Polyphenols from Chinese Herbal Medicine: Molecular Mechanisms and Therapeutic Targets in Pulmonary Fibrosis.

Pulmonary fibrosis (PF) is a highly confounding and fatal pathological process with finite treatment options. Multiple factors such as oxidative and immune/inflammation involve key pathological processes in chronic lung disease, and their intimate interactions mediate chronic lung damage, denudation of the alveolar epithelium, hyperproliferation of type II alveolar epithelial cells (AECIIs), proliferation and differentiation of fibroblasts, and the permeability of microvessels. We reviewed the classic mechanism of PF and highlighted a few emerging mechanisms for studying complex networks in lung disease pathology. Polyphenols, as a multi-target drug, has excellent potential in the treatment of pulmonary fibrosis. We then reviewed recent advances in discovering phenolic compounds from fruits, tea, and medical herbs with the bioactivities of simultaneously regulating multiple factors (e.g., oxidative stress, inflammation, autophagy, apoptosis, pyroptosis) for minimizing pulmonary fibrosis injury. These compounds include resveratrol, curcumin, salvianolic acid B, epigallocatechin-3-gallate, gallic acid, corilagin. Each phenolic compound can exert its anti-PF effect through various mechanisms, and the signaling pathways involved in different phenolic compounds are not the same. This review summarized the available evidence on phenolic compounds' effectiveness in pulmonary diseases and explored the molecular mechanisms and therapeutic targets of phenolic compounds from Chinese herbal medicine with the properties of inhibition of ongoing fibrogenesis and resolution of existing fibrosis.

New biomarkers of Kawasaki disease identified by urine proteomic analysis.

Kawasaki disease (KD) is an acute systemic vasculitis that mainly afflicts infants and young children. The symptoms of KD are similar to those of various febrile diseases. Here, we attempted to develop accurate diagnostic biomarkers of KD by performing urine proteomic analysis of samples from healthy controls, patients with KD, and patients with another febrile disease, pneumonia (two patients). We identified differentially expressed proteins (DEPs) in KD as compared to normal controls. We also constructed functional annotation and protein-protein interaction (PPI) networks of DEPs in KD and pneumonia. DEPs common to both KD and pneumonia were identified, as well as DEPs specific to KD. Compared to normal control, 43 and 62 DEPs were identified in KD and pneumonia, respectively. Serine hydroxymethyltransferase 1 is a hub protein of the KD-specific PPI network. Thirteen DEPs common to both KD and pneumonia and 30 DEPs specific to KD were identified. Of these, the expression of eight DEPs could cluster normal and pneumonia samples into one group and cluster KD samples into another group based on hierarchical clustering. Our study identified several DEPs that may play a role in KD and that may serve as diagnostic biomarkers to distinguish patients with KD from both normal control and other febrile diseases.

Genome-wide mRNA processing in methanogenic archaea reveals post-transcriptional regulation of ribosomal protein synthesis.

Unlike stable RNAs that require processing for maturation, prokaryotic cellular mRNAs generally follow an 'all-or-none' pattern. Herein, we used a 5΄ monophosphate transcript sequencing (5΄P-seq) that specifically captured the 5΄-end of processed transcripts and mapped the genome-wide RNA processing sites (PSSs) in a methanogenic archaeon. Following statistical analysis and stringent filtration, we identified 1429 PSSs, among which 23.5% and 5.4% were located in 5΄ untranslated region (uPSS) and intergenic region (iPSS), respectively. A predominant uridine downstream PSSs served as a processing signature. Remarkably, 5΄P-seq detected overrepresented uPSS and iPSS in the polycistronic operons encoding ribosomal proteins, and the majority upstream and proximal ribosome binding sites, suggesting a regulatory role of processing on translation initiation. The processed transcripts showed increased stability and translation efficiency. Particularly, processing within the tricistronic transcript of rplA-rplJ-rplL enhanced the translation of rplL, which can provide a driving force for the 1:4 stoichiometry of L10 to L12 in the ribosome. Growth-associated mRNA processing intensities were also correlated with the cellular ribosomal protein levels, thereby suggesting that mRNA processing is involved in tuning growth-dependent ribosome synthesis. In conclusion, our findings suggest that mRNA processing-mediated post-transcriptional regulation is a potential mechanism of ribosomal protein synthesis and stoichiometry.

The Thioredoxin GbNRX1 Plays a Crucial Role in Homeostasis of Apoplastic Reactive Oxygen Species in Response to Verticillium dahliae Infection in Cotton.

Examining the proteins that plants secrete into the apoplast in response to pathogen attack provides crucial information for understanding the molecular mechanisms underlying plant innate immunity. In this study, we analyzed the changes in the root apoplast secretome of the Verticillium wilt-resistant island cotton cv Hai 7124 (Gossypium barbadense) upon infection with Verticillium dahliae Two-dimensional differential gel electrophoresis and matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry analysis identified 68 significantly altered spots, corresponding to 49 different proteins. Gene ontology annotation indicated that most of these proteins function in reactive oxygen species (ROS) metabolism and defense response. Of the ROS-related proteins identified, we further characterized a thioredoxin, GbNRX1, which increased in abundance in response to V. dahliae challenge, finding that GbNRX1 functions in apoplastic ROS scavenging after the ROS burst that occurs upon recognition of V. dahliae Silencing of GbNRX1 resulted in defective dissipation of apoplastic ROS, which led to higher ROS accumulation in protoplasts. As a result, the GbNRX1-silenced plants showed reduced wilt resistance, indicating that the initial defense response in the root apoplast requires the antioxidant activity of GbNRX1. Together, our results demonstrate that apoplastic ROS generation and scavenging occur in tandem in response to pathogen attack; also, the rapid balancing of redox to maintain homeostasis after the ROS burst, which involves GbNRX1, is critical for the apoplastic immune response.

Proteomic insights into the temperature responses of a cold-adaptive archaeon Methanolobus psychrophilus R15.

Cold-adaptive methanogens contribute significantly to methane emission from the cold area, while the cold-adaptive mechanisms used by Archaea remain elusive. Methanolobus psychrophilus R15, a cold-adaptive methanogen isolated from a Tibetan plateau wetland, grows at 0-25 °C and optimally at 18 °C when isolated; however, it grows optimally at 30 °C after culturing at 18 °C for several years. Aiming to gain insights into the protein profiles that are involved in optimal growth and cold adaptation of this methanogen, here, we performed a comparative proteomic study using 2D DIGE on the cultures grown at 30, 18 and 4 °C. 1439 protein spots (3167 ORFs annotated in the R15 genome) were detected, and 202 of 322 differentially expressed protein spots were identified by MALDI-TOF/TOF. The protein abundance of most enzymes involved in methanogenesis, energy conservation and central metabolism were increased at 30 °C, while most ribosome proteins were decreased at 30 °C. Proteasome and ROS scavengers increased expressions at 4 °C, suggesting more aberrant proteins and ROS formed at lower temperatures. Different from the cold-adaptive Methanococcoides burtonii, some chaperones were increased at 4 °C, implying that protein folding was impaired at cold in this psychrophilic archaeon. This study indicates that diverse cold-adaptive mechanisms can be used by different methanogenic Archaea.

Proteome reference map of Haloarcula hispanica and comparative proteomic and transcriptomic analysis of polyhydroxyalkanoate biosynthesis under genetic and environmental perturbations.

Many haloarchaea are known as polyhydroxyalkanoates (PHAs) producers, but a global and integrated view of the PHA biosynthesis is still lacking in this group of archaea. In this study, a combined proteomic and transcriptomic approach was employed in Haloarcula hispanica, a model haloarchaeon that accumulates poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) under nutrient-limiting conditions with excess carbon source. First, a comprehensive proteome reference map was established for H. hispanica. A total of 936 spots representing 839 unique proteins (21.7% of the predicted proteome) were identified by MALDI-TOF/TOF PMF and MS/MS. The map was further utilized to reconstruct central metabolic pathways to facilitate functional genomic analysis in H. hispanica. The results from the proteomic and transcriptomic analysis indicated that active PHA production coordinated with the TCA cycle to maintain balanced growth in wild-type H. hispanica, which was grown in nutrient-limited medium (PHA-accumulating conditions) versus nutrient-rich medium (non-PHA-accumulating conditions). Under nutrient-limiting conditions with excess carbon source, the PHA biosynthetic genes including phaEC, phaB, and phaP were upregulated at the transcriptional level, whereas the TCA cycle and respiratory chain were downregulated. Thus, acetyl-CoA could be fed into the PHA biosynthetic pathway, leading to the accumulation of PHA granules in the cell. Simultaneously, the large amount of NADPH required during PHA accumulation was likely supplied by the C3 (pyruvate) and C4 (malate) pathway coupled with the urea cycle. When PHA biosynthesis was blocked, that is, in the PHA synthase mutant (ΔphaEC) versus wild type grown in nutrient-limited medium, the mutant might direct additional carbon and energy to the TCA cycle, but without obvious contribution to biomass accumulation. The combined approaches of proteomic and transcriptomic analysis were highly complementary, extending the physiological understanding of PHA biosynthesis and its regulation. This is the first integrated proteome and transcriptome investigation of PHA biosynthesis and regulation in haloarchaea. It has provided basic information for future systemic engineering of haloarchaea to meet industrial needs.

Induction of holomycin production and complex metabolic changes by the argR mutation in Streptomyces clavuligerus NP1.

In bacteria, arginine biosynthesis is tightly regulated by a universally conserved regulator, ArgR, which regulates the expression of arginine biosynthetic genes, as well as other important genes. Disruption of argR in Streptomyces clavuligerus NP1 resulted in complex phenotypic changes in growth and antibiotic production levels. To understand the metabolic changes underlying the phenotypes, comparative proteomic studies were carried out between NP1 and its argR disruption mutant (designated CZR). In CZR, enzymes involved in holomycin biosynthesis were overexpressed; this is consistent with its holomycin overproduction phenotype. The effects on clavulanic acid (CA) biosynthesis are more complex. Several proteins from the CA cluster were moderately overexpressed, whereas several proteins from the 5S clavam biosynthetic cluster and from the paralog cluster of CA and 5S clavam biosynthesis were severely downregulated. Obvious changes were also detected in primary metabolism, which are mainly reflected in the altered expression levels of proteins involved in acetyl-coenzyme A (CoA) and cysteine biosynthesis. Since acetyl-CoA and cysteine are precursors for holomycin synthesis, overexpression of these proteins is consistent with the holomycin overproduction phenotype. The complex interplay between primary and secondary metabolism and between secondary metabolic pathways were revealed by these analyses, and the insights will guide further efforts to improve production levels of CA and holomycin in S. clavuligerus.

Deletion of the topoisomerase III gene in the hyperthermophilic archaeon Sulfolobus islandicus results in slow growth and defects in cell cycle control.

Topoisomerase III (topo III), a type IA topoisomerase, is widespread in hyperthermophilic archaea. In order to interrogate the in vivo role of archaeal topo III, we constructed and characterized a topo III gene deletion mutant of Sulfolobus islandicus. The mutant was viable but grew more slowly than the wild-type strain, especially in a nutrient-poor medium. Flow cytometry analysis revealed changes of the mutant in growth cycle characteristics including an increase in proportion of cells containing either more than two genome equivalents or less than one genome equivalent in exponentially-growing cultures. As shown by fluorescence microscopy, a fraction of mutant cells in the cultures were drastically enlarged, and at least some of the enlarged cells were apparently capable of resuming cell division. The mutant also shows a different transcriptional profile from that of the wild-type strain. Our results suggest that the enzyme may serve roles in chromosomal segregation and control of the level of supercoiling in the cell.

Comparative proteomic analysis of an Aspergillus fumigatus mutant deficient in glucosidase I (AfCwh41).

Alpha-glucosidase I regulates trimming of the terminal alpha-1,2-glucose residue in the N-glycan processing pathway, which plays an important role in quality control systems in mammalian cells. Previously, we identified the gene encoding alpha-glucosidase I in the opportunistic human fungal pathogen Aspergillus fumigatus, namely Afcwh41. Deletion of the Afcwh41 gene results in a severe reduction of conidia formation, a temperature-sensitive deficiency of cell wall integrity, and abnormalities of polar growth and septation. An upregulation of the genes encoding Rho-type GTPases was also observed, which suggests activation of the cell wall integrity pathway in the mutant. Using 2D gel analysis, we revealed that the proteins involved in protein assembly, ubiquitin-mediated degradation and actin organization are altered in the DeltaAfcwh41 mutant. Evidence was obtained for a defect in the polarized localization of the actin cytoskeleton in the mutant. Our results suggest that blocking of the glucose trimming in A. fumigatus might induce accumulation of misfolded proteins in the endoplasmic reticulum; these misfolded proteins are probably required for cell wall synthesis and thus activate the cell wall integrity pathway, which then causes the abnormal polarity associated with the DeltaAfcwh41 mutant.

[Current status on proteomics of extremophilic microorganisms--a review].

We summarized the key handicap and troubleshooting when proteomic techniques were used to investigate extremophilic microorganisms, and the actual state of their proteomes research in recent years. Up to now, proteomics techniques keep developing and improving rapidly, but they has not been widely used to explore proteome of extremophilic microorganisms including halophiles, thermophiles, psychophiles, acidophiles and alkaliphiles due to specific problems including incomplete dissociation of protein-protein complexes of extremophiles, and a lot of proteins synthesized by extremophiles are resistant to the conditions which dissociated and denatured proteins synthesized by mesophilic organisms. However, the foreground of potential application of the techniques draws people on attempting zealously multifarious methods. At the present time, several technical problems for separating halophilic proteins, integral membrane proteins and predicting the function of new proteins have been solved availably. Proteomics data have validated some conclusions of genome predictions, and revealed many novel proteins and a few properties of extremophiles can not be resolved fully by genome data. The investigation of extremophiles proteomes indicated that a comprehensive view of protein expression profiles should rely on more than one proteomic method. In addition, the mutual verification of conclusions on the basis of genome and proteome and combination of these two techniques must accelerate the study of extremophilic microorganisms, and redound to uncover deeply and wholly the unique mechanisms of microorganisms adaptation to extreme environments. Moreover, it would clarify the mechanisms of their survival, and point out new direction of survey for improving damage result from stresses, finally contribute to human survival and healthy.

Cloning and characterization of the genes encoding a glycine betaine ABC-type transporter in Halobacillus trueperi DSM10404T.

By using Southern blot hybridization and inverse polymerase chain reaction, a 5.5-kb DNA fragment was obtained from the genomic DNA of Halobacillus trueperi DSM10404(T). Sequence analysis revealed that it contained a potential operon with high levels of sequence similarity to the opuA operon encoding glycine betaine transporter from Bacillus subtilis, which is a member of the ATP-binding cassette (ABC) substrate binding the protein-dependent transporter superfamily. The potential operon, designated as qatA (quaternary amine transporter), consists of three structural genes, which are predicted to encode an ATP-binding protein (QatAA), a membrane-associated protein (QatAB), and an extracellular substrate-binding protein (QatAC). Moreover, the putative promoter region of the operon was found with close homology to the sigma(A)-dependent promoter of B. subtilis. Reverse transcription (RT)-PCR analysis revealed that qatAA, qatAB, and qatAC genes were transcribed in cells of H. trueperi. Cells of Escherichia coli mutant MKH13 harboring qatA on pAY41 were able to grow on selective M9 salt medium containing glycine betaine and accumulated glycine betaine in the cytoplasm, showing that qatAA, qatAB, and qatAC genes together encode a functional glycine betaine transporter.

[Two-dimensional gel electrophoresis analysis of moderately halophilic bacterium Halobacillus dabanensis D-8T under hypoosmotic shock condition].

Halobacillus dabanensis D-8T was isolated from the saline deposits of Daban lake in Xinjiang of China, and is able to grow in complex medium containing 0.5% to 25% salt. To figure out the survival mechanisms of Gram-positive moderately halophilic bacteria under hypoosmotic shock conditions, two-dimensional gel electrophoresis (2-DE) was carried out to investigate differential protein expression profiles of H. dabanensis D-8T in response to low osmotic challenge. The 2-D gels were stored as dry gels and their images were taken by ImageScanner and analyzed by Imagemaster 2D Platinum software. About 650 protein spots were detected in 2-D gel. Most of proteins were distributed in molecular mass of 17.5 - 66kDa and the range of isoelectric point 4.0 - 5.9. A total of 34 protein spots were found to alter their expression after strain D-8T was subjected to hypoosmotic shock from 20% to 0% salinity for 5 min and 50 min. Among them, the expression of 20 protein spots is up-regulated including 6 new protein spots, while that of 14 protein spots is down-regulated in answer to sudden osmotic down-shift. Protein spots of interest were excised from the gels and digested by trypsin. By means of matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF/MS) and MASCOT search engine, 4 up-regulated protein spots were identified with peptide mass fingerprint, and are similar to heat shock protein DanK, rod shape-determining protein, penicillin-binding protein (PBP-1A) and 5-enolpyruvoylshikimate-3-phosphate synthase, respectively. Noticeably, PBP-1A firstly was up-regulated after shock of 5 min but disappeared after shock of 50 min. This indicated that the strain activate a minor mechanism of peptidoglycan synthesis to compensate the major synthesis mechanism for cells survival through a down-shift challenge. In addition, this paper was the first report that heat shock proteins were up-regulated in response to sudden osmotic down-shift.

[Construction of the genomic library of Halobacillus sp. D8 and isolation of the glycine betaine transporter betH gene].

Halobacillus sp. D8 is a sporing-forming, gram-positive moderately halophilic bacterium which could tolerate up to 25% (W/V) NaCl. A genomic library of Halobacillus sp. D8 was constructed using pUC18 as vector, and 9000 recombinant plasmids were obtained. By dot blot hybridization, colony PCR and DNA sequencing, the entire glycine betaine transporter betH gene was isolated from the constructed library. Inspection of the sequenced 4.3 kb DNA region revealed the presence of three ORFs. The putative ORF of betH is 1515bp long, encoding a 505-residue protein (BetH) with a calculated molecular mass of 56.1kD. Hydrophobicity plot analysis of BetH indicated a transmembrane protein containing 12 transmembrane regions. Homology searches for BetH of strain D8 in the GenBank using the BLAST program revealed significant sequence identities to other glycine betaine transporters: the putative glycine betaine transporter of O. iheyensis (64% identity), OpuD of B. subtilis (51% identity), BetH of H. trueperi (49% identity), BetL of L. monocytogenes (48% identity), BetM of M. halophilus (43% identity) and the putative glycine betaine transporter of B. halodurans (44% identity).

Cloning and characterization of the Halobacillus trueperi betH gene, encoding the transport system for the compatible solute glycine betaine.

Halobacillus trueperi accumulates glycine betaine under condition of high osmolarity. A fragment of the glycine betaine transporter betH gene was obtained from the genome of H. trueperi with degenerate primers. Through Southern blot hybridization and inverse PCR, a 5.1 kb EcoRI fragment containing the complete betH gene was identified and subsequently sequenced. The betH gene was predicted to encode a 55.2 kDa protein (504 amino acid residues) with 12 transmembrane regions. BetH showed 56% identity to the OpuD of Bacillus subtilis which belongs to the betaine/carnitine/choline transporter (BCCT) family. Its putative promoter region was highly homologous to sigmaB-dependent promoter of B. subtilis. A 2.6 kb fragment containing the betH gene was cloned into pUC18 and transformed into the Escherichia coli MKH13. The accumulation of glycine betaine in transformed E. coli MKH13 bacteria was confirmed using 13C nuclear magnetic resonance spectroscopy.