De Chang

The development of space microbiology in the future: the value and significance of space microbiology research

The role and mechanisms of the space environ-ment with regard to microorganisms is a cut-ting-edge issue. China has recently launched the ShenZhou VIII spacecraft that carried 15 species of microorganism to test the response of micro -organisms following exposure to the space envi -ronment. This revealed that effects were mainly seen in changes to bacterial invasion, antibiotic resistance and environmental adaptation. The mechanisms could be due to multiple changes in the genome, transcriptome, proteome and metabolome, and can be used to explain effects at molecular, cellular, tissue, organ and whole organism levels. Based on these findings, we have proposed the direction of the space microbiology development.With increasingly frequent space exploration, space has become a new field of human activ-ity. Microorganisms are natural constituents of our current environment, existing in air, water, soil and biotic systems. Therefore, human space activities inevitably transport some microorgan -isms to space. Although outer space is an extreme and very complex environment, microorganisms readily adapt to changes in environmental vari -ables, such as weightlessness, cosmic radiation, temperature, pressure and nutrient levels, and exhibit a variety of morphological and physi-ological changes. Various microbial changes can happen in space, which could either be use -ful or harmful. Microorganisms often possess characteristics such as being small, fast growing and adaptable and so are extremely suitable for space study, and have an important role in the development of space biology. Currently, world -wide research relevant to the space biomedical field is still in its infancy. The effects of the space environment on microorganisms and the mecha -nisms by which they occur are cutting-edge issues that urgently require our attention.Owing to the limitations of space-flight time, specific environmental conditions and other uncontrollable factors, implementation of spaceship-based experimental research is more difficult. To overcome these weaknesses, terrestrial laboratory facilities are designed to simulate parameters of outer space, such as rotary cell culture system, parabolic flight simulation and diamagnetic levitation. However, since a ground-based simulation environment is artificial, many different results will be generated due to the various types of machine models, parameters and operators used in the simulation. Hence, a unified standard is beyond current space research. Researchers have recognized that the ground-based simulation of conditions such as microgravity and ionizing radiation only imitates the real space environment in a limited manner for the microbes being analyzed

Draft Genome Sequence of Pseudomonas aeruginosa Strain ATCC 27853

Pseudomonas aeruginosa is a common bacterium that can cause disease. The versatility of Pseudomonas aeruginosa enables the organism to infect damaged tissues or those with reduced immunity which cause inflammation and sepsis. Here we report the genome sequence of the strain ATCC 27853.

WWTR1 promotes cell proliferation and inhibits apoptosis through cyclin A and CTGF regulation in non-small cell lung cancer

The Hippo pathway plays a major role in development and organ size control, and its dysregulation contributes to tumorigenesis. WWTR1 is a transcription coactivator acting downstream of the Hippo pathway. Recently, WWTR1 has been reported to be overexpressed in several human cancers including lung cancer. However, the molecular mechanism of WWTR1 regulating lung cancer aggressiveness remains ambiguous. In the present study, we analyzed the expression of WWTR1 in NSCLC cell lines and found that WWTR1 was overexpressed at both the mRNA and protein levels. Knockdown of WWTR1 by siRNA interference in A549 cells significantly inhibited cell proliferation and increased paclitaxel-induced apoptosis. On the other side, WWTR1 overexpression in HBE cell line promoted cell proliferation and inhibited apoptosis. In addition, we found that the decreased proliferation after siRNA treatment was due to cell cycle arrest. Further analysis showed that WWTR1 could induce cyclin A, connective tissue growth factor (CTGF) expression, and inhibit caspase3 cleavage. In conclusion, WWTR1 promotes malignant cell growth and inhibits apoptosis by cyclin A and CTGF regulation.

Draft Genome Sequence of Escherichia coli LCT-EC106

Escherichia coli is a Gram-negative, rod-shaped bacterium that is commonly found in the intestine of warm-blooded organisms. Most E. coli strains are harmless, but some serotypes can cause serious food poisoning in humans. Here, we present the complete genome sequence of Escherichia coli LCT-EC106, which was isolated from CGMCC 1.2385.

A multi-omic analysis of an Enterococcus faecium mutant reveals specific genetic mutations and dramatic changes in mRNA and protein expression

BackgroundFor a long time, Enterococcus faecium was considered a harmless commensal of the mammalian gastrointestinal (GI) tract and was used as a probiotic in fermented foods. In recent decades, E. faecium has been recognised as an opportunistic pathogen that causes diseases such as neonatal meningitis, urinary tract infections, bacteremia, bacterial endocarditis and diverticulitis. E. faecium could be taken into space with astronauts and exposed to the space environment. Thus, it is necessary to observe the phenotypic and molecular changes of E. faecium after spaceflight.ResultsAn E. faecium mutant with biochemical features that are different from those of the wild-type strain was obtained from subculture after flight on the SHENZHOU-8 spacecraft. To understand the underlying mechanism causing these changes, the whole genomes of both the mutant and the WT strains were sequenced using Illumina technology. The genomic comparison revealed that dprA, a recombination-mediator gene, and arpU, a gene associated with cell wall growth, were mutated. Comparative transcriptomic and proteomic analyses showed that differentially expressed genes or proteins were involved with replication, recombination, repair, cell wall biogenesis, glycometabolism, lipid metabolism, amino acid metabolism, predicted general function and energy production/conversion.ConclusionThis study analysed the comprehensive genomic, transcriptomic and proteomic changes of an E. faecium mutant from subcultures that were loaded on the SHENZHOU-8 spacecraft. The implications of these gene mutations and expression changes and their underlying mechanisms should be investigated in the future. We hope that the current exploration of multiple “-omics” analyses of this E. faecium mutant will provide clues for future studies on this opportunistic pathogen.

Draft Genome Sequence of Serratia marcescens Strain LCT-SM213

Serratia marcescens is a species of Gram-negative, rod-shaped bacterium of the family Enterobacteriaceae. S. marcescens can cause nosocomial infections, particularly catheter-associated bacteremia, urinary tract infections, and wound infections. Here, we present the draft genome sequence of Serratia marcescens strain LCT-SM213, which was isolated from CGMCC 1.1857.

Whole-Genome Sequence of Klebsiella pneumonia Strain LCT-KP214

Klebsiella pneumoniae is a gram-negative, nonmotile, encapsulated, lactose-fermenting, facultative anaerobic, rod-shaped bacterium found in the normal flora of the mouth, skin, and intestines. Here we present the fine-draft genome sequence of K. pneumoniae strain LCT-KP214, which originated from K. pneumoniae strain CGMCC 1.1736.

Comparative genomic analysis of Klebsiella pneumonia (LCT-KP214) and a mutant strain (LCT-KP289) obtained after spaceflight

BackgroundWith the development of space science, it is important to analyze the relationship between the space environment and genome variations that might cause phenotypic changes in microbes. Klebsiella pneumoniae is commonly found on the human body and is resistant to multiple drugs. To study space-environment-induced genome variations and drug resistance changes, K. pneumoniae was carried into outer space by the Shenzhou VIII spacecraft.ResultsThe K. pneumoniae strain LCT-KP289 was selected after spaceflight based on its phenotypic differences compared to the ground-control strain. Analysis of genomic structural variations revealed one inversion, 25 deletions, fifty-nine insertions, two translocations and six translocations with inversions. In addition, 155 and 400 unique genes were observed in LCT-KP214 and LCT-KP289, respectively, including the gene encoding dihydroxyacetone kinase, which generates the ATP and NADH required for microbial growth. Furthermore, a large number of mutant genes were related to transport and metabolism. Phylogenetic analysis revealed that most genes in these two strains had a dN/dS value greater than 1, indicating that the strain diversity increased after spaceflight. Analysis of drug-resistance phenotypes revealed that the K. pneumoniae strain LCT-KP289 was resistant to sulfamethoxazole, whereas the control strain, LCT-KP214, was not; both strains were resistant to benzylpenicillin, ampicillin, lincomycin, vancomycin, chloramphenicol and streptomycin. The sulfamethoxazole resistance may be associated with sequences in Scaffold7 in LCT-KP289, which were not observed in LCT-K214; this scaffold contained the gene sul1. In the strain LCT-KP289, we also observed a drug-resistance integron containing emrE (confers multidrug resistance) and ant (confers resistance to spectinomycin, streptomycin, tobramycin, kanamycin, sisomicin, dibekacin, and gentamicin). The gene ampC (confers resistance to penicillin, cephalosporin-ii and cephalosporin-i) was present near the integron. In addition, 30 and 26 drug-resistance genes were observed in LCT-KP289 and LCT-KP214, respectively.ConclusionsComparison of a K. pneumoniae strain obtained after spaceflight with the ground-control strain revealed genome variations and phenotypic changes and elucidated the genomic basis of the acquired drug resistance. These data pave the way for future studies on the effects of spaceflight.

Genome Sequence of Enterococcus faecium Clinical Isolate LCT-EF128

Enterococcus faecium, an opportunistic human pathogen that inhabits the gastrointestinal tracts of most mammals, has emerged as an important opportunistic nosocomial pathogen and is a prominent cause of multiresistant nosocomial infections. Here, we report the draft genome sequence of strain LCT-EF128, isolated from clinical specimens.

Impact of a short-term exposure to spaceflight on the phenotype, genome, transcriptome and proteome of Escherichia coli

Escherichia coli ( E. coli ) is the most widely applied model organism in current biological science. As a widespread opportunistic pathogen, E. coli can survive not only by symbiosis with human, but also outside the host as well, which necessitates the evaluation of its response to the space environment. Therefore, to keep humans safe in space, it is necessary to understand how the bacteria respond to this environment. Despite extensive investigations for a few decades, the response of E. coli to the real space environment is still controversial. To better understand the mechanisms how E. coli overcomes harsh environments such as microgravity in space and to investigate whether these factors may induce pathogenic changes in E. coli that are potentially detrimental to astronauts, we conducted detailed genomics, transcriptomic and proteomic studies on E. coli that experienced 17 days of spaceflight. By comparing two flight strains LCT-EC52 and LCT-EC59 to a control strain LCT-EC106 that was cultured under the same temperature conditions on the ground, we identified metabolism changes, polymorphism changes, differentially expressed genes and proteins in the two flight strains. The flight strains differed from the control in the utilization of more than 30 carbon sources. Two single nucleotide polymorphisms (SNPs) and one deletion were identified in the flight strains. The expression level of more than 1000 genes altered in flight strains. Genes involved in chemotaxis, lipid metabolism and cell motility express differently. Moreover, the two flight strains also differed extensively from each other in terms of metabolism, transcriptome and proteome, indicating the impact of space environment on individual cells is heterogeneous and probably genotype-dependent. This study presents the first systematic profile of E. coli genome, transcriptome and proteome after spaceflight, which helps to elucidate the mechanism that controls the adaptation of microbes to the space environment.