Your search keyword '"Ryan D, Heselpoth"' showing total 26 results

1. Thermal Characterization and Interaction of the Subunits from the Multimeric Bacteriophage Endolysin PlyC

Author

J. Todd Hoopes, Ryan D. Heselpoth, Frederick P. Schwarz, and Daniel C. Nelson

Subjects

PlyC, endolysin, antimicrobial, thermal stability, thermodynamic characterization, differential scanning calorimetry, Biology (General), QH301-705.5

Abstract

Bacteriophage endolysins degrade the bacterial peptidoglycan and are considered enzymatic alternatives to small-molecule antibiotics. In particular, the multimeric streptococcal endolysin PlyC has appealing antibacterial properties. However, a comprehensive thermal analysis of PlyC is lacking, which is necessary for evaluating its long-term stability and downstream therapeutic potential. Biochemical and kinetic-based methods were used in combination with differential scanning calorimetry to investigate the structural, kinetic, and thermodynamic stability of PlyC and its various subunits and domains. The PlyC holoenzyme structure is irreversibly compromised due to partial unfolding and aggregation at 46 °C. Unfolding of the catalytic subunit, PlyCA, instigates this event, resulting in the kinetic inactivation of the endolysin. In contrast to PlyCA, the PlyCB octamer (the cell wall-binding domain) is thermostable, denaturing at ~75 °C. The isolation of PlyCA or PlyCB alone altered their thermal properties. Contrary to the holoenzyme, PlyCA alone unfolds uncooperatively and is thermodynamically destabilized, whereas the PlyCB octamer reversibly dissociates into monomers and forms an intermediate state at 74 °C in phosphate-buffered saline with each subunit subsequently denaturing at 92 °C. Adding folded PlyCA to an intermediate state PlyCB, followed by cooling, allowed for in vitro reconstitution of the active holoenzyme.

Published

2023

2. PaP1, a Broad-Spectrum Lysin-Derived Cationic Peptide to Treat Polymicrobial Skin Infections

Author

Ryan D. Heselpoth, Chad W. Euler, and Vincent A. Fischetti

Subjects

lysin, antimicrobial peptide, antibiotic resistance, bacteriophage, broad-spectrum, Pseudomonas aeruginosa, Microbiology, QR1-502

Abstract

Most skin infections, including those complicating burns, are polymicrobial involving multiple causative bacteria. Add to this the fact that many of these organisms may be antibiotic-resistant, and a simple skin lesion or burn could soon become life-threatening. Membrane-acting cationic peptides from Gram-negative bacteriophage lysins can potentially aid in addressing the urgent need for alternative therapeutics. Such peptides natively constitute an amphipathic region within the structural composition of these lysins and function to permit outer membrane permeabilization in Gram-negative bacteria when added externally. This consequently allows the lysin to access and degrade the peptidoglycan substrate, resulting in rapid hypotonic lysis and bacterial death. When separated from the lysin, some of these cationic peptides kill sensitive bacteria more effectively than the native molecule via both outer and cytoplasmic membrane disruption. In this study, we evaluated the antibacterial properties of a modified cationic peptide from the broad-acting lysin PlyPa01. The peptide, termed PaP1, exhibited potent in vitro bactericidal activity toward numerous high priority Gram-positive and Gram-negative pathogens, including all the antibiotic-resistant ESKAPE pathogens. Both planktonic and biofilm-state bacteria were sensitive to the peptide, and results from time-kill assays revealed PaP1 kills bacteria on contact. The peptide was bactericidal over a wide temperature and pH range and could withstand autoclaving without loss of activity. However, high salt concentrations and complex matrices were found to be largely inhibitory, limiting its use to topical applications. Importantly, unlike other membrane-acting antimicrobials, PaP1 lacked cytotoxicity toward human cells. Results from a murine burn wound infection model using methicillin-resistant Staphylococcus aureus or multidrug-resistant Pseudomonas aeruginosa validated the in vivo antibacterial efficacy of PaP1. In these studies, the peptide enhanced the potency of topical antibiotics used clinically for treating chronic wound infections. Despite the necessity for additional preclinical drug development, the collective data from our study support PaP1 as a potential broad-spectrum monotherapy or adjunctive therapy for the topical treatment of polymicrobial infections and provide a foundation for engineering future lysin-derived peptides with improved antibacterial properties.

Published

2022

3. High avidity drives the interaction between the streptococcal C1 phage endolysin, PlyC, with the cell surface carbohydrates of Group A Streptococcus

Author

James Fodor, Blake T. Riley, Kirill Tsyganov, Anne Geert Volbeda, Daniel C. Nelson, Kylie A Farrow, Brooke K. Hayes, Colin J. Jackson, Sheena McGowan, Sebastian S. Broendum, Ben E. Clifton, Ryan D. Heselpoth, Jeroen D. C. Codée, Felix Kraus, Daniel E. Williams, Nyssa Drinkwater, and Ashley M. Buckle

Subjects

Streptococcus pyogenes, Lysin, Peptidoglycan, Biology, Rhamnose, Microbiology, Group A, Bacteriophage, 03 medical and health sciences, chemistry.chemical_compound, Cell Wall, Endopeptidases, Bacteriophages, Avidity, Binding site, Molecular Biology, 030304 developmental biology, 0303 health sciences, Binding Sites, 030306 microbiology, Cell Membrane, Rhamnose binding, biology.organism_classification, Molecular Docking Simulation, chemistry, Lytic cycle, Protein Binding

Abstract

Endolysin enzymes from bacteriophage cause bacterial lysis by degrading the peptidoglycan cell wall. The streptococcal C1 phage endolysin PlyC, is the most potent endolysin described to date and can rapidly lyse group A, C, and E streptococci. PlyC is known to bind the Group A streptococcal cell wall, but the specific molecular target or the binding site within PlyC remain uncharacterized. Here we report for the first time, that the polyrhamnose backbone of the Group A streptococcal cell wall is the binding target of PlyC. We have also characterized the putative rhamnose binding groove of PlyC and found four key residues that were critical to either the folding or the cell wall binding action of PlyC. Based on our results, we suggest that the interaction between PlyC and the cell wall may not be a high-affinity interaction as previously proposed, but rather a high avidity one, allowing for PlyC's remarkable lytic activity. Resistance to our current antibiotics is reaching crisis levels and there is an urgent need to develop the antibacterial agents with new modes of action. A detailed understanding of this potent endolysin may facilitate future developments of PlyC as a tool against the rise of antibiotic resistance.

Published

2021

4. A bacteriophage endolysin that eliminates intracellular streptococci

Author

Yang Shen, Marilia Barros, Tarek Vennemann, D Travis Gallagher, Yizhou Yin, Sara B Linden, Ryan D Heselpoth, Dennis J Spencer, David M Donovan, John Moult, Vincent A Fischetti, Frank Heinrich, Mathias Lösche, and Daniel C Nelson

Subjects

bacteriophage, membrane protein, endolysin, structure/function, Medicine, Science, Biology (General), QH301-705.5

Abstract

PlyC, a bacteriophage-encoded endolysin, lyses Streptococcus pyogenes (Spy) on contact. Here, we demonstrate that PlyC is a potent agent for controlling intracellular Spy that often underlies refractory infections. We show that the PlyC holoenzyme, mediated by its PlyCB subunit, crosses epithelial cell membranes and clears intracellular Spy in a dose-dependent manner. Quantitative studies using model membranes establish that PlyCB interacts strongly with phosphatidylserine (PS), whereas its interaction with other lipids is weak, suggesting specificity for PS as its cellular receptor. Neutron reflection further substantiates that PlyC penetrates bilayers above a PS threshold concentration. Crystallography and docking studies identify key residues that mediate PlyCB–PS interactions, which are validated by site-directed mutagenesis. This is the first report that a native endolysin can traverse epithelial membranes, thus substantiating the potential of PlyC as an antimicrobial for Spy in the extracellular and intracellular milieu and as a scaffold for engineering other functionalities.

Published

2016

5. Thermal characterization of the multimeric bacteriophage endolysin PlyC

Author

J. Todd Hoopes, Ryan D. Heselpoth, Frederick P. Schwarz, and Daniel C. Nelson

Abstract

Bacteriophage endolysins degrade the bacterial peptidoglycan and are considered enzymatic alternatives to small molecule antibiotics. In particular, the multimeric streptococcal endolysin PlyC has appealing antibacterial properties. However, a comprehensive thermal analysis of PlyC is lacking, which is necessary for evaluating long-term stability and downstream therapeutic potential. Biochemical and kinetic-based methods were used in combination with differential scanning calorimetry to investigate the structural, kinetic and thermodynamic stability of PlyC and its various subunits and domains. The PlyC holoenzyme structure is irreversibly compromised due to partial unfolding and aggregation at 46ºC. Unfolding of the catalytic subunit, PlyCA, instigates this event, resulting in the kinetic inactivation of the endolysin. In contrast to PlyCA, the PlyCB octamer (the cell wall binding domain) is thermostable, denaturing at ∼75ºC. Isolation of PlyCA or PlyCB alone altered their thermal properties. Contrary to the holoenzyme, PlyCA alone unfolds uncooperatively and is thermodynamically destabilized whereas the PlyCB octamer reversibly dissociates into monomers and forms an intermediate state at 74ºC in phosphate buffered saline, with each subunit subsequently denaturing at 92ºC. Adding folded PlyCA to an intermediate state PlyCB, followed by cooling, allowed for in vitro reconstitution of the active holoenzyme.

Published

2022

6. Safety Studies of Pneumococcal Endolysins Cpl-1 and Pal

Author

Marek Harhala, Daniel C. Nelson, Paulina Miernikiewicz, Ryan D. Heselpoth, Beata Brzezicka, Joanna Majewska, Sara B. Linden, Xiaoran Shang, Aleksander Szymczak, Dorota Lecion, Karolina Marek-Bukowiec, Marlena Kłak, Bartosz Wojciechowicz, Karolina Lahutta, Andrzej Konieczny, and Krystyna Dąbrowska

Subjects

endolysin, Pal, Cpl-1, safety, toxicity, immune response, Streptococcus pneumoniae, Microbiology, QR1-502

Abstract

Bacteriophage-derived endolysins have gained increasing attention as potent antimicrobial agents and numerous publications document the in vivo efficacy of these enzymes in various rodent models. However, little has been documented about their safety and toxicity profiles. Here, we present preclinical safety and toxicity data for two pneumococcal endolysins, Pal and Cpl-1. Microarray, and gene profiling was performed on human macrophages and pharyngeal cells exposed to 0.5 µM of each endolysin for six hours and no change in gene expression was noted. Likewise, in mice injected with 15 mg/kg of each endolysin, no physical or behavioral changes were noted, pro-inflammatory cytokine levels remained constant, and there were no significant changes in the fecal microbiome. Neither endolysin caused complement activation via the classic pathway, the alternative pathway, or the mannose-binding lectin pathway. In cellular response assays, IgG levels in mice exposed to Pal or Cpl-1 gradually increased for the first 30 days post exposure, but IgE levels never rose above baseline, suggesting that hypersensitivity or allergic reaction is unlikely. Collectively, the safety and toxicity profiles of Pal and Cpl-1 support further preclinical studies.

Published

2018

7. PaP1, a Broad-Spectrum Lysin-Derived Cationic Peptide to Treat Polymicrobial Skin Infections

Author

Ryan D. Heselpoth, Chad W. Euler, and Vincent A. Fischetti

Subjects

Microbiology (medical), Microbiology

Abstract

Most skin infections, including those complicating burns, are polymicrobial involving multiple causative bacteria. Add to this the fact that many of these organisms may be antibiotic-resistant, and a simple skin lesion or burn could soon become life-threatening. Membrane-acting cationic peptides from Gram-negative bacteriophage lysins can potentially aid in addressing the urgent need for alternative therapeutics. Such peptides natively constitute an amphipathic region within the structural composition of these lysins and function to permit outer membrane permeabilization in Gram-negative bacteria when added externally. This consequently allows the lysin to access and degrade the peptidoglycan substrate, resulting in rapid hypotonic lysis and bacterial death. When separated from the lysin, some of these cationic peptides kill sensitive bacteria more effectively than the native molecule via both outer and cytoplasmic membrane disruption. In this study, we evaluated the antibacterial properties of a modified cationic peptide from the broad-acting lysin PlyPa01. The peptide, termed PaP1, exhibited potent in vitro bactericidal activity toward numerous high priority Gram-positive and Gram-negative pathogens, including all the antibiotic-resistant ESKAPE pathogens. Both planktonic and biofilm-state bacteria were sensitive to the peptide, and results from time-kill assays revealed PaP1 kills bacteria on contact. The peptide was bactericidal over a wide temperature and pH range and could withstand autoclaving without loss of activity. However, high salt concentrations and complex matrices were found to be largely inhibitory, limiting its use to topical applications. Importantly, unlike other membrane-acting antimicrobials, PaP1 lacked cytotoxicity toward human cells. Results from a murine burn wound infection model using methicillin-resistant Staphylococcus aureus or multidrug-resistant Pseudomonas aeruginosa validated the in vivo antibacterial efficacy of PaP1. In these studies, the peptide enhanced the potency of topical antibiotics used clinically for treating chronic wound infections. Despite the necessity for additional preclinical drug development, the collective data from our study support PaP1 as a potential broad-spectrum monotherapy or adjunctive therapy for the topical treatment of polymicrobial infections and provide a foundation for engineering future lysin-derived peptides with improved antibacterial properties.

Published

2021

8. Characterization of AlgMsp, an alginate lyase from Microbulbifer sp. 6532A.

Author

Steven M Swift, Jeffrey W Hudgens, Ryan D Heselpoth, Patrick M Bales, and Daniel C Nelson

Subjects

Medicine, Science

Abstract

Alginate is a polysaccharide produced by certain seaweeds and bacteria that consists of mannuronic acid and guluronic acid residues. Seaweed alginate is used in food and industrial chemical processes, while the biosynthesis of bacterial alginate is associated with pathogenic Pseudomonas aeruginosa. Alginate lyases cleave this polysaccharide into short oligo-uronates and thus have the potential to be utilized for both industrial and medicinal applications. An alginate lyase gene, algMsp, from Microbulbifer sp. 6532A, was synthesized as an E.coli codon-optimized clone. The resulting 37 kDa recombinant protein, AlgMsp, was expressed, purified and characterized. The alginate lyase displayed highest activity at pH 8 and 0.2 M NaCl. Activity of the alginate lyase was greatest at 50°C; however the enzyme was not stable over time when incubated at 50°C. The alginate lyase was still highly active at 25°C and displayed little or no loss of activity after 24 hours at 25°C. The activity of AlgMsp was not dependent on the presence of divalent cations. Comparing activity of the lyase against polymannuronic acid and polyguluronic acid substrates showed a higher turnover rate for polymannuronic acid. However, AlgMSP exhibited greater catalytic efficiency with the polyguluronic acid substrate. Prolonged AlgMsp-mediated degradation of alginate produced dimer, trimer, tetramer, and pentamer oligo-uronates.

Published

2014

9. Crystal structure of ORF210 from E. coli O157:H1 phage CBA120 (TSP1), a putative tailspike protein.

Author

Chen Chen, Patrick Bales, Julia Greenfield, Ryan D Heselpoth, Daniel C Nelson, and Osnat Herzberg

Subjects

Medicine, Science

Abstract

Bacteriophage tailspike proteins act as primary receptors, often possessing endoglycosidase activity toward bacterial lipopolysaccharides or other exopolysaccharides, which enable phage absorption and subsequent DNA injection into the host. Phage CBA120, a contractile long-tailed Viunalikevirus phage infects the virulent Escherichia coli O157:H7. This phage encodes four putative tailspike proteins exhibiting little amino acid sequence identity, whose biological roles and substrate specificities are unknown. Here we focus on the first tailspike, TSP1, encoded by the orf210 gene. We have discovered that TSP1 is resistant to protease degradation, exhibits high thermal stability, but does not cleave the O157 antigen. An immune-dot blot has shown that TSP1 binds strongly to non-O157:H7 E. coli cells and more weakly to K. pneumoniae cells, but exhibits little binding to E. coli O157:H7 strains. To facilitate structure-function studies, we have determined the crystal structure of TSP1 to a resolution limit of 1.8 Å. Similar to other tailspikes proteins, TSP1 assembles into elongated homotrimers. The receptor binding region of each subunit adopts a right-handed parallel β helix, reminiscent yet not identical to several known tailspike structures. The structure of the N-terminal domain that binds to the virion particle has not been seen previously. Potential endoglycosidase catalytic sites at the three subunit interfaces contain two adjacent glutamic acids, unlike any catalytic machinery observed in other tailspikes. To identify potential sugar binding sites, the crystal structures of TSP1 in complexes with glucose, α-maltose, or α-lactose were determined. These structures revealed that each sugar binds in a different location and none of the environments appears consistent with an endoglycosidase catalytic site. Such sites may serve to bind sugar units of a yet to be identified bacterial exopolysaccharide.

Published

2014

10. Enzybiotics: Endolysins and Bacteriocins

Author

Steven M. Swift, Sara B. Linden, Michael S. Mitchell, Ryan D. Heselpoth, and Daniel C. Nelson

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Bacteriocin, 030106 microbiology, Lysin, Computational biology, Biology, Enzybiotics

Published

2021

11. Structure and function of bacteriophage CBA120 ORF211 (TSP2), the determinant of phage specificity towards E. coli O157:H7

Author

Petr G. Leiman, Xiaoran Shang, Ryan D. Heselpoth, Sara B. Linden, Yan Zhou, Osnat Herzberg, Heng Luo, Julia Greenfield, and Daniel C. Nelson

Subjects

0301 basic medicine, Glycoside Hydrolases, Stereochemistry, 030106 microbiology, Mutant, lcsh:Medicine, Trimer, Escherichia coli O157, medicine.disease_cause, Biochemistry, Genome, Article, Bacteriophage, 03 medical and health sciences, Species Specificity, Catalytic Domain, medicine, Bacteriophages, Asparagine, lcsh:Science, Escherichia coli, Alanine, Multidisciplinary, biology, Chemistry, lcsh:R, Virion, Viral Tail Proteins, biology.organism_classification, Structure and function, 030104 developmental biology, lcsh:Q, Structural biology

Abstract

The genome of Escherichia coli O157:H7 bacteriophage vB_EcoM_CBA120 encodes four distinct tailspike proteins (TSPs). The four TSPs, TSP1-4, attach to the phage baseplate forming a branched structure. We report the 1.9 Å resolution crystal structure of TSP2 (ORF211), the TSP that confers phage specificity towards E. coli O157:H7. The structure shows that the N-terminal 168 residues involved in TSPs complex assembly are disordered in the absence of partner proteins. The ensuing head domain contains only the first of two fold modules seen in other phage vB_EcoM_CBA120 TSPs. The catalytic site resides in a cleft at the interface between adjacent trimer subunits, where Asp506, Glu568, and Asp571 are located in close proximity. Replacement of Asp506 and Asp571 for alanine residues abolishes enzyme activity, thus identifying the acid/base catalytic machinery. However, activity remains intact when Asp506 and Asp571 are mutated into asparagine residues. Analysis of additional site-directed mutants in the background of the D506N:D571N mutant suggests engagement of an alternative catalytic apparatus comprising Glu568 and Tyr623. Finally, we demonstrate the catalytic role of two interacting glutamate residues of TSP1, located in a cleft between two trimer subunits, Glu456 and Glu483, underscoring the diversity of the catalytic apparatus employed by phage vB_EcoM_CBA120 TSPs.

Published

2020

12. Searching for a Bacteriophage Lysin to Treat Corynebacterium bovis in Immunocompromised Mice

Author

Lars F. Westblade, Neil S. Lipman, Christopher Cheleuitte-Nieves, Vincent A. Fischetti, and Ryan D. Heselpoth

Subjects

040301 veterinary sciences, medicine.drug_class, Antibiotics, Lysin, Biology, Corynebacterium, General Biochemistry, Genetics and Molecular Biology, Microbiology, Enterotoxemia, 0403 veterinary science, Bacteriophage, Rodent Diseases, Immunocompromised Host, Mice, Lysogenic cycle, medicine, Animals, Bacteriophages, Prophage, Original Research, General Veterinary, Corynebacterium Infections, 04 agricultural and veterinary sciences, Corynebacterium bovis, biology.organism_classification, Anti-Bacterial Agents, Lytic cycle

Abstract

Corynebacterium bovis is the causative agent of Corynebacterium-associated hyperkeratosis in immunocompromised mice. The resulting skin pathology can be profound and can be associated with severe wasting, making the animals unsuitable for research. Although the administration of antibiotics is effective in resolving clinical symptoms, antibiotics do not eradicate the offending bacterium. Furthermore, antibiotic use may be contraindicated as it can affect tumor growth and is associated with Clostridioides difficile enterotoxemia in highly immunocompromised murine strains. Lysins, which are lytic enzymes obtained from bacteriophages, are novel antimicrobial agents for treating bacterial diseases. The advantage of lysins are its target specificity, with minimal off-target complications that could affect the host or the biology of the engrafted tumor. The aim of this study was to identify lysins active against C. bovis. Chemical activation of latent prophages by using mitomycin C in 3 C. bovis isolates did not cause bacteriophage induction as determined through plaque assays and transmission electron microscopy. As an alternative approach, 8 lysins associated with other bacterial species, including those from the closely related species C. falsenii, were tested for their lytic action against C. bovis but were unsuccessful. These findings were congruent with the previously reported genomic analysis of 21 C. bovis isolates, which failed to reveal bacteriophage sequences by using the PHAST and PHASTER web server tools. From these results, we suggest C. bovis is among those rare bacterial species devoid of lysogenic bacteriophages, thus making the identification of C. bovis-specific lysins more challenging. However, C. bovis may be a useful model organism for studying the effects of antiphage systems.

Published

2020

13. Lysocins: Bioengineered Antimicrobials That Deliver Lysins across the Outer Membrane of Gram-Negative Bacteria

Author

Vincent A. Fischetti, Raymond Schuch, Chad W. Euler, and Ryan D. Heselpoth

Subjects

Male, Gram-negative bacteria, Lysin, Colicins, HL-60 Cells, Peptidoglycan, medicine.disease_cause, Gram-Positive Bacteria, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Mice, Bacteriocin, Anti-Infective Agents, Bacteriocins, Cell Line, Tumor, Gram-Negative Bacteria, medicine, Animals, Humans, Pharmacology (medical), Experimental Therapeutics, Bacteriophages, 030304 developmental biology, Pharmacology, 0303 health sciences, Pyocins, biology, 030306 microbiology, Pseudomonas aeruginosa, Periplasmic space, biology.organism_classification, Mice, Inbred C57BL, Infectious Diseases, Bacterial Outer Membrane, chemistry, Periplasm, bacteria, Bacterial outer membrane, Bacteria

Abstract

The prevalence of multidrug-resistant Pseudomonas aeruginosa has stimulated development of alternative therapeutics. Bacteriophage peptidoglycan hydrolases, termed lysins, represent an emerging antimicrobial option for targeting Gram-positive bacteria. However, lysins against Gram-negatives are generally deterred by the outer membrane and their inability to work in serum. One solution involves exploiting evolved delivery systems used by colicin-like bacteriocins (e.g., S-type pyocins of P. aeruginosa) to translocate through the outer membrane. Following surface receptor binding, colicin-like bacteriocins form Tol- or TonB-dependent translocons to actively import bactericidal domains through outer membrane protein channels. With this understanding, we developed lysocins, which are bioengineered lysin-bacteriocin fusion molecules capable of periplasmic import. In our proof-of-concept studies, components from the P. aeruginosa bacteriocin pyocin S2 (PyS2) responsible for surface receptor binding and outer membrane translocation were fused to the GN4 lysin to generate the PyS2-GN4 lysocin. PyS2-GN4 delivered the GN4 lysin to the periplasm to induce peptidoglycan cleavage and log-fold killing of P. aeruginosa with minimal endotoxin release. While displaying narrow-spectrum antipseudomonal activity in human serum, PyS2-GN4 also efficiently disrupted biofilms, outperformed standard-of-care antibiotics, exhibited no cytotoxicity toward eukaryotic cells, and protected mice from P. aeruginosa challenge in a bacteremia model. In addition to targeting P. aeruginosa, lysocins can be constructed to target other prominent Gram-negative bacterial pathogens.

Published

2019

14. Structure and tailspike glycosidase machinery of ORF212 from E. coli O157:H7 phage CBA120 (TSP3)

Author

Daniel C. Nelson, Xiaoran Shang, Heng Luo, Yan Zhou, Osnat Herzberg, Ryan D. Heselpoth, and Julia Greenfield

Subjects

0301 basic medicine, Models, Molecular, Glycoside Hydrolases, Viral protein, Stereochemistry, Protein Conformation, Protein subunit, Mutant, lcsh:Medicine, medicine.disease_cause, Crystallography, X-Ray, Escherichia coli O157, Biochemistry, Article, Bacteriophage, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Catalytic Domain, Enzyme Stability, medicine, Humans, Bacteriophages, lcsh:Science, Escherichia coli, Peptide sequence, Escherichia coli Infections, X-ray crystallography, Multidisciplinary, biology, Chemistry, lcsh:R, Active site, Viral Tail Proteins, biology.organism_classification, 030104 developmental biology, Proteolysis, biology.protein, lcsh:Q, 030217 neurology & neurosurgery

Abstract

Bacteriophage tailspike proteins mediate virion absorption through reversible primary receptor binding, followed by lipopolysaccharide or exopolysaccharide degradation. The Escherichia coli O157:H7 bacteriophage CBA120 genome encodes four distinct tailspike proteins, annotated as ORFs 210 through 213. Previously, we reported the crystal structure of ORF210 (TSP1). Here we describe the crystal structure of ORF212 (TSP3) determined at 1.85 Å resolution. As observed with other tailspike proteins, TSP3 assembles into a trimer. Each subunit of TSP3 has an N-terminal head domain that is structurally similar to that of TSP1, consistent with their high amino acid sequence identity. In contrast, despite sharing a β-helix fold, the overall structure of the C-terminal catalytic domain of TSP3 is quite different when compared to TSP1. The TSP3 structure suggests that the glycosidase active site resides in a cleft at the interface between two adjacent subunits where three acidic residues, Glu362 and Asp383 on one subunit, and Asp426 on a second subunit, are located in close proximity. Comparing the glycosidase activity of wild-type TSP3 to various point mutants revealed that catalysis requires the carboxyl groups of Glu362 and Asp426, and not of Asp383, confirming the enzyme employs two carboxyl groups to degrade lippopolysaccharide using an acid/base mechanism.

Published

2019

15. Middle region of theBorrelia burgdorferisurface-located protein 1 (Lmp1) interacts with host chondroitin-6-sulfate and independently facilitates infection

Author

Xiuli Yang, Utpal Pal, Daniel C. Nelson, Jinhong Qin, Ryan D. Heselpoth, Yi-Pin Lin, John M. Leong, Ozlem Buyuktanir, and Faith Kung

Subjects

0301 basic medicine, Infectivity, biology, 030106 microbiology, Immunology, Mutant, Plasma protein binding, biology.organism_classification, Microbiology, Homology (biology), Bacterial adhesin, 03 medical and health sciences, Membrane protein, Virology, Borrelia burgdorferi, Pathogen

Abstract

Borrelia burgdorferi surface-located membrane protein 1, also known as Lmp1, has been shown to play critical roles in pathogen evasion of host-acquired immune defences, thereby facilitating persistent infection. Lmp1 possesses three regions representing potentially discrete domains: Lmp1N, Lmp1M and Lmp1C. Because of its insignificant homology to known proteins, how Lmp1 or its specific regions contribute to microbial biology and infection remains enigmatic. Here, we show that distinct from Lmp1N and Lmp1C, Lmp1M is composed of at least 70% alpha helices and completely lacks recognizable beta sheets. The region binds to host glycosaminoglycan chondroitin-6-sulfate molecules and facilitates mammalian cell attachment, suggesting an adhesin function of Lmp1M. Phenotypic analysis of the Lmp1-deficient mutant engineered to produce Lmp1M on the microbial surface suggests that Lmp1M can independently support B. burgdorferi infectivity in murine hosts. Further exploration of functions of Lmp1 distinct regions will shed new light on the intriguing biology and infectivity of spirochetes and help develop novel interventions to combat Lyme disease.

Published

2015

16. Increasing the stability of the bacteriophage endolysin PlyC using rationale-based FoldX computational modeling

Author

Daniel C. Nelson, Yizhou Yin, Ryan D. Heselpoth, and John Moult

Subjects

Mutant, CHAP domain, Lysin, Bioengineering, Crystallography, X-Ray, Protein Engineering, Biochemistry, Amidohydrolases, Bacteriophage, Viral Proteins, Endopeptidases, Enzyme Stability, Hydrolase, Point Mutation, Bacteriophages, Histidine, Molecular Biology, FoldX, biology, Amidohydrolase, Computational Biology, Hydrogen Bonding, Protein engineering, biology.organism_classification, Kinetics, Biophysics, Algorithms, Biotechnology

Abstract

Endolysins are bacteriophage-derived peptidoglycan hydrolases that represent an emerging class of proteinaceous therapeutics. While the streptococcal endolysin PlyC has been validated in vitro and in vivo for its therapeutic efficacy, the inherent thermosusceptible structure of the enzyme correlates to transient long-term stability, thereby hindering the feasibility of developing the enzyme as an antimicrobial. Here, we thermostabilized the cysteine, histidine-dependent amidohydrolase/peptidase (CHAP) domain of the PlyCA catalytic subunit of PlyC using a FoldX-driven computational protein engineering approach. Using a combination of FoldX and Rosetta algorithms, as well as visual inspection, a final list of PlyC point mutant candidates with predicted stabilizing ΔΔG values was assembled and thermally characterized. Five of the eight point mutations were found experimentally to be destabilizing, a result most likely attributable to computationally modeling a complex and dynamic nine-subunit holoenzyme with a corresponding 3.3-Å X-ray crystal structure. However, one of the mutants, PlyC (PlyCA) T406R, was shown experimentally to increase the thermal denaturation temperature by ∼2.2°C and kinetic stability 16-fold over wild type. This mutation is expected to introduce a thermally advantageous hydrogen bond between the Q106 side chain of the N-terminal glycosyl hydrolase domain and the R406 side chain of the C-terminal CHAP domain.

Published

2015

17. Author response: A bacteriophage endolysin that eliminates intracellular streptococci

Author

Dennis J. Spencer, Vincent A. Fischetti, D. Travis Gallagher, Mathias Lösche, Sara B. Linden, David M. Donovan, Frank Heinrich, Ryan D. Heselpoth, Marília A. S. Barros, John Moult, Tarek Vennemann, Daniel C. Nelson, Yizhou Yin, and Yang Shen

Subjects

Bacteriophage, biology, Chemistry, Lysin, biology.organism_classification, Intracellular, Microbiology

Published

2016

18. A bacteriophage endolysin that eliminates intracellular streptococci

Author

Daniel C. Nelson, Marília A. S. Barros, D. Travis Gallagher, Mathias Lösche, Yang Shen, Sara B. Linden, Ryan D. Heselpoth, Vincent A. Fischetti, Tarek Vennemann, John Moult, David M. Donovan, Frank Heinrich, Yizhou Yin, and Dennis J. Spencer

Subjects

0301 basic medicine, structure/function, Streptococcus Phages, DNA Mutational Analysis, Lysin, medicine.disease_cause, Crystallography, X-Ray, Biochemistry, Bacteriophage, Cell membrane, bacteriophage, membrane protein, Bacteriophages, Biology (General), biology, Antimicrobials, General Neuroscience, food and beverages, General Medicine, N-Acetylmuramoyl-L-alanine Amidase, Biophysics and Structural Biology, 3. Good health, Transport protein, Cell biology, Molecular Docking Simulation, Protein Transport, medicine.anatomical_structure, Medicine, Insight, Intracellular, Research Article, Human, QH301-705.5, Streptococcus pyogenes, Protein subunit, Science, 030106 microbiology, Phosphatidylserines, General Biochemistry, Genetics and Molecular Biology, Microbiology, 03 medical and health sciences, S. pyogenes, Endopeptidases, Extracellular, medicine, Humans, Microbial Viability, General Immunology and Microbiology, fungi, Cell Membrane, Epithelial Cells, biology.organism_classification, 030104 developmental biology, endolysin, Mutagenesis, Site-Directed

Abstract

PlyC, a bacteriophage-encoded endolysin, lyses Streptococcus pyogenes (Spy) on contact. Here, we demonstrate that PlyC is a potent agent for controlling intracellular Spy that often underlies refractory infections. We show that the PlyC holoenzyme, mediated by its PlyCB subunit, crosses epithelial cell membranes and clears intracellular Spy in a dose-dependent manner. Quantitative studies using model membranes establish that PlyCB interacts strongly with phosphatidylserine (PS), whereas its interaction with other lipids is weak, suggesting specificity for PS as its cellular receptor. Neutron reflection further substantiates that PlyC penetrates bilayers above a PS threshold concentration. Crystallography and docking studies identify key residues that mediate PlyCB–PS interactions, which are validated by site-directed mutagenesis. This is the first report that a native endolysin can traverse epithelial membranes, thus substantiating the potential of PlyC as an antimicrobial for Spy in the extracellular and intracellular milieu and as a scaffold for engineering other functionalities. DOI: http://dx.doi.org/10.7554/eLife.13152.001, eLife digest Streptococcus pyogenes is the bacterium that causes throat infections and other serious infections in humans. Antibiotics such as penicillin are used to treat active infections, but so-called “strep throat infections” often return after treatment. This is because S. pyogenes can enter the cells that line the throat and hide from the antibiotics, which cannot enter the throat cells. Endolysins are enzymes produced by viruses that attack bacteria, and these enzymes target and destroy the bacterial cell wall. A previous study revealed that an endolysin known as PlyC could destroy S. pyogenes bacteria on contact. PlyC and other endolysins have the potential to act as alternatives to common antibiotics, but before these enzymes can be developed as therapeutics, it is important to understand how they interact with human host cells. Like antibiotics, the PlyC endolysin was not expected to enter throat cells. However, Shen, Barros et al. have now discovered that not only can PlyC enter throat cells, it can essentially chase down and kill S. pyogenes that are hiding inside. Other similar enzymes could not act in this way, and further studies confirmed that PlyC could move around inside a throat cell without causing it damage. Shen, Barros et al. also determined that PlyC has a pocket on its surface that binds with a specific component of the throat cell membrane, a molecule called phosphatidylserine. This interaction – which is a bit like a lock and key – grants PlyC access into the cell. While it is clear that PlyC eventually kills S. pyogenes hiding inside throat cells, future experiments will aim to determine how PlyC moves around once inside an infected throat cell. Together, an understanding of how an endolysin enters cells and destroys hiding S. pyogenes will contribute to the development of endolysins with broader activity, which can be used as alternatives to common antibiotics. DOI: http://dx.doi.org/10.7554/eLife.13152.002

Published

2016

19. Middle region of the Borrelia burgdorferi surface-located protein 1 (Lmp1) interacts with host chondroitin-6-sulfate and independently facilitates infection

Author

Xiuli, Yang, Yi-Pin, Lin, Ryan D, Heselpoth, Ozlem, Buyuktanir, Jinhong, Qin, Faith, Kung, Daniel C, Nelson, John M, Leong, and Utpal, Pal

Subjects

Mice, Bacterial Proteins, Borrelia burgdorferi, Chondroitin Sulfates, Host-Pathogen Interactions, Animals, Membrane Proteins, Bacterial Adhesion, Protein Structure, Secondary, Article, Protein Binding, Protein Structure, Tertiary

Abstract

Borrelia burgdorferi surface-located membrane protein 1, also known as Lmp1, has been shown to play critical roles in pathogen evasion of host-acquired immune defences, thereby facilitating persistent infection. Lmp1 possesses three regions representing potentially discrete domains: Lmp1N, Lmp1M and Lmp1C. Because of its insignificant homology to known proteins, how Lmp1 or its specific regions contribute to microbial biology and infection remains enigmatic. Here, we show that distinct from Lmp1N and Lmp1C, Lmp1M is composed of at least 70% alpha helices and completely lacks recognizable beta sheets. The region binds to host glycosaminoglycan chondroitin-6-sulfate molecules and facilitates mammalian cell attachment, suggesting an adhesin function of Lmp1M. Phenotypic analysis of the Lmp1-deficient mutant engineered to produce Lmp1M on the microbial surface suggests that Lmp1M can independently support B. burgdorferi infectivity in murine hosts. Further exploration of functions of Lmp1 distinct regions will shed new light on the intriguing biology and infectivity of spirochetes and help develop novel interventions to combat Lyme disease.

Published

2015

20. Biochemical and biophysical characterization of PlyGRCS, a bacteriophage endolysin active against methicillin-resistant Staphylococcus aureus

Author

Sara B. Linden, Yang Shen, Helena Zhang, Ryan D. Heselpoth, Fritz Eichenseher, Mathias Schmelcher, and Daniel C. Nelson

Subjects

Methicillin-Resistant Staphylococcus aureus, Lysin, medicine.disease_cause, Applied Microbiology and Biotechnology, Enzybiotics, Bacterial cell structure, Amidase, Microbiology, chemistry.chemical_compound, Staphylococcus epidermidis, Cell Wall, Catalytic Domain, Endopeptidases, medicine, Bacteriophages, Histidine, Cysteine, Cloning, Molecular, biology, Circular Dichroism, General Medicine, N-Acetylmuramoyl-L-alanine Amidase, biology.organism_classification, chemistry, Biochemistry, Staphylococcus aureus, Biofilms, Mutagenesis, Site-Directed, Peptidoglycan, Biotechnology, Binding domain

Abstract

The increasing rate of resistance of pathogenic bacteria, such as Staphylococcus aureus, to classical antibiotics has driven research toward identification of other means to fight infectious disease. One particularly viable option is the use of bacteriophage-encoded peptidoglycan hydrolases, called endolysins or enzybiotics. These enzymes lyse the bacterial cell wall upon direct contact, are not inhibited by traditional antibiotic resistance mechanisms, and have already shown great promise in the areas of food safety, human health, and veterinary science. We have identified and characterized an endolysin, PlyGRCS, which displays dose-dependent antimicrobial activity against both planktonic and biofilm S. aureus, including methicillin-resistant S. aureus (MRSA). The spectrum of lytic activity for this enzyme includes all S. aureus and Staphylococcus epidermidis strains tested, but not other Gram-positive pathogens. The contributions of the PlyGRCS putative catalytic and cell wall binding domains were investigated through deletion analysis. The cysteine, histidine-dependent amidohydrolase/peptidase (CHAP) catalytic domain displayed activity by itself, though reduced, indicating the necessity of the binding domain for full activity. In contrast, the SH3_5 binding domain lacked activity but was shown to interact directly with the staphylococcal cell wall via fluorescent microscopy. Site-directed mutagenesis studies determined that the active site residues in the CHAP catalytic domain were C29 and H92, and its catalytic functionality required calcium as a co-factor. Finally, biochemical assays coupled with mass spectrometry analysis determined that PlyGRCS displays both N-acetylmuramoyl-l-alanine amidase and d-alanyl-glycyl endopeptidase hydrolytic activities despite possessing only a single catalytic domain. These results indicate that PlyGRCS has the potential to become a revolutionary therapeutic option to combat bacterial infections.

Published

2014

21. Crystal Structure of ORF210 from E. coli O157:H1 Phage CBA120 (TSP1), a Putative Tailspike Protein

Author

Daniel C. Nelson, Chen Chen, Patrick M. Bales, Julia Greenfield, Osnat Herzberg, and Ryan D. Heselpoth

Subjects

Models, Molecular, Protein Structure, Glycoside Hydrolases, Viral protein, Protein subunit, lcsh:Medicine, medicine.disease_cause, Crystallography, X-Ray, Escherichia coli O157, Biochemistry, Endoglycosidase, Protein Structure, Secondary, Bacteriophage, Protein structure, medicine, Bacteriophages, Protein Interaction Domains and Motifs, Binding site, lcsh:Science, Escherichia coli, Peptide sequence, Multidisciplinary, Binding Sites, biology, lcsh:R, Biology and Life Sciences, Proteins, Hydrogen Bonding, Viral Tail Proteins, biology.organism_classification, Molecular biology, Enzymes, Enzyme Structure, biology.protein, Enzymology, lcsh:Q, Research Article, Saccharidases

Abstract

Bacteriophage tailspike proteins act as primary receptors, often possessing endoglycosidase activity toward bacterial lipopolysaccharides or other exopolysaccharides, which enable phage absorption and subsequent DNA injection into the host. Phage CBA120, a contractile long-tailed Viunalikevirus phage infects the virulent Escherichia coli O157:H7. This phage encodes four putative tailspike proteins exhibiting little amino acid sequence identity, whose biological roles and substrate specificities are unknown. Here we focus on the first tailspike, TSP1, encoded by the orf210 gene. We have discovered that TSP1 is resistant to protease degradation, exhibits high thermal stability, but does not cleave the O157 antigen. An immune-dot blot has shown that TSP1 binds strongly to non-O157:H7 E. coli cells and more weakly to K. pneumoniae cells, but exhibits little binding to E. coli O157:H7 strains. To facilitate structure-function studies, we have determined the crystal structure of TSP1 to a resolution limit of 1.8 A. Similar to other tailspikes proteins, TSP1 assembles into elongated homotrimers. The receptor binding region of each subunit adopts a right-handed parallel β helix, reminiscent yet not identical to several known tailspike structures. The structure of the N-terminal domain that binds to the virion particle has not been seen previously. Potential endoglycosidase catalytic sites at the three subunit interfaces contain two adjacent glutamic acids, unlike any catalytic machinery observed in other tailspikes. To identify potential sugar binding sites, the crystal structures of TSP1 in complexes with glucose, α-maltose, or α-lactose were determined. These structures revealed that each sugar binds in a different location and none of the environments appears consistent with an endoglycosidase catalytic site. Such sites may serve to bind sugar units of a yet to be identified bacterial exopolysaccharide.

Published

2014

22. Characterization of AlgMsp, an alginate lyase from Microbulbifer sp. 6532A

Author

Patrick M. Bales, Steven M. Swift, Jeffrey W. Hudgens, Daniel C. Nelson, and Ryan D. Heselpoth

Subjects

Applied Microbiology, Science, Lyases, medicine.disease_cause, Polysaccharide, Biochemistry, Microbiology, Substrate Specificity, chemistry.chemical_compound, Environmental Biotechnology, Biosynthesis, Bacterial Proteins, Enzyme Stability, medicine, Escherichia coli, Microbulbifer, Polysaccharide-Lyases, chemistry.chemical_classification, Enzyme Kinetics, Multidisciplinary, biology, Alteromonadaceae, Circular Dichroism, Hexuronic Acids, Substrate (chemistry), Biology and Life Sciences, Proteins, biology.organism_classification, Lyase, Recombinant Proteins, Enzymes, Enzyme, chemistry, Enzymology, Biodegradation, Medicine, Bacteria, Research Article, Biotechnology

Abstract

Alginate is a polysaccharide produced by certain seaweeds and bacteria that consists of mannuronic acid and guluronic acid residues. Seaweed alginate is used in food and industrial chemical processes, while the biosynthesis of bacterial alginate is associated with pathogenic Pseudomonas aeruginosa. Alginate lyases cleave this polysaccharide into short oligo-uronates and thus have the potential to be utilized for both industrial and medicinal applications. An alginate lyase gene, algMsp, from Microbulbifer sp. 6532A, was synthesized as an E.coli codon-optimized clone. The resulting 37 kDa recombinant protein, AlgMsp, was expressed, purified and characterized. The alginate lyase displayed highest activity at pH 8 and 0.2 M NaCl. Activity of the alginate lyase was greatest at 50°C; however the enzyme was not stable over time when incubated at 50°C. The alginate lyase was still highly active at 25°C and displayed little or no loss of activity after 24 hours at 25°C. The activity of AlgMsp was not dependent on the presence of divalent cations. Comparing activity of the lyase against polymannuronic acid and polyguluronic acid substrates showed a higher turnover rate for polymannuronic acid. However, AlgMSP exhibited greater catalytic efficiency with the polyguluronic acid substrate. Prolonged AlgMsp-mediated degradation of alginate produced dimer, trimer, tetramer, and pentamer oligo-uronates.

Published

2014

23. A New Screening Method for the Directed Evolution of Thermostable Bacteriolytic Enzymes

Author

Ryan D. Heselpoth and Daniel C. Nelson

Subjects

Lysis, enzybiotic, General Chemical Engineering, Immunology, Lysin, thermal behavior, Microbiology, General Biochemistry, Genetics and Molecular Biology, Bacteriophage, Heating, chemistry.chemical_compound, Endopeptidases, Enzyme Stability, Genetics, Escherichia coli, Enzyme kinetics, Thermolabile, directed evolution, Molecular Biology, Thermostability, bacteriolytic, biology, Issue 69, General Immunology and Microbiology, General Neuroscience, Streptococcus, biology.organism_classification, Directed evolution, thermostability, Recombinant Proteins, therapeutic, chemistry, Biochemistry, endolysin, PlyC, Mutagenesis, Site-Directed, antimicrobial, Peptidoglycan, Transformation, Bacterial

Abstract

Directed evolution is defined as a method to harness natural selection in order to engineer proteins to acquire particular properties that are not associated with the protein in nature. Literature has provided numerous examples regarding the implementation of directed evolution to successfully alter molecular specificity and catalysis(1). The primary advantage of utilizing directed evolution instead of more rational-based approaches for molecular engineering relates to the volume and diversity of variants that can be screened(2). One possible application of directed evolution involves improving structural stability of bacteriolytic enzymes, such as endolysins. Bacteriophage encode and express endolysins to hydrolyze a critical covalent bond in the peptidoglycan (i.e. cell wall) of bacteria, resulting in host cell lysis and liberation of progeny virions. Notably, these enzymes possess the ability to extrinsically induce lysis to susceptible bacteria in the absence of phage and furthermore have been validated both in vitro and in vivo for their therapeutic potential(3-5). The subject of our directed evolution study involves the PlyC endolysin, which is composed of PlyCA and PlyCB subunits(6). When purified and added extrinsically, the PlyC holoenzyme lyses group A streptococci (GAS) as well as other streptococcal groups in a matter of seconds and furthermore has been validated in vivo against GAS(7). Significantly, monitoring residual enzyme kinetics after elevated temperature incubation provides distinct evidence that PlyC loses lytic activity abruptly at 45 °C, suggesting a short therapeutic shelf life, which may limit additional development of this enzyme. Further studies reveal the lack of thermal stability is only observed for the PlyCA subunit, whereas the PlyCB subunit is stable up to ~90 °C (unpublished observation). In addition to PlyC, there are several examples in literature that describe the thermolabile nature of endolysins. For example, the Staphylococcus aureus endolysin LysK and Streptococcus pneumoniae endolysins Cpl-1 and Pal lose activity spontaneously at 42 °C, 43.5 °C and 50.2 °C, respectively(8-10). According to the Arrhenius equation, which relates the rate of a chemical reaction to the temperature present in the particular system, an increase in thermostability will correlate with an increase in shelf life expectancy(11). Toward this end, directed evolution has been shown to be a useful tool for altering the thermal activity of various molecules in nature, but never has this particular technology been exploited successfully for the study of bacteriolytic enzymes. Likewise, successful accounts of progressing the structural stability of this particular class of antimicrobials altogether are nonexistent. In this video, we employ a novel methodology that uses an error-prone DNA polymerase followed by an optimized screening process using a 96 well microtiter plate format to identify mutations to the PlyCA subunit of the PlyC streptococcal endolysin that correlate to an increase in enzyme kinetic stability (Figure 1). Results after just one round of random mutagenesis suggest the methodology is generating PlyC variants that retain more than twice the residual activity when compared to wild-type (WT) PlyC after elevated temperature treatment.

Published

2012

24. X-ray crystal structure of the streptococcal specific phage lysin PlyC

Author

James T. Hoopes, Daniel C. Nelson, Sheena McGowan, Vincent A. Fischetti, Cyril F. Reboul, Michael S. Mitchell, Ruby Hp Law, D. Travis Gallagher, Ryan D. Heselpoth, James C. Whisstock, Yang Shen, and Ashley M. Buckle

Subjects

chemistry.chemical_classification, Multidisciplinary, Streptococcus Phages, Viral protein, Lysin, Mutagenesis (molecular biology technique), Biology, Biological Sciences, medicine.disease_cause, biology.organism_classification, Crystallography, X-Ray, Bacterial cell structure, Enzymes, Protein Structure, Tertiary, Viral Proteins, Enzyme, chemistry, Biochemistry, medicine, Streptococcus equi, Glycoside hydrolase, Protein Structure, Quaternary, Bacteria, Cysteine

Abstract

Bacteriophages deploy lysins that degrade the bacterial cell wall and facilitate virus egress from the host. When applied exogenously, these enzymes destroy susceptible microbes and, accordingly, have potential as therapeutic agents. The most potent lysin identified to date is PlyC, an enzyme assembled from two components (PlyCA and PlyCB) that is specific for streptococcal species. Here the structure of the PlyC holoenzyme reveals that a single PlyCA moiety is tethered to a ring-shaped assembly of eight PlyCB molecules. Structure-guided mutagenesis reveals that the bacterial cell wall binding is achieved through a cleft on PlyCB. Unexpectedly, our structural data reveal that PlyCA contains a glycoside hydrolase domain in addition to the previously recognized cysteine, histidine-dependent amidohydrolases/peptidases catalytic domain. The presence of eight cell wall-binding domains together with two catalytic domains may explain the extraordinary potency of the PlyC holoenyzme toward target bacteria.

Published

2012

25. High throughput structural analysis of yeast ribosomes using hSHAPE

Author

Ryan D. Heselpoth, Jonathan A. Leshin, Jonathan D. Dinman, and Ashton T. Belew

Subjects

Protein Conformation, Saccharomyces cerevisiae, Molecular Sequence Data, Computational biology, Ribosome, Primer extension, Acylation, Protein structure, Molecular Biology, Throughput (business), DNA Primers, Genetics, Binding Sites, biology, Base Sequence, Cryoelectron Microscopy, RNA, Fungal, Cell Biology, Ribosomal RNA, biology.organism_classification, Yeast, RNA, Ribosomal, Nucleic Acid Conformation, Ribosomes, Research Paper

Abstract

Global mapping of rRNA structure by traditional methods is prohibitive in terms of time, labor and expense. High throughput selective 2' hydroxyl acylation analyzed by primer extension (hSHAPE) bypasses these problems by using fluorescently labeled primers to perform primer extension reactions, the products of which can be separated by capillary electrophoresis, thus enabling long read lengths in a cost effective manner. The data so generated is analyzed in a quantitative fashion using SHAPEFinder. This approach was used to map the flexibility of nearly the entire sequences of the 3 largest rRNAs from intact, empty yeast ribosomes. Mapping of these data onto near-atomic resolution yeast ribosome structures revealed the binding sites of known trans-acting factors, as well as previously unknown highly flexible regions of yeast rRNA. Refinement of this technology will enable nucleotide-specific mapping of changes in rRNA structure depending on the status of tRNA occupancy, the presence or absence of other trans-acting factors, due to mutations of intrinsic ribosome components or extrinsic factors affecting ribosome biogenesis, or in the presence of translational inhibitors.

Published

2011

26. Quantitative analysis of the thermal stability of the gamma phage endolysin PlyG: A biophysical and kinetic approach to assaying therapeutic potential

Author

Jacqueline M. Owens, Ryan D. Heselpoth, and Daniel C. Nelson

Subjects

Protein Denaturation, Reducing agent, Endolysin, Lysin, Bacteriophage, Anthrax, chemistry.chemical_compound, Viral Proteins, Virology, Enzyme Stability, chemistry.chemical_classification, Methionine, biology, Protein Stability, Temperature, N-Acetylmuramoyl-L-alanine Amidase, Thermal stability, PlyG, biology.organism_classification, Bacillus anthracis, Anti-Bacterial Agents, Kinetics, Enzyme, chemistry, Lytic cycle, Biochemistry, Antimicrobial, Cysteine

Abstract

Endolysins are lytic enzymes encoded by bacteriophage that represent an emerging class of protein therapeutics. Considering macromolecular thermoresistance correlates with shelf life, PlyG, a Bacillus anthracis endolysin, was thermally characterized to further evaluate its therapeutic potential. Results from a biophysical thermal analysis revealed full-length PlyG and its isolated domains comprised thermal denaturation temperatures exceeding 63°C. In the absence of reducing agent, PlyG was determined to be kinetically unstable, a finding hypothesized to be attributable to the chemical oxidation of cysteine and/or methionine residues. The presence of reducing agent kinetically stabilized the endolysin, with PlyG retaining at least ~50% residual lytic activity after being heated at temperatures up to 80°C and remaining enzymatically functional after being boiled. Furthermore, the endolysin had a kinetic half-life at 50°C and 55°C of 35 and 5.5h, respectively. PlyG represents a thermostable proteinaceous antibacterial with subsequent prolonged therapeutic shelf life expectancy.