Biosynthesis of catecholamines in organotypic cultures of the peripheral autonomic nervous system: Modifications by biopterin and other agents

Organotypic cultures of chick-embryo sympathetic ganglion chains maintained in vitro for 3–4 weeks rapidly synthesized catecholamines, as demonstrated by the conversion of L-[U-¹⁴C]tyrosine to catechol derivatives and by histofluorescence assay. The biosynthesis of catechols from radioactive L-tyrosine leveled off at 6 hr of incubation and dropped slightly at 10 hr. The addition of DL-α-methyl-p-tyrosine to the culture medium did not affect protein synthesis, but produced a complete block in the synthesis of catecholamines from L-tyrosine, with consequent loss of fluorescence in the bodies and proximal processes of adrenergic neurons in 2 hr, and essentially complete loss in 6 hr. Our observations suggest that a major portion of the catecholamines were synthesized in the perikarya and transported via neuronal processes to their terminals. The addition of monoamine oxidase inhibitors to the incubation medium produced a moderate to pronounced increase in fluorescence; reserpine caused a rapid and profound loss of catecholamines. When added to the culture medium, crude biopterin produced an increase in the synthesis of catechol derivatives from radioactive L-tyrosine and a marked increase in fluorescence, beginning in the neuronal perikarya. This effect was completely blocked by DL-α-methyl-p-tyrosine. The mechanism of biopterin's action in the synthesis of catecholamines in cultures of sympathetic ganglia is not completely elucidated from these studies, but may be related to the role it plays as cofactor for tyrosine hydroxylase.     

Microfluorimetric quantitation of catecholamine turnover in the sympathetic neurons of rat

Summary The quantitative aspects of the formaldehydeinduced fluorescence and the turnover of catecholamines in the sympathetic neuronal perikaryon of different sympathetic ganglia were studied after a blockade of the amine synthesis with -methyltyrosine. The concentration of catecholamines was determined by microfluorimetric quantitation method. The half-life of catecholamines in sympathetic neuronal perikarya was short and depended on the ganglion studied. The turnover rate of catecholamines in sympathetic neurons was highest in superior cervical and lowest in coeliac ganglion. Brightly fluorescent fibers were still seen five hours after the amine synthesis blockade, whereas almost all cell bodies had lost their fluorescence. Also small intensely fluorescent cells were still brightly fluorescent after the follow-up period. Microfluorimetrically determined turnover of catecholamines gave more detailed information about the turnover of catecholamines in sympathetic nervous system when compared to the biochemical methods used earlier.     

Chronic depolarization stimulates norepinephrine transporter expression via catecholamines

Chronic depolarization increases norepinephrine (NE) uptake and expression of the norepinephrine transporter (NET) in sympathetic neurons, but the mechanisms are unknown. Depolarization of sympathetic neurons stimulates catecholamine synthesis, and several studies suggest that NET can be regulated by catecholamines. It is not clear if the depolarization-induced increase in NET is because of nerve activity per se, or is secondary to elevated catecholamines. To determine if induction of NET mRNA was a result of increased catecholamines, we used pharmacological manipulations to (i) inhibit tyrosine hydroxylase activity in neurons depolarized with 30 mm KCl, thereby preventing increased catecholamines, or (ii) stimulate tyrosine hydroxylase activity in the absence of depolarization. Inhibiting the depolarization-induced increase in catecholamines prevented the up-regulation of NET mRNA, but did not block the increase in tyrosine hydroxylase (TH) mRNA. Furthermore, stimulating catecholamine production in the absence of depolarization elevated NE uptake, NET protein, and NET mRNA in sympathetic neurons. Similarly, elevating endogenous catecholamines in SK-N-BE2M17 neuroblastoma cells increased NE uptake and NET expression. These data suggest that chronic depolarization of sympathetic neurons induces NET expression through increasing catecholamines, and that M17 neuroblastoma cells provide a model system in which to investigate catechol regulation of NET expression.     

PRIMARY CULTURES OF DISSOCIATED SYMPATHETIC NEURONS : II. Initial Studies on Catecholamine Metabolism

Initial studies are reported on the catecholamine metabolism of low-density cultures of dissociated primary sympathetic neurons. Radioactive tyrosine was used to study the synthesis and breakdown of catecholamines in the cultures. The dependence of catecholamine synthesis and accumulation on external tyrosine concentration was examined and a concentration which is near saturation, 30 µM, was chosen for further studies. The free tyrosine pool in the nerve cells equilibrated with extracellular tyrosine within 1 h; the total accumulation of tyrosine (free tyrosine plus protein, catecholamines, and metabolites) was linear for more than 24 h of incubation. Addition of biopterin, the cofactor of tyrosine hydroxylase, only slightly enhanced catecholamine biosynthesis by the cultured neurons. However, addition of reduced ascorbic acid, the cosubstrate for dopamine β-hydroxylase, markedly stimulated the conversion of dopamine (DA) to norepinephrine (NE). Phenylalanine, like tyrosine, served as a precursor for some of the DA and NE produced by the cultures, but tyrosine always accounted for more than 90% of the catecholamines produced. The DA pool labeled rapidly to a saturation level characteristic of the age of the culture. The NE pool filled more slowly and was much larger than the DA pool. The disappearance of radioactive NE and DA during chase experiments followed a simple exponential curve. Older cultures showed both more rapid production and more rapid turnover of the catecholamines than did younger cultures, suggesting a process of maturation.     

PRIMARY CULTURES OF DISSOCIATED SYMPATHETIC NEURONS : III. Changes in Metabolism with Age in Culture

Several biochemical parameters of dissociated sympathetic neurons from superior cervical ganglia of the newborn rat were monitored as a function of age in culture. The neurons, which were grown in the virtual absence of non-neural cells, displayed a striking increase in their ability to synthesize and accumulate catecholamines. This capacity increased 50-fold during a 3-wk period in vitro, after which it appeared to reach a steady level. The major change took place during the second week. The time course of this change was not affected by plating the neurons at a higher cell density. The change in the catecholamine metabolism was far greater in magnitude and quite different in time course from the overall growth of the cells which was monitored by the incorporation of radioactive tyrosine into protein, lipid synthesis from radioactive choline, and incorporation of radioactive uridine into acid-precipitable material. Of the total tyrosine used by the cultures, the proportion devoted to catecholamine synthesis increased to 25% (a 10-fold rise) during the 3-wk period. This changing pattern of metabolism in the cultures suggested a process of maturation which may be similar to neuronal development in vivo.     

Hydrocortisone-induced increase in the number of small intensely fluorescent cells and their histochemically demonstrable catecholamine content in cultures of sympathetic ganglia of the newborn rat

Synopsis It is known that hydrocortisone causes a great increase in the number of small intensely fluorescent (SIF) cells in the sympathetic ganglia when injected into newborn rats. The effect of hydrocortisone on nervous tissuein vitro has not been studied previously.Pieces of newborn rat sympathetic ganglia were cultivated in Rose chambers. Hydrocortisone was dissolved in the medium in concentrations of 1–9 mg/l. Both control and hydrocortisone-containing cultures were examined daily by phase-contrast microscopy, and the catecholamines were demonstrated histochemically by formaldehyde-induced fluorescence after 7 days in culture.All cultures showed outgrowths of axons and supporting cells elements, although these were less extensive in the groups of cultures with hydrocortisone. After a week, SIF cells with a green fluorescence were observed in the control explants. In all cultures with hydrocortisone, a concentration-dependent increase was observed in the fluorescence intensity and the number of the SIF cells in the explant; numerous SIF cells were also seen in the outgrowth. Some SIF cells showed processes and the longest processes were seen in cultures with the highest concentration of hydrocortisone.It is concluded that hydrocortisone causes an increased synthesis of catecholamines in the SIF cellsin vitro, and an increase in their number by affecting either their division or their differentiation from a more immature form, or both. This effect was a direct one and not mediated by any system other than the ganglion itself. Induction of enzyme synthesis by hydrocortisone is proposed as an explanation of the increase in catecholamine concentration.University of Melbourne Senior Research Fellow, September 1971-August 1972Sunshine Foundation and Rowden White Trust Overseas Research Fellow in the University on Melbourne, September 1971-August 1972     

Light and electron microscopic histochemistry of the monoamines in the human foetal sympathetic ganglion in culture

Synopsis Sympathetic ganglia of 13 to 19-week-old human foetuses were cultured in small pieces with and without nerve growth factor for up to 5 weeksin vitro. The cultures were studied using phase-contrast, fluorescence and electron microscopy. Monoamines were demonstrated with the formaldehyde-induced fluorescence method, with and without pretreatment of the cultures with catecholamines or monoamine oxidase inhibitor.In the long-term cultures, primitive sympathetic cells, sympathicoblasts of types I and II, and young sympathetic neurons showed a fine structure identical to that described earlierin vivo. There were virtually no satellite or Schwann cells in the cultures. The neurons showed a considerable capacity to grow new nerve fibres in culture, even without nerve growth factor. Nerve terminals with accumulations of other nervous structures. Large granular vesicles were regularly found in the sympathicoblasts after glutaraldehyde-osmium tetroxide fixation. After permanganate fixation, dense-cored vesicles typical of adrenergic neurons were not seen, either in the perikarya, or in the processes, although it was possible to demonstrate specific fluorescence. No small intensely fluorescent (SIF) cells were observed.Variable formaldehyde-induced fluorescence was observed in the nerve cell perikarya and nerve fibres. The intensity of the fluorescence increased after treatment of the cultures with monoamine oxidase inhibitor and after incubation with catecholamines.     

Dopamine synthesis by non-dopaminergic neurons of the rat fetus arquate nucleus

Our hypothesis was tested in respect to dopamine synthesis by non-dopaminergic neurons expressing individual complementary enzymes of the DA synthetic pathway. According to the hypothesis, L-dihydroxyphenylalanine (L-DOPA) synthesised in tyrosine hydroxylase(TH)-expressing neurons for conversion to dopamine. The mediobasal hypothalamus of rats on the 21st embryonic day was used as an experimental model. The fetal substantia nigra containing dopaminergic neurons served as control. Dopamine and L-DOPA were measured by high performance liquid chromatography in cell extracts and incubation medium in presence or absence of L-tyrosine. L-tyrosine administration increased L-DOPA synthesis in the mediobasal hypothalamus and substantia nigra. Moreover, L-tyrosine provoked an increase of dopamine synthesis in substantia nigra and a decrease in the mediobasal hypothalamus. This is, probably, due to an L-tyrosine-induced competitive inhibition of the L-DOPA transport to monoenzymatic AADC neurons after its release from the monoenzymatic TH neurons. This study provides a convincing evidence of dopamine synthesis by non-dopaminergic neurons expressing TH or AADC, in cooperation.     

PRIMARY CULTURES OF DISSOCIATED SYMPATHETIC NEURONS : I. Establishment of Long-Term Growth in Culture and Studies of Differentiated Properties

Rat sympathetic ganglia were disrupted by mechanical agitation to yield dissociated primary neurons, and the conditions for long-term growth in culture of the isolated neurons were examined. The neurons were grown with or without non-neural cells, simply by the addition or deletion of bicarbonate during growth in culture. Fluorescence histochemistry indicated that the isolated neurons contained catecholamines; incubations with radioactive precursors were used to verify the synthesis and accumulation of both dopamine and norepinephrine. The neurons also produced octopamine using tyramine as precursor, but not with tyrosine as the precursor. In the presence of eserine, older cultures synthesized and stored small amounts of acetylcholine. The cultures did not synthesize and accumulate detectable levels of radioactive γ-aminobutyric acid, 5-hydroxytryptamine, or histamine.     

Synthesis of angiotensinogen by isolated rat liver cells and its regulation in comparison to serum albumin

Angiotensinogen (renin substrate) and albumin are synthesized by isolated hepatocytes almost linearly for 5 hr. The incorporation of radioactive leucine into total protein proceeded linearly for 3 hr. Without addition of amino acids to the incubation medium the synthesis of both proteins was still linear but fell off to 40% compared to the synthesis rate obtained by incubation with amino acids in serum concentrations. Higher amino acid concentrations could not further stimulate the synthesis. Addition or withdrawal of tryptophan had no effect on the synthesis rate of both proteins. After 5 hr incubation hydrocortisone had stimulated the incorporation of radioactive leucine into total protein by 13%, the albumin synthesis by 43%, and the angiotensinogen synthesis by 142%.     

"Matrigenin" activity from bovine bone--III. Effects on glycosaminoglycans and proteoglycans of human synovial cells in culture

1. Human synovial fibroblastic cells were cultured in the presence and absence of an extract from bovine bone containing "matrigenin" activity. The rate of incorporation of radioactivity into the glycosaminoglycans of the medium of "matrigenin"-treated cultures increased after 24 hr of incubation, compared to "controls". 2. Higher serum concentrations had a greater effect on the incorporation of radioactivity into hyaluronic acid synthesized by "matrigenin"-treated cultures, than by "controls". 3. Incorporation of radioactive precursors into the proteoglycans isolated from the medium was greater in the "matrigenin"-treated cultures than in "controls". The synthesis of a large mol. wt proteoglycan was specifically stimulated.     

Biosynthesis, Development, and Regulation of Neuropeptide Y in Superior Cervical Ganglion Culture

The biosynthesis of neuropeptide Y (NPY) and norepinephrine (NE) has been examined in dissociated neuronal cultures from newborn rat superior cervical ganglion (SCG). NPY synthetic rate was measured by immunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis after incubation in medium containing a labeled amino acid. The authenticity of the NPY was confirmed by reverse-phase HPLC analyses of tryptic peptides. The NPY synthetic rate in cultures grown in complete serum free medium increased 30-fold after plating, in parallel to catecholamine synthesis; both NPY and the catecholamines reached the rate for adult SCG neurons. This development in culture is seen without spinal cord input, target organs, or significant numbers of glial cells. NPY synthesis was maintained in the face of a major decrease in the rate of NE production after cholinergic induction.     

The role of serum in human mixed lymphocyte cultures.

Mixed lymphocyte cultures employing human lymphocytes were established in serum-supplemented medium. After an initial incubation of 72 hr or longer, proliferation of the cultures was observed in serum-free medium for an additional 24–48 hr. Thereafter, the proliferation decreased to below values seen in autologous controls. No DNA synthesis was observed in serum-free cultures or in cultures initially incubated with serum for less than 72 hr. Human albumin added to the cultures could not replace serum, although a weak response was obtained. Serum therefore must be present throughout the incubation period in human mixed lymphocyte cultures, if a maximum response is to be elicited.     

Regulation of Guanosine Triphosphate Cyclohydrolase and Tetrahydrobiopterin Levels and the Role of the Cofactor in Tyrosine Hydroxylation in Primary Cultures of Adrenomedullary Chromaffin Cells

Selective modification of the tetrahydrobiopterin levels in cultured chromaffin cells were followed by changes in the rate of tyrosine hydroxylation. Addition of sepiapterin, an intermediate on the salvage pathway for tetrahydrobiopterin synthesis, rapidly increased intracellular levels of tetrahydrobiopterin and elevated the rate of tyrosine hydroxylation in the intact cell. Tyrosine hydroxylation was also enhanced when tetrahydrobiopterin was directly added to the incubation medium of intact cells. When the cultured chromaffin cells were treated for 72 h with N-acetylserotonin, an inhibitor of sepiapterin reductase, tetrahydrobiopterin content and the rate of tyrosine hydroxylation were decreased. Addition of sepiapterin or N-acetylserotonin had no consistent effect on total extractable tyrosine hydroxylase activity or on catecholamine content in the cultured chromaffin cells. Three-day treatment of chromaffin cell cultures with compounds that increase levels of cyclic AMP (forskolin, cholera toxin, theophylline, dibutyryl- and 8-bromo cyclic AMP) increased total extractable tyrosine hydroxylase activity and GTP-cyclohydrolase, the rate-limiting enzyme in the biosynthesis of tetrahydrobiopterin. Tetrahydrobiopterin levels and intact cell tyrosine hydroxylation were markedly increased after 8-bromo cyclic AMP. The increase in GTP-cyclohydrolase and tetrahydrobiopterin induced by 8-bromo cyclic AMP was blocked by the protein synthesis inhibitor cycloheximide. Agents that deplete cellular catecholamines (reserpine, tetrabenazine, and brocresine) increased both total tyrosine hydroxylase and GTP-cyclohydrolase activities, although treating the cultures with reserpine or tetrabenazine resulted in no change in cellular levels of cyclic AMP. Brocresine and tetrabenazine increased tetrahydrobiopterin levels, but the addition of reserpine to the cultures decreased catecholamine and tetrahydrobiopterin content and resulted in a decreased rate of intact cell tyrosine hydroxylation in spite of the increased activity of the total extractable enzyme. These data indicate that in cultured chromaffin cells GTP-cyclohydrolase activity like tyrosine hydroxylase activity is regulated by both cyclic AMP-dependent and cyclic AMP-independent mechanisms and that the intracellular level of tetrahydrobiopterin is one of the many factors that control the rate of tyrosine hydroxylation.     

Protein synthesis in neuronal perikarya isolated from cerebral cortex of the immature rat

Abstract— Homogenates of neuronal perikarya isolated from the cerebral cortex of the 8-day-old rat were incubated with [³H]leucine, and the characteristics of the protein synthetic process were studied. Incorporation of leucine into protein was linear up to 90 min, proceeded optimally at pH 7.6 and was stimulated by K⁺ and NH₄⁺, unaffected by Li⁺ and inhibited by Na⁺. Puromycin, cycloheximide, RNAse, sulphhydryl blocking agents and phospholipase A exerted a pronounced inhibition, whereas chloramphenicol and phospholipase C had no effect. About 42 per cent of the total radioactive protein formed in the optimally fortified in uitro system was recovered in non-sedimentable form. Incorporation into the subcellular fractions of the neuronal perikarya increased steadily with increasing time of incubation. The microsomal fraction acquired the highest specific radioactivity (d.p.m./mg of protein), followed by the mitochondrial and the nuclear + cell debris fractions. The high-speed soluble fraction exhibited the lowest specific radioactivity. Although the addition of L-methionine to a suitably fortified incubation medium inhibited neuronal protein synthesis by about 80 per cent, the addition of D-methionhe, α-methyl-DL-methionine or L-tryptophan was relatively ineffective by comparison.     

Effect of divalent cations of the amphetamine-induced stimulation of [3H]catechol synthesis in the striatum.

Abstract— The effects of divalent cations on the stimulation of [³H]catechol formation in striatal slices induced by d-amphetamine was studied in order to determine the role of calcium in this action of amphetamine. In the absence of any divalent cations in the medium, amphetamine did not significantly stimulate [³H]catechol synthesis in striatal slices, but it produced a marked stimulation of synthesis when calcium (1.25 mm ) was added to the medium. In the presence of calcium (1.25 mm ), high concentrations of magnesium (15mm ), other divalent cations (2.5 mm ) such as barium, strontium, manganese and cobalt, as well as verapamil, inhibited the amphetamine-induced stimulation. When the slices were incubated in medium containing no divalent cations, the addition to the medium of either strontium, cobalt, zinc, or magnesium (2.5 mm ) could not support the amphetamine-induced stimulation of [³H]catechol synthesis, while the addition of barium resulted in a significant stimulation of synthesis. In contrast, the stimulation produced by amphetamine in the presence of manganese was comparable to that observed when calcium had been added to the medium. Since amphetamine did not alter the specific activity of [³H]tyrosine in the tissue in the presence of any of the divalent cations tested, the amphetamine-induced stimulation of [³H]catechol synthesis was probably due to an increase in tyrosine hydroxylase activity. Calcium and manganese were also able to support the stimulation of [³H]catechol synthesis in striatal slices induced by high potassium concentration. However, compared to the effects with amphetamine, manganese was much less effective than calcium in supporting the stimulation induced by high potassium concentration. These results show that specific divalent cations can support the stimulation of catechol synthesis induced by amphetamine in striatal slices, and suggest that the entry of these specific ions into cells, presumably dopamine neurons, is involved in this action.     

In Vitro Synthesis of Dopamine and Noradrenaline in the Isolated Rat Pineal Gland: Day-Night Variations and Effects of Electrical Stimulation

Isolated rat pineal glands were incubated in vitro in a medium containing [14C]dopamine or [14C]tyrosine, and the tissue contents of 14C-labelled and total dopamine and noradrenaline were determined by HPLC followed by electrochemical detection and scintillation spectrometry. During incubation with [14C]dopamine, the labelled amine accumulated in pineal glands and was partially converted into [14C]noradrenaline. Nomifensine, a neuronal amine uptake blocker, largely inhibited the accumulation of [14C]dopamine and the formation of [14C]noradrenaline. These experiments demonstrated dopamine beta-hydroxylase activity in the sympathetic nerves of the pineal gland. During incubation with [14C]tyrosine, formation of [14C]dopamine and [14C]noradrenaline was observed in the pineal tissue, indicating that noradrenaline can also be synthesized from dopamine, endogenously formed in the gland. Electrical stimulation of the stalk region of the pineal gland during incubation with [14C]dopamine enhanced the accumulation of [14C]dopamine and synthesis of [14C]noradrenaline. Electrical stimulation also enhanced the formation of [14C]dopamine during incubation with [14C]tyrosine. Compared to that at midday, the tissue content of endogenous noradrenaline at midnight was enhanced by 50% and that of dopamine by 450%. The in vitro accumulation of [14C]dopamine, as well as the synthesis of [14C]dopamine and [14C]noradrenaline, was also increased at midnight. In conclusion, sympathetic nerves in the rat pineal gland contain tyrosine hydroxylase and dopamine beta-hydroxylase, the two enzymes required for the synthesis of noradrenaline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Amphibian sympathetic ganglia in tissue culture

1. A culture medium has been developed for amphibian sympathetic nervous tissue but it is suggested that the ionic values should be adjusted to correspond to the concentrations of salts in the plasma of particular species. 2. The morphology, monoamine fluorescence, growth and differentiation of sympathetic ganglia of the frog, Limnodynastes dumerili, have been studied in culture. 3. Two types of neuron could be distinguished largely according to size, namely small, 18 X 20 mum and large, 38 X 42 mum. The possibility that these represent one type at different stages in development or represent functionally distinct neurons is discussed. 4. The sympathetic neurons are extremely sensitive to nerve growth factor (NGF) which caused an increase in the size of the cell bodies, the number of nerve fibres regenerating, the rate of axonal growth and synthesis of catecholamines. 5. Various other cell types appearing in the cultures have been described, including chromaffin, satellite, Schwann, multipolar and epithelial cells as well as fibroblasts, melanocytes and macrophages. The epithelial cells show slow contractions and changes in shape.     

Basal and thyroliberin-stimulated prolactin synthesis in single-cell cultures and in populations of rat pituitary cells.

1. Newly synthesized prolactin was obtained from cultures of rat pituitary tumour cells (GH4C1 cells) after incubation with [35S]methionine. 2. Radioactive synthesized and secreted prolactin was quantified by an immunoprecipitation method by using disc-gel electrophoresis of the dissolved immunoprecipitate in the presence of sodium dodecyl sulphate. By using a microanalytical modification, hormone synthesis and secretion could also be studied in single-cell cultures. This technique was combined with a cytoimmunofluorescence method in which rhodamine-conjugated antibodies were used for studying intracellular prolactin. 3. The presence of radioactive synthesized and secreted prolactin was demonstrated in nine out of 13 single-cell cultures. Cell cultures containing 10 cells or more and clonal populations originating from one cell always secreted radioactive prolactin. 4. Thyroliberin treatment (2 muM) for 24h increased the extracellular accumulation of radioactive prolactin in five out of seven single-cell cultures and always in populations of cells. 5. The number of cells showing prolactin specific fluorescence increased from 20 to 50% and the intensity of this fluorescence became greater after thyroliberin treatment. 6. Studies of [35S]prolactin secretion from single cells and immunochemical detection of intracellular prolactin showed that some cells in an unsynchronized population did not secret radioactive prolactin or show prolactin specific fluorescence. 7. The quantitative effect of thyroliberin as studied in single-cell cultures suggested that the main if not the only effect was to increase prolactin synthesis in cells already producing hormone.     

Relationship ofAzotobacter chrooccum siderophores with nitrogen fixation

In iron-limited medium, a siderophore producing soil isolate ofAzotobacter chroococcum showed a high level of hydroxamate with relatively low level of nitrogen fixation. Inclusion of iron in the medium resulted in increased nitrogen fixation with decreased hydroxamate production. Under shake culture conditions, the level of both hydroxamate and catechol type of siderophores decreased after 2 d of incubation in iron-deficient medium. However, under iron-sufficient conditions, both siderophore production and nitrogen fixation increased with time although the level of siderophore was quite low. A number of soil isolates and mutants ofA. chrococcum were tested for nitrogen fixation, hydroxamate and catechol type of siderophore production. Wide variation was observed in the siderophore level and nitrogen fixation in the cultures tested. Nitrogen fixation was higher in the iron-sufficient medium than in iron-limited one while hydroxamate yield was higher in iron-limited medium than in the iron-sufficient one in all the cultures. Inclusion of ammonium acetate in the medium induced catechol synthesis in more than 60% of the cultures.