Metalloenzymes required for glycan processing and morphological development in Streptomyces lividans

Streptomyces are filamentous soil-dwelling bacteria with a complex life cycle. Elucidating the signals that regulate morphological change in microbes is of fundamental importance for biotechnology applications. In the case of Streptomyces a development switch occurs with the concomitant production of secondary metabolites, many of which have pharmaceutical properties. For the industrially used strain S. lividans this switch is dependent on the bioavailability of copper (Cu) in the environment. This thesis has explored the relationship between Cu-chaperones and a haem peroxidase, part of the sco operon, with the maturation of a Cu-containing oxidase, GlxA. In S. lividans the GlxA gene is part of the cslA/glxA operon that contains genes encoding putative enzymes involved in glycan processing. Both these gene clusters are highly conserved in streptomycetes. In Chapter 2 the characterisation of GlxA is reported. It was found to be membrane associated with a mononuclear Cu site and possess a Cys-Tyr redox cofactor capable of housing a protein radical, comparable to the fungal galactose oxidase (Gox). The tertiary structure of GlxA revealed a unique domain arrangement, atypical spectroscopic properties compared to Gox and a lack of enzymatic activity with classical Gox substrates. Generation of the ΔglxA null mutant was found to stall aerial hyphae development on solid media and dramatically change the morphology in liquid cultures. This was ascribed to the absence of the oxidation of a glycan by GlxA produced by CslA (a cellulose-synthase), required for morphogenesis on solid and liquid cultures. The molecular nature of this glycan is unknown. A number of GlxA variants were created in Chapter 3 to elucidate the proteins unique spectroscopic properties. It was found that the second coordination sphere residue, Trp288, plays a major role in tuning the electronic properties of the buried Cu site in GlxA. Its removal abolishes the Cys-Tyr radical and perturbs the spectroscopic properties such that they resemble Gox. Monoclonal antibodies were used to follow the maturation of GlxA through observing mobility differences on denaturing PAGE gels based on the presence or absence of the Cys-Tyr cross-link. X-ray crystallography provided structural insight into the maturation process. A surprising outcome of Chapter 3 was that upon removal of the crosslinking Cys121, a new protein radical is formed as opposed to the expected abolition. Chapter 4 addresses another surprising finding in that a putative haem peroxidase (DtpA), part of the sco operon, plays a role in GlxA maturation and in the Cu-dependent morphological development. DtpA is shown through enzymology and structural analysis to be a member of the dye-decolourising peroxidase (DyP) family. Crucially, it is shown that DtpA functions as a peroxidase in the presence of GlxA using the GlxA substrate, glycolaldehyde. Synthesis and modification of the CslA/GlxA glycan will inevitably require degradation during the life cycle. As part of the cslA-glxA gene cluster are two genes encoding for putative polysaccharide degrading enzymes. One of these is a putative Cu lytic polysaccharide monooxygenase, SliLPMO10E. Chapter 5 structurally characterises SliLPMO10E and also investigates the kinetics of Cu-binding. The latter brings to the attention that LPMOs are able to bind Cu in two forms at a single site before relaxing into a final substrate active form. Importantly, SliLPMO10E is found to be active only with chitin via a C1 sugar ring oxidation mechanism. This hints at the possibility that the glycan produced by CslA and modified by GlxA is chitin-like possessing N-acetyl glucosamine moieties. By combining the in vitro results from this thesis together with the in vivo results obtained through the duration of this work from collaborators at Leiden University an overall model of the Cu-dependent morphogenesis and glycan processing in the hyphal tips of S. lividans is presented. Chapters 2 through to 5 focus on events that occur under Cu limitations, i.e. homeostasis. Chapter 6 extends on previous work that characterised the CsoR regulon. The Cu sensitive operon repressor (CsoR) protein determines the set point of Cu(I) concentration in the cytosol. Under Cu stress, Cu(I) binds to CsoR and de-represses genes under its transcriptional control. Chapter 6 explores the possibility of whether CopZ-like Cuchaperones can traffic Cu(I) to the DNA-bound CsoR, resulting in the up-regulation of control systems to return the cell to homeostasis. Size-exclusion and EMSA studies showed that Cu(I) was transferred from CopZ to CsoR in a unidirectional manner. Re-analysis of previous RNA-seq data using the S. lividans genome as input, enabled for a more complete model for the CsoR regulon in S. lividans to be proposed

Genomics, Computational Biology and Drug Discovery for Mycobacterial Infections: Fighting the Emergence of Resistance

Tuberculosis (TB) and leprosy are mycobacterial infections caused by Mycobacterium tuberculosis and Mycobacterium leprae respectively. These diseases continue to be endemic in developing countries where the cost of new medicines presents major challenges. The situation is further exacerbated by the emergence of resistance to many front-line antibiotics. A priority now is to design new antimycobacterials that are not only effective in combatting the diseases but are also less likely to give rise to resistance. In both these respects understanding the structure of drug targets in M. tuberculosis and M. leprae is crucial. In this review we describe structure-guided approaches to understanding the impacts of mutations that give rise to antimycobacterial resistance and the use of this information in the design of new medicines

Druggable binding sites in the multicomponent assemblies that characterise DNA double-strand-break repair through non-homologous end joining.

Non-homologous end joining (NHEJ) is one of the two principal damage repair pathways for DNA double-strand breaks in cells. In this review, we give a brief overview of the system including a discussion of the effects of deregulation of NHEJ components in carcinogenesis and resistance to cancer therapy. We then discuss the relevance of targeting NHEJ components pharmacologically as a potential cancer therapy and review previous approaches to orthosteric regulation of NHEJ factors. Given the limited success of previous investigations to develop inhibitors against individual components, we give a brief discussion of the recent advances in computational and structural biology that allow us to explore different targets, with a particular focus on modulating protein-protein interaction interfaces. We illustrate this discussion with three examples showcasing some current approaches to developing protein-protein interaction inhibitors to modulate the assembly of NHEJ multiprotein complexes in space and time

An Aromatic Dyad Motif in Dye Decolourising Peroxidases Has Implications for Free Radical Formation and Catalysis

Dye decolouring peroxidases (DyPs) are the most recent class of heme peroxidase to be discovered. On reacting with H2O2, DyPs form a high‐valent iron(IV)‐oxo species and a porphyrin radical (Compound I) followed by stepwise oxidation of an organic substrate. In the absence of substrate, the ferryl species decays to form transient protein‐bound radicals on redox active amino acids. Identification of radical sites in DyPs has implications for their oxidative mechanism with substrate. Using a DyP from Streptomyces lividans, referred to as DtpA, which displays low reactivity towards synthetic dyes, activation with H2O2 was explored. A Compound I EPR spectrum was detected, which in the absence of substrate decays to a protein‐bound radical EPR signal. Using a newly developed version of the Tyrosyl Radical Spectra Simulation Algorithm, the radical EPR signal was shown to arise from a pristine tyrosyl radical and not a mixed Trp/Tyr radical that has been widely reported in DyP members exhibiting high activity with synthetic dyes. The radical site was identified as Tyr374, with kinetic studies inferring that although Tyr374 is not on the electron‐transfer pathway from the dye RB19, its replacement with a Phe does severely compromise activity with other organic substrates. These findings hint at the possibility that alternative electron‐transfer pathways for substrate oxidation are operative within the DyP family. In this context, a role for a highly conserved aromatic dyad motif is discussed

Heterogeneity in the histidine-brace copper coordination sphere in auxiliary activity family 10 (AA10) lytic polysaccharide monooxygenases

Copper-dependent lytic polysaccharide monooxygenases (LPMOs) are enzymes that oxidatively deconstruct polysaccharides. The active site copper in LPMOs is coordinated by a histidine-brace. This utilizes the amino group and side chain of the N-terminal His residue with the side chain of a second His residue to create a T-shaped arrangement of nitrogen ligands. We report a structural, kinetic, and thermodynamic appraisal of copper binding to the histidine-brace in an auxiliary activity family 10 (AA10) LPMO from Streptomyces lividans (SliLPMO10E). Unexpectedly, we discovered the existence of two apo-SliLPMO10E species in solution that can each bind copper at a single site with distinct kinetic and thermodynamic (exothermic and endothermic) properties. The experimental EPR spectrum of copper-bound SliLPMO10E requires the simulation of two different line shapes, implying two different copper-bound species, indicative of three and two nitrogen ligands coordinating the copper. Amino group coordination was probed through the creation of an N-terminal extension variant (SliLPMO10E- Ext). The kinetics and thermodynamics of copper binding to SliLPMO10E-Ext are in accord with copper binding to one of the apo-forms in the wild-type protein, suggesting that amino group coordination is absent in the two-nitrogen coordinate form of SliLPMO10E. Copper binding to SliLPMO10B was also investigated, and again it revealed the presence of two apo-forms with kinetics and stoichiometry of copper binding identical to that of SliLPMO10E. Our findings highlight that heterogeneity exists in the active site copper coordination sphere of LPMOs that may have implications for the mechanism of loading copper in the cell

Structural insights into inhibitor regulation of the DNA repair protein DNA-PKcs.

The DNA-dependent protein kinase catalytic subunit (DNA-PKcs) has a central role in non-homologous end joining, one of the two main pathways that detect and repair DNA double-strand breaks (DSBs) in humans1,2. DNA-PKcs is of great importance in repairing pathological DSBs, making DNA-PKcs inhibitors attractive therapeutic agents for cancer in combination with DSB-inducing radiotherapy and chemotherapy3. Many of the selective inhibitors of DNA-PKcs that have been developed exhibit potential as treatment for various cancers4. Here we report cryo-electron microscopy (cryo-EM) structures of human DNA-PKcs natively purified from HeLa cell nuclear extracts, in complex with adenosine-5'-(γ-thio)-triphosphate (ATPγS) and four inhibitors (wortmannin, NU7441, AZD7648 and M3814), including drug candidates undergoing clinical trials. The structures reveal molecular details of ATP binding at the active site before catalysis and provide insights into the modes of action and specificities of the competitive inhibitors. Of note, binding of the ligands causes movement of the PIKK regulatory domain (PRD), revealing a connection between the p-loop and PRD conformations. Electrophoretic mobility shift assay and cryo-EM studies on the DNA-dependent protein kinase holoenzyme further show that ligand binding does not have a negative allosteric or inhibitory effect on assembly of the holoenzyme complex and that inhibitors function through direct competition with ATP. Overall, the structures described in this study should greatly assist future efforts in rational drug design targeting DNA-PKcs, demonstrating the potential of cryo-EM in structure-guided drug development for large and challenging targets

A subtle structural change in the distal haem pocket has a remarkable effect on tuning hydrogen peroxide reactivity in dye decolourising peroxidases from Streptomyces lividans

Dye decolourising peroxidases (DyPs) are oxidative haem containing enzymes that can oxidise organic substrates by first reacting with hydrogen peroxide. Herein, we have focused on two DyP homologs, DtpAa and DtpA, from the soil-dwelling bacterium Streptomyces lividans. By using X-ray crystallography, stopped-flow kinetics, deuterium kinetic isotope studies and EPR spectroscopy, we show that both DyPs react with peroxide to form Compound I (a FeIV=O species and a porphyrin π-cation radical), via a common mechanism, but the reactivity and rate limits that define the mechanism are markedly different between the two homologs (DtpA forms Compound I rapidly, no kinetic isotope effect; DtpAa 100-fold slower Compound I formation and a distinct kinetic isotope effect). By determining the validated ferric X-ray structure of DtpAa and comparing it with the ferric DtpA structure, we attribute the kinetic differences to a subtle structural repositioning of the distal haem pocket Asp side chain. Through site-directed mutagenesis we show the acid-base catalyst responsible for proton-transfer to form Compound I comprises a combination of a water molecule and the distal Asp. Compound I formation in the wild-type enzymes as well as their distal Asp variants is pH dependent, sharing a common ionisation equilibrium with an apparent pKa of ~ 4.5-5.0. We attribute this pKa to the deprotonation/protonation of the haem bound H₂O₂. Our studies therefore reveal a mechanism for Compound I formation in which the rate limit may be shifted from peroxide binding to proton-transfer controlled by the distal Asp position and the associated hydrogen-bonded water molecules

Active site maturation and activity of the copper-radical oxidase GlxA is governed by a tryptophan residue

GlxA from Streptomyces lividans is a mononuclear copper-radical oxidase and a member of the auxiliary activity family 5 (AA5). Its domain organisation and low sequence homology make it a distinct member of the AA5 family in which the fungal galactose 6-oxidase (Gox) is the best-characterized. GlxA is a key cuproenzyme in the copper-dependent morphological development of S. lividans with a function that is linked to the processing of an extracytoplasmic glycan. The catalytic site in GlxA and Gox contain two distinct one-electron acceptors comprising the copper ion and a 3'-(S-cysteinyl) tyrosine. The latter is formed post-translationally through a covalent bond between a cysteine and a copper coordinating tyrosine ligand and houses a radical. In GlxA and Gox a second coordination sphere tryptophan residue (Trp288 in GlxA) is present, but the orientation of the indole ring differs between the two enzymes creating a marked difference in the ?-? stacking interaction of the benzyl ring with the 3'-(S-cysteinyl) tyrosine. Differences in the spectroscopic and enzymatic activity have been reported between GlxA and Gox with the indole orientation suggested as a reason. Here we report a series of in vivo and in vitro studies using the W288F and W288A variants of GlxA to assess the role of Trp288 on the morphology, maturation, spectroscopic and enzymatic properties. Our findings point towards a salient role for Trp288 in the kinetics of copper loading and maturation of GlxA, with its presence essential for stabilising the metalloradical site required for coupling catalytic activity and morphological development

A cytosolic copper storage protein provides a second level of copper tolerance in Streptomyces lividans.

Streptomyces lividans has a distinct dependence on the bioavailability of copper for its morphological development. A cytosolic copper resistance system is operative in S. lividans that serves to preclude deleterious copper levels. This system comprises of several CopZ-like copper chaperones and P1-type ATPases, predominantly under the transcriptional control of a metalloregulator from the copper sensitive operon repressor (CsoR) family. In the present study, we discover a new layer of cytosolic copper resistance in S. lividans that involves a protein belonging to the newly discovered family of copper storage proteins, which we have named Ccsp (cytosolic copper storage protein). From an evolutionary perspective, we find Ccsp homologues to be widespread in Bacteria and extend through into Archaea and Eukaryota. Under copper stress Ccsp is upregulated and consists of a homotetramer assembly capable of binding up to 80 cuprous ions (20 per protomer). X-ray crystallography reveals 18 cysteines, 3 histidines and 1 aspartate are involved in cuprous ion coordination. Loading of cuprous ions to Ccsp is a cooperative process with a Hill coefficient of 1.9 and a CopZ-like copper chaperone can transfer copper to Ccsp. A Δccsp mutant strain indicates that Ccsp is not required under initial copper stress in S. lividans, but as the CsoR/CopZ/ATPase efflux system becomes saturated, Ccsp facilitates a second level of copper tolerance

SAP domain forms a flexible part of DNA aperture in Ku70/80.

Funder: Victorian GovernmentFunder: BBSRCNonhomologous end joining (NHEJ) is a DNA repair mechanism that religates double-strand DNA breaks to maintain genomic integrity during the entire cell cycle. The Ku70/80 complex recognizes DNA breaks and serves as an essential hub for recruitment of NHEJ components. Here, we describe intramolecular interactions of the Ku70 C-terminal domain, known as the SAP domain. Using single-particle cryo-electron microscopy, mass spectrometric analysis of intermolecular cross-linking and molecular modelling simulations, we captured variable positions of the SAP domain depending on DNA binding. The first position was localized at the DNA aperture in the Ku70/80 apo form but was not observed in the DNA-bound state. The second position, which was observed in both apo and DNA-bound states, was found below the DNA aperture, close to the helical arm of Ku70. The localization of the SAP domain in the DNA aperture suggests a function as a flexible entry gate for broken DNA. DATABASES: EM maps have been deposited in EMDB (EMD-11933). Coordinates have been deposited in Protein Data Bank (PDB 7AXZ). Other data are available from corresponding authors upon a request