An inducible acetate transport system in Neurospora crassa conidia

Neurospora crassa conidia possess an active transport system for the uptake of acetate. This system was characterized as: (a) energy dependent; (b) taking place against a concentration gradient; (c) saturating at higher substrate concentrations and (d) competitively inhibited by propionate.Activity of the acetate transport system can be further enhanced by preincubating conidia in 1 mM acetate medium for 180 min (the inducible transport system). The conidial system and the inducible system have similar properties. The development of the inducible transport was dependent on RNA and protein synthesis. A genetic control of this system was further confirmed by isolating a mutant (acp⁻ⁱ acetate permease, inducible) that fails to develop the inducible transport system.     

Active transport of oxalate by Pseudomonas oxalaticus OX1

Membrane vesicles isolated from oxalategrown cells of Pseudomonas oxalaticus accumulated oxalate by an inducible transport system in unmodified form against a concentration gradient. This accumulation was dependent on the presence of a suitable electron donor system such as ascorbate-phenazinemethosulphate. In the presence of this energy source, steady state levels of accumulation of oxalate were 10–20-fold higher than in its absence. The oxalate transport system involved showed a high affinity for oxalate (K _m =11 M) and was highly specific. Oxalate transport was not affected by the presence of other dicarboxylic acids, such as malate, succinate and fumarate and only partly inhibited by acetate. The energy requirement for oxalate transport is discussed and it is concluded that this requirement is most likely equivalent to 1 mole of ATP per mole of oxalate.Abbreviation PMS phenazinemethosulphate     

Bioaccumulation of Germanium by Pseudomonas putida in the Presence of Two Selected Substrates

The uptake of germanium by Pseudomonas putida ATCC 33015 was studied in the presence of catechol or acetate or both as representative substrates differing in their ability to form complexes with this element. The bacteria were taken from a batch culture grown on acetate as the sole carbon source. Cells introduced into a medium containing germanium and either catechol or a mixture of catechol and acetate accumulated germanium in a biphasic way. After a lower level of accumulation that corresponded to the value obtained in the presence of acetate was reached, a further increase in the germanium content up to a higher saturation level was observed. The appearance of the second step of accumulation, which corresponded to the linear degradation of catechol, proved that catechol facilitated the transport of germanium into the cells through the nonspecific uptake of the germanium-catechol complex by an inducible catechol transport system.     

Active Transport of Alcohol in Corynebacterium acetophilum

The transport of alcohols was studied in Corynebacterium acetophilum, which was isolated as a strain growing well on acetate and ethanol. The transport of ethanol was found to be inducible by ethanol, n-propanol, n-butanol, and acetate, whereas transport of methanol occurred by noninducible passive diffusion. The entry of ethanol into the cells occurred against a concentration gradient and showed saturation kinetics with two K(m) values of 2.4 x 10(-5) M and 6.0 x 10(-5) M. Uptake of ethanol was inhibited by sodium azide, sodium cyanide, 2,4-dinitrophenol, and p-chloromercuribenzoate. The transport of ethanol was competitively inhibited by normal alcohols, but not by iso- or tert-alcohols. From these studies, we concluded that an inducible active alcohol transport system mediates the entry of ethanol, n-propanol, or n-butanol into the cells of C. acetophilum.     

Transport of lactate and other short-chain monocarboxylates in the yeast Candida utilis

Summary Lactic acid grown cells of the yeast Candida utilis transported lactate by an accumulative electroneutral proton-lactate symport with a proton-lactate stoicheiometry of 1:1. The accumulation ratio at pH 5.5 was about twenty. The symport accepted the following monocarboxylates (K _svalues at 25°C, pH 5.5 in brackets): d-lactate (0.06 mM), l-lactate (0.06 mM), pyruvate (0.03 mM), propionate (0.05 mM) and acetate (0.1 mM). The system was inducible and was subject to glucose repression. The affinity of the symport for lactate was not affected by pH over the range 3–6, while the maximum transport velocity was strongly pH dependent, its optimum pH being around pH 5. Undissociated lactic acid entered the cells by simple diffusion. The permeability for the undissociated acid increased exponentially with pH, the diffusion constant increasing 35-fold when the pH was increased from 3 to 5.5.     

An inducible proline transport system in Candida albicans.

1. When Candida albicans cells were preincubated with proline or grown in the presence of proline as the sole nitrogen source they exhibited a rapid increase in the influx of proline (the inducible transport system). 2. The induction appeared to be specific for proline and also demonstrated in other Candida species. 3. Both the inducible and constitutive proline uptake systems exhibited similar characteristic features. 4. The nature of the inducer for proline uptake in C. albicans appeared to be free proline. 5. The development of the inducible proline transport system was dependent on concomitant synthesis of RNA and protein and the induction was not affected by glucose or any other carbon sources used.     

Induction of nitrate transport in maize roots, and kinetics of influx, measured with nitrogen-13

Unlike phosphate or potassium transport, uptake of nitrate by roots is induced, in part, by contact with the substrate ion. Plasmalemma influx of ¹³N-labeled nitrate in maize roots was studied in relation to induction of the uptake system, and the influence of short-term N starvation. Maize (Zea mays) roots not previously exposed to nitrate had a constitutive transport system (state 1), but influx increased 250% during six hours of contact with 100 micromolar nitrate, by which time the transport mechanism appeared to be fully synthesized (state 2). A three-day period of N starvation prior to induction and measurement of nitrate influx resulted in a greater capacity to transport nitrate than in unstarved controls, but this was fully expressed only if roots were kept in contact with nitrate for the six hours needed for full induction (state 2E). A kinetic analysis indicated a 160% increase in maximum influx in N-starved, induced roots with a small decrease in K_m. The inducible component to nitrate influx was induced only by contact with nitrate. Full expression of the nitrate inducible transport system was dependent upon mRNA synthesis. An inhibitor of cytoplasmic protein synthesis (cycloheximide) eliminated the formation of the transport system while inhibition by chloramphenicol of mitochondrial- or plastid-coded protein synthesis had no effect. Poisoning of membrane-bound proteins effectively disabled both the constitutive and induced transport systems.     

Light-dependent degradation of nitrophenols by the phototrophic bacterium Rhodobacter capsulatus E1F1.

Rhodobacter capsulatus E1F1, a phototrophic purple nonsulfur bacterium capable of photoassimilating nitrate or nitrite, grew phototrophically in the presence of mono- and dinitrophenols with acetate as a carbon source, the highest growth levels being obtained under microaerobic conditions. Utilization of 2,4-dinitrophenol was strictly light dependent, was inhibited by O2 and by ammonium, and took place with the simultaneous and stoichiometric production of 2-amino-4-nitrophenol, which accumulated in the medium and was poorly used for further growth in anaerobiosis. Metabolism of mononitrophenols was also light dependent but was activated by O2 and by ammonium. Metabolism of nitrophenols seemed to depend on inducible systems which were repressed in nitrogen-starved cells. Induction of the in vivo 2,4-dinitrophenol reducing system was strongly inhibited by chloramphenicol.     

Light-dependent degradation of nitrophenols by the phototrophic bacterium Rhodobacter capsulatus E1F1.

Rhodobacter capsulatus E1F1, a phototrophic purple nonsulfur bacterium capable of photoassimilating nitrate or nitrite, grew phototrophically in the presence of mono- and dinitrophenols with acetate as a carbon source, the highest growth levels being obtained under microaerobic conditions. Utilization of 2,4-dinitrophenol was strictly light dependent, was inhibited by O2 and by ammonium, and took place with the simultaneous and stoichiometric production of 2-amino-4-nitrophenol, which accumulated in the medium and was poorly used for further growth in anaerobiosis. Metabolism of mononitrophenols was also light dependent but was activated by O2 and by ammonium. Metabolism of nitrophenols seemed to depend on inducible systems which were repressed in nitrogen-starved cells. Induction of the in vivo 2,4-dinitrophenol reducing system was strongly inhibited by chloramphenicol.     

Germination and adhesion of fungal conidia on polycarbonate membranes and on apple fruit exposed to mycoactive acetate esters

The adhesion and germination of conidia of nine fungal species were assessed on polycarbonate membranes or on the skin of apple fruit in sealed glass bottles injected or not injected with acetate esters. Adhesion was determined after dislodging conidia from surfaces using a sonication probe. Adhesion and germination of conidia of Aspergillus flavus, Aspergillus fumigatus, Aspergillus niger, Penicillium citrinum, Penicillium claviforme, or Trichoderma sp. on membranes after 48 h were not increased in a 1.84 microg mL(-1) headspace of butyl acetate (BA), ethyl acetate, hexyl acetate, 2-methylbutyl acetate, pentyl acetate, or propyl acetate. Adhesion and germination of Botrytis cinerea, Penicillium expansum, and Penicillium roquefortii conidia were stimulated by all esters. Only conidia of B. cinerea and P. expansum exhibited increased adhesion and germination on the skin of apple fruit in bottles exposed to 0.92 microg mL(-1) of BA. Only conidia of B. cinerea and P. expansum produced decay in inoculated puncture wounds on fruit. Freshly made puncture wounds or 24-h-old puncture wounds in fruit were more adhesive than the unpunctured skin of fruit to conidia of B. cinerea or P. expansum. Fresh wounds were more adhesive to both fungi than 24-h-old puncture wounds. The skin and wounds of fruit were as adhesive to B. cinerea conidia as they were to P. expansum conidia. A 4-h exposure to 1.43 microg mL(-1) of BA increased adhesion of B. cinerea and P. expansum conidia in 24-h-old wounds. Results suggest that acetate-ester stimulation most likely is not a rare phenomenon in the fungi. For nutrient-dependent decay pathogens of apple fruit, acetate esters may be an alternative chemical cue used to maintain adhesion of conidia to wound surfaces.     

Active transport of l-aspartic acid in Neurospora crassa

Transport of l-aspartic acid in Neurospora crassa conidia is shown to be mediated by neutral and general amino acid transport systems. The transport activity is dependent on pH and results in accumulation of l-aspartic acid against a gradient. Mutants deficient in transport of l-aspartic acid are described.     

The highly toxic oxyanion tellurite (TeO<Stack><Subscript>3</Subscript><Superscript>2−</Superscript></Stack>) enters the phototrophic bacterium <Emphasis Type="Italic">Rhodobacter capsulatus</Emphasis> via an as yet uncharacterized monocarboxylate transport system

The facultative phototroph Rhodobacter capsulatus takes up the highly toxic oxyanion tellurite when grown under both photosynthetic and respiratory growth conditions. Previous works on Escherichia coli and R. capsulatus suggested that tellurite uptake occurred through a phosphate transporter. Here we present evidences indicating that tellurite enters R. capsulatus cells via a monocarboxylate transport system. Indeed, intracellular accumulation of tellurite was inhibited by the addition of monocarboxylates such as pyruvate, lactate and acetate, but not by dicarboxylates like malate or succinate. Acetate was the strongest tellurite uptake antagonist and this effect was concentration dependent, being already evident at 1 μM acetate. Conversely, tellurite at 100 μM was able to restrict the acetate entry into the cells. Both tellurite and acetate uptakes were energy dependent processes, since they were abolished by the protonophore FCCP and by the respiratory electron transport inhibitor KCN. Interestingly, cells grown on acetate, lactate or pyruvate showed a high level resistance to tellurite, whereas cells grown on malate or succinate proved to be very sensitive to the oxyanion. Taking these data together, we propose that: (a) tellurite enters R. capsulatus cells via an as yet uncharacterized monocarboxylate(s) transporter, (b) competition between acetate and tellurite results in a much higher level of tolerance against the oxyanion and (c) the toxic action of tellurite at the cytosolic level is significantly restricted by preventing tellurite uptake.     

Transport of phenylalanine by conidia of Fusarium sulphureum.

L-Phenylalanine was actively transported by conidia of Fusarium sulphurenum Schlect (isolate 1). Uptake was optimal at pH 7, 30 degrees C; respiration-dependent; and was unaffected by relatively high internal concentrations of phenylalanine. The Km for transport was 1-3 X 10(-5) M and the Vmax was 2.5-4 nmol/min per milligram dry weight. Phenylalanine is transported by a general transport system for basic and neutral amino acids. Sucrose repressed uptake of phenylalanine and this repression was largely negated by cycloheximide. Efflux of accumulated phenylalanine was influx-dependent; this transport system deteriorated slowly with aging of the conidial culture.     

Bioenergetic models for acetate and phosphate transport in bacteria important in enhanced biological phosphorus removal

Most of our understanding of the physiology of microorganisms is the result of investigations in pure culture. However, in order to understand complex environmental processes, there is a need to investigate mixed microbial communities. This is true for enhanced biological phosphorus removal (EBPR), an environmental process that results in the enrichment of the polyphosphate-accumulating organism Accumulibacter spp. and the glycogen non-polyphosphate accumulating organism Defluviicoccus spp. We investigated acetate and inorganic phosphate (P(i)) uptake in enrichments of Accumulibacter spp. and acetate uptake in enrichments of Defluviicoccus spp. For both enrichments, anaerobic acetate uptake assays in the presence of the protonophore, carbonyl cyanide m-chlorophenylhydrazone (CCCP) or the membrane potential (Delta psi) uncoupler valinomycin, indicated that acetate is likely to be taken up by a permease-mediated process driven by the Delta psi. Further investigation with the sodium ionophore monensin suggested that anaerobic acetate uptake by Defluviicoccus spp. may in part be dependent on a sodium potential. Results of this study also suggest that Accumulibacter spp. generate a proton motive force (pmf or Delta p) for anaerobic acetate uptake by efflux of protons in symport with P(i) through an inorganic phosphate transport (Pit) system. In contrast, we suggest that the anaerobic Delta p in Defluviicoccus spp. is generated by an efflux of protons across the cell membrane by the fumarate respiratory system, or by extrusion of sodium ions via decarboxylation of methylmalonyl-CoA. Aerobic P(i) uptake by the Accumulibacter spp. enrichment was strongly inhibited in the presence of an ATPase inhibitor, suggesting that the phosphate-specific transport (Pst) system is important even under relatively high concentrations of P(i). Acetate permease activity in these microorganisms may play an important role in the competition for acetate in the often acetate-limited EBPR process. Activity of a high-velocity Pst system in Accumulibacter spp. may further explain its ability to compete strongly in EBPR.     

Transport of volatile fatty acids across the hindgut of the cockroach Panesthia cribrata Saussure and the termite, Mastotermes darwiniensis Froggatt

Acetate ion was actively transported from the lumen across the colon wall of the cockroach Panesthia cribrata. A maximal initial rate of transport of 81 μmol/h was obtained when the concentration of acetate was increased 400 times the physiological level to over 2 M. The transport system could not be saturated. Transport was not affected by 2,4-dinitrophenol or cyanide nor was it dependent on the maintenance of a sodium gradient. Propionate was transported to a lesser extent, but butyrate was transported at rates comparable to acetate. Acetate was also actively transported by the paunch and upper colon of Mastotermes darwiniensis but the transport system could not be saturated. A maximal initial rate of 3 μmol/h was obtained.     

Isolation and characterization of Aspergillus oryzae vacuolar protein sorting mutants

The vacuolar protein sorting (vps) system in the filamentous fungus Aspergillus oryzae, which has unique cell polarity and the ability to secrete large amounts of proteins, was evaluated by using mutants that missort vacuolar proteins into the medium. Vacuolar carboxypeptidase Y (CPY) fused with enhanced green fluorescent protein (EGFP) was used as a vacuolar marker. Twenty dfc (dim EGFP fluorescence in conidia) mutants with reduced intracellular EGFP fluorescence in conidia were isolated by fluorescence-activated cell sorting from approximately 20,000 UV-treated conidia. Similarly, 22 hfm (hyper-EGFP fluorescence released into the medium) mutants with increased extracellular EGFP fluorescence were isolated by using a fluorescence microplate reader from approximately 20,000 UV-treated conidia. The dfc and hfm mutant phenotypes were pH dependent, and missorting of CPY-EGFP could vary by 10- to 40-fold depending on the ambient pH. At pH 5.5, the dfc-14 and hfm-4 mutants had an abnormal hyphal morphology that is consistent with fragmentation of vacuoles and defects in cell polarity. In contrast, the hyphal and vacuolar morphology of the dfc-14 and hfm-4 mutants was normal at pH 8.0, although CPY-EGFP accumulated in perivacuolar dot-like structures similar to the class E compartments in Saccharomyces cerevisiae vps mutants. In hfm-21, CPY-EGFP localized at the Spitzenk?rper when the mutant was grown at pH 8.0 but not in vacuoles, suggesting that hfm-21 may transport CPY-EGFP via a novel pathway that involves the Spitzenk?rper. Correlations between vacuolar protein sorting, pH response, and cell polarity are reported for the first time for filamentous fungi.     

Choline transport activity in Staphylococcus aureus induced by osmotic stress and low phosphate concentrations.

Uptake of [14C]choline upon hyperosmotic stress of exponential-phase Staphylococcus aureus cultures in a complex medium occurred after a delay of 2.5 to 3.5 h. This uptake could be prevented by chloramphenicol, suggesting that it occurred via an inducible transport system. Radioactivity from [14C]choline was accumulated as [14C]glycine betaine. However, neither choline nor glycine betaine could act as the major carbon and energy source for the organism, suggesting that choline was not metabolized beyond glycine betaine. Assay of choline transport activity in cells grown under different conditions in defined media revealed that osmotic stress was mainly responsible for the induction, but choline gave a further increase in induction. The system was not induced in anaerobically grown cells. Choline transport activity was repressed by glycine betaine and proline betaine, suggesting that these compounds are corepressors. Choline transport activity was not induced in cells osmotically stressed by 1 M potassium phosphate or 0.5 M sodium phosphate, but was induced in cells grown in low-phosphate medium in the absence of osmotic stress. This suggests that there is a connection between the phosphate and osmotic stress regulons. Choline transport was energy and Na+ dependent and had a Km of 46 microM and a maximum rate of transport (Vmax) of 54 nmol/min/mg (dry weight). The results of competition studies suggested that N-methyl and an alcohol group or aldehyde groups at the ends of the molecule were important in its recognition by the system. Glycine betaine was not a highly effective competitor, suggesting that its transport system and the choline transport system were distinct from each other. Choline transport was highly susceptible to a variety of inhibitors, which may be related to the greater dependence on respiratory metabolism of cells grown in the presence of high NaC1 concentrations.     

Metabolic regulation in Pseudomonas oxalaticus OX1. Diauxic growth on mixtures of oxalate and formate or acetate

Diauxic growth was observed in batch cultures of Pseudomonas oxalaticus when cells were pregrown on acetate and then transferred to mixtures of acetate and oxalate. In the first phase of growth only acetate was utilized. After the exhaustion of acetate from the medium enzymes involved in the metabolism of oxalate were synthesized during a lag phase of 2 h, followed by a second growth phase on oxalate. When the organism was pregrown on oxalate, oxalate utilization from the mixture with acetate completely ceased after a few hours during which acetate became the preferred substrate. Similar observations were made with formate/oxalate mixtures in which formate was the preferred substrate. Until formate was exhausted, it completely suppressed oxalate metabolism, again resulting in diauxic growth. However, when the organism was pregrown on oxalate and then transferred to mixtures of oxalate and formate, both substrates were utilized simultaneously although the initial rate of oxalate utilization from the mixture was strongly reduced as compared to growth on oxalate alone.Since both preferred substrates cross the cytoplasmic membrane by diffusion, whereas oxalate is accumulated by an inducible, active transport system, the effect of acetate and formate on oxalate transport was studied at different external pH values. At pH 5.5 both substrates completely inhibited oxalate transport. However, at pH 7.5, the pH at which the diauxic growth experiments were performed, formate and acetate did not affect oxalate transport. Growth patterns and enzymes profiles suggest that, at higher pH values, formate and acetate possibly affect oxalate utilization via an effect on the internal pool of oxalyl-CoA, the first product of oxalate metabolism.Abbreviations PMS phenazine methosulphate - RuBPCase ribulosebisphosphate carboxylase - DCPIP 2,6-dichlorophenolindophenol - FDH formate dehydrogenase - p.m.f. protonmotive force     

Tryptophan Transport in Neurospora crassa: a Tryptophan-Binding Protein Released by Cold Osmotic Shock

Osmotic shock treatment of germinated conidia of Neurospora reduced the capacity for tryptophan transport in these cells approximately 90% without an appreciable loss of cell viability. Tryptophan-binding proteins and alkaline phosphatase were consistently released into the osmotic shock fluid by this treatment. Four lines of evidence suggest that the binding protein may be related to the tryptophan transport system. (i) It appears to be located on or near the cell surface. (ii) a decreased capacity for binding tryptophan was observed in shock fluids from cells repressed for tryptophan uptake; reduced or altered binding capacity was released from a transport-negative mutant. (iii) The specificity of tryptophan binding was similar to that observed in the in vivo transport system. (iv) The dissociation constant for binding, as measured by equilibrium dialysis, was approximately the same as the K(m) for tryptophan transport.     

Properties of an inducible uptake system for beta-ketoadipate in Pseudomonas putida.

Wild-type strains of Pseudomonas putida form an inducible uptake system that appears to act on beta-ketoadipate under normal physiological conditions. The system is induced by beta-ketoadipate and is represented by catabolites derived from it. Adipate is metabolized very slowly by wild-type P. putida cultures; [14C]adipate was used as an analogue of beta-ketoadipate to measure the transport activity in wild-type cells and in cells that constitutively produced the uptake system. Constitutive cells that contained high levels of the uptake system concentrated adipate to a level up to 200-fold above the concentration in the external medium. The process was energy dependent. The activity of the system with radioactive adipate was inhibited by beta-ketoadipate, by beta-ketoadipate analogues, and by some compounds (e.g., acetate, glucose) that are structurally unrelated to beta-ketoadipate; it is not known if the inhibitory effects are exerted directly by the compounds themselves or indirectly by catabolites derived from the compounds. The discovery of the beta-ketoadipate uptake system is surprising in view of earlier studies that had indicated that beta-ketoadipate does not permeate the membrane of wild-type P. putida cells. Contradictions between the former investigations and the present analysis are due primarily to the relatively high concentrations of substrate used in the earlier experiments. The existence of the beta-ketoadipate uptake system indicates that beta-ketoadipate may exist as a selective nutrient in the natural niche of P. putida and may play a determinative role in the evolution of induction mechanisms that are characteristic of fluorescent pseudomonads.