A vacuolar H(+)-pyrophosphatase differential activation and energy coupling integrate the responses of weeds and crops to drought stress.

BACKGROUND: Cyperus rotundus L. is a C4 weed of large vegetative and reproductive vigor endowed with competitive advantages over most crop species mainly under adverse environmental conditions. Vacuole functions are critical for the mechanisms of drought resistance, and here the modulation of the primary system of vacuolar ion transport is investigated during a transient water stress imposed to this weed and to C4 crop species (Zea mays L.). METHODS: The vacuolar H(+) pumps, the H(+)-ATPase and H(+)-PPiase, expression, activities and the energy coupling were spectrophotometrically investigated as key elements in the differential drought-resistance mechanisms developed by weeds and crops. RESULTS: In C. rotundus tonoplasts, ATP hydrolysis was more sensitive to drought than its coupled H(+) transport, which was in turn at least 3-folds faster than that mediated by the H(+)-PPiase. Its PPi hydrolysis was only slightly affected by severe water deficit, contrasting with the disruption induced in the PPi-dependent H(+)-gradient. This effect was antagonized by plant rehydration as the H(+)-PPiase activity was highly stimulated, reassuming a coupled PPi-driven H(+) pumping. Maize tonoplasts exhibited 2-4 times lower hydrolytic activities than that of C. rotundus, but were able to overactivate specifically PPi-dependent H(+) pumping in response to stress relief, resulting in an enhanced H(+)-pumps coupling efficiency. CONCLUSION: These results together with immunoanalysis revealed profiles consistent with pre- and post-translational changes occurring on the tonoplast H(+)-pumps, which differ between weeds and crops upon water deficit. GENERAL SIGNIFICANCE: The evidences highlight an unusual modulation of the H(+)-PPiase energy coupling as a key biochemical change related to environmental stresses adaptive capacity of plants.

Adição de ácido cítrico potencializa a ação de ácidos húmicos e altera o perfil protéico da membrana plasmática em raízes de milho / Citric acid addition improve humic acids action and change proteins profile from plasma membrane of maize roots

A promoção do crescimento vegetal pelos ácidos húmicos tem sido atribuída a ações similares a hormônios, devido à promoção do desenvolvimento e proliferação das raízes, resultando numa absorção mais eficiente de água e nutrientes. O objetivo deste trabalho foi analisar as mudanças na arquitetura radicular em plântulas de milho e no perfil de proteínas da membrana plasmática (MP) promovidas pelo tratamento com ácidos húmicos (AH) isolados de vermicomposto (20mg C L-1). O efeito da adição de ácido cítrico (AC), importante ácido orgânico presente nos exudados radiculares, sobre a bioatividade destes AH também foi investigada. Foram analisados o comprimento da raiz principal, o número de sítios de mitose, o número e comprimento de raízes laterais e a área radicular total. Para a análise do perfil protéico, vesículas da MP de células de raízes foram obtidas por fracionamento celular e as proteínas analisadas por eletroforese uni (1D) e bidimensional (2D). Observou-se que a adição de AC (0,005mM) aos AH estimularam a promoção do crescimento das raízes laterais (126 por cento), da área radicular (58 por cento) e do número de raízes laterais (55 por cento) em relação às plantas controle. A atividade da bomba de H+ da membrana plasmática, analisada como marcador bioquímico de indução do mecanismo do crescimento ácido, também foi significativamente estimulada (374 por cento) pela solução húmica suplementada com AC. O perfil protéico da MP revelou uma supressão da expressão das proteínas nesta membrana, induzida pelo tratamento com AH e, na presença de AC, esse efeito foi ainda mais evidente. Os resultados obtidos corroboram o mecanismo proposto para a bioatividade de AH no qual a ação de ácidos orgânicos exudados pelas plantas, tais como o AC, promove o rompimento da associação supramolecular dessas substâncias, tornando as moléculas bioativas presentes nos agregados húmicos mais acessíveis aos receptores celulares das raízes.

The plant growth stimulation by humic acids (HA) has been attributed to a hormone-like effect as promoting the root development and proliferation, resulting in a more efficient water and nutrient absorption. This research aims to investigate how the humic acids isolated from vermicompost (20mg L-1) can modify the root architecture and the plasma membrane (PM) protein patterns in maize roots. It was also analyzed the effect of the citric acid (CA), an organic acid present in root exudates. The changes induced in the corn root system were estimated by measuring the taproot length, the amount of root mitotic sites and lateral roots, and the total root area. Plasma membrane vesicles were purified by cell fractionation and the protein patterns were analyzed by uni (1D) and bidimensional (2D) electrophoresis. The results show that the HA in solution with CA (0.005mM) increases the lateral root growth promotion (126 percent), the root area (58 percent), and the number of lateral roots (55 percent). The activity of the plasma membrane H+ pump, analyzed as a marker of the induction of the acid growth mechanism, was also enhanced (374 percent) by the humic solution supplemented with CA. Expression of several plasma membrane proteins was inhibited when plants were treated with HA and this effect was more pronounced upon CA supplementation. The obtained results corroborate the proposed mechanism for the HA bioactivity, by which under the action of root-exuded organic acids, such as CA, a disruption of the HA macrostructure is promoted releasing bioactive molecules presented in the humic aggregates, which becomes more accessible to the root cell receptors.