Development of Male Gametophyte

  

In the life history of angiospermic plant there are two stages, the sporophyte and gametophyte which alternate with each other.

Sporophytic stage:

This stage is derived from the diploid zygote, so it is a diploid stage in angiospermic plants. The plant body belongs to this stage. Reproductive organs or flowers develop on this plant.

Gametophytic stage:

This is the highly reduced haploid stage of angiospermic plant. This stage is derived from a spore which is a product of meiotic division of spore mother cells.  In angiosperms, spore mother cells are of two types : the microspore mother cells and megaspore mother cells.  Microspore mother cells develop in an anther while megaspore mother cell develops from the nucellus of the ovule. Each of these mother cells in turn gives rise to respective microspore and megaspores after undergoing meiotic divisions.  Consequently the microscope and megaspores which are haploid structures give rise to male and female gametophytes respectively.  The male gametophyte gives rise to male gametes and female gametophyte forms egg cell.  Fusion of male gamete and female gamete results in the formation of diploid zygote that later becomes embryo in the seed.

When the seed germinates the embryo develops into a sporophytic plant.

Structure of Anther and Microsporogenesis

Structure of Anther

Pollen grains which contribute the male gametes, are formed within an anther. A typical (dithecous) anther consists of two anther lobes, between which there is a column of sterile tissue called the connective. Each anther lobe in turn bears two pollen chambers or pollen sacs. Each pollen chamber represents a microsporangium. Thus, a typical dithecous anther comprises of four pollen sacs or microsporangia.

In some plants, such as Moringa and Wolffia, each anther lobe has only one microsporangium. Such anthers are called monothecous.

 A very young anther comprises of a homogenous mass of cells bound by a well-defined epidermis. During its development the anther assumes a four-lobed, and rows of hypodermal cells become differentiated in each lobe by their larger size, radial elongation, and more conspicuous nuclei. These form the archesporium.

The archesporial cells divide in a plane parallel to the outer walls of the anther lobe (periclinal division) to form a primary parietal layer toward the outside and a primary sporogenous layer toward the inside.

The cells of the parietal layer undergo a series of periclinal and anticlinal divisions to form 2-5 concentric layers composing the wall of the anther. The primary sporogenous cells either directly or after a few divisions, function as microspore mother cells.

Each anther at maturity consists of sporogenous tissue covered by an anther wall.

Anther Wall:

The anther wall consists of epidermis, endothecium, middle layers and tapetum

Epidermis:

It is the outermost layer of the anther, it is one celled thick and useful for protection. The epidermal cells undergo repeated anticlinal divisions in order to cope up with the enlargement of the anther.

The epidermal cells present between the pollensac are thin walled and constitute ‘stomium’ which is useful for the dehiscence of pollen sac. The stomium degenerates by the time the spore mother cells undergo divisions.

Endothecium:

The layer of cells lying immediately beneath the epidermis is the endothecium. Its maximum development is attained at the time when the pollen grains are about to be shed. The cells are radially elongated and from their inner tangential walls thickened fibrous bands develop. These thickenings are hygroscopic.

The presence of fibrous bands, differential expansion of the outer and inner tangential walls, and the hygrospic nature of the endothecial cells help in the dehiscence of anthers at maturity.

Middle Layers:

Next to the endothecium there are usually one to three middle layers. They are ephemeral in nature and are crushed during meiosis of pollen mother cells.

Tapetum:

The innermost layer of anther wall is called as tapetum which of considerable physiological significance, for all the food material entering into the sporogenous cells must pass through it. The cells of tapetum are large, with thin cell walls, abundant cytoplasm and prominent nuclei.

Based on behaviour, the tapetum is of two types:

1.     Amoeboid ( also called invasive or periplasmodial):

This type of tapetum is characterized by breakdown of the inner and radial walls of the tapetal cells. The protoplasm moves or protrude into the anther cavity, where they coalesce to form a continuous mass called the tapetal periplasmodium, closely investing the pollen mother cells or the microspores.

This type of tapetum is found in Alisma, Butomus, Tradescantia,Typha

2.     Secretory or Glandular :

In this type, the tapetal cells remain in their position throughout the microspore development. Subtances are contributed by secretion from the inner faces of the cells. Toward the close of the meiotic divisions in the microspore mother cells, the tapetal cells begin to lose contact with each other and finally cells are entirely absorbed at the time when the microspores begin to separate from one another.

This type of tapetum is common occurrence in angiosperms

A common feature of tapetum , amoeboid as well as secretory is the presence of more than one nucleus.

The tapetum plays a significant role in the development of pollen. Tapetum stores starch and protein during early stages of anther development and such tapetal reserves are used by pollen grains. During post-meiotic period, tapetum exhibits nutritional value in concern with the pollen wall formation.

During meiosis it transport the nutrients to the inside of the anther locule since tapetum is the only channel through which material can reach the meiocytes.

 

Sporogenous Tissue:

The tissue present inside the anther wall is called sporogenous tissue. It is diploid in nature. The sporogenous cells may directly function as microspore mother cells or pollen mother cells  or they may undergo a few mitosis to add up to their number before entering meiosis.

Each pollen mother cells by a meiotic division, give rise to a group of four haploid microspores or pollen tetrads. Cytokinesis during the meiotic division is of two types in the pollen mother cells, they are –

1.     Successive type : the nuclear divisions are accompanied by wall formation. After the first meiotic division a wall is formed separating the two nuclei. This leads to the formation of a dyad. After second division walls are again fomed resulting in a tetrad.

2.     Simultaneous type : in this type of cytokinesis, the first meiotic division is not followed by wall formation. Consequently, binucleate cell is formed after meiosis – I; there is no dyad stage. The two nuclei synchronously undergo the second meiotic division. The walls are formed after the second meiotic division, giving rise to a tetrad.

After the completion of the meiotic division in the microspore mother cell, different types of tetrads are formed. These are –

i.  Tetrahedral type: this type of arrangement is associated with simultaneous type of cytokinesis in the pollen mother cell. In the tetrad three microspores are seen in one surface while the fourth one appears on the backside.

ii.     Isobilateral type: four microspores are arranged in the four corners of the square. All the four spores are visible in the same surface. This is formed due to successive type of cytokinesis in the microspore mother cell. E.g., Zea mays.

iii.   Decussate type: microspores are arranged in two pairs. One pair of microspores is at right angles to the other. E.g., Magnolia, Atriplex

iv.    T Shaped type: two microspores are arranged side by side, while the other two appear one above the other. Thus, giving a T shaped appearance. E.g., Aristolochia.

v. Linear type: four microspores are arranged one above the other in a single row.

Usually, the microspores soon separate from one another but in some plants they adhere in tetrads to form the so called ‘compound‘ pollen grains. In the Mimosaceae there are larger units composed of 8 to 64 cells and in genera belonging to the Asclepiadaceae all the microspores in a sporangium remain together to form a single mass called the pollinium.

 Development of Male Gametophyte:

In angiosperms, the microspores represent the beginning of the male gametophytic generation. It is the first cell of male gametophyte.

They possess a haploid nucleus and dense cytoplasm. Soon after it’s release from the tetrad the microspore or pollen grain rapidly increases in volume and accompanying formation of a vacuole. The nucleus is displaced from the centre to a place adjacent to the wall.

The first division of the microspore gives rise to the vegetative and generative cells. The generative cell is small and lens shaped.

Pollen grains are usually dispersed from the anther in 2-celled condition. In certain plants the generative cell divides in the pollen grain while it is in the anther itself giving rise to two male gametes or sperm cells. The pollen grains are thus 3-celled condition in these plants.

The pollen grains or male gametophyte reach the stigma either in 2-celled or 3-celled condition, through various pollinating agents.

By absorbing water available in the exudates of stigma, the pollen germinates and the intine of the pollen grain comes out and forms a pollen tube. Generally only one pollen tube develops from a pollen grain (Monosiphonous). But in Malvaceae and Cucurbitaceae more number of pollen tubes may form from a single pollen grain (Polysiphonous).

The vegetative and generative nuclei enter into the pollen tube along with cytoplasm. The vegetative and generative cells change their position during their travel in the pollen tube. The generative cell undergoes mitotic division and two haploid male gametes are formed. This is called as spermatogenesis as the male gametes are equivalent to the ciliated sperms of the lower groups of plants.

 Nemec Phenomenon or Embryo sac like pollen grains:

Normally, the number of nuclei in a mature pollen grain is two or three. Occasionally, grains with more nuclei resulting in abnormal type of the male gametophyte occurs. In 1898 Nemec noted that in anther of Hyacinthus orientalis the pollen grains some time form large eight nucleate structures showing a resemblance to embryo sacs.

He believed that they arose as the result of degeneration of the generative nucleus and three divisions of the vegetative nucleus.

The microspores increase in size to form large sac-like bodies. Later the nucleus undergoes three successive divisions to form 8 daughter nuclei. Of these, 3 lie at the end where the exine is still intact, 3 at the opposite end and 2 in the middle. Cells found at the exine end represent egg and synergids, the opposite end nuclei form the antipodals. The tow central nuclei represent the polar nuclei.

 

Androgenic Embryoids (Haploid plants)

Guha and Maheshwari working with anther cultures of Datura innoxia reported that embryo like structures called embryoids develop from the pollen grains. The embryoids give rise to haploid plants.

The anther is excised from the flower bud of Nicotiana and cultured on a suitable medium. Pollen grains inside the anther by repeated divisions form a multicellular tissue within the parent wall. Ultimately the pollen wall bursts, releasing the tissue mass. This tissue mass is capable to grow directly into an ambryoid and germinates to from a haploid plant.

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