Vl. Quartin et al., Phosphorus deficiency is responsible for biomass reduction of triticale innutrient solution with aluminum, J PLANT NUT, 24(12), 2001, pp. 1901-1911
Plants of triticale (X Triticosecale, Wittmack) cultivars Arabian, Beagle,
and TTE 9201 were submitted to aluminum (Al) treatments applied as Al(SO4)(
3) . 16H(2)O in a nutrient solution adjusted to pH 4, in concentrations of
0, 370, 555, and 740 muM. The plants were harvested at the end of the biolo
gical cycle showing stronger dry matter inhibition in the shoot than in the
root. The increasing order of tolerance among cultivars was Arabian, Beagl
e, and TTE 9201. The concentration of phosphorus (P), calcium (Ca), and mag
nesium (Mg) decreased in the leaves whereas manganese (Mn) and zinc (Zn) in
creased. The Al in the shoot represents 0.5% of the root concentration. The
translocation of P and nitrogen (N) was also affected because the fraction
of these minerals found in the root or shoot (respectively, for P and N) w
as higher in the Al-treated plants. The relationship between biomass produc
ed and a range of P, Ca, and Mn concentrations in leaves was obtained from
another set of experiments designed to define critical foliar concentration
s of these elements associated with biomass inhibition. These critical conc
entrations were 3 mg g(-1) dw for P in young plants and 1.5 mg g(-1) dw in
mature plants, 1-2 mg g(-1) dw for Ca, and 2.5 mg g(-1) dw for Mn toxicity.
Such concentrations are valuable for diagnosis of the mineral element whic
h probably is limiting growth in acid soils which currently have problems w
ith excess Al and Mn and low Ca and P, Phosphorus deficiency was probably t
he most important limiting factor in acid nutrient solutions with Al that h
ave been used in previous and present experiments with triticale.