[Amine neuromediators, their precursors, and oxidation products in the culture of Escherichia coli K-12].

Growth dynamics of the synthesis of monoamine neuromediators serotonin, norepinephrine, and dopamine in Escherichia coli K-12 was investigated for the first time using high performance liquid chromatography with electrodetection. Maximum (micromolar) concentrations of these compounds were detected in E. coli cells during the early growth phases; their intracellular content decreases after the transition to late growth phases. E. coli biomass contains the substances DOPA and 5-hydroxytryptamine that serve in animal cells as neuromediator precursors and the products of their oxidative deamination. Presumably, the biosynthesis and degradation of monoamine neuromediators in bacterial cells involves enzyme systems analogous to those typical of animals. The culture fluid of E. coli contains micromolar concentrations of DOPA and nanomolar of serotonin, dopamine, and norepinephrine during the late growth phase. These concentrations are sufficient for animal/human receptors to bind them. This article deals with the potential biotechnological applications of the data obtained.

[Effects of monoamine neuromediators on the growth-related variables of Escherichia coli K-12].

The monoamine neuromediators serotonin (5-HT), histamine, dopamine (DA), and norepinephrine (NE), added to an Escherichia coli K-12 strain MC 4100 culture upon inoculation, stimulate cell proliferation (determined from CFU formation) and biomass accumulation (monitored nephelometrically) during the late lag phase and the early exponential growth phase. These effects are less significant in the late exponential and stationary phase cultures. According to the concentration dependence of the stimulatory effects, the neuromediators can be classified into two groups: (i) the catecholamines DA and NE, whose effects increase almost linearly with increasing concentrations within the range of 0.1-100 microM, and (ii) histamine and 5-HT, which are characterized by bell-shaped concentration dependence curves with maxima at 0.1 (histamine) and 1 microM (5-HT). On an agar-containing medium, the growing E. coli population includes solitary cells and compact cell groups (microcolonies). In this system, both tested catecholamines exert a relatively weak stimulatory influence that manifests itself as an increase in the number of both solitary cells and cell groups, and occurs at concentrations of 10 microM and higher. In analogy to the culture grown on the liquid medium, 5-HT and histamine are distinguished by nonlinear concentration dependence curves: their effects peak at 0.1 microM (histamine) or 1 microM (5-HT); an increase in the neuromediator concentrations results in a decrease in effects that are enhanced by further increasing the concentrations to the submillimolar range. DA increases the percentage of solitary cells, whereas the other tested amines promote cell group formation. The results are interpreted in terms of specific (probably receptor-dependent) mechanisms of action of the neuromediators involved.

[Population organization and communication in microorganisms].

This review concentrates on the history of the subfield of microbiology referred to as the population organization- and communication-related research direction (POCRRD). The focal points of POCRRD include intercellular interactions, information exchange between cells, and multicellular structures (colonies, biofilms, flocs, etc.). Special attention in this review is given to the contribution of Russian scientists to the development of POCRRD. In terms of POCRRD, microorganisms are viewed as social creatures that constantly communicate and form supraorganismic, intrinsically heterogeneous systems.

[Effect of serotonin (5-hydroxytryptamine) on the growth and differentiation of microorganisms]. / Deistvie serotonina (5-oksitriptamina) na rost i differentsiatsiiu mikroorganizmov.

Serotonin (5-hydroxytryptamine), a neurotransmitter and social behavior factor in higher animals, accelerates culture growth and induces cell aggregation in Escherichia coli and Rhodospirillum rubrum at concentrations of 2 x 10(-7)-2 x 10(-5)M. In the myxobacterium Polyangium sp., 10(-6)-10(-5)M serotonin stimulates cell aggregation and myxospore formation. At concentrations over 20 microM, serotonin induces the opposite effect: it inhibits cell aggregation and microbial culture growth. Serotonin at these concentrations also inhibits the light-dependent membrane potential generation in Rsp. rubrum (the data were obtained by the method of penetrating ions). Therefore, the above effects can be due to the elimination of the transmembrane electrical gradient by serotonin. As for micromolar serotonin concentrations, their effects presumably result from the specific action of serotonin as an intercellular communication agent accelerating and possibly synchronizing the development of the cell population.