Wehrmann A, Phillipp B, Sahm H, Eggeling L
Forschungszentrum Jülich GmbH, Germany.
J Bacteriol. 1998 Jun;180(12):3159-65. doi: 10.1128/JB.180.12.3159-3165.1998.
In eubacteria, there are three slightly different pathways for the synthesis of m-diaminopimelate (m-DAP), which is one of the key linking units of peptidoglycan. Surprisingly, for unknown reasons, some bacteria use two of these pathways together. An example is Corynebacterium glutamicum, which uses both the succinylase and dehydrogenase pathways for m-DAP synthesis. In this study, we clone dapD and prove by enzyme experiments that this gene encodes the succinylase (M(r) = 24082), initiating the succinylase pathway of m-DAP synthesis. By using gene-directed mutation, dapD, as well as dapE encoding the desuccinylase, was inactivated, thereby forcing C. glutamicum to use only the dehydrogenase pathway of m-DAP synthesis. The mutants are unable to grow on organic nitrogen sources. When supplied with low ammonium concentrations but excess carbon, their morphology is radically altered and they are less resistant to mechanical stress than the wild type. Since the succinylase has a high affinity toward its substrate and uses glutamate as the nitrogen donor, while the dehydrogenase has a low affinity and incorporates ammonium directly, the m-DAP synthesis is another example of twin activities present in bacteria for access to important metabolites such as the well-known twin activities for the synthesis of glutamate or for the uptake of potassium.
在真细菌中,存在三种略有不同的合成内消旋二氨基庚二酸(m-DAP)的途径,m-DAP是肽聚糖的关键连接单元之一。令人惊讶的是,由于未知原因,一些细菌同时使用其中两种途径。例如谷氨酸棒杆菌,它在合成m-DAP时同时使用琥珀酰化酶途径和脱氢酶途径。在本研究中,我们克隆了dapD,并通过酶实验证明该基因编码琥珀酰化酶(相对分子质量=24082),启动了m-DAP合成的琥珀酰化酶途径。通过基因定向突变,使dapD以及编码去琥珀酰化酶的dapE失活,从而迫使谷氨酸棒杆菌仅使用m-DAP合成的脱氢酶途径。这些突变体无法在有机氮源上生长。当提供低铵浓度但过量碳源时,它们的形态会发生根本改变,并且与野生型相比,它们对机械应力的抵抗力更弱。由于琥珀酰化酶对其底物具有高亲和力并使用谷氨酸作为氮供体,而脱氢酶具有低亲和力并直接掺入铵,m-DAP合成是细菌中存在的获取重要代谢物的双重活性的另一个例子,例如众所周知的谷氨酸合成或钾摄取的双重活性。