Aims This study aimed to investigate how the colonization numbers of nitrogen-fixing, phosphate-solubilizing, and potassium-solubilizing bacteria affect the physiological traits of Malus sieversii and to ascertain the abundance of rhizosphere microorganisms conducive to their thriving in Xinjiang, China.
Methods In this study, we utilized the rhizosphere soil of M. sieversii sourced from eight distinct natural populations in Xinjiang as our primary experimental materials. Our objectives included the isolation and quantification of nitrogen-fixing bacteria (NFB), organic phosphate-solubilizing bacteria (oPSB), inorganic phosphate-solubilizing bacteria (iPSB), and potassium-solubilizing bacteria (KSB). Additionally, we assessed the physiological characteristics of M. sieversii leaves, as well as determined the nitrogen, phosphorus, and potassium content in both the leaves and the soil.
Important findings (1) A statistically significant difference was observed in the total count of four functional bacterial strains colonizing the rhizosphere across eight distinct populations of M. sieversii. The population in Wild Fruit Forest, Xinyuan County exhibited the highest cumulative count of oPSB, iPSB, NFB, and the four functional strains, while the population in Nazi Work Team, Gongliu County, displayed the highest count of KSB. (2) Both the cumulative count of the four functional bacterial strains and the count of PSB exhibited a positive correlation with changes in catalase activity within the leaves. Simultaneously, the count of KSB demonstrated a positive correlation with peroxidase activity. These findings support the existence of a correlation between the population of rhizosphere bacteria activating nitrogen, phosphorus, and potassium in M. sieversii and its resistance to external factors. (3) Regarding nutrient uptake, the counts of oPSB corresponded to phosphorus and nitrogen levels in the leaves, while iPSB counts aligned with soil phosphorus content. Additionally, both oPSB and NFB counts correlated with soil nitrogen content, while KSB counts reflected the potassium content in both leaves and soil. (4) Optimal nutritional growth of M. sieversii occurred with bacterial colonization counts of 7.08 × 104 CFU·g-1 (NFB), 2.7 × 107 CFU·g-1 (PSB), and 4.98 × 105 CFU·g-1 (KSB), respectively, resulting in higher nitrogen, phosphorus, and potassium levels in both leaves and soil.