At the windbreak site,we found high

At the windbreak site,we found higherwheat aboveground biomass
and number of grains per spike in the agroforestry than in conventional
agricultural system soils for the threewater treatments. This result suggests
that the beneficial effects of agroforestry soil on wheat growth
most likely occurred during its reproductive period, when the number
of grains per spike was determined. Soil extractable-P (drought and
flooding treatments) and microbial biomass (control), which tended
to be higher in the agroforestry soils, were positively related to wheat
biomass (Fig. 4). Power et al. (1961) found that increasing P availability
may result in higher nutrient uptake and wheat dry matter production
at all growth stages, without interaction with different soil moisture
conditions. Other soil properties were not considered in this study,
but may have had a positive feedback on wheat production. These include
soil cation exchange capacity and base cation concentrations
(Moreno et al., 2007), microbial diversity (Loreau, 2001), soil enzyme
activities (Mungai et al., 2005), and AM fungi composition and abundance
(Plenchette et al., 2005). Grain yield did not differ between
both types of system, as observed for wheat biomass and number of
grains per spike at the windbreak site. This result may be due to a slight
compensatory increase in 1000-grain weight in the conventional agricultural
system (10%, although not significant). Indeed, reducing the
number of grains per spike often results in earlier mobilization of
non-structural reserve carbohydrates from the stem and leaf sheaths,
which increases the
and nutrient availability limiting the growth rate of resistant microbial
cells. Yet, there are clear indications that potential microbial growth
rates and nutrient availability were substantially more limiting at the
tree-based intercropping than at the windbreak site (Table 1).