Wenting Liao

Metabonomic Profiles Delineate the Effect of Traditional Chinese Medicine Sini Decoction on Myocardial Infarction in Rats

Background In spite of great advances in target-oriented Western medicine for treating myocardial infarction (MI), it is still a leading cause of death in a worldwide epidemic. In contrast to Western medicine, Traditional Chinese medicine (TCM) uses a holistic and synergistic approach to restore the balance of Yin-Yang of body energy so the bodys normal function can be restored. Sini decoction (SND) is a well-known formula of TCM which has been used to treat MI for many years. However, its holistic activity evaluation and mechanistic understanding are still lacking due to its complex components. Methodology/Principal Findings A urinary metabonomic method based on nuclear magnetic resonance and ultra high-performance liquid chromatography coupled to mass spectrometry was developed to characterize MI-related metabolic profiles and delineate the effect of SND on MI. With Elastic Net for classification and selection of biomarkers, nineteen potential biomarkers in rat urine were screened out, primarily related to myocardial energy metabolism, including the glycolysis, citrate cycle, amino acid metabolism, purine metabolism and pyrimidine metabolism. With the altered metabolism pathways as possible drug targets, we systematically analyze the therapeutic effect of SND, which demonstrated that SND administration could provide satisfactory effect on MI through partially regulating the perturbed myocardial energy metabolism. Conclusions/Significance Our results showed that metabonomic approach offers a useful tool to identify MI-related biomarkers and provides a new methodological cue for systematically dissecting the underlying efficacies and mechanisms of TCM in treating MI.

Potential Biomarkers in Mouse Myocardium of Doxorubicin-Induced Cardiomyopathy: A Metabonomic Method and Its Application

Background Doxorubicin (DOX) is one of the most potent antitumor agents available; however, its clinical use is limited because of the risk of severe cardiotoxicity. Though numerous studies have ascribed DOX cardiomyopathy to specific cellular pathways, the precise mechanism remains obscure. Sini decoction (SND) is a well-known formula of Traditional Chinese Medicine (TCM) and is considered as efficient agents against DOX-induced cardiomyopathy. However, its action mechanisms are not well known due to its complex components. Methodology/Principal Findings A tissue-targeted metabonomic method using gas chromatography–mass spectrometry was developed to characterize the metabolic profile of DOX-induced cardiomyopathy in mice. With Elastic Net for classification and selection of biomarkers, twenty-four metabolites corresponding to DOX-induced cardiomyopathy were screened out, primarily involving glycolysis, lipid metabolism, citrate cycle, and some amino acids metabolism. With these altered metabolic pathways as possible drug targets, we systematically analyzed the protective effect of TCM SND, which showed that SND administration could provide satisfactory effect on DOX-induced cardiomyopathy through partially regulating the perturbed metabolic pathways. Conclusions/Significance The results of the present study not only gave rise to a systematic view of the development of DOX-induced cardiomyopathy but also provided the theoretical basis to prevent or modify expected damage.

Evolutional selection of a combinatorial phage library displaying randomly-rearranged various single domains of immunoglobulin (Ig)-binding proteins (IBPs) with four kinds of Ig molecules

BackgroundProtein A, protein G and protein L are three well-defined immunoglobulin (Ig)-binding proteins (IBPs), which show affinity for specific sites on Ig of mammalian hosts. Although the precise functions of these molecules are not fully understood, it is thought that they play an important role in pathogenicity of bacteria. The single domains of protein A, protein G and protein L were all demonstrated to have function to bind to Ig. Whether combinations of Ig-binding domains of various IBPs could exhibit useful novel binding is interesting.ResultsWe used a combinatorial phage library which displayed randomly-rearranged various-peptide-linked molecules of D and A domains of protein A, designated PA(D) and PA(A) respectively, B2 domain of protein G (PG) and B3 domain of protein L (PL) for affinity selection with human IgG (hIgG), human IgM (hIgM), human IgA (hIgA) and recombinant hIgG1-Fc as bait respectively. Two kinds of novel combinatorial molecules with characteristic structure of PA(A)-PG and PA(A)-PL were obtained in hIgG (hIgG1-Fc) and hIgM (hIgA) post-selection populations respectively. In addition, the linking peptides among all PA(A)-PG and PA(A)-PL structures was strongly selected, and showed interestingly divergent and convergent distribution. The phage binding assays and competitive inhibition experiments demonstrated that PA(A)-PG and PA(A)-PL combinations possess comparable binding advantages with hIgG/hIgG1-Fc and hIgM/hIgA respectively.ConclusionIn this work, a combinatorial phage library displaying Ig-binding domains of protein A, protein G, or protein L joined by various random linking peptides was used to conducted evolutional selection in vitro with four kinds of Ig molecules. Two kinds of novel combinations of Ig-binding domains, PA(A)-PG and PA(A)-PL, were obtained, and demonstrate the novel Ig binding properties.

A simple, universal, efficient PCR-based gene synthesis method: Sequential OE-PCR gene synthesis ☆

Herein we present a simple, universal, efficient gene synthesis method based on sequential overlap extension polymerase chain reactions (OE-PCRs). This method involves four key steps: (i) the design of paired complementary 54-mer oligonucleotides with 18 bp overlaps, (ii) the utilisation of sequential OE-PCR to synthesise full-length genes, (iii) the cloning and sequencing of four positive T-clones of the synthesised genes and (iv) the resynthesis of target genes by OE-PCR with correct templates. Mispriming and secondary structure were found to be the principal obstacles preventing successful gene synthesis and were easily identified and solved in this method. Compensating for the disadvantages of being laborious and time-consuming, this method has many attractive advantages, such as the ability to guarantee successful gene synthesis in most cases and good allowance for Taq polymerase, oligonucleotides, PCR conditions and a high error rate. Thus, this method provides an alternative tool for individual gene synthesis without strict needs of the high-specialised experience.

HIV-1 Tat induces biochemical changes in the serum of mice

The HIV-1 Tat protein is released by infected cells and has numerous biological activities which might contribute either to the impairment of the immune response or to viral dissemination and pathogenesis. To date, the effects of Tat protein on metabolites remain unclear. In this study, a metabolomic study on serum of HIV-1 Tat-induced ICR mice was performed to research the pathologic mechanism of Tat protein by using gas chromatography coupled to mass spectrometry (GC/MS). Clear separations among the HIV-1 Tat-induced mice and the inaTat-induced or control mice were observed by principal component analysis and partial least-squares discriminant analysis based on the GC/MS spectral data. Additionally, 16 significantly changed metabolites in HIV-1 Tat-induced mice were identified that are involved in multiple perturbed metabolic pathways, which contributed to the elucidation of the complex pathogenic mechanism of Tat protein and may shed new lights on future improvement of HIV-1 therapy.

A designed Tat immunogen generates enhanced anti-Tat C-terminal antibodies

HIV-1 Tat has been identified as an attractive target for vaccine development and is currently under investigation in clinical trials as both a therapeutic and preventative vaccine for HIV-1. The Tat C-terminal region is of significant importance for its extracellular activity. In this study, we designed two recombinant Tat immunogens, Tat(B41-100N) and Tat(B41-100C), with two extended Tat C-terminal regions (41-100 aa) and compared their humoral immune response with native Tat. Interestingly, our results showed that Tat(B41-100C) elicited a higher antibody titer than Tat and Tat(B41-100N) in both mice and rabbits. The recombinant fusion protein-based epitope analysis showed that Tat(B41-100C) induced a remarkably enhanced humoral immune response against extended Tat C-terminal regions containing residues 38-100, 49-100 and 60-100. Our study demonstrates that the designed Tat(B41-100C) presents a designed immunogenicity that elicits enhanced Tat-specific antibodies especially against extended Tat C-terminal regions.

Phage-based molecular directed evolution yields multiple tandem human IgA affibodies with intramolecular binding avidity

Affibodies are a group of affinity proteins that are based on a 58-amino-acid residue protein domain derived from one of the IgG-binding domains of staphylococcal protein A. A single human IgA affibody with high IgA affinity has been generated by directed evolution. It remains interesting whether tandem IgA affibody proteins could increase binding capacity. Here, we report the generation of multiple tandem IgA affibodies by directed evolution using a combinatorial phage library displaying the IgA affibody A1 and/or A2 linked with three random amino acids. These affibodies exhibited markedly increased IgA binding capacity, as shown by enzyme linked immunosorbent assay, immunoblotting and surface plasmon resonance assays. We further showed that these tandem IgA affibodies displayed preferential binding to intact IgA molecules compared to individual IgA chain, suggesting intramolecular binding avidity. Our data demonstrates that artificial multiple tandem human IgA affibodies with relevant biological binding avidity were successfully yielded by phage-based molecular evolution. These results have broad implications for the design and development of binding proteins that target important biological molecules.