Your search keyword '"Biomolecular engineering"' showing total 35 results

1. 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

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

Author

Debnath A, Mitra S, Ghosh S, and Sen R

Subjects

Metabolic Networks and Pathways, Crystallization, Extracellular Polymeric Substance Matrix metabolism, Biomineralization, Bacteria metabolism, Bacteria genetics, Minerals metabolism

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., (© 2024. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2024

3. 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

4. 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

5. 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

6. 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

7. 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

8. Biotechnology applications of proteins functionalized with DNA oligonucleotides.

Author

Gokulu IS and Banta S

Subjects

DNA chemistry, Amino Acids metabolism, Biotechnology, Oligonucleotides chemistry, Proteins chemistry

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., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2023

9. 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

10. Are museums the future of evolutionary medicine?

Author

Charlier P, Bourdin V, Augias A, Brun L, Kenmogne JB, and Josue E

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2022

11. 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

12. Data Management Schema Design for Effective Nanoparticle Formulation for Neurotherapeutics.

Author

Helmbrecht H, Xu N, Liao R, and Nance E

Abstract

Translation of nanotherapeutics from preclinical research to clinical application is difficult due to the complex and dynamic interaction space between the nanotherapeutic and the brain environment. To improve translation, increased insight into nanoformulation-brain interactions in preclinical research is necessary. We developed a nanoformulation-brain database and wrote queries to connect the complex physical, chemical, and biological features of neurotherapeutics based on experimental data. We queried the database to select nanoformulations based on specific physical characteristics that enable effective penetration within the brain, including size, polydispersity index, and zeta potential. Additionally, we demonstrate the ability to query the database to return select nanoformulation characteristics, including nanoformulation methodology or methodological variables such as surfactant, polymer, drug loading, and sonication times. Finally, we show the capacity of our database to produce correlations relating nanoparticle formulation parameters to biological outcomes, including nanotherapeutic impact on cell viability in cultured brain slices.

Published

2021

13. Next generation Fc scaffold for multispecific antibodies.

Author

Estes B, Sudom A, Gong D, Whittington DA, Li V, Mohr C, Li D, Riley TP, Shi SD, Zhang J, Garces F, and Wang Z

Abstract

Bispecific antibodies (Bispecifics) demonstrate exceptional clinical potential to address some of the most complex diseases. However, Bispecific production in a single cell often requires the correct pairing of multiple polypeptide chains for desired assembly. This is a considerable hurdle that hinders the development of many immunoglobulin G (IgG)-like bispecific formats. Our approach focuses on the rational engineering of charged residues to facilitate the chain pairing of distinct heavy chains (HC). Here, we deploy structure-guided protein design to engineer charge pair mutations (CPMs) placed in the CH3-CH3' interface of the fragment crystallizable (Fc) region of an antibody (Ab) to correctly steer heavy chain pairing. When used in combination with our stable effector functionless 2 (SEFL2.2) technology, we observed high pairing efficiency without significant losses in expression yields. Furthermore, we investigate the relationship between CPMs and the sequence diversity in the parental antibodies, proposing a rational strategy to deploy these engineering technologies., Competing Interests: The authors declare no competing interests., (© 2021 The Authors.)

Published

2021

14. Characteristic ERK1/2 signaling dynamics distinguishes necroptosis from apoptosis.

Author

Sipieter F, Cappe B, Leray A, De Schutter E, Bridelance J, Hulpiau P, Van Camp G, Declercq W, Héliot L, Vincent P, Vandenabeele P, and Riquet FB

Abstract

ERK1/2 involvement in cell death remains unclear, although many studies have demonstrated the importance of ERK1/2 dynamics in determining cellular responses. To untangle how ERK1/2 contributes to two cell death programs, we investigated ERK1/2 signaling dynamics during hFasL-induced apoptosis and TNF-induced necroptosis in L929 cells. We observed that ERK1/2 inhibition sensitizes cells to apoptosis while delaying necroptosis. By monitoring ERK1/2 activity by live-cell imaging using an improved ERK1/2 biosensor (EKAR4.0), we reported differential ERK1/2 signaling dynamics between cell survival, apoptosis, and necroptosis. We also decrypted a temporally shifted amplitude- and frequency-modulated (AM/FM) ERK1/2 activity profile in necroptosis versus apoptosis. ERK1/2 inhibition, which disrupted ERK1/2 signaling dynamics, prevented TNF and IL-6 gene expression increase during TNF-induced necroptosis. Using an inducible cell line for activated MLKL, the final executioner of necroptosis, we showed ERK1/2 and its distinctive necroptotic ERK1/2 activity dynamics to be positioned downstream of MLKL., Competing Interests: The authors declare no conflict of interest., (© 2021 The Author(s).)

Published

2021

15. In situ observation of mitochondrial biogenesis as the early event of apoptosis.

Author

Shao CS, Zhou XH, Miao YH, Wang P, Zhang QQ, and Huang Q

Abstract

Mitochondrial biogenesis is a cell response to external stimuli which is generally believed to suppress apoptosis. However, during the process of apoptosis, whether mitochondrial biogenesis occurs in the early stage of the apoptotic cells remains unclear. To address this question, we constructed the COX8-EGFP-ACTIN-mCherry HeLa cells with recombinant fluorescent proteins respectively tagged on the nucleus and mitochondria and monitored the mitochondrial changes in the living cells exposed to gamma-ray radiation. Besides in situ detection of mitochondrial fluorescence changes, we also examined the cell viability, nuclear DNA damage, reactive oxygen species (ROS), mitochondrial superoxide, citrate synthase activity, ATP, cytoplasmic and mitochondrial calcium, mitochondrial mass, mitochondrial morphology, and protein expression related to mitochondrial biogenesis, as well as the apoptosis biomarkers. As a result, we confirmed that significant mitochondrial biogenesis took place preceding the radiation-induced apoptosis, and it was closely correlated with the apoptotic cells at late stage. The involved mechanism was also discussed., Competing Interests: The authors declare that they have no competing interests., (© 2021 The Author(s).)

Published

2021

16. A Combined Experimental and Computational Study of Halogen and Hydrogen Bonding in Molecular Salts of 5-Bromocytosine.

Author

Aschi M, Toto Brocchi G, and Portalone G

Subjects

Crystallography, X-Ray methods, Cysteine chemistry, Cytosine chemistry, Cytosine metabolism, DNA chemistry, Electrons, Halogens chemistry, Hydrogen chemistry, Hydrogen Bonding, Models, Molecular, Protons, Pyridines chemistry, RNA chemistry, X-Ray Diffraction methods, Cytosine analogs & derivatives

Abstract

Although natural or artificial modified pyrimidine nucleobases represent important molecules with valuable properties as constituents of DNA and RNA, no systematic analyses of the structural aspects of bromo derivatives of cytosine have appeared so far in the literature. In view of the biochemical and pharmaceutical relevance of these compounds, six different crystals containing proton-transfer derivatives of 5-bromocytosine are prepared and analyzed in the solid-state by single crystal X-ray diffraction. All six compounds are organic salts, with proton transfer occurring to the N imino atom of the pyridine ring. Experimental results are then complemented with Hirshfeld surface analysis to quantitively evaluate the contribution of different intermolecular interactions in the crystal packing. Furthermore, theoretical calculations, based on different arrangements of molecules extracted from the crystal structure determinations, are carried out to analyze the formation mechanism of halogen bonds (XBs) in these compounds and provide insights into the nature and strength of the observed interactions. The results show that the supramolecular architectures of the six molecular salts involve extensive classical intermolecular hydrogen bonds. However, in all but one proton-transfer adducts, weak to moderate XBs are revealed by C-Br … O short contacts between the bromine atom in the fifth position, which acts as XB donor (electron acceptor). Moreover, the lone pair electrons of the oxygen atom of adjacent pyrimidine nucleobases and/or counterions or water molecules, which acts as XB acceptor (electron donor).

Published

2021

17. Prion-derived tetrapeptide stabilizes thermolabile insulin via conformational trapping.

Author

Mukherjee M, Das D, Sarkar J, Banerjee N, Jana J, Bhat J, Reddy G J, Bharatam J, Chattopadhyay S, Chatterjee S, and Chakrabarti P

Abstract

Unfolding followed by fibrillation of insulin even in the presence of various excipients grappled with restricted clinical application. Thus, there is an unmet need for better thermostable, nontoxic molecules to preserve bioactive insulin under varying physiochemical perturbations. In search of cross-amyloid inhibitors, prion-derived tetrapeptide library screening reveals a consensus V(X)YR motif for potential inhibition of insulin fibrillation. A tetrapeptide VYYR, isosequential to the β2-strand of prion, effectively suppresses heat- and storage-induced insulin fibrillation and maintains insulin in a thermostable bioactive form conferring adequate glycemic control in mouse models of diabetes and impedes insulin amyloidoma formation. Besides elucidating the critical insulin-IS1 interaction (R4 of IS1 to the N24 insulin B-chain) by nuclear magnetic resonance spectroscopy, we further demonstrated non-canonical dimer-mediated conformational trapping mechanism for insulin stabilization. In this study, structural characterization and preclinical validation introduce a class of tetrapeptide toward developing thermostable therapeutically relevant insulin formulations., Competing Interests: There is no conflict of interest., (© 2021 The Authors.)

Published

2021

18. A Biological Take on Halogen Bonding and Other Non-Classical Non-Covalent Interactions.

Author

Czarny RS, Ho AN, and Shing Ho P

Subjects

DNA chemistry, Halogens chemistry, Models, Molecular, DNA metabolism, Halogens metabolism, Thermodynamics

Abstract

Classical hydrogen bonds have, for many decades, been the dominant non-covalent interaction in the toolbox that chemists and chemical engineers have used to design and control the structures of compounds and molecular assemblies as novel materials. Recently, a set of non-classical non-covalent (NC-NC) interactions have emerged that exploit the properties of the Group IV, V, VI, and VII elements of the periodic table (the tetrel, pnictogen, chalcogen, and halogen bonds, respectively). Our research group has been characterizing the prevalence, geometric constraints, and structure-function relationship specifically of the halogen bond in biological systems. We have been particularly interested in exploiting the biological halogen bonds (or BXBs) to control the structures, stabilities, and activities of biomolecules, including the DNA Holliday junction and enzymes. In this review, we first provide a set of criteria for how to determine whether BXBs or any other NC-NC interactions would have biological relevance. We then navigate the trail of studies that had led us from an initial, very biological question to our current point in the journey to establish BXBs as a tool for biomolecular engineering. Finally, we close with a perspective on future directions for this line of research., (© 2021 The Chemical Society of Japan & Wiley-VCH GmbH.)

Published

2021

19. Single-Chain Lanthanide Luminescence Biosensors for Cell-Based Imaging and Screening of Protein-Protein Interactions.

Author

Chen T, Pham H, Mohamadi A, and Miller LW

Abstract

Lanthanide-based, Förster resonance energy transfer (LRET) biosensors enabled sensitive, time-gated luminescence (TGL) imaging or multiwell plate analysis of protein-protein interactions (PPIs) in living cells. We prepared stable cell lines that expressed polypeptides composed of an alpha helical linker flanked by a Tb(III) complex-binding domain, GFP, and two interacting domains at each terminus. The PPIs examined included those between FKBP12 and the rapamycin-binding domain of m-Tor (FRB) and between p53 (1-92) and HDM2 (1-128). TGL microscopy revealed dramatic differences (>500%) in donor- or acceptor-denominated, Tb(III)-to-GFP LRET ratios between open (unbound) and closed (bound) states of the biosensors. We observed much larger signal changes (>2,500%) and Z'-factors of 0.5 or more when we grew cells in 96- or 384-well plates and analyzed PPI changes using a TGL plate reader. The modular design and exceptional dynamic range of lanthanide-based LRET biosensors will facilitate versatile imaging and cell-based screening of PPIs., Competing Interests: The authors declare no competing interests., (© 2020 The Authors.)

Published

2020

20. The importance and future of biochemical engineering.

Author

Whitehead TA, Banta S, Bentley WE, Betenbaugh MJ, Chan C, Clark DS, Hoesli CA, Jewett MC, Junker B, Koffas M, Kshirsagar R, Lewis A, Li CT, Maranas C, Terry Papoutsakis E, Prather KLJ, Schaffer S, Segatori L, and Wheeldon I

Subjects

Humans, Biochemistry, Bioengineering, Biotechnology

Abstract

Today's Biochemical Engineer may contribute to advances in a wide range of technical areas. The recent Biochemical and Molecular Engineering XXI conference focused on "The Next Generation of Biochemical and Molecular Engineering: The role of emerging technologies in tomorrow's products and processes". On the basis of topical discussions at this conference, this perspective synthesizes one vision on where investment in research areas is needed for biotechnology to continue contributing to some of the world's grand challenges., (© 2020 Wiley Periodicals LLC.)

Published

2020

21. 10th Royan Institute's International Summer School on "Molecular Biomedicine: From Diagnostics to Therapeutics".

Author

Moradi S, Torabi P, Mohebbi S, Amjadian S, Bosma P, Faridbod F, Khoddami V, Hosseini M, Babashah S, Ghotbaddini M, Rasti A, Shekari F, Sadeghi-Abandansari H, Kiani J, Shamsara M, Kazemi-Ashtiani M, and Gholami S

Subjects

Humans, Schools

Published

2020

22. Computer-based Engineering of Thermostabilized Antibody Fragments.

Author

Lee J, Der BS, Karamitros CS, Li W, Marshall NM, Lungu OI, Miklos AE, Xu J, Kang TH, Lee CH, Tan B, Hughes RA, Jung ST, Ippolito GC, Gray JJ, Zhang Y, Kuhlman B, Georgiou G, and Ellington AD

Abstract

We used the molecular modeling program Rosetta to identify clusters of amino acid substitutions in antibody fragments (scFvs and scAbs) that improve global protein stability and resistance to thermal deactivation. Using this methodology, we increased the melting temperature (T m ) and resistance to heat treatment of an antibody fragment that binds to the Clostridium botulinum hemagglutinin protein (anti-HA33). Two designed antibody fragment variants with two amino acid replacement clusters, designed to stabilize local regions, were shown to have both higher T m compared to the parental scFv and importantly, to retain full antigen binding activity after 2 hours of incubation at 70 °C. The crystal structure of one thermostabilized scFv variants was solved at 1.6 Å and shown to be in close agreement with the RosettaAntibody model prediction., Competing Interests: Declaration of Interests JJG is an unpaid board member of the Rosetta Commons. Under institutional participation agreements between the University of Washington, acting on behalf of the Rosetta Commons, Johns Hopkins University may be entitled to a portion of revenue received on licensing Rosetta software including programs described here. As a member of the Scientific Advisory Board of Cyrus Biotechnology, JJG is granted stock options. Cyrus Biotechnology distributes the Rosetta software, which may include methods described in this article.

Published

2020

23. Bridging 2D and 3D culture: probing impact of extracellular environment on fibroblast activation in layered hydrogels.

Author

Smithmyer ME, Cassel SE, and Kloxin AM

Abstract

Many cell behaviors are significantly affected by cell culture geometry, though it remains unclear which geometry from two- to three-dimensional (2D to 3D) culture is appropriate for probing a specific cell function and mimicking native microenvironments. Toward addressing this, we established a 2.5D culture geometry, enabling initial cell spreading while reducing polarization to bridge between 2D and 3D geometries, and examined the responses of wound healing cells, human pulmonary fibroblasts, within it. To achieve this, we used engineered biomimetic hydrogels formed by photopolymerization, creating robust layered hydrogels with spread fibroblasts at the interface. We found that fibroblast responses were similar between 2D and 2.5D culture and different from 3D culture, with some underlying differences in mechanotransduction. These studies established the 2.5D cell culture geometry in conjunction with biomimetic synthetic matrices as a useful tool for investigations of fibroblast activation with relevance to the study of other cell functions and types., Competing Interests: Conflicts of interest The authors have no conflicts of interest to declare.

Published

2019

24. Loss of Phosphate Determines the Versatility of a Spider Orb-web Glue Ball.

Author

Zhao Y, Morita M, and Sakamoto T

Subjects

Adhesiveness, Animals, Biomechanical Phenomena, Mass Spectrometry, Salts metabolism, Phosphates metabolism, Spiders metabolism

Abstract

Spiders capture their prey by weaving an "invisible" orb-web that has both adhesive and fixed properties. Different types of silk in the orb-web have different functions, wherein the key to capturing a prey is the ball-like glue (glue ball), which coats the silk strands. This glue ball has highly versatile properties, but the mechanisms leading to its versatility remain unclear. The salts found in the web have been previously suggested to play an important role in terms of viscosity, not water. However, the distribution of salt and water in the glue ball has not yet been directly observed. Here, we mapped the salts in different states using a homemade time-of-flight secondary ion mass spectrometer (TOF-SIMS) with a high lateral resolution. To our surprise, the glue ball was found to contain little water. The functional transformation of the glue ball from a viscous glycoprotein (capturing prey) to a hardened protein (retaining prey) relies solely on the stimulation of mechanical forces. The phosphate is a key factor for its versatility.

Published

2019

25. Strategies for Engineering Natural Product Biosynthesis in Fungi.

Author

Skellam E

Subjects

Biological Products metabolism, Biosynthetic Pathways genetics, Fungi genetics, Fungi metabolism, Metabolic Engineering methods

Abstract

Fungi are a prolific source of bioactive compounds, some of which have been developed as essential medicines and life-enhancing drugs. Genome sequencing has revealed that fungi have the potential to produce considerably more natural products (NPs) than are typically observed in the laboratory. Recently, there have been significant advances in the identification, understanding, and engineering of fungal biosynthetic gene clusters (BGCs). This review briefly describes examples of the engineering of fungal NP biosynthesis at the global, pathway, and enzyme level using in vivo and in vitro approaches and refers to the range and scale of heterologous expression systems available, developments in combinatorial biosynthesis, progress in understanding how fungal BGCs are regulated, and the applications of these novel biosynthetic enzymes as biocatalysts., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

26. Probing the Acyl Carrier Protein-Enzyme Interactions within Terminal Alkyne Biosynthetic Machinery.

Author

Su M, Zhu X, and Zhang W

Abstract

The alkyne functionality has attracted much interest due to its diverse chemical and biological applications. We recently elucidated an acyl carrier protein (ACP)-dependent alkyne biosynthetic pathway, however, little is known about ACP interactions with the alkyne biosynthetic enzymes, an acyl-ACP ligase (JamA) and a membrane-bound bi-functional desaturase/acetylenase (JamB). Here, we showed that JamB has a more stringent interaction with ACP than JamA. In addition, site directed mutagenesis of a non-cognate ACP significantly improved its compatibility with JamB, suggesting a possible electrostatic interaction at the ACP-JamB interface. Finally, error-prone PCR and screening of a second non-cognate ACP identified hot spots on the ACP that are important for interacting with JamB and yielded mutants which were better recognized by JamB. Our data thus not only provide insights into the ACP interactions in alkyne biosynthesis, but it also potentially aids in future combinatorial biosynthesis of alkyne-tagged metabolites for chemical and biological applications.

Published

2018

27. Application of chemical reaction engineering principles to 'body-on-a-chip' systems.

Author

Sung JH, Wang YI, Kim JH, Lee JM, and Shuler ML

Abstract

The combination of cell culture models with microscale technology has fostered emergence of in vitro cell-based microphysiological models, also known as organ-on-a-chip systems. Body-on-a-chip systems, which are multi-organ systems on a chip to mimic physiological relations, enable recapitulation of organ-organ interactions and potentially whole-body response to drugs, as well as serve as models of diseases. Chemical reaction engineering principles can be applied to understanding complex reactions inside the cell or human body, which can be treated as a multi-reactor system. These systems use physiologically-based pharmacokinetic (PBPK) models to guide the development of microscale systems of the body where organs or tissues are represented by living cells or tissues, and integrated into body-on-a-chip systems. Here, we provide a brief overview on the concept of chemical reaction engineering and how its principles can be applied to understanding and predicting the behavior of body-on-a-chip systems.

Published

2018

28. Engineering Biomolecular Switches for Dynamic Metabolic Control.

Author

Ma CW, Zhou LB, and Zeng AP

Subjects

Metabolic Engineering methods, Metabolism genetics

Abstract

Living organisms have been exploited as production hosts for a large variety of compounds. To improve the efficiency of bioproduction, metabolic pathways in an organism are usually manipulated by various genetic modifications. However, bottlenecks during the conversion of substrate to a desired product may result from cellular regulations at different levels. Dynamic regulation of metabolic pathways according to the need of cultivation process is therefore essential for developing effective bioprocesses, but represents a major challenge in metabolic engineering and synthetic biology. To this end, switchable biomolecules which can sense the intracellular concentrations of metabolites with different response types and dynamic ranges are of great interest. This chapter summarizes recent progress in the development of biomolecular switches and their applications for improvement of bioproduction via dynamic control of metabolic fluxes. Further studies of bioswitches and their applications in industrial strain development are also discussed.

Published

2018

29. Relationships between hydrogen bonds and halogen bonds in biological systems.

Author

Rowe RK and Ho PS

Subjects

Binding, Competitive, Crystallography, X-Ray, DNA chemistry, DNA metabolism, Enzymes chemistry, Enzymes metabolism, Hydrogen Bonding, Ketosteroids metabolism, Molecular Conformation, Proteins antagonists & inhibitors, Proteins metabolism, Steroid Isomerases chemistry, Steroid Isomerases metabolism, Halogens chemistry, Proteins chemistry

Abstract

The recent recognition that halogen bonding (XB) plays important roles in the recognition and assembly of biological molecules has led to new approaches in medicinal chemistry and biomolecular engineering. When designing XBs into strategies for rational drug design or into a biomolecule to affect its structure and function, we must consider the relationship between this interaction and the more ubiquitous hydrogen bond (HB). In this review, we explore these relationships by asking whether and how XBs can replace, compete against or behave independently of HBs in various biological systems. The complex relationships between the two interactions inform us of the challenges we face in fully utilizing XBs to control the affinity and recognition of inhibitors against their therapeutic targets, and to control the structure and function of proteins, nucleic acids and other biomolecular scaffolds.

Published

2017

30. In vitro analysis of essential binding sites on the promoter of the Serratia marcescens spn operon with the quorum-sensing receptor SpnR.

Author

Takayama Y and Kato N

Subjects

Binding Sites, Protein Binding, Bacterial Proteins genetics, Operon genetics, Promoter Regions, Genetic genetics, Protein Interaction Mapping methods, Quorum Sensing genetics, Receptors, Cytoplasmic and Nuclear genetics, Serratia marcescens genetics, Trans-Activators genetics

Abstract

The N-acylhomoserine lactone (AHL) receptor SpnR is a LuxR family protein that acts as a negative regulator of AHL-dependent quorum sensing (QS). SpnR binds to DNA in Serratia marcescens AS-1 via the spn box; however, the binding affinity of SpnR with the nucleotides on the spn box has not yet been investigated. In this study, we used an spn-box-modified sensor electrode, and quartz crystal microbalance analysis demonstrated a drastic reduction of the uptake of SpnR. The nucleotides G5 and C16 at the AHL-receptor complex-binding site are conserved in Gram-negative bacteria, including the lux box in Vibrio fischeri, the tra box in Agrobacterium tumefaciens, and the spn box in S. marcescens. Indeed, the affinity of SpnR to DNA was reduced to 8% by G5C substitution of the spn box. The affinity of SpnR tagged with maltose-binding protein to the immobilized gene promoter was reduced in the order of C16G and G5C substitutions, which corresponded with previous reports on the lux box. These results suggest that formation of hydrogen bonds at amino acid residues containing guanine at position 5 on a lux-box-like promoter universally contributes to the stability of the receptor complex, whose interaction initiates a sequential QS process in the LuxR family. Biotechnol. Bioeng. 2016;113: 2513-2517. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2016

31. Engineering responsive supramolecular biomaterials: Toward smart therapeutics.

Author

Webber MJ

Abstract

Engineering materials using supramolecular principles enables generalizable and modular platforms that have tunable chemical, mechanical, and biological properties. Applying this bottom-up, molecular engineering-based approach to therapeutic design affords unmatched control of emergent properties and functionalities. In preparing responsive materials for biomedical applications, the dynamic character of typical supramolecular interactions facilitates systems that can more rapidly sense and respond to specific stimuli through a fundamental change in material properties or characteristics, as compared to cases where covalent bonds must be overcome. Several supramolecular motifs have been evaluated toward the preparation of "smart" materials capable of sensing and responding to stimuli. Triggers of interest in designing materials for therapeutic use include applied external fields, environmental changes, biological actuators, applied mechanical loading, and modulation of relative binding affinities. In addition, multistimuli-responsive routes can be realized that capture combinations of triggers for increased functionality. In sum, supramolecular engineering offers a highly functional strategy to prepare responsive materials. Future development and refinement of these approaches will improve precision in material formation and responsiveness, seek dynamic reciprocity in interactions with living biological systems, and improve spatiotemporal sensing of disease for better therapeutic deployment.

Published

2016

32. Biomedical applications of collagens.

Author

Ramshaw JA

Subjects

Animals, Humans, Structure-Activity Relationship, Biocompatible Materials chemistry, Collagen chemistry

Abstract

Collagen-based biomedical materials have developed into important, clinically effective materials used in a range of devices that have gained wide acceptance. These devices come with collagen in various formats, including those based on stabilized natural tissues, those that are based on extracted and purified collagens, and designed composite, biosynthetic materials. Further knowledge on the structure and function of collagens has led to on-going developments and improvements. Among these developments has been the production of recombinant collagen materials that are well defined and are disease free. Most recently, a group of bacterial, non-animal collagens has emerged that may provide an excellent, novel source of collagen for use in biomaterials and other applications. These newer collagens are discussed in detail. They can be modified to direct their function, and they can be fabricated into various formats, including films and sponges, while solutions can also be adapted for use in surface coating technologies., (© 2015 Wiley Periodicals, Inc.)

Published

2016

33. In vivo biotinylation and incorporation of a photo-inducible unnatural amino acid to an antibody-binding domain improve site-specific labeling of antibodies.

Author

Kanje S and Hober S

Subjects

Amino Acids chemistry, Antibodies genetics, Binding Sites, Biotin chemistry, Biotinylation, Models, Molecular, Amino Acids metabolism, Antibodies chemistry, Antibodies metabolism, Biotin metabolism, Protein Engineering methods

Abstract

Antibodies are important molecules in many research fields, where they play a key role in various assays. Antibody labeling is therefore of great importance. Currently, most labeling techniques take advantage of certain amino acid side chains that commonly appear throughout proteins. This makes it hard to control the position and exact degree of labeling of each antibody. Hence, labeling of the antibody may affect the antibody-binding site. This paper presents a novel protein domain based on the IgG-binding domain C2 of streptococcal protein G, containing the unnatural amino acid BPA, that can cross-link other molecules. This novel domain can, with improved efficiency compared to previously reported similar domains, site-specifically cross-link to IgG at the Fc region. An efficient method for simultaneous in vivo incorporation of BPA and specific biotinylation in a flask cultivation of Escherichia coli is described. In comparison to a traditionally labeled antibody sample, the C2-labeled counterpart proved to have a higher proportion of functional antibodies when immobilized on a solid surface and the same limit of detection in an ELISA. This method of labeling is, due to its efficiency and simplicity, of high interest for all antibody-based assays where it is important that labeling does not interfere with the antibody-binding site., (Copyright © 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

34. Sensitivity of immune response quality to influenza helix 190 antigen structure displayed on a modular virus-like particle.

Author

Anggraeni MR, Connors NK, Wu Y, Chuan YP, Lua LH, and Middelberg AP

Subjects

Animals, Antibodies, Viral immunology, Female, Hemagglutinin Glycoproteins, Influenza Virus genetics, Humans, Influenza A Virus, H1N1 Subtype immunology, Influenza, Human immunology, Mice, Mice, Inbred BALB C, Molecular Dynamics Simulation, Orthomyxoviridae Infections immunology, Polyomavirus genetics, Polyomavirus immunology, Protein Conformation, Vaccines, Virus-Like Particle, Hemagglutinin Glycoproteins, Influenza Virus immunology, Influenza Vaccines immunology, Protein Engineering, Vaccines, Synthetic immunology

Abstract

Biomolecular engineering enables synthesis of improved proteins through synergistic fusion of modules from unrelated biomolecules. Modularization of peptide antigen from an unrelated pathogen for presentation on a modular virus-like particle (VLP) represents a new and promising approach to synthesize safe and efficacious vaccines. Addressing a key knowledge gap in modular VLP engineering, this study investigates the underlying fundamentals affecting the ability of induced antibodies to recognize the native pathogen. Specifically, this quality of immune response is correlated to the peptide antigen module structure. We modularized a helical peptide antigen element, helix 190 (H190) from the influenza hemagglutinin (HA) receptor binding region, for presentation on murine polyomavirus VLP, using two strategies aimed to promote H190 helicity on the VLP. In the first strategy, H190 was flanked by GCN4 structure-promoting elements within the antigen module; in the second, dual H190 copies were arrayed as tandem repeats in the module. Molecular dynamics simulation predicted that tandem repeat arraying would minimize secondary structural deviation of modularized H190 from its native conformation. In vivo testing supported this finding, showing that although both modularization strategies conferred high H190-specific immunogenicity, tandem repeat arraying of H190 led to a strikingly higher immune response quality, as measured by ability to generate antibodies recognizing a recombinant HA domain and split influenza virion. These findings provide new insights into the rational engineering of VLP vaccines, and could ultimately enable safe and efficacious vaccine design as an alternative to conventional approaches necessitating pathogen cultivation., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

35. Effects of pre-existing anti-carrier immunity and antigenic element multiplicity on efficacy of a modular virus-like particle vaccine.

Author

Chuan YP, Rivera-Hernandez T, Wibowo N, Connors NK, Wu Y, Hughes FK, Lua LH, and Middelberg AP

Subjects

Animals, Drug Carriers, Electrophoresis, Polyacrylamide Gel, Immunoglobulin G blood, Mice, Mice, Inbred BALB C, Models, Molecular, Antigens immunology, Peptides immunology, Polyomavirus immunology, Vaccines, Virus-Like Particle administration & dosage, Vaccines, Virus-Like Particle chemistry, Vaccines, Virus-Like Particle immunology

Abstract

Modularization of a peptide antigen for presentation on a microbially synthesized murine polyomavirus (MuPyV) virus-like particle (VLP) offers a new alternative for rapid and low-cost vaccine delivery at a global scale. In this approach, heterologous modules containing peptide antigenic elements are fused to and displayed on the VLP carrier, allowing enhancement of peptide immunogenicity via ordered and densely repeated presentation of the modules. This study addresses two key engineering questions pertaining to this platform, exploring the effects of (i) pre-existing carrier-specific immunity on modular VLP vaccine effectiveness and (ii) increase in the antigenic element number per VLP on peptide-specific immune response. These effects were studied in a mouse model and with modular MuPyV VLPs presenting a group A streptococcus (GAS) peptide antigen, J8i. The data presented here demonstrate that immunization with a modular VLP could induce high levels of J8i-specific antibodies despite a strong pre-existing anti-carrier immune response. Doubling of the J8i antigenic element number per VLP did not enhance J8i immunogenicity at a constant peptide dose. However, the strategy, when used in conjunction with increased VLP dose, could effectively increase the peptide dose up to 10-fold, leading to a significantly higher J8i-specific antibody titer. This study further supports feasibility of the MuPyV modular VLP vaccine platform by showing that, in the absence of adjuvant, modularized GAS antigenic peptide at a dose as low as 150 ng was sufficient to raise a high level of peptide-specific IgGs indicative of bactericidal activity., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013