钙螯合和水结合在细菌孢子内休眠和耐热性中的作用

K.S. Rajan, R. Jaw, N. Grecz
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引用次数: 9

摘要

根据孢子结合钙的配位特性,研究了细菌内生孢子的水结合与它们的休眠和耐热性之间的可能关系。在由DPA、甘氨酸、丙氨酸、谷氨酸、丙酰-谷氨酸、甘油三酯和四甘氨酸组成的模型系统中,通过电位平衡pH测量来确定典型细胞质和结构孢子组分钙复合物的稳定性。研究了肉毒杆菌33A Ca++型和H+型孢子在体内的吸水和耐热特性。结果表明,钙和Ca(II)-DPA的络合可能在以下三个水平上对孢子抗性和休眠具有显著的生物学意义:(1)与孢子细胞质池成分络合,符合金属螯合交联细胞质或孢子水泥稳定基本生物大分子的想法;(2)与孢子结构成分络合,与模型肽相互作用表明;(3)与水协调,在孢子中产生明显的脱水环境,这从Ca++形式的孢子的吸水能力大得多而H+形式的孢子的吸水能力小得多可见一斑。有趣的是,在没有金属离子的情况下,DPA本身与二肽、三肽和四肽有一定的相互作用,与氨基酸有微弱但可检测到的相互作用。虽然dpa -肽相互作用的确切模式尚不清楚,但推测其可能参与孢子休眠和抗性的控制是有吸引力的。
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Role of Chelation and Water Binding of Calcium in Dormancy and Heat Resistance of Bacterial Endospores

The possible relationship between the water binding by bacterial endospores and their dormancy and heat resistances has been examined in terms of the coordination characteristics of the spore-bound calcium. Stabilities of the calcium complexes of typical cytoplasmic and structural spore components were determined by potentiometric equilibrium pH measurements in model systems consisting of DPA, glycine, alanine, glutamic acid, alanyl-glutamic acid, triglycine, and tetraglycine. The Ca++-form and H+-form spores of Clostridium botulinum 33A were investigated in vivo with respect to their water sorption and heat-resistance characteristics.

The results suggest that the complexing of calcium and Ca(II)-DPA may be biologically significant for spore resistance and dormancy at the following three levels: (1) complexing with spore cytoplasmic pool constituents consistent with the idea of a metal-chelate cross-linked cytoplasm or spore cement stabilizing the essential biological macromolecules, (2) complexing with structural components of the spore as indicated by the interaction with model peptides, and (3) coordination with water to produce an apparently dehydrated environment in the spore as evident from the much greater watersorption capacity of the Ca++-form spores vs the much smaller water sorption of the H+-form spores.

Interestingly enough, DPA itself, in the absence of metal ion, showed some interaction with di-, tri-, and tetrapeptides and a weak but detectable interaction with amino acids. Although the exact mode of the DPA-peptide interaction is not clear, it is attractive to speculate about its possible involvement in the control of spore dormancy and resistance.

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