Your search keyword '"Tong eZhang"' showing total 6 results

1. Comparative analysis of genomics and proteomics in the new isolated Bacillus thuringiensis X022 revealed the metabolic regulation mechanism of carbon flux following Cu2+ treatment

Author

Meifang eQuan, Junyan eXie, Jie eRang, Xuemei eLiu, Tong eZhang, Fengjuan eZhou, Liqiu eXia, Shengbiao eHu, Yunjun eSun, and Xuezhi eDing

Subjects

Bacillus thuringiensis, Proteomics, annotation, Genome sequencing, comparative analysis, poly-β-hydroxybutyrate, Microbiology, QR1-502

Abstract

Bacillus thuringiensis (Bt) X022, which showed strong insecticidal activity against several Lepidopteran pests, is a novel strain isolated from soil in China. In this work, we performed whole genome sequencing of this Bt strain using the next-generation sequencing technology, and further conducted a comparative analysis with the proteomics data of the specific spore-release period based on LC-MS/MS approach. The Bt X022 genome consisted of one circular chromosomal DNA and seven plasmids, which were further functionally annotated using the RAST server. Comparative analysis of insecticidal substances showed that X022 contained genes coding for three Cry proteins (Cry1Ac, Cry1Ia and Cry2Ab) and a vegetative insecticidal protein (Vip3A). However, three insecticidal crystal proteins (ICPs) (Cry1Ca, Cry1Ac and Cry1Da) were detected by proteomics in the spore-release period. Moreover, a putative biosynthetic gene cluster and the metabolic pathway for poly-β-hydroxybutyrate in Bt X022 were deduced based on the comparative analysis of genomic and proteomic data, which revealed the metabolic regulation mechanism of carbon flux correlated with increased production of ICPs caused by Cu2+ . Hence, these results provided a deeper understanding of the genetic background and protein expression profile of Bt X022. This study established a foundation for directed genetic modification and further application of this new isolated Bt strain.

Published

2016

2. Protein phosphorylation and redox modification in stomatal guard cells

Author

Kelly eBalmant, Tong eZhang, and Sixue eChen

Subjects

Phosphorylation, signaling, redox, guard cell, abiotic and biotic stresses, Physiology, QP1-981

Abstract

Post-translational modification (PTM) is recognized as a major process accounting for protein structural variation, functional diversity, and the dynamics and complexity of the proteome. Since PTMs can change the structure and function of proteins, they are essential to coordinate signaling networks and to regulate important physiological processes in eukaryotes. Plants are constantly challenged by both biotic and abiotic stresses that reduce productivity, causing economic losses in crops. The plant responses involve complex physiological, cellular, and molecular processes, with stomatal movement as one of the earliest responses. In order to activate such a rapid response, stomatal guard cells employ cellular PTMs of key protein players in the signaling pathways to regulate the opening and closure of the stomatal pores. Here we discuss two major types of PTMs, protein phosphorylation and redox modification that play essential roles in stomatal movement under stress conditions. We present an overview of PTMs that occur in stomatal guard cells, especially the methods and technologies, and their applications in PTM identification and quantification. Our focus is on PTMs that modify molecular components in guard cell signaling at the stages of signal perception, second messenger production, as well as downstream signaling events and output. Improved understanding of guard cell signaling will enable generation of crops with enhanced stress tolerance, and increased yield and bioenergy through biotechnology and molecular breeding.

Published

2016

3. Back to the future of soil metagenomics

Author

Joseph eNesme, Wafa eAchouak, Spiros eAgathos, Mark eBailey, Petr eBaldrian, Dominique eBrunel, Asa eFrostegard, Thierry eHeulin, Janet K. Jansson, Edouard eJurkevitch, George A. Kowalchuk, Kristiina Leena Kruus, Antonio eLagares, Hilary M. Lapin-Scott, Denis eLe Paslier, Ines eMandic-Mulec, Colin eMurrell, David D. Myrold, Renaud eNalin, Paolo eNannipieri, Josh David Neufeld, Fergal eO'Gara, John Jacob eParnell, Alfred ePühler, Victor ePylro, Juan Luis eRamos, Luiz eRoesch, Christa eSchleper, Michael eSchloter, Alexander eSczyrba, Angela eSessitsch, Sara eSjöling, Jan eSørensen, Søren J Sørensen, Christoph C. Tebbe, Ed eTopp, George eTsiamis, Jan Dirk eVan Elsas, Geertje eVan Keulen, Michael eWagner, Franco eWidmer, Tong eZhang, Xiaojun eZhang, Liping eZhao, Yong-Guan eZhu, Timothy M. Vogel, and Pascal eSimonet

Subjects

Soil Microbiology, microbial ecology, soil ecology, terrestrial microbiology, Metagenomic, Microbiology, QR1-502

Published

2016

4. Exploring Antibiotic Resistance Genes and Metal Resistance Genes in Plasmid Metagenomes from Wastewater Treatment Plants

Author

An-Dong eLi, Li-Guan eLi, and Tong eZhang

Subjects

Metagenome, antibiotic resistance, metal resistance, Plasmid, wastewater treatment, Microbiology, QR1-502

Abstract

Plasmids operate as independent genetic elements in microorganism communities. Through horizontal gene transfer, they can provide their host microorganisms with important functions such as antibiotic resistance and heavy metal resistance. In this study, six metagenomic libraries were constructed with plasmid DNA extracted from influent, activated sludge and digested sludge of two wastewater treatment plants. Compared with the metagenomes of the total DNA extracted from the same sectors of the wastewater treatment plant, the plasmid metagenomes had significantly higher annotation rates, indicating that the functional genes on plasmids are commonly shared by those studied microorganisms. Meanwhile, the plasmid metagenomes also encoded many more genes related to defense mechanisms, including ARGs. Searching against an antibiotic resistance genes (ARGs) database and a metal resistance genes (MRGs) database revealed a broad-spectrum of antibiotic (323 out of a total 618 subtypes) and metal resistance genes (23 out of a total 23 types) on these plasmid metagenomes. The influent plasmid metagenomes contained many more resistance genes (both ARGs and MRGs) than the activated sludge and the digested sludge metagenomes. Sixteen novel plasmids with a complete circular structure that carried these resistance genes were assembled from the plasmid metagenomes. The results of this study demonstrated that the plasmids in wastewater treatment plants could be important reservoirs for resistance genes, and may play a significant role in the horizontal transfer of these genes.

Published

2015

5. Microbial- and Thiosulfate-Mediated Dissolution of Mercury Sulfide Minerals and Transformation to Gaseous Mercury

Author

Adiari eVázquez-Rodríguez, Colleen Michelle Hansel, Tong eZhang, Carl eLamborg, Cara M Santelli, Samuel eWebb, and Scott eBrooks

Subjects

Mercury, Thiobacillus, Sulfur oxidation, Sulfur metabolism, thiosulfate, Metacinnabar, Microbiology, QR1-502

Abstract

Mercury (Hg) is a toxic heavy metal that poses significant human and environmental health risks. Soils and sediments, where Hg can exist as the Hg sulfide mineral metacinnabar (β-HgS), represent major Hg reservoirs in aquatic environments. Metacinnabar has historically been considered a sink for Hg in all but severely acidic environments, and thus disregarded as a potential source of Hg back to aqueous or gaseous pools. Here, we conducted a combination of field and laboratory incubations to identify the potential for metacinnabar as a source of dissolved Hg within near neutral pH environments and the underpinning (a)biotic mechanisms at play. We show that the abundant and widespread sulfur-oxidizing bacterium Thiobacillus extensively colonized metacinnabar chips incubated within aerobic, near neutral pH creek sediments. Laboratory incubations of axenic Thiobacillus cultures lead to the release of metacinnabar-hosted Hg(II) and subsequent volatilization to Hg(0). This dissolution and volatilization was greatly enhanced in the presence of the sulfur intermediate, thiosulfate, which served a dual role by enhancing HgS dissolution and providing an additional metabolic substrate for Thiobacillus. These findings reveal a new coupled abiotic-biotic pathway for the transformation of metacinnabar-bound Hg(II) to Hg(0), while expanding the sulfide substrates available for neutrophilic chemosynthetic bacteria to Hg-laden sulfides. They also point to mineral-hosted Hg as an underappreciated source of gaseous elemental Hg to the environment.

Published

2015

6. Phosphoproteomics technologies and applications in plant biology research

Author

Jinna eLi, Cecilia eSilva-Sanchez, Tong eZhang, Sixue eChen, and Haiying eLi

Subjects

plant biology, Enrichment, phosphoproteomics, quantification, phosphorylation site mapping, Plant culture, SB1-1110

Abstract

Protein phosphorylation has long been recognized as an essential mechanism to regulate many important processes of plant life. However, studies on phosphorylation mediated signaling events in plants are challenged with low stoichiometry and dynamic nature of phosphorylated proteins. Significant advances in mass spectrometry based phosphoproteomics have taken place in recent decade, including phosphoprotein/phosphopeptide enrichment, detection and quantification and phosphorylation site localization. This review describes a variety of separation and enrichment methods for phosphoproteins and phosphopeptides, the applications of technological innovations in plant phosphoproteomics, and highlights significant achievement of phosphoproteomics in the areas of plant signal transduction, growth and development.

Published

2015