Your search keyword '"Marletta MA"' showing total 251 results

1. MODULATION OF CARRAGEENAN EDEMA BY ENDOGENOUS NITRIC-OXIDE

Author

IALENTI, ARMANDO, IANARO, ANGELA, MONCADA, S, DI ROSA, M., IALENTI, A, IANARO, A, MONCADA, S, DI ROSA, M, Moncada, S, Marletta, MA, Hibbs, JB, Higgs, EA, Ialenti, Armando, Ianaro, Angela, and DI ROSA, M.

Published

1992

2. Second-Sphere Histidine Catalytic Function in a Fungal Polysaccharide Monooxygenase.

Author

Batka AE, Thomas WC, Tudorica DA, Sayler RI, and Marletta MA

Subjects

Fungal Proteins metabolism, Fungal Proteins chemistry, Fungal Proteins genetics, Catalytic Domain, Kinetics, Catalysis, Models, Molecular, Oxygen metabolism, Oxygen chemistry, Histidine chemistry, Histidine metabolism, Mixed Function Oxygenases metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases genetics

Abstract

Fungal polysaccharide monooxygenases (PMOs) oxidatively degrade cellulose and other carbohydrate polymers via a mononuclear copper active site using either O 2 or H 2 O 2 as a cosubstrate. Cellulose-active fungal PMOs in the auxiliary activity 9 (AA9) family have a conserved second-sphere hydrogen-bonding network consisting of histidine, glutamine, and tyrosine residues. The second-sphere histidine has been hypothesized to play a role in proton transfer in the O 2 -dependent PMO reaction. Here the role of the second-sphere histidine (H157) in an AA9 PMO, Mt PMO9E, was investigated. This PMO is active on soluble cello-oligosaccharides such as cellohexaose (Glc6), thus enabling kinetic analysis with the point variants H157A and H157Q. The variants appeared to fold similarly to the wild-type (WT) enzyme and yet exhibited weaker affinity toward Glc6 than WT (WT K D = 20 ± 3 μM). The variants had comparable oxidase (O 2 reduction to H 2 O 2 ) activity to WT at all pH values tested. Using O 2 as a cosubstrate, the variants were less active for Glc6 hydroxylation than WT, with H157A being the least active. Similarly, H157Q was competent for Glc6 hydroxylation with H 2 O 2 , but H157A was less active. Comparison of the crystal structures of H157Q and WT Mt PMO9E reveals that a terminal heteroatom of Q157 overlays with N ε of H157. Altogether, the data suggest that H157 is not important for proton transfer, but support a role for H157 as a hydrogen-bond donor to diatomic-oxygen intermediates, thus facilitating catalysis with either O 2 or H 2 O 2 .

Published

2024

3. Proteases influence colony aggregation behavior in Vibrio cholerae.

Author

Detomasi TC, Batka AE, Valastyan JS, Hydorn MA, Craik CS, Bassler BL, and Marletta MA

Subjects

Peptides, Substrate Specificity, Catalysis, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins physiology, Leucyl Aminopeptidase chemistry, Leucyl Aminopeptidase genetics, Leucyl Aminopeptidase physiology, Serine Proteases chemistry, Serine Proteases genetics, Serine Proteases physiology, Vibrio cholerae enzymology, Vibrio cholerae genetics, Vibrio cholerae physiology

Abstract

Aggregation behavior provides bacteria protection from harsh environments and threats to survival. Two uncharacterized proteases, LapX and Lap, are important for Vibrio cholerae liquid-based aggregation. Here, we determined that LapX is a serine protease with a preference for cleavage after glutamate and glutamine residues in the P1 position, which processes a physiologically based peptide substrate with a catalytic efficiency of 180 ± 80 M -1 s -1 . The activity with a LapX substrate identified by a multiplex substrate profiling by mass spectrometry screen was 590 ± 20 M -1 s -1 . Lap shares high sequence identity with an aminopeptidase (termed VpAP) from Vibrio proteolyticus and contains an inhibitory bacterial prepeptidase C-terminal domain that, when eliminated, increases catalytic efficiency on leucine p-nitroanilide nearly four-fold from 5.4 ± 4.1 × 10 4  M -1 s -1 to 20.3 ± 4.3 × 10 4  M -1 s -1 . We demonstrate that LapX processes Lap to its mature form and thus amplifies Lap activity. The increase is approximately eighteen-fold for full-length Lap (95.7 ± 5.6 × 10 4  M -1 s -1 ) and six-fold for Lap lacking the prepeptidase C-terminal domain (11.3 ± 1.9 × 10 5  M -1 s -1 ). In addition, substrate profiling reveals preferences for these two proteases that could inform in vivo function. Furthermore, purified LapX and Lap restore the timing of the V. cholerae aggregation program to a mutant lacking the lapX and lap genes. Both proteases must be present to restore WT timing, and thus they appear to act sequentially: LapX acts on Lap, and Lap acts on the substrate involved in aggregation., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Role of the Coiled-Coil Domain in Allosteric Activity Regulation in Soluble Guanylate Cyclase.

Author

Wittenborn EC, Thomas WC, Houghton KA, Wirachman ES, Wu Y, and Marletta MA

Subjects

Humans, Soluble Guanylyl Cyclase metabolism, Cryoelectron Microscopy, Models, Molecular, Protein Domains, Guanylate Cyclase genetics, Guanylate Cyclase metabolism, Signal Transduction, Nitric Oxide metabolism

Abstract

Soluble guanylate cyclase (sGC) is the primary nitric oxide (NO) receptor in higher eukaryotes, including humans. NO-dependent signaling via sGC is associated with important physiological effects in the vascular, pulmonary, and neurological systems, and sGC itself is an established drug target for the treatment of pulmonary hypertension due to its central role in vasodilation. Despite isolation in the late 1970s, high-resolution structural information on full-length sGC remained elusive until recent cryo-electron microscopy structures were determined of the protein in both the basal unactivated state and the NO-activated state. These structures revealed large-scale conformational changes upon activation that appear to be centered on rearrangements within the coiled-coil (CC) domains in the enzyme. Here, a structure-guided approach was used to engineer constitutively unactivated and constitutively activated sGC variants through mutagenesis of the CC domains. These results demonstrate that the activation-induced conformational change in the CC domains is necessary and sufficient for determining the level of sGC activity.

Published

2023

5. Characterization of a unique polysaccharide monooxygenase from the plant pathogen Magnaporthe oryzae .

Author

Martinez-D'Alto A, Yan X, Detomasi TC, Sayler RI, Thomas WC, Talbot NJ, and Marletta MA

Subjects

Mixed Function Oxygenases metabolism, Polysaccharides metabolism, Cellulose metabolism, Plant Diseases microbiology, Fungal Proteins metabolism, Ascomycota metabolism, Magnaporthe genetics, Oryza metabolism

Abstract

Blast disease in cereal plants is caused by the fungus Magnaporthe oryzae and accounts for a significant loss in food crops. At the outset of infection, expression of a putative polysaccharide monooxygenase ( Mo PMO9A) is increased. Mo PMO9A contains a catalytic domain predicted to act on cellulose and a carbohydrate-binding domain that binds chitin. A sequence similarity network of the Mo PMO9A family AA9 showed that 220 of the 223 sequences in the Mo PMO9A-containing cluster of sequences have a conserved unannotated region with no assigned function. Expression and purification of the full length and two Mo PMO9A truncations, one containing the catalytic domain and the domain of unknown function (DUF) and one with only the catalytic domain, were carried out. In contrast to other AA9 polysaccharide monooxygenases (PMOs), Mo PMO9A is not active on cellulose but showed activity on cereal-derived m ixed (1→3, 1→4)- β -D- g lucans (MBG). Moreover, the DUF is required for activity. Mo PMO9A exhibits activity consistent with C4 oxidation of the polysaccharide and can utilize either oxygen or hydrogen peroxide as a cosubstrate. It contains a predicted 3-dimensional fold characteristic of other PMOs. The DUF is predicted to form a coiled-coil with six absolutely conserved cysteines acting as a zipper between the two α-helices. Mo PMO9A substrate specificity and domain architecture are different from previously characterized AA9 PMOs. The results, including a gene ontology analysis, support a role for Mo PMO9A in MBG degradation during plant infection. Consistent with this analysis, deletion of Mo PMO9A results in reduced pathogenicity.

Published

2023

6. A moonlighting function of a chitin polysaccharide monooxygenase, CWR-1, in Neurospora crassa allorecognition.

Author

Detomasi TC, Rico-Ramírez AM, Sayler RI, Gonçalves AP, Marletta MA, and Glass NL

Subjects

Chitin, Fungal Proteins genetics, Histidine, Mixed Function Oxygenases genetics, Neurospora crassa genetics

Abstract

Organisms require the ability to differentiate themselves from organisms of different or even the same species. Allorecognition processes in filamentous fungi are essential to ensure identity of an interconnected syncytial colony to protect it from exploitation and disease. Neurospora crassa has three cell fusion checkpoints controlling formation of an interconnected mycelial network. The locus that controls the second checkpoint, which allows for cell wall dissolution and subsequent fusion between cells/hyphae, cwr (cell wall remodeling) , encodes two linked genes, cwr-1 and cwr-2 . Previously, it was shown that cwr-1 and cwr-2 show severe linkage disequilibrium with six different haplogroups present in N. crassa populations. Isolates from an identical cwr haplogroup show robust fusion, while somatic cell fusion between isolates of different haplogroups is significantly blocked in cell wall dissolution. The cwr-1 gene encodes a putative polysaccharide monooxygenase (PMO). Herein we confirm that CWR-1 is a C1-oxidizing chitin PMO. We show that the catalytic (PMO) domain of CWR-1 was sufficient for checkpoint function and cell fusion blockage; however, through analysis of active-site, histidine-brace mutants, the catalytic activity of CWR-1 was ruled out as a major factor for allorecognition. Swapping a portion of the PMO domain (V86 to T130) did not switch cwr haplogroup specificity, but rather cells containing this chimera exhibited a novel haplogroup specificity. Allorecognition to mediate cell fusion blockage is likely occurring through a protein-protein interaction between CWR-1 with CWR-2. These data highlight a moonlighting role in allorecognition of the CWR-1 PMO domain., Competing Interests: TD, AR, RS, AG, MM, NG No competing interests declared, (© 2022, Detomasi, Rico-Ramírez et al.)

Published

2022

7. Ratiometric Oxygen Sensing with H-NOX Protein Conjugates.

Author

Lemon CM, Hanley D, Batka AE, and Marletta MA

Subjects

Fluorescence Resonance Energy Transfer, Heme metabolism, Oxygen chemistry, Hemeproteins, Porphyrins chemistry

Abstract

Ratiometric sensors are self-referencing constructs that are functional in cells and tissues, and the read-out is independent of sensor concentration. One strategy for ratiometric sensing is to utilize two-color emission, where one component possesses analyte-dependent emission and the other is independent of analyte concentration, serving as an internal standard. In this way, the intensity ratio of the two components is a quantitative measure of the analyte. In this study, protein-based ratiometric oxygen sensors are prepared using the heme nitric oxide/oxygen-binding protein (H-NOX) from the thermophilic bacterium Caldanaerobacter subterraneus . The native heme cofactor is replaced with a Pd(II) or Pt(II) porphyrin as the oxygen-responsive phosphor. Mutagenesis is performed to incorporate a cysteine residue on the protein surface for thiol/maleimide coupling of the oxygen-insensitive dye, which serves as a Förster resonance energy transfer (FRET) donor for the porphyrin. While both Pd(II)- and Pt(II)-based sensors are responsive over biologically relevant ranges, the Pd sensor exhibits greater sensitivity at lower oxygen concentrations. Together, these sensors represent a new class of protein-based ratiometric oxygen sensors, and the modular platform allows the oxygen sensitivity to be tailored for a specific application. This proof-of-principle study has identified the key considerations and optimal methodologies to develop and subsequently refine protein-based ratiometric oxygen sensors.

Published

2022

8. Nitric oxide signaling controls collective contractions in a colonial choanoflagellate.

Author

Reyes-Rivera J, Wu Y, Guthrie BGH, Marletta MA, King N, and Brunet T

Subjects

Animals, Cyclic GMP metabolism, Guanylate Cyclase genetics, Nitric Oxide metabolism, Nitric Oxide Synthase genetics, Nitric Oxide Synthase metabolism, Signal Transduction physiology, Choanoflagellata metabolism

Abstract

Although signaling by the gaseous molecule nitric oxide (NO) regulates key physiological processes in animals, including contractility, 1-3 immunity, 4 , 5 development, 6-9 and locomotion, 10 , 11 the early evolution of animal NO signaling remains unclear. To reconstruct the role of NO in the animal stem lineage, we set out to study NO signaling in choanoflagellates, the closest living relatives of animals. 12 In animals, NO produced by the nitric oxide synthase (NOS) canonically signals through cGMP by activating soluble guanylate cyclases (sGCs). 13 , 14 We surveyed the distribution of the NO signaling pathway components across the diversity of choanoflagellates and found three species that express NOS (of either bacterial or eukaryotic origin), sGCs, and downstream genes previously shown to be involved in the NO/cGMP pathway. One of the species coexpressing sGCs and a bacterial-type NOS, Choanoeca flexa, forms multicellular sheets that undergo collective contractions controlled by cGMP. 15 We found that treatment with NO induces cGMP synthesis and contraction in C. flexa. Biochemical assays show that NO directly binds C. flexa sGC1 and stimulates its cyclase activity. The NO/cGMP pathway acts independently from other inducers of C. flexa contraction, including mechanical stimuli and heat, but sGC activity is required for contractions induced by light-to-dark transitions. The output of NO signaling in C. flexa-contractions resulting in a switch from feeding to swimming-resembles the effect of NO in sponges 1-3 and cnidarians, 11 , 16 , 17 where it interrupts feeding and activates contractility. These data provide insights into the biology of the first animals and the evolution of NO signaling., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

9. Corrole-protein interactions in H-NOX and HasA.

Author

Lemon CM, Nissley AJ, Latorraca NR, Wittenborn EC, and Marletta MA

Abstract

Replacing the native porphyrin cofactor in haem proteins has led to the development of novel designer proteins for a variety of applications. In most cases, haem analogues bind in a way that is comparable to the iron porphyrin, but this is not necessarily the case for complexes bearing non-exchangeable ligands. This study probes how a P[double bond, length as m-dash]O corrole binds to functionally disparate hemoproteins: a haem-dependent oxygen sensor (H-NOX) and a haem-scavenging protein (HasA). The results demonstrate that the protein-cofactor interactions are distinct from the native, haem-bound holoprotein. In H-NOX, the P[double bond, length as m-dash]O unit primarily hydrogen bonds with the haem-ligating histidine (H102), rather than the hydrogen-bonding network that stabilises the Fe(ii)-O 2 complex in the native protein. In the absence of H102, the protein is still able to bind the corrole, albeit at reduced levels. Molecular dynamics simulations were utilised to determine the flexibility of apo H-NOX and revealed the coupled motion of key residues necessary for corrole binding. In the case of HasA, the P[double bond, length as m-dash]O unit does not primarily interact with either the haem-ligating histidine (H32) or tyrosine (Y75). Instead, histidine 83, the hydrogen-bonding partner for Y75, is critical for P[double bond, length as m-dash]O corrole binding. The conformation of HasA is interrogated by site-specifically labelling the protein and exploiting Förster resonance energy transfer (FRET) to determine the dye-cofactor distance. HasA reconstituted with the P[double bond, length as m-dash]O corrole exhibits an extended, apo-like conformation. Together, these results demonstrate that non-natural cofactors can bind to proteins in unexpected ways and highlight the need to uncover these interactions for the further development of designer haem proteins., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2022

10. Ceragenins and Antimicrobial Peptides Kill Bacteria through Distinct Mechanisms.

Author

Mitchell G, Silvis MR, Talkington KC, Budzik JM, Dodd CE, Paluba JM, Oki EA, Trotta KL, Licht DJ, Jimenez-Morales D, Chou S, Savage PB, Gross CA, Marletta MA, and Cox JS

Subjects

Escherichia coli, Proteomics, Bacteria, Anti-Bacterial Agents pharmacology, Antimicrobial Cationic Peptides pharmacology, Microbial Sensitivity Tests, Antimicrobial Peptides, Anti-Infective Agents pharmacology

Abstract

Ceragenins are a family of synthetic amphipathic molecules designed to mimic the properties of naturally occurring cationic antimicrobial peptides (CAMPs). Although ceragenins have potent antimicrobial activity, whether their mode of action is similar to that of CAMPs has remained elusive. Here, we reported the results of a comparative study of the bacterial responses to two well-studied CAMPs, LL37 and colistin, and two ceragenins with related structures, CSA13 and CSA131. Using transcriptomic and proteomic analyses, we found that Escherichia coli responded similarly to both CAMPs and ceragenins by inducing a Cpx envelope stress response. However, whereas E. coli exposed to CAMPs increased expression of genes involved in colanic acid biosynthesis, bacteria exposed to ceragenins specifically modulated functions related to phosphate transport, indicating distinct mechanisms of action between these two classes of molecules. Although traditional genetic approaches failed to identify genes that confer high-level resistance to ceragenins, using a Clustered Regularly Interspaced Short Palindromic Repeats interference (CRISPRi) approach we identified E. coli essential genes that when knocked down modify sensitivity to these molecules. Comparison of the essential gene-antibiotic interactions for each of the CAMPs and ceragenins identified both overlapping and distinct dependencies for their antimicrobial activities. Overall, this study indicated that, while some bacterial responses to ceragenins overlap those induced by naturally occurring CAMPs, these synthetic molecules target the bacterial envelope using a distinctive mode of action. IMPORTANCE The development of novel antibiotics is essential because the current arsenal of antimicrobials will soon be ineffective due to the widespread occurrence of antibiotic resistance. The development of naturally occurring cationic antimicrobial peptides (CAMPs) for therapeutics to combat antibiotic resistance has been hampered by high production costs and protease sensitivity, among other factors. The ceragenins are a family of synthetic CAMP mimics that kill a broad spectrum of bacterial species but are less expensive to produce, resistant to proteolytic degradation, and seemingly resistant to the development of high-level resistance. Determining how ceragenins function may identify new essential biological pathways of bacteria that are less prone to the development of resistance and will further our understanding of the design principles for maximizing the effects of synthetic CAMPs.

Published

2022

11. Designer Heme Proteins: Achieving Novel Function with Abiological Heme Analogues.

Author

Lemon CM and Marletta MA

Subjects

Escherichia coli, Heme, Metals, Hemeproteins, Metalloproteins

Abstract

Heme proteins have proven to be a convenient platform for the development of designer proteins with novel functionalities. This is achieved by substituting the native iron porphyrin cofactor with a heme analogue that possesses the desired properties. Replacing the iron center of the porphyrin with another metal provides one inroad to novel protein function. A less explored approach is substitution of the porphyrin cofactor with an alternative tetrapyrrole macrocycle or a related ligand. In general, these ligands exhibit chemical properties and reactivity that are distinct from those of porphyrins. While these techniques have most prominently been utilized to develop artificial metalloenzymes, there are many other applications of this methodology to problems in biochemistry, health, and medicine. Incorporation of synthetic cofactors into protein environments represents a facile way to impart water solubility and biocompatibility. It circumvents the laborious synthesis of water-soluble cofactors, which often introduces substantial charge that leads to undesired bioaccumulation. To this end, the incorporation of unnatural cofactors in heme proteins has enabled the development of designer proteins as optical oxygen sensors, MRI contrast agents, spectroscopic probes, tools to interrogate protein function, antibiotics, and fluorescent proteins.Incorporation of an artificial cofactor is frequently accomplished by denaturing the holoprotein with removal of the heme; the refolded apoprotein is then reconstituted with the artificial cofactor. This process often results in substantial protein loss and does not necessarily guarantee that the refolded protein adopts the native structure. To circumvent these issues, our laboratory has pioneered the use of the RP523 strain of E. coli to incorporate artificial cofactors into heme proteins using expression-based methods. This strain lacks the ability to biosynthesize heme, and the bacterial cell wall is permeable to heme and related molecules. In this way, heme analogues supplemented in the growth medium are incorporated into heme proteins. This approach can also be leveraged for the direct expression of the apoprotein for subsequent reconstitution.These methodologies have been exploited to incorporate non-native cofactors into heme proteins that are resistant to harsh environmental conditions: the heme nitric oxide/oxygen binding protein (H-NOX) from Caldanaerobacter subterraneus ( Cs ) and the heme acquisition system protein A (HasA) from Pseudomonas aeruginosa ( Pa ). The exceptional stability of these proteins makes them ideal scaffolds for biomedical applications. Optical oxygen sensing has been accomplished using a phosphorescent ruthenium porphyrin as the artificial heme cofactor. Paramagnetic manganese and gadolinium porphyrins yield high-relaxivity, protein-based MRI contrast agents. A fluorescent phosphorus corrole serves as a heme analogue to produce fluorescent proteins. Iron complexes of nonporphyrin cofactors bound to HasA inhibit the growth of pathogenic bacteria. Moreover, HasA can deliver a gallium phthalocyanine into the bacterial cytosol to serve as a sensitizer for photochemical sterilization. Together, these examples illustrate the potential for designer heme proteins to address burgeoning problems in the areas of health and medicine. The concepts and methodologies presented in this Account can be extended to the development of next-generation biomedical sensing and imaging agents to identify and quantify clinically relevant metabolites and other key disease biomarkers.

Published

2021

12. Revisiting Nitric Oxide Signaling: Where Was It, and Where Is It Going?

Author

Marletta MA

Subjects

Animals, Anions metabolism, Bacteria metabolism, Biochemistry history, History, 20th Century, Humans, Metabolic Networks and Pathways, Nitric Oxide Synthase metabolism, Soluble Guanylyl Cyclase metabolism, Nitric Oxide metabolism, Signal Transduction

Abstract

Nitric oxide (NO) has long been known to be an intermediate in bacterial pathways of denitrification. Only in the middle to late 1980s was it found to play a central role in a much broader biological context. For example, it is now well established that NO acts as a signaling agent in metazoans, including humans, yet NO is toxic and very reactive under biological conditions. How is the biology in which NO plays a role controlled? How is NO used and the inherent toxicity avoided? Looking back at the initial discovery time, to the present, and on to the future provides many answers to questions such as those listed above.

Published

2021

13. Structural Perspectives on the Mechanism of Soluble Guanylate Cyclase Activation.

Author

Wittenborn EC and Marletta MA

Subjects

Animals, Cryoelectron Microscopy methods, Cyclic GMP metabolism, Humans, Nitric Oxide metabolism, Signal Transduction physiology, Soluble Guanylyl Cyclase metabolism

Abstract

The enzyme soluble guanylate cyclase (sGC) is the prototypical nitric oxide (NO) receptor in humans and other higher eukaryotes and is responsible for transducing the initial NO signal to the secondary messenger cyclic guanosine monophosphate (cGMP). Generation of cGMP in turn leads to diverse physiological effects in the cardiopulmonary, vascular, and neurological systems. Given these important downstream effects, sGC has been biochemically characterized in great detail in the four decades since its discovery. Structures of full-length sGC, however, have proven elusive until very recently. In 2019, advances in single particle cryo-electron microscopy (cryo-EM) enabled visualization of full-length sGC for the first time. This review will summarize insights revealed by the structures of sGC in the unactivated and activated states and discuss their implications in the mechanism of sGC activation.

Published

2021

14. Corrole-Substituted Fluorescent Heme Proteins.

Author

Lemon CM and Marletta MA

Subjects

Crystallography, X-Ray, Hemeproteins chemistry, Luminescent Proteins chemistry, Porphyrins chemistry

Abstract

Although fluorescent proteins have been utilized for a variety of biological applications, they have several optical limitations, namely weak red and near-infrared emission and exceptionally broad (>200 nm) emission profiles. The photophysical properties of fluorescent proteins can be enhanced through the incorporation of novel cofactors with the desired properties into a stable protein scaffold. To this end, a fluorescent phosphorus corrole that is structurally similar to the native heme cofactor is incorporated into two exceptionally stable heme proteins: H-NOX from Caldanaerobacter subterraneus and heme acquisition system protein A (HasA) from Pseudomonas aeruginosa . These yellow-orange emitting protein conjugates are examined by steady-state and time-resolved optical spectroscopy. The HasA conjugate exhibits enhanced fluorescence, whereas emission from the H-NOX conjugate is quenched relative to the free corrole. Despite the low fluorescence quantum yields, these corrole-substituted proteins exhibit more intense fluorescence in a narrower spectral profile than traditional fluorescent proteins that emit in the same spectral window. This study demonstrates that fluorescent corrole complexes are readily incorporated into heme proteins and provides an inroad for the development of novel fluorescent proteins.

Published

2021

15. An iron (II) dependent oxygenase performs the last missing step of plant lysine catabolism.

Author

Thompson MG, Blake-Hedges JM, Pereira JH, Hangasky JA, Belcher MS, Moore WM, Barajas JF, Cruz-Morales P, Washington LJ, Haushalter RW, Eiben CB, Liu Y, Skyrud W, Benites VT, Barnum TP, Baidoo EEK, Scheller HV, Marletta MA, Shih PM, Adams PD, and Keasling JD

Subjects

Arabidopsis metabolism, Oryza metabolism, Pseudomonas putida metabolism, Iron metabolism, Lysine metabolism, Oxygenases metabolism

Abstract

Despite intensive study, plant lysine catabolism beyond the 2-oxoadipate (2OA) intermediate remains unvalidated. Recently we described a missing step in the D-lysine catabolism of Pseudomonas putida in which 2OA is converted to D-2-hydroxyglutarate (2HG) via hydroxyglutarate synthase (HglS), a DUF1338 family protein. Here we solve the structure of HglS to 1.1 Å resolution in substrate-free form and in complex with 2OA. We propose a successive decarboxylation and intramolecular hydroxylation mechanism forming 2HG in a Fe(II)- and O 2 -dependent manner. Specificity is mediated by a single arginine, highly conserved across most DUF1338 proteins. An Arabidopsis thaliana HglS homolog coexpresses with known lysine catabolism enzymes, and mutants show phenotypes consistent with disrupted lysine catabolism. Structural and biochemical analysis of Oryza sativa homolog FLO7 reveals identical activity to HglS despite low sequence identity. Our results suggest DUF1338-containing enzymes catalyze the same biochemical reaction, exerting the same physiological function across bacteria and eukaryotes.

Published

2020

16. Allosteric activation of the nitric oxide receptor soluble guanylate cyclase mapped by cryo-electron microscopy.

Author

Horst BG, Yokom AL, Rosenberg DJ, Morris KL, Hammel M, Hurley JH, and Marletta MA

Subjects

Allosteric Regulation, Animals, Indazoles metabolism, Nitric Oxide metabolism, Protein Conformation, Cryoelectron Microscopy, Manduca enzymology, Soluble Guanylyl Cyclase ultrastructure

Abstract

Soluble guanylate cyclase (sGC) is the primary receptor for nitric oxide (NO) in mammalian nitric oxide signaling. We determined structures of full-length Manduca sexta sGC in both inactive and active states using cryo-electron microscopy. NO and the sGC-specific stimulator YC-1 induce a 71° rotation of the heme-binding β H-NOX and PAS domains. Repositioning of the β H-NOX domain leads to a straightening of the coiled-coil domains, which, in turn, use the motion to move the catalytic domains into an active conformation. YC-1 binds directly between the β H-NOX domain and the two CC domains. The structural elongation of the particle observed in cryo-EM was corroborated in solution using small angle X-ray scattering (SAXS). These structures delineate the endpoints of the allosteric transition responsible for the major cyclic GMP-dependent physiological effects of NO., Competing Interests: BH, AY, DR, KM, MH, JH No competing interests declared, MM Reviewing editor, eLife

Published

2019

17. Allorecognition upon Fungal Cell-Cell Contact Determines Social Cooperation and Impacts the Acquisition of Multicellularity.

Author

Gonçalves AP, Heller J, Span EA, Rosenfield G, Do HP, Palma-Guerrero J, Requena N, Marletta MA, and Glass NL

Subjects

Alleles, Amino Acid Sequence genetics, Cell Communication physiology, Cell Fusion, Evolution, Molecular, Fungal Proteins genetics, Fungal Proteins metabolism, Genes, Fungal genetics, Neurospora crassa genetics, Neurospora crassa growth & development, Phylogeny, Polymorphism, Genetic genetics, Cell Communication genetics, Cell Wall genetics, Cell Wall metabolism

Abstract

Somatic cell fusion and conspecific cooperation are crucial social traits for microbial unicellular-to-multicellular transitions, colony expansion, and substrate foraging but are also associated with risks of parasitism. We identified a cell wall remodeling (cwr) checkpoint that acts upon cell contact to assess genetic compatibility and regulate cell wall dissolution during somatic cell fusion in a wild population of the filamentous fungus Neurospora crassa. Non-allelic interactions between two linked loci, cwr-1 and cwr-2, were necessary and sufficient to block cell fusion: cwr-1 encodes a polysaccharide monooxygenase (PMO), a class of enzymes associated with extracellular degradative capacities, and cwr-2 encodes a predicted transmembrane protein. Mutations of sites in CWR-1 essential for PMO catalytic activity abolished the block in cell fusion between formerly incompatible strains. In Neurospora, alleles cwr-1 and cwr-2 were highly polymorphic, fell into distinct haplogroups, and showed trans-species polymorphisms. Distinct haplogroups and trans-species polymorphisms at cwr-1 and cwr-2 were also identified in the distantly related genus Fusarium, suggesting convergent evolution. Proteins involved in chemotropic processes showed extended localization at contact sites, suggesting that cwr regulates the transition between chemotropic growth and cell wall dissolution. Our work revealed an allorecognition surveillance system based on kind discrimination that inhibits cooperative behavior in fungi by blocking cell fusion upon contact, contributing to fungal immunity by preventing formation of chimeras between genetically non-identical colonies., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

18. Substrate selectivity in starch polysaccharide monooxygenases.

Author

Vu VV, Hangasky JA, Detomasi TC, Henry SJW, Ngo ST, Span EA, and Marletta MA

Subjects

Amylose chemistry, Amylose metabolism, Binding Sites, Catalytic Domain, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Molecular Docking Simulation, Neurospora crassa enzymology, Oxidation-Reduction, Protein Conformation, alpha-Helical, Sordariales enzymology, Starch chemistry, Substrate Specificity, Fungal Proteins metabolism, Mixed Function Oxygenases metabolism, Starch metabolism

Abstract

Degradation of polysaccharides is central to numerous biological and industrial processes. Starch-active polysaccharide monooxygenases (AA13 PMOs) oxidatively degrade starch and can potentially be used with industrial amylases to convert starch into a fermentable carbohydrate. The oxidative activities of the starch-active PMOs from the fungi Neurospora crassa and Myceliophthora thermophila , Nc AA13 and Mt AA13, respectively, on three different starch substrates are reported here. Using high-performance anion-exchange chromatography coupled with pulsed amperometry detection, we observed that both enzymes have significantly higher oxidative activity on amylose than on amylopectin and cornstarch. Analysis of the product distribution revealed that Nc AA13 and Mt AA13 more frequently oxidize glycosidic linkages separated by multiples of a helical turn consisting of six glucose units on the same amylose helix. Docking studies identified important residues that are involved in amylose binding and suggest that the shallow groove that spans the active-site surface of AA13 PMOs favors the binding of helical amylose substrates over nonhelical substrates. Truncations of Nc AA13 that removed its native carbohydrate-binding module resulted in diminished binding to amylose, but truncated Nc AA13 still favored amylose oxidation over other starch substrates. These findings establish that AA13 PMOs preferentially bind and oxidize the helical starch substrate amylose. Moreover, the product distributions of these two enzymes suggest a unique interaction with starch substrates., (© 2019 Vu et al.)

Published

2019

19. Characterization of a Carbon Monoxide-Activated Soluble Guanylate Cyclase from Chlamydomonas reinhardtii.

Author

Horst BG, Stewart EM, Nazarian AA, and Marletta MA

Subjects

Algal Proteins chemistry, Algal Proteins genetics, Carbon Dioxide metabolism, Chlamydomonas reinhardtii genetics, Heme chemistry, Heme metabolism, Kinetics, Nitric Oxide metabolism, Protein Binding, Protein Multimerization, Signal Transduction, Soluble Guanylyl Cyclase chemistry, Soluble Guanylyl Cyclase genetics, Up-Regulation, Algal Proteins metabolism, Carbon Monoxide metabolism, Chlamydomonas reinhardtii enzymology, Soluble Guanylyl Cyclase metabolism

Abstract

Signaling pathways that involve diatomic gases in photosynthetic organisms are not well understood. Exposure to nitric oxide or carbon monoxide is known to elicit certain responses in some photosynthetic organisms. For example, Chlamydomonas reinhardtii grown in low-iron media responds to exogenous carbon monoxide by increasing cell growth and intracellular chlorophyll levels. Here, we characterize Cyg11, a gas-responsive soluble guanylate cyclase from the eukaryotic green alga C. reinhardtii that converts GTP to cGMP. Cyg11 transcription is upregulated when C. reinhardtii is grown in iron-limited media, suggesting its importance in nutrient-limited environments. Cyg11 is purified as a homodimer and is activated by nitric oxide (2.5-fold over basal activity) and carbon monoxide (6.3-fold). The heme binding stoichiometry of Cyg11 was found to be one heme per homodimer, an unexpected result based on the sequence and oligomerization state of the enzyme. Gas binding properties, the kinetics of gas binding, and the ligand-modulated activity of Cyg11 are consistent with CO as the relevant physiological ligand.

Published

2019

20. Structural Insight into H-NOX Gas Sensing and Cognate Signaling Protein Regulation.

Author

Guo Y and Marletta MA

Subjects

Bacteria metabolism, Escherichia coli Proteins metabolism, Histidine Kinase metabolism, Phosphorus-Oxygen Lyases metabolism, Protein Binding, Protein Domains, Signal Transduction physiology, Bacterial Proteins metabolism, Hemeproteins metabolism, Nitric Oxide metabolism, Oxygen metabolism

Abstract

Heme-nitric oxide/oxygen binding (H-NOX) proteins are a family of gas-binding hemoproteins that bind diatomic gas ligands such as nitric oxide (NO) and oxygen (O 2 ). In bacteria, H-NOXs are often associated with signaling partners, including histidine kinases (HKs), diguanylate cyclases (DGCs) or methyl-accepting chemotaxis proteins (MCPs), either as a stand-alone protein or as a domain of a larger polypeptide. H-NOXs regulate the activity of cognate signaling proteins through ligand-induced conformational changes in the H-NOX domain and protein/protein interactions between the H-NOX and the cognate signaling partner. This review summarizes recent progress toward deciphering the molecular mechanism of bacterial H-NOX activation and the subsequent regulation of H-NOX-associated cognate sensor proteins from a structural and biochemical point of view., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

21. A Dual-H-NOX Signaling System in Saccharophagus degradans.

Author

Guo Y, Cooper MM, Bromberg R, and Marletta MA

Subjects

Bacterial Proteins chemistry, Hemeproteins chemistry, Phylogeny, Bacterial Proteins metabolism, Gammaproteobacteria metabolism, Hemeproteins metabolism, Histidine Kinase antagonists & inhibitors, Nitric Oxide metabolism

Abstract

Nitric oxide (NO) is a critical signaling molecule involved in the regulation of a wide variety of physiological processes across every domain of life. In most aerobic and facultative anaerobic bacteria, heme-nitric oxide/oxygen binding (H-NOX) proteins selectively sense NO and inhibit the activity of a histidine kinase (HK) located on the same operon. This NO-dependent inhibition of the cognate HK alters the phosphorylation of the downstream response regulators. In the marine bacterium Saccharophagus degradans ( Sde), in addition to a typical H-NOX ( Sde 3804)/HK ( Sde 3803) pair, an orphan H-NOX ( Sde 3557) with no associated signaling protein has been identified distant from the H-NOX/HK pair in the genome. The characterization reported here elucidates the function of both H-NOX proteins. Sde 3557 exhibits a weaker binding affinity with the kinase, yet both Sde 3804 and Sde 3557 are functional H-NOXs with proper gas binding properties and kinase inhibition activity. Additionally, Sde 3557 has an NO dissociation rate that is significantly slower than that of Sde 3804, which may confer prolonged kinase inhibition in vivo. While it is still unclear whether Sde 3557 has another signaling partner or shares the histidine kinase with Sde 3804, Sde 3557 is the only orphan H-NOX characterized to date. S. degradans is likely using a dual-H-NOX system to fine-tune the downstream response of NO signaling.

Published

2018

22. Physiological activation and deactivation of soluble guanylate cyclase.

Author

Horst BG and Marletta MA

Subjects

Animals, Enzyme Activation, Humans, Nitric Oxide metabolism, Signal Transduction, Soluble Guanylyl Cyclase metabolism

Abstract

Soluble guanylate cyclase (sGC) is responsible for transducing the gaseous signaling molecule nitric oxide (NO) into the ubiquitous secondary signaling messenger cyclic guanosine monophosphate in eukaryotic organisms. sGC is exquisitely tuned to respond to low levels of NO, allowing cells to respond to non-toxic levels of NO. In this review, the structure of sGC is discussed in the context of sGC activation and deactivation. The sequence of events in the activation pathway are described into a comprehensive model of in vivo sGC activation as elucidated both from studies with purified enzyme and those done in cells. This model is then used to discuss the deactivation of sGC, as well as the molecular mechanisms of pathophysiological deactivation., (Copyright © 2018. Published by Elsevier Inc.)

Published

2018

23. Native Alanine Substitution in the Glycine Hinge Modulates Conformational Flexibility of Heme Nitric Oxide/Oxygen (H-NOX) Sensing Proteins.

Author

Hespen CW, Bruegger JJ, Guo Y, and Marletta MA

Subjects

Alanine chemistry, Bacterial Proteins chemistry, Glycine chemistry, Heme chemistry, Hemeproteins chemistry, Ligands, Mutation, Oxidation-Reduction, Pliability, Protein Binding, Protein Conformation, Bacterial Proteins metabolism, Flavobacteriaceae chemistry, Hemeproteins metabolism, Nitric Oxide metabolism

Abstract

Heme nitric oxide/oxygen sensing (H-NOX) domains are direct NO sensors that regulate a variety of biological functions in both bacteria and eukaryotes. Previous work on H-NOX proteins has shown that upon NO binding, a conformational change occurs along two glycine residues on adjacent helices (termed the glycine hinge). Despite the apparent importance of the glycine hinge, it is not fully conserved in all H-NOX domains. Several H-NOX sensors from the family Flavobacteriaceae contain a native alanine substitution in one of the hinge residues. In this work, the effect of the increased steric bulk within the Ala-Gly hinge on H-NOX function was investigated. The hinge in Kordia algicida OT-1 ( Ka H-NOX) is composed of A71 and G145. Ligand-binding properties and signaling function for this H-NOX were characterized. The variant A71G was designed to convert the hinge region of Ka H-NOX to the typical Gly-Gly motif. In activity assays with its cognate histidine kinase (HnoK), the wild type displayed increased signal specificity compared to A71G. Increasing titrations of unliganded A71G gradually inhibits HnoK autophosphorylation, while increasing titrations of unliganded wild type H-NOX does not inhibit HnoK. Crystal structures of both wild type and A71G Ka H-NOX were solved to 1.9 and 1.6 Å, respectively. Regions of H-NOX domains previously identified as involved in protein-protein interactions with HnoK display significantly higher b-factors in A71G compared to wild-type H-NOX. Both biochemical and structural data indicate that the hinge region controls overall conformational flexibility of the H-NOX, affecting NO complex formation and regulation of its HnoK.

Published

2018

24. A Random-Sequential Kinetic Mechanism for Polysaccharide Monooxygenases.

Author

Hangasky JA and Marletta MA

Subjects

Catalysis, Copper metabolism, Hydrogen-Ion Concentration, Kinetics, Mixed Function Oxygenases metabolism, Oxidation-Reduction, Oxygen chemistry, Polysaccharides chemistry, Copper chemistry, Mixed Function Oxygenases chemistry

Abstract

Polysaccharide monooxygenases (PMOs) are mononuclear copper enzymes that catalyze the hydroxylation of polysaccharides leading to the scission of the glycosidic bond. The mechanism, in which PMOs utilize molecular oxygen to oxidize the polysaccharide substrate, still remains largely unknown. Here, steady-state kinetics assays were used to probe the mechanism of oxygen-dependent cellohexaose oxidation catalyzed by MtPMO9E. Kinetic analysis indicated that both k cat / K M(O 2 ) and k cat / K M(Glc6) were dependent on the concentration of the second substrate. Inhibition studies using carbon monoxide were also carried out. In addition, K D values for Glc6 were determined for the Cu(I) and Cu(II) forms of the enzyme. Taken together, PMOs follow a random-sequential kinetic mechanism to form a ternary ES-O 2 complex. The optimal pH for MtPMO9E turnover was determined to be between pH 6.00 and pH 7.00. Furthermore, the kinetic parameters k cat , k cat / K M(O 2 ) , and k cat / K M(Glc6) demonstrate a decrease in PMO activity at a low pH and provide equivalent kinetic p K a 's of 5.10. This points to the protonation of a general base required for turnover. These results provide a basis for the initial chemical steps in the mechanism of PMOs.

Published

2018

25. Reactivity of O 2 versus H 2 O 2 with polysaccharide monooxygenases.

Author

Hangasky JA, Iavarone AT, and Marletta MA

Subjects

Catalytic Domain, Copper chemistry, Fungal Proteins chemistry, Glycoside Hydrolases chemistry, Hydrogen Peroxide chemistry, Mixed Function Oxygenases chemistry, Oxygen chemistry, Sordariales enzymology

Abstract

Enzymatic conversion of polysaccharides into lower-molecular-weight, soluble oligosaccharides is dependent on the action of hydrolytic and oxidative enzymes. Polysaccharide monooxygenases (PMOs) use an oxidative mechanism to break the glycosidic bond of polymeric carbohydrates, thereby disrupting the crystalline packing and creating new chain ends for hydrolases to depolymerize and degrade recalcitrant polysaccharides. PMOs contain a mononuclear Cu(II) center that is directly involved in C-H bond hydroxylation. Molecular oxygen was the accepted cosubstrate utilized by this family of enzymes until a recent report indicated reactivity was dependent on H 2 O 2 Reported here is a detailed analysis of PMO reactivity with H 2 O 2 and O 2 , in conjunction with high-resolution MS measurements. The cosubstrate utilized by the enzyme is dependent on the assay conditions. PMOs will directly reduce O 2 in the coupled hydroxylation of substrate (monooxygenase activity) and will also utilize H 2 O 2 (peroxygenase activity) produced from the uncoupled reduction of O 2 Both cosubstrates require Cu reduction to Cu(I), but the reaction with H 2 O 2 leads to nonspecific oxidation of the polysaccharide that is consistent with the generation of a hydroxyl radical-based mechanism in Fenton-like chemistry, while the O 2 reaction leads to regioselective substrate oxidation using an enzyme-bound Cu/O 2 reactive intermediate. Moreover, H 2 O 2 does not influence the ability of secretome from Neurospora crassa to degrade Avicel, providing evidence that molecular oxygen is a physiologically relevant cosubstrate for PMOs., Competing Interests: The authors declare no conflict of interest.

Published

2018

26. Comparative and integrative metabolomics reveal that S -nitrosation inhibits physiologically relevant metabolic enzymes.

Author

Bruegger JJ, Smith BC, Wynia-Smith SL, and Marletta MA

Subjects

Animals, Mice, Mice, Knockout, Nitrosation, Oxidoreductases genetics, Metabolome, Metabolomics, Nitric Oxide metabolism, Oxidoreductases metabolism, Protein Processing, Post-Translational

Abstract

Cysteine S -nitrosation is a reversible post-translational modification mediated by nitric oxide ( • NO)-derived agents. S -Nitrosation participates in cellular signaling and is associated with several diseases such as cancer, cardiovascular diseases, and neuronal disorders. Despite the physiological importance of this nonclassical • NO-signaling pathway, little is understood about how much S -nitrosation affects protein function. Moreover, identifying physiologically relevant targets of S -nitrosation is difficult because of the dynamics of transnitrosation and a limited understanding of the physiological mechanisms leading to selective protein S -nitrosation. To identify proteins whose activities are modulated by S -nitrosation, we performed a metabolomics study comparing WT and endothelial nitric-oxide synthase knockout mice. We integrated our results with those of a previous proteomics study that identified physiologically relevant S -nitrosated cysteines, and we found that the activity of at least 21 metabolic enzymes might be regulated by S -nitrosation. We cloned, expressed, and purified four of these enzymes and observed that S -nitrosation inhibits the metabolic enzymes 6-phosphogluconate dehydrogenase, Δ1-pyrroline-5-carboxylate dehydrogenase, catechol- O -methyltransferase, and d-3-phosphoglycerate dehydrogenase. Furthermore, using site-directed mutagenesis, we identified the predominant cysteine residue influencing the observed activity changes in each enzyme. In summary, using an integrated metabolomics approach, we have identified several physiologically relevant S -nitrosation targets, including metabolic enzymes, which are inhibited by this modification, and we have found the cysteines modified by S -nitrosation in each enzyme., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

27. Mapping the H-NOX/HK Binding Interface in Vibrio cholerae by Hydrogen/Deuterium Exchange Mass Spectrometry.

Author

Guo Y, Iavarone AT, Cooper MM, and Marletta MA

Subjects

Bacterial Proteins metabolism, Deuterium Exchange Measurement, Hemeproteins metabolism, Histidine Kinase metabolism, Mass Spectrometry, Nitric Oxide metabolism, Vibrio cholerae metabolism, Bacterial Proteins chemistry, Hemeproteins chemistry, Histidine Kinase chemistry, Nitric Oxide chemistry, Vibrio cholerae chemistry

Abstract

Heme-nitric oxide/oxygen binding (H-NOX) proteins are a group of hemoproteins that bind diatomic gas ligands such as nitric oxide (NO) and oxygen (O 2 ). H-NOX proteins typically regulate histidine kinases (HK) located within the same operon. It has been reported that NO-bound H-NOXs inhibit cognate histidine kinase autophosphorylation in bacterial H-NOX/HK complexes; however, a detailed mechanism of NO-mediated regulation of the H-NOX/HK activity remains unknown. In this study, the binding interface of Vibrio cholerae ( Vc) H-NOX/HK complex was characterized by hydrogen/deuterium exchange mass spectrometry (HDX-MS) and further validated by mutagenesis, leading to a new model for NO-dependent kinase inhibition. A conformational change in Vc H-NOX introduced by NO generates a new kinase-binding interface, thus locking the kinase in an inhibitory conformation.

Published

2018

28. Regulation of nitric oxide signaling by formation of a distal receptor-ligand complex.

Author

Guo Y, Suess DLM, Herzik MA Jr, Iavarone AT, Britt RD, and Marletta MA

Subjects

Bacterial Proteins chemistry, Bacterial Proteins isolation & purification, Histidine Kinase antagonists & inhibitors, Histidine Kinase metabolism, Ligands, Models, Molecular, Nitric Oxide chemistry, Bacterial Proteins metabolism, Nitric Oxide metabolism, Shewanella metabolism, Signal Transduction

Abstract

The binding of nitric oxide (NO) to the heme cofactor of heme-nitric oxide/oxygen binding (H-NOX) proteins can lead to the dissociation of the heme-ligating histidine residue and yield a five-coordinate nitrosyl complex, an important step for NO-dependent signaling. In the five-coordinate nitrosyl complex, NO can reside on either the distal or proximal side of the heme, which could have a profound influence over the lifetime of the in vivo signal. To investigate this central molecular question, we characterized the Shewanella oneidensis H-NOX (So H-NOX)-NO complex biophysically under limiting and excess NO conditions. The results show that So H-NOX preferably forms a distal NO species with both limiting and excess NO. Therefore, signal strength and complex lifetime in vivo will be dictated by the dissociation rate of NO from the distal complex and the rebinding of the histidine ligand to the heme.

Published

2017

29. Physiological and Molecular Understanding of Bacterial Polysaccharide Monooxygenases.

Author

Agostoni M, Hangasky JA, and Marletta MA

Subjects

Animals, Bacteria genetics, Bacteria metabolism, Bacteria pathogenicity, Bacterial Infections microbiology, Cellulose metabolism, Chitin metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Host-Pathogen Interactions, Humans, Listeria monocytogenes enzymology, Listeria monocytogenes genetics, Mixed Function Oxygenases chemistry, Pseudomonas enzymology, Pseudomonas genetics, Substrate Specificity, Virulence Factors, Bacteria enzymology, Mixed Function Oxygenases genetics, Mixed Function Oxygenases metabolism, Polysaccharides, Bacterial chemistry, Polysaccharides, Bacterial metabolism

Abstract

Bacteria have long been known to secrete enzymes that degrade cellulose and chitin. The degradation of these two polymers predominantly involves two enzyme families that work synergistically with one another: glycoside hydrolases (GHs) and polysaccharide monooxygenases (PMOs). Although bacterial PMOs are a relatively recent addition to the known biopolymer degradation machinery, there is an extensive amount of literature implicating PMO in numerous physiological roles. This review focuses on these diverse and physiological aspects of bacterial PMOs, including facilitating endosymbiosis, conferring a nutritional advantage, and enhancing virulence in pathogenic organisms. We also discuss the correlation between the presence of PMOs and bacterial lifestyle and speculate on the advantages conferred by PMOs under these conditions. In addition, the molecular aspects of bacterial PMOs, as well as the mechanisms regulating PMO expression and the function of additional domains associated with PMOs, are described. We anticipate that increasing research efforts in this field will continue to expand our understanding of the molecular and physiological roles of bacterial PMOs., (Copyright © 2017 American Society for Microbiology.)

Published

2017

30. The Role of the Secondary Coordination Sphere in a Fungal Polysaccharide Monooxygenase.

Author

Span EA, Suess DLM, Deller MC, Britt RD, and Marletta MA

Subjects

Crystallography, X-Ray, Hydrogen Bonding, Protein Conformation, Fungal Polysaccharides chemistry, Mixed Function Oxygenases chemistry

Abstract

Polysaccharide monooxygenases (PMOs) are secreted metalloenzymes that catalyze the oxidative degradation of polysaccharides in a copper-, oxygen-, and reductant-dependent manner. Cellulose-active fungal PMOs degrade cellulosic substrates to be utilized as a carbon source for fungal growth. To gain insight into the PMO mechanism, the role of conserved residues in the copper coordination sphere was investigated. Here, we report active-site hydrogen-bonding motifs in the secondary copper coordination sphere of MtPMO3*, a C1-oxidizing PMO from the ascomycete fungus Myceliophthora thermophila. A series of point substitutions that disrupt this conserved network are used to interrogate its function. Activity assays, in conjunction with EPR spectroscopy, demonstrate that residues H161 and Q167 are involved in stabilizing bound oxygen, and H161 appears to play a role in proton transfer. Additionally, Q167 increases the ligand donor strength of Y169 to the copper via a hydrogen-bonding interaction. Altogether, H161 and Q167 are important for oxygen activation, and the results are suggestive of a copper-oxyl active intermediate.

Published

2017

31. Nitric Oxide-Induced Conformational Changes Govern H-NOX and Histidine Kinase Interaction and Regulation in Shewanella oneidensis.

Author

Rao M, Herzik MA Jr, Iavarone AT, and Marletta MA

Subjects

Histidine Kinase genetics, Kinetics, Models, Molecular, Mutagenesis, Protein Binding drug effects, Signal Transduction drug effects, Substrate Specificity, Catalytic Domain drug effects, Heme metabolism, Histidine Kinase chemistry, Histidine Kinase metabolism, Nitric Oxide pharmacology, Shewanella enzymology

Abstract

Nitric oxide (NO) is implicated in biofilm regulation in several bacterial families via heme-nitric oxide/oxygen binding (H-NOX) protein signaling. Shewanella oneidensis H-NOX (So H-NOX) is associated with a histidine kinase (So HnoK) encoded on the same operon, and together they form a multicomponent signaling network whereby the NO-bound state of So H-NOX inhibits So HnoK autophosphorylation activity, affecting the phosphorylation state of three response regulators. Although the conformational changes of So H-NOX upon NO binding have been structurally characterized, the mechanism of HnoK inhibition by NO-bound So H-NOX remains unclear. In the present study, the molecular details of So H-NOX and So HnoK interaction and regulation are characterized. The N-terminal domain in So HnoK was determined to be the site of H-NOX interaction, and the binding interface on So H-NOX was identified using a combination of hydrogen-deuterium exchange mass spectrometry and surface-scanning mutagenesis. Binding kinetics measurements and analytical gel filtration revealed that NO-bound So H-NOX has a tighter affinity for So HnoK compared that of H-NOX in the unliganded state, correlating binding affinity with kinase inhibition. Kinase activity assays with binding-deficient H-NOX mutants further indicate that while formation of the H-NOX-HnoK complex is required for HnoK to be catalytically active, H-NOX conformational changes upon NO-binding are necessary for HnoK inhibition.

Published

2017

32. Structural and Functional Evidence Indicates Selective Oxygen Signaling in Caldanaerobacter subterraneus H-NOX.

Author

Hespen CW, Bruegger JJ, Phillips-Piro CM, and Marletta MA

Subjects

Crystallography, X-Ray, Ferrous Compounds metabolism, Nitric Oxide chemistry, Nitric Oxide metabolism, Protein Conformation, Oxygen metabolism, Signal Transduction, Thermoanaerobacter metabolism

Abstract

Acute and specific sensing of diatomic gas molecules is an essential facet of biological signaling. Heme nitric oxide/oxygen binding (H-NOX) proteins are a family of gas sensors found in diverse classes of bacteria and eukaryotes. The most commonly characterized bacterial H-NOX domains are from facultative anaerobes and are activated through a conformational change caused by formation of a 5-coordinate Fe(II)-NO complex. Members of this H-NOX subfamily do not bind O2 and therefore can selectively ligate NO even under aerobic conditions. In contrast, H-NOX domains encoded by obligate anaerobes do form stable 6-coordinate Fe(II)-O2 complexes by utilizing a conserved H-bonding network in the ligand-binding pocket. The biological function of O2-binding H-NOX domains has not been characterized. In this work, the crystal structures of an O2-binding H-NOX domain from the thermophilic obligate anaerobe Caldanaerobacter subterraneus (Cs H-NOX) in the Fe(II)-NO, Fe(II)-CO, and Fe(II)-unliganded states are reported. The Fe(II)-unliganded structure displays a conformational shift distinct from the NO-, CO-, and previously reported O2-coordinated structures. In orthogonal signaling assays using Cs H-NOX and the H-NOX signaling effector histidine kinase from Vibrio cholerae (Vc HnoK), Cs H-NOX regulates Vc HnoK in an O2-dependent manner and requires the H-bonding network to distinguish O2 from other ligands. The crystal structures of Fe(II) unliganded and NO- and CO-bound Cs H-NOX combined with functional assays herein provide the first evidence that H-NOX proteins from obligate anaerobes can serve as O2 sensors.

Published

2016

33. Starch-degrading polysaccharide monooxygenases.

Author

Vu VV and Marletta MA

Subjects

Amino Acid Sequence, Computational Biology, Models, Molecular, Starch chemistry, Substrate Specificity, Mixed Function Oxygenases metabolism, Starch metabolism

Abstract

Polysaccharide degradation by hydrolytic enzymes glycoside hydrolases (GHs) is well known. More recently, polysaccharide monooxygenases (PMOs, also known as lytic PMOs or LPMOs) were found to oxidatively degrade various polysaccharides via a copper-dependent hydroxylation. PMOs were previously thought to be either GHs or carbohydrate binding modules (CBMs), and have been re-classified in carbohydrate active enzymes (CAZY) database as auxiliary activity (AA) families. These enzymes include cellulose-active fungal PMOs (AA9, formerly GH61), chitin- and cellulose-active bacterial PMOs (AA10, formerly CBM33), and chitin-active fungal PMOs (AA11). These PMOs significantly boost the activity of GHs under industrially relevant conditions, and thus have great potential in the biomass-based biofuel industry. PMOs that act on starch are the latest PMOs discovered (AA13), which has expanded our perspectives in PMOs studies and starch degradation. Starch-active PMOs have many common structural features and biochemical properties of the PMO superfamily, yet differ from other PMO families in several important aspects. These differences likely correlate, at least in part, to the differences in primary and higher order structures of starch and cellulose, and chitin. In this review we will discuss the discovery, structural features, biochemical and biophysical properties, and possible biological functions of starch-active PMOs, as well as their potential application in the biofuel, food, and other starch-based industries. Important questions regarding various aspects of starch-active PMOs and possible economical driving force for their future studies will also be highlighted.

Published

2016

34. Chemoproteomic Strategy to Quantitatively Monitor Transnitrosation Uncovers Functionally Relevant S-Nitrosation Sites on Cathepsin D and HADH2.

Author

Zhou Y, Wynia-Smith SL, Couvertier SM, Kalous KS, Marletta MA, Smith BC, and Weerapana E

Subjects

3-Hydroxyacyl CoA Dehydrogenases isolation & purification, Humans, MCF-7 Cells, Nitrosation, 3-Hydroxyacyl CoA Dehydrogenases chemistry, 3-Hydroxyacyl CoA Dehydrogenases metabolism, Cathepsin D chemistry, Cathepsin D metabolism, Proteomics

Abstract

S-Nitrosoglutathione (GSNO) is an endogenous transnitrosation donor involved in S-nitrosation of a variety of cellular proteins, thereby regulating diverse protein functions. Quantitative proteomic methods are necessary to establish which cysteine residues are most sensitive to GSNO-mediated transnitrosation. Here, a competitive cysteine-reactivity profiling strategy was implemented to quantitatively measure the sensitivity of >600 cysteine residues to transnitrosation by GSNO. This platform identified a subset of cysteine residues with a high propensity for GSNO-mediated transnitrosation. Functional characterization of previously unannotated S-nitrosation sites revealed that S-nitrosation of a cysteine residue distal to the 3-hydroxyacyl-CoA dehydrogenase type 2 (HADH2) active site impaired catalytic activity. Similarly, S-nitrosation of a non-catalytic cysteine residue in the lysosomal aspartyl protease cathepsin D (CTSD) inhibited proteolytic activation. Together, these studies revealed two previously uncharacterized cysteine residues that regulate protein function, and established a chemical-proteomic platform with capabilities to determine substrate specificity of other cellular transnitrosation agents., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

35. The framework of polysaccharide monooxygenase structure and chemistry.

Author

Span EA and Marletta MA

Subjects

Catalytic Domain, Mixed Function Oxygenases classification, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases metabolism, Polysaccharides metabolism

Abstract

Polysaccharide monooxygenases, or PMOs (also known as lytic PMOs or LPMOs), are a group of enzymes discovered in recent years to catalyze the oxidative degradation of carbohydrate polymers. The PMO catalytic domain has a β-sandwich fold that bears a strong resemblance to both immunoglobulin (Ig) and fibronectin type III (FnIII) domains. PMOs are secreted by fungi and bacteria, and there is recent evidence for their roles in pathogenesis, in addition to biomass processing. This review addresses the biological origins and functions of emerging PMO families, as well as describes the aspects of PMO structure that support the chemistry of copper-catalyzed, oxidative polysaccharide degradation., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

36. The Influence of Nitric Oxide on Soluble Guanylate Cyclase Regulation by Nucleotides: ROLE OF THE PSEUDOSYMMETRIC SITE.

Author

Sürmeli NB, Müskens FM, and Marletta MA

Subjects

Adenosine Triphosphate genetics, Adenosine Triphosphate metabolism, Amino Acid Substitution, Animals, Enzyme Activation, Guanylate Cyclase genetics, Guanylate Cyclase metabolism, Heme genetics, Heme metabolism, Kinetics, Mutation, Missense, Nitric Oxide genetics, Nitric Oxide metabolism, Rats, Receptors, Cytoplasmic and Nuclear genetics, Receptors, Cytoplasmic and Nuclear metabolism, Sf9 Cells, Soluble Guanylyl Cyclase, Spodoptera, Adenosine Triphosphate chemistry, Guanylate Cyclase chemistry, Heme chemistry, Models, Chemical, Nitric Oxide chemistry, Receptors, Cytoplasmic and Nuclear chemistry

Abstract

Activation of soluble guanylate cyclase (sGC) by the signaling molecule nitric oxide (NO) leads to formation of the second messenger cGMP, which mediates numerous physiological processes. NO activates sGC by binding to the ferrous heme cofactor; the relative amount of NO with respect to sGC heme affects the enzyme activity. ATP can also influence the activity by binding to an allosteric site, most likely the pseudosymmetric site located in the catalytic domain. Here, the role of the pseudosymmetric site on nucleotide regulation was investigated by point mutations at this site. ATP inhibition kinetics of wild type and a pseudosymmetric site (α1-C594A/β1-D477A) variant of sGC was determined at various levels of NO. Results obtained show that in the presence of less than 1 eq of NO, there appears to be less than complete activation and little change in the nucleotide binding parameters. The most dramatic effects are observed for the addition of excess NO, which results in an increase in the affinity of GTP at the catalytic site and full activation of sGC. The pseudosymmetric site mutation only affected nucleotide affinities in the presence of excess NO; there was a decrease in the affinity for ATP in both the allosteric and catalytic sites. These observations led to a new kinetic model for sGC activity in the presence of excess NO. This model revealed that the active and allosteric sites show cooperativity. This new comprehensive model gives a more accurate description of sGC regulation by NO and nucleotides in vivo., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

37. Nitric Oxide Mediates Biofilm Formation and Symbiosis in Silicibacter sp. Strain TrichCH4B.

Author

Rao M, Smith BC, and Marletta MA

Subjects

Bacterial Adhesion, Cyanobacteria metabolism, Cyclic GMP analogs & derivatives, Cyclic GMP metabolism, Gene Expression Regulation, Bacterial, Histidine Kinase, Protein Kinases metabolism, Rhodobacteraceae growth & development, Signal Transduction, Transcription Factors metabolism, Biofilms growth & development, Cyanobacteria physiology, Microbial Interactions, Nitric Oxide metabolism, Rhodobacteraceae drug effects, Rhodobacteraceae physiology, Symbiosis

Abstract

Unlabelled: Nitric oxide (NO) plays an important signaling role in all domains of life. Many bacteria contain a heme-nitric oxide/oxygen binding (H-NOX) protein that selectively binds NO. These H-NOX proteins often act as sensors that regulate histidine kinase (HK) activity, forming part of a bacterial two-component signaling system that also involves one or more response regulators. In several organisms, NO binding to the H-NOX protein governs bacterial biofilm formation; however, the source of NO exposure for these bacteria is unknown. In mammals, NO is generated by the enzyme nitric oxide synthase (NOS) and signals through binding the H-NOX domain of soluble guanylate cyclase. Recently, several bacterial NOS proteins have also been reported, but the corresponding bacteria do not also encode an H-NOX protein. Here, we report the first characterization of a bacterium that encodes both a NOS and H-NOX, thus resembling the mammalian system capable of both synthesizing and sensing NO. We characterized the NO signaling pathway of the marine alphaproteobacterium Silicibacter sp. strain TrichCH4B, determining that the NOS is activated by an algal symbiont, Trichodesmium erythraeum. NO signaling through a histidine kinase-response regulator two-component signaling pathway results in increased concentrations of cyclic diguanosine monophosphate, a key bacterial second messenger molecule that controls cellular adhesion and biofilm formation. Silicibacter sp. TrichCH4B biofilm formation, activated by T. erythraeum, may be an important mechanism for symbiosis between the two organisms, revealing that NO plays a previously unknown key role in bacterial communication and symbiosis., Importance: Bacterial nitric oxide (NO) signaling via heme-nitric oxide/oxygen binding (H-NOX) proteins regulates biofilm formation, playing an important role in protecting bacteria from oxidative stress and other environmental stresses. Biofilms are also an important part of symbiosis, allowing the organism to remain in a nutrient-rich environment. In this study, we show that in Silicibacter sp. strain TrichCH4B, NO mediates symbiosis with the alga Trichodesmium erythraeum, a major marine diazotroph. In addition, Silicibacter sp. TrichCH4B is the first characterized bacteria to harbor both the NOS and H-NOX proteins, making it uniquely capable of both synthesizing and sensing NO, analogous to mammalian NO signaling. Our study expands current understanding of the role of NO in bacterial signaling, providing a novel role for NO in bacterial communication and symbiosis., (Copyright © 2015 Rao et al.)

Published

2015

38. Cellulose degradation by polysaccharide monooxygenases.

Author

Beeson WT, Vu VV, Span EA, Phillips CM, and Marletta MA

Subjects

Bacteria metabolism, Fungi enzymology, Fungi metabolism, Phylogeny, Plant Cells chemistry, Plant Cells metabolism, Plants metabolism, Polysaccharides metabolism, Cellulose metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases metabolism

Abstract

Polysaccharide monooxygenases (PMOs), also known as lytic PMOs (LPMOs), enhance the depolymerization of recalcitrant polysaccharides by hydrolytic enzymes and are found in the majority of cellulolytic fungi and actinomycete bacteria. For more than a decade, PMOs were incorrectly annotated as family 61 glycoside hydrolases (GH61s) or family 33 carbohydrate-binding modules (CBM33s). PMOs have an unusual surface-exposed active site with a tightly bound Cu(II) ion that catalyzes the regioselective hydroxylation of crystalline cellulose, leading to glycosidic bond cleavage. The genomes of some cellulolytic fungi contain more than 20 genes encoding cellulose-active PMOs, suggesting a diversity of biological activities. PMOs show great promise in reducing the cost of conversion of lignocellulosic biomass to fermentable sugars; however, many questions remain about their reaction mechanism and biological function. This review addresses, in depth, the structural and mechanistic aspects of oxidative depolymerization of cellulose by PMOs and considers their biological function and phylogenetic diversity.

Published

2015

39. α1-A680T variant in GUCY1A3 as a candidate conferring protection from pulmonary hypertension among Kyrgyz highlanders.

Author

Wilkins MR, Aldashev AA, Wharton J, Rhodes CJ, Vandrovcova J, Kasperaviciute D, Bhosle SG, Mueller M, Geschka S, Rison S, Kojonazarov B, Morrell NW, Neidhardt I, Surmeli NB, Aitman TJ, Stasch JP, Behrends S, and Marletta MA

Subjects

Alleles, Altitude Sickness pathology, Amino Acid Sequence, Animals, Cyclic GMP metabolism, Female, Genotype, Guanylate Cyclase metabolism, HEK293 Cells, High-Throughput Nucleotide Sequencing, Humans, Hypertension, Pulmonary pathology, Male, Middle Aged, Molecular Sequence Data, Nitric Oxide metabolism, Phylogeny, Polymorphism, Single Nucleotide, Receptors, Cytoplasmic and Nuclear metabolism, Sequence Alignment, Sequence Analysis, DNA, Signal Transduction, Soluble Guanylyl Cyclase, Altitude Sickness genetics, Guanylate Cyclase genetics, Hypertension, Pulmonary genetics, Receptors, Cytoplasmic and Nuclear genetics

Abstract

Background: Human variation in susceptibility to hypoxia-induced pulmonary hypertension is well recognized. High-altitude residents who do not develop pulmonary hypertension may host protective gene mutations., Methods and Results: Exome sequencing was conducted on 24 unrelated Kyrgyz highlanders living 2400 to 3800 m above sea level, 12 (10 men; mean age, 54 years) with an elevated mean pulmonary artery pressure (mean±SD, 38.7±2.7 mm Hg) and 12 (11 men; mean age, 52 years) with a normal mean pulmonary artery pressure (19.2±0.6 mm Hg) to identify candidate genes that may influence the pulmonary vascular response to hypoxia. A total of 140 789 exomic variants were identified and 26 116 (18.5%) were classified as novel or rare. Thirty-three novel or rare potential pathogenic variants (frameshift, essential splice-site, and nonsynonymous) were found exclusively in either ≥3 subjects with high-altitude pulmonary hypertension or ≥3 highlanders with a normal mean pulmonary artery pressure. A novel missense mutation in GUCY1A3 in 3 subjects with a normal mean pulmonary artery pressure encodes an α1-A680T soluble guanylate cyclase (sGC) variant. Expression of the α1-A680T sGC variant in reporter cells resulted in higher cyclic guanosine monophosphate production compared with the wild-type enzyme and the purified α1-A680T sGC exhibited enhanced sensitivity to nitric oxide in vitro., Conclusions: The α1-A680T sGC variant may contribute to protection against high-altitude pulmonary hypertension and supports sGC as a pharmacological target for reducing pulmonary artery pressure in humans at altitude., (© 2014 American Heart Association, Inc.)

Published

2014

40. Structural insights into the role of iron-histidine bond cleavage in nitric oxide-induced activation of H-NOX gas sensor proteins.

Author

Herzik MA Jr, Jonnalagadda R, Kuriyan J, and Marletta MA

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites genetics, Crystallography, X-Ray, Heme chemistry, Heme metabolism, Hemeproteins genetics, Hemeproteins metabolism, Histidine metabolism, Iron metabolism, Models, Molecular, Molecular Sequence Data, Molecular Structure, Mutation, Nitric Oxide metabolism, Protein Binding, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Shewanella genetics, Shewanella metabolism, Spectrophotometry, Atomic, Bacterial Proteins chemistry, Hemeproteins chemistry, Histidine chemistry, Iron chemistry, Nitric Oxide chemistry

Abstract

Heme-nitric oxide/oxygen (H-NOX) binding domains are a recently discovered family of heme-based gas sensor proteins that are conserved across eukaryotes and bacteria. Nitric oxide (NO) binding to the heme cofactor of H-NOX proteins has been implicated as a regulatory mechanism for processes ranging from vasodilation in mammals to communal behavior in bacteria. A key molecular event during NO-dependent activation of H-NOX proteins is rupture of the heme-histidine bond and formation of a five-coordinate nitrosyl complex. Although extensive biochemical studies have provided insight into the NO activation mechanism, precise molecular-level details have remained elusive. In the present study, high-resolution crystal structures of the H-NOX protein from Shewanella oneidensis in the unligated, intermediate six-coordinate and activated five-coordinate, NO-bound states are reported. From these structures, it is evident that several structural features in the heme pocket of the unligated protein function to maintain the heme distorted from planarity. NO-induced scission of the iron-histidine bond triggers structural rearrangements in the heme pocket that permit the heme to relax toward planarity, yielding the signaling-competent NO-bound conformation. Here, we also provide characterization of a nonheme metal coordination site occupied by zinc in an H-NOX protein.

Published

2014

41. A family of starch-active polysaccharide monooxygenases.

Author

Vu VV, Beeson WT, Span EA, Farquhar ER, and Marletta MA

Subjects

Copper chemistry, Copper metabolism, Fungal Proteins isolation & purification, Fungal Proteins metabolism, Mixed Function Oxygenases isolation & purification, Mixed Function Oxygenases metabolism, Oxygen chemistry, Oxygen metabolism, Protein Structure, Tertiary, Starch metabolism, Substrate Specificity, Fungal Proteins chemistry, Mixed Function Oxygenases chemistry, Neurospora crassa enzymology, Starch chemistry

Abstract

The recently discovered fungal and bacterial polysaccharide monooxygenases (PMOs) are capable of oxidatively cleaving chitin, cellulose, and hemicelluloses that contain β(1→4) linkages between glucose or substituted glucose units. They are also known collectively as lytic PMOs, or LPMOs, and individually as AA9 (formerly GH61), AA10 (formerly CBM33), and AA11 enzymes. PMOs share several conserved features, including a monocopper center coordinated by a bidentate N-terminal histidine residue and another histidine ligand. A bioinformatic analysis using these conserved features suggested several potential new PMO families in the fungus Neurospora crassa that are likely to be active on novel substrates. Herein, we report on NCU08746 that contains a C-terminal starch-binding domain and an N-terminal domain of previously unknown function. Biochemical studies showed that NCU08746 requires copper, oxygen, and a source of electrons to oxidize the C1 position of glycosidic bonds in starch substrates, but not in cellulose or chitin. Starch contains α(1→4) and α(1→6) linkages and exhibits higher order structures compared with chitin and cellulose. Cellobiose dehydrogenase, the biological redox partner of cellulose-active PMOs, can serve as the electron donor for NCU08746. NCU08746 contains one copper atom per protein molecule, which is likely coordinated by two histidine ligands as shown by X-ray absorption spectroscopy and sequence analysis. Results indicate that NCU08746 and homologs are starch-active PMOs, supporting the existence of a PMO superfamily with a much broader range of substrates. Starch-active PMOs provide an expanded perspective on studies of starch metabolism and may have potential in the food and starch-based biofuel industries.

Published

2014

42. Molecular architecture of mammalian nitric oxide synthases.

Author

Campbell MG, Smith BC, Potter CS, Carragher B, and Marletta MA

Subjects

Animals, Calmodulin chemistry, Calmodulin metabolism, Crystallization, Dimerization, Holoenzymes chemistry, Holoenzymes metabolism, Humans, Imaging, Three-Dimensional, Mammals, Mice, Microscopy, Electron, Transmission, Nitric Oxide metabolism, Nitric Oxide Synthase Type I metabolism, Nitric Oxide Synthase Type II metabolism, Nitric Oxide Synthase Type III metabolism, Oxidoreductases chemistry, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Rats, Nitric Oxide Synthase Type I chemistry, Nitric Oxide Synthase Type II chemistry, Nitric Oxide Synthase Type III chemistry

Abstract

NOSs are homodimeric multidomain enzymes responsible for producing NO. In mammals, NO acts as an intercellular messenger in a variety of signaling reactions, as well as a cytotoxin in the innate immune response. Mammals possess three NOS isoforms--inducible, endothelial, and neuronal NOS--that are composed of an N-terminal oxidase domain and a C-terminal reductase domain. Calmodulin (CaM) activates NO synthesis by binding to the helical region connecting these two domains. Although crystal structures of isolated domains have been reported, no structure is available for full-length NOS. We used high-throughput single-particle EM to obtain the structures and higher-order domain organization of all three NOS holoenzymes. The structures of inducible, endothelial, and neuronal NOS with and without CaM bound are similar, consisting of a dimerized oxidase domain flanked by two separated reductase domains. NOS isoforms adopt many conformations enabled by three flexible linkers. These conformations represent snapshots of the continuous electron transfer pathway from the reductase domain to the oxidase domain, which reveal that only a single reductase domain participates in electron transfer at a time, and that CaM activates NOS by constraining rotational motions and by directly binding to the oxidase domain. Direct visualization of these large conformational changes induced during electron transfer provides significant insight into the molecular underpinnings governing NO formation.

Published

2014

43. Nitric oxide-induced conformational changes in soluble guanylate cyclase.

Author

Underbakke ES, Iavarone AT, Chalmers MJ, Pascal BD, Novick S, Griffin PR, and Marletta MA

Subjects

Amino Acid Sequence, Catalytic Domain, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Guanylate Cyclase genetics, Humans, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Folding, Protein Multimerization, Protein Structure, Secondary, Protein Subunits genetics, Receptors, Cytoplasmic and Nuclear genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Soluble Guanylyl Cyclase, Cyclic GMP chemistry, Guanylate Cyclase chemistry, Nitric Oxide chemistry, Protein Subunits chemistry, Receptors, Cytoplasmic and Nuclear chemistry

Abstract

Soluble guanylate cyclase (sGC) is the primary mediator of nitric oxide (NO) signaling. NO binds the sGC heme cofactor stimulating synthesis of the second messenger cyclic-GMP (cGMP). As the central hub of NO/cGMP signaling pathways, sGC is important in diverse physiological processes such as vasodilation and neurotransmission. Nevertheless, the mechanisms underlying NO-induced cyclase activation in sGC remain unclear. Here, hydrogen/deuterium exchange mass spectrometry (HDX-MS) was employed to probe the NO-induced conformational changes of sGC. HDX-MS revealed NO-induced effects in several discrete regions. NO binding to the heme-NO/O2-binding (H-NOX) domain perturbs a signaling surface implicated in Per/Arnt/Sim (PAS) domain interactions. Furthermore, NO elicits striking conformational changes in the junction between the PAS and helical domains that propagate as perturbations throughout the adjoining helices. Ultimately, NO binding stimulates the catalytic domain by contracting the active site pocket. Together, these conformational changes delineate an allosteric pathway linking NO binding to activation of the catalytic domain., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

44. Direct meso-alkynylation of metalloporphyrins through gold catalysis for hemoprotein engineering.

Author

Nierth A and Marletta MA

Subjects

Catalysis, Models, Molecular, Molecular Conformation, Alkynes chemistry, Ferrous Compounds chemistry, Gold chemistry, Metalloporphyrins chemistry, Protein Engineering

Abstract

A method was developed for the direct functionalization of metalloporphyrins at the methine protons (meso positions) to yield asymmetric alkynylated derivatives by using gold catalysis and hypervalent iodine reagents. This single-step procedure was applied to b-type heme and the product was incorporated into a gas-sensor heme protein. The terminal alkyne allows fluorophore labeling through copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC). Hemoproteins with this type of engineered cofactor have several potential applications in labeling and imaging technologies. Additionally, the alkyne provides a handle for modulating porphyrin electron density, which affects cofactor redox potential and ligand affinity. This method will be helpful for investigating the chemistry of natural heme proteins and for designing artificial variants with altered properties and reactivities., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

45. Single-particle EM reveals the higher-order domain architecture of soluble guanylate cyclase.

Author

Campbell MG, Underbakke ES, Potter CS, Carragher B, and Marletta MA

Subjects

Animals, Cloning, Molecular, Enzyme Activators metabolism, Guanylate Cyclase metabolism, Image Processing, Computer-Assisted, Microscopy, Electron, Transmission, Protein Binding, Protein Structure, Tertiary, Rats, Receptors, Cytoplasmic and Nuclear metabolism, Soluble Guanylyl Cyclase, Guanylate Cyclase chemistry, Guanylate Cyclase ultrastructure, Models, Molecular, Protein Conformation, Receptors, Cytoplasmic and Nuclear chemistry, Receptors, Cytoplasmic and Nuclear ultrastructure

Abstract

Soluble guanylate cyclase (sGC) is the primary nitric oxide (NO) receptor in mammals and a central component of the NO-signaling pathway. The NO-signaling pathways mediate diverse physiological processes, including vasodilation, neurotransmission, and myocardial functions. sGC is a heterodimer assembled from two homologous subunits, each comprised of four domains. Although crystal structures of isolated domains have been reported, no structure is available for full-length sGC. We used single-particle electron microscopy to obtain the structure of the complete sGC heterodimer and determine its higher-order domain architecture. Overall, the protein is formed of two rigid modules: the catalytic dimer and the clustered Per/Art/Sim and heme-NO/O2-binding domains, connected by a parallel coiled coil at two hinge points. The quaternary assembly demonstrates a very high degree of flexibility. We captured hundreds of individual conformational snapshots of free sGC, NO-bound sGC, and guanosine-5'-[(α,β)-methylene]triphosphate-bound sGC. The molecular architecture and pronounced flexibility observed provides a significant step forward in understanding the mechanism of NO signaling.

Published

2014

46. Determinants of regioselective hydroxylation in the fungal polysaccharide monooxygenases.

Author

Vu VV, Beeson WT, Phillips CM, Cate JH, and Marletta MA

Subjects

Amino Acid Sequence, Carbohydrate Conformation, Fungal Proteins chemistry, Hydroxylation, Mixed Function Oxygenases chemistry, Models, Molecular, Molecular Sequence Data, Phylogeny, Polysaccharides chemistry, Sequence Alignment, Stereoisomerism, Fungal Proteins metabolism, Mixed Function Oxygenases metabolism, Neurospora crassa enzymology, Polysaccharides metabolism

Abstract

The ubiquitous fungal polysaccharide monooxygenases (PMOs) (also known as GH61 proteins, LPMOs, and AA9 proteins) are structurally related but have significant variation in sequence. A heterologous expression method in Neurospora crassa was developed as a step toward connecting regioselectivity of the chemistry to PMO phylogeny. Activity assays, as well as sequence and phylogenetic analyses, showed that the majority of fungal PMOs fall into three major groups with distinctive active site surface features. PMO1s and PMO2s hydroxylate glycosidic positions C1 and C4, respectively. PMO3s hydroxylate both C1 and C4. A subgroup of PMO3s (PMO3*) hydroxylate C1. Mutagenesis studies showed that an extra subdomain of about 12 amino acids contribute to C4 oxidation in the PMO3 family.

Published

2014

47. Phosphorylation-dependent derepression by the response regulator HnoC in the Shewanella oneidensis nitric oxide signaling network.

Author

Plate L and Marletta MA

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, DNA Footprinting, Electrophoretic Mobility Shift Assay, Microarray Analysis, Models, Biological, Phosphorylation, Regulatory Elements, Transcriptional genetics, Shewanella growth & development, Bacterial Proteins physiology, Biofilms growth & development, Nitric Oxide metabolism, Regulatory Elements, Transcriptional physiology, Shewanella metabolism, Signal Transduction physiology

Abstract

Nitric oxide (NO) is an important signaling molecule that regulates diverse physiological processes in all domains of life. In many gammaproteobacteria, NO controls behavioral responses through a complex signaling network involving heme-nitric oxide/oxygen binding (H-NOX) domains as selective NO sensors. In Shewanella oneidensis, H-NOX-mediated NO sensing increases biofilm formation, which is thought to serve as a protective mechanism against NO cytotoxicity. The H-NOX/NO-responsive (hno) signaling network involves H-NOX-dependent control of HnoK autophosphorylation and phosphotransfer from HnoK to three response regulators. Two of these response regulators, HnoB and HnoD, regulate cyclic-di-GMP levels and influence biofilm formation. However, the role of the third response regulator in the signaling network, HnoC, has not been determined. Here we describe a role for HnoC as a transcriptional repressor for the signaling genes in the hno network. The genes controlled by HnoC were identified by microarray analysis, and its function as a repressor was confirmed in vivo. HnoC belongs to an uncharacterized family of DNA-binding response regulators. Binding of HnoC to its promoter targets was characterized in vitro, revealing an unprecedented regulation mechanism, which further extends the functional capabilities of DNA-binding response regulators. In the unphosphorylated state HnoC forms a tetramer, which tightly binds to an inverted-repeat target sequence overlapping with the promoter regions. Phosphorylation of HnoC induces dissociation of the response regulator tetramer and detachment of subunits from the promoter DNA, which subsequently leads to transcriptional derepression.

Published

2013

48. Nitric oxide-sensing H-NOX proteins govern bacterial communal behavior.

Author

Plate L and Marletta MA

Subjects

Bacterial Proteins chemistry, Models, Molecular, Bacteria metabolism, Bacterial Proteins metabolism, Heme metabolism, Nitric Oxide metabolism

Abstract

Heme-nitric oxide/oxygen binding (H-NOX) domains function as sensors for the gaseous signaling agent nitric oxide (NO) in eukaryotes and bacteria. Mammalian NO signaling is well characterized and involves the H-NOX domain of soluble guanylate cyclase. In bacteria, H-NOX proteins interact with bacterial signaling proteins in two-component signaling systems or in cyclic-di-GMP metabolism. Characterization of several downstream signaling processes has shown that bacterial H-NOX proteins share a common role in controlling important bacterial communal behaviors in response to NO. The H-NOX pathways regulate motility, biofilm formation, quorum sensing, and symbiosis. Here, we review the latest structural and mechanistic studies that have elucidated how H-NOX domains selectively bind NO and transduce ligand binding into conformational changes that modulate activity of signaling partners. Furthermore, we summarize the recent advances in understanding the physiological function and biochemical details of the H-NOX signaling pathways., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

49. Porphyrin π-stacking in a heme protein scaffold tunes gas ligand affinity.

Author

Weinert EE, Phillips-Piro CM, and Marletta MA

Subjects

Carbon Dioxide metabolism, Carbon Monoxide metabolism, Hemeproteins metabolism, Ligands, Models, Molecular, Oxidation-Reduction, Oxygen metabolism, Porphyrins metabolism, Carbon Dioxide chemistry, Carbon Monoxide chemistry, Hemeproteins chemistry, Oxygen chemistry, Porphyrins chemistry

Abstract

The role of π-stacking in controlling redox and ligand binding properties of porphyrins has been of interest for many years. The recent discovery of H-NOX domains has provided a model system to investigate the role of porphyrin π-stacking within a heme protein scaffold. Removal of a phenylalanine-porphyrin π-stack dramatically increased O2, NO, and CO affinities and caused changes in redox potential (~40mV) without any structural changes. These results suggest that small changes in redox potential affect ligand affinity and that π-stacking may provide a novel route to engineer heme protein properties for new functions., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

50. Nitric oxide synthase domain interfaces regulate electron transfer and calmodulin activation.

Author

Smith BC, Underbakke ES, Kulp DW, Schief WR, and Marletta MA

Subjects

Animals, Calmodulin metabolism, Deuterium Exchange Measurement, Dimerization, Electron Transport, Electrophoresis, Polyacrylamide Gel, Flavin Mononucleotide metabolism, Flavin-Adenine Dinucleotide metabolism, Fluorescence, Heme metabolism, Mass Spectrometry, Nitric Oxide Synthase Type II genetics, Nitric Oxide Synthase Type II metabolism, Species Specificity, Calmodulin chemistry, Models, Molecular, Nitric Oxide Synthase Type II chemistry, Protein Conformation

Abstract

Nitric oxide (NO) produced by NO synthase (NOS) participates in diverse physiological processes such as vasodilation, neurotransmission, and the innate immune response. Mammalian NOS isoforms are homodimers composed of two domains connected by an intervening calmodulin-binding region. The N-terminal oxidase domain binds heme and tetrahydrobiopterin and the arginine substrate. The C-terminal reductase domain binds FAD and FMN and the cosubstrate NADPH. Although several high-resolution structures of individual NOS domains have been reported, a structure of a NOS holoenzyme has remained elusive. Determination of the higher-order domain architecture of NOS is essential to elucidate the molecular underpinnings of NO formation. In particular, the pathway of electron transfer from FMN to heme, and the mechanism through which calmodulin activates this electron transfer, are largely unknown. In this report, hydrogen-deuterium exchange mass spectrometry was used to map critical NOS interaction surfaces. Direct interactions between the heme domain, the FMN subdomain, and calmodulin were observed. These interaction surfaces were confirmed by kinetic studies of site-specific interface mutants. Integration of the hydrogen-deuterium exchange mass spectrometry results with computational docking resulted in models of the NOS heme and FMN subdomain bound to calmodulin. These models suggest a pathway for electron transfer from FMN to heme and a mechanism for calmodulin activation of this critical step.

Published

2013