Your search keyword '"Heyu Lin"' showing total 4 results

1. Comparative genomic analysis reveals the evolution and environmental adaptation strategies of vibrios

Author

Heyu Lin, Min Yu, Xiaolei Wang, and Xiao-Hua Zhang

Subjects

Vibrio, Comparative genomics, Phylogeny, Environmental adaptation, Gene gain/loss, Chitinase, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Vibrios are among the most diverse and ecologically important marine bacteria, which have evolved many characteristics and lifestyles to occupy various niches. The relationship between genome features and environmental adaptation strategies is an essential part for understanding the ecological functions of vibrios in the marine system. The advent of complete genome sequencing technology has provided an important method of examining the genetic characteristics of vibrios on the genomic level. Results Two Vibrio genomes were sequenced and found to occupy many unique orthologues families which absent from the previously genes pool of the complete genomes of vibrios. Comparative genomics analysis found vibrios encompass a steady core-genome and tremendous pan-genome with substantial gene gain and horizontal gene transfer events in the evolutionary history. Evolutionary analysis based on the core-genome tree suggested that V. fischeri emerged ~ 385 million years ago, along with the occurrence of cephalopods and the flourish of fish. The relatively large genomes, the high number of 16S rRNA gene copies, and the presence of R-M systems and CRISPR system help vibrios live in various marine environments. Chitin-degrading related genes are carried in nearly all the Vibrio genomes. The number of chitinase genes in vibrios has been extremely expanded compared to which in the most recent ancestor of the genus. The chitinase A genes were estimated to have evolved along with the genus, and have undergone significant purifying selective force to conserve the ancestral state. Conclusions Vibrios have experienced extremely genome expansion events during their evolutionary history, allowing them to develop various functions to spread globally. Despite their close phylogenetic relationships, vibrios were found to have a tremendous pan-genome with a steady core-genome, which indicates the highly plastic genome of the genus. Additionally, the existence of various chitin-degrading related genes and the expansion of chitinase A in the genus demonstrate the importance of the chitin utilization for vibrios. Defensive systems in the Vibrio genomes may protect them from the invasion of external DNA. These genomic features investigated here provide a better knowledge of how the evolutionary process has forged Vibrio genomes to occupy various niches.

Published

2018

2. Comparative genomic analysis reveals the evolution and environmental adaptation strategies of vibrios

Author

Xiaolei Wang, Min Yu, Xiao-Hua Zhang, and Heyu Lin

Subjects

0301 basic medicine, lcsh:QH426-470, lcsh:Biotechnology, Genome, Evolution, Molecular, 03 medical and health sciences, Species Specificity, Phylogenetics, lcsh:TP248.13-248.65, Genetics, Seawater, Gene gain/loss, Gene, Phylogeny, Vibrio, Whole genome sequencing, Comparative genomics, biology, Phylogenetic tree, Chitinase, Genetic Variation, High-Throughput Nucleotide Sequencing, Genomics, biology.organism_classification, Adaptation, Physiological, Environmental adaptation, lcsh:Genetics, 030104 developmental biology, Evolutionary biology, Horizontal gene transfer, Genome, Bacterial, Research Article, Biotechnology

Abstract

Background Vibrios are among the most diverse and ecologically important marine bacteria, which have evolved many characteristics and lifestyles to occupy various niches. The relationship between genome features and environmental adaptation strategies is an essential part for understanding the ecological functions of vibrios in the marine system. The advent of complete genome sequencing technology has provided an important method of examining the genetic characteristics of vibrios on the genomic level. Results Two Vibrio genomes were sequenced and found to occupy many unique orthologues families which absent from the previously genes pool of the complete genomes of vibrios. Comparative genomics analysis found vibrios encompass a steady core-genome and tremendous pan-genome with substantial gene gain and horizontal gene transfer events in the evolutionary history. Evolutionary analysis based on the core-genome tree suggested that V. fischeri emerged ~ 385 million years ago, along with the occurrence of cephalopods and the flourish of fish. The relatively large genomes, the high number of 16S rRNA gene copies, and the presence of R-M systems and CRISPR system help vibrios live in various marine environments. Chitin-degrading related genes are carried in nearly all the Vibrio genomes. The number of chitinase genes in vibrios has been extremely expanded compared to which in the most recent ancestor of the genus. The chitinase A genes were estimated to have evolved along with the genus, and have undergone significant purifying selective force to conserve the ancestral state. Conclusions Vibrios have experienced extremely genome expansion events during their evolutionary history, allowing them to develop various functions to spread globally. Despite their close phylogenetic relationships, vibrios were found to have a tremendous pan-genome with a steady core-genome, which indicates the highly plastic genome of the genus. Additionally, the existence of various chitin-degrading related genes and the expansion of chitinase A in the genus demonstrate the importance of the chitin utilization for vibrios. Defensive systems in the Vibrio genomes may protect them from the invasion of external DNA. These genomic features investigated here provide a better knowledge of how the evolutionary process has forged Vibrio genomes to occupy various niches. Electronic supplementary material The online version of this article (10.1186/s12864-018-4531-2) contains supplementary material, which is available to authorized users.

Published

2018

3. Genomic insight into Aquimarina longa SW024T: its ultra-oligotrophic adapting mechanisms and biogeochemical functions

Author

Heyu Lin, Xiao-Hua Zhang, Tingting Xu, Zenghu Zhang, Min Yu, and Jiwen Liu

Subjects

food.ingredient, Adaptation, Biological, Genomics, Biology, medicine.disease_cause, Genome, Open Reading Frames, food, Aquimarina longa, Genetics, medicine, Oligotrophic bacterium, Seawater, Genome size, Phylogeny, Base Composition, Genome comparison, Aquimarina, Genome analysis, Genome project, Multigene Family, Energy source, Flavobacteriaceae, Genome, Bacterial, Research Article, Biotechnology, Sulfur utilization

Abstract

Background South Pacific Gyre (SPG) is the largest and clearest gyre in the world, where the concentration of surface chlorophyll a and primary production are extremely low. Aquimarina longa SW024T was isolated from surface water of the SPG center. To understand how this bacterium could survive in this ultra-oligotrophic oceanic environment and its function in biogeochemical cycle, we sequenced the genome of A. longa SW024T and performed extensive genomic analyses. Methods Genomic DNA was extracted and sequenced using Illumina Hiseq 2000 and Miseq platform. Genome annotation, genomic comparison and phylogenetic analyses were performed with the use of multiple bioinformatics tools like: BLAST+ 2.2.24, Glimmer3.0, RAST server, Geneious 4.8.5, ClustalW2 and MEGA5. Physiological and morphological features were tested by bacterial culture, electron microscopy, fluorescence microscopy and exopolysaccharides extraction. Results Analysis of seven Aquimarina genomes and 30 other genomes of Flavobacteriaceae isolated from seawater showed that most of the strains had low DNA G + C contents, and Aquimarina had larger genomes than other strains. Genome comparison showed varying genomic properties among seven Aquimarina genomes, including genome sizes and gene contents, which may warrant their specific adaptive strategies. Genome of A. longa SW024T was further compared with the genomes of two other Aquimarina species which were also isolated from the SPG and A. longa SW024T appeared to have much more genes related to replication, recombination and repair. As a copiotroph, A. longa SW024T is long in length, and possesses large genome size and diverse transporters. However, it has also evolved many properties to survive in the oligotrophic marine environment. This bacterium grew better on solid medium than in liquid medium, suggesting it may be liable to attach to particle surfaces in order to survive in the nutrient-limiting environment. Gliding motility and the capacity to degrade various polymers possibly allow the bacterium to grow on detritus particles and use polymeric substances as carbon and energy sources. Moreover, genes related to carbon, nitrogen, and sulfur metabolisms were identified, which showed that A. longa SW024T might be involved in various elemental cycles. Conclusions Genomic comparison of Aquimarina genus exhibits comprehensive capabilities of the strains to adapt to diverse marine environments. The genomic characteristics of A. longa SW024T reveal that it evolves various strategies to cope with both copiotrophic and ultra-oligotrophic marine environment, which provides a better understanding of the survival abilities of bacteria in prevalent and even extreme oceanic environments. Furthermore, carbon, nitrogen and sulfur utilization of A. longa SW024T may represent its potential functions in the global biogeochemical cycle. Electronic supplementary material The online version of this article (doi:10.1186/s12864-015-2005-3) contains supplementary material, which is available to authorized users.

Published

2015

4. Genomic insight into Aquimarina longa SW024T: its ultra-oligotrophic adapting mechanisms and biogeochemical functions.

Author

Tingting Xu, Min Yu, Heyu Lin, Zenghu Zhang, Jiwen Liu, and Xiao-Hua Zhang

Subjects

PLANT genomes, CHLOROPHYLL synthesis, WATER, DNA, PHYLOGENY

Abstract

Background: South Pacific Gyre (SPG) is the largest and clearest gyre in the world, where the concentration of surface chlorophyll a and primary production are extremely low. Aquimarina longa SW024T was isolated from surface water of the SPG center. To understand how this bacterium could survive in this ultra-oligotrophic oceanic environment and its function in biogeochemical cycle, we sequenced the genome of A. longa SW024T and performed extensive genomic analyses. Methods: Genomic DNA was extracted and sequenced using Illumina Hiseq 2000 and Miseq platform. Genome annotation, genomic comparison and phylogenetic analyses were performed with the use of multiple bioinformatics tools like: BLAST+ 2.2.24, Glimmer3.0, RAST server, Geneious 4.8.5, ClustalW2 and MEGA5. Physiological and morphological features were tested by bacterial culture, electron microscopy, fluorescence microscopy and exopolysaccharides extraction. Results: Analysis of seven Aquimarina genomes and 30 other genomes of Flavobacteriaceae isolated from seawater showed that most of the strains had low DNA G + C contents, and Aquimarina had larger genomes than other strains. Genome comparison showed varying genomic properties among seven Aquimarina genomes, including genome sizes and gene contents, which may warrant their specific adaptive strategies. Genome of A. longa SW024T was further compared with the genomes of two other Aquimarina species which were also isolated from the SPG and A. longa SW024T appeared to have much more genes related to replication, recombination and repair. As a copiotroph, A. longa SW024T is long in length, and possesses large genome size and diverse transporters. However, it has also evolved many properties to survive in the oligotrophic marine environment. This bacterium grew better on solid medium than in liquid medium, suggesting it may be liable to attach to particle surfaces in order to survive in the nutrient-limiting environment. Gliding motility and the capacity to degrade various polymers possibly allow the bacterium to grow on detritus particles and use polymeric substances as carbon and energy sources. Moreover, genes related to carbon, nitrogen, and sulfur metabolisms were identified, which showed that A. longa SW024T might be involved in various elemental cycles. Conclusions: Genomic comparison of Aquimarina genus exhibits comprehensive capabilities of the strains to adapt to diverse marine environments. The genomic characteristics of A. longa SW024T reveal that it evolves various strategies to cope with both copiotrophic and ultra-oligotrophic marine environment, which provides a better understanding of the survival abilities of bacteria in prevalent and even extreme oceanic environments. Furthermore, carbon, nitrogen and sulfur utilization of A. longa SW024T may represent its potential functions in the global biogeochemical cycle. [ABSTRACT FROM AUTHOR]

Published

2015