John R. Rowley scite author profile

Contents Summary 483 Introduction 483 Progress of research on pollen wall development 485 The developmental role of the special cell wall 487 Meiosis and the establishment of microspore symmetry 489 The origins of the exine during the tetrad stage 490 The free microspore stage to pollen maturation 495 Conclusions 495 Acknowledgements 496 References 496 Summary The outer pollen wall, or exine, is more structurally complex than any other plant cell wall, comprising several distinct layers, each with its own organizational pattern. Since elucidation of the basic events of pollen wall ontogeny using electron microscopy in the 1970s, knowledge of their developmental genetics has increased enormously. However, self‐assembly processes that are not under direct genetic control also play an important role in pollen wall patterning. This review integrates ultrastructural and developmental findings with recent models for self‐assembly in an attempt to understand the origins of the morphological complexity and diversity that underpin the science of palynology.

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Transfer of material through the microspore exine from the loculus into the cytoplasm

Rowley¹,

Skvarla²,

El‐Ghazaly³

2003

Can. J. Bot.

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Our results and those we review indicate that the exine has a great capacity for modifications that enable nutrients to pass through from the anther loculus to the microspore cytoplasm. Avenues of passage include strands, some of which are viscin threads, from the tapetum to microspores in, for example, Betula, Fuchsia, and Epilobium. Micro channels in Lopezia, Gaura, and Gelsemium extend through the ectexine, endexine, and intine to the cytoplasm. The bulge regions in Epilobium represent portions of the endexine that become very greatly enlarged, forming conducting channels that transport materials into the microspore cytoplasm. Results with tracers such as colloidal iron and lanthanum have also shown that exines of microspores are permeable across areas lacking obvious channels.Key words: Betula, Epilobium, exine, Fuchsia, Gaura, Gelsemium, Lopezia, microchannels, pollen, tapetum, tufts, viscin threads.

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Exine development in Nymphaea colorata (Nymphaeaceae)

Gabarayeva

Rowley

1994

Nordic Journal of Botany

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We show a sequence of developmental events in microspores and tapetal cells in Nymphaea colorata based upon transmission and scanning electron microscopic observations. There are parallel cytoplasmic processes and surface coatings in microspores and tapetal cells. Uptake is indicated by the passage of lanthanum as a tracer from anther locule into the microspore cytoplasm and by the condition of the cytoplasmic surface of microspores. The callose envelope is not a barrier to transfer of lanthanum. During formation of the proexine glycocalyx tiny spiral elements, components of the exine substructural units, were oriented in different directions in the surface coating of microspores and tapetum. Lipoidal globules are associated with the spiral elements. After the uniform proexine stage, three regions of different exine structure and their gradations become differentiated in the sporoderm: 1) a proximal region with thick tectum and foot layer, thin columellae and a compact layer of lamellated endexine; 2) a distal pole region with separately disposed endexine lamellae; and 3) an equatorial encircling‐sulcate aperture region which consists of infratectal layer, foot layer, and endexine lamellae. Based upon the presence of structurally comparable surface coats in microspores and tapetal cells, experimental uptake of lanthanum nitrate, and the co‐ordinated processes in tapetum and microspores, we conclude that there is probably a reciprocal controlling influence between the microspores and the tapetum and other sporophytic tissues.

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The Exine Structure of “Cereal” and “Wild” Type Grass Pollen

Rowley

1960

Grana Palynologica

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Polarity, aperture condition and germination in pollen grains ofEphedra (Gnetales)

1998

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John R. Rowley

Pollen wall development in flowering plants

Transfer of material through the microspore exine from the loculus into the cytoplasm

Exine development in Nymphaea colorata (Nymphaeaceae)

The Exine Structure of “Cereal” and “Wild” Type Grass Pollen

Polarity, aperture condition and germination in pollen grains ofEphedra (Gnetales)

Contact Info

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Resources

About

John R. Rowley

Pollen wall development in flowering plants

Transfer of material through the microspore exine  from the loculus into the cytoplasm

Exine development in Nymphaea colorata (Nymphaeaceae)

The Exine Structure of “Cereal” and “Wild” Type Grass Pollen

Polarity, aperture condition and germination in pollen grains ofEphedra (Gnetales)

Contact Info

Product

Resources

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Transfer of material through the microspore exine from the loculus into the cytoplasm