Difference between revisions of "Team:Hong Kong HKU/Description"

 
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<h3><center>What is Huntington's disease?</center><h3>
  
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<p>Huntington’s disease (HD) is an inherited neurodegenerative disorder that results in the death of brain cells. Genetic mutations, namely the trinucleotide repeats in the Huntingtin gene (HTT) located on Chromosome 4, lead to the development of HD [1]  .
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Though the disease is incurable, early diagnosis can help to better relieve symptoms by allowing treatments to start sooner. In the early stages of HD, only subtle changes in personality, cognitive and physical abilities can be identified.
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<h3><center>Early Diagnosis of Huntington's disease</center></h3>
  
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<h1 id="main-heading">Project Description</h1></br>
 
 
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Diagnosis of HD (in cases where the parents do not have HD) is usually carried out only after symptoms are identified and the patient approaches the medical professionals. As the early symptoms are generally not severe enough to be recognized as HD symptoms on their own, the treatment is usually delayed.
The field of DNA nanotechnology has proved to be one of the fastest growing fields in synthetic biology. Recent advances have focused on the development of DNA origami, tweezer structures and various other two and three dimensional structures, with the aim of applying such structures into areas such as diagnostics, drug delivery, detection and more.
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Although commercially available RT-PCR arrays for Huntington’s disease gene targets do exist, they tend to be time-consuming and require a level of lab expertise[2] (Figure 2)
<b>Hypothesis:</b>
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According to the interviews conducted with the medical workers using various diagnostics tools, their primary concerns were the accuracy of the test and the ease of use. We hope to allow prompt treatment with our non-invasive and highly accessible diagnostic method.
Through our project, we expect to follow in the footsteps of such advancements, however taking them a step further to develop a three dimensional DNA nanostructure that can undergo an induced structural change in the presence of its specific nucleic acid targets (RNA or DNA) not solely in vitro but also in living cells after expression.
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<b>Objectives:</b>
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Our objectives would be to first prove the efficiency and accuracy of our structure in detecting its respective target in vitro with the application of various laboratory techniques, for example gel electrophoresis and colorimetric assays, followed by the expression of our DNA nanostructure in organisms, namely <i>E.coli</i>, after which the structure can be extracted and tested as well again.
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In brief, we will aim to construct a three dimensional DNA nanostructure that can be used for the detection of nucleic acid markers and explore its functionality, both in vitro and in living cells.
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<h3><center>DNA nanostructures and miRNAs as biomarkers</center><h5>
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<p>Compared to its antibody based counterparts, DNA based diagnostic device are more stable and do not require a cold-chain, the maintenance of proteins at cool
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temperature to avoid degradation[3]. DNA has emerged as a promising material that allows researchers to construct novel designs as its structure could be predicted easily and accurately[4]. Examples of DNA nanostructures
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include nano-tweezers to detect norovirus and a DNA ‘Nano-Claw’ (Figure 4) to detect membrane markers of cancer cells [5,6]
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</div><br><br><h4>Figure: Nano-Claw</h4>
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DNA Boolean logic gates have been constructed to produce signals in the
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presence of multiple targets, such as OR-gate and AND-gate DNA tetrahedra that generate fluorescence resonance energy transfer (FRET) signal when multiple inputs hybridize with the probe[7].
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<h4 style="float:right">Figure: Protein hybridization process.</h4>
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As for the targets to be detected, different microRNAs (miRNAs) have been identified to be associated with cancers. For example, miR-15b-5p, miR-338-5p, and miR-764 found in plasma are potential biomarkers for detecting hepatocellular carcinoma cancer (HCC), a common type of liver cancer[8]. It has already been reported that it is promising to use these biomarkers - miRNAs to detect cancers[9].
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<h4>Figure: Plasma levels of miR-15b-5p, miR-338-5p, and miR-764</h4>
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<p>For Huntington’s disease, Hsa-miR-34b can be used as a biomarker. This miRNA is stable in the plasma, allowing diagnosis to be carried out just by extracting small amounts of the patient’s blood. The miRNA is also elevated in pre-manifest Huntington’s Disease, which allows HD to be detected at the earliest stage possible, before the surfacing of symptoms[10].
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<p><b>References:</b></p>
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<ol>
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<li>Fo, W. (2007). Huntington’s Disease. The Lancet, 369(9557), 218-228</li>
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<li>https://www.qiagen.com/us/shop/pcr/primer-sets/rt2-profiler-pcr-arrays/?catno=PAHS-123Z#resources.</li>
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<li>Thiviyanathan, Varatharasa, and David G. Gorenstein. "Aptamers and the next generation of diagnostic reagents." PROTEOMICS-Clinical Applications 6.11-12 (2012): 563-573.</li>
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<li>Chen, Y. J., Groves, B., Muscat, R. A., & Seelig, G. (2015). DNA nanotechnology from the test tube to the cell. Nature nanotechnology, 10(9), 748-760.</li>
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<li>Nakatsuka, K., Shigeto, H., Kuroda, A., & Funabashi, H. (2015). A split G-quadruplex-based DNA nano-tweezers structure as a signal-transducing molecule for the homogeneous detection of specific nucleic acids. Biosensors and Bioelectronics, 74, 222-226. </li>
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<li>You, M., Peng, L., Shao, N., Zhang, L., Qiu, L., Cui, C., & Tan, W. (2014). DNA “nano-claw”: logic-based autonomous cancer targeting and therapy. Journal of the American Chemical Society, 136(4), 1256-1259.</li>
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<li>Pei, H., Liang, L., Yao, G., Li, J., Huang, Q., & Fan, C. (2012). Reconfigurable Three‐Dimensional DNA Nanostructures for the Construction of Intracellular Logic Sensors. Angewandte Chemie, 124(36), 9154-9158. </li>
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<li>Chen, Y., Chen, J., Liu, Y., Li, S., & Huang, P. (2015). Plasma miR-15b-5p, miR-338-5p, and miR-764 as Biomarkers for Hepatocellular Carcinoma. Medical science monitor: international medical journal of experimental and clinical research, 21, 1864. </li>
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<li>Montani, F., & Bianchi, F. (2016). Circulating Cancer Biomarkers: The Macro-revolution of the Micro-RNA. EBioMedicine, 5, 4-6.</li>
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<li>Kantcheva, R.B. (2013). Identification and analysis of genetic modifiers of mutant huntingtin toxicity in Saccharomyces cerevisiae. Diss. University of Leicester.</li>
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Latest revision as of 18:21, 1 November 2017



What is Huntington's disease?

Huntington’s disease (HD) is an inherited neurodegenerative disorder that results in the death of brain cells. Genetic mutations, namely the trinucleotide repeats in the Huntingtin gene (HTT) located on Chromosome 4, lead to the development of HD [1] . Though the disease is incurable, early diagnosis can help to better relieve symptoms by allowing treatments to start sooner. In the early stages of HD, only subtle changes in personality, cognitive and physical abilities can be identified.





Early Diagnosis of Huntington's disease

Diagnosis of HD (in cases where the parents do not have HD) is usually carried out only after symptoms are identified and the patient approaches the medical professionals. As the early symptoms are generally not severe enough to be recognized as HD symptoms on their own, the treatment is usually delayed. Although commercially available RT-PCR arrays for Huntington’s disease gene targets do exist, they tend to be time-consuming and require a level of lab expertise[2] (Figure 2) According to the interviews conducted with the medical workers using various diagnostics tools, their primary concerns were the accuracy of the test and the ease of use. We hope to allow prompt treatment with our non-invasive and highly accessible diagnostic method.








DNA nanostructures and miRNAs as biomarkers

Compared to its antibody based counterparts, DNA based diagnostic device are more stable and do not require a cold-chain, the maintenance of proteins at cool temperature to avoid degradation[3]. DNA has emerged as a promising material that allows researchers to construct novel designs as its structure could be predicted easily and accurately[4]. Examples of DNA nanostructures include nano-tweezers to detect norovirus and a DNA ‘Nano-Claw’ (Figure 4) to detect membrane markers of cancer cells [5,6]



Figure: Nano-Claw






DNA Boolean logic gates have been constructed to produce signals in the presence of multiple targets, such as OR-gate and AND-gate DNA tetrahedra that generate fluorescence resonance energy transfer (FRET) signal when multiple inputs hybridize with the probe[7].
























Figure: Protein hybridization process.








As for the targets to be detected, different microRNAs (miRNAs) have been identified to be associated with cancers. For example, miR-15b-5p, miR-338-5p, and miR-764 found in plasma are potential biomarkers for detecting hepatocellular carcinoma cancer (HCC), a common type of liver cancer[8]. It has already been reported that it is promising to use these biomarkers - miRNAs to detect cancers[9].




Figure: Plasma levels of miR-15b-5p, miR-338-5p, and miR-764






For Huntington’s disease, Hsa-miR-34b can be used as a biomarker. This miRNA is stable in the plasma, allowing diagnosis to be carried out just by extracting small amounts of the patient’s blood. The miRNA is also elevated in pre-manifest Huntington’s Disease, which allows HD to be detected at the earliest stage possible, before the surfacing of symptoms[10].




References:

  1. Fo, W. (2007). Huntington’s Disease. The Lancet, 369(9557), 218-228
  2. https://www.qiagen.com/us/shop/pcr/primer-sets/rt2-profiler-pcr-arrays/?catno=PAHS-123Z#resources.
  3. Thiviyanathan, Varatharasa, and David G. Gorenstein. "Aptamers and the next generation of diagnostic reagents." PROTEOMICS-Clinical Applications 6.11-12 (2012): 563-573.
  4. Chen, Y. J., Groves, B., Muscat, R. A., & Seelig, G. (2015). DNA nanotechnology from the test tube to the cell. Nature nanotechnology, 10(9), 748-760.
  5. Nakatsuka, K., Shigeto, H., Kuroda, A., & Funabashi, H. (2015). A split G-quadruplex-based DNA nano-tweezers structure as a signal-transducing molecule for the homogeneous detection of specific nucleic acids. Biosensors and Bioelectronics, 74, 222-226.
  6. You, M., Peng, L., Shao, N., Zhang, L., Qiu, L., Cui, C., & Tan, W. (2014). DNA “nano-claw”: logic-based autonomous cancer targeting and therapy. Journal of the American Chemical Society, 136(4), 1256-1259.
  7. Pei, H., Liang, L., Yao, G., Li, J., Huang, Q., & Fan, C. (2012). Reconfigurable Three‐Dimensional DNA Nanostructures for the Construction of Intracellular Logic Sensors. Angewandte Chemie, 124(36), 9154-9158.
  8. Chen, Y., Chen, J., Liu, Y., Li, S., & Huang, P. (2015). Plasma miR-15b-5p, miR-338-5p, and miR-764 as Biomarkers for Hepatocellular Carcinoma. Medical science monitor: international medical journal of experimental and clinical research, 21, 1864.
  9. Montani, F., & Bianchi, F. (2016). Circulating Cancer Biomarkers: The Macro-revolution of the Micro-RNA. EBioMedicine, 5, 4-6.
  10. Kantcheva, R.B. (2013). Identification and analysis of genetic modifiers of mutant huntingtin toxicity in Saccharomyces cerevisiae. Diss. University of Leicester.