Performance of products was affecte

Performance of products was affected by soil conditions. The
effect of products on growth wasmore pronounced in Vertisol and
this was consistent under both nursery and field conditions. Compared
to Rhodic Ferralsol (P level of 7 ppm) and Humic Nitisol (P
level of 8.5 ppm), Vertisol had lower P levels (3 ppm), suggesting
soil P level as an important factor influencing performance of products.
This implies that all the products perform best under low
P conditions. There is a lot of existing evidence on the effects of
mycorrhizae at low P levels, solubilization of P by Bacillus based
products, and limited information on Trichorderma and P. Beneficial
effects of bacterial inoculation are optimal in nutrient deficient
soils than in nutrient rich soil (Egamberdiyeva, 2007). In pot experiments
with calcareous calcisol soil taken from Sirdarya, Uzbekistan
and loamy sand from Muencheberg, Germany, Egamberdiyeva
(2007), found that bacteria strains Pseudomonas alcaligenes PsA15,
Bacillus polymyxa BcP26 and Mycobacterium phlei MbP18 had a
much better stimulatory effect on plant growth and nitrogen (N),
phosphorus (P) and potassium (K) uptake of maize in nutrient
deficient calcisol soil. Their stimulatory efficiency reduced in relatively
rich loamy sand soil where bacterial inoculants stimulated
only root growth and N, K uptake of roots. These results suggest
that plant growth stimulating efficiency of bacterial inoculants is
affected by soil nutritional conditions. The bacterial inoculation
has a much better stimulatory effect on plant growth in nutrient
deficient soil than in nutrient rich soil. This may explain the low
response (for example 15.0% increase in shoot weight) to Bacillus
inoculation by plants established in the Humic Nitisol and conventional
media. Benefits of mycorrhiza are greatest in P-deficient
soils and decrease as soil phosphate levels increase (Schubert et al.,
1986). In banana cropping systems, the soil population density of
AM fungi was affected by soil texture and P, agro-chemical use and
soil wetness. Sandy soils were associated with lower and clay soils
with higher AM fungi soil populations in intensive banana cultivation
systems of Martinique (Declerck et al., 1999). Low P was
associated with higher AM fungal populations in soil and roots
(Declerck et al., 1999). This may therefore explain the increased
plant growth observed with inoculation of plants in the Vertisol
which is a clay soil. The development of mycorrhizal relationships
was found to be greatest when soil P levels were at 50 mg/kg
(Schubert et al., 1986). The P level in the conventional media
(56 mg/kg) was slightly above 50 mg/kg thresh hold thus providing
better conditions for the mycorrhizae to function and may explain
the enhanced shoot dry weight (by 11.5%), number of secondary
roots (by 7.0%) and root length (by 1.1 times) compared to the control
in the conventional media under green house conditions and
the enhanced (92.0% increase) by addition of inorganic phosphate
as evidenced by the high apparent volume of plants established in
the conventional practice under field conditions in the Rhodic Ferralsol.
This prompts further investigation in to the combining of
appropriate doses of inorganic fertilizers with microbial inoculants
for optimal plant growth and performance.
Altomare et al. (1999) and Yedida et al. (1999) noted that
Trichoderma harzianum increases the solubility of phosphate and
micronutrients such as zinc, copper, iron and manganese ions
which have low solubility and stimulates secretion of exogenous
enzymes, siderophores (Jalal et al., 1987) and vitamins (Inbar et al.,
1994; Kleifeld and Chet, 1992). These all play an important role in
plant growth (Altomare et al., 1999). The increase in plant growth
as a result of Trichoderma inoculation may also be explained by
the high organic carbon level (3. 7%) in the Vertisol compared to
the Rhodic Ferralsol (1.0%) and Humic Nitisol (2.63%). This may
explain the over 60% increase in growth observed with Trichoderma
inoculated plants in the Vertisol compared to the conventional
practice which had a C level of 5.8%. Okoth et al. (2007), investigating
the effect of land use system on occurrence and distribution
of Trichoderma found that physical and chemical factors influenced
the occurrence of Trichoderma spp. Forests soils were high in C,
N, Fe, organic matter and Mg and this favored the occurrence of
the fungus (Okoth et al., 2007). Another possible explanation for
the increased plant growth could be the ability of Trichoderma to
promote growth root development, a factor that was not easily
evaluated under field conditions since it involves destructive harvesting
of the plant. Okoth et al. (2011). reported an increase of
primary root length and root branching in maize and beans inoculated
with Trichoderma. Harman (2000) found that a strain of T.
harzianum induced about twice as many deep roots in maize as
compared to non-inoculated control. T. harzianum strains were also
reported to have increased the height, shoot and root dry weight by
26.0, 14.0, and 29.0% respectively in tomato seedlings transplanted
into pots in the green-house (Ozbay and Newman, 2004).
4.3. Mycorrhizal colonization