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1. Exploring Toehold-Mediated Strand Displacement as a Strategy to Program DNAzyme-catalyzed Peroxidation Localized to DNA Condensates

   https://doi.org/10.5281/zenodo.17215666  

   Terkazaryan, Emily; Safar, Eliana; Khosravian, Cynthia; Mhlanga, Gracious; Rivera, Megan; Franco, Elisa; Blatti, Jillian L (January 2025, Journal of advanced technological education)

   DNA nanotechnology can be leveraged to engineer nanoscale biochemical reactions, and thus, revolutionize biomanufacturing. The programmability is encoded in the interactions between base pairs of the nucleic acids. Functional nanostructures can be envisioned and formed, such as DNA nanostars, whose properties can be fine-tuned by engineering the number of arms or base pairs per arm and can yield synthetic condensate structures, and DNA-based enzymes that exhibit peroxidase-like activity. For example, certain guanine-rich sequences of DNA can fold into a quadruplex structure, bind a hemin co-factor, and catalyze a peroxidation reaction in which the substrate ABTS (2,2’-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid)) gets oxidized by hydrogen peroxide and results in a colorimetric change. Because ABTS produces a blue-green color change upon oxidation, it can be used to visually observe the peroxidation reaction taking place within the DNA condensates. In this work, peroxidase-mimicking DNAzymes were used to catalyze colorimetric peroxidation within DNA condensate compartments; and toehold-mediated strand displacement (TMSD) was explored as a strategy to program the peroxidation reaction–specifically, by unwinding the G-quadruplex structure, which would effectively turn the reaction “off”. TMSD is a method of designing a single strand of DNA with an additional overhang region, called a toehold, to oust and replace a second strand attached to the toehold-possessing target strand. The presence of complementary toeholds on both the invading strand and the target strand increases the thermodynamic probability of displacing the single DNA strand originally bound to the target. Here, TMSD was adapted for use in ‘turning off’ the DNAzyme-catalyzed peroxidation reaction, either by preventing folding or disrupting the folded structure of the DNAzyme. A displacer strand complementary to the DNAzyme/toehold region was designed and added to the reaction mixture at different time points and concentrations for this purpose. Elucidating mechanisms to unwind the G-quadruplex structure of DNAzymes has promise in treating genetic disorders caused by unregulated G4 formation in the human genome. Furthermore, DNA nanotechnology can be used to compartmentalize, functionalize, and program the release of bioactive molecules in drug delivery strategies and other synthetic biology applications, highlighting the potential of TMSD to program DNA-based bioreactors. This high-impact study, carried out as part of the NSF Future Manufacturing program at Pasadena City College in collaboration with UCLA, UCSB, and Caltech, allowed undergraduate researchers to design and conduct their own experiments within a community college setting after undergoing scientific training by graduate students and postdocs from our collaborators’ institutions. \n\nIt also provided opportunities to communicate the scientific research through writing, poster presentations at national conferences, and teaching in courses and STEM outreach. The student researchers of the PCC nanostar program applied their knowledge in a classroom setting, where they taught other undergraduate students how to conduct aspects of this research in a General, Organic and Biochemistry laboratory course at PCC. This article underscores the importance of creating significant research and teaching opportunities for students as they begin their careers in STEM, impactful mentorship through undergraduate research, and the creativity involved in modern synthetic biology research and in the development of accessible and innovative science lessons. 

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2. Molecular Visualization in Nanotechnology Education, Research, and Outreach: Simulating Catalytic DNA Nanostars Using oxDNA

   https://doi.org/10.5281/zenodo.17041760  

   Blatti, Jillian L; Blatti, Jillian L; Terkazaryan, Emily; Salman, Reina; Paredes, Fabiana; Gonzalez, Vanessa; Safar, Eliana; Lam_Yu, Wing; Rivera, Megan; Mhlanga, Gracious; et al (January 2025, Journal of advanced technological education)

   Through the NSF Future Manufacturing undergraduate research program at Pasadena City College (PCC), students utilize the tools of synthetic biology to build sustainable, DNA-based materials. The manipulation of DNA enables the construction of microscopic biochemical reactors through the formation of liquid-liquid phase-separated droplets, or DNA condensates. This research investigates the potential of DNA nanostars fused with G-tetraplexes, which can bind hemin, an iron-containing porphyrin co-factor, to form a DNAzyme capable of catalyzing peroxidation reactions within single condensate layers. The in vitro component of this research was enhanced by in silico coarse-grained molecular dynamics simulations, which generated 3D models of the DNA nanostars that allowed student researchers to visualize the behavior of the structures created in the laboratory. Leveraging this computational technique, student researchers developed educational resources and modular lessons to introduce these molecular simulations to a broad student audience at PCC. The simulation programs used, oxDNA and oxView, were instrumental in making this research accessible and engaging for diverse student groups. DNA nanostar simulations were integrated into the General, Organic, and Biochemistry curriculum at PCC, as well as during outreach events such as Girls Science Day, offering students insights into DNA nanostar dynamics and potential applications of DNA-based inventions. This paper details the use of simulation programs to recreate nucleic acid-based nanostructures, advancing the field of DNA nanotechnology. Molecular simulations helped the PCC research students develop experiments that demonstrate how enzymatic activity within DNA droplets can be achieved through G4 complexing. Simulating DNA nanostars with G4s was a profound educational exercise for students, as it taught them about the powerful synergy between in silico and in vitro experimentation. Students also learned about the limitations of modeling biomolecules using computational software, and our G4 simulation results may even inspire the integration of guanine-guanine interactions into the oxDNA program. These findings underscore the significant implications of in silico modeling and structural analysis in biochemical manufacturing and industrial applications, paving the way for further innovations in programmable biomolecular systems. By developing YouTube tutorials that teach students how to carry out nucleic acid simulations on any standard computer, the exploration of DNA dynamics and molecular programming is now widely accessible to both students and educators. 

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3. Calcium-Dependent Chemiluminescence Catalyzed by a Truncated c-MYC Promoter G-Triplex DNA

   https://doi.org/10.3390/molecules29184457  

   Das, Malay Kumar; Williams, Elizabeth P; Myhre, Mitchell W; David, Wendi M; Kerwin, Sean M (September 2024, Molecules)

   The dynamic landscape of non-canonical DNA G-quadruplex (G4) folding into G-triplex intermediates has led to the study of G-triplex structures and their ability to serve as peroxidase-mimetic DNAzymes. Here we report the formation, stability, and catalytic activity of a 5′-truncated c-MYC promoter region G-triplex, c-MYC-G3. Through circular dichroism, we demonstrated that c-MYC-G3 adopts a stable, parallel-stranded G-triplex conformation. The chemiluminescent oxidation of luminol by the peroxidase mimicking DNAzyme activity of c-MYC-G3 was increased in the presence of Ca2+ ions. We utilized surface plasmon resonance to characterize both c-MYC-G3 G-triplex formation and its interaction with hemin. The detailed study of c-MYC-G3 and its ability to form a G-triplex structure and its DNAzyme activity identifies issues that can be addressed in future G-triplex DNAzyme designs. 

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4. G-quadruplexes catalyze protein folding by reshaping the energetic landscape

   https://doi.org/10.1073/pnas.2414045122  

   Huang, Zijue; Ghosh, Kingshuk; Stull, Frederick; Horowitz, Scott (February 2025, Proceedings of the National Academy of Sciences)

   Many proteins have slow folding times in vitro that are physiologically untenable. To combat this challenge, ATP-dependent chaperonins are thought to possess the unique ability to catalyze protein folding. Performing quantitative model selection using protein folding and unfolding data, we here show that short nucleic acids containing G-quadruplex (G4) structure can also catalyze protein folding. Performing the experiments as a function of temperature demonstrates that the G4 reshapes the underlying driving forces of protein folding. As short nucleic acids can catalyze protein folding without the input of ATP, the ability of the cell to fold proteins is far higher than previously anticipated. 

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5. Antigenic Variation in Neisseria gonorrhoeae Occurs Independently of RecQ-Mediated Unwinding of the pilE G Quadruplex

   https://doi.org/10.1128/JB.00607-19  

   Voter, Andrew F.; Callaghan, Melanie M.; Tippana, Ramreddy; Myong, Sua; Dillard, Joseph P.; Keck, James L.; Stock, Ann M. (January 2020, Journal of Bacteriology)

   ABSTRACT The obligate human pathogen Neisseria gonorrhoeae alters its cell surface antigens to evade the immune system in a process known as antigenic variation (AV). During pilin AV, portions of the expressed pilin gene ( pilE ) are replaced with segments of silent pilin genes ( pilS ) through homologous recombination. The pilE-pilS exchange is initiated by formation of a parallel guanine quadruplex (G4) structure near the pilE gene, which recruits the homologous recombination machinery. The RecQ helicase, which has been proposed to aid AV by unwinding the pilE G4 structure, is an important component of this machinery. However, RecQ also promotes homologous recombination through G4-independent duplex DNA unwinding, leaving the relative importance of its G4 unwinding activity unclear. Previous investigations revealed a guanine-specific pocket (GSP) on the surface of RecQ that is required for G4, but not duplex, DNA unwinding. To determine whether RecQ-mediated G4 resolution is required for AV, N. gonorrhoeae strains that encode a RecQ GSP variant that cannot unwind G4 DNA were created. In contrast to the hypothesis that G4 unwinding by RecQ is important for AV, the RecQ GSP variant N. gonorrhoeae strains had normal AV levels. Analysis of a purified RecQ GSP variant confirmed that it retained duplex DNA unwinding activity but had lost its ability to unwind antiparallel G4 DNA. Interestingly, neither the GSP-deficient RecQ variant nor the wild-type RecQ could unwind the parallel pilE G4 nor the prototypical c- myc G4. Based on these results, we conclude that N. gonorrhoeae AV occurs independently of RecQ-mediated pilE G4 resolution. IMPORTANCE The pathogenic bacteria Neisseria gonorrhoeae avoids clearance by the immune system through antigenic variation (AV), the process by which immunogenic surface features of the bacteria are exchanged for novel variants. RecQ helicase is critical in AV and its role has been proposed to stem from its ability to unwind a DNA secondary structure known as a guanine quadruplex (G4) that is central to AV. In this work, we demonstrate that the role of RecQ in AV is independent of its ability to resolve G4s and that RecQ is incapable of unwinding the G4 in question. We propose a new model of RecQ’s role in AV where the G4 might recruit or orient RecQ to facilitate homologous recombination. 

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