshihara et al. (2000) Plant Cell Physiol. 41: 1299]. The mRNA of S. elongatus pixJ (SepixJ) was expressed in vivo as a part of the product of an operon. SePixJ was detected exclusively in the membrane fraction after cell fractionation. Immunogold labeling of SePixJ in ultra-thin sections indicated that it existed only in both ends of the rod-shaped cell; probably bound with the cytoplasmic membrane.

Comparison of callose plug structure between dicotyledon and monocotyledon pollen germinatedin vitro

Miyamoto

Onozuka

et al. 2006

Grana

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

Sexual Plant Reproduction

Shiota

Tanaka

2002

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.