puccinia: structure,lifecycle

puccinia:

Kingdom                 : Mycetae

Division                   : Amastigomycotina

Sub division            : Basiomycotina

Class                        :  Basidiomycetes

Sub class                 : Teliomycetidae

Order                       : uredinales

Family                     : pucciniaceae

Genus                      : puccinia         

occurrence: 

• the genus Puccina causes rust diseases of many of mans economic plants like barley, wheat, Oats, etc. the name puccina has been given to the genus after  T. Puccini<, an Italian scientist. It is called rust because of the reddish brown color of the spores that are found chiefly upon the surface of the host leaves and stem.
• The most important of all the rusts is P. graminis which causes black stem rust of wheat. It causes the most serious damage to the wheat crop. It is an internal obligate parasite & is found everywhere wheat is grown.
• It is heteroeious, i.e. Requires two host (triticum vulgare) and barbery (Beta vulgaris) to one normal life cycle. Mycelium of one host is unable to grow on the other, and the full life cycle only when  both the hosts are present. The wheat plant is called the primary host and the barbery the secondary or alternate host.
• It is macro cyclic & polymorphic rust, in which life cycle involves five spore forms, each with a different function. The different spore form follows one another in a definite sequence within a life span of one year.

• Vegetative structure: 

• mycelium is well developed and consists of septate and intercellular hyphae, obtthe myaining the nourishment by sending small, round or branced haustoria into the host cells. There is single central pore in each spectrum for the protoplasm communication from one cell to another. The hyphae do not ramify throughout the interior of the host but are restricted to isolated patches on the organ attached.

during the life cycle two types of mycelia are produced, the monokaryotic mycelium found in the alternate host & the dikaryotic mycelium in the primary host.
 

LIFE CYCLE OF FUNGUS:

Uredo stage: 

• the wheat plant becomes infected by aecidiospores which are produced by the fungus on the alternate host (barbery leaf). These aecidiospores are blown off by wind & can infect only the wheat plants. Since the aecidiospores are biuncleate it gives rise to binucleate mycelium (dikaryotic). The hyphae produced ramify through the host tissue, forming haustoria that draw nourishment from surrounding cells of the wheat plant but do not kill them. In the early summer the mycelium leads to the formation of elongated, rust & reddish brown streaks or pustules termed as uredopustules or uredorus on the stem and leaf sheath. This is developed from a mass of dikaryotic hyphae which collect below the epidermis of the host. From the base of the uredosori arise specialized hyphae the sporophores which bear at their apices oval, thick walled brown uredospores. The epidermis of the host plant becomes ruptured by the pressure of the underlying uredospores forming elongated, rusted reddish brown pustules.
• Each uredospore is stalked, broadly ovoid, brown & finely echinulate. It has four germ pores. The uredospores formed are flown by wind currents & carried to other wheat plants where they germinate to produce new crop of uredospores.
• Germination of uredospore within 4-5 days the uredospore germinates producing germ tube, the germ tube does not enter the host tissue directly. It grows over the surface of the epidermis & on reaching stoma, the tip swells up to form an elongated ‘appressorium’. The protoplast of the germ tube migrates into the appressorium & the empty germ tube is cut off from appressorium by cross wall. The appressorium gives rise to a fine branch that passes through the stomata & swells to form a substomatal vesicle from which arise one or more hyphae which ramify through intercellular spaces of the host tissue producing much branched mycelium made up of binucleate cells.
• The uredospores are also called repeating spores because they are produced in successive crops in a season causing widespread infection from plant to plant throughout the field.

• Teleuto stage: 
• letra in summer, after the host plant matures, the same mycelium that gave rise to uredospores now begins to give rise to teliospores or teleutospores. They are produced in the same pustule or develop new pustules termed as teleutosorus or teleutopustules. These telia form elongated, dark brown to black ustules on the stem & leaves of the host plant. Teleutospores are dark brown to black pustules on the surface of the stem & leaves of wheat & it has resulted in the common name black stem rust of wheat for this fungus.
• The teleutospores are stalked, dark brown to black in color, thin walled & two celled, each cell containing a pair of nuclei. The apex of each teleutospore is round or sometimes pointed. Each cell of the spore has a germ pore. The germ pore is situated apically in the upper cell, while in the lower cell; it lies just below the septum.
• When the spore is mature the two nuclei fuse resulting in diploid nuclei each cell. The teleutospores are not capable of immediate germination. It germinates only in the spring.

Basidial stage: 

• during the early spring the teleutospores germinate on ground. Under favourable conditions each cell of the teleutospores forms an elongated germ tube like structure called promycelium (epibasidium). The diploid or fusion nucleus of teleutospores migrates into the promycelium where it undergoes meosis & forms. 4 haploid nuclei each of which later forms into the baisdiospore nuclei. Each basidiospore is stalked (sterigmata). Each promycelium gives rise to four basdiospore 2 of + & 2 of –ve strain. Basidiospores infect only barbery.

Pycnidial or spermogonial stage:

•  in the presence of moisture the basidiospore germinate on the surface of the barbery leaf forming a slender germ tube. The germ tube penetrates into the epidermis directly & there it branches freely forming haploid monokaryotic mycelium of either + or –ve strain depending on the Basidiospores strain.
•  Many basidiospores land and infect the same barbery leaf so that both + & -ve mycelia are developed side by side in the barbery tissues.4 days after infection of the host the monokaryotic mycelium branch & grow vigorously between epidermis & the palisade to form dense mat. There are primordial of pycnia (spermogonia).These are seen as yellow or red patches on the leaf surface.
• In addition to the formation or pycnia primordial few monokaryotic mycelium grow towards the lower epidermis & form structures called ‘aecia primordial’. These mycelium do not develop further unless & until it is dikaryotized.
• The spermagonia may be+ or  -ve depending on the mycelium from  which it arises. A mature spermogonium is flask shaped with an opening called ostiole.
• At the base of the spermoginal cavity pseudo parenchymatous mass of uninucleate cells are present from which arise number of elongated uninucleate spermatiophores. Spermatiphores gives rise to pycnidiospores(spermatia) in chains.they ooze out on the leaf surface in small droplets of nectar through the ostioles.other than spermatiophores thin hyphae arise which are long & protrude out from the  ostiole which is the receptive hyphae(female gametangia).spermatia act as male cells.
• Insects like flies are attracted to the leaf by sugary necter. Some spermatia stick to the leg & proboscis of the visiting insects and thus are carried from one pycnium to the receptive hyphae of other pycnia. If a pycniospore of one strain comes into contact with a receptive hyphae projecting from a pycnium of opposite strain or vice versa, they fuse and the nucleus passes into the receptive hyphae moves downward establishing dikaryon condition. The nucleus repeatedly divides  & the resulting nuclei pass through pores in the hyphae cross walls.

Aecidial stage: 

• Each aecium primordium, which has been previously formed on the lower surface of the host leaf by the same mycelium that gave rise to spermogonium on the upper surface of the leaf, consist only of an upper closely packed weft of uninucleate hyphae the basal cells & a lower group of parenchyma like cells.
• Fusion of the spermatium with receptive hyphae is followed by migration of spermatial nuclei into the receptive hyphae & through septal perforation of the mycelium to the basal cells of aecial primoridia which thus became dikaryotized. Each binucleate cell has a + & a –  ve  strain nuclei. If due to any reason dikaryotisation fails, the protoaecidium aborts & the aecidial cup is not formed.
• The diakryotized (binucleate) basal cells are called aecidiospores mother cells or sporophores & from them are cut off terminally the chains of biuncleate spores the aecidiospores, alternating with sterile cell or disjunction cells. The neighboring marginal  at the base of the aecidium divide & form the pridium which surrounds cells in aecidium.
• The aecidial cup remains partly embedded in the leaf tissue & partly projects above it. The edge of peridium bends upward & a bell shaped structure is formed. They appear on the lower surface structure of the infected leaf as white cups, filled with golden yellow powder of spores. The developing aecidium exerts pressure on the leaf tissue & rulptures the peridium as well as the lower epidermis & as a result, the exposed binucleate aecidiospores fall from the aecidium.
• These aecidiospores are unicellular, thin walled. Polyhedral in shape & areunable to reinfect barbery but it infects only the wheat plants repeating the life cycle.

algae:economic importance

algae:economic importance

• Algae are important in the field of agriculture and industry in addition used as food, fodder and manure.

beneficial aspects

A)algae as food:

• Algae are important as a source of food in some coastal parts of the world.
• In the pacific islands the red,brown and green algae form a regular portion of diet.
• In india spirogyra and oedogonium are dried and used in soup preparations.
• In Europe ulva is used for soup preparation.
• The colonies of nostoc are boiled and used as food in brazil.
• Porphyra a red algae is considered a taste ful dish in England and it is common diet in korea,japan and china.
• It is rich in vitamin b and c.
• Seaweeds like porphyra tenera(red alga) and laminaria(brown alga) are consumed by the coastal people of china and japan.
• Caulerpa racemosa(green alga) is cultivated in Philippines as a source of food in japan about 25% of the daily diet consists of seaweeds.

B)algae as fodder:

• In Norway,france,usa,Denmark and new Zealand,seaweeds are used as fodder for animals.
• In great Britain,france,Scandinavia and pacific coasts of usa,kelps are chopped for sheep and chicken.
• Some countries have even developed small industries for processing the weeds such as ascophyllum,focus and laminaria into suitable cattle feed.
• The processed food is given to cattle,poultry and pigs. A red alga rhodymenia is used as a cattle fodder in france.

C)role of algae in industries:

• Algae are useful as a source of many commercial products.
• The major products commonly derived from them are 1)agar agar,2)carrageenin,3)alginic acid and 4)diatomite

1)agar agar:

• It is mucilage produced by certain red algae and stored with cellulose in the cell wall.
• Main sources of agar aaagar are:gelidium,gracilaria,gigartina
• Other sources of agar agar are camphylaephora,hypnea,furcellaria
• Agar agar is a gelatinous,clear,nitrogen free extract from the above mentioned genera of red algae.
• This extract is a solid which melts between90 to 100 f at lower temperature it changes back to a solid.
• Uses:preparation of foodstuffs.
• Forms a base for culture media for bacteria,fungi,algae and other tissues.
• Preparation of certain medicines,cosmetics,leather and textile industry

2)alginic acid:

• Algin is a carbohydrate which occurs in the middle lamella and primary walls of a few seaweeds.
• The soluble calcium of alginic acid is known as algin.
• The insoluble extract is alginic acid.
• The salts of alginic acid found in the cell walls of the algae are called alginates
• Sources:ascophyllum,laminaria,lessonia,macrocystis
• Uses:used as thickness in food industry cosmetics and textile industry
• Used in preparing plastics and artificial fibers
• Also used in rubber industry
• They are of great value as emulsifiers,as gelling agents of confectionaries,paints and ice creams.

3)carrageenin:

• it is cell wall polysaccharide and is a mucilaginous extract.
• Source:a red alga chondrus crispus
• Uses:in food,textiles,pharmaceuticals,leather and brewing industry used as a component of toothpastes,deodorants,cosmetics and paints.

4)diatomite/kkieselguhr:

• it is a rock like deposit formed from the indestructible siliceous frustules of the the past diatoms that had collected over many millions of years on the floor of the sea to form organic sediments.
• These diatomaceous earth which is put to several commercial uses.
• Property:it is a white substance firm but usually soft and light.
• It is highly porous and insoluble.
• It has abrasive qualities,is chemically inert and is fire proof.
• Uses:used as filters for oils and other solutions in industry
• Used in insulations of refrigerators,boilers,hot and cold popes.
• Sound proof rooms and in furnaces.
• Used in polishes for metals.
• Used in manufacture of dynamite.
• Used as a constituent of some tooth powder and bleaching powders.

D)role of algae in agriculture:

•  the seaweeds,mostly brown and red algae are used as organic fertilizers
• They are richer in potassium but poor in nitrogen and phosphorus than the farm manureturbinaria is used as a fertilizer around palm trees.
• Concentrated liquid extracts of sea weeds are sold as liquid fertilizers as also insecticides.
• The seaweed products aid in binding sandy soils ass well as in the breakdown of clayey soils.

E)role of algae in medicines:

• Many seaweeds contain a high percentage of iodine contents and are thus used in the preparation of various goitea medicines.
• Chlorellin an antibiotic is obtained from chlorella.
• Agar agar forms the basis of many medicines used as laxatives.
• Carrageenin extract acts as a blood coagulant.

F)role in algae in sewage disposal

• Sewage consists of many domestic and industrial wastes.
• It contain many organic and inorganic constituents in dissolved or suspended stage.
• The disposal of this sewage is mainly an aerobic process and this oxygenation is facilitated mainly by some algae e.g. chlamydomonas,chlorella,euglena,scenedesmus etc.
• The aeration of sewage is essential,especially in smaller sewage bodies or ponds to avoid unpleasant odour.

G)algae and soil conservation:

• Soil conservation is effected by algae to a great extent.
• After rains,the members of chlorphyceae develop and check soil erosion on disturbed on burned soils.

   Negative aspects

A)role in water supply:

• Algae grow luxuriantly in water.
• Reservoirs meant for domestic water supplies.
• They produce bad tastes in drinking water and also interfere with the filtration process of water.
• Common algae found in reservoirs of water supply are chlamydomonas,volvox etc.
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riccia (liverworts):habit,structure,reproduction,fertilization

riccia(liverworts):

Classification:

Division: Bryophyta

Class: hepaticopsida (liverworts)

Order: marchantiales

Genus: Riccia

Species: Fluitans (only floating sp.) natans, discolor.

Habitat

·         Riccia is cosmopolitan (worldwide) genus.

·         ~130 species known, 22 found in India.

·         Only R.fluitans is floating sp. Rest all are terrestrial.

·         It grows on damp soil-rocks, under shade (mostly).

·         Habit/structure.

1.       Gametophyte       2. Sporophyte

1       1)Gametophyte:

§  Plant body is thallus.

§  Prostate

§  Dorsiventral, ribbon like

§  Dichotomously branched

§  May from rosette form

§  Thickened midrib present

·         Midrib found on dorsal surface formed by `median longitudinal furrow’.

·         Growing point is `apical notch’.

·         Ventral surface has rhizoids & scales.

  è  Rhizoids: elongated hair like structure act as root, unicellular.

Function: 1. Attach thallus to substratum.

2.       Absorb water & food from soil.

       Types: 1) smooth walled

2                       2)   Tuberculate

  è               :  scales:violet color on ventral side present on both edge of thallus multicellular work as anchor. Covers/protects growing apex of thallus at tip.

Internal structure (anatomy)

·         Thallus shows internal tissue differention.

·         In transverse section, it appears elliptical shape.

·         Storage zone: lower/ventral region of thallus-has compact colorless, parenchymatous tissue. No intercellular spaces. Chlorophyll absent, starch present.

·         Photosynthetic zone: upper/dorsal region of thallus has vertical rows of chlorophyll us cells. Narrow vertical air chambers present.

§  It is photosynthetic zone.

§  Rhizoids are present on ventral side.

§  Scales are also present in two rows on ventral side.

§  Apical growth: The tips of thallus contain 3-5 apical cells.

§  Thallus hence grows apically.

Reproduction

  è                    vegetative reproduction

·         By progressive death and decay of old parts of thallus, the growing dichotomous branch splits into two, hence two new growing thallus is made.

·         Adventitious branch arise from ventral surface of thallus, separation of these branches results in formation of new thalli.

·         Apex at the end of growing season grows down into the soil and became thick. At favorable season it starts growing back.

·         New thallus may be produced from the apex of a rhizoid.

·         At end of growing season, thalli may produce tubers.

·         Tubers will grow new thallus at end of unfavorable season.

  è                      sexual reproduction

·         Antheridia (male sex organ) and archegonia (female sex organ) may grow on some thallus (homo thallic/monoencious) or on separate thalli (heterothallic, dioecious).

·         No distinct morphological difference between male and female spores.

·         Sex organ are develop singly on the dorsal surface of the thallus within median longitudinal furrow extending backwards from the growing point.

·         Sex organs arise superficially on the floor of dorsal furrow of the thallus. At it matures, up growth of surrounding vegetative cells surrounds it.

·         Hence it becomes embedded in tree.

·         Each sex organ comes to lie at the bottom/ventral of the individual cavity.

·         Cavity is known as `anthredial chamber’.

       

the mature antheridium:

stalk:short,few celled,attached to the base of the antheridial chamber.

oval body:

• flat base,rounded/conical apex,covered by sterile jacket layer cell.
• inside jacket is single layer of cell which produce androcytes.

• androcytes produce two antherozoids(male sperm).

     

Archegonium:

• Chamber is surrounded by narrow cylindrical canal,archegonium chamber in cylindrical canal,distal portion of neck projects beyond archegonial chamber.
• The mature archegonium
• Archegonium is flask shaped,with long neck.
• Attached to the tissue of thallus by short stalk.
• Basal swollen portion=venter.
• Elongated slender=neck.
• Neck is single cell layer tube.has 6-9 tiers of elongated cells arranged in 6 vertical rows=makes narrow canal(tube).
• Canal is occupied by one raw of 4 neck canal cells.
• Upper part of neck is made of 4 enlarged neck cover cells.
• Venter is one cell layer cover,which enclose naked egg and a small venter canal cell.
• When archegonium is fully mature neck canal and venter canal cell dissolves and makes mucilaginous mass.
• Fertilization(syngamy)
• By help of water,jacket layer of antheridium breaks and release all anthrozoids in water droplets.
• By help of water,4 neck cover cells swell up and breaks neck is hence free for anthrozoids entry.
• anthrozoids get attracted by sugars in mucilaginous mass in neck and reaches to egg.
• egg(n) gets fertilized by  one single anthrozoids(n).

• it produces diploid(2n) zygote.

sporophytes

• protect growing sporogenium.stage of life cycle from zygote to formation of spores is known as sporophyte(2n).
• zygote secreates its own cell wall.
• venter becomes layers of many cells known as embryo.
• at stage 20-40 cell spherical mass is formed.
• from this stage outer layer cells:amphithecium.
• and inner cell mass is:endothecium.
• amphithecium:makes sterile jacket.
• endothecium:archesporium(fertile).
• means first cell generation of the sporogenous tissue.
• they divide several times to make mass of sporogenous cells:spore mother cells.
• some of these cells die to give nutrition to developing spore,known as 'nutritive cells'.
• each of spore mother cells(2n) divide by meiosis(reduction division) and produce 4 cells.
• known as spore tetrad(4 spores) 
• each of these 4 spore will be dispersed when sporophyte breaks.
• no special mechanism adapted by riccia for dispersal.

after a year when favourable condition of moisture comes spore(n) germinate into either male or female gametophyte(n).

fungi:general character and structure

fungi:

•   Fungi are a large group of achlorophyllus organisms.
•  Study of fungi is called as ‘mycology’ and scientist concerned with fungi called as‘mycologists’
•     it is non-green , nucleated plant body.
• *      Habitat: it grows almost everywhere on earth, where dead or living organic material is present. 

• General characters and introduction to fungi:

• ·   They lacks chlorophyll so cannot make their own food, so they are “heterotrophs”.

  ·      They cannot ingest solid food but can absorb through cell membrane as saprophytes or parasites.
• a)  Saprophytic fungi: which grows where dead organic matter abounds in the substiatum.
  b) Parasite: which live in or on the living bodies of other living organisms and obtain food from them.
  §  Parasitic fungi may cause harm to the host on which it is surviving which is called as disease.
  §  Ectoparasite: - thallus of parasitic fungus may grow on the external surface of the host.
  §  Endoparasite: - where thallus of fungi grows in the tissue of the host plant.
  §  Obligate parasite: - which can grow only upon suitable living host tissues.eg: downy and powdery mildews.
  §  Few fungi also develop symbiotic reaction with green or blue-green algae and form lichens.
  §  Another example is mycorrhiza, where fungus establishes a relationship with the roots of certain higher plants. e.g.: pinus roots and fungal hyphae. Where hyphae performs as a root hair and helps in absorption of water and minerals from soil. While tree provides food and shelter for fungus.
• 
  
• Habit or structure of fungi
• a.  Thallus
                          i.               Unicellular thallus- in some lower fungi, thallus is more or less a spherical, single-celled structure. e.g. yeast cell.
                       ii.               Filamentous thallus- majority of fungi are filamentous
  ·      After germination of spore, it give rise to a fluffy thallus consisting of a cottony mass of branched or unbranched filaments called as hyphae.
  ·      Hyphae are usually colorless and embedded in substratum. Hyphae or mycelia can be multinucleated, colorless, septate or aseptate.
  ·      Hyphae comprise the vegetative body of a fungus, called as mycelium. So, hyphae are a structural unit of a mycelium.
  ·      If mycelium is aseptate, multinucleated called as coenocytic. Septate mycelium develop internal cross walls called the septa, which divide the hyphae into segments.
  ·      It can be uni or multinucleated.
  ·      Septa can be oblique, longitudinal, or transverse.
  Ø P.A. micheli (1679-1737) is referred as “father of mycology”, who published book named “Nova plantarum genera”.
  Ø Sir E.J. Butler put the firm foundation of mycology and plant pathology in India. He authored a classic book “fungi and disease in plants”. He is referred as “father of Indian mycology”.

  *      Structure of the fungal cell:

  §  It consists of strong, rigid cell wall enclosing protoplast.
  §  Cell wall is made up of chitin which is also called as “fungal cellulose” because it is different from insect chitin ( polysaccharide based on ‘N’ contain sugar.)
  §  In lower fungi, some flagellated oomycetes consist of ‘cellulosic wall’.
  §  Chitin wall of fungi is permeable both to water and substance in true solution.
  §  Protoplasm which lacks chloroplast, but other than that it consist of cell membrane, vacuole, cell organelles and oue or more nuclei.
  §  All fungi group lacks motile cells in the life cycle. Except some lower fungi where they possess whip-like threads known as flagella.
  “ Aggregation & modification of the hyphae”.
  §  Fungal hyphae are interwoven loosely to form mycelium.
  §  Aggregation of mycelium in different ways makes mycelium.
  
  
  1.  Plectenchyma /Prosenchyma
                        \Pseudo parenchyma
  a)  Prosenchyma- Run more or less parallel to one another & composed of elongated cells.
  b) Pseudo parenchyma- Hyphae gets fused & lose their individuality and forms isodiametric oval cells.
  2.  Rhizomorph-  thick strand or root like aggregation of somatic hyphae is called rhizomorph.
  3.  Other than that other structures like sclerotic, stomata, haustoria etc. forms in different fungi.
  
  
  
  
  
  
    

diatoms(algae)

Diatoms:algae

division:chrysophyta/bacillariophytaclass:baccillariophyceaegenus:diatoms

• pigment diatomin present(golden brown)algae
• diatoms are classified into 2 orders on the basis of their symmetry.

order 1:pannales

it shows bilateral symmetry

order 2:centrales

it shows radial symmetry

occurence:

• found in aqutic environment both fresh water and marine water.
• some occur as planktons.
• some species are found in terrestial habitat.
• some species are epiphytic on other algae.

thallus structure

• diatoms are unicellular algae,the cells may sometimes get ambeded in a common gelations matrix to fodrm simple colonies.
• the cell wall shows the deposition of silica.
• cell wall is made up of 2 overlapping theca,the smaller fitting into the larger.
• it is called as frustuies.
• the outer/upper half is the epitheca and inner/lower half is hypotheca.
• each theca has 2 main parts.
• 1)valve:a more or less flattened plate like structure the surface of the theca.
• 2)the connecting band(cingulum):the incurved margins of the valves.it form girdle.
• when the frustules lies in such a way that upperside/lowerside/valveside is seen it is called as valve view or top view and when connecting bands are uppermost it is called girdle view/side view.
• frustules is made up of pectin.in valve region,frustules is silicified.
• this siliceous material is laid down in certain pattern that makes the wall ornamented.
• in pinnate diatoms,ornamentition is symmetrically that arranged on either side of the central line.in the middle of theca there is a longitudial slit called 'raphe'.
• raphe extends form one end to the other end.
• each pole the raphe terminated into a  swelling called as 'polar nodule'.
• raphe is interrupted at the mid point by a swelling called central point by a swelling called central nodule.
• protoplast is surrounded by plasma membrane.inside is a thick layer of cytoplasm surrounding a large central vacuole.
• the cells are uninucleate,oval or spherical nucleas embedded in the pariential cytoplasm.
• chloroplast are large pariental plate like arranged parallel to each other.
• movement occur through gliding.

vegetative reproduction 

• occurs by cell division.
• before the cell division,the protoplast of the cell increases in size pushing away epitheca from hypotheca.
• the nucleus divides mitotically followed by division of protoplast into two daughter cell produces a new hypotheca.
• the daughter cell which has the epitheca nearly of same size as that of the parent cell is nearly of same size as that of the parent cell.

asexual reproduction

• it takes place by means of auxospore.
• by continuous multipliction by cell division there is reduction in cell size in the successive generation.
• the reduction can continue only upto certain limit and beyond this limit either the cell die or convert into an auxospore.
• in auxospore formation,the original size of cell is restored.
• the cell secretes a large amount of mucilage which pushes the 2 valve apart.thus the protoplast is set free.
• it grows in size and attains the normal cell size.
• then it secrets around itself a silicified membrane'perizonium' new valves are secreted inside and auxospore becomes an independent cell.

    sexual reproduction 

• mostly homothalic,isogamous in pennate diatoms.
• this process occurs when the cell is reduced to a certain critical point after the cell division.
• two such cells come close to each other and get enveloped with in a common muucilaginous mass.
• the diploid nuclei of thes cells undergo meiosis and produces 4n nuclei.
• out of 4 nuclei in a cell,2 degenerates and thr another two remain function.
• the protoplast of the cell divides in 2 segments, each carrying a single haploid nucleus.
• two gametes from different cell fuse to form a zygote.
• the two zygote formed will grow in size to from auxospore.
• the auxospores secretes a perizonium layer and siliceous valve are formed.

  life cycle

•  life cycle is diploid predominant.
• the vegetative cell is diploid.
• the haploid phase is represented only by gametes formed by meiotic division of diploid cells.
• these gametes fuse to form zygotes which are diploid.
•   

funaria(moss),bryophyta

funaria(moss)

Classification:

Divinsion: Bryophyta

Class: bryopsida (moss)

Order: Funariales

Family: Funariaceae

Genus: Funaria

Species: Hygrometrica

Habitat

• It’s very common moss, widely distributed throughout the world.
• ~117 sp. Worldwide
• 15 sp. In India
• It usually grows on group as close tufts, frequently on recently burnt land where ashes of plants are present.
• Also found on rocks, walls or crevices as mats.

·         Structure of gametophytes :

·         Gametophyte shows two distinct phases.

1.       Protonema= prostrate filamenous, alga- like structure.

2.       Gametophores= upright leafy persistent moss plant.

·         Gametophores are about 1.3 cm high.

·         Consists of slender, erect, radial stem covered with small, simple leaves.

·         Stem: monopodially branched, branches grow as erect structure.

·         At the base of gametophores numerous-branched-slender, multicellular rhizoids are present.

·         Leaves: spirally arranged, 3/8 phyllotaxy ovate shape, attached to stem by broad base.

Lower leaves are smaller-scattered upper/young leaves are larger and crowded at the tip of stem.

·         Internal structure:

1.       Stem: well differentiated tissues present.

·         3 parts =

a)      Central cylinder

b)      Cortex

c)       Epidermis

.                  Central cylinder: consists of long, narrow, thin walled cells, protoplast absent.

              Cortex: it covers central cylinder, cells contain chloroplast thicker & reddish-brown cells in outer        region, thin walled cells towards inside.

C.              Epidermis: one cell layer, contain chlorophyll, stomata absent.

2.       Leaves:

• ·         Well defined midrib present.
• ·         Wing (blade) on either side of midrib is single cell layered.
• ·         In centre of midrib, narrow thin walled conducting strand is present.
• ·         Blade on either side contains polygonal cells with numerous large chloroplasts.
• ·          Chloroplasts here continue to multiply even after cell division, hence this leaf cells are used for chloroplast related studies.

Reproduction

• ·         It happens only through sexual mode of reproduction.
• ·         F.hygrometrica is monoencious & or autoecious (male and female are separate branches of same plant).
• ·         The main shoot (apex) bears a group of antheridia at tip = male branch female branch develops later as lateral branch grows higher than male branch.

Antheridia (male)

• ·         Short massive stalk, body ~0.25 mm club shaped body.
• ·         Jackets contain chloroplasts at young and turn orange while mature.
• ·         Tip of body contain 2-4 cells of thick wall known as operculum cells.
• ·         Central parts contain antherozoids.

·         Paraphysis: hair like strive structure present around antheridia cluster.

• ·         It fuctions for providing moisture to antheridium and also photosynthesis.
• ·         Release of antheridia tnakes place by presence of water.
• ·         Operculum cell breaks and antherozoids are released.

Archegonia (female)        

• Multiple archegonia develop on female branch at tip.
• ·         Leaves surrounding it known as “perichaetial leaves”.
• ·         Within these leaves it presence of numerous archegonia surrounded by Paraphysis.
• ·         Mature archegonia has-long massive stalk.
• ·         Jacket is double layered.
• ·         Neck is single layered. Have ~6 neck canal cells. Slightly enlarged ventral canal cell.
• ·         Inside chamber, will be presence of egg cell.
• ·         At maturity, neck canal cells and Vcc disintegrate and form mucilaginous mass cover cells are removed leaving passage for antherozoids.

Sporophyte

  è                     mature sporogonium is composed of:

1.       Foot

2.       Seta

3.       Capsule

1)      Foot: foot is poorly developed small, dagger-like conical structure embedded in apex.

·         It only contains parenchymatrus cells.

2)      Seta: seta is long, slender, twisted structure.

·         It’s strand like structure which conducts water and food from thallus through foot and supply to the developing capsule.

3)      Capsule: capsule is present at tip of seta.

         i.            Apophysis: its lower most portion of capsule.

·         Contain central strand of ending seta.

·         Surrounding seta, it has chloroplast containing photosynthetic cells is which provide food to growing capsule.

·         Outer most layer of cells which is epidermis which covers whole capsule. Only apophysis region, epidermis contains stomata.

       ii.           heca: urn-shaped, middle fertile region of capsule.

·  spore   sac has:

a.       Outer spore sac wall

b.      Inner spore sac wall

c.       Spore sac

·         Central region is made of sterile strong cells = columella which provide mechanical strength to capsule.    It has 2 layered hypodermis, spore sac is surrounded by air space connected to rest tissues by trabeculae.

• Diatoms(algae)

      iii.            Operculum: cap-like structure placed on theca.

·         Contain annulus & peristome.

·         Through this structure, spores are dispersed.

·         Capsule here dehisce by work of hygroscopic peristome.

·         During presence of moisture, the peristome opens operculum and spores come out from spore sac.

·         Spore germinates during favorable condition to give rise to either male/female gametophyte.