BIOFERTILIZERS
Biofertilizers
are defined as preparations containing living cells or latent cells of
efficient strains of microorganisms that help crop plants uptake of nutrients
by their interactions in the rhizosphere when applied through seed or soil. They
accelerate certain microbial processes in the soil which augment the extent of
availability of nutrients in a form easily assimilated by plants.
Use
of biofertilizers is one of the important components of integrated nutrient
management, as they are cost effective and renewable source of plant nutrients
to supplement the chemical fertilizers for sustainable agriculture. Several
microorganisms and their association with crop plants are being exploited in
the production of biofertilizers. They can be grouped in different ways based
on their nature and function.
I. N2 fixers
a.
Free living
|
: Aerobic – Azotobacter, Beijerinckia, Anabaena
|
||
Anaerobic – Clostridium
|
|||
Faultative anaerobic – Klebsiella
|
|||
b.
Symbiotic
|
: Rhizobium, Frankia, Anabaena azollae
|
||
c.
Associative symbiotic
|
:
|
Azospirillum
|
|
d.
Endophytic
|
:
|
Gluconacetobacter
|
|
Burkholdria
|
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II. Phosphorus solubilizers
|
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Bacteria
|
:
|
Bacillus megaterium var. phosphaticum
|
|
B. subtilis, B.
circulans
|
|||
Pseudomonas striata
|
|||
Fungi
|
:
|
Penicillium sp.
|
|
Aspergillus awamori
|
III. P mobilizers
a) AM fungi
b) Ectomycorrhizal fungi
c) Ericoid Mycorrhiza
d) Orchid mycorrhiza
IV.
Silicate and Zinc solubilizers: Bacillus
sp,
V. Plant
growth promoting Rhizobacteria: Pseudomans
spp.,and many more
Biofertilizers are known to make a number of positive contributions in
agriculture.
•
Supplement fertilizer supplies for meeting the
nutrient needs of crops.
•
Add 20 –
200 kg N/ha (by fixation) under optimum conditions and solubilise/mobilise
30-50 kg P2O5/ha.
•
They
liberate growth promoting substances and vitamins and help to maintain soil
fertility.
•
They suppress the incidence of pathogens and
control diseases.
•
Increase
the crop yield by 10-50%. N2 fixers reduce depletion of soil nutrients
and provide sustainability to the farming system.
•
Cheaper, pollution free and based on renewable
energy sources.
•
They improve soil physical properties, tilth
and soil health.
1. Rhizobium
Rhizobia
are soil bacteria, live freely in soil and in the root region of both
leguminous and non-leguminous plants. However they enter into symbiosis only
with leguminous plants, by infesting their roots and forming nodules on them.
Non legume nodulated by Rhizobia is
Trema or
Parasponia sp.
The nodulated legumes contribute a good deal to the amount of N2
fixed in the biosphere, (50-200 kg N/ha) varied with crops.
Clover
|
-
|
130
kg N/ha
|
Cowpea
|
-
|
62 – 128 kg N/ha
|
Beijerinck
first isolated and cultivate a microorganism from the roots of legumes in 1888
and he named this as Bacillus radicola
and latter modified as Rhizobium.
Legume
plants fix and utilise this N by working symbiotically with Rhizobium in nodules on their roots. The
host plants provide a home for bacteria and energy to fix atmospheric N2 and
in turn the plant receives fixed N2 (as protein).
Cross inoculation group (CGI)
It refers the group of leguminous plant that
will develop nodules when inoculated with the rhizobia obtained from the
nodules from any member of that legume group
Genera/species
|
Principal and other reported hosts
|
|
Rhizobium
|
||
R.etli
|
Phaseolus vulgaris,
Mimosa affinis
|
|
Galega orientalis,
G.officinalis
|
||
R.gallicum
|
Phaseolus vulgaris,
Leucaena, Macroptilium, Onobrychis
|
|
R.giardini
|
Phaseolus vulgaris,
Leucaena, Macroptilium
|
|
R.hainanense
|
Desmodium sinuatum,
Stylosanthes, Vigna, Arachis,
|
|
Centrosema
|
||
R.huautlense
|
Sesbania herbacea
|
|
R.indigoferae
|
Indigofera
|
|
R.leguminosarum
|
||
bv trifolii
|
Trifolium
|
|
bv viciae
|
Lathyrus, Lens,
Pisum, and Vicia,
|
|
bv.phaseoli
|
Phaseolus vulgaris
|
|
R.mongolense
|
Medicago ruthenica,
Phaseolus vulgaris
|
|
R.sullae
|
Hedysarum coronarium
|
|
R.tropici
|
Phaseolus vulgaris,
Dalea, Leucaena, Macroptilium,
|
|
Onobrychis
|
||
Mesorhizobium
|
M.amorphae
M.chacoense
M.ciceri
M.huakuii
M.loti
M. mediterraneum
M.plurifarium
M.tianshanense
Sinorhizobium
S.abri
S.americanus
S.arboris
S.fredi
S.indiaense
S.kostiense
S.kummerowiae
S.meliloti
Amorpha fruticosa Prosopis alba Cicer
arietinum Astragalus sinicus, Acacia Lotus
corniculatus Cicer
arietinum Acacia
senegal, Prosopis juriflora, Leucaena Glycyrrhiza pallidflora, Swansonia, Glycine,
Caragana,
Sophora
Abrus precatorius
Acacia spp.
Acacia senegal, Prosopis chilensis
Glycine max
Sesbania rostrata
Acacia senegal, Prosopis chilensis
Kummerowia stipulacea
Medicago, Melilotus, Trigonella
Description and characteristics
Classification
1.
|
Family
|
:
|
Rhizobiaceae
|
2.
|
Genus
|
:
|
Azorhizobium-for stem nodulation
|
Bradyrhizobium
|
|||
Rhizobium
|
|||
Sinorhizobium
|
Morphology
1. Unicellular,
cell size less than 2µ wide, short to medium rod, pleomorphic.
2. Motile
with Peritrichous flagella
3. Gram
negative
4. Accumulate
PHB granules.
Physiology
1.
|
Nature
|
:
|
Chemoheterotrophic,
symbiotic with legume
|
||||
2.
|
C
source
|
:
|
Supplied
|
by
|
legume
|
through
|
photosynthates,
|
monosaccharides,
disaccharide
|
|||||||
3.
|
N
source
|
:
|
Fixed
atmospheric N2
|
Description and characteristics
Classification
1.
|
Family
|
:
|
Rhizobiaceae
|
2.
|
Genus
|
:
|
Azorhizobium-for stem nodulation
|
Bradyrhizobium
|
|||
Rhizobium
|
|||
Sinorhizobium
|
Morphology
1. Unicellular,
cell size less than 2µ wide, short to medium rod, pleomorphic.
2. Motile
with Peritrichous flagella
3. Gram
negative
4. Accumulate
PHB granules.
Physiology
1.
|
Nature
|
:
|
Chemoheterotrophic,
symbiotic with legume
|
||||
2.
|
C
source
|
:
|
Supplied
|
by
|
legume
|
through
|
photosynthates,
|
monosaccharides,
disaccharide
|
|||||||
3.
|
N
source
|
:
|
Fixed
atmospheric N2
|
4.
|
Respiration
|
:
|
Aerobic
|
||||
5.
|
Growth
|
:
|
Fast (Rhizobium),
slow (Bradyrhizobium)
|
||||
6.
|
Doubling
time
|
:
|
Fast
|
growers
|
–
|
2-4
|
hrs
|
Slow
growers – 6-12 hrs
|
|||||||
7.
|
Growth
media
|
:
|
YEMA
|
Contribution
1. Direct
contribution of N symbiotically with legumes.
2. Residual
nitrogen benefit for the succeeding crop.
3. Yield
increase is by 10-35%.
4. Improve
soil structure.
5. Produces
exopolysaccharides.
6. Produces
plant growth hormone.
Recommended for legumes
(Pulses, oilseeds, fodders)
Promising strains: NGR 6, NC 92, CC 1, CRR 6, CRU 14, COBE 13.
2. Azotobacter
It
is a free living N2 fixer, the cells are not prevent on the
rhizoplane, but are abundant in the rhizosphere region. It is classified under
the family Azotobacteriaceae. It requires more of organic matter and depend on
the energy derived from the degradation of plant residues. Beijerinck was the
first to isolate and describe Azotobacter.
Species
Cell
size, flagellation, pigmentation and production of extracellular slime are
considered as diagnostic features of these bacteria in distinguishing species.
A. chroococcum
|
:Black to brown insoluble pigment.
|
|
A. vinelandii, A.
paspali,
|
:Green fluorescent and soluble pigments
|
|
A. agilis
|
||
A. beijerinckii
|
:Yellow to light brown insoluble pigments
|
|
A. macrocytogenes
|
:
|
Pink
soluble pigments
|
A. insignis
|
:
|
Yellow
brown pigments
|
Azotobacter cells are polymorphic,
gram negative, form cyst and accumulate Poly
Beta hydroxy butyric acid and produces abundant gum.
.
Morphology
Cell size
|
:Large ovoid cells, size 2.0 – 7.0 x 1.0 – 2.5 µ
|
||
Cell character
|
:
|
Polymorphic
|
|
Gram character
|
:
|
Negative
|
|
Physiology
|
|||
1.
|
Nature
|
:
|
Chemoheterotrophic,
free living
|
2.
|
C
source
|
:Mono,
di saccharides, organic acids
|
|
3.
|
N
source
|
:N2 through fixation, amino
acids, NH4+, NO3-
|
|
4.
|
Respiration
|
:
|
Aerobic
|
5.
|
Growth
|
:Ashby
/ Jensen's medium
|
|
6.
|
Doubling
time
|
:
|
3
hours
|
Benefits
•
Ability to fix atmospheric N2 – 20-40
mg BNF/g of C source in laboratory equivalent to 20-40 kg N/ha.
•
Production of growth promoting substances like
vitamin B, Indole acetic acid, GA.
•
Ability to produce thiamine, riboflavin,
pyridoxin, cyanogobalanine, nicotinic acid, pantothenic acid, etc.
•
Biological control of plant diseases by
suppressing Aspergillus, Fusarium.
- Recommended
for Rice, wheat, millets, cereals, cotton, vegetables, sunflower, mustard and
flowers.
3. Azospirillum
Azospirillum was I isolated by Beijerinck (1922)
in Brazil from the roots of Paspalum and
named it as Azotobacter paspali and
later named as Spirillum lipoferum.
Dobereiner and Day (1976) reported the nitrogen fixing potential of some forage
grasses due to the activity
of S. lipoferum in their roots. Dobereiner
coined the term "Associative
symbiosis" to denote the occurrence of N2
fixing spirillum in plants. Taxonomy
was re-examined and Tarrand et al.
(1978) designated this organism as Azospirillum.
It is an aerobic or micro aerophilic, motile, gram negative bacterium.
Non spore former and spiral shaped bacterium, inhabiting the plant roots both
externally and internally. Being a micro aerophilic organism, it can be
isolated on a semi solid malate medium by enrichment procedures.
Classification
Species: (7) Family
– Spirillaceae
1. A. brasilense
2. A. lipoferum
3. A. amazonense
4. A. halopraeferens
5. A. irkense
6. A. dobereinerae
7. A. largimobilis
Morphology
1.
|
Cell
size
|
: Curved
|
rods,
|
1
|
mm dia,
|
size
|
and shape
|
|||
vary
|
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2.
|
Accumulate
|
:
|
PHB
|
|||||||
3.
|
Gram
reaction
|
:
|
Negative
|
|||||||
4.
|
Development
of white pellicles
|
:
|
2-4
mm below the surface of NFB medium
|
|||||||
Physiology
|
||||||||||
1.
|
Nature
|
:
|
Chemoheterotrophic,
associative
|
|||||||
2.
|
Sole
carbon source
|
:
|
Organic
|
acids,
|
L-arabinose,
|
D-gluconate,
|
||||
D-fructose,
D-glucose, sucrose, Pectin
|
||||||||||
3.
|
N
source
|
:N2 through fixation, amino
acids, N2, NH4+, NO3-
|
||||||||
4.
|
Respiration
|
:
|
Aerobic,
Microaerophilic
|
|||||||
5.
|
Growth
media
|
:
|
NFBTB
(NFB) medium
|
|||||||
6.
|
Doubling
time
|
:
|
1
|
hr
|
in
|
ammonia
|
containing
|
medium
|
||
5.5 –
7.0 hrs in
malate containing semisolid
|
||||||||||
medium
|
Mechanism of Action
1. Contribution
by BNF
2. Production
of PGP substances by bacteria
– Increases root hair
development, biomass.
– Morphological changes in
root cells.
– Increased activity of IAA
oxidase
– Increase in endogenous IAA
– Increased mineral and water uptake, root development, vegetative
growth and crop yield.
4. Competition
in the rhizosphere with other harmful microorganism.
5. Polyamines
and amino acids production.
6. Increased
extrusion of protons and organic acids in plants.
Benefits
1. Promotes
plant growth.
2. Increased
mineral and water uptake, root development, vegetative growth and crop yield.
3. Inoculation
reduced the use of chemical fertilizers (20-50%, 20-40 kg N/ha)
4. Increases
cost benefit ratio.
5. Reduces
pathogen damage.
6. Inhibit
germination of parasitic weeds.
7. Restoration
of arid zone, margine mangrove ecosystem.
8. Reduces
humic acid toxicity in compost.
- Recommended
for rice, millets, maize, wheat, sorghum, sugarcane and co-inoculant for
legumes.
4. Gluconacetobacter diazotrophicus
It is an endophytic N2 fixer
and form to occur on large numbers in roots, stem and
leaf
of sugarcane and other sugar rich crops. It was first isolated from sugarcane.
Cavalcanti and Dobereiner (1988) reported this new endophytic N2
fixer and recently called as from G. diazotrophicus. It can tolerate upto 30%
sucrose concentration and pH upto 3.0. Optimum sucrose concentration is 10-15%.
Produce
surface yellow pellicle on semisolid medium. Does not grow at pH 7.0. Optimum
is 5.5.
Benefits
- Fixes atmospheric N2
- Production of PG hormones (GA, DAA is double than Azospirillum). - Suitable for sugar rich
crops with acidic pH.
These
genera can produce stem nodules. Stem nodulation has been reported in 3 genera
of legumes: Aeschynomene, Neptunia and
Sesbania.
Stem
nodulating Rhizobium comprises both
fast and slow growing types having the generation time of 3-4 hr and 10 hrs
respectively. Those nodulate Aeschynone
can cross inoculate with S. rostrata
strains Azorhizobium caulinodans.
- fix
N2 in
free living conditions without differentiating into bacteroids.
- have
O2
protection mechanisms, to fix N2 under free living conditions.
- Mode
of entry is through lateral root cracks. No infection thread is formed during
colonization.
- Form
both stem and root nodules in S. rostrata.
- Gram
negative, motile rods.
- Produces
root nodules in rice, wheat.
6. Algal Biofertilizers
The
agronomic potential of cyanobacterial N2 fixation in rice fields was recognised in
India during 1939 by De who attributed the natural fertility of tropical rice
fields to N2 fixing blue green algae. The rice field
ecosystem provides an environment favourable for the growth of blue green algae
with respect to their requirements for light, water, high temperature and
nutrient availability.
Algal
biofertilizers constitutes a perpetual source of nutrients and they do not
contaminate ground water and deplete the resources. In addition to contributing
25-30 kg N ha-1 of biologically fixed N2,
they can also add organic matter to the soil, excrete growth promoting
substances, solubilises insoluble phosphates and amend the physical and
chemical properties of the soil.
Blue
green algae are a group of prokaryotic, photo synthetic microscopic plants,
vigorously named as Myxophyceae, Cyanophyceae and Cyanobacteria. They show
striking morphological and physiological similarities like bacteria and hence
called as cyanobacteria.
Cyanobacteria
They
are the photosynthetic bacteria and some of them are able to fix N2.
They can be divided into two major groups based on growth habit.
a) Unicellular
forms and
b) Filamentous
forms.
N2
fixing species are from both groups, found in paddy fields, but the predominant
ones are the heterocystous filamentous forms.
Cyanobacteria are not restricted to
permanently wet habitats, as they are resistant to desiccation and hot
temperatures, and can be abundant in upland soils. However wet paddy soils and
overlying flood waters provide an ideal environment for them to grow and fix N2.
Natural distribution
BGA are cosmopolitan in distribution and more
widely distributed in tropical zone. Free living cyanobacteria can grow
epiphytically on aquatic and emergent plant as well as in flood water or on the
soil surface. Heterocystous cyanobacteria formed less than 10% of the
population of eukaryotic green algae and the abundance increased with the
amount of available phosphorus and with the pH value over the range 4 – 6.5. In
rice soil, population ranges from 10 – 107 cfu g-1 soil.
The main taxa of N2 fixing cyanobacteria
|
||||||||
Group
|
Genera
|
DNA
|
||||||
(mol % GC)
|
||||||||
Group-I. Unicelluar: single
|
Gloeothece,
|
35-71
|
||||||
cells
or cell aggregates
|
Gloeobacter,Synechococcus,
|
|||||||
Cyanothece,
|
Gloeocapsa,
|
|||||||
Synechocystis,
|
Chamaesiphon,
|
|||||||
Merismopedia
|
||||||||
Group-II.
|
Pleurocapsalean:
|
Dermocarpa,
|
Xenococcus,
|
40-46
|
||||
reproduce
by formation of small
|
Dermocarpella,
|
Pleurocapsa,
|
||||||
spherical cells
called baeocytes
|
Myxosarcina, Chroococcidiopsis
|
|||||||
produced
|
through
|
multiple
|
||||||
fission.
|
||||||||
Group-III.
|
Oscillatorian:
|
Oscillatoria,
|
Spirulina,
|
Arthrospira,
|
40-67
|
|||
filamentous cells
that divide by
|
Lyngbya,
|
Microcoleus,
|
||||||
binary
fission in a single plane.
|
Pseudanabaena.
|
|||||||
Group-IV.
|
Nostocalean:
|
Anabaena,
|
Nostoc,
|
Calothrix,
|
38-46
|
|||
filamentous
|
cells that
|
produce
|
Nodularia,
|
Cylinodrosperum,
|
||||
heterocysts
|
Scytonema
|
|||||||
Group-V.Branching:
|
cells
|
Fischerella,
|
Stigonema,
|
42-46
|
||||
divide to form branches
|
Chlorogloeopsis, Hapalosiphon
|
|||||||
The
N2 fixing forms generally have a specialized
structure known as heterocyst. The BGA have minimum growth requirement needing
only diffused light, simple inorganic
nutrients
and moisture. The heterocysts which are modified vegetative cells, because of
their thick walls and absence of photonactin II in photosynthesis, act as ideal
sites for N2 fixation under aerobic conditions. Although
the nitrogenase is present in vegetative cells, it remains inactive because of
the presence of oxygenic photosynthesis. They built up natural fertility (C, N)
in soil.
N2
fixing BGA: Anabaena, Nostoc, Cylindrospermum,
Tolypothrix, Calothrix, Scytonema, Westiellopsis
belonging to orders Nostocales and Stignematales. Many non-heterocystous forms
are also fix N2. eg: But need microaerobic or anaerobic
conditions. Gleocapsa fix in aerobic
condition.
The
species of BGA, known to fix atmospheric N2 are grouped as 3 groups.
(i)
Heterocystous – aerobic forms
(ii)
Aerobic unicellular forms
(iii)
Non-heterocystous, filamentous, micro
aerophilic forms.
The
blue green algal culture's composite inoculum consists of Nostoc, Anabaena, Calothrix,
Tolypothrix, Plectonema, Aphanotleca, Gleocapsa, Oscillatoria, Cylindrospermum,
Aulosira and Scytonema.
Contributions of algal biofertilizer
- Important
component organic farming.
- Contribute
20 – 25 kg N ha-1.
- Add
organic matter to the soil.
- Excrete
growth promoting substances.
- Solubilize
insoluble phosphates.
- Improve
fertilizer use efficiency of crop plants.
- Improve
physical and chemical properties of soil.
- Reduce
C:N ratio.
- Increase
the rice yield by 25-30%.
- Cyanobacteria
are more compatible with nitrate N than ammonium N.
It
increases FUE of the crop plants through exudation of growth promoting
substances and preventing a part of applied fertilizer N from being lost.
I. Phosphate solubilising Microorganisms
Introduction
Though
most soils contain appreciable amounts of inorganic P, most of it being
insoluble forms, cannot be utilized by crops unless they are solubilzied. Soils
also contain organic P that could not be utilized by plants only when it is
mineralized. Phosphate solubilizing microorganisms not only able to solubilize
insoluble forms of inorganic P but are also capable to mineralize organic forms
of P, thus improving the availability of native soil P making their P available
to plants. PSM can also solubilize P from rock phosphate (RP), slag or bone
meal making their P available to plants.
Thus
PSM biofertilizer being economical and environmentally safe offers a viable
alternative to chemical fertilizers.
Microorganisms involved
Many
microorganisms can solubilize inorganic phosphates, which are largely
unavailable to plants. Microbial involvement in solubilization of inorganic
phosphate was first shown by Stalstron (1903) and Sacket et al. (1908) gave conclusive evidence for bacterial solubilization
of RP, bonemeal and TCP.
Various
bacteria and fungi reported to solubilize different types of insoluble
phosphates. Not only solubilizes but also mineralize organic P compounds and
release orthophosphates.
In
general PSM constitute 0.5 – 1.0% of soil microbial population with bacteria
and out numbers the fungi by 2 – 150 folds. But bacteria may loose the P
solubilizing ability while sub culturing and fungi do not lose. Among bacteria,
aerobic spore forming bacteria are more effective P solubilizers.
Mechanism of PO4 solubilization
Different
mechanisms were suggested for the solubilization of inorganic phosphates. ØØ Production
of organic acids
ØØ Chelating
effect
ØØ Production
of inorganic acids
ØØ Hydrogen
sulphide production (H2S)
ØØ Effect of carbon dioxide ØØ Proton extrution
ØØ Siderophore
production
Siderophores, bind iron tightly to prohibit its reaction with soluble
phosphate and rather help release PO4 fixed as ferric phosphate. It is important in
acid soils, where ferric PO4 is one of the major forms.
The
extent of PO4 solubilization depends on the type of
organisms involved. The genus Bacillus
showed maximum activity followed by Penicillium
and Aspergillus. Streptomyces was least effective.
A. awamori & A. niger, Bacillus polymixa & Penicillium
striata are effective in solubilization
of phosphate solubilizarion
II. Mycorrhizae
Mycorrhiza
(fungus root) is the mutualistic association between plant roots and fungal
mycelia. Frank (1885) gave the name "mycorrhiza"
to the peculiar association between tree roots and ectomycorrhizal fungi. 95%
of the plant species form mycorrhizae. It can act as a critical linkage between
plant roots and soil. This association is characterized by the movement of
plant produced carbon to fungus and fungal acquired nutrients to plants.
Mycorrhizal fungi are the key components of the rhizosphere are considered to
have important roles in natural and managed ecosystems.
Types of mycorrhiza
Mycorrhizal
associations vary widely in structure and function. Two main groups of
mycorrhizae are recognized; the ectomycorrhizae and endomycorrhizae, although
the rare group with intermediate properties, the ectendotrophic mycorrhizae.
1. Ectomycorrhiza
The
fungal hyphae form a mantle both outside the root and within the root in the
intercellular spaces of the epidermis and cortex. No intracellular penetration
into epidermal or cortical cells occurs, but an extensive network called the
Hartignet is formed between these cells. Sheath or Mantle increases the surface
area of absorbing roots and offers protection to the roots. Hartignet can act
as storage and transport organ for P.
Ectomycorrhizae
are common on trees, including members of the families pinaceae (Pin, Fir,
Spruce, Larch, Semlock), Fagaceae (Willow, Poplar, Chesnut), Betulaceae (Birch,
Alder), Salicaceae (Willow, Poplar) and Myrtaceae.
The
fungi forming Ectomycorrhizal association are coming under Basidiomycotina and
Ascomycotina. eg: Laccaria laccata,
Suillus, Rhizopogan, Amanita
2. Endomycorrhizae
Endomycorrhizae
consist of three sub groups, but by far the most common are the Arbuscular
Mycorrhizal fungi. Fungi under AM are the members of Endogonaceae and they
produce an internal network of hyphae between cortical cells that extends out
into the soil,
where
the hyphae absorb mineral salts and water. This fungus do not form an external
mantle but lives within the root. In all forms, hyphae runs between and inside
the root cells which includes,
Ericoid mycorrhiza
|
-
|
Associated with some species of Ericaceous plants
|
Orchid mycorrhiza
|
-
|
associated
with orchid plants
|
Arbuscular mycorrhiza
|
-
|
associated
with most of the plant families
|
Arbuscular Mycorrhizal fungi
The most important one is AM
AM,
an endomorphic mycorrhizae formed by the aseptate phycomycetous fungi are
associated with majority of agricultural crops, growing under broad ecological
range.
Class
|
:
|
Zygomycotina
|
Order
|
:
|
Endogonales
|
Family
|
:
|
Endogonaceae
|
150 species of AMF are
known
.
Colonization Process
Roots
do not show visual morphological changes due to AM colonization. AM fungal
infection into a host occurs by germination of spore, hyphal growth through
soil to host roots, penetration of host roots and spread of infection inter and
intracellularly in the root cortex. Colonization occurs under two phases: (1)
Extra matrical phase and (2) Intra radical phase.
Extra matrical phase: Events occurring outside the root after the germination of chlamydospores. Mycelium explores larger soil volume. Fungal
growth can be 80-130 times the length of root. Extra matrical hyphae (EMH) are
larger in diameter than inner hyphae. Once the fungus recognises the plant,
appresorium is formed in the host roots and penetration occurs via the
appresorium. EMH ends with resting spores in soil.
Intra radical phase: Events occurring inside the root cortex. After penetrating the
cortex, the fungus may produce intercellular as well as intracellular
hyphae in the cortical cells. Forms two morphological structures namely
arbuscules and vesicles inside the cortical cells. Arbuscules: are the first formed structures after the hyphal entry
into the cortical cells. Arbuscules are the fine
dichotomously branched hyphal filaments look like little trees. Arbuscules
start to form approximately 2 days after penetration. They are considered as
the
major
site of exchange between the fungus and host root. They are short lived (4-13
days) and degenerate.
Vesicles: Following the formation of arbuscules, some species of fungi also
form vesicles in the roots. Terminal or
intercallery hyphal swellings of the hyphae called vesicles. Vesicles contain
lipids and cytoplasm. They act as P storage organ and they ever be present in
the root. Size of the vesicles is about 30-100 µm. In vesicles P can be
accumulated as polyphosphates.
EMH,
vesicles and Arbuscules play a key role in nutrient transfer particularly in
mobilisation of phosphorus.
Mechanism of action
The
beneficial effect on plant growth and yields following inoculation with VAM is
attributed to
(i)
improved mineral nutrition, especially P (P,
Zn, Cu, K, S, NH4)
(ii)
Mobilization of nutrients through greater soil
exploration.
(iii)
Protection of host roots against pathogen
infection.
(iv)
Improved water relation
(v)
Better tolerance to stress like salinity,
heavy metal pollution
(vi)
Protection against transplantation shock.
Reasons for Enhanced P uptake by AM Fungi
- Physical
exploration of soil.
- Higher
affinity towards P
- Lower
threshold concentration
- Rhizosphere
modification
- Differences
in anion and cation absorption due to exudation pattern.
- Siderophore
production.
- Selective
stimulation of microorganisms in the rhizosphere.
- Increased
hyphal area for absorption (EMH).
- Absorb
and transport P beyond the depletion zone around the root.
- P
absorption by EMH is 1000 times faster than normal hyphae and 3-4 times
greater.
Disease resistance
- Resist
the parasitic invasion and minimises the loss.
- Mycorrhizal
roots harbour more actinomycetes.
- Mycorrhizal
roots have elevated levels of phenols, while offers resistance to fungal
hydrolytic enzymes.
- Mycorrhizal
infection stimulates biosynthesis of phytoalexins.
Organic fertilizers
are fertilizers derived from animal matter, animal excreta (manure), human excreta, and vegetable matter. (e.g. compost and crop residues).[1] Naturally occurring organic fertilizers include animal wastes from meat processing, peat, manure, slurry, and guano.
In contrast, the majority of fertilizers used in commercial farming are extracted from minerals (e.g., phosphate rock) or produced industrially (e.g., ammonia). Organic agriculture, a system of farming, allows for certain fertilizers and amendments and disallows others; that is also distinct from this topic.
The main organic fertilizers are, peat, animal wastes (often from slaughter houses), plant wastes from agriculture, and treated sewage sludge.
Mineral
By some definitions, minerals are distinctly separate from organic materials. However, certain organic fertilizers and amendments are mined, specifically guano and peat, and other mined minerals are fossil products of animal activity, such as greensand (anaerobic marine deposits), some limestones (fossil shell deposits) and some rock phosphates, (fossil guano). Peat, a precursor to coal, offers no nutritional value to the plants, but improves the soil by aeration and absorbing water; it is sometimes credited as being the most widely used organic fertilizer and by volume is the top organic amendment.
Animal sources
These materials include the products of the slaughter of animals. Bloodmeal, bone meal, hides, hoofs, and horns are typical precursors.[1] fish meal, and feather meal are other sources.
Chicken litter, which consists of chicken manure mixed with sawdust, is an organic fertilizer that has been shown to better condition soil for harvest than synthesized fertilizer. Researchers at the Agricultural Research Service (ARS) studied the effects of using chicken litter, an organic fertilizer, versus synthetic fertilizers on cotton fields, and found that fields fertilized with chicken litter had a 12% increase in cotton yields over fields fertilized with synthetic fertilizer. In addition to higher yields, researchers valued commercially sold chicken litter at a $17/ton premium (to a total valuation of $78/ton) over the traditional valuations of $61/ton due to value added as a soil conditioner.[2]
Plant[edit]
Processed organic fertilizers include compost, humic acid, amino acids, and seaweed extracts. Other examples are natural enzyme-digested proteins. Decomposing crop residue (green manure) from prior years is another source of fertility.
Other ARS studies have found that algae used to capture nitrogen and phosphorus runoff from agricultural fields can not only prevent water contamination of these nutrients, but also can be used as an organic fertilizer. ARS scientists originally developed the "algal turf scrubber" to reduce nutrient runoff and increase quality of water flowing into streams, rivers, and lakes. They found that this nutrient-rich algae, once dried, can be applied to cucumber and corn seedlings and result in growth comparable to that seen using synthetic fertilizers.[3]
Treated sewage sludge
Although night soil (from human excreta) was a traditional organic fertilizer, the main source of this type is nowadays treated sewage sludge, also known as biosolids.
Biosolids as soil amendment is only available to less than 1% of US agricultural land. Industrial pollutants in sewage sludge prevents recycling it as fertilizer. The USDA prohibits use of sewage sludge in organic agricultural operations in the U.S. due to industrial pollution, pharmaceuticals, hormones, heavy metals, and other factors.[4][5][6] The USDA now requires 3rd-party certification of high-nitrogen liquid organic fertilizers sold in the U.S.[7]
Sewage sludge use in organic agricultural operations in the U.S. has been extremely limited and rare due to USDA prohibition of the practice (due to toxic metal accumulation, among other factors).[8][9][10]
Urine
Further information: Reuse of excreta
Animal sourced urea and urea-formaldehyde from urine are suitable for organic agriculture; however, synthetically produced urea is not.[11] The common thread that can be seen through these examples is that organic agriculture attempts to define itself through minimal processing (e.g., via chemical energy such as petroleum — see Haber process), as well as being naturally occurring or via natural biological processes such as composting.
What is Green Manure?
Green manure is a term used to describe specific plant or crop varieties that are grown and turned into the soil to improve its overall quality. A green manure crop can be cut and them plowed into the soil or simply left in the ground for an extended period prior to tilling garden areas. Examples of green manure crops include grass mixtures and legume plants. Some of the most commonly used are:
Green Manure Crop Benefits The growing and turning of green manure cover crops provides additional nutrients and organic matter to the soil. When incorporated into the soil, these plants break down, eventually releasing important nutrients, such as nitrogen, that are necessary for adequate plant growth. It also increases soil drainage and water retention capabilities. In addition to adding nutrients and organic materials to the soil, green manure crops can be grown to scavenge leftover nutrients following the harvest season. This helps prevent leaching, soil erosion, and weed growth
Making Green Manure When making green manure cover crops, consider the season, the site, and the specific needs of the soil. For instance, a good green manure crop for fall or winter would be a cool-season grass like winter rye. Heat-loving crops, like beans, are good for spring and summer. For garden areas in need of additional nitrogen, legumes, such as clover, are ideal. Green manure crops should be turned just before flowering. However, it is also acceptable to wait until the crop has died off. Since green manure crops grow quickly, they make an ideal choice for amending soil prior to spring planting. Learning more about green manure crops can provide home gardeners with the tools necessary for acquiring the optimal soil quality. The healthier the soil, the greater gardening success.
Making Green Manure When making green manure cover crops, consider the season, the site, and the specific needs of the soil. For instance, a good green manure crop for fall or winter would be a cool-season grass like winter rye. Heat-loving crops, like beans, are good for spring and summer. For garden areas in need of additional nitrogen, legumes, such as clover, are ideal. Green manure crops should be turned just before flowering. However, it is also acceptable to wait until the crop has died off. Since green manure crops grow quickly, they make an ideal choice for amending soil prior to spring planting. Learning more about green manure crops can provide home gardeners with the tools necessary for acquiring the optimal soil quality. The healthier the soil, the greater gardening success.
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