Tapetum-specific protein A9.

Basic leucine zipper 34; Transcriptional activator involved in the sporophytic control of cell wall patterning and gametophytic control of pollen development. May play a role in the control of metabolic pathways regulating cellular transport and lipid metabolism.

Tapetum-specific protein A9.

Cytochrome P450 703A2; Involved in pollen wall development. Catalyzes the conversion of medium-chain saturated fatty acids to the corresponding monohydroxylated fatty acids, with a preferential hydroxylation of lauric acid at the C-7 position. In-chain hydroxylated fatty acids, together with omega-hydroxylated fatty acids, are key monomeric aliphatic building blocks for sporopollenin synthesis during exine formation; Belongs to the cytochrome P450 family.

Tapetum-specific protein A9.

BZIP family transcription factor.

Tapetum-specific protein A9.

Probable magnesium transporter NIPA1; Acts as a Mg(2+) transporter. Can also transport other divalent cations such as Fe(2+), Sr(2+), Ba(2+), Mn(2+) and Co(2+) but to a much less extent than Mg(2+) (By similarity).

Tapetum-specific protein A9.

Protein JINGUBANG; Negative regulator of pollen germination. Prevents pollination in moist environments by inhibiting jasmonic acid synthesis. Stabilizes pollen tube growth.

Tapetum-specific protein A9.

GTP-binding protein-like protein.

Tapetum-specific protein A9.

Bidirectional sugar transporter SWEET8; Mediates both low-affinity uptake and efflux of sugar across the plasma membrane. Required, in pollen, for microspore cell integrity and primexine pattern formation.

Basic leucine zipper 34; Transcriptional activator involved in the sporophytic control of cell wall patterning and gametophytic control of pollen development. May play a role in the control of metabolic pathways regulating cellular transport and lipid metabolism.

Tapetum-specific protein A9.

Basic leucine zipper 34; Transcriptional activator involved in the sporophytic control of cell wall patterning and gametophytic control of pollen development. May play a role in the control of metabolic pathways regulating cellular transport and lipid metabolism.

Probable magnesium transporter NIPA1; Acts as a Mg(2+) transporter. Can also transport other divalent cations such as Fe(2+), Sr(2+), Ba(2+), Mn(2+) and Co(2+) but to a much less extent than Mg(2+) (By similarity).

Basic leucine zipper 34; Transcriptional activator involved in the sporophytic control of cell wall patterning and gametophytic control of pollen development. May play a role in the control of metabolic pathways regulating cellular transport and lipid metabolism.

Bifunctional inhibitor/lipid-transfer protein/seed storage 2S albumin superfamily protein.

Basic leucine zipper 34; Transcriptional activator involved in the sporophytic control of cell wall patterning and gametophytic control of pollen development. May play a role in the control of metabolic pathways regulating cellular transport and lipid metabolism.

Bidirectional sugar transporter SWEET8; Mediates both low-affinity uptake and efflux of sugar across the plasma membrane. Required, in pollen, for microspore cell integrity and primexine pattern formation.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Callose synthase 9; Involved in sporophytic and gametophytic development. Required for normal plant development. During pollen formation, required for the entry of microspores into mitosis and microspore symmetric division. May be required for correct temporal and spatial control of callose deposition during pollen mitosis. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Cytochrome P450 703A2; Involved in pollen wall development. Catalyzes the conversion of medium-chain saturated fatty acids to the corresponding monohydroxylated fatty acids, with a preferential hydroxylation of lauric acid at the C-7 position. In-chain hydroxylated fatty acids, together with omega-hydroxylated fatty acids, are key monomeric aliphatic building blocks for sporopollenin synthesis during exine formation; Belongs to the cytochrome P450 family.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Protein JINGUBANG; Negative regulator of pollen germination. Prevents pollination in moist environments by inhibiting jasmonic acid synthesis. Stabilizes pollen tube growth.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Bidirectional sugar transporter SWEET8; Mediates both low-affinity uptake and efflux of sugar across the plasma membrane. Required, in pollen, for microspore cell integrity and primexine pattern formation.

Callose synthase 9; Involved in sporophytic and gametophytic development. Required for normal plant development. During pollen formation, required for the entry of microspores into mitosis and microspore symmetric division. May be required for correct temporal and spatial control of callose deposition during pollen mitosis. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Callose synthase 9; Involved in sporophytic and gametophytic development. Required for normal plant development. During pollen formation, required for the entry of microspores into mitosis and microspore symmetric division. May be required for correct temporal and spatial control of callose deposition during pollen mitosis. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Protein JINGUBANG; Negative regulator of pollen germination. Prevents pollination in moist environments by inhibiting jasmonic acid synthesis. Stabilizes pollen tube growth.

Cytochrome P450 703A2; Involved in pollen wall development. Catalyzes the conversion of medium-chain saturated fatty acids to the corresponding monohydroxylated fatty acids, with a preferential hydroxylation of lauric acid at the C-7 position. In-chain hydroxylated fatty acids, together with omega-hydroxylated fatty acids, are key monomeric aliphatic building blocks for sporopollenin synthesis during exine formation; Belongs to the cytochrome P450 family.

Tapetum-specific protein A9.

Cytochrome P450 703A2; Involved in pollen wall development. Catalyzes the conversion of medium-chain saturated fatty acids to the corresponding monohydroxylated fatty acids, with a preferential hydroxylation of lauric acid at the C-7 position. In-chain hydroxylated fatty acids, together with omega-hydroxylated fatty acids, are key monomeric aliphatic building blocks for sporopollenin synthesis during exine formation; Belongs to the cytochrome P450 family.

Callose synthase 5; Required for the formation of the callose wall separating the tetraspores (interstitial wall) and surrounding the pollen mother cells (pheripheral wall). Required for exine formation on pollen wall. May be involved in callose synthesis during pollen tube growth. During plant growth and development, callose is found as a transitory component of the cell plate in dividing cells, is a major component of pollen mother cell walls and pollen tubes, and is found as a structural component of plasmodesmatal canals.

Cytochrome P450 703A2; Involved in pollen wall development. Catalyzes the conversion of medium-chain saturated fatty acids to the corresponding monohydroxylated fatty acids, with a preferential hydroxylation of lauric acid at the C-7 position. In-chain hydroxylated fatty acids, together with omega-hydroxylated fatty acids, are key monomeric aliphatic building blocks for sporopollenin synthesis during exine formation; Belongs to the cytochrome P450 family.

Probable magnesium transporter NIPA1; Acts as a Mg(2+) transporter. Can also transport other divalent cations such as Fe(2+), Sr(2+), Ba(2+), Mn(2+) and Co(2+) but to a much less extent than Mg(2+) (By similarity).