Your search keyword '"Biomolecular engineering"' showing total 31 results

1. Directed evolution of an orthogonal transcription engine for programmable gene expression in eukaryotes

Author

Kar, Shaunak, Gardner, Elizabeth C., Javanmardi, Kamyab, Boutz, Daniel R., Shroff, Raghav, Horton, Andrew P., Segall-Shapiro, Thomas H., Ellington, Andrew D., and Gollihar, Jimmy

Published

2025

2. Understanding microbial biomineralization at the molecular level: recent advances.

Author

Debnath, Ankita, Mitra, Sayak, Ghosh, Supratit, and Sen, Ramkrishna

Subjects

*BIOMIMETIC synthesis, *BIOMINERALIZATION, *BIOINORGANIC chemistry, *MICROBIAL cells, *CELL morphology, *BIOMIMETIC materials

Abstract

Microbial biomineralization is a phenomenon involving deposition of inorganic minerals inside or around microbial cells as a direct consequence of biogeochemical cycling. The microbial metabolic processes often create environmental conditions conducive for the precipitation of silicate, carbonate or phosphate, ferrate forms of ubiquitous inorganic ions. Till date the fundamental mechanisms underpinning two of the major types of microbial biomineralization such as, microbially controlled and microbially induced remains poorly understood. While microbially-controlled mineralization (MCM) depends entirely on the genetic makeup of the cell, microbially-induced mineralization (MIM) is dependent on factors such as cell morphology, cell surface structures and extracellular polymeric substances (EPS). In recent years, the organic template-mediated nucleation of inorganic minerals has been considered as an underlying mechanism based on the principles of solid-state bioinorganic chemistry. The present review thus attempts to provide a comprehensive and critical overview on the recent progress in holistic understanding of both MCM and MIM, which involves, organic–inorganic biomolecular interactions that lead to template formation, biomineral nucleation and crystallization. Also, the operation of specific metabolic pathways and molecular operons in directing microbial biomineralization have been discussed. Unravelling these molecular mechanisms of biomineralization can help in the biomimetic synthesis of minerals for potential therapeutic applications, and facilitating the engineering of microorganisms for commercial production of biominerals. [ABSTRACT FROM AUTHOR]

Published

2024

3. Efficient proximal tubule-on-chip model from hiPSC-derived kidney organoids for functional analysis of renal transporters

Author

Cheng Ma, Ramin Banan Sadeghian, Ryosuke Negoro, Kazuya Fujimoto, Toshikazu Araoka, Naoki Ishiguro, Minoru Takasato, and Ryuji Yokokawa

Subjects

Biomolecular Engineering, Molecular biology experimental approach, Science

Abstract

Summary: Renal transporters play critical roles in predicting potential drug-drug interactions. However, current in vitro models often fail to adequately express these transporters, particularly solute carrier proteins, including organic anion transporters (OAT1/3), and organic cation transporter 2 (OCT2). Here, we developed a hiPSC-derived kidney organoids-based proximal tubule-on-chip (OPTC) model that emulates in vivo renal physiology to assess transporter function. Compared to chips based on immortalized cells, OPTC derived from the two most commonly used differentiation protocols exhibited significant improvement in expression level and polarity of OAT1/3 and OCT2. Hence, the OPTC demonstrates enhanced functionality in efflux and uptake assessments, and nephrotoxicity. Furthermore, these functionalities are diminished upon adding inhibitors during substrate-inhibitor interactions, which were closer to in vivo observations. Overall, these results support that OPTC can reliably assess the role of renal transporters in drug transport and nephrotoxicity, paving the way for personalized models to assess renal transport and disease modeling.

Published

2024

4. Supramolecular DNA-based catalysis in organic solvents

Author

Gurudas Chakraborty, Konstantin Balinin, Rafael del Villar-Guerra, Meike Emondts, Giuseppe Portale, Mark Loznik, Wiebe Jacob Niels Klement, Lifei Zheng, Tanja Weil, Jonathan B. Chaires, and Andreas Herrmann

Subjects

Chemistry, Catalysis, Biomolecular engineering, Science

Abstract

Summary: The distinct folding accompanied by its polymorphic character renders DNA G-quadruplexes promising biomolecular building blocks to construct novel DNA-based and supramolecular assemblies. However, the highly polar nature of DNA limits the use of G-quadruplexes to water as a solvent. In addition, the archetypical G-quadruplex fold needs to be stabilized by metal-cations, which is usually a potassium ion. Here, we show that a noncovalent PEGylation process enabled by electrostatic interactions allows the first metal-free G-quadruplexes in organic solvents. Strikingly, incorporation of an iron-containing porphyrin renders the self-assembled metal-free G-quadruplex catalytically active in organic solvents. Hence, these “supraG4zymes” enable DNA-based catalysis in organic media. The results will allow the broad utilization of DNA G-quadruplexes in nonaqueous environments.

Published

2024

5. Bioengineering and Bioprocessing of Virus-Like Particle Vaccines in Escherichia coli

Author

Abidin, Rufika S., Sainsbury, Frank, Steinbüchel, Alexander, Series Editor, Rehm, Bernd H. A., editor, and Wibowo, David, editor

Published

2022

6. Targeting extracellular CIRP with an X-aptamer shows therapeutic potential in acute pancreatitis

Author

Wuming Liu, Jianbin Bi, Yifan Ren, Huan Chen, Jia Zhang, Tao Wang, Mengzhou Wang, Lin Zhang, Junzhou Zhao, Zheng Wu, Yi Lv, Bing Liu, and Rongqian Wu

Subjects

Biomolecular engineering, Cell biology, Molecular physiology, Pathophysiology, Science

Abstract

Summary: Severe acute pancreatitis (AP) is associated with a high mortality rate. Cold-inducible RNA binding protein (CIRP) can be released from cells in inflammatory conditions and extracellular CIRP acts as a damage-associated molecular pattern. This study aims to explore the role of CIRP in the pathogenesis of AP and evaluate the therapeutic potential of targeting extracellular CIRP with X-aptamers. Our results showed that serum CIRP concentrations were significantly increased in AP mice. Recombinant CIRP triggered mitochondrial injury and ER stress in pancreatic acinar cells. CIRP−/− mice suffered less severe pancreatic injury and inflammatory responses. Using a bead-based X-aptamer library, we identified an X-aptamer that specifically binds to CIRP (XA-CIRP). Structurally, XA-CIRP blocked the interaction between CIRP and TLR4. Functionally, it reduced CIRP-induced pancreatic acinar cell injury in vitro and L-arginine-induced pancreatic injury and inflammation in vivo. Thus, targeting extracellular CIRP with X-aptamers may be a promising strategy to treat AP.

Published

2023

7. Biotechnology applications of proteins functionalized with DNA oligonucleotides.

Author

Gokulu, Ipek Simay and Banta, Scott

Subjects

*PROTEIN biotechnology, *PROTEOMICS, *PEPTIDES, *DNA, *CHIMERIC proteins, *OLIGONUCLEOTIDES

Abstract

The functionalization of proteins with DNA through the formation of covalent bonds enables a wide range of biotechnology advancements. For example, single-molecule analytical methods rely on bioconjugated DNA as elastic biolinkers for protein immobilization. Labeling proteins with DNA enables facile protein identification, as well as spatial and temporal organization and control of protein within DNA–protein networks. Bioconjugation reactions can target native, engineered, and non-canonical amino acids (NCAAs) within proteins. In addition, further protein engineering via the incorporation of peptide tags and self-labeling proteins can also be used for conjugation reactions. The selection of techniques will depend on application requirements such as yield, selectivity, conjugation position, potential for steric hindrance, cost, commercial availability, and potential impact on protein function. The formation of covalent bonds between proteins and DNA has become an important step in a number of emerging biotechnological applications. Native amino acids can be targeted for DNA conjugation, however, this approach can suffer from poor selectivity. Protein engineering, ranging from single site-directed amino acid changes, to non-canonical amino acid incorporation, to the creation of fusion proteins, can be used to increase conjugation selectivities. More advanced conjugation strategies have been developed but these can require expensive oligonucleotide modifications and can suffer from lower yields. The optimal conjugation technique for each application may differ based on limiting factors such as yield, selectivity, flexibility in conjugation position, steric hindrance, cost, commercial availability of oligonucleotides, and risk of altering native protein properties. [ABSTRACT FROM AUTHOR]

Published

2023

8. R3Design: deep tertiary structure-based RNA sequence design and beyond.

Author

Tan C, Zhang Y, Gao Z, Cao H, Li S, Ma S, Blanchette M, and Li SZ

Subjects

Computational Biology methods, RNA Folding, Sequence Analysis, RNA methods, Algorithms, Base Sequence, RNA chemistry, RNA genetics, Nucleic Acid Conformation, Software

Abstract

The rational design of Ribonucleic acid (RNA) molecules is crucial for advancing therapeutic applications, synthetic biology, and understanding the fundamental principles of life. Traditional RNA design methods have predominantly focused on secondary structure-based sequence design, often neglecting the intricate and essential tertiary interactions. We introduce R3Design, a tertiary structure-based RNA sequence design method that shifts the paradigm to prioritize tertiary structure in the RNA sequence design. R3Design significantly enhances sequence design on native RNA backbones, achieving high sequence recovery and Macro-F1 score, and outperforming traditional secondary structure-based approaches by substantial margins. We demonstrate that R3Design can design RNA sequences that fold into the desired tertiary structures by validating these predictions using advanced structure prediction models. This method, which is available through standalone software, provides a comprehensive toolkit for designing, folding, and evaluating RNA at the tertiary level. Our findings demonstrate R3Design's superior capability in designing RNA sequences, which achieves around $44\%$ in terms of both recovery score and Macro-F1 score in multiple datasets. This not only denotes the accuracy and fairness of the model but also underscores its potential to drive forward the development of innovative RNA-based therapeutics and to deepen our understanding of RNA biology., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

9. Mixed-surface polyamidoamine polymer variants retain nucleic acid-scavenger ability with reduced toxicity

Author

Lyra B. Olson, Nicole I. Hunter, Rachel E. Rempel, Haixiang Yu, Diane M. Spencer, Cynthia Z. Sullenger, William S. Greene, Anastasia K. Varanko, Seyed A. Eghtesadi, Ashutosh Chilkoti, David S. Pisetsky, Jeffrey I. Everitt, and Bruce A. Sullenger

Subjects

Immunology, Biomolecular engineering, Nanotechnology, Science

Abstract

Summary: Nucleic acid-binding polymers can have anti-inflammatory properties and beneficial effects in animal models of infection, trauma, cancer, and autoimmunity. PAMAM G3, a polyamidoamine dendrimer, is fully cationic bearing 32 protonable surface amines. However, while PAMAM G3 treatment leads to improved outcomes for mice infected with influenza, at risk of cancer metastasis, or genetically prone to lupus, its administration can lead to serosal inflammation and elevation of biomarkers of liver and kidney damage. Variants with reduced density of cationic charge through the interspersal of hydroxyl groups were evaluated as potentially better-tolerated alternatives. Notably, the variant PAMAM G3 50:50, similar in size as PAMAM G3 but with half the charge, was not toxic in cell culture, less associated with weight loss or serosal inflammation after parenteral administration, and remained effective in reducing glomerulonephritis in lupus-prone mice. Identification of such modified scavengers should facilitate their development as safe and effective anti-inflammatory agents.

Published

2022

10. Are museums the future of evolutionary medicine?

Author

Philippe Charlier, Virginie Bourdin, Anaïs Augias, Luc Brun, Jean-Blaise Kenmogne, and Erol Josue

Subjects

paleogenetics, paleomicrobiome, evolutionary medicine, paleopathology, biomolecular engineering, Genetics, QH426-470

Published

2022

11. NYU Tandon researchers create microchips capable of detecting and diagnosing diseases.

Abstract

NYU Tandon researchers have developed microchips capable of detecting multiple diseases from a single cough or air sample, revolutionizing healthcare diagnostics. These microchips use field-effect transistors (FETs) to detect biological markers and offer faster results, simultaneous testing for multiple diseases, and immediate data transmission to healthcare providers. The researchers are exploring new ways to modify FET surfaces to enable parallel detection of multiple pathogens, with breakthrough technology like thermal scanning probe lithography (tSPL) showing promise in achieving this goal. The study, supported by industry partners, demonstrates the potential for creating portable diagnostic devices that could be used in various settings, from hospitals to homes. [Extracted from the article]

Published

2025

12. Engineering salt-tolerant Cas12f1 variants for gene-editing applications.

Author

Daskalakis V and Papapetros S

Subjects

CRISPR-Cas Systems, Protein Engineering methods, Mutation, Models, Molecular, Protein Domains, Salt Tolerance genetics, Bacterial Proteins genetics, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Gene Editing methods, CRISPR-Associated Proteins genetics, CRISPR-Associated Proteins metabolism

Abstract

CRISPR has revolutionized the field of genome editing in life sciences by serving as a versatile and state-of-the-art tool. Cas12f1 is a small nuclease of the bacterial immunity CRISPR system with an ideal size for cellular delivery, in contrast to CRISPR-associated (Cas) proteins like Cas9 or Cas12. However, Cas12f1 works best at low salt concentrations. In this study, we find that the plasticity of certain Cas12f1 regions (K196-Y202 and I452-L515) is negatively affected by increased salt concentrations. On this line, key protein domains (REC1, WED, Nuc, lid) that are involved in the DNA-target recognition and the activation of the catalytic RuvC domain are in turn also affected. We suggest that salt concentration should be taken in to consideration for activity assessments of Cas engineered variants, especially if the mutations are on the protospacer adjacent motif interacting domain. The results can be exploited for the engineering of Cas variants and the assessment of their activity at varying salt concentrations. We propose that the K198Q mutation can restore at great degree the compromised plasticity and could potentially lead to salt-tolerant Cas12f1 variants. The methodology can be also employed for the study of biomolecules in terms of their salinity tolerance.Communicated by Ramaswamy H. Sarma.

Published

2024

13. Efficient proximal tubule-on-chip model from hiPSC-derived kidney organoids for functional analysis of renal transporters.

Author

Ma C, Banan Sadeghian R, Negoro R, Fujimoto K, Araoka T, Ishiguro N, Takasato M, and Yokokawa R

Abstract

Renal transporters play critical roles in predicting potential drug-drug interactions. However, current in vitro models often fail to adequately express these transporters, particularly solute carrier proteins, including organic anion transporters (OAT1/3), and organic cation transporter 2 (OCT2). Here, we developed a hiPSC-derived kidney organoids-based proximal tubule-on-chip (OPTC) model that emulates in vivo renal physiology to assess transporter function. Compared to chips based on immortalized cells, OPTC derived from the two most commonly used differentiation protocols exhibited significant improvement in expression level and polarity of OAT1/3 and OCT2. Hence, the OPTC demonstrates enhanced functionality in efflux and uptake assessments, and nephrotoxicity. Furthermore, these functionalities are diminished upon adding inhibitors during substrate-inhibitor interactions, which were closer to in vivo observations. Overall, these results support that OPTC can reliably assess the role of renal transporters in drug transport and nephrotoxicity, paving the way for personalized models to assess renal transport and disease modeling., Competing Interests: R.Y., C.M., R.B.S., K.F., T.A., M.T., and R.N. are inventors on JP patent application no. 2024–73489 “Construction of proximal tubules micro-physiological system”., (© 2024 The Author(s).)

Published

2024

14. Are museums the future of evolutionary medicine?

Author

Charlier, Philippe, Bourdin, Virginie, Augias, Anaïs, Brun, Luc, Kenmogne, Jean-Blaise, and Josue, Erol

Subjects

MUSEUMS, PALEOPATHOLOGY

Published

2022

15. Patent Issued for Engineered gyri-like mutein aptamers, and related methods (USPTO 12104201).

Abstract

Crosslife Technologies Inc. has been issued a patent for engineered gyri-like mutein aptamers, which are non-native variant proteins designed from the Gyrl-like family of proteins. These aptamers, known as GYRAPTs or GYRYZYMEs, can bind to various target organic molecules and function as on/off bioswitches. The patent outlines methods for creating these aptamers through rational mutagenesis or mutant library screening, highlighting their potential applications in molecular imaging, diagnostics, and therapeutics. The Gyrl-like proteins used as scaffolds for these aptamers are small-molecule binding proteins found in prokaryotes and eukaryotes, offering a versatile platform for designing novel biotechnological tools. [Extracted from the article]

Published

2024

16. Researchers develop affordable, rapid blood test for brain cancer.

Abstract

Researchers at the University of Notre Dame have developed an automated device that can diagnose glioblastoma, a fast-growing and incurable brain cancer, in less than an hour. The device uses a biochip that utilizes electrokinetic technology to detect biomarkers, specifically active Epidermal Growth Factor Receptors (EGFRs), which are overexpressed in certain cancers like glioblastoma. The biochip is able to distinguish between active and non-active EGFRs and is sensitive and selective in detecting active EGFRs on extracellular vesicles from blood samples. The device has the potential to be adapted for detecting other types of biological nanoparticles and biomarkers for different diseases. [Extracted from the article]

Published

2024

17. Electrochemical biosensing interfaced with cell-free synthetic biology.

Author

Wang, Baoguo, Zhao, Jinming, Zhang, Jiayin, Wei, Tianxiang, Han, Kun, and Gao, Tao

Subjects

*BIOENGINEERING, *SYNTHETIC biology, *MICROBIAL fuel cells, *ELECTRONIC equipment, *ENGINEERING, *BIOSENSORS, *ELECTRODES

Abstract

Synthetic biology's multiscale approaches to biosensing facilitate biological detection across diverse environments, leading to the development of advanced bio/electronic devices that convert biological events into electrical signals. Electrochemical biosensors are particularly promising due to their cost-effectiveness, ease of fabrication, and potential for miniaturization. Cell-free synthetic biology (CFSB) utilizes cell-free biological components to engineer and mimic the behavior, functions, and characteristics of cell systems, providing versatile approaches to bioengineering beyond cellular contexts. Engineering electrode surface with the principles of CFSB systems may represent a cutting-edge research direction for electrochemical biosensing, potentially solving bioanalytical issues of selectivity, sensitivity, and biocompatibility. This review highlights the latest trends in creating biosensing electrodes with CFSB components, as categorized by transcriptional, translational, and novel CFSB types. It provides a comprehensive analysis of the benefits and challenges of engineering CFSB components on electrode surfaces, aiming to inspire the future integration of CFSB technologies into electrochemical biosensing research. • Description of the role of cell-free synthetic biology (CFBS) system for bioelectronic surface engineering. • Categorizing and discussing advantages and challenges the CFSB systems for the development of electrochemical biosensors. • Providing new insights on biomolecular engineering of electrode surface for enhanced bioanalytical performance. [ABSTRACT FROM AUTHOR]

Published

2024

18. Uncovering the relationship between macrophages and polypropylene surgical mesh.

Author

Farr NTH, Workman VL, Saad S, Roman S, Hearnden V, Chapple CR, Murdoch C, Rodenburg C, and MacNeil S

Subjects

Humans, Materials Testing, Polypropylenes chemistry, Biocompatible Materials, Macrophages, Surgical Mesh adverse effects, Urinary Incontinence, Stress surgery

Abstract

Currently, in vitro testing examines the cytotoxicity of biomaterials but fails to consider how materials respond to mechanical forces and the immune response to them; both are crucial for successful long-term implantation. A notable example of this failure is polypropylene mid-urethral mesh used in the treatment of stress urinary incontinence (SUI). The mesh was largely successful in abdominal hernia repair but produced significant complications when repurposed to treat SUI. Developing more physiologically relevant in vitro test models would allow more physiologically relevant data to be collected about how biomaterials will interact with the body. This study investigates the effects of mechanochemical distress (a combination of oxidation and mechanical distention) on polypropylene mesh surfaces and the effect this has on macrophage gene expression. Surface topology of the mesh was characterised using SEM and AFM; ATR-FTIR, EDX and Raman spectroscopy was applied to detect surface oxidation and structural molecular alterations. Uniaxial mechanical testing was performed to reveal any bulk mechanical changes. RT-qPCR of selected pro-fibrotic and pro-inflammatory genes was carried out on macrophages cultured on control and mechanochemically distressed PP mesh. Following exposure to mechanochemical distress the mesh surface was observed to crack and craze and helical defects were detected in the polymer backbone. Surface oxidation of the mesh was seen after macrophage attachment for 7 days. These changes in mesh surface triggered modified gene expression in macrophages. Pro-fibrotic and pro-inflammatory genes were upregulated after macrophages were cultured on mechanochemically distressed mesh, whereas the same genes were down-regulated in macrophages exposed to control mesh. This study highlights the relationship between macrophages and polypropylene surgical mesh, thus offering more insight into the fate of an implanted material than existing in vitro testing., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

19. Supramolecular DNA-based catalysis in organic solvents.

Author

Chakraborty G, Balinin K, Villar-Guerra RD, Emondts M, Portale G, Loznik M, Niels Klement WJ, Zheng L, Weil T, Chaires JB, and Herrmann A

Abstract

The distinct folding accompanied by its polymorphic character renders DNA G-quadruplexes promising biomolecular building blocks to construct novel DNA-based and supramolecular assemblies. However, the highly polar nature of DNA limits the use of G-quadruplexes to water as a solvent. In addition, the archetypical G-quadruplex fold needs to be stabilized by metal-cations, which is usually a potassium ion. Here, we show that a noncovalent PEGylation process enabled by electrostatic interactions allows the first metal-free G-quadruplexes in organic solvents. Strikingly, incorporation of an iron-containing porphyrin renders the self-assembled metal-free G-quadruplex catalytically active in organic solvents. Hence, these "supraG4zymes" enable DNA-based catalysis in organic media. The results will allow the broad utilization of DNA G-quadruplexes in nonaqueous environments., Competing Interests: The authors declare no competing interests., (© 2024 The Author(s).)

Published

2024

20. Solving an age-old mystery about crystal formation.

Abstract

A recent publication in PNAS by Peter Vekilov, a researcher at the University of Houston, has shed light on the process of crystal formation and how molecules become a part of them. Vekilov's research utilized advanced experimental techniques to uncover that incorporation into crystal kinks occurs in two steps, with an intermediate state playing a crucial role in the stability and growth of crystals. This discovery challenges previous theories and could aid in understanding the influence of small parts in a liquid on the shapes of natural crystals. The findings have implications for various fields, including bioengineering, nanobiotechnology, and emerging technologies. [Extracted from the article]

Published

2024

21. Mitochondrial protein plays key role in glioblastoma and therapeutic resistance.

Subjects

MITOCHONDRIAL proteins, BRAIN tumors, GLIOBLASTOMA multiforme

Abstract

Out of 577 samples, they found that the CHCHD2 genes had higher expression in tumor cells, compared to non-tumor tissue, and was higher in advanced cases of glioblastoma. Keywords: Animal Science; Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; Cancer; Carl R. Woese Institute for Genomic Biology University of Illinois at Urbana-Champaign; Drugs and Therapies; Emerging Technologies; Engineering; Genetics; Glioblastomas; Health and Medicine; Mitochondrial Proteins; Nanobiotechnology; Nanotechnology; Oncology; Therapeutics; Therapy EN Animal Science Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology Cancer Carl R. Woese Institute for Genomic Biology University of Illinois at Urbana-Champaign Drugs and Therapies Emerging Technologies Engineering Genetics Glioblastomas Health and Medicine Mitochondrial Proteins Nanobiotechnology Nanotechnology Oncology Therapeutics Therapy 607 607 1 10/30/23 20231030 NES 231030 2023 OCT 31 (NewsRx) -- By a News Reporter-Staff News Editor at Veterinary Week -- Glioblastoma is the most common type of brain tumor that affects adults and, unfortunately, still remains incurable. [Extracted from the article]

Published

2023

22. Drug-filled nanocapsule helps make immunotherapy more effective in mice.

Abstract

To achieve that goal, the team developed a treatment encapsulating an enzyme called lactate oxidase into a tiny nanocapsule that reduces lactate levels and releases hydrogen peroxide in the tumor. Keywords: Anions; Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; Cancer; Chemicals; Drug Delivery Systems; Drugs and Therapies; Electrolytes; Elements; Emerging Technologies; Engineering; Enzymes and Coenzymes; Gases; Genetics; Health and Medicine; Hydrogen; Hydrogen Peroxide; Immunotherapy; Inorganic Chemicals; Ions; Nanobiotechnology; Nanocapsules; Nanotechnology; Oncology; Organic Chemicals; Oxidase; Oxides; Peroxides; Reactive Oxygen Species; Solid Cancer; University of California - Los Angeles Health Sciences EN Anions Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology Cancer Chemicals Drug Delivery Systems Drugs and Therapies Electrolytes Elements Emerging Technologies Engineering Enzymes and Coenzymes Gases Genetics Health and Medicine Hydrogen Hydrogen Peroxide Immunotherapy Inorganic Chemicals Ions Nanobiotechnology Nanocapsules Nanotechnology Oncology Organic Chemicals Oxidase Oxides Peroxides Reactive Oxygen Species Solid Cancer University of California - Los Angeles Health Sciences 287 287 1 10/24/23 20231024 NES 231024 2023 OCT 24 (NewsRx) -- By a News Reporter-Staff News Editor at Immunotherapy Weekly -- UCLA researchers have developed a new treatment method using a tiny nanocapsule to help boost the immune response, making it easier for the immune system to fight and kill solid tumors. "Moreover, this dual-action approach improved the success of a specific type of cancer immunotherapy treatment called immune checkpoint blockade and we believe it could be an effective strategy to help make cancer immunotherapy more effective.". [Extracted from the article]

Published

2023

23. Lehigh University researchers make sand that flows uphill.

Abstract

Bioengineering, Biomolecular Engineering, Bionanotechnology, Biotechnology, Emerging Technologies, Engineering, Lehigh University, Nanobiotechnology, Nanotechnology Keywords: Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; Emerging Technologies; Engineering; Lehigh University; Nanobiotechnology; Nanotechnology EN Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology Emerging Technologies Engineering Lehigh University Nanobiotechnology Nanotechnology 2542 2542 1 10/03/23 20231006 NES 231006 2023 OCT 6 (NewsRx) -- By a News Reporter-Staff News Editor at Health & Medicine Week -- Engineering researchers at Lehigh University have discovered that sand can actually flow uphill. [Extracted from the article]

Published

2023

24. With $5 million grant, the Welch Center for Advanced Bioactive Materials Crystallization is formed at University of Houston.

Abstract

Keywords: Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; Chemical Engineering; Chemistry; Emerging Technologies; Engineering; Nanobiotechnology; Nanoparticles; Nanotechnology; University of Houston EN Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology Chemical Engineering Chemistry Emerging Technologies Engineering Nanobiotechnology Nanoparticles Nanotechnology University of Houston 1703 1703 1 09/25/23 20230929 NES 230929 2023 SEP 29 (NewsRx) -- By a News Reporter-Staff News Editor at Genomics & Genetics Weekly -- Jeffrey Rimer, Abraham E. Dukler Professor of Chemical Engineering, known globally for his seminal breakthroughs that control crystals to help treat malaria and kidney stones, has been awarded an inaugural $5 million Catalyst for Discovery Program Grant from The Welch Foundation, to establish the Welch Center for Advanced Bioactive Materials Crystallization. Bioengineering, Biomolecular Engineering, Bionanotechnology, Biotechnology, Chemical Engineering, Chemistry, Emerging Technologies, Engineering, Nanobiotechnology, Nanoparticles, Nanotechnology, University of Houston. [Extracted from the article]

Published

2023

25. Celebrating excellence: Inaugural cohort of UH-Chevron Energy Graduate Fellows.

Abstract

Keywords: Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; Chemical Engineering; Chemicals; Clean Energy; Deep Learning; Elements; Emerging Technologies; Energy; Energy Generation; Energy Industry; Engineering; Environment; Environmental Engineering; Gases; Geophysics; Hospitals; Hydrogen; India; Inorganic Chemicals; Machine Learning; Mathematics; Nanobiotechnology; Nanotechnology; Oil & Gas; Petroleum Engineering; Physics; Politics; Renewable Energy; Science And Engineering; Sustainability Research; Sustainable Energy; University of Houston EN Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology Chemical Engineering Chemicals Clean Energy Deep Learning Elements Emerging Technologies Energy Energy Generation Energy Industry Engineering Environment Environmental Engineering Gases Geophysics Hospitals Hydrogen India Inorganic Chemicals Machine Learning Mathematics Nanobiotechnology Nanotechnology Oil & Gas Petroleum Engineering Physics Politics Renewable Energy Science And Engineering Sustainability Research Sustainable Energy University of Houston 1030 1030 1 09/11/23 20230917 NES 230917 2023 SEP 17 (NewsRx) -- By a News Reporter-Staff News Editor at Medical Letter on the CDC & FDA -- University of Houston, the Energy University, is proud to introduce the inaugural cohort of UH-Chevron Energy Graduate Fellows - eight graduate students who are actively involved in innovative energy-related research across the UH campus. The potential impact of this research extends to renewable energy generation, electric power transmission and advanced scientific applications, all of which contribute to a sustainable clean energy future. [Extracted from the article]

Published

2023

26. Targeting extracellular CIRP with an X-aptamer shows therapeutic potential in acute pancreatitis.

Author

Liu W, Bi J, Ren Y, Chen H, Zhang J, Wang T, Wang M, Zhang L, Zhao J, Wu Z, Lv Y, Liu B, and Wu R

Abstract

Severe acute pancreatitis (AP) is associated with a high mortality rate. Cold-inducible RNA binding protein (CIRP) can be released from cells in inflammatory conditions and extracellular CIRP acts as a damage-associated molecular pattern. This study aims to explore the role of CIRP in the pathogenesis of AP and evaluate the therapeutic potential of targeting extracellular CIRP with X-aptamers. Our results showed that serum CIRP concentrations were significantly increased in AP mice. Recombinant CIRP triggered mitochondrial injury and ER stress in pancreatic acinar cells. CIRP -/- mice suffered less severe pancreatic injury and inflammatory responses. Using a bead-based X-aptamer library, we identified an X-aptamer that specifically binds to CIRP (XA-CIRP). Structurally, XA-CIRP blocked the interaction between CIRP and TLR4. Functionally, it reduced CIRP-induced pancreatic acinar cell injury in vitro and L-arginine-induced pancreatic injury and inflammation in vivo . Thus, targeting extracellular CIRP with X-aptamers may be a promising strategy to treat AP., Competing Interests: The authors reported no conflict of interest in this study., (© 2023 The Author(s).)

Published

2023

27. Human pangenome reference will enable more complete and equitable understanding of genomic diversity.

Abstract

Creating the pangenome The pangenome was made possible through the development of advanced computational techniques to align the multiple genome sequences into one, usable reference in a structure called a pangenome graph. Because of the methods used in this project, all of the genomes within the pangenome reference are of extremely high quality and accuracy, covering more than 99 percent of each human genome with more than 99 percent accuracy. [Extracted from the article]

Published

2023

28. Enhancing at-home COVID tests with glow-in-the dark materials.

Subjects

SARS-CoV-2, COVID-19 testing

Abstract

Bioengineering, Biomolecular Engineering, Bionanotechnology, Biotechnology, COVID-19, Coronavirus, Diagnostics and Screening, Emerging Technologies, Engineering, Nanotechnology, RNA Viruses, SARS-CoV-2, Severe Acute Respiratory Syndrome Coronavirus 2, Technology, University of Houston, Nanobiotechnology, Viral, Virology Keywords: Bioengineering; Biomolecular Engineering; Bionanotechnology; Biotechnology; COVID-19; Coronavirus; Diagnostics and Screening; Emerging Technologies; Engineering; Nanobiotechnology; Nanotechnology; RNA Viruses; SARS-CoV-2; Severe Acute Respiratory Syndrome Coronavirus 2; Technology; University of Houston; Viral; Virology EN Bioengineering Biomolecular Engineering Bionanotechnology Biotechnology COVID-19 Coronavirus Diagnostics and Screening Emerging Technologies Engineering Nanobiotechnology Nanotechnology RNA Viruses SARS-CoV-2 Severe Acute Respiratory Syndrome Coronavirus 2 Technology University of Houston Viral Virology 18 18 1 03/23/23 20230320 NES 230320 2023 MAR 24 (NewsRx) -- By a News Reporter-Staff News Editor at NewsRx COVID-19 Weekly -- Researchers at the University of Houston are using glow-in-the-dark materials to enhance and improve rapid COVID-19 home tests. If you've taken an at-home COVID-19 or pregnancy test, then you've taken what is scientifically called a lateral flow assay (LFA) test, a diagnostic tool widely used because of its rapid results, low cost and ease of operation. [Extracted from the article]

Published

2023

29. Cell-free synthetic biology: Orchestrating the machinery for biomolecular engineering.

Author

Lin X, Wang T, and Lu Y

Abstract

Due to inherent complexity, incompatibility, and variability in living cell systems, biomolecular engineering faces significant obstacles. To find novel solutions to these issues, researchers have turned to cell-free synthetic biology (CFSB), a relatively young field of study. Biochemical processes can be triggered in vitro through cell-free synthesis, providing a wider range of options for biomolecular engineering. Here, we provide a survey of recent advances in cell-free synthesis. These have sparked innovative studies in areas including the synthesis of complex proteins, incorporation of unnatural amino acids, precise post-translational modifications, high-throughput workflow, and synthetic biomolecular network regulation. CFSB has transformed the studies of biological machinery in a profound and practical way for versatile biomolecular engineering applications., Competing Interests: The authors declare no conflict of interest., (© 2022 The Authors.)

Published

2022

30. Mixed-surface polyamidoamine polymer variants retain nucleic acid-scavenger ability with reduced toxicity.

Author

Olson LB, Hunter NI, Rempel RE, Yu H, Spencer DM, Sullenger CZ, Greene WS, Varanko AK, Eghtesadi SA, Chilkoti A, Pisetsky DS, Everitt JI, and Sullenger BA

Abstract

Nucleic acid-binding polymers can have anti-inflammatory properties and beneficial effects in animal models of infection, trauma, cancer, and autoimmunity. PAMAM G3, a polyamidoamine dendrimer, is fully cationic bearing 32 protonable surface amines. However, while PAMAM G3 treatment leads to improved outcomes for mice infected with influenza, at risk of cancer metastasis, or genetically prone to lupus, its administration can lead to serosal inflammation and elevation of biomarkers of liver and kidney damage. Variants with reduced density of cationic charge through the interspersal of hydroxyl groups were evaluated as potentially better-tolerated alternatives. Notably, the variant PAMAM G3 50:50, similar in size as PAMAM G3 but with half the charge, was not toxic in cell culture, less associated with weight loss or serosal inflammation after parenteral administration, and remained effective in reducing glomerulonephritis in lupus-prone mice. Identification of such modified scavengers should facilitate their development as safe and effective anti-inflammatory agents., Competing Interests: Duke University has applied for patents on the strategy to reduce inflammation via nucleic acid scavengers. Lyra Olson, Nicole Hunter, Rachel Rempel, and Bruce Sullenger are listed as inventors on such patents., (© 2022 The Author(s).)

Published

2022

31. Scaling up DNA computation with next-generation sequencing and modified nucleic acids

Author

Wang, Siyuan Stella

Subjects

DNA computation, Nucleic acids, Biomolecular engineering, DNA storage, Nucleic acid rational design

Abstract

A central goal of biomolecular engineering is the construction of tools to manipulate nanoscale processes. DNA has proved to be a programmable material suited for this task. DNA strand displacement reactions can be designed to process chemical information in the form of concentrations and sequences. DNA nanotechnology has thus far produced devices for the detection of disease biomarkers, performed computation on chemical inputs, powered mechanical action at both the nanoscale and the macroscale, and assembled precise sub-micron structures from the bottom up. This dissertation addresses three main topics. First, we develop predictive models for non-canonical nucleic acid hybridization that enable rational design. Second, we show how rationally designed DNA strand displacement reactions can be used to perform computations on information stored in DNA. Third, we present nucleic acid computation with both strand displacement and transcription and discuss strategies for facilitating the scale up of networks. Finally, we discuss data storage in nucleic acid variants in the appendix. Rational design of DNA circuits and structures is possible because the thermodynamics of DNA and RNA hybridization can be approximated using a nearest-neighbor model. The parameters of this model are typically experimentally determined through the hyperchromism of denatured nucleic acids. This is measured through low-throughput UV-Vis spectrophotometry melting experiments that require a sizable amount of duplexes for a large set of sequences. For non-canonical nucleic acids or non-standard interactions, this characterization can be prohibitively costly and time consuming. Initially, we considered repurposing a next-generation sequencing (NGS) platform for high-throughput mapping of nucleic acid hybridization across a large sequence space; however, we found that the platform is suitable for mapping protein-nucleic acid interactions but not nucleic acid-nucleic acid hybridization due to its dynamic range. We then assessed whether high-resolution melting (HRM) can be used as a rapid method for determining approximate model parameters and found that HRM models can predict relative stabilities between duplexes of different sequences. Using this method, we developed a predictive model for phosphorothioate DNA which we then applied to the design of a phosphorothioate-modified catalytic hairpin assembly circuit. DNA strand displacement reactions can be used not only to manipulate chemical information in the form of concentration, but also to read and write to more permanent forms of information, such as sequence and secondary structure. We developed and demonstrated a DNA data storage scheme that enables in-memory computation. DNA is a promising data storage medium for meeting today's rapidly growing data storage needs; however, because computation on the stored data is usually performed in silico, strands must be sequenced and re-synthesized at every read-write cycle. Our scheme circumvents the bottleneck of de novo oligonucleotide synthesis by updating information using strand displacement cascades that result in sequence changes readable by NGS. We experimentally demonstrated two algorithms - binary counting and cellular automaton Rule 110 - and additionally showed that biologically-occurring DNA sequences without sequence design can be repurposed for storage and computation. Our scheme is capable of computation on multiple data in parallel, as well as random access and sequential computation, allowing for scaled up storage. Programmable chemical computation is also possible with enzymatic reactions such as transcription. Catalytic activity from enzymes has the potential to simplify circuit design and produce biologically potent signals. Practical concerns to expanding chemical computation circuits such as transcription networks include limited readout of signals and time-consuming purification. We addressed these concerns by expanding on previous efforts to build scalable in vitro transcription networks. We updated a single-stranded inhibitory transcription switch design for compatibility with multiplexed NGS readout and developed an analogous single-stranded switch that is activated by nucleic acid signals.

Published

2022