Seed habit The differentiation of spores into microspores and megaspores and their dependence on the parent sporophyte for the nutrition, are the certain features in the life cycle of Selaginella, which have been considered as the essential pre-requite for formation of seed, the characteristic of spermatophyte.
The evolution of heterospory and seed habits in Selaginella is evident by the following characters
(i) Reduction to a single functional megaspore per sporangium.
(ii) Retention and germination of megaspore within megasporangium
(iii) Development of protective layer and nutritive tissue called tapetum is present.
(iv) Development of embryosac with in the sporangium.
(v) Modification of distal end of mega sporangium to capture pollen grain.
(vi) Pollination and siphonogamy.
(vii) Temporary suspension of growth of embryo (dormancy period).
Cycas as the relic of past Cycas is an evergreen plant which looks like a palm. It has unbranched stem and large compound leaf. It exhibit phylogenetic relationship with pteridophyte. Its evolutionary characters are
(i) Slow growth.
(ii) Shedding of seed when the embryo is still immature.
(iii) Little secondary growth and manoxylic wood.
(iv) Leaf like megasporophyllus.
(v) Flagellate sperms even when pollen tube is present.
(vi) Persistent leaf bases.
(vii) Circinate ptysix.
(viii) Arrangement of microsporangia is well defined archegonia.
Heterospory, i.e., production of two types of spores smaller microspores and larger megaspore was first reported in Selaginella a pteridophyte. In Selaginella, the smaller microspores are destined to produce male gametophytes and the larger megaspores to female gametophyte.
The male gametophyte produces male gametes, whereas the female gametophyte produces archegonia and also provides nourishment to the developing embryo.
The phenomenon of heterospory, thus lead to the reduction of gametophyte, in situ germination of spores, retention of megagametophyte in the megasporangia and finally to the seed development. Thus, the heterospory in Selaginella forms the base for seed habit development in gymnosperms.
The life cycle of fern (Dryopteris) clearly shows the alternation of generation. The gametophytic stage $(n)$ alternates with the sporophytic stage $(2 n)$ figure given shows its complete life cycle.
Prothallus The prothallus of the fern is multicellular, free living, thalloid, haploid and autotrophic structure. It develops from the spores produced by sporophyte after reduction division. These spore germinate with a germtube with an apical cell and forms a filament of 3-6 cells and one or two rhizoids at the base which later develops into gametophytic plant.
The male and female gametophytes of pteridophytes and gymnosperms different from each other are
| Male Gametophyte of Pteridophyte | Male Gametophyte of Gymnosperm |
|---|---|
| A distinct male gametophyte may not be present. | A male gametophyte is always present. |
| It contains an antheridium. | An antheridium is not found. |
| Male gametes are flagellated. | Male gametes may or may not be flagellated. |
| Male gametes reach the female gamete by swimming in a film of water. | Male gametes reach the female gamete through a pollen tube. Water is not required. |
| Female Gametophyte of Pteridophyte | Female Gametophyte of Gymnosperm |
|---|---|
| A distinct female gametophyte may or may not be present. | A distinct gametophyte is always present. |
| It is largely independent.. | Female gametophyte does not leave the parent plant. |
| It is not enclosed is an ovule. | It is enclosed inside an ovule. |