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MAKALAH BMPT
Interaksi
Proto-cooperation Mikroba dengan Tanaman
2/8/2016
RIDHO
PRATAMA YENDI
F1C413042
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TITLE :
INSIDE THE ROOT MICROBIOME: BACTERIAL ROOT
ENDOPHYTES AND PLANT GROWTH PROMOTION.
AUTHOR : JONATHAN R .
GAIERO , CRYSTAL A. MCCALL , KAREN A.
THOMPSON , ICOLA
J. DAY , ANNA S. BEST , AND KARI E.
DUNFIELD.
REVIEWED BY :
Ridho
Pratama Yendi. F1C413042. S1- BIOLOGI, FST, UNJA, 2016
What would research be?
Bacterial
root endophytes reside in a vast number of plant species as part of their root
microbiome, with some being shown to positively infl uence plant growth.
Endophyte community structure (species diversity: richness and relative
abundances) within the plant is dynamic and is infl uenced by abiotic and
biotic factors such as soil conditions, biogeography, plant species, microbes
interactions and plant–microbe interactions, both at local and larger scales.
Plant-growth-promoting bacterial endophytes (PGPBEs) have been identifi ed, but
the predictive success at positively infl uencing plant growth in fi eld
conditions has been limited. Concurrent to the development of modern molecular
techniques, the goal of predicting an organism’s ability to promote plant
growth can perhaps be realized by more thorough examination of endophyte
community dynamics. This paper reviews the drivers of endophyte community
structure relating to plant growth promotion, the mechanisms of plant growth
promotion, and the current and future use of molecular techniques to study
these communities.
Why the research
should be?
The interaction
between plants and microorganisms in the soil is well recognized. It’s first
observed that microorganisms were more abundant in the soil surrounding the
plant roots than in soil remote from the root and called this area the
Rhizosphere. Plant roots exude many organic compounds that stimulate microbial
growth and can have a major impact on the composition of the rhizosphere
micro-biome. Recently, research focus has been redirected on the composition of
the rhizosphere micro-biome, examining the impact it can have on plant growth
and health. The micro-biome within plant roots can differ significantly from
that within the rhizosphere, suggesting plants impact the microbial communities
found inside their roots. Microorganisms found within plant tissues, termed
endophytes, are a subset of the root micro-biome, which also includes the
rhizosphere and rhizoid micro-biomes. Extensive research has been done on the
potential of root endophytes as plant inoculants for plant growth promotion.
However, our understanding of the drivers of endophyte communities is lacking
and has hindered our ability to predict the success of endophytes to promote
plant growth in the field.
How would focused in this research by?
The focused of this are
endophyte Bacteria and microbes, and about their interaction especially
Proto-cooperation, on the term, Proto-cooperation same with mutualism symbion,
the differ of them is from the site of cited. Proto-cooperation mean, that one
organism before the interacted are 1 after the interacted are same still in 1.
Mutualism-symbion mean, between two organism before interacted are 0, then
after interacted are 1 and hard for changing one of them cause them still it
bound on. All of this, show the same meaning, like a positive interaction all
of them still be advantages some of it.
In the case, mean in
this Journals tell what the interacted between microbes and plant still in
Rhizosphere., all of part of soils., They are boundary in Endophytes, mean
inside of plant sited, especially in root surfaced. This journal still telling
about the Endophyte Microbes and Bacteria inside the root surfacing, they told,
Endophytes
are conventionally defi ned as bacteria or fungi that reside internally in
plant tissues, can be isolated from the plant after surface disinfection, and
cause no negative effects on plant growth (i.e., they are either beneficial or
commensal). Recent molecular advances require that this defi nition be adjusted
since an abundance of unculturable endophytes have been sequenced, but not
isolated. Furthermore, it appears that certain fungal endophytes can shift
between parasitic and mutualistic life strategies, described as a balanced
antagonism. Therefore, a more endophytes from the Rhizobiaceae family
and their host plants has been the subject of a large amount of research and
reviews. The focus of this paper will specifi cally be root-associated
bacterial endophytes with plant growth promoting life strategies.
How’s ‘bout the result?
The result in this shows
the describing data are Endophyte
distribution within plants depends on a combination of ability to colonize and
the allocation of plant resources. Root endophytes often colonize and penetrate
the epidermis at sites of lateral root emergence, below the root hair zone, and
in root cracks. These colonizers are capable of establishing populations both
inter- and intracellularly. After initial colonization, some endophytes can
move to other areas of the plant by entering the vascular tissues and spreading
systemically. Using endophytes
labeled with
green-fl uorescent-protein (GFP), it’s demonstrated the transport of the
endophytes
from seeds into
plant roots and tissues, and endophytes injected into stems moved into the
roots and rhizosphere, suggesting that there may be a continuing movement of
organisms throughout the root microbiome. The second factor infl uencing
distribution is the allocation of resources throughout the plant. Different
plant tissues can harbor compositionally distinct endophyte communities. For
example, found that Pseudomonas spp. Were more common in the stems than
in the roots of potatoes ( Solanum tuberosum ) after 1 mo of growth. It’s
speculated that the higher endophyte concentration within carrot ( Daucus
carota ) crowns compared with that in the
metaxylem
tissues was due to higher concentrations of photosynthate in crown regions,
supplying more resources for a larger community to proliferate. While molecular
studies can identify an observable distribution pattern of endophytes within
plant s, the mechanisms behind the establishment of the distribution patterns
is not clear, and is a promising area for new research. Experiments
characterizing transcriptome dynamics of endophytes and their host plants offer
promising methods to discover some of the drivers of the plant–endophyte
interactions.
Then,
Plant-growth-promoting bacterial endophytes (PGPBEs) facilitate plant growth
via three interrelated mechanisms: phytostimulation, biofertilization, and
biocontrol. Plant-growth-promoting bacterial endophytes (PGPBEs) facilitate
plant growth via three interrelated mechanisms: phytostimulation,
biofertilization, and biocontrol. Phytostimulation, Phytostimulation is
the direct promotion of plant growth through the production of phytohormones.
The most highly studied example of phytostimulation involves lowering plant
hormone ethylene levels by the enzyme 1-aminocyclopropane-1-carboxylate (ACC)
deaminase. Several endophytes that release ACC deaminase have been shown to
increase plant growth, including Arthrobacter spp. and Bacillus spp.
in pepper plants ( Capsicum annuum), as well as Pseudomonas putida and
Rhodococcus spp. in peas ( Pisum sativum). The mechanism of plant
growth promotion is unknown; however, ACC deaminase production may reduce
abiotic stress by balancing plant ethylene-level production, because elevated
ethylene levels inhibit cell division, DNA synthesis, and root/shoot growth (
Burg, 1973 ). The production of other plant hormones including indole-3-acetic
acid, jasmonates, and abscisic acid by bacterial strains may
also stimulate
plant growth. Biofertilization, The promotion of plant growth by
increasing the accessibility or supply of major nutrients is termed
biofertilization ( Bashan, 1998 ). A well-studied form of biofertilization is
nitrogen fixation, which is the conversion of atmospheric nitrogen to ammonia.
Several PGPBEs have been studied extensively for their ability to fix nitrogen
including Azospirillum spp. ( Hill and Crossman, 1983 ), Pantoea
agglomerans ( Verma et al., 2001 ), and Azoarcus spp. ( Hurek et
al., 2002 ). Some PGPBEs can increase phosphorus availability to the plant
through phosphorus solubilization. The release of low molecular weight acids
can allow the chelation of the metal cation attached to phosphorus, making it
more accessible to plants. It’s isolated, characterized, and quantified the
phosphate solubilization abilities of endophytes in sunfl ower ( Helianthus
annuus ), identifying Achromobacter xiloxidans and Bacillus
pumilus as having the highest chelating capabilities. Yazdani and Bahmanyar
(2009) showed that the use of PGPBEs in fertilizer treatments for corn ( Zea
mays ) reduced the need for phosphorus application by 50% without
significant loss in grain yield. Biocontrol, The promotion of plant
growth through protection from phytopathogens is known as biocontrol. Several
mechanisms may be involved, including the production of siderophores or
antibiotics. Siderophores, such as pyochelin and salicylic acid, chelate iron
and can indirectly contribute to disease control by competing with
phytopathogens for trace metals. Antimicrobial metabolites produced by PGPBEs,
such as 2,4-diacetylphloroglucinol (DAPG), can enhance disease suppression in
plants. For example, eggplant wilt caused by Ralstonia solanacearum was
reduced by 70% after seeds were inoculated with DAPG-producing endophytic
isolates.
Importance of
endophytes
The
potential of PGPBEs to improve plant health has led to a great
number of studies examine their applied use as inoculants, primarily in
agricultural crops. The potential for microbial inoculants to reduce the need
for chemicals such as pesticides and fertilizers makes them important in the development
of sustainable agricultural practices. In the following sections, we will
review drivers that determine endophyte community structure and factors that
will need to be considered for applied use of PGPBEs in a field setting.
What would conclusion state in cited?
The
ubiquity of beneficial and non beneficial, naturally occurring bacterial
endophytes in plant roots is undisputed. It is less clear what determines
absolutely whether the endophytes will be benefi cial for the host plant or
not, the external factors or cues involved, and what shapes the dynamics of the
plant–endophyte relationship. Endophytes tested in isolation may indicate
different life strategies and plant-growth-promoting characteristics compared
to similar species or co-inoculating multiple strains. In a similar vein,
external factors may contribute to altered life strategies of endophytes, such
as the conditions imposed upon them via the host plant including soil and geographic
factors, and anthropogenic management of the crops. These factors drive the
overall structure and function in the root interior microbiome. As with all
species assemblages, the internal root microbiome is dynamic and determined by
many interacting abiotic and biotic factors that occur at various spatial and temporal
scales. Endophyte community dynamics remain an important area of future
research. Researchers now have the tools to more fully explore the interactions
of abiotic and biotic factors that infl uence these communities and the
subsequent impact of these changes on plant health. A particularly relevant
question is how these populations will be affected in an environment that is
under the infl uence of climate change. Novel molecular methods have
highlighted the limitations of the past, increased our overall understanding of
the nature of plant–microbe and microbe– interactions, and have helped outline
new questions for the future. Future application of this research in
combination may lead to the development of an optimal PGPBE inoculants strain
that is robust, such that slight variations in external environmental factors
and in the plant will not affect the efficacy of plant growth promotion.
