Monoclonal antibody Y01 prevents tauopathy progression induced by lysine 280-acetylated tau in cell and mouse models.

The spatiotemporal pattern of the spread of pathologically modified tau through brain regions in Alzheimer's disease (AD) can be explained by prion-like cell-to-cell seeding and propagation of misfolded tau aggregates. Hence, to develop targeted therapeutic antibodies, it is important to identify the seeding- and propagation-competent tau species. The hexapeptide 275VQIINK280 of tau is a critical region for tau aggregation, and K280 is acetylated in various tauopathies, including AD. However, the mechanism that links tau acetylated on lysine 280 (tau-acK280) to subsequent progression to neurodegenerative disease remains unclear. Here, we demonstrate that tau-acK280 is critical for tau propagation processes including secretion, aggregation, and seeding. We developed an antibody, Y01, that specifically targets tau-acK280 and solved the crystal structure of Y01 in complex with an acK280 peptide. The structure confirmed that Y01 directly recognizes acK280 and the surrounding residues. Strikingly, upon interaction with acetylated tau aggregates, Y01 prevented tauopathy progression and increased neuronal viability in neuron cultures and in tau-Tg mice through antibody-mediated neutralization and phagocytosis, respectively. Based on our observations that tau-acK280 is a core species involved in seeding and propagation activities, the Y01 antibody that specifically recognizes acK280 represents a promising therapeutic candidate for AD and other neurodegenerative diseases associated with tauopathy.

Structure-based functional analysis of a PadR transcription factor from Streptococcus pneumoniae and characteristic features in the PadR subfamily-2.

Since the first discovery of phenolic acid decarboxylase transcriptional regulator (PadR), its homologs have been identified mostly in bacterial species and constitute the PadR family. PadR family members commonly contain a winged helix-turn-helix (wHTH) motif and function as a transcription factor. However, the PadR family members are varied in terms of molecular size and structure. As a result, they are divided into PadR subfamily-1 and PadR subfamily-2. PadR subfamily-2 proteins have been reported in some pathogenic bacteria, including Listeria monocytogenes and Streptococcus pneumoniae, and implicated in drug resistance processes. Despite the growing numbers of known PadR family proteins and their critical functions in bacteria survival, biochemical and biophysical studies of the PadR subfamily-2 are limited. Here, we report the crystal structure of a PadR subfamily-2 member from Streptococcus pneumoniae (SpPadR) at a 2.40 Å resolution. SpPadR forms a dimer using its N-terminal and C-terminal helices. The two wHTH motifs of a SpPadR dimer expose their positively charged residues presumably to interact with DNA. Our structure-based mutational and biochemical study indicates that SpPadR specifically recognizes a palindromic nucleotide sequence upstream of its encoding region as a transcriptional regulator. Furthermore, comparative structural analysis of diverse PadR family members combined with a modeling study highlights the structural and regulatory features of SpPadR that are canonical to the PadR family or specific to the PadR subfamily-2.

Crystal structure of the Pseudomonas aeruginosa PA0423 protein and its functional implication in antibiotic sequestration.

Pseudomonas aeruginosa is a widely found opportunistic pathogen. The emergence of multidrug-resistant strains and persistent chronic infections have increased. The protein encoded by the pa0423 gene in P. aeruginosa is proposed to be critical for pathogenesis and could be a virulence-promoting protease or a bacterial lipocalin that binds a lipid-like antibiotic for drug resistance. Although two functions of proteolysis and antibiotic resistance are mutually related to bacterial survival in the host, it is very unusual for a single-domain protein to target unrelated ligand molecules such as protein substrates and lipid-like antibiotics. To clearly address the biological role of the PA0423 protein, we performed structural and biochemical studies. We found that PA0423 adopts a single-domain ß-barrel structure and belongs to the lipocalin family. The PA0423 structure houses an internal tubular cavity, which accommodates a ubiquinone-8 molecule. Furthermore, we reveal that PA0423 can directly interact with the polymyxin B antibiotic using the internal cavity, suggesting that PA0423 has a physiological function in the antibiotic resistance of P. aeruginosa.

Structure-based molecular characterization and regulatory mechanism of the LftR transcription factor from Listeria monocytogenes: Conformational flexibilities and a ligand-induced regulatory mechanism.

Listeria monocytogenes is a foodborne pathogen that causes listeriosis and can lead to serious clinical problems, such as sepsis and meningitis, in immunocompromised patients and neonates. Due to a growing number of antibiotic-resistant L. monocytogenes strains, listeriosis can steadily become refractory to antibiotic treatment. To develop novel therapeutics against listeriosis, the drug resistance mechanism of L. monocytogenes needs to be determined. The transcription factor LftR from L. monocytogenes regulates the expression of a putative multidrug resistance transporter, LieAB, and belongs to the PadR-2 subfamily of the PadR family. Despite the functional significance of LftR, our molecular understanding of the transcriptional regulatory mechanism for LftR and even for the PadR-2 subfamily is highly limited. Here, we report the crystal structure of LftR, which forms a dimer and protrudes two winged helix-turn-helix motifs for DNA recognition. Structure-based mutational and comparative analyses showed that LftR interacts with operator DNA through a LftR-specific mode as well as a common mechanism used by the PadR family. Moreover, the LftR dimer harbors one intersubunit cavity in the center of the dimeric structure as a putative ligand-binding site. Finally, conformational flexibilities in the LftR dimer and in the cavity suggest that a ligand-induced regulatory mechanism would be used by the LftR transcription factor.

Expression and regulation of inhibitor of DNA binding proteins ID1, ID2, ID3, and ID4 at the maternal-conceptus interface in pigs.

Inhibitor of DNA binding (ID) proteins, ID1, ID2, ID3, and ID4 are transcriptional regulators that have a helix-loop-helix (HLH) domain but not a basic DNA binding domain. ID proteins inhibit the functions of basic HLH transcription factors and regulate cell proliferation and differentiation. However, the expression and function of ID1, ID2, ID3, and ID4 at the maternal-conceptus interface are not fully understood in pigs. Therefore, we determined the expressions of ID1, ID2, ID3, and ID4 in porcine endometrium, conceptus, and chorioallantoic tissues. ID1, ID2, ID3, and ID4 mRNAs were expressed in the endometrium, with lower levels of ID1, ID2, and ID4 on Day 12 of pregnancy than during the estrous cycle. ID1, ID2, ID3, and ID4 mRNAs were also detected in conceptus and chorioallantoic tissues during pregnancy. ID2 protein was mainly localized to luminal epithelia and weakly to vascular smooth muscle cells in the endometrium and conceptus trophectoderm. Increasing doses of interleukin-1ß decreased levels of ID2 mRNA, while estradiol-17ß increased levels of ID3 mRNA in endometrial explants. The expressions of ID2 and ID4 mRNAs were higher in endometria from gilts with somatic cell nuclear transfer-derived conceptuses compared with endometria from gilts carrying conceptuses derived from natural mating on Day 12. These results indicate that the expressions of ID family genes are dynamically regulated at the maternal-conceptus interface, suggesting that ID proteins may play critical roles in the regulation of endometrial epithelial cell function and conceptus development to support the establishment and maintenance of pregnancy in pigs.

Recombinant Protein Expression, Crystallization, and Biophysical Studies of a Bacillus-conserved Nucleotide Pyrophosphorylase, BcMazG.

To overcome safety restrictions and regulations when studying genes and proteins from true pathogens, their homologues can be studied. Bacillus anthracis is an obligate pathogen that causes fatal inhalational anthrax. Bacillus cereus is considered a useful model for studying B. anthracis due to its close evolutionary relationship. The gene cluster ba1554 - ba1558 of B. anthracis is highly conserved with the bc1531- bc1535 cluster in B. cereus, as well as with the bt1364-bt1368 cluster in Bacillus thuringiensis, indicating the critical role of the associated genes in the Bacillus genus. This manuscript describes methods to prepare and characterize a protein product of the first gene (ba1554) from the gene cluster in B. anthracis using a recombinant protein of its ortholog in B. cereus, bc1531.

Crystal structure of the flagellar chaperone FliS from Bacillus cereus and an invariant proline critical for FliS dimerization and flagellin recognition.

FliS is a cytoplasmic flagellar chaperone for the flagellin, which polymerizes into filaments outside of the flagellated bacteria. Cytoplasmic interaction between FliS and flagellin is critical to retain the flagellin protein in a monomeric form, which is transported from the cytoplasm through the flagellar export apparatus to the extracellular space for filament assembly. Defects in the FliS protein directly diminish bacterial motility, pathogenicity, and viability. Although the overall structure of FliS is known, structural and mutational studies on FliS from other bacterial species are still required to reveal any unresolved biophysical features of FliS itself or functionally critical residues for flagellin recognition. Here, we present the crystal structure of FliS from Bacillus cereus (BcFliS) at 2.0 Å resolution. FliS possesses a highly dynamic N-terminal region, which is appended to the common four-helix bundle structure. An invariant proline residue (Pro17 in B. cereus FliS) was identified in all known FliS sequences between the N-terminal region and the four-helix bundle. The N-terminal proline residue functions as a helix breaker critical for FliS dimerization and flagellin recognition.

Structural and functional analysis of BF2549, a PadR-like transcription factor from Bacteroides fragilis.

A phenolic acid decarboxylase (padC) regulator, PadR and its homologs proteins belong to the PadR family. Despite the growing numbers of the PadR family members and their various roles in bacteria, such as detoxifications, drug transports and circadian rhythms, biochemical and biophysical studies of the PadR family are very limited. Thus, a ligand-induced regulatory mechanism of the PadR family transcription factors remains to be elucidated. Here, we report a crystal structure of a Bacteroides fragilis PadR-like protein, BF2549 and revealed its interaction with putative operator DNA and ligand molecules. Comparative structural and primary sequence analyses provide a PadR-specific motif that is conserved in the PadR family but deviated from the MarR family. Furthermore, putative ligand binding sites are observed in the BF2549 structure. Finally, a homology-based structure model of BF2549 and 29-mer dsDNA propose regulatory mechanisms of the PadR family in transcriptional derepression.

Crystal structure and catalytic mechanism of pyridoxal kinase from Pseudomonas aeruginosa.

Pyridoxal kinase is a ubiquitous enzyme essential for pyridoxal 5'-phosphate (PLP) homeostasis since PLP is required for the catalytic activity of a variety of PLP-dependent enzymes involved in amino acid, lipid, and sugar metabolism as well as neurotransmitter biosynthesis. Previously, two catalytic mechanisms were proposed with regard to Pdx kinases, in which either the aspartate or the cysteine residue is involved as a catalytic residue. Because the Pdx kinase of Pseudomonas aeruginosa (PaPdxK) contains both residues, the catalytic mechanism of PaPdxK remains elusive. To elucidate the substrate-recognition and catalytic mechanisms of PaPdxK, the crystal structure of PaPdxK was determined at a 2.0 Å resolution. The PaPdxK structure possesses a channel that can accommodate substrates and a metallic cofactor. Our structure-based biochemical and mutational analyses in combination with modeling studies suggest that PaPdxK catalysis is mediated by an acid-base mechanism through the catalytic acid Asp225 and a helical dipole moment.

Crystal structure of the Bacillus-conserved MazG protein, a nucleotide pyrophosphohydrolase.

BA1544 from Bacillus anthracis was previously annotated as a transcription factor for the gene cluster ba1554 - ba1558, but has not been experimentally characterized. B. anthracis is an obligate pathogen causing fatal inhalational anthrax, and BA1544 is absolutely conserved in Bacillus species, including Bacillus cereus, Bacillus thuringiensis and Bacillus mycoides, with 100% sequence identity. To address the function of BA1544, we performed structural and biochemical studies, which revealed that BA1544 is a MazG protein. Thus, herein, the protein is defined as Bacillus-conserved MazG (BcMazG). Like other MazG structures, BcMazG assembles into a tetrameric architecture. Each monomer adopts a four-α-helix bundle that accommodates a metal ion using four acidic residues, and presents one putative substrate-binding site. Enzymatic characterization demonstrated that BcMazG is a nucleoside triphosphate (NTP) pyrophosphohydrolase and prefers adenosine triphosphate as a substrate among canonical NTPs. Moreover, structural comparison of BcMazG with its homologues revealed a potential regulation mechanism whereby the enzymatic activity of BcMazG is regulated by its C-terminal region.

Purification, crystallization and X-ray crystallographic studies of a Bacillus cereus MepR-like transcription factor, BC0657.

Transcription factors of the MarR family respond to internal and external changes and regulate a variety of biological functions through ligand association with microorganisms. MepR belongs to the MarR family, and its mutations are associated with the development of multidrug resistance in Staphylococcus aureus, which has caused a growing health problem. In this study, a Bacillus cereus MepR-like transcription regulator, BC0657, was crystallized. The BC0657 crystals diffracted to 2.05 Å resolution and belonged to either space group P6(2)22 or P6(4)22, with unit-cell parameters a = 110.57, b = 110.57, c = 67.29 Å. There was one molecule per asymmetric unit. Future comparative structural studies on BC0657 would extend knowledge of ligand-induced transcriptional regulatory mechanisms in the MarR family and would make a significant contribution to the design of antibiotic drugs against multidrug-resistant bacteria.

Structure analysis of Bacillus cereus MepR-like transcription regulator, BC0657, in complex with pseudo-ligand molecules.

The MarR family of transcriptional regulatory proteins in bacteria and archaea respond to environmental changes and regulate transcriptional processes by ligand binding or cysteine oxidation. MepR belongs to the MarR family, and its mutations are associated with the development of multidrug resistances, causing a growing health problem. Therefore, it has been of great interest to locate the ligand binding site of MepR and reveal the ligand-mediated transcriptional regulation mechanism. Here, we report on the crystal structure of Bacillus cereus MepR-like transcription factor, BC0657, at 2.16 Å resolution. Interestingly, BC0657 was complexed with fortuitous pseudo-ligands, which were assessed to be lipid molecules containing a long fatty acid, rather than phenolic compounds previously observed in other MarR proteins. The BC0657-ligand interaction provides the first molecular view of how MepR recognizes ligands to respond to toxic chemicals. Moreover, our comparative structure analyses of ligand binding sites on BC0657 and its homologs suggest that transcriptional repression by MepR would be relieved by ligand-induced changes in dimerization organization.