Changwen Jin

Chitin-Induced Dimerization Activates a Plant Immune Receptor

Dissecting Chitin Binding The chitin in fungal cells walls serves as a trigger to initiate plant defenses against pathogenic fungi. Arabidopsis detects these signals through a cell surface chitin receptor whose intracellular kinase domain initiates a signaling cascade in response to chitin that activates the plants response to infection. Liu et al. (p. 1160) have now solved the crystal structure of the Arabidopsis chitin receptor AtCERK1. The results show how chitin binds to the receptor and suggest that the biological response requires dimerisation of the receptor when it binds a chitin oligomer at least seven or eight subunits long. Structural analysis shows how fungus-derived chitin dimerizes its receptor on target plants and triggers defense responses. Pattern recognition receptors confer plant resistance to pathogen infection by recognizing the conserved pathogen-associated molecular patterns. The cell surface receptor chitin elicitor receptor kinase 1 of Arabidopsis (AtCERK1) directly binds chitin through its lysine motif (LysM)–containing ectodomain (AtCERK1-ECD) to activate immune responses. The crystal structure that we solved of an AtCERK1-ECD complexed with a chitin pentamer reveals that their interaction is primarily mediated by a LysM and three chitin residues. By acting as a bivalent ligand, a chitin octamer induces AtCERK1-ECD dimerization that is inhibited by shorter chitin oligomers. A mutation attenuating chitin-induced AtCERK1-ECD dimerization or formation of nonproductive AtCERK1 dimer by overexpression of AtCERK1-ECD compromises AtCERK1-mediated signaling in plant cells. Together, our data support the notion that chitin-induced AtCERK1 dimerization is critical for its activation.

The Binding Interface between an E2 (UBC9) and a Ubiquitin Homologue (UBL1)

Human UBC9 is a member of the E2 (ubiquitin conjugation enzyme) family of proteins. Instead of conjugating to ubiquitin, it conjugates with a ubiquitin homologue UBL1 (also known as SUMO-1, GMP1, SMTP3, PIC1, and sentrin). UBC9 has been shown to be involved in cell cycle regulation, DNA repair, and p53-dependent processes. The binding interfaces of the UBC9 and UBL1 complex have been determined by chemical shift perturbation using nuclear magnetic resonance spectroscopy. The binding site of UBL1 resides on the ubiquitin domain, and the binding site of UBC9 is located on a structurally conserved region of E2 . Because the UBC9-UBL1 system shares many similarities with the ubiquitin system in structures and in conjugation with each other and with target proteins, the observed binding interfaces may be conserved in E2-ubiquitin interactions in general.

Beclin 1-independent autophagy induced by a Bcl-XL/Bcl-2 targeting compound, Z18.

Inhibitors of Bcl-XL/Bcl-2 can induce autophagy by releasing the autophagic protein Beclin 1 from its complexes with these proteins. Here we report a novel compound targeting the BH3 binding groove of Bcl-XL/Bcl-2, Z18, which efficiently induces autophagy-associated cell death in HeLa cells, without apparent apoptosis. Unexpectedly, the inhibition of Beclin 1 and phosphatidylinositol 3-kinase have no obvious effect on Z18-induced autophagy in HeLa cells, implying that it is a non-canonical Beclin 1-independent autophagy. Meanwhile, the accumulation of autophagosomes is positively correlated with Z18-induced cell death and the full flux of autophagy is not necessary.

Solution NMR structure of the TatA component of the twin-arginine protein transport system from gram-positive bacterium Bacillus subtilis

The twin-arginine transport (Tat) system translocates folded proteins across the bacterial cytoplasmic or chloroplast thylakoid membrane of plants. The Tat system in most Gram-positive bacteria consists of two essential components, the TatA and TatC proteins. TatA is considered to be a bifunctional subunit, which can form a protein-conducting channel by self-oligomerization and can also participate in substrate recognition. However, the molecular mechanism underlying protein translocation remains elusive. Herein, we report the solution structure of the TatA(d) protein from Bacillus subtilis by NMR spectroscopy, the first structure of the Tat system at atomic resolution. TatA(d) shows an L-shaped structure formed by a transmembrane helix and an amphipathic helix, while the C-terminal tail is largely unstructured. Our results strongly support the postulated topology of TatA(d) in which the transmembrane helix is inserted into the lipid bilayer while the amphipathic helix lies at the membrane-water interface. Moreover, the structure of TatA(d) revealed the structural importance of several conserved residues at the hinge region, thus shedding new light on further elucidation of the protein transport mechanism of the Tat system.

Conformational fluctuations coupled to the thiol-disulfide transfer between thioredoxin and arsenate reductase in Bacillus subtilis.

Arsenic compounds commonly exist in nature and are toxic to nearly all kinds of life forms, which directed the evolution of enzymes in many organisms for arsenic detoxification. In bacteria, the thioredoxin-coupled arsenate reductase catalyzes the reduction of arsenate to arsenite by intramolecular thiol-disulfide cascade. The oxidized arsenate reductase ArsC is subsequently regenerated by thioredoxin through an intermolecular thiol-disulfide exchange process. The solution structure of the Bacillus subtilis thioredoxin-arsenate reductase complex represents the transiently formed intermediate during the intermolecular thiol-disulfide exchange reaction. A comparison of the complex structure with that of thioredoxin and arsenate reductase proteins in redox states showed substantial conformational changes coupled to the reaction process, with arsenate reductase, especially, adopting an “intermediate” conformation in the complex. Our current studies provide novel insights into understanding the reaction mechanisms of the thioredoxin-arsenate reductase pathway.

Solution Structure of a Low-Molecular-Weight Protein Tyrosine Phosphatase from Bacillus subtilis

The low-molecular-weight (LMW) protein tyrosine phosphatases (PTPs) exist ubiquitously in prokaryotes and eukaryotes and play important roles in cellular processes. We report here the solution structure of YwlE, an LMW PTP identified from the gram-positive bacteria Bacillus subtilis. YwlE consists of a twisted central four-stranded parallel beta-sheet with seven alpha-helices packing on both sides. Similar to LMW PTPs from other organisms, the conformation of the YwlE active site is favorable for phosphotyrosine binding, indicating that it may share a common catalytic mechanism in the hydrolysis of phosphate on tyrosine residue in proteins. Though the overall structure resembles that of the eukaryotic LMW PTPs, significant differences were observed around the active site. Residue Asp115 is likely interacting with residue Arg13 through electrostatic interaction or hydrogen bond interaction to stabilize the conformation of the active cavity, which may be a unique character of bacterial LMW PTPs. Residues in the loop region from Phe40 to Thr48 forming a wall of the active cavity are more flexible than those in other regions. Ala41 and Gly45 are located near the active cavity and form a noncharged surface around it. These unique properties demonstrate that this loop may be involved in interaction with specific substrates. In addition, the results from spin relaxation experiments elucidate further insights into the mobility of the active site. The solution structure in combination with the backbone dynamics provides insights into the mechanism of substrate specificity of bacterial LMW PTPs.

A novel Bcl-XL inhibitor Z36 that induces autophagic cell death in Hela cells

Inhibition of Bcl2 family proteins Bcl-XL and Bcl-2 represents a promising drug development strategy for cancer treatment by triggering apoptosis in cancer cells. Here we report a novel Bcl-XL inhibitor, Z36, which unexpectedly induces only autophagic cell death, but not apoptosis. This special property distinguishes Z36 from other previously reported Bcl-XL and Bcl-2 inhibitors that induce cancer cell death mainly through apoptosis, and makes Z36 an attractive molecular tool for studying the cellular regulation of autophagic cell death and apoptosis.

Heteronuclear nuclear magnetic resonance assignments, structure and dynamics of SUMO-1, a human ubiquitin-like protein.

The structure of a ubiquitin-like protein, small ubiquitin-related modifier-1 (SUMO-1), was earlier determined using homonuclear nuclear magnetic resonance (NMR) spectroscopy, since the spectral quality of the protein was not suitable for heteronuclear NMR data collection. In this study, a slightly different construct of the SUMO-1 gene was used for protein over-expression. The protein purified from this construct showed high spectral qualities, therefore, multi-dimensional heteronuclear NMR data for a dynamic study and structural determination were acquired. The structure of SUMO-1 obtained in this study differs in several respects from the structure obtained from homonuclear NMR data. Furthermore, structural differences were observed between the new SUMO-1 and ubiquitin structures. These differences may be important for SUMO-1-specific recognition in cells. Additionally, relaxation parameters indicate that SUMO-1 undergoes highly anisotropic tumbling in solution and that the long amino (N)-terminal sequence of SUMO-1 is highly dynamic with increasing flexibility towards the end.

The solution structure of Escherichia coli Wzb reveals a novel substrate recognition mechanism of prokaryotic low molecular weight protein-tyrosine phosphatases.

Low molecular weight protein-tyrosine phosphatases (LMW-PTPs) are small enzymes that ubiquitously exist in various organisms and play important roles in many biological processes. In Escherichia coli, the LMW-PTP Wzb dephosphorylates the autokinase Wzc, and the Wzc/Wzb pair regulates colanic acid production. However, the substrate recognition mechanism of Wzb is still poorly understood thus far. To elucidate the molecular basis of the catalytic mechanism, we have determined the solution structure of Wzb at high resolution by NMR spectroscopy. The Wzb structure highly resembles that of the typical LMW-PTP fold, suggesting that Wzb may adopt a similar catalytic mechanism with other LMW-PTPs. Nevertheless, in comparison with eukaryotic LMW-PTPs, the absence of an aromatic amino acid at the bottom of the active site significantly alters the molecular surface and implicates Wzb may adopt a novel substrate recognition mechanism. Furthermore, a structure-based multiple sequence alignment suggests that a class of the prokaryotic LMW-PTPs may share a similar substrate recognition mechanism with Wzb. The current studies provide the structural basis for rational drug design against the pathogenic bacteria.

Solution structure of the N-terminal catalytic domain of human H-REV107--a novel circular permutated NlpC/P60 domain

H‐REV107 is a Ca2+‐independent phospholipase A1/2, and it is also a pro‐apoptosis protein belonging to the novel class II tumor suppressor family, H‐REV107‐like family. Here we report the solution structure of the N‐terminal catalytic domain of human H‐REV107, which has a similar architecture to classical NlpC/P60 domains, even though their fold topologies are different due to circular permutation in the primary sequence. The phospholipase active site possesses a structurally conserved Cys–His–His catalytic triad as found in NlpC/P60 peptidases, indicating H‐REV107 should adopt a similar catalytic mechanism towards phospholipid substrates to that of NlpC/P60 peptidases towards peptides. As H‐REV107 is highly similar to lecithin retinol acyltransferase, our study also provides structural insight to this essential enzyme in retinol metabolism.