Your search keyword '"duplication events"' showing total 8 results

1. Evolutionary significance of amino acid permease transporters in 17 plants from Chlorophyta to Angiospermae

Author

Chao Zhang, Nana Kong, Minxuan Cao, Dongdong Wang, Yue Chen, and Qin Chen

Subjects

AAP family, Evolution, Sequencing plants, Phylogenetic analysis, Duplication events, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Nitrogen is an indispensable nutrient for plant growth. It is used and transported in the form of amino acids in living organisms. Transporting amino acids to various parts of plants requires relevant transport proteins, such as amino acid permeases (AAPs), which were our focus in this study. Results We found that 5 AAP genes were present in Chlorophyte species and more AAP genes were predicted in Bryophyta and Lycophytes. Two main groups were defined and group I comprised 5 clades. Our phylogenetic analysis indicated that the origin of clades 2, 3, and 4 is Gymnospermae and that these clades are closely related. The members of clade 1 included Chlorophyta to Gymnospermae. Group II, as a new branch consisting of non-seed plants, is first proposed in our research. Our results also indicated that the AAP family was already present in Chlorophyta and then expanded accompanying the development of vasculature. Concurrently, the AAP family experienced multiple duplication events that promoted the generation of new functions and differentiation of sub-functions. Conclusions Our findings suggest that the AAP gene originated in Chlorophyta, and some non-seed AAP genes clustered in one group. A second group, which contained plants of all evolutionary stages, indicated the evolution of AAPs. These new findings can be used to guide future research.

Published

2020

2. The structure, functional evolution, and evolutionary trajectories of the H+-PPase gene family in plants

Author

Yiming Zhang, Xue Feng, Lihui Wang, Yanping Su, Zhuodong Chu, and Yanxiang Sun

Subjects

H+-PPase gene family, Duplication events, Functional divergence, Positive selection, Evolutionary trajectories, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The H+-PPase (pyrophosphatase) gene family is an important class of proton transporters that play key roles in plant development and stress resistance. Although the physiological and biochemical functions of H+-PPases are well characterized, the structural evolution and functional differentiation of this gene family remain unclear. Results We identified 124 H+-PPase members from 27 plant species using complete genomic data obtained from algae to angiosperms. We found that all analyzed plants carried H+-PPase genes, and members were not limited to the two main types (type I and II). Differentiation of this gene family occurred early in evolutionary history, probably prior to the emergence of algae. The type I and II H+-PPase genes were retained during the subsequent evolution of higher plants, and their copy numbers increased rapidly in some angiosperms following whole-genome duplication (WGD) events, with obvious expression pattern differentiation among the new copies. We found significant functional divergence between type I and II H+-PPase genes, with both showing evidence for positive selection pressure. We classified angiosperm type I H+-PPases into subtypes Ia and non-Ia, which probably differentiated at an early stage of angiosperm evolution. Compared with non-Ia subtype, the Ia subtype appears to confer some advantage in angiosperms, as it is highly conserved and abundantly expressed, but shows no evidence for positive selection. Conclusions We hypothesized that there were many types of H+-PPase genes in the plant ancestral genome, and that different plant groups retained different types of these genes. In the early stages of angiosperm evolution, the type I H+-PPase genes differentiated into various subtypes. In addition, the expression pattern varied not only among genes of different types or subtypes, but also among copies of the same subtype. Based on the expression patterns and copy numbers of H+-PPase genes in higher plants, we propose two possible evolutionary trajectories for this gene family.

Published

2020

3. Genome-Wide Evolution and Comparative Analysis of Superoxide Dismutase Gene Family in Cucurbitaceae and Expression Analysis of Lagenaria siceraria Under Multiple Abiotic Stresses

Author

Shamsur Rehman, Arif Rashid, Muhammad Aamir Manzoor, Lingling Li, Weibo Sun, Muhammad Waheed Riaz, Dawei Li, and Qiang Zhuge

Subjects

LsiSOD genes, phylogenetic analysis, stress response, duplication events, expression pattern, Genetics, QH426-470

Abstract

Superoxide dismutase (SOD) is an important enzyme that serves as the first line of defense in the plant antioxidant system and removes reactive oxygen species (ROS) under adverse conditions. The SOD protein family is widely distributed in the plant kingdom and plays a significant role in plant growth and development. However, the comprehensive analysis of the SOD gene family has not been conducted in Cucurbitaceae. Subsequently, 43 SOD genes were identified from Cucurbitaceae species [Citrullus lanatus (watermelon), Cucurbita pepo (zucchini), Cucumis sativus (cucumber), Lagenaria siceraria (bottle gourd), Cucumis melo (melon)]. According to evolutionary analysis, SOD genes were divided into eight subfamilies (I, II, III, IV, V, VI, VII, VIII). The gene structure analysis exhibited that the SOD gene family had comparatively preserved exon/intron assembly and motif as well. Phylogenetic and structural analysis revealed the functional divergence of Cucurbitaceae SOD gene family. Furthermore, microRNAs 6 miRNAs were predicted targeting 3 LsiSOD genes. Gene ontology annotation outcomes confirm the role of LsiSODs under different stress stimuli, cellular oxidant detoxification processes, metal ion binding activities, SOD activity, and different cellular components. Promoter regions of the SOD family revealed that most cis-elements were involved in plant development, stress response, and plant hormones. Evaluation of the gene expression showed that most SOD genes were expressed in different tissues (root, flower, fruit, stem, and leaf). Finally, the expression profiles of eight LsiSOD genes analyzed by qRT-PCR suggested that these genetic reserves responded to drought, saline, heat, and cold stress. These findings laid the foundation for further study of the role of the SOD gene family in Cucurbitaceae. Also, they provided the potential for its use in the genetic improvement of Cucurbitaceae.

Published

2022

4. The structure, functional evolution, and evolutionary trajectories of the H+-PPase gene family in plants

Author

Feng Xue, Zhuodong Chu, Sun Yanxiang, Lihui Wang, Yiming Zhang, and Yanping Su

Subjects

0106 biological sciences, lcsh:QH426-470, lcsh:Biotechnology, Proteomics, 01 natural sciences, 03 medical and health sciences, Algae, Evolutionary trajectories, H+-PPase gene family, lcsh:TP248.13-248.65, Gene duplication, Genetics, Functional divergence, Gene family, Duplication events, Gene, 030304 developmental biology, 0303 health sciences, biology, fungi, food and beverages, Transporter, biology.organism_classification, Positive selection, lcsh:Genetics, DNA microarray, 010606 plant biology & botany, Biotechnology

Abstract

Background The H+-PPase (pyrophosphatase) gene family is an important class of proton transporters that play key roles in plant development and stress resistance. Although the physiological and biochemical functions of H+-PPases are well characterized, the structural evolution and functional differentiation of this gene family remain unclear. Results We identified 124 H+-PPase members from 27 plant species using complete genomic data obtained from algae to angiosperms. We found that all analyzed plants carried H+-PPase genes, and members were not limited to the two main types (type I and II). Differentiation of this gene family occurred early in evolutionary history, probably prior to the emergence of algae. The type I and II H+-PPase genes were retained during the subsequent evolution of higher plants, and their copy numbers increased rapidly in some angiosperms following whole-genome duplication (WGD) events, with obvious expression pattern differentiation among the new copies. We found significant functional divergence between type I and II H+-PPase genes, with both showing evidence for positive selection pressure. We classified angiosperm type I H+-PPases into subtypes Ia and non-Ia, which probably differentiated at an early stage of angiosperm evolution. Compared with non-Ia subtype, the Ia subtype appears to confer some advantage in angiosperms, as it is highly conserved and abundantly expressed, but shows no evidence for positive selection. Conclusions We hypothesized that there were many types of H+-PPase genes in the plant ancestral genome, and that different plant groups retained different types of these genes. In the early stages of angiosperm evolution, the type I H+-PPase genes differentiated into various subtypes. In addition, the expression pattern varied not only among genes of different types or subtypes, but also among copies of the same subtype. Based on the expression patterns and copy numbers of H+-PPase genes in higher plants, we propose two possible evolutionary trajectories for this gene family.

Published

2020

5. Evolutionary significance of amino acid permease transporters in 17 plants from Chlorophyta to Angiospermae

Author

Yue Chen, Nana Kong, Dongdong Wang, Qin Chen, Minxuan Cao, and Chao Zhang

Subjects

0106 biological sciences, lcsh:QH426-470, Amino Acid Transport Systems, Evolution, Nitrogen, lcsh:Biotechnology, Chlorophyta, Biology, 01 natural sciences, Evolution, Molecular, 03 medical and health sciences, Magnoliopsida, lcsh:TP248.13-248.65, Gene Duplication, Gene duplication, Genetics, Duplication events, Clade, Gene, Phylogeny, 030304 developmental biology, Plant Proteins, chemistry.chemical_classification, 0303 health sciences, AAP family, Sequencing plants, Phylogenetic analysis, Phylogenetic tree, Permease, Sequence Analysis, DNA, biology.organism_classification, Amino acid, Amino acid permease, lcsh:Genetics, chemistry, Multigene Family, 010606 plant biology & botany, Biotechnology, Research Article

Abstract

Background Nitrogen is an indispensable nutrient for plant growth. It is used and transported in the form of amino acids in living organisms. Transporting amino acids to various parts of plants requires relevant transport proteins, such as amino acid permeases (AAPs), which were our focus in this study. Results We found that 5 AAP genes were present in Chlorophyte species and more AAP genes were predicted in Bryophyta and Lycophytes. Two main groups were defined and group I comprised 5 clades. Our phylogenetic analysis indicated that the origin of clades 2, 3, and 4 is Gymnospermae and that these clades are closely related. The members of clade 1 included Chlorophyta to Gymnospermae. Group II, as a new branch consisting of non-seed plants, is first proposed in our research. Our results also indicated that the AAP family was already present in Chlorophyta and then expanded accompanying the development of vasculature. Concurrently, the AAP family experienced multiple duplication events that promoted the generation of new functions and differentiation of sub-functions. Conclusions Our findings suggest that the AAP gene originated in Chlorophyta, and some non-seed AAP genes clustered in one group. A second group, which contained plants of all evolutionary stages, indicated the evolution of AAPs. These new findings can be used to guide future research.

Published

2020

6. The kinome of pineapple: catalog and insights into functions in crassulacean acid metabolism plants

Author

Qunkang Cheng, Hui Liu, Zong-Ming Max Cheng, Xinlu Chen, and Kaikai Zhu

Subjects

0301 basic medicine, Drought tolerance, Plant Science, Biology, Ananas, Expression patterns, Genome, Chromosomes, Plant, Phylogenetic relationship, 03 medical and health sciences, Protein Domains, Gene Expression Regulation, Plant, Gene Duplication, lcsh:Botany, Gene duplication, Kinome, Duplication events, Gene, Phylogeny, Synteny, Plant Proteins, Genetics, fungi, biology.organism_classification, Introns, Circadian Rhythm, lcsh:QK1-989, 030104 developmental biology, Coexpression network, Crassulacean acid metabolism, Protein Kinases, Genome, Plant, Alternative splicing

Abstract

Background Crassulacean acid metabolism (CAM) plants use water 20–80% more efficiently by shifting stomata opening and primary CO2 uptake and fixation to the nighttime. Protein kinases (PKs) play pivotal roles in this biological process. However, few PKs have been functionally analyzed precisely due to their abundance and potential functional redundancy (caused by numerous gene duplications). Results In this study, we systematically identified a total of 758 predicted PK genes in the genome of a CAM plant, pineapple (Ananas comosus). The pineapple kinome was classified into 20 groups and 116 families based on the kinase domain sequences. The RLK was the largest group, containing 480 members, and over half of them were predicted to locate at the plasma membrane. Both segmental and tandem duplications make important contributions to the expansion of pineapple kinome based on the synteny analysis. Ka/Ks ratios showed all of the duplication events were under purifying selection. The global expression analysis revealed that pineapple PKs exhibit different tissue-specific and diurnal expression patterns. Forty PK genes in a cluster performed higher expression levels in green leaf tip than in white leaf base, and fourteen of them had strong differential expression patterns between the photosynthetic green leaf tip and the non-photosynthetic white leaf base tissues. Conclusions Our findings provide insights into the evolution and biological function of pineapple PKs and a foundation for further functional analysis of PKs in CAM plants. The gene duplication, expression, and coexpression analysis helped us to rapidly identify the key candidates in pineapple kinome, which may play roles in the carbon fixation process in pineapple and help engineering CAM pathway into C3 crops for improved drought tolerance.

Published

2018

7. Genomic Dissection and Expression Profiling Revealed Functional Divergence in Triticum aestivum Leucine Rich Repeat Receptor Like Kinases (TaLRRKs)

Author

Shumayla ., Shailesh Sharma, Rohit Kumar, Venugopal Mendu, Kashmir Singh, and Santosh Kumar Upadhyay

Subjects

0301 basic medicine, Genetics, neofunctionalization, phylogenetic groups, Subfamily, TaLRRKs, Triticum aestivum, food and beverages, Expression, Plant Science, lcsh:Plant culture, Biology, Leucine-rich repeat, Gene expression profiling, stress, 03 medical and health sciences, 030104 developmental biology, Gene duplication, Gene family, lcsh:SB1-1110, Neofunctionalization, Gene, Functional divergence, duplication events

Abstract

The leucine rich repeat receptor like kinases (LRRK) constitute the largest subfamily of receptor like kinases (RLK), which play critical roles in plant development and stress responses. Herein, we identified 531 TaLRRK genes in Triticum aestivum (bread wheat), which were distributed throughout the A, B, and D sub-genomes and chromosomes. These were clustered into 233 homologous groups, which were mostly located on either homeologous chromosomes from various sub-genomes or in proximity on the same chromosome. A total of 255 paralogous genes were predicted which depicted the role of duplication events in expansion of this gene family. Majority of TaLRRKs consisted of trans-membrane region and localized on plasma-membrane. The TaLRRKs were further categorized into eight phylogenetic groups with numerous subgroups on the basis of sequence homology. The gene and protein structure in terms of exon/intron ratio, domains, and motifs organization were found to be variably conserved across the different phylogenetic groups/subgroups, which indicated a potential divergence and neofunctionalization during evolution. High-throughput transcriptome data and quantitative real time PCR analyses in various developmental stages, and biotic and abiotic (heat, drought, and salt) stresses provided insight into modus operandi of TaLRRKs during these conditions. Distinct expression of majority of stress responsive TaLRRKs homologous genes suggested their specified role in a particular condition. These results provided a comprehensive analysis of various characteristic features including functional divergence, which may provide the way for future functional characterization of this important gene family in bread wheat.

Published

2016

8. Soybean kinome: functional classification and gene expression patterns

Author

Nana Chen, Tarek Hewezi, C. Neal Stewart, Joshua N. Grant, Jinyi Liu, and Zong-Ming Max Cheng

Subjects

abiotic stress, Physiology, Gene Expression, Plant Science, Biology, Genome, Segmental Duplications, Genomic, biotic stress, Gene expression, Gene family, Kinome, Amino Acid Sequence, Gene, Phylogeny, Segmental duplication, Plant Proteins, soybean kinases, Genetics, co-expression network, Intron, Chromosome Mapping, collinearity analysis, Organ Specificity, Multigene Family, Soybeans, Protein Kinases, Functional divergence, Genome, Plant, Research Paper, duplication events

Abstract

Highlight Identification and functional classification of soybean kinase gene family revealed wide expansion and extensive divergence in gene structure, subcellular localizations, and tissue and stress gene expression patterns., The protein kinase (PK) gene family is one of the largest and most highly conserved gene families in plants and plays a role in nearly all biological functions. While a large number of genes have been predicted to encode PKs in soybean, a comprehensive functional classification and global analysis of expression patterns of this large gene family is lacking. In this study, we identified the entire soybean PK repertoire or kinome, which comprised 2166 putative PK genes, representing 4.67% of all soybean protein-coding genes. The soybean kinome was classified into 19 groups, 81 families, and 122 subfamilies. The receptor-like kinase (RLK) group was remarkably large, containing 1418 genes. Collinearity analysis indicated that whole-genome segmental duplication events may have played a key role in the expansion of the soybean kinome, whereas tandem duplications might have contributed to the expansion of specific subfamilies. Gene structure, subcellular localization prediction, and gene expression patterns indicated extensive functional divergence of PK subfamilies. Global gene expression analysis of soybean PK subfamilies revealed tissue- and stress-specific expression patterns, implying regulatory functions over a wide range of developmental and physiological processes. In addition, tissue and stress co-expression network analysis uncovered specific subfamilies with narrow or wide interconnected relationships, indicative of their association with particular or broad signalling pathways, respectively. Taken together, our analyses provide a foundation for further functional studies to reveal the biological and molecular functions of PKs in soybean.

Published

2015