Basic and applied aspects of metabolic diversity: The phosphoenolpyruvate node

The phosphoenolpyruvate (PEP) node represents a metabolic crossroad where carbon is distributed into several metabolic pathways. This node is specially important for the industrial production of several metabolites. Depending on the organism and its habitat, the enzymes that utilize PEP are regulated by different effectors, and each branch of the node is important in PEP consumption. In this review we will focus our attention on the metabolic diversity of this node.     

Basic and applied aspects in the microbial degradation of azo dyes

Azo dyes are the most important group of synthetic colorants. They are generally considered as xenobiotic compounds that are very recalcitrant against biodegradative processes. Nevertheless, during the last few years it has been demonstrated that several microorganisms are able, under certain environmental conditions, to transform azo dyes to non-colored products or even to completely mineralize them. Thus, various lignolytic fungi were shown to decolorize azo dyes using ligninases, manganese peroxidases or laccases. For some model dyes, the degradative pathways have been investigated and a true mineralization to carbon dioxide has been shown. The bacterial metabolism of azo dyes is initiated in most cases by a reductive cleavage of the azo bond, which results in the formation of (usually colorless) amines. These reductive processes have been described for some aerobic bacteria, which can grow with (rather simple) azo compounds. These specifically adapted microorganisms synthesize true azoreductases, which reductively cleave the azo group in the presence of molecular oxygen. Much more common is the reductive cleavage of azo dyes under anaerobic conditions. These reactions usually occur with rather low specific activities but are extremely unspecific with regard to the organisms involved and the dyes converted. In these unspecific anaerobic processes, low-molecular weight redox mediators (e.g. flavins or quinones) which are enzymatically reduced by the cells (or chemically by bulk reductants in the environment) are very often involved. These reduced mediator compounds reduce the azo group in a purely chemical reaction. The (sulfonated) amines that are formed in the course of these reactions may be degraded aerobically. Therefore, several (laboratory-scale) continuous anaerobic/aerobic processes for the treatment of wastewaters containing azo dyes have recently been described.     

1-磷酸鞘氨醇与相关疾病的研究进展

1-磷酸鞘氨醇(sphingosine-1-phosphate,S1P)是一种重要的生物活性鞘脂类代谢物,其介导的细胞传导途径(SphK-S1P-S1PRs信号通路)参与各种生理病理过程,调节人体生长发育。现发现5种S1P受体(S1PR1-S1PR5)广泛分布于人体各个组织,其形成的交联信号通路影响着细胞的迁移、粘附、存活和增殖,并干预着肿瘤、糖尿病、心血管疾病等诸多疾病的发生发展过程。因而S1PRs的研究对治疗疾病提供了新的靶点和方向,将其应用于临床,实施个体化治疗方案,成为当今热门的研究课题之一。     

Mycoplasma bovis shares insertion sequences with Mycoplasma agalactiae and Mycoplasma mycoides subsp. mycoides SC: Evolutionary and developmental aspects

Three new insertion elements, ISMbov1, ISMbov2 and ISMbov3, which are closely related to ISMag1 (Mycoplasma agalactiae), ISMmy1 and IS1634 (both Mycoplasma mycoides subsp. mycoides SC), respectively, have been discovered in Mycoplasma bovis, an important pathogen of cattle. Southern blotting showed that the genome of M. bovis harbours 6-12 copies of ISMbov1, 11-15 copies of ISMbov2 and 4-10 copies of ISMbov3, depending on the strain. A fourth insertion element, the IS30-like element, is present in 4-8 copies. This high number of IS elements in M. bovis, which represent a substantial part of its genome, and their relatedness with IS elements of both M. agalactiae and M. mycoides subsp. mycoides SC suggest the occurrence of two evolutionary events: (i) a divergent evolution into M. agalactiae and M. bovis upon infection of different hosts; (ii) a horizontal transfer of IS elements during co-infection with M. mycoides subsp. mycoides SC and M. bovis of a same bovine host.     

Gliding motility of Mycoplasma sp. nov. strain 163K.

The gliding movements of Mycoplasma sp. nov. strain 163K cells were characterized by photomicrographic and microcinematographic studies. The capability of gliding proved to be a very stable property of strain 163K. Cells were continuously moving, without interruption by resting periods, on glass as well as on plastic surfaces covered with liquid medium. Gliding cells always moved in the direction of their headlike structure; their course did not indicate any preference for a certain direction. Under appropriate growth conditions, cells showed linear and circular movements. Under inadequate conditions, cells glided in narrow circles or entered into zigzag trembling and tumbling movements. Organisms glided as single cells, in pairs, and in multicellular configurations. Movement patterns and gliding velocity were significantly affected by the cultivation and preparation time, the medium viscosity, and the storage and observation temperature. The number of passages on artificial media and the composition of the media used did not have a striking influence on gliding motility, but movements were effectively inhibited by homologous antiserum. The data obtained suggest that at least some of the structures associated with gliding are heat sensitive and located on the cell surface, that the gliding mechanism requires an intact energy metabolism, and, finally, that gliding motility is an extremely stable genetic property of Mycoplasma sp. nov. strain 163K.     

Active K+ transport in Mycoplasma mycoides var. Capri. Net and unidirectional K+ movements.

Analysis of the cation composition of growing Mycoplasma mycoides var. Capri indicates that these organisms have a high intracellular K+ concentration (Ki: 200--300 mM) which greatly exceeds that of the growth medium, and a low Na+ concentration (Na+i: 20 mM). Unlike Na+i,K+i varies with cell aging. The K+ transport properties studied in washed organisms resuspended in buffered saline solution show that cells maintain a steady and large K+ concentration gradient across their membrane at the expense of metabolic energy mainly derived from glycolysis. In starved cells, K+i decreases and is partially compensated by a gain in Na+. This substitution completely reverses when metabolic substrate is added (K+ reaccumulation process). Kinetic analysis of K+ movement in cells with steady K+ level shows that most of K+ influx is mediated by an autologous K+-K+ exchange mechanism. On the other hand, during K+ reaccumulation by K+-depleted cells, a different mechanism (a K+ uptake mechanism) with higher transport capacity and affinity drives the net K+ influx. Both mechanisms are energy-dependent. Ouabain and anoxia have no effect on K+ transport mechanisms; in contrast, both processes are completely blocked by dicyclohexylcarbodiimide, an inhibitor of the Mg2+ -dependent ATPase activity.     

I. P. Pavlov and K. Lorenz

In the thirtieth, the founder of ethology Austrian zoologist Konrad Lorenz put forward the new theory of behavior, which was met with considerable resistance of the dominant views on the mechanisms of behavior, including Pavlov's concept. From his first theoretical works and later on Lorenz debated with Pavlov. However, these debates were not reduced to a disagreement. He appreciated greatly the scientific contribution of Pavlov, and the ideas of the Russian physiologist were often the starting point of his own speculations. His polemics with Pavlov differed very much from his uncompromising controversies with behaviorists. When Lorenz compared Pavlov's views with behaviorism, he often preferred Pavlov's ideas. Lorenz also draw some parallels between the Pavlov's understanding of behavior and the ethological approach. Lorenz's discussion with Pavlov about the nature of conditioned reflex is of particular interest, since it stimulated Lorenz to develop the theory of this phenomenon.