Ex vitro hairy root induction in detached peanut leaves for plant–nematode interaction studies

Guimarães, Larissa Arrais; Pereira, Bruna Medeiros; Araújo, Ana Cláudia Guerra; Guimarães, P. M.; Brasileiro, Ana Cristina Miranda

doi:10.1186/s13007-017-0176-4

Cited by 30 publications

(40 citation statements)

References 53 publications

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“…In the present study, many genes coding for cell wall modifying proteins were activated in response to dehydration and an EXPANSIN A (EXPA) was amongst the most highly upregulated of the genes analyzed by qRT-PCR ( Fig 8 ). These results support our previous hypothesis that wild Arachis Expansins are common and crucial players in responses to multiple and simultaneous stresses, including drought, ultraviolet light exposure, and nematode infection [ 19 , 21 , 23 , 65 ]. In contrast, AQUAPORIN transcripts were downregulated in all expression analyses conducted on both species.…”

Section: Discussionsupporting

confidence: 91%

Early responses to dehydration in contrasting wild Arachis species

et al. 2018

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Wild peanut relatives (Arachis spp.) are genetically diverse and were selected throughout evolution to a range of environments constituting, therefore, an important source of allelic diversity for abiotic stress tolerance. In particular, A. duranensis and A. stenosperma, the parents of the reference Arachis A-genome genetic map, show contrasting transpiration behavior under limited water conditions. This study aimed to build a comprehensive gene expression profile of these two wild species under dehydration stress caused by the withdrawal of hydroponic nutrient solution. For this purpose, roots of both genotypes were collected at seven time-points during the early stages of dehydration and used to construct cDNA paired-end libraries. Physiological analyses indicated initial differences in gas exchange parameters between the drought-tolerant genotype of A. duranensis and the drought-sensitive genotype of A. stenosperma. High-quality Illumina reads were mapped against the A. duranensis reference genome and resulted in the identification of 1,235 and 799 Differentially Expressed Genes (DEGs) that responded to the stress treatment in roots of A. duranensis and A. stenosperma, respectively. Further analysis, including functional annotation and identification of biological pathways represented by these DEGs confirmed the distinct gene expression behavior of the two contrasting Arachis species genotypes under dehydration stress. Some species-exclusive and common DEGs were then selected for qRT-PCR analysis, which corroborated the in silico expression profiling. These included genes coding for regulators and effectors involved in drought tolerance responses, such as activation of osmosensing molecular cascades, control of hormone and osmolyte content, and protection of macromolecules. This dataset of transcripts induced during the dehydration process in two wild Arachis genotypes constitute new tools for the understanding of the distinct gene regulation processes in these closely related species but with contrasting drought responsiveness. In addition, our findings provide insights into the nature of drought tolerance in wild germoplasm, which might be explored as novel sources of diversity and useful wild alleles to develop climate-resilient crop varieties.

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Section: Discussionsupporting

confidence: 91%

Early responses to dehydration in contrasting wild Arachis species

et al. 2018

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“…Therefore, the clinical application value or market demand of hEGF has become huge and booming in recent years. Hairy root is a good host for mass production of recombinant protein due to its abundant quality and extensive lateral branches [19]. Hairy root production system has received considerable interest in recent years [20,21].…”

Section: Discussionmentioning

confidence: 99%

“…Seeds of peanuts were germinated on soil and grown under greenhouse conditions (25 °C and approximately 16 h light /8 h dark photoperiod) for 30 d. Surface-sterilized leaf disks (approximately 2 × 2 cm) were inoculated with various concentrations of Agrobacterium rhizogenes R1601 and HR1601 strain (OD 600 = 0.5, 1.0, 1.5 or 2.0) for 2 min [19]. After removal of the excess strain with distilled water, leaf disks were then transferred to Murashige and Skoog medium (MS) containing cefotaxime sodium (200 mg/L) and allowed to grow in continuous light (8800 LUX) at 25 °C for about three weeks for hairy root emergence.…”

Section: Methodsmentioning

confidence: 99%

High Efficient Expression and Purification of Human Epidermal Growth Factor in Arachis Hypogaea L.

Yao

Liu

et al. 2019

IJMS

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Background: Human epidermal growth factor (hEGF) has drawn intense research attention due to its potential ability to promote healing of serious injuries, such as cuts, burns, and diabetic ulcers. Although hEGF displays prospective clinical value, the growth factor is restricted to the treatment of chronic diabetic ulcers because of its high production cost. Methods: Leguminous plant peanut (Arachis hypogaea L.) hairy roots contain relatively few toxic and harmful substances, and tested as an excellent production system for hEGF in our study. To explore the possibility of hEGF expression in peanut, hEGF overexpression hairy roots were obtained by infecting leaves with Agrobacterium rhizogenes R1601. Results: The maximum transgenic hairy roots inducing rate was 82%. Protein purification and mass spectrometry assays showed that the protein expressed in peanut hairy roots was identified as hEGF. Furthermore, Methylthiazolyldiphenyl-tetrazolium bromide assay showed that hEGF promoted HL-7702 liver cells proliferation, which indicate that hEGF has biological activity and non-toxic on human cells. Conclusion: Our results demonstrate the capacity of peanut hairy root cultures as a controlled, sustainable, and scalable production system that can be induced to produce valued human proteins, such as hEGF.

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“…12 Generation of transgenic roots might be a promising approach in future owing to their specific characteristics including higher genetic and biochemical constancy, easy maintenance, fast growth, ability to synthesize a range of secondary metabolites, growth in PGRs-free media, 13,14 high lateral branching and plagiotropism. 15 As previously reported, numerous elements affect the transformation frequency in various plants such as bacterial strain, type of explant, co-cultivation media, co-cultivation period, inoculation media, inoculation temperature, type and concentration of carbohydrate source, seedling age, genotype variation and different nutrient components. [16][17][18][19] In hairy root system, some factors including medium composition, light and temperature have significant impacts on growth and production of natural products, which are frequently species dependent.…”

mentioning

confidence: 83%

“…The rol genes have significant impacts on hairy roots growth and secondary metabolite synthesis by activating the special transcription factors . Generation of transgenic roots might be a promising approach in future owing to their specific characteristics including higher genetic and biochemical constancy, easy maintenance, fast growth, ability to synthesize a range of secondary metabolites, growth in PGRs‐free media, high lateral branching and plagiotropism . As previously reported, numerous elements affect the transformation frequency in various plants such as bacterial strain, type of explant, co‐cultivation media, co‐cultivation period, inoculation media, inoculation temperature, type and concentration of carbohydrate source, seedling age, genotype variation and different nutrient components .…”

Section: Introductionmentioning

confidence: 96%

Potential of the genetically transformed root cultures of Plumbago europaea for biomass and plumbagin production

Beigmohamadi

Movafeghi

Jafari

et al. 2019

Biotechnology Progress

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Plumbago europaea L. is the main source of plumbagin which is a well‐known pharmacological active compound. In this investigation, genetically transformed roots of P. europaea were obtained by improving some factors affecting the efficiency of Agrobacterium rhizoigenes‐mediated transformation such as explant type, A. rhizoigenes strain, bacterial infection period, co‐cultivation period and acetosyringone concentration. The leaf, hypocotyl and stem explants from in vitro grown plantlets were infected with bacterial strains (A4, ATCC15834, MSU440 and A13). The highest transformation rate of 69.3% was achieved after 7–9 days by inoculating A. rhizogenes MSU440 strain onto the 3‐week‐old stem explants followed by a co‐cultivation period of 2 days on a medium containing 100 μM acetosyringone. To investigate the existence of the rolB gene, polymerase chain reaction was carried out using specific primers. Effects of growth media (MS, 1/2 MS, MS‐B5 and ½ MS‐B5), different sucrose concentrations and illumination on biomass production and plumbagin biosynthesis in P. europaea hairy root cultures were analyzed using stem explants after infection with MSU440 strain. ½ MS‐B5 liquid medium containing 30 g L−1 sucrose incubated in the dark resulted in the efficient biomass production of transformed hairy roots (12.5 g fresh weight, 1.8 g dry weight) with 3.2 mg g−1 DW plumbagin accumulation. This procedure provides a framework for large‐scale cultivation of hairy roots for plumbagin production. This is the first report describing the establishment of P. europaea hairy root culture with special emphasis on plumbagin production.

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Ex vitro hairy root induction in detached peanut leaves for plant–nematode interaction studies

Cited by 30 publications

References 53 publications

Early responses to dehydration in contrasting wild Arachis species

Early responses to dehydration in contrasting wild Arachis species

High Efficient Expression and Purification of Human Epidermal Growth Factor in Arachis Hypogaea L.

Potential of the genetically transformed root cultures of Plumbago europaea for biomass and plumbagin production

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