Reclamation of Calcareous Sodic Soil by Brevibacterium sp. SOTI06, a Calcite Dissolving Bacteria.

IF 2.6 3区生物学 Q3 MICROBIOLOGY

Current Microbiology Pub Date : 2025-04-04 DOI:10.1007/s00284-025-04205-1

S M Tamilselvi, P M Brindhavani, Chitdeshwari Thiyagarajan, Sivakumar Uthandi

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引用次数: 0

Abstract

Soil degradation due to sodicity is a major constraint to agricultural development in arid and semi-arid regions. The accumulation of exchangeable Na⁺ ions affects soil physicochemical properties, which subsequently increases pH, thus reducing crop yield and nutrient availability. Several practices have been followed for revitalizing salt-affected soils, such as the addition of inorganic or organic amendments. Since most of these soils are calcareous (CaCO₃) in nature, they can serve as a cationic source to release Ca²⁺ to replace the Na⁺ from the clay-complex. Though CaCO₃ is poorly soluble, dissolution can be easily achieved by calcite dissolving bacteria. The present study aimed to evaluate the efficiency of Brevibacterium sp. SOTI06, in reclaiming calcareous sodic soil, along with organic and inorganic inputs through a soil incubation study. The reduction in pH, Na⁺, ESP (Exchangeable sodium percent), and free CaCO₃ during the incubation period confirms the efficiency of amendments. The pH was drastically reduced from 9.10 to 8.20 in gypsum-applied soils. The combined effect of bacterium and press mud reduced higher rates of CaCO₃ in soil (16.6 to 14.5%), with a rise of Ca²⁺ ions (23.5 to 28.7 meq 100 g soil^-1). The mean calcite dissolution was higher in bioinoculant and gypsum-applied soils (9.04%). The SEM (Scanning Electron Microscopy) images confirmed the colonization and calcite dissolution potential of Brevibacterium sp. SOTI06 by pit formation in calcite stones. Hence, this study revealed that the combined application of bioinoculants with organic and inorganic amendments can effectively reclaim calcareous sodic soils.

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一种溶解方解石的细菌 Brevibacterium sp.

盐碱化导致的土壤退化是干旱半干旱地区农业发展的主要制约因素。交换性Na+离子的积累影响土壤理化性质，进而导致pH值升高，从而降低作物产量和养分有效性。为了使受盐影响的土壤恢复活力，已经采取了几种做法，例如添加无机或有机改良剂。由于大多数这些土壤本质上是钙质的（CaCO3），它们可以作为释放Ca2+的阳离子源来取代粘土复合体中的Na+。虽然CaCO3难溶，但解解石溶菌很容易将其溶解。本研究旨在通过土壤培养研究，评价短杆菌SOTI06对钙质碱土的回收效率，以及有机和无机输入。在孵育期间，pH、Na+、ESP（交换钠百分比）和游离CaCO3的降低证实了改性的有效性。施石膏土壤的pH值从9.10急剧下降到8.20。细菌和压泥的联合作用降低了土壤中CaCO3的较高比率（16.6%至14.5%），Ca2+离子的增加（23.5至28.7 meq / 100 g土壤-1）。在施用生物固化剂和石膏的土壤中，方解石的平均溶解度较高（9.04%）。扫描电镜（SEM）图像证实了短杆菌sp. SOTI06在方解石中的定植和溶解潜力。因此，本研究揭示了生物接种剂与有机和无机改良剂的联合应用可以有效地回收钙质碱化土壤。

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来源期刊

Current Microbiology 生物-微生物学

CiteScore

4.80

自引率

3.80%

发文量

380

审稿时长

2.5 months

期刊介绍： Current Microbiology is a well-established journal that publishes articles in all aspects of microbial cells and the interactions between the microorganisms, their hosts and the environment. Current Microbiology publishes original research articles, short communications, reviews and letters to the editor, spanning the following areas: physiology, biochemistry, genetics, genomics, biotechnology, ecology, evolution, morphology, taxonomy, diagnostic methods, medical and clinical microbiology and immunology as applied to microorganisms.