Likewise, the higher solubilization and higher production of organic acids in the presence of TCP could be attributed to its amorphous nature with simple structure and absence of any free carbonates as compared to the crystalline lattice structure TSA HDAC research buy of the rock phosphates [25]. Cluster analysis of organic acid profiles generated different groups
revealing inter and intra-specific variation in the production of organic acids by Pseudomonas strains (Fig. 2). The strains clustered together and those standing outside the clusters or sub-clusters belonged to different Pseudomonas species characterized previously by 16S rRNA gene sequencing [8, 9]. The strains standing outside the clusters differed qualitatively and/or quantitatively from other strains in the production of organic acids (Tables 2, 3, 4, 5). The results implied that Pseudomonas strains are independent of their genetic relatedness in their phosphate-solubilizing ability and organic acid production even under similar set of culture conditions. Phosphate solubilization is a complex phenomenon which depends on the nutritional, physiological and growth GS-4997 purchase conditions of the culture [26]. The enhanced growth and higher N, P and K contents in maize with PSB treatments underlined the
advantage of phosphate-solubilizing https://www.selleckchem.com/products/a-1210477.html activity of microorganisms for plant growth promotion (Table 6 and 7). The increased growth and P uptake have been reported
on PSB inoculations with Pseudomonas sp. and Serratia marcescens in maize [17], Pseudomonas fluorescens in peanut [27], Bacillus circulans in mungbean [28] and Pseudomonas sp. in wheat [29]. The TCP solubilization in soil by fluorescent Pseudomonas strains as evidenced by in vitro TCP solubilization, increased soil P availability and higher plant P content would be useful particularly in the cold deserts of Lahaul and Spiti where soil P deficiency is attributed mainly to the reaction next of P with calcium carbonate and calcium sulphate forming insoluble di- and tricalcium phosphates. The rock phosphates recommended for acid soils are reportedly not effective in alkaline soils as P source for the crops [30]. The significantly higher plant growth and N, P, and K content in plant tissues and soil with some PSB treatments over NPSSPK might be due to the immobilization of applied P by native soil microbiota and physico-chemical reactions in the soil. The increased and continuous P availability in the soil promotes biological nitrogen fixation [27]. No correlation among TCP solubilization, production of organic acids and plant growth promotion could be established as the highest solubilization and plant growth promoting activity was observed for P. trivialis BIHB 745 not showing the highest organic acid production. However, the lowest organic acid production and plant growth promotion by Pseudomonas sp.