Growth rate,sugar consumption,chlortetracycline production and anhydrotetracycline oxygenase activity inStreptomyces aureofaciens

The relationship between the activity of ATC oxygenase, CTC production and growth rate was investigated in a low-producing strain ofStreptomyces aureofaciens, closely related to the wildtype strain, and in a higher-producing variant. Different growth rates were achieved by using glucose, fructose and sucrose as carbon sources. Activity of the enzyme and CTC yield in both strains were inversely proportional to the rate of sugar utilization but in the higherproducing variant sugar utilization was slower than in the low-producing strain. The expression of ATC oxygenase was less sensitive to “catabolite repression” in the higherproduc ing strain. BT, a stimulator of CTC production, markedly inhibited growth of the higher-producing variant in a medium with slowly utilized sugars (fructose and sucrose) but had little effect on growth of the lowproducing strain. It also increased the level of ATC oxygenase in both strains under all experimental conditions. It could be established that there was no obligatory relationship between the increase of antibiotic synthesis and the increase of enzyme activity.     

From Microscopic to Macroscopic Descriptions of Cell Migration on Growing Domains

Cell migration and growth are essential components of the development of multicellular organisms. The role of various cues in directing cell migration is widespread, in particular, the role of signals in the environment in the control of cell motility and directional guidance. In many cases, especially in developmental biology, growth of the domain also plays a large role in the distribution of cells and, in some cases, cell or signal distribution may actually drive domain growth. There is an almost ubiquitous use of partial differential equations (PDEs) for modelling the time evolution of cellular density and environmental cues. In the last 20 years, a lot of attention has been devoted to connecting macroscopic PDEs with more detailed microscopic models of cellular motility, including models of directional sensing and signal transduction pathways. However, domain growth is largely omitted in the literature. In this paper, individual-based models describing cell movement and domain growth are studied, and correspondence with a macroscopic-level PDE describing the evolution of cell density is demonstrated. The individual-based models are formulated in terms of random walkers on a lattice. Domain growth provides an extra mathematical challenge by making the lattice size variable over time. A reaction–diffusion master equation formalism is generalised to the case of growing lattices and used in the derivation of the macroscopic PDEs.     

Opposite fates of the purine metabolite allantoin under water and nitrogen limitations in bread wheat

Plant Molecular Biology - Degradation of nitrogen-rich purines is tightly and oppositely regulated under drought and low nitrogen supply in bread wheat. Allantoin is a key target metabolite for...     

Cytoskeletal Components Define Protein Location to Membrane Microdomains

The plasma membrane is an important compartment that undergoes dynamic changes in composition upon external or internal stimuli. The dynamic subcompartmentation of proteins in ordered low-density (DRM) and disordered high-density (DSM) membrane phases is hypothesized to require interactions with cytoskeletal components. Here, we systematically analyzed the effects of actin or tubulin disruption on the distribution of proteins between membrane density phases. We used a proteomic screen to identify candidate proteins with altered submembrane location, followed by biochemical or cell biological characterization in Arabidopsis thaliana. We found that several proteins, such as plasma membrane ATPases, receptor kinases, or remorins resulted in a differential distribution between membrane density phases upon cytoskeletal disruption. Moreover, in most cases, contrasting effects were observed: Disruption of actin filaments largely led to a redistribution of proteins from DRM to DSM membrane fractions while disruption of tubulins resulted in general depletion of proteins from the membranes. We conclude that actin filaments are necessary for dynamic movement of proteins between different membrane phases and that microtubules are not necessarily important for formation of microdomains as such, but rather they may control the protein amount present in the membrane phases.Living cells need borders and molecular compartments for biochemical reactions and storage of metabolites. The plasma membrane therefore is a prerequisite for the evolution of different life forms. It consists of a phospholipid bilayer into which proteins and special lipid species such as sterols, sphingolipids, and glycolipids are inserted. The first complex model of plasma membrane was proposed in 1972 by Jonathan Singer and Garth Nicolson (1), replacing the concept of the plasma membrane as a strict protein–lipid–protein sandwich that was generally accepted until then. In Singer and Nicolson''s model, the cell membrane is a two-dimensionally oriented viscous solution in which the membrane constituents are orientated in the most thermodynamically favorable manner, hiding hydrophobic hydrocarbon chains inside the lipid bilayer and exposing polar and ionic groups to the aqueous phase. This fluid mosaic model also implied that membrane proteins as well as lipid components are distributed in a homogeneous lipid bilayer at long range, but they can form specific aggregates and phases at short range, which were also termed “lipid rafts” or membrane microdomains.Over the past 30 years, it has become evident that the plasma membrane is not such a homogeneous structure as it was initially proposed. We now know that the lipid bilayer is asymmetric (2) and that the free diffusion of membrane proteins is restricted by their interactions with intracellular and extracellular components (3). More recently, Simons and Ikonen suggested that large ordered phases, enriched with cholesterol and sphingolipids, emerge within the plasma membrane and that they function as platforms for enrichment of certain proteins while excluding others (4). This current membrane model suggests that the mixture of sterols and polar lipids within the plasma membrane can appear in two distinct phases: liquid disordered (L_d) and liquid ordered (L_o) phase (5). In this view, the so-called membrane microdomains are considered to be part of the L_o phase. Based on work on model membranes, it is suggested that lateral segregation of components into L_d and L_o phases occurs spontaneously (6) with the self-associating properties between sterols and highly saturated hydrocarbon chains of phopsho- and sphingolipids as the main driving force (7). Additionally, it is suggested that also specific lipid-protein and protein-protein interactions are essential for the formations of membrane domains as well as for stabilization of smaller nanodomains which subsequently may cause formation of larger platforms. In contrast to the animal cells, in plants these membrane microdomains seem to be rather immobile (8), possibly due to their attachment to the outer cell wall. More recently, it became obvious that membrane microdomains within a single cell are highly diverse and of different compositions (9). Generally, in the plant model, organisms'' plasma membrane microdomains turned out to be important in plant defense (10, 11), cell polarity (12, 13), and general signaling properties of the plasma membrane (14, 15).The cytoskeleton was identified as an essential cellular component with important roles in membrane topography, bordering, trafficking, and organelle movement (16). Single particle tracking in mammalian cells revealed that the transferrin receptor and macroglobulin receptor demonstrate normal Brownian diffusion but only within a specific membrane compartment (17). Two hypothetical models were proposed in order to explain this phenomenon (supplemental Fig. 1). Direct interactions between transmembrane proteins and cytoskeleton are suggested to creates a barrier, called “fence,” where cytosolic parts of transmembrane proteins collides with cytoskeletal components, limiting their diffusion to certain areas. These molecules can jump over the “fence” to a neighboring compartment, possibly due to the dynamic nature of the interaction of membrane proteins and cytoskeleton, where they are again temporally trapped (17). This phenomenon was recently described also in A. thaliana where the interplay between membrane microdomains and microtubules plays a role in secondary cell wall formation (reviewed in (18)). The second model assumes, additionally, that particular transmembrane proteins are anchored to and lined up along cytoskeleton and act as “pickets” to arrest free diffusion of other membrane components, including nontransmembrane proteins, within the enclosed compartment (19).For plants, the composition of these sterol-rich membranes phases was analyzed in several biochemical studies (14, 20–22). Thereby, low-density preparations of plasma membrane fractions after treatment with nonionic detergents (DRM¹ fractions) were considered as a biochemical representation enriched in cellular membrane ordered phases or microdomains. Proteomic studies in mammalian cells consistently reported that the DRM fraction is highly enriched with several cytoskeletal proteins such as actin, tubulin, myosin, dynamin, actinin, and supervillin (23–25). Additionally, the level of phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2), a lipid connecting the plasma membrane to actin filaments, was also significantly elevated in DRM preparations (26). Treatment with microtubule and actin depolymerizing agent results in drastic loss of many signaling proteins from these DRM fractions prepared from adult rat cardiac myocytes (27) or human embryonic retinal cells (28).Based on this knowledge, we propose two hypothetical models for the relationship between cytoskeleton and membrane microdomains for plant cells: (i) Actin filaments and microtubules could be important in the membrane phase separation or formation of the membrane microdomains themselves. In this case, disruption of the cytoskeleton would cause a lack of phase segregation in the plasma membrane. (ii) The cytoskeleton is only important for the incorporation of specific protein into the sterol-enriched regions but not for the general formation of these phase separations. This view implies that phase separations or membrane microdomains would still be present after cytoskeleton disruption but their protein composition can be different. Another possible scenario is (iii) that cytoskeletal elements serve as anchors for membrane microdomains at particular position in the plasma membrane, so the absence of these anchors would cause the increased mobility of microdomains (supplemental Fig. 1).The primary aim of this study was to characterize the interplay between cytoskeletal components and different membrane phases (microdomains) in A. thaliana suspension cell cultures. To reach this goal, biochemical and proteomic approaches were combined with confocal microscopy and activity assays measuring the influence of actin or tubulin disruption on the composition, localization, and biochemical properties of the sterol-enriched membrane microdomains. Thereby, for biochemical analyses, low-density detergent-resistant membrane fractions are analyzed as containing cellular sterol-rich membrane compartments.     

A plastid-localized glycogen synthase kinase 3 modulates stress tolerance and carbohydrate metabolism

Glycogen synthase kinase 3 (GSK-3) was originally identified as a regulator of glycogen synthesis in mammals. Like starch in plants, glycogen is a polymer of glucose, and serves as an energy and carbon store. Starch is the main carbohydrate store in plants. Regulation of starch metabolism, in particular in response to environmental cues, is of primary importance for carbon and energy flow in plants but is still obscure. Here, we provide evidence that MsK4, a novel Medicago sativa GSK-3-like kinase, connects stress signalling with carbon metabolism. MsK4 was found to be a plastid-localized protein kinase that is associated with starch granules. High-salt stress rapidly induced the in vivo kinase activity of MsK4. Metabolic profiling of MsK4 over-expressor lines revealed changes in sugar metabolism, including increased amounts of maltose, the main degradation product of starch in leaves. Plants over-expressing MsK4 showed improved tolerance to salt stress. Moreover, under high-salinity conditions, MsK4-over-expressing plants accumulated significantly more starch and showed modified carbohydrate content compared with wild-type plants. Overall, these data indicate that MsK4 is an important regulator that adjusts carbohydrate metabolism to environmental stress.     

Purification of tropomyosin, paramyosin, actin, tubulin, troponin and kinases for chemiproteomics and its application to different scientific fields

Background

p-aminobenzamidine (p-ABA) is used as a ligand in the purification of many serine proteases and in their removal from heterogeneous samples. Moreover, p-ABA has a potent ability to bind Ca²⁺-binding proteins. The binding ability and use of p-ABA in purification processes is still not fully understood.

Methodology/Principal Findings

A p-Aminobenzamidine (p-ABA) ligand enabled the purification of the panallergenic proteins tropomyosin and paramyosin, as well as actin, tubulin, troponin and several kinases and annexins, with variable specificity depending on the tissue source and slight modifications to the purification process. The high affinity of p-ABA to tropomyosin, paramyosin, actin, troponin and myosin is calcium-dependent, since calcium regulates the function of these proteins. In addition, p-ABA probably simulates phosphorylated serine and therefore purified appropriate kinases. Because p-ABA binds to calcium-dependent proteins, and probably those with binding sites containing serine, it is not a suitable inhibitor of proteolysis during the purification of such proteins. p-ABA is widely used to inhibit proteases during protein purification processes, but it is used in columns here to purify non-protease proteins. Two strategies were applied; the first was the inactivation of proteases that were not of interest using protease inhibitors. The second strategy employed was the use of a Ca²⁺ wash solution to remove calcium-dependent proteins. The removal of calcium-dependent proteins from rabbit hind muscle pointed out even more selective purification. It is possible to obtain two purified samples: a) calcium dependent proteins and b) calcium independent proteins. Moreover, p-ABA may be useful as a model to study processes involving the phosphorylation of serine.

Conclusion

A p-Aminobenzamidine (p-ABA) ligand enabled the purification of non-protease proteins, with variable specificity depending on the tissue source and slight modifications to the purification process. The method is applicable to various scientific branches, but is especially practical for medicinal applications.