Aluminum toxicity effect on the initial growth of yacon plantlets

Mendes, Tiago Pacheco; Oliveira, Fábio Luiz de; Tomaz, Marcelo Antônio; Rodrigues, Wagner Nunes; Teixeira, Ariany das Graças

doi:10.1590/0034-737x201865020002

Cited by 5 publications

(4 citation statements)

References 27 publications

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“…Restrictions on shoot biomass accumulation due to Al 3+ effect, among other factors, occur due to a reduction in photosynthetic activity. Specifically, Al 3+ interfering with the absorption process of nutrients such as nitrogen and manganese may limit the formation and function of chloroplasts (Konrad et al, 2005;Mendes et al, 2018).…”

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confidence: 99%

The different response of sugarcane genotypes in multiple stress

2018

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Research focused on identify abiotic stress-tolerant genotypes is highly desirable since their use may reduce costs of soil and crop management and productivity losses. The aim of this study was to determine the behavior of 24 sugarcane genotypes under high levels of Al 3+ and Mn 2+ associated with low availability of mineral nutrients. The experiment was carried out under greenhouse condition in a 24 × 2 factorial scheme (24 genotypes × 2 treatments: with and without stress), and four replications in completely randomized design. In the treatment without stress plants were grown in a complete nutrient solution whereas in the treatment with stress a nutrient solution with a high acidity (4.0 ± 0.1) and 5% of its original concentration, as well as a high concentration of aluminum (60 mg L -1 ) and manganese (700 mg L -1 ) was used. The genotypes RB966928, RB855443, IACSP96-3060, SP81-3250, RB867515, CTC 21, RB965902, and IAC91-1099 had their biometric characteristics less affected by the stress, possibly due to the ability to continue the process of cell division and elongation and to maintain meristematic viable regions, hence they were considered as the most tolerant. On the other hand, the genotypes RB965917, CTC 15, CTC17, RB855536, CTC 2, CTC 20, and CTC99-1906 were the most sensitive to stress. Root system was the most affected by stress, with most genotypes showing more than 70% reduction in root biomass. No relationship was observed between tolerance level of genotypes and the maturation cycles. RESUMOPesquisas científicas focadas em identificar genótipos tolerantes a estresse abiótico são altamente desejáveis, pois, o uso desses genótipos permite reduzir custos de manejo do solo, da cultura e perdas de produtividade. O objetivo desse trabalho foi determinar o comportamento de 24 genótipos de cana-de-açúcar sob elevados teores de Al 3+ e Mn 2+ , associado a baixa disponibilidade de nutrientes. O ensaio foi instalado e conduzido em casa de vegetação em delineamento inteiramente casualizado, num esquema fatorial 24x2, correspondendo a 24 genótipos, dois tratamentos (com e sem estresse), com quatro repetições. No tratamento sem estresse, as plantas foram cultivadas em solução nutritiva completa e no com estresse foi utilizada solução nutritiva com elevada acidez (4,0 ± 0,1) e com 5% da sua concentração original, além da elevada concentração de alumínio (60 mg L -1 ) e manganês (700 mg L -1 ). Os genótipos RB966928, RB855443, IACSP96-3060, SP81-3250, RB867515, CTC 21, RB965902 e IAC91-1099 foram os que tiveram suas características biométricas menos afetadas pelo estresse, possivelmente devido a capacidade de continuarem o processo de divisão e elongação celular e manterem regiões meristemáticas viáveis, dessa forma, foram considerados os mais tolerantes. Por outro lado, os genótipos RB965917, CTC 15, CTC17, RB855536, CTC 2, CTC 20 e CTC99-1906 foram os mais sensíveis ao estresse. O sistema radicular foi o mais afetado pelo estresse sendo que a maioria dos genótipos apresentaram mais de 70% de redução da biomas...

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confidence: 99%

The different response of sugarcane genotypes in multiple stress

2018

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“…Aluminum can also affect chlorophyll biosynthesis by inhibiting δaminolavulinic acid dehydratase activity, which accounts for chlorophyll molecule and cytochrome formation (Cunha Neto et al 2020). Therefore, higher concentrations of this ion can change chlorophyll and carotenoid composition, which can limit plant metabolic potential (Mendes et al 2018).…”

Section: Aluminummentioning

confidence: 99%

Can species Cedrela fissilis Vell. be used in sites contaminated with toxic aluminum and cadmium metals?

Kuinchtner¹,

Oliveira²,

Aguilar³

et al. 2021

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“…CUNHA NETO et al Lana, 2013). Aluminum also causes oxidative damage by inhibiting aminolaevulinic acid, which plays an important role in the synthesis of chlorophyll (Mendes et al, 2018).…”

Section: Cernementioning

confidence: 99%