Bjørn Dalhus

DNA base repair – recognition and initiation of catalysis

Endogenous DNA damage induced by hydrolysis, reactive oxygen species and alkylation modifies DNA bases and the structure of the DNA duplex. Numerous mechanisms have evolved to protect cells from these deleterious effects. Base excision repair is the major pathway for removing base lesions. However, several mechanisms of direct base damage reversal, involving enzymes such as transferases, photolyases and oxidative demethylases, are specialized to remove certain types of photoproducts and alkylated bases. Mismatch excision repair corrects for misincorporation of bases by replicative DNA polymerases. The determination of the 3D structure and visualization of DNA repair proteins and their interactions with damaged DNA have considerably aided our understanding of the molecular basis for DNA base lesion repair and genome stability. Here, we review the structural biochemistry of base lesion recognition and initiation of one-step direct reversal (DR) of damage as well as the multistep pathways of base excision repair (BER), nucleotide incision repair (NIR) and mismatch repair (MMR).

Structure-based mutagenesis reveals the albumin-binding site of the neonatal Fc receptor

Albumin is the most abundant protein in blood where it has a pivotal role as a transporter of fatty acids and drugs. Like IgG, albumin has long serum half-life, protected from degradation by pH-dependent recycling mediated by interaction with the neonatal Fc receptor, FcRn. Although the FcRn interaction with IgG is well characterized at the atomic level, its interaction with albumin is not. Here we present structure-based modelling of the FcRn–albumin complex, supported by binding analysis of site-specific mutants, providing mechanistic evidence for the presence of pH-sensitive ionic networks at the interaction interface. These networks involve conserved histidines in both FcRn and albumin domain III. Histidines also contribute to intramolecular interactions that stabilize the otherwise flexible loops at both the interacting surfaces. Molecular details of the FcRn–albumin complex may guide the development of novel albumin variants with altered serum half-life as carriers of drugs.

Structural Basis for Thermophilic Protein Stability: Structures of Thermophilic and Mesophilic Malate Dehydrogenases

The three-dimensional structure of four malate dehydrogenases (MDH) from thermophilic and mesophilic phototropic bacteria have been determined by X-ray crystallography and the corresponding structures compared. In contrast to the dimeric quaternary structure of most MDHs, these MDHs are tetramers and are structurally related to tetrameric malate dehydrogenases from Archaea and to lactate dehydrogenases. The tetramers are dimers of dimers, where the structures of each subunit and the dimers are similar to the dimeric malate dehydrogenases. The difference in optimal growth temperature of the corresponding organisms is relatively small, ranging from 32 to 55 degrees C. Nevertheless, on the basis of the four crystal structures, a number of factors that are likely to contribute to the relative thermostability in the present series have been identified. It appears from the results obtained, that the difference in thermostability between MDH from the mesophilic Chlorobium vibrioforme on one hand and from the moderate thermophile Chlorobium tepidum on the other hand is mainly due to the presence of polar residues that form additional hydrogen bonds within each subunit. Furthermore, for the even more thermostable Chloroflexus aurantiacus MDH, the use of charged residues to form additional ionic interactions across the dimer-dimer interface is favored. This enzyme has a favorable intercalation of His-Trp as well as additional aromatic contacts at the monomer-monomer interface in each dimer. A structural alignment of tetrameric and dimeric prokaryotic MDHs reveal that structural elements that differ among dimeric and tetrameric MDHs are located in a few loop regions.

Characterization of the chitinolytic machinery of Enterococcus faecalis V583 and high-resolution structure of its oxidative CBM33 enzyme.

Little information exists for the ability of enterococci to utilize chitin as a carbon source. We show that Enterococcus faecalis V583 can grow on chitin, and we describe two proteins, a family 18 chitinase (ef0361; EfChi18A) and a family 33 CBM (carbohydrate binding module) (ef0362; EfCBM33A) that catalyze chitin conversion in vitro. Various types of enzyme activity assays showed that EfChi18A has functional properties characteristic of an endochitinase. EfCBM33A belongs to a recently discovered family of enzymes that cleave glycosidic bonds via an oxidative mechanism and that act synergistically with classical hydrolytic enzymes (i.e., chitinases). The structure and function of this protein were probed in detail. An ultra-high-resolution crystal structure of EfCBM33A revealed details of a conserved binding surface that is optimized to interact with chitin and contains the catalytic center. Chromatography and mass spectrometry analyses of product formation showed that EfCBM33A cleaves chitin via the oxidative mechanism previously described for CBP21 from Serratia marcescens. Metal-depletion studies showed that EfCBM33A is a copper enzyme. In the presence of an external electron donor, EfCBM33A boosted the activity of EfChi18A, and combining the two enzymes led to rapid and complete conversion of β-chitin to chitobiose. This study provides insight into the structure and function of the CBM33 family of enzymes, which, together with their fungal counterpart called GH61, currently receive considerable attention in the biomass processing field.

Synthesis of 1-substituted 7-cyano-2,3-diphenylindolizines and evaluation of antioxidant properties

Protocols for the synthesis of novel 1-substituted 7-cyano-2,3-diphenylindolizines from the corresponding indolizinol have been developed, and the compounds’ abilities to act as antioxidants, i.e. To inhibit lipid peroxidation in vitro, have been examined. 1-bromo-7-cyano-2,3-diphenylindolizine 9 readily participates in pd-catalysed coupling reactions with organotin, organozinc, and organoboron reagents. Similar treatment of the corresponding indolizinyl triflate 6, on the other hand, resulted only in partial cleavage of the triflate back to the indolizinol, except in reaction with 1-ethoxyethenyl(tributyl)tin. Here, the unexpected acetal (1-ethoxyethoxy)indolizine 10 was formed. The structure of 10 was determined by single-crystal x-ray diffraction methods at 150 k. An alternative strategy for the introduction of substituents at c-1 is by lithiation of the bromide 9 followed by reaction with electrophiles. The ability of the indolizine derivatives to inhibit lipid peroxidation in vitro was examined. Lipid peroxidation of boiled rat liver microsomes was induced by ascorbic acid/feso4 and peroxidation was determined by measuring the material reactive to thiobarbituric acid. In particular, the indolizinyl acetate 4 and the triflate 6 appear to be highly active antioxidants, with ic50 values below 1 µm in the bioassay.

A dominant STIM1 mutation causes Stormorken syndrome.

Stormorken syndrome is a rare autosomal‐dominant disease with mild bleeding tendency, thrombocytopathy, thrombocytopenia, mild anemia, asplenia, tubular aggregate myopathy, miosis, headache, and ichthyosis. A heterozygous missense mutation in STIM1 exon 7 (c.910C>T; p.Arg304Trp) (NM_003156.3) was found to segregate with the disease in six Stormorken syndrome patients in four families. Upon sensing Ca2+ depletion in the endoplasmic reticulum lumen, STIM1 undergoes a conformational change enabling it to interact with and open ORAI1, a Ca2+ release‐activated Ca2+ channel located in the plasma membrane. The STIM1 mutation found in Stormorken syndrome patients is located in the coiled‐coil 1 domain, which might play a role in keeping STIM1 inactive. In agreement with a possible gain‐of‐function mutation in STIM1, blood platelets from patients were in a preactivated state with high exposure of aminophospholipids on the outer surface of the plasma membrane. Resting Ca2+ levels were elevated in platelets from the patients compared with controls, and store‐operated Ca2+ entry was markedly attenuated, further supporting constitutive activity of STIM1 and ORAI1. Thus, our data are compatible with a near‐maximal activation of STIM1 in Stormorken syndrome patients. We conclude that the heterozygous mutation c.910C>T causes the complex phenotype that defines this syndrome.

Extending Serum Half-life of Albumin by Engineering Neonatal Fc Receptor (FcRn) Binding

Background: FcRn controls the long serum half-life of albumin. Results: A single amino acid substitution of albumin considerably improved binding to FcRn and extended serum half-life in mice and rhesus monkeys. Conclusion: Serum half-life of albumin may be tailored by engineering the FcRn-albumin interaction. Significance: This study reports on engineered albumin that may be attractive for improving the serum half-life of biopharmaceuticals. A major challenge for the therapeutic use of many peptides and proteins is their short circulatory half-life. Albumin has an extended serum half-life of 3 weeks because of its size and FcRn-mediated recycling that prevents intracellular degradation, properties shared with IgG antibodies. Engineering the strictly pH-dependent IgG-FcRn interaction is known to extend IgG half-life. However, this principle has not been extensively explored for albumin. We have engineered human albumin by introducing single point mutations in the C-terminal end that generated a panel of variants with greatly improved affinities for FcRn. One variant (K573P) with 12-fold improved affinity showed extended serum half-life in normal mice, mice transgenic for human FcRn, and cynomolgus monkeys. Importantly, favorable binding to FcRn was maintained when a single-chain fragment variable antibody was genetically fused to either the N- or the C-terminal end. The engineered albumin variants may be attractive for improving the serum half-life of biopharmaceuticals.

Structures of Endonuclease V with DNA Reveal Initiation of Deaminated Adenine Repair

Endonuclease V (EndoV) initiates a major base-repair pathway for nitrosative deamination resulting from endogenous processes and increased by oxidative stress from mitochondrial dysfunction or inflammatory responses. We solved the crystal structures of Thermotoga maritima EndoV in complex with a hypoxanthine lesion substrate and with product DNA. The PYIP wedge motif acts as a minor groove–damage sensor for helical distortions and base mismatches and separates DNA strands at the lesion. EndoV incises DNA with an unusual offset nick 1 nucleotide 3′ of the lesion, as the deaminated adenine is rotated ∼90° into a recognition pocket ∼8 Å from the catalytic site. Tight binding by the lesion-recognition pocket in addition to Mg2+ and hydrogen-bonding interactions to the DNA ends stabilize the product complex, suggesting an orderly recruitment of downstream proteins in this base-repair pathway.

Crystal structure and enzymatic properties of a bacterial family 19 chitinase reveal differences from plant enzymes

We describe the cloning, overexpression, purification, characterization and crystal structure of chitinase G, a single‐domain family 19 chitinase from the Gram‐positive bacterium Streptomyces coelicolor A3(2). Although chitinase G was not capable of releasing 4‐methylumbelliferyl from artificial chitooligosaccharide substrates, it was capable of degrading longer chitooligosaccharides at rates similar to those observed for other chitinases. The enzyme was also capable of degrading a colored colloidal chitin substrate (carboxymethyl‐chitin–remazol–brilliant violet) and a small, presumably amorphous, subfraction of α‐chitin and β‐chitin, but was not capable of degrading crystalline chitin completely. The crystal structures of chitinase G and a related Streptomyces chitinase, chitinase C [Kezuka Y, Ohishi M, Itoh Y, Watanabe J, Mitsutomi M, Watanabe T & Nonaka T (2006) J Mol Biol358, 472–484], showed that these bacterial family 19 chitinases lack several loops that extend the substrate‐binding grooves in family 19 chitinases from plants. In accordance with these structural features, detailed analysis of the degradation of chitooligosaccharides by chitinase G showed that the enzyme has only four subsites (− 2 to + 2), as opposed to six (− 3 to + 3) for plant enzymes. The most prominent structural difference leading to reduced size of the substrate‐binding groove is the deletion of a 13‐residue loop between the two putatively catalytic glutamates. The importance of these two residues for catalysis was confirmed by a site‐directed mutagenesis study.

Hallmarks of processivity in glycoside hydrolases from crystallographic and computational studies of the Serratia marcescens chitinases

Background: Nature employs processive and nonprocessive glycoside hydrolases to degrade polysaccharides. Results: We solved the Serratia marcescens nonprocessive chitinase (ChiC2) structure and used simulation to identify dynamic hallmarks of processivity in S. marcescens chitinases. Conclusion: Dynamic metrics complement structural insights in determining processivity. Significance: Identification of hallmarks of processivity is a key step toward development of a general, molecular-level theory of glycoside hydrolase processivity. Degradation of recalcitrant polysaccharides in nature is typically accomplished by mixtures of processive and nonprocessive glycoside hydrolases (GHs), which exhibit synergistic activity wherein nonprocessive enzymes provide new sites for productive attachment of processive enzymes. GH processivity is typically attributed to active site geometry, but previous work has demonstrated that processivity can be tuned by point mutations or removal of single loops. To gain additional insights into the differences between processive and nonprocessive enzymes that give rise to their synergistic activities, this study reports the crystal structure of the catalytic domain of the GH family 18 nonprocessive endochitinase, ChiC, from Serratia marcescens. This completes the structural characterization of the co-evolved chitinolytic enzymes from this bacterium and enables structural analysis of their complementary functions. The ChiC catalytic module reveals a shallow substrate-binding cleft that lacks aromatic residues vital for processivity, a calcium-binding site not previously seen in GH18 chitinases, and, importantly, a displaced catalytic acid (Glu-141), suggesting flexibility in the catalytic center. Molecular dynamics simulations of two processive chitinases (ChiA and ChiB), the ChiC catalytic module, and an endochitinase from Lactococcus lactis show that the nonprocessive enzymes have more flexible catalytic machineries and that their bound ligands are more solvated and flexible. These three features, which relate to the more dynamic on-off ligand binding processes associated with nonprocessive action, correlate to experimentally measured differences in processivity of the S. marcescens chitinases. These newly defined hallmarks thus appear to be key dynamic metrics in determining processivity in GH enzymes complementing structural insights.