Team:Goettingen/project overview/perspectives

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        <h3>Project</h3>
 
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        <ul>
 
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        <li><a href="https://2014.igem.org/wiki/index.php?title=Team:Goettingen/project_overview">Background</a></li>
 
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<ul>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview">The global burden of fungal infections</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/fungal_infections">Fungal infections</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/current_tools">Current diagnostic tools</a></li></ul>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/project">Our project!</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/perspectives">Further perspectives</a></li>
 
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<ul>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/diganosis">Diagnosis</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/therapeutics">Therapeutics</a></li></ul>
 
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        <li><a href="https://2014.igem.org/Team:Goettingen/project_overview/project_gallery">Gallery</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/project_drylab">Dry lab</a></li>
 
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<li><a href="https://2014.igem.org/Team:Goettingen/project_overview/project_wetlab">Wet lab</a></li>
 
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      <h1 >Background</h1>
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      <h2 id="global_burden">The global burden of fungal infections</h2>      <br />
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    <p>Fungal pathogens are a major public health threat with significant global effects which, surprisingly, is not being addressed as it should. Globally, around 1.5 million people die each year of invasive fungal infections and the number of people who die each year from the top 10 invasive fungal diseases is at least equal to those dying from tuberculosis or malaria. Moreover, the mortality rate of invasive fungal infections is usually greater than 50%.</p><br><p>In contrast, funding for medical mycology is highly underrepresented, accounting for 1.4-2.5% of the total of what the Wellcome Trust, the U.K. Medical Research Council and the U.S. National Institutes of Health spent in 5 years during the late 2010s. This underrepresentation could be just an effect of the number of applications for funding in the area, but even so, the need for an increased awareness and engagement by funding institutions and researchers is no less urgent: the development of new diagnostic and therapeutic tools is critical to improve the situation of high-risk patients.</p>
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<h2 id="fungal_inf">Fungal infections and current diagnostic tools</h2>
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<p>The most common fungal infections are superficial skin, nails and mucosal infections, which are caused in most cases by fungi of the genus <i>Candida</i>. These infections are usually not life threatening and have such common manifestations as athlete's foot and vulvovaginal candidiasis.</p>
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<br /><p>Invasive fungal infections, on the other hand, have unacceptably high mortality rates. Patients with a compromised immune system -such as AIDS patients and post-transplantation patients taking immunosupresants- are at special risk as they don't have the usual barriers that prevent invasive infections in healthy individuals.</p><br />
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<p>According to Brown, <i>et al</i>., (2012), more than 90% of the reported deaths caused by fungi are associated with species from four genera: <i>Cryptococcus</i>, <i>Candida</i>, <i>Aspergillus</i> and <i>Pneumocystis</i>, but epidemiological data for fungal infections is poor, as these infections are often misdiagnosed and there is a lack of accurate data from the developing world.</p><br />
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<h3>Endemic dimorphic fungosis</h3><br />
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<p> The following map is an adaptiation of the information presented in Brown, <i>et al</i>., (2012), where the authors make some comments regarding the quality of that information: 1) the data is extrapolated from a few and geographically localized studies and 2) accurate data is lacking from the developing world and the calculations may underestimate the true values of the presented statistics.</p><br />
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       <h1>Further perspectives</h1>
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      {name: '<b>Disease:</b> Penicilliosis<br><b>Pathogen:</b><i> Penicillium marneffei</i><br><b>Region:</b> Southeast Asia<br><b>Est. life-threatening infections per year</b>: >8,000', latitude: 10.1333, longitude: 102.7000, radius: 8, fillKey: 'gt50'},
+
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      {name: '<b>Disease: </b>Histoplasmosis<br><b>Pathogen:</b><i> Histoplasma capsulatum</i><br><b>Region:</b> Midwestern United States<br><b>Est. life-threatening infections per year</b>: ~25,000', latitude: 40.5, longitude: -85, radius: 25, fillKey: 'gt50'},
+
-
      {name: '<b>Disease:</b> Coccidioidomycosis<br><b>Pathogen:</b><i> Coccidioides immitis</i><br><b>Region:</b> Southwestern United States<br><b>Est. life-threatening infections per year</b>: ~25,000', latitude: 39, longitude: -115.5, radius: 25, fillKey: 'gt50'},
+
-
{name: '<b>Disease:</b> Blastomycosis<br><b>Pathogen:</b><i> Blastomyces dermatitidis</i><br><b>Region:</b> Midwestern and Atlantic United States<br><b>Est. life-threatening infections per year</b>3: ~3,000', latitude: 37, longitude: -80, radius: 3, fillKey: 'gt51'},
+
<p>We have attained two milestones as far as the applications of our project is concerned. First, the identification of peptides with an affinity to a specific fungal surface molecule and second, is the  proof of principle that our selection scheme can be used to generate peptides with affinity to a molecule under scrutiny. Both milestones hold promise but before that, we would like to elaborate on the future scope of the first milestone since it bears relevance to medicine and healthcare.</p><br />
-
{name: '<b>Disease:</b> Paracoccidioidomycosis<br><b>Pathogen:</b><i> Paracoccidioides brasiliensis</i><br><b>Region:</b> Brazil<br><b>Est. life-threatening infections per year</b>: ~4,000', latitude: -15.7833, longitude: -47.8667, radius: 4, fillKey: 'gt50'},
+
 +
<h2 id="diagnostics">Applications in Diagnostics</h2>      <br />   
 +
<h3>Lowering costs</h3><br />
 +
<p>The attachment of a chemical moiety that emits a quantifiable signal (a
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fluorescent, enzymatic or luminiscent moiety) to our peptides can lead to an
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alternative diagnostic method to antibody and antibody fragments with the added
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benefit of the relative low cost of production and modification of small peptides. This cost reduction may
 +
help to spread this diagnostic tool to the markets of the developing world, where
 +
fungal infections have the largest mortality rates and where health care is
-
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largely affected by economic constraints. Moreover, if the peptides prove to have a high species-specificity, the diagnosis based on them may give more information for a proper therapy choice, potentially reducing the toxicity risks associated with the use of broad spectrum antimycotics.</p><br />
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<br />
 
 +
<h3><i>In vivo</i> diagnosis and the potential of artificial selection</h3><br />
 +
<p>Short peptides are currently being used as diagnostic tools for certain kind
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of cancers. These peptides are naturally produced by humans
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natural target, and they also have been modified with radionuclides that make it
 +
possible to detect the location of tumors cells where their binding proteins are
 +
overrepresented with PET or SECT imaging.</p><br />
 +
<p>The most common isotopically labelled peptide used for diagnosisis a <sup>111</sup>In-labelled somatostatin analogue, known as OctreoScan<sup>TM</sup>, which is used to diagnose a variety of tumors. Other peptides under
 +
develompent are cholecystokinin/gastrin analogues, glucagon-like peptide-1,
 +
bombesin, chemokine receptor CXCR4 targeting peptides, RGD peptides, exendin,
-
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Substance P, LHRH, neurotensin, &alpha;-M2, &alpha;-M2H and VIP.</p>  <br />
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<p>Following the same rationale, our artificially selected peptides can be modified and optimized to increase their binding affinity and their half-life. The peptides can then be tagged with radionuclides to enable the diagnosis by imaging techniques. The results of such a diagnostic method will give more information about the localization and spread of the fungal infection inside the patients body than any of the currently available diagnostic methods.</p><br /><br />
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<h2 id="therapeutics">Therapeutic Applications</h1><br />   
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The peptides we developed have significant applications from a clinical standpoint: they can be modified with molecules that modulate the immune response against fungi and they can be attached to an anti-mycotic drug to increase specificity and potentially reduce the drug's adverse effects.</p>
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 +
<p>
 +
We don't expect our peptides to be part of a one-drug therapy. Patients with invasive fungal infections are very often immunocompromised and measures have to be taken to strengthen their immune system for a therapy to be effective. As for the stimulation of the immune system in case of individuals with immunodeficiencies, the use of adjuvants (immune response enhancers) to augment the response is one strategy. In addition to this, natural immuno-modulatory molecules called cytokines (such as Interleukin-1 and Interferon-gamma) to stimulate the appropriate branches of the immune system can be employed as well. </p><br />
 +
<h3>Fungal Infections and  the branches of the immune system that deal with them</h3><br />
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<p>It has been observed that individuals suffering from deficiencies in antibody and complement mediated cytotoxicity are less vulnerable to fungal infections than the ones suffering from phagocytic defects. Moreover, studies have shown that neutrophils are pivotal in fending off fungal infections.  This is further supported by the fact that many cases of fungal infections were following a period of neutropenia (low neutrophil count in blood).</p> <br />
 +
<p>Two vital principles can be gathered from the aforementioned information:</p> <br />
 +
<ul>
 +
<li><p>- Phagocytes (especially neutrophils) play a very important role in the resolution (clearance) of the fungal infection.</li></p><br />
 +
<li><p>- Antibodies and the complement system are not that effective against fungal pathogens due to the surface of these pathogens being unsuitable to binding.</li></p><br />
-
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+
<p>As such, the modulation of these branches of the immune system should aid in the resolution of the disease. It is important to mention that since most patients suffering from invasive mycoses are immunocompromised and that there are different types of immunodeficiencies. Depending upon which branch is dysfunctional, an appropriate strategy of immunomodulation can be adopted.</p> <br />
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Our peptides can bind to the fungal surface and they can be further modified using the Fc (constant) region of the IgG1 or IgG3 antibody subtype (IgG2a in mice). This region is important as it is recognized by the effector cells (neutrophils and macrophages) of the immune system and thereafter, leads to the death of the target cell. This way, not only can it bind to fungal pathogens but can also “draw attention” towards itself from the immune system. In addition to this, the constant region can also activate the complement cascade via the "classical" pathway. Essentially, this set-up functions as a modified antibody with an added bonus of greater affinity. </p> <br />
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<h3>Homing anti-fungal drugs to the site of infection</h3><br />
-
  }
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<p>Anti-mycotics, such as amphotericin B and fluconazole have been used extensively to treat fungal infections. While they have been effective, they are more toxic to the human body than antibiotics that kill bacteria. This is due to the fact that bacteria are more dissimilar to humans than fungi are. As a result, it is relatively simpler to find targets for antibiotics than anti-mycotics. Simply but, the more we humans have in common with a pathogen, the greater is the difficulty in coming up with a drug that harms only one (in other words, there is a need for selective toxicity).</p>
 +
<br />
 +
<p>Thus, yet another potential application of the novel peptides we developed is that they can act as “guides” to these molecules thereby reducing side-effects due to the drug in question.</p>
 +
<br />
 +
<hr>
 +
<h2>References</h2>
 +
<br /><br />
 +
<ul>
 +
<li>
 +
<p>1. Raghavan M, Bjorkman P (1996). "Fc receptors and their interactions with immunoglobulins". Annu Rev Cell Dev Biol 12: 181–220.
 +
<br /><br /></p></li>
 +
<li>
 +
<p>2. Swanson J, Hoppe A (2004). "The coordination of signaling during Fc receptor-mediated phagocytosis", J Leukoc Biol 76 (6): 1093–103. doi:10.1189/jlb.0804439
 +
<br /><br /></p></li>
 +
<li>
 +
<p>3. Pan L, Pei P (2003). "Signaling transduction by IgG receptors". Chin Med J (Engl) 116 (4): 487–94.
 +
<br /><br /></p></li>
 +
<li>
 +
<p>4.  Mueller-Loebnitz C, Ostermann H, Franzke A,Loeffler J, Uharek L, Topp M, and  Einsel H: Immunological Aspects of Candida and Aspergillus Systemic Fungal Infections: Interdisciplinary Perspectives on Infectious Diseases, Volume 2013 (2013), Article ID 102934
 +
<br /><br /></p></li>
 +
<li><p>5. Fani, M., et al., (2012), Radiolabeled peptides: valuable tools for the detection and treatment of cancer, <i>Theranostics</i>, 2(5).<br /><br /></p></li>
 +
<li><p>6. Laverman, P., (2012), Radiolabelled peptides for oncological diagnosis, <i>Eur J Nucl Med Mol Imaging</i>, 39 (Suppl I).<br /><br /></p></li>
 +
</ul>
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<div><a href="https://2014.igem.org/Team:Goettingen/project_overview/project_wetlab" class="button_pre"><b>Previous</b></a><a href="https://2014.igem.org/Team:Goettingen/project_overview/project_biobrick" class="button_next"><b>Next</b></a></div>
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<h2>Our project: paving the way for new diagnostic and therapeutic tools</h2>
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  Our aim is to develop a diagnostic technique capable of detecting the presence of fungal pathogens in  a sample collected from a patient. Briefly, our approach is as follows. Through a yeast two-hybrid assay we will select a set of peptides that show affinity towards surface proteins from different fungi (<i>Aspergillus nidulans</i>, <i>A. fumigatus</i>, <i>Candida albicans</i> and <i>C. glabrata</i>). After confirming the interaction between the surface proteins and a given peptide, we intend to attach a molecule to the peptide marker. In our project, this molecule will be a fluorescent protein, but in principle can also be an immune system activator which is then recognized by the immune cells or other chemical moiety that adds novel functionalities or increases the peptide stability. In comparison to antibodies or antibody fragments, peptides are small, easily synthesized, modified less expensively and show higher diffusion rates in tissues. We expect our method to be faster, more accurate and cheaper than other existing methods. Other laboratories may follow our approach to generate and refine their own peptides with specificity towards their proteins of interest.
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Latest revision as of 00:13, 18 October 2014

Further perspectives

We have attained two milestones as far as the applications of our project is concerned. First, the identification of peptides with an affinity to a specific fungal surface molecule and second, is the proof of principle that our selection scheme can be used to generate peptides with affinity to a molecule under scrutiny. Both milestones hold promise but before that, we would like to elaborate on the future scope of the first milestone since it bears relevance to medicine and healthcare.


Applications in Diagnostics


Lowering costs


The attachment of a chemical moiety that emits a quantifiable signal (a fluorescent, enzymatic or luminiscent moiety) to our peptides can lead to an alternative diagnostic method to antibody and antibody fragments with the added benefit of the relative low cost of production and modification of small peptides. This cost reduction may help to spread this diagnostic tool to the markets of the developing world, where fungal infections have the largest mortality rates and where health care is largely affected by economic constraints. Moreover, if the peptides prove to have a high species-specificity, the diagnosis based on them may give more information for a proper therapy choice, potentially reducing the toxicity risks associated with the use of broad spectrum antimycotics.


In vivo diagnosis and the potential of artificial selection


Short peptides are currently being used as diagnostic tools for certain kind of cancers. These peptides are naturally produced by humans and have their natural binding proteins in the surface of cells; however, they have been optimized to increase their half-life and their affinity towards their natural target, and they also have been modified with radionuclides that make it possible to detect the location of tumors cells where their binding proteins are overrepresented with PET or SECT imaging.


The most common isotopically labelled peptide used for diagnosisis a 111In-labelled somatostatin analogue, known as OctreoScanTM, which is used to diagnose a variety of tumors. Other peptides under develompent are cholecystokinin/gastrin analogues, glucagon-like peptide-1, bombesin, chemokine receptor CXCR4 targeting peptides, RGD peptides, exendin, Substance P, LHRH, neurotensin, α-M2, α-M2H and VIP.


Following the same rationale, our artificially selected peptides can be modified and optimized to increase their binding affinity and their half-life. The peptides can then be tagged with radionuclides to enable the diagnosis by imaging techniques. The results of such a diagnostic method will give more information about the localization and spread of the fungal infection inside the patients body than any of the currently available diagnostic methods.




Therapeutic Applications


The peptides we developed have significant applications from a clinical standpoint: they can be modified with molecules that modulate the immune response against fungi and they can be attached to an anti-mycotic drug to increase specificity and potentially reduce the drug's adverse effects.

We don't expect our peptides to be part of a one-drug therapy. Patients with invasive fungal infections are very often immunocompromised and measures have to be taken to strengthen their immune system for a therapy to be effective. As for the stimulation of the immune system in case of individuals with immunodeficiencies, the use of adjuvants (immune response enhancers) to augment the response is one strategy. In addition to this, natural immuno-modulatory molecules called cytokines (such as Interleukin-1 and Interferon-gamma) to stimulate the appropriate branches of the immune system can be employed as well.


Fungal Infections and the branches of the immune system that deal with them


It has been observed that individuals suffering from deficiencies in antibody and complement mediated cytotoxicity are less vulnerable to fungal infections than the ones suffering from phagocytic defects. Moreover, studies have shown that neutrophils are pivotal in fending off fungal infections. This is further supported by the fact that many cases of fungal infections were following a period of neutropenia (low neutrophil count in blood).


Two vital principles can be gathered from the aforementioned information:


  • - Phagocytes (especially neutrophils) play a very important role in the resolution (clearance) of the fungal infection.


  • - Antibodies and the complement system are not that effective against fungal pathogens due to the surface of these pathogens being unsuitable to binding.


  • As such, the modulation of these branches of the immune system should aid in the resolution of the disease. It is important to mention that since most patients suffering from invasive mycoses are immunocompromised and that there are different types of immunodeficiencies. Depending upon which branch is dysfunctional, an appropriate strategy of immunomodulation can be adopted.


    Our peptides can bind to the fungal surface and they can be further modified using the Fc (constant) region of the IgG1 or IgG3 antibody subtype (IgG2a in mice). This region is important as it is recognized by the effector cells (neutrophils and macrophages) of the immune system and thereafter, leads to the death of the target cell. This way, not only can it bind to fungal pathogens but can also “draw attention” towards itself from the immune system. In addition to this, the constant region can also activate the complement cascade via the "classical" pathway. Essentially, this set-up functions as a modified antibody with an added bonus of greater affinity.



    Homing anti-fungal drugs to the site of infection


    Anti-mycotics, such as amphotericin B and fluconazole have been used extensively to treat fungal infections. While they have been effective, they are more toxic to the human body than antibiotics that kill bacteria. This is due to the fact that bacteria are more dissimilar to humans than fungi are. As a result, it is relatively simpler to find targets for antibiotics than anti-mycotics. Simply but, the more we humans have in common with a pathogen, the greater is the difficulty in coming up with a drug that harms only one (in other words, there is a need for selective toxicity).


    Thus, yet another potential application of the novel peptides we developed is that they can act as “guides” to these molecules thereby reducing side-effects due to the drug in question.



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