Lateral organ boundaries domain (LBD) proteins belong to a particular class of transcription factors of lateral organ boundary (LOB) specific domains that play essential roles in plant growth and development. However, a potato phylogenetic analysis of the LBD family has not been fully studied by scholars and researchers. In this research, bioinformatics methods and the growth of potatoes were used to identify 43 StLBD proteins. We separated them into seven subfamilies: Ia, Ib, Ic, Id, Ie, IIa and IIb. The number of amino acids encoded by the potato LBD family ranged from 94 to 327. The theoretical isoelectric point distribution ranged from 4.16 to 9.12 Kda, and they were distributed among 10 chromosomes. The results of qRT-PCR showed that the expression levels of StLBD2-6 and StLBD3-5 were up-regulated under drought stress in the stem. The expression levels of StLBD1-5 and StLBD2-6 were down-regulated in leaves. We hypothesized that StLBD1-5 was down-regulated under drought stress, and that StLBD2-6 and StLBD3-5 up-regulation might help to maintain the normal metabolism of potato and enhance the potatoes’ resistance to drought.
No abstract
PHT1 (phosphate transporter 1) family genes play important roles in regulating plant growth and responding to stress. However, there has been little research on the role of the PHT1 family in potatoes. In this study, using molecular and bioinformatic approaches, 8 PHT1 family genes were identified from the potato genome. StPHT1;7 was highly expressed in the whole potato plants. The overexpression and silence vectors of StPHT1;7 were constructed and transformed into the potato cultivar Desiree. Consequently, StPHT1;7 overexpression (with a relative expression 2–7-fold that in the control) and silence lines (with a relative expression of 0.3%–1% that in the control) were obtained. Their growth vigor was ranked in the order overexpression line > wild type > silence line. In the absence of phosphorus, the root length of the overexpression line was approximately 2.6 times that of the wild type, while the root length of the silence line was approximately 0.6 times that of the wild type. Furthermore, their tolerance to drought stress was ranked as wild type > overexpression line > silence line. These results suggest that StPHT1;7 affects growth and stress tolerance in potato plants.
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.
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.
Background: Potato is the fourth world's most important crops. Global warming has heavily constrained potato production. Although some work has been undertaken regarding the response of potato to moderately increased temperature (25-30°C), few studies have examined the extreme high temperature above 35°C and sustaining high temperature impact on physiological, biochemical and molecular responses of potato. Methods: Potato plants were subjected to high temperature (35°C/33 °C day/night) treatments for 6 h (short) and 3 days (long), physiological and biochemical response of electrolyte leakage and photosynthetic performance were measured, transcriptome and metabolome profiles of leaves were examined. Expression profiles of 20 DEGs were verified by RT–qPCR, heat induced conserved genes were transient expressed in Nicotiana benthamiana.Results: Growth at short heat stress induced stomata open and lower membrane stability. Prolonged heat stress decreased the photosynthetic parameters and increased photosynthetic pigments. Integration of transcriptomics and metabolomics methods demonstrated that 448 heat upregulated and 918 heat downregulated genes as well as 325 and 219 compounds in the positive and negative ionization modes, respectively, that were up- or down-regulated in leaves detected in responsive to short and prolonged heat stress. Global transcripts changes were mainly induced by short heat stress, where metabolites changes were mainly activated by prolonged heat stress. General responses to heat stress in gene expression and metabolite accumulation enriched in amino acid metabolism and secondary metabolism pathway. Metabolite and transcript abundances for the up-regulation of flavone and flavonol biosynthesis under the prolonged heat stress were closely correlated. Both conserved and heat- and potato-specific stress responsive genes were identified by comparing heat and drought stress in potato as well as heat stress in potato and Arabidopsis shoots, transient expression of four heat induced genes in Nicotiana benthamiana exhibited heat tolerance to higher temperature.Conclusions: A new potato leaf transcriptomes and metabolomes revealed a widely adaptive response to high temperature by mainly generation and accumulation of heat shock proteins.
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