Ping-Chiang Lyu

TRYPSIN-INDUCED PROTEOME ALTERATION DURING CELL SUBCULTURE IN MAMMALIAN CELLS

BackgroundIt is essential to subculture the cells once cultured cells reach confluence. For this, trypsin is frequently applied to dissociate adhesive cells from the substratum. However, due to the proteolytic activity of trypsin, cell surface proteins are often cleaved, which leads to dysregulation of the cell functions.MethodsIn this study, a triplicate 2D-DIGE strategy has been performed to monitor trypsin-induced proteome alterations. The differentially expressed spots were identified by MALDI-TOF MS and validated by immunoblotting.Results36 proteins are found to be differentially expressed in cells treated with trypsin, and proteins that are known to regulate cell metabolism, growth regulation, mitochondrial electron transportation and cell adhesion are down-regulated and proteins that regulate cell apoptosis are up-regulated after trypsin treatment. Further study shows that bcl-2 is down-regulated, p53 and p21 are both up-regulated after trypsinization.ConclusionsIn summary, this is the first report that uses the proteomic approach to thoroughly study trypsin-induced cell physiological changes and provides researchers in carrying out their experimental design.

Energetic contribution of solvent-exposed ion pairs to alpha-helix structure ☆

Understanding the role of amino acid side-chain interactions in forming secondary structure in proteins is useful for deciphering how proteins fold and for predicting folded structures of proteins from their sequence. Analysis of the secondary structure as a function of pH in two designed synthetic peptides with identical composition but different sequences, affords a quantitative estimate of the free energy contribution of a single ion pair to the stability of an isolated alpha-helix. One peptide contains repeated blocks of Glu4Lys4. The second has repeated blocks of Glu2Lys2. The former contains significant helical structure at neutral pH while the latter has none, based on ultraviolet light circular dichroism measurements and 1H nuclear magnetic resonance spectroscopy. The difference is attributed to formation of helix-stabilizing salt-bridges between Glu- and Lys+ spaced at i, i + 4 intervals in the former peptide. The free energy of formation of a single Glu(-)-Lys+ salt-bridge can be evaluated by using a statistical model of the helix-coil transition that explicitly includes salt-bridges: the result is -0.50(+/- 0.05) kcal/mol at 4 degrees C and neutral pH in 10 mM salt, in agreement with a value derived for a single salt-bridge in a helix on the surface of a globular protein.

Proteomics study of oxidative stress and Src kinase inhibition in H9C2 cardiomyocytes: a cell model of heart ischemia-reperfusion injury and treatment.

Protein phosphorylation plays a crucial role in the signal transduction pathways that regulate gene expression, metabolism, cell adhesion, and cell survival in response to oxidative stress. In this study, we have used hydrogen peroxide treatment of H9C2 rat cardiomyocytes as a model of oxidative stress in heart ischemia-reperfusion injury. We show that oxidative stress induces a robust tyrosine phosphorylation of multiple proteins in this cell type. A phosphoproteomics approach using anti-phosphotyrosine affinity purification and LC-MS/MS was then used to identify the protein targets of this stress-induced phosphorylation. Twenty-three tyrosine-phosphorylated proteins were identified, with the majority known to be associated with cell-cell junctions, the actin cytoskeleton, and cell adhesion. This suggested that oxidative stress may have a profound effect on intercellular connections and the cytoskeleton to affect cell adhesion, morphology, and survival. Importantly, Src kinase was shown to be a major upstream regulator of these events. Immunofluorescence studies, fluorescence-activated cell sorting, and cell-based assays were used to demonstrate oxidative stress-induced modification of cell adhesion structures and the cytoskeleton, induced de-adhesion, and increased apoptosis, which were reversed by treatment with the Src kinase inhibitor PP1. These data demonstrate the critical role of Src kinase in oxidative stress-induced phosphorylation and cell damage in cardiomyocytes and suggest that targeting this kinase may be an effective strategy for preventing ischemia-reperfusion injury in the heart.

DSAP: deep-sequencing small RNA analysis pipeline.

DSAP is an automated multiple-task web service designed to provide a total solution to analyzing deep-sequencing small RNA datasets generated by next-generation sequencing technology. DSAP uses a tab-delimited file as an input format, which holds the unique sequence reads (tags) and their corresponding number of copies generated by the Solexa sequencing platform. The input data will go through four analysis steps in DSAP: (i) cleanup: removal of adaptors and poly-A/T/C/G/N nucleotides; (ii) clustering: grouping of cleaned sequence tags into unique sequence clusters; (iii) non-coding RNA (ncRNA) matching: sequence homology mapping against a transcribed sequence library from the ncRNA database Rfam (http://rfam.sanger.ac.uk/); and (iv) known miRNA matching: detection of known miRNAs in miRBase (http://www.mirbase.org/) based on sequence homology. The expression levels corresponding to matched ncRNAs and miRNAs are summarized in multi-color clickable bar charts linked to external databases. DSAP is also capable of displaying miRNA expression levels from different jobs using a log2-scaled color matrix. Furthermore, a cross-species comparative function is also provided to show the distribution of identified miRNAs in different species as deposited in miRBase. DSAP is available at http://dsap.cgu.edu.tw.

Solution structure of plant nonspecific lipid transfer protein-2 from rice (Oryza sativa).

The three-dimensional structure of rice nonspecific lipid transfer protein (nsLTP2) has been solved for the first time. The structure of nsLTP2 was obtained using 813 distance constraints, 30 hydrogen bond constraints, and 19 dihedral angle constraints. Fifteen of the 50 random simulated annealing structures satisfied all of the constraints and possessed good nonbonded contacts. The novel three-dimensional fold of rice nsLTP2 contains a triangular hydrophobic cavity formed by three prominent helices. The four disulfide bonds required for stabilization of the nsLTP2 structure show a different pattern of cysteine pairing compared with nsLTP1. The C terminus of the protein is very flexible and forms a cap over the hydrophobic cavity. Molecular modeling studies suggested that the hydrophobic cavity could accommodate large molecules with rigid structures, such as sterols. The positively charged residues on the molecular surface of nsLTP2 are structurally similar to other plant defense proteins.

Solution structure of the plant defensin VrD1 from mung bean and its possible role in insecticidal activity against bruchids

Vigna radiata plant defensin 1 (VrD1) is the first reported plant defensin exhibiting insecticidal activity. We report herein the nuclear magnetic resonance solution structure of VrD1 and the implication on its insecticidal activity. The root‐mean‐square deviation values are 0.51 ± 0.35 and 1.23 ± 0.29 Å for backbone and all heavy atoms, respectively. The VrD1 structure comprises a triple‐stranded antiparallel β‐sheet, an α‐helix, and a 310 helix stabilized by four disulfide bonds, forming a typical cysteine‐stabilized αβ motif. Among plant defensins of known structure, VrD1 is the first to contain a 310 helix. Glu 26 is highly conserved among defensins; VrD1 contains an arginine at this position, which may induce a shift in the orientation of Trp10, thereby promoting the formation of this 310 helix. Moreover, VrD1 inhibits Tenebrio molitor α‐amylase. α‐Amylase has an essential role in the digestion of plant starch in the insect gut, and expression of the common bean α‐amylase inhibitor 1 in transgenic pea imparts complete resistance against bruchids. These results imply that VrD1 insecticidal activity has its basis in the inhibition of a polysaccharide hydrolase. Sequence and structural comparisons between two groups of plant defensins having different specificity toward insect α‐amylase reveal that the loop between β2 and β3 is the probable binding site for the α‐amylase. Computational docking experiments were used to study VrD1–α‐amylase interactions, and these results provide information that may be used to improve the insecticidal activity of VrD1. Proteins 2006.

Relationship between protein structures and disulfide-bonding patterns.

We found that that disulfide‐bonding patterns can be used to discriminate structure similarity. Our method, based on the hierarchical clustering scheme, is applicable to proteins with two or more disulfide bonds and is able to detect the structural similarities of proteins of low sequence identities (<25%). Our results show the surprisingly close relationship between disulfide‐bonding patterns and proteins structures. Our findings should be useful in protein structure modeling. Proteins 2003.

Relationship between local structural entropy and protein thermostability.

We developed a technique to compute structural entropy directly from protein sequences. We explored the possibility of using structural entropy to identify residues involved in thermal stabilization of various protein families. Examples include methanococcal adenylate kinase, Ribonuclease HI and holocytochrome c551. Our results show that the positions of the largest structural entropy differences between wild type and mutant usually coincide with the residues relevant to thermostability. We also observed a good linear relationship between the average structural entropy and the melting temperatures for adenylate kinase and its chimeric constructs. To validate this linear relationship, we compiled a large dataset comprised of 1153 sequences and found that most protein families still display similar linear relationships. Our results suggest that the multitude of interactions involved in thermal stabilization may be generalized into the tendency of proteins to maintain local structural conservation. The linear relationship between structural entropy and protein thermostability should be useful in the study of protein thermal stabilization. Proteins 2004.

Functional proteomic and structural insights into molecular targets related to the growth inhibitory effect of tanshinone IIA on HeLa cells.

Certain antitumor agents have recently been extracted from the roots of Salvia miltiorrhiza Bunge. The diterpene derivative, tanshinone IIA, possesses cytotoxic activity against several human carcinoma cell lines. It also inhibits invasion and metastasis of cancer cells. In the present study, we isolated tanshinone IIA from S. miltiorrhiza, and it exhibited strong growth inhibition against human cervical cancer cells in dose‐ and time‐dependent manners with a 50% cell growth inhibition value of 2.5 μg/mL (8.49 μM). Flow cytometric analysis of cell cycle progression revealed that G2/M arrest was initiated after a 24 h exposure to the drug. It also resulted in DNA fragmentation and degradation of poly (ADP‐ribose) polymerase indicating that tanshinone IIA may be a potential antitumor agent. Furthermore, we performed a comprehensive proteomic analysis to survey global protein changes induced by tanshinone IIA treatment on HeLa cells. Significant changes in the levels of cytoskeleton proteins as well as stress‐associated proteins were observed. Immunoblot analysis and immunofluorescence staining were used to confirm the levels of protein expression. Overexpression of the vimentin rescued these tanshinone IIA‐induced events. Computational docking methods indicated that tanshinone IIA could stably bind to the β‐subunit of the microtubule protein. An interaction network analysis of these 12 proteins using MetaCore™ software suggested that tanshinone IIA treatment regulated the expressions of proteins involved in apoptotic processes, spindle assembly, and p53 activation, including vimentin, Maspin, α‐ and β‐tubulin, and GRP75. Taken together, our results suggest that tanshinone IIA strongly inhibited the growth of cervical cancer cells through interfering in the process of microtubule assembly, leading to G2/M phase arrest and sequent apoptosis. The success of this large‐scale effort was assessed by a bioinformatics analysis of proteins through predictions of protein domains and possible functional roles. The possible contributions of these proteins to the cytotoxicity of tanshinone IIA provide potential opportunities for the development of cancer therapeutics.

Construction and analysis of a plant non-specific lipid transfer protein database (nsLTPDB)

BackgroundPlant n on-s pecific l ipid t ransfer p roteins (nsLTPs) are small and basic proteins. Recently, nsLTPs have been reported involved in many physiological functions such as mediating phospholipid transfer, participating in plant defence activity against bacterial and fungal pathogens, and enhancing cell wall extension in tobacco. However, the lipid transfer mechanism of nsLTPs is still unclear, and comprehensive information of nsLTPs is difficult to obtain.MethodsIn this study, we identified 595 nsLTPs from 121 different species and constructed an nsLTPs database -- nsLTPDB -- which comprises the sequence information, structures, relevant literatures, and biological data of all plant nsLTPs http://nsltpdb.life.nthu.edu.tw/.ResultsMeanwhile, bioinformatics and statistics methods were implemented to develop a classification method for nsLTPs based on the patterns of the eight highly-conserved cysteine residues, and to suggest strict Prosite-styled patterns for Type I and Type II nsLTPs. The pattern of Type I is C X2 V X5-7 C [V, L, I] × Y [L, A, V] X8-13 CC × G X12 D × [Q, K, R] X2 CXC X16-21 P X2 C X13-15C, and that of Type II is C X4 L X2 C X9-11 P [S, T] X2 CC X5 Q X2-4 C[L, F]C X2 [A, L, I] × [D, N] P X10-12 [K, R] X4-5 C X3-4 P X0-2 C. Moreover, we referred the Prosite-styled patterns to the experimental mutagenesis data that previously established by our group, and found that the residues with higher conservation played an important role in the structural stability or lipid binding ability of nsLTPs.ConclusionsTaken together, this research has suggested potential residues that might be essential to modulate the structural and functional properties of plant nsLTPs. Finally, we proposed some biologically important sites of the nsLTPs, which are described by using a new Prosite-styled pattern that we defined.