Difference between revisions of "Team:Waterloo/Modeling/Intracellular Spread"

 
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<h1>Viral Spread</h1>
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<h1>Viral Spread Model</h1>
  
<h2>Modelling Viral Spread</h2>
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<h2>Motivation</h2>
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<p>The spread of infection between cells and among populations has been modelling extensively, but the middle ground of intercellular spread is relatively unexplored. We investigated whether our defense system would protect individual <em>Arabidopsis</em> plants using an agent-based approach. Briefly, each plant cell is treated an agent that may become infected by CaMV or resistant to infection due to plant defense signalling. Infected cells run an instance <a href="https://2015.igem.org/Team:Waterloo/Modeling/CaMV_Replication">ODE model that was created to study viral replication</a> and then may pass infection to their neighbours. The spread through the stems and leaves of the plant can be tracked with and without the CRISPR/Cas9 system</p>
  
<h3>Overview</h3>
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[insert screenshot of the simulation]
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<p>
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Cauliflower mosaic virus (CaMV) is typically spread from plant to plant through aphids acting as viral vectors. Once in the plant cell, CaMV exploits host transport mechanisms in order to spread.  Neighbouring plant cells share cytoplasmic connections through connections called plasmodesmata, which are utilized by CaMV to spread to neighbouring cells. Additionally, viruses can also form tubules through cell walls to spread to adjacent cells. These two processes, however, are quite slow. An additional feature of the plant that the virus able to exploit is the plant’s vascular system, where it is able to spread quickly through the plant’s vascular system, leading to what is called systemic infection. </p>
  
<p>Most of the existing work on infection spread has focused on the cellular and population levels; the middle ground of within-host spread is relatively unexplored. However, the mechanisms discussed above, of both short- and long-range viral transport discussed above provide a basis for understanding, which has been mathematized by several papers from Santiago Elena’s lab.</p>
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[insert diagram of the plant’s plasmodesmata and vascular system]
  
<h3>Time to systemic infection</h3>
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<p>As a reaction to the presence of the virus, the plant cells will destroy infected cells through apoptosis as well as signal to the rest of the plant to begin production of defensive chemicals in preparation for attack. This signaling causes systemic required resistance, a broad, long-term increased resistant to future infections. <cite ref="Ryals1994"></cite>
  
<p>Rodrigo and colleagues (Rodrigo et al. 2014) explicitly consider within-host dynamics as governed by short- and long-term dynamics. In this model, the infection expands outward from the primary infection site, becoming systemic once it reaches the vasculature (and after an additional latency period for vascular movement). The area of local spread required before reaching the vascular system follows a normal distribution, which yields variable times to systemic infection. This model also accounts for multiple sites of initial infection, which operate independently. The crucial virus-dependent parameters influencing time to systemic infection are the two latency periods (for the initial infected cell and for vascular transport) and the diffusion rate for cell-to-cell viral infection. These models were validated by experimental trials with two variants (low and high diffusion constants) of Turnip Mosaic Virus in nicotiana benthamiana. Their parameters cannot directly translate to adabidopsis, but it is a useful framework for predicting variable times to systemic infection.</p>
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-Explain and link this to the parameters in the model once the parameters are finalized</p>
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-Explain reasons for the parameters
  
<h3>Tracking infection spread in individual leaves</h3>
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</p>
  
<p>Tromas and colleagues (Tromas et al. 2014) take a different theoretical model: individual leaves are considered as each having their own internal dynamics given by a susceptible-infectious model. Beyond the need to find different transmission parameters for each leaf, there are a few modifications to the standard SI model: a spatial aggregation parameter (accounting for the fact that plant cells are not subject to random mixing) and transmission from leaves further down the phloem.</p>
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<h2>Model Formation</h2>
  
<p>The real strength of this work, however, is in the data. By using flow cytometry to measure the viral load of large numbers of plant cells, tracking over both time and space (although only at the scale of leaves). These experiments used Tobacco Etch Virus in nicotiana tabacum, and measured 50 000 cells per leaf for each sample, with 5 replicates. This allowed for the measurement of important parameters, such as the viral multiplicity of infection (which we know to be higher for CaMV (Gutierrez et al. 2010)) and the cellular contagion rate – the number of secondary infections per infected cell per day. The cellular contagion rate is an informative parameter, giving a detailed portrayal of the dynamics of the infection over time. In this case, it was found to be small: it decreased from an already-low value of 1.342 cells/cell/day 3 days post-infection down to 0.196 cells/cell/day 7 days post-infection. These low values may, however, be characteristic of plant RNA viruses (Tromas et al. 2014) -- meaning we might see something different for CaMV.</p>
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<h3>Biology of Viral Infection Spread</h3>
  
<h3>Summary</h3>
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<h4>Intercellular</h4>
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            <p>Cauliflower mosaic virus exploits host transport mechanisms in order to spread. Neighbouring plant cells share cytoplasmic connections through connections called plasmodesmata. These symplastic connections are exploited by CaMV to spread to neighbouring cells, but it is a fairly slow process. The virions must travel between the plasma membrane and the desmotubule (cytoplasmic channel) of the plasmodesmata, a very narrow passage. The size of molecule able to diffuse through the plasmodesmata is determined by the size exclusion limit (SEL), which is affected by the gating properties of the plasmodesmata. In another slow cell-to-cell process, the virus can move through tubules formed through the cell wall. However, CaMV is able to spread to different regions of the plant quite quickly using the plant’s phloem (sugar-transport network). <cite ref="Carrington1996"></cite>
  
<p>These two different modeling approaches both tackle the difficult issue of within-host virus spread. They are quite different, since each focuses on a different unit of spatial analysis. Neither incorporates mechanistic modeling of plant defenses – the first model only investigates up to the point of systemic infection (and includes no variable defenses against local spread), while the second model incorporates defense only indirectly via reductions in the cellular contagion rate (which could also be due to exhaustion of susceptibles, changing viral strategies, or other factors). We will have to pick our unit of spatial analysis based on the measurements we can take and the research questions we wish to pursue. It might be interesting to incorporate modeling of the plant adaptive immune response into the viral spread model – beyond simply being useful, this could be new research.</p>
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Microtubules are a key component of intercellular transmission as well as intracellular motion. They form viral inclusions that encourage uptake by aphids (the major plant-to-plant transport agent) and of viral factories (Niehl et al., 2013) ****WE NEED TO FIND THIS REFERENCE*****. CaMV can induce the formation of microtubules in order to increase its rate of spread <cite ref="Carrington1996"></cite>.</p>
  
<h3>Differences Compared to CaMV and Arabidopsis</h3>
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        <h4>Systemic Infection</h4>
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              <p>-Phloem/Vascular System</p>
  
<p>(This section is more a compilation of rough notes, but it's important to track these differences. These quotes are all direct from Tromas et al. 2014.)
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<h3>Plant Defense Mechanisms</h3>
  
“Moreover, this array of plant immune mechanisms probably contributes to the relatively low between-host variation typically found in experimental settings (Zwart et al. 2012)”.
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<h4>Hypersensitive Response (HR)</h4>
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              </p>Interplant signalling plays an important role in the hypersensitive response of plants, where plant cells selectively undergo apoptosis in order to destroy infected or damaged cells, such as in the event of pathogen attacks like CaMV.
  
“For Cauliflower mosaic virus (CaMV), MOI was reported to vary from 2 to 13 over time, and most cells were infected (Gutierrez 2010). Furthermore, for CaMV virion concentrations in vascular tissue are correlated to MOI (Gutierrez et al. 2012)”
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A main intercellular signaling molecule is hydrogen peroxide (H2O2), formed during electron transport processes <cite ref="Neill2002"></cite>. This is produced in elevated levels the event of pathogen attack and other stresses, and can damage DNA and proteins <cite ref="Neill2002"></cite>. It allows for the localization of apoptosis which occurs as a result of the hypersensitive response as well as increased expression of defense genes, which it modulates during defense response <cite ref="Neill2002"></cite>. H2O2 has been observed in tobacco plants to induce the production of proteasomes linked to the degradation of cells in programmed cell death <cite ref="Neill2002"></cite>. In Arabidopsis thaliana, it has been observed that increased generation of H2O2 leads to an increase of calcium ions in the form of cytosolic calcium, which, triggering a cascade of reactions leading to the apoptosis of infected cells <cite ref="Neill2002"></cite>. H2O2 has also been observed inducing the expression of glutathione S-transferase (GST) and phenylalanine ammonia‐lyase (PAL), both of which are defense-related genes, as well as genes involved in the production and degradation of H2O2 <cite ref="Neill2002"></cite>. Additionally, it has been observed to cause the stomatal closure of cells <cite ref="Neill2002"></cite>.
  
“On the other hand, in a similar model-selection-based analysis for TMV and CaMV MOI, two viruses that also move by cell-to-cell movement, spatial aggregation only marginally improved model fit for both datasets (Zwart et al. 2013).</p>
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Another intercellular signaling molecule is nitric oxide (NO), found primarily in its gaseous form, which may be produced at the same time as (H2O2) after pathogen challenge, and induces a similar defense response as (H2O2). <cite ref="Neill2002"></cite> It increases the gene expression of defensive genes such as PAL1 and GST. <cite ref="Neill2002"></cite> Additionally, NO may have a role in iron-level regulation in plants, and redox signaling through its potential involvement with pathogen-induced oxygenase. <cite ref="Neill2002"></cite> There is limited research for NO as a plant signal, however, it has been researched extensively as a signaling molecule in mammalian cells <cite ref="Neill2002"></cite>. Like in mammalian cells, NO has been observed increasing levels of cyclic GMP in the event of pathogen challenge and inducing programmed cell death. <cite ref="Neill2002"></cite>
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In additional to working concurrently with each other, NO and H2O2 also interact with a whole host of other signaling molecules, such as jasmonic acid, ethylene, and salicylic acid <cite ref="Neill2002"></cite>, which have to be taken into consideration when studying intercellular plant signaling as a whole.</p>
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<h4>Systemic  Acquired Resistance (SAR)</h3>
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<h4>Mechanisms</h4>
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                      <p>The systemic acquired resistance (SAR) defense mechanism, or immunization of plants, is a broad, long-term increased resistant to future infections. <cite ref="Ryals1994"></cite> This is similar to the increased resistance against diseases in mammals, after having been infected. <cite ref="Ryals1994"></cite> It is important to note that this resistance is not triggered by mechanical damage caused by factors such as herbivore attack. <cite ref="Ryals1994"></cite> This mechanism is only activated after a pathogen is detected within the plant, triggering defenses through signals <cite ref="Ryals1994"></cite> Salicylic acid (SA) has been identified as a molecule with an indispensable role in the pathway to systemic acquired resistance. <cite ref="Klessig2000"></cite> Additionally, NO also has an important role in activating systemic acquired resistance. <cite ref="Klessig2000"></cite> During the initial wave of defense after pathogen detection, there is an “oxidative burst” wherein levels of oxidative species suddenly increase. <cite ref="Klessig2000"></cite> This is accompanied by cell wall protein linkage, the activation of kinase and increased gene expression defensive genes. <cite ref="Klessig2000"></cite> A second wave of defense is found in the hypersensitive response, wherein lesions form (from programmed cell death). <cite ref="Klessig2000"></cite> NO and SA play an interconnected role with each other, where reactive oxygen species (ROS) such as NO have been observed accumulating SA, and in turn, SA triggers ROS production (including NO and H2O2). <cite ref="Klessig2000"></cite></p>
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  <h4>Signalling and Spread</h4>
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<h3>Agent-Based Model Design</h3>
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<em>Include Model Assumptions!!!</em>
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      <h4>Plant Structure</h4>
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      -Plasmodesmata
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      -Phloems/Vascular System
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      <h4>Virus</h4>
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      -Initial Infection Sites
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      -Founder Population
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      -Viral Spread Rates
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    -Viral Spread Chance
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    -Viral Assembly
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      <h4>Plant Response</h4>
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    -SA Chance (Plant Defense)
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    -Lysis Chance
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    -SAR
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    -SAR Spread Chance
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<h3>Modelling Software Choice</h3>
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<p>
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The agent-based modelling software for the simulation had several different criteria needed to be fulfilled: the ability to create different kinds of agents, control over the connections between agents (e.g. plasmodesmata betweeen cells), an option to have complex rules within each agent, being able to have an arbitrary number of model states and keep track of time since infection, as well as being easy to use. Originally, three different software packages (MASON, MESA and Netlogo) were chosen out of several as the top candidates to create the viral spread simulation due to their fulfillment of the above criteria. All of the languages required were unfamiliar, and thus would have to be learned from scratch. Netlogo was chosen to create the final simulation due to a variety of its strengths as well as time constraints. Although Netlogo was the most unfamiliar-looking language, it presented itself as the simulation package with the smallest learning curve. Additionally, it had readily-available documentation and a built-in GUI. MESA was a Python-based simulation package and ultimately was not chosen due to its documentation not being as detailed or as readily available as MASON or Netlogo’s, as well as the level of familiarity with Python required to create the model being too high to achieve within the time constraints. MASON, a Java-based simulation package, despite having excellent, easily-found documentation did not have a built-in GUI, and did not have as many built in-functions as the Netlogo, thus requiring more work to get off the ground. Although in some cases the fewer amount of built-in functions could have proved to be an advantage (it would have added more flexibility and customization to the simulation), due to the time constraints and the demand of a level familiarity with Java (as with MESA) to create a simulation with MASON, Netlogo was thus chosen over MASON. </p>
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<h4>Software Downloads</h4>
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<div class= "col-sm-4">
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<figure>
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    <a href="https://ccl.northwestern.edu/netlogo/"><img src="https://static.igem.org/mediawiki/2015/1/16/Waterloo_Math_ViralSpread_NetlogoIcon.png" style="width:200px;"/></a>
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        <figcaption>Link to Download Netlogo</figcaption>     
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          <div class="img-att">i
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          <ul class="img-att-bubble">
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                    <li>Photo &copy; <a href="https://ccl.northwestern.edu/netlogo/">Uri Wilensky</a></li>
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                    <li><a href="http://www.macupdate.com/app/mac/21469/netlogo">Original Photo</a></li>
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</figure>
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<div class= "col-sm-4">
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<figure>
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      <a href= "https://pypi.python.org/pypi/Mesa/"><img src="https://static.igem.org/mediawiki/2015/4/4b/Waterloo_Math_ViralSpread_MESAIcon.svg" style="width:200px;"/></a>
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        <figcaption>Link to Download MESA</figcaption>     
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</figure>
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<figure>
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      <a href= "https://cs.gmu.edu/~eclab/projects/mason/"></a><img src="https://static.igem.org/mediawiki/2015/a/a2/Waterloo_Math_ViralSpread_MASONIcon.svg "style="width:200px;"/></a>
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        <figcaption>Link to Download MASON</figcaption>     
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</figure>
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<h2>Results</h2>
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<h2>Discussion</h2>
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<h2>References</h2>
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<ol id="reflist">
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</ol>
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</section>
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{{Waterloo_Footer}}

Latest revision as of 01:38, 15 September 2015

Viral Spread Model

Motivation

The spread of infection between cells and among populations has been modelling extensively, but the middle ground of intercellular spread is relatively unexplored. We investigated whether our defense system would protect individual Arabidopsis plants using an agent-based approach. Briefly, each plant cell is treated an agent that may become infected by CaMV or resistant to infection due to plant defense signalling. Infected cells run an instance ODE model that was created to study viral replication and then may pass infection to their neighbours. The spread through the stems and leaves of the plant can be tracked with and without the CRISPR/Cas9 system

[insert screenshot of the simulation]

Cauliflower mosaic virus (CaMV) is typically spread from plant to plant through aphids acting as viral vectors. Once in the plant cell, CaMV exploits host transport mechanisms in order to spread. Neighbouring plant cells share cytoplasmic connections through connections called plasmodesmata, which are utilized by CaMV to spread to neighbouring cells. Additionally, viruses can also form tubules through cell walls to spread to adjacent cells. These two processes, however, are quite slow. An additional feature of the plant that the virus able to exploit is the plant’s vascular system, where it is able to spread quickly through the plant’s vascular system, leading to what is called systemic infection.

[insert diagram of the plant’s plasmodesmata and vascular system]

As a reaction to the presence of the virus, the plant cells will destroy infected cells through apoptosis as well as signal to the rest of the plant to begin production of defensive chemicals in preparation for attack. This signaling causes systemic required resistance, a broad, long-term increased resistant to future infections. -Explain and link this to the parameters in the model once the parameters are finalized

-Explain reasons for the parameters

Model Formation

Biology of Viral Infection Spread

Intercellular

Cauliflower mosaic virus exploits host transport mechanisms in order to spread. Neighbouring plant cells share cytoplasmic connections through connections called plasmodesmata. These symplastic connections are exploited by CaMV to spread to neighbouring cells, but it is a fairly slow process. The virions must travel between the plasma membrane and the desmotubule (cytoplasmic channel) of the plasmodesmata, a very narrow passage. The size of molecule able to diffuse through the plasmodesmata is determined by the size exclusion limit (SEL), which is affected by the gating properties of the plasmodesmata. In another slow cell-to-cell process, the virus can move through tubules formed through the cell wall. However, CaMV is able to spread to different regions of the plant quite quickly using the plant’s phloem (sugar-transport network). Microtubules are a key component of intercellular transmission as well as intracellular motion. They form viral inclusions that encourage uptake by aphids (the major plant-to-plant transport agent) and of viral factories (Niehl et al., 2013) ****WE NEED TO FIND THIS REFERENCE*****. CaMV can induce the formation of microtubules in order to increase its rate of spread .

Systemic Infection

-Phloem/Vascular System

Plant Defense Mechanisms

Hypersensitive Response (HR)

Interplant signalling plays an important role in the hypersensitive response of plants, where plant cells selectively undergo apoptosis in order to destroy infected or damaged cells, such as in the event of pathogen attacks like CaMV. A main intercellular signaling molecule is hydrogen peroxide (H2O2), formed during electron transport processes . This is produced in elevated levels the event of pathogen attack and other stresses, and can damage DNA and proteins . It allows for the localization of apoptosis which occurs as a result of the hypersensitive response as well as increased expression of defense genes, which it modulates during defense response . H2O2 has been observed in tobacco plants to induce the production of proteasomes linked to the degradation of cells in programmed cell death . In Arabidopsis thaliana, it has been observed that increased generation of H2O2 leads to an increase of calcium ions in the form of cytosolic calcium, which, triggering a cascade of reactions leading to the apoptosis of infected cells . H2O2 has also been observed inducing the expression of glutathione S-transferase (GST) and phenylalanine ammonia‐lyase (PAL), both of which are defense-related genes, as well as genes involved in the production and degradation of H2O2 . Additionally, it has been observed to cause the stomatal closure of cells . Another intercellular signaling molecule is nitric oxide (NO), found primarily in its gaseous form, which may be produced at the same time as (H2O2) after pathogen challenge, and induces a similar defense response as (H2O2). It increases the gene expression of defensive genes such as PAL1 and GST. Additionally, NO may have a role in iron-level regulation in plants, and redox signaling through its potential involvement with pathogen-induced oxygenase. There is limited research for NO as a plant signal, however, it has been researched extensively as a signaling molecule in mammalian cells . Like in mammalian cells, NO has been observed increasing levels of cyclic GMP in the event of pathogen challenge and inducing programmed cell death. In additional to working concurrently with each other, NO and H2O2 also interact with a whole host of other signaling molecules, such as jasmonic acid, ethylene, and salicylic acid , which have to be taken into consideration when studying intercellular plant signaling as a whole.

Systemic Acquired Resistance (SAR)

Mechanisms

The systemic acquired resistance (SAR) defense mechanism, or immunization of plants, is a broad, long-term increased resistant to future infections. This is similar to the increased resistance against diseases in mammals, after having been infected. It is important to note that this resistance is not triggered by mechanical damage caused by factors such as herbivore attack. This mechanism is only activated after a pathogen is detected within the plant, triggering defenses through signals Salicylic acid (SA) has been identified as a molecule with an indispensable role in the pathway to systemic acquired resistance. Additionally, NO also has an important role in activating systemic acquired resistance. During the initial wave of defense after pathogen detection, there is an “oxidative burst” wherein levels of oxidative species suddenly increase. This is accompanied by cell wall protein linkage, the activation of kinase and increased gene expression defensive genes. A second wave of defense is found in the hypersensitive response, wherein lesions form (from programmed cell death). NO and SA play an interconnected role with each other, where reactive oxygen species (ROS) such as NO have been observed accumulating SA, and in turn, SA triggers ROS production (including NO and H2O2).

Signalling and Spread

Agent-Based Model Design

Include Model Assumptions!!!

Plant Structure

-Plasmodesmata -Phloems/Vascular System

Virus

-Initial Infection Sites -Founder Population -Viral Spread Rates -Viral Spread Chance -Viral Assembly

Plant Response

-SA Chance (Plant Defense) -Lysis Chance -SAR -SAR Spread Chance

Modelling Software Choice

The agent-based modelling software for the simulation had several different criteria needed to be fulfilled: the ability to create different kinds of agents, control over the connections between agents (e.g. plasmodesmata betweeen cells), an option to have complex rules within each agent, being able to have an arbitrary number of model states and keep track of time since infection, as well as being easy to use. Originally, three different software packages (MASON, MESA and Netlogo) were chosen out of several as the top candidates to create the viral spread simulation due to their fulfillment of the above criteria. All of the languages required were unfamiliar, and thus would have to be learned from scratch. Netlogo was chosen to create the final simulation due to a variety of its strengths as well as time constraints. Although Netlogo was the most unfamiliar-looking language, it presented itself as the simulation package with the smallest learning curve. Additionally, it had readily-available documentation and a built-in GUI. MESA was a Python-based simulation package and ultimately was not chosen due to its documentation not being as detailed or as readily available as MASON or Netlogo’s, as well as the level of familiarity with Python required to create the model being too high to achieve within the time constraints. MASON, a Java-based simulation package, despite having excellent, easily-found documentation did not have a built-in GUI, and did not have as many built in-functions as the Netlogo, thus requiring more work to get off the ground. Although in some cases the fewer amount of built-in functions could have proved to be an advantage (it would have added more flexibility and customization to the simulation), due to the time constraints and the demand of a level familiarity with Java (as with MESA) to create a simulation with MASON, Netlogo was thus chosen over MASON.

Software Downloads

Link to Download Netlogo
i
Link to Download MESA
Link to Download MASON

Results

Discussion

References

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