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<h2> The Alternative </h2>
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<p class="intro"> Antibodies have provided many useful applications through the years. Therapeutically, antibodies have provided treatments for various diseases such as: cancers, infectious diseases and allergies. Antibodies have also proven to be useful in various immunology and protein detection techniques, such as ELISA.(1) However, the expensiveness and time-consuming part of antibody production entails that research and development of alternatives is needed.    </p>
  
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<span class="intro"> Peptide aptamers make up one alternative. </span> These combinatorial recognition proteins have been known for over fifteen years (2, 3) and they provide high specificity and strong binding affinity. They consist of a variable peptide sequence inserted into a protein scaffold and they only bind their targets through this variable peptide loop. Various scaffolds have been used as carriers and conformational stabilizers of peptide aptamers: green fluorescent protein, gluthatione-S-transferase, staphyllococal nuclease and stefin A. However the most frequently used is the bacterial and human thioredoxin (4). In our project we construct a system for screening peptide aptamers presented in latter one.
  
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<span class="intro"> In order to maintain the combinatorial ability </span> and diverse specificity of the antibodies, the peptide aptamers have a random peptide loop. These are typical from 10 to 20 amino acids long. To construct these combinatorial peptide libraries, twenty (or ten) repeats of the codon NNK, is inserted into the scaffold, where N is A,T, G or C and K is G or C. The latter is to minimize the number of stop codons. If a 20 aa long peptide loop is chosen, you will get 20^20=1,05*10^26 different peptide combinations. This should give enough diversification to resemble the diversity of antibodies. 
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<p> <span class="intro"> Why did we choose </span> the hTrx-based peptide aptamer as our alternative to the antibody? In contrary to antibodies, peptide aptamers are small monomeric proteins that have been proven to be efficiently expressed and produced in bacteria such as E. coli - especially when presented in a human thioredoxin scaffold (4). Because of their high specificity and strong binding affinity, it has been proposed and verified that they can replace antibodies in many methods involving protein detection (5). Specific peptide aptamers with anticancer and antiviral activity have already been identified (6). Even though they are well described and characterized, peptide aptamers are not used to the same extent as antibodies.
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<p> <span class="intro"> For therapeutic reasons </span>, the scaffold for our peptide aptamer should be not immunogenic in humans. By choosing a protein with human origin as a scaffold for the peptide aptamer, like the human thioredoxin, we expected it to be less immunogenic than other potential scaffolds. With an estimated half-life of 100 hours (7), the human thioredoxin provides a stable scaffold and helps prevent the peptide aptamer for premature degradation. This is of course the half-life for the non-recombinant hTrx. The half-life for the recombinant hTrx is probably influenced by the insertion of the random generated peptide sequence.
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<p> <span class="intro"> Peptide aptamers are by far not the only </span> antibody mimetics known. Other affinity proteins have been studied throughout the years - and few even commercialized(8). However the market is very small. We believe that the hTrx-based peptide aptamer in combination with bacterial-two hybrid screening method provides an easy and fast alternative to antibody production.
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1. Nelson PN, Reynolds GM, Waldron EE, Ward E, Giannopoulos K, Murray PG. Demystified …: Monoclonal antibodies. Molecular Pathology. 2000;53(3):111-7.
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2. Colas P. The eleven-year switch of peptide aptamers. Journal of biology. 2008;7(1):2.
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3. Colas P, Cohen B, Jessen T, Grishina I, McCoy J, Brent R. Genetic selection of peptide aptamers that recognize and inhibit cyclin-dependent kinase 2. Nature. 1996;380(6574):548-50.
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4. Borghouts C, Kunz C, Delis N, Groner B. Monomeric recombinant peptide aptamers are required for efficient intracellular uptake and target inhibition. Molecular cancer research : MCR. 2008;6(2):267-81.
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5. Evans D, Johnson S, Laurenson S, Davies AG, Ko Ferrigno P, Wälti C. Electrical protein detection in cell lysates using high-density peptide-aptamer microarrays. Journal of biology. 2008;7(1):3.
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6. Li J, Tan S, Chen X, Zhang CY, Zhang Y. Peptide aptamers with biological and therapeutic applications. Current medicinal chemistry. 2011;18(27):4215-22.
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7. Swiss Institute of Bioinformatics. 2015. Available from: http://web.expasy.org/cgi-bin/protparam/protparam1?P10599%402-105.
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8. Key Benefits: Affimers have some simple but essential advantages over antibodies: Avacta Life Sciences;  [updated 19-08-2015]. Available from: https://www.avactalifesciences.com/key-benefits.
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Revision as of 14:18, 19 August 2015

The Alternative

Antibodies have provided many useful applications through the years. Therapeutically, antibodies have provided treatments for various diseases such as: cancers, infectious diseases and allergies. Antibodies have also proven to be useful in various immunology and protein detection techniques, such as ELISA.(1) However, the expensiveness and time-consuming part of antibody production entails that research and development of alternatives is needed.

Peptide aptamers make up one alternative. These combinatorial recognition proteins have been known for over fifteen years (2, 3) and they provide high specificity and strong binding affinity. They consist of a variable peptide sequence inserted into a protein scaffold and they only bind their targets through this variable peptide loop. Various scaffolds have been used as carriers and conformational stabilizers of peptide aptamers: green fluorescent protein, gluthatione-S-transferase, staphyllococal nuclease and stefin A. However the most frequently used is the bacterial and human thioredoxin (4). In our project we construct a system for screening peptide aptamers presented in latter one.

In order to maintain the combinatorial ability and diverse specificity of the antibodies, the peptide aptamers have a random peptide loop. These are typical from 10 to 20 amino acids long. To construct these combinatorial peptide libraries, twenty (or ten) repeats of the codon NNK, is inserted into the scaffold, where N is A,T, G or C and K is G or C. The latter is to minimize the number of stop codons. If a 20 aa long peptide loop is chosen, you will get 20^20=1,05*10^26 different peptide combinations. This should give enough diversification to resemble the diversity of antibodies.

Why did we choose the hTrx-based peptide aptamer as our alternative to the antibody? In contrary to antibodies, peptide aptamers are small monomeric proteins that have been proven to be efficiently expressed and produced in bacteria such as E. coli - especially when presented in a human thioredoxin scaffold (4). Because of their high specificity and strong binding affinity, it has been proposed and verified that they can replace antibodies in many methods involving protein detection (5). Specific peptide aptamers with anticancer and antiviral activity have already been identified (6). Even though they are well described and characterized, peptide aptamers are not used to the same extent as antibodies.

For therapeutic reasons , the scaffold for our peptide aptamer should be not immunogenic in humans. By choosing a protein with human origin as a scaffold for the peptide aptamer, like the human thioredoxin, we expected it to be less immunogenic than other potential scaffolds. With an estimated half-life of 100 hours (7), the human thioredoxin provides a stable scaffold and helps prevent the peptide aptamer for premature degradation. This is of course the half-life for the non-recombinant hTrx. The half-life for the recombinant hTrx is probably influenced by the insertion of the random generated peptide sequence.

Peptide aptamers are by far not the only antibody mimetics known. Other affinity proteins have been studied throughout the years - and few even commercialized(8). However the market is very small. We believe that the hTrx-based peptide aptamer in combination with bacterial-two hybrid screening method provides an easy and fast alternative to antibody production.

1. Nelson PN, Reynolds GM, Waldron EE, Ward E, Giannopoulos K, Murray PG. Demystified …: Monoclonal antibodies. Molecular Pathology. 2000;53(3):111-7. 2. Colas P. The eleven-year switch of peptide aptamers. Journal of biology. 2008;7(1):2. 3. Colas P, Cohen B, Jessen T, Grishina I, McCoy J, Brent R. Genetic selection of peptide aptamers that recognize and inhibit cyclin-dependent kinase 2. Nature. 1996;380(6574):548-50. 4. Borghouts C, Kunz C, Delis N, Groner B. Monomeric recombinant peptide aptamers are required for efficient intracellular uptake and target inhibition. Molecular cancer research : MCR. 2008;6(2):267-81. 5. Evans D, Johnson S, Laurenson S, Davies AG, Ko Ferrigno P, Wälti C. Electrical protein detection in cell lysates using high-density peptide-aptamer microarrays. Journal of biology. 2008;7(1):3. 6. Li J, Tan S, Chen X, Zhang CY, Zhang Y. Peptide aptamers with biological and therapeutic applications. Current medicinal chemistry. 2011;18(27):4215-22. 7. Swiss Institute of Bioinformatics. 2015. Available from: http://web.expasy.org/cgi-bin/protparam/protparam1?P10599%402-105. 8. Key Benefits: Affimers have some simple but essential advantages over antibodies: Avacta Life Sciences; [updated 19-08-2015]. Available from: https://www.avactalifesciences.com/key-benefits.