Reversion by calcium of a yeast-like development to the original filamentous form, of the 10V10 5-fluorocytosine-sensitive mutant of Aspergillus niger

Goulart, Rosangela de Carvalho; Marin, José Moacir

doi:10.1590/S1517-83822005000300018

Abstracts

Some filamentous fungi present the phenomenon of dimorphism, their morphological structure alterations being capable of inducing metabolism changes. The Aspergillus niger strain 10v10, a producer of citric acid, was submitted to the mutagenic action of ultraviolet irradiation which respectively selects mutants sensitive or resistant to the antifungi agent 5 fluorocytosine (5-FC). 5-FC sensitive mutants presented a morphological alteration to a yeast-like form. The effects of pH changes, addition of salts (KH2PO4, NH4NO3, MgSO4 and MgCl2), the presence of osmotic stabilizers, as well as of calcium chloride, on morphological reversal and acid production were studied. Morphological reversal to the filamentous form was observed only in the presence of CaCl2 (500mM) for the mutants strains 1 and 2, while the acid production occurred in both, yeast-like and filamentous forms.

Aspergillus niger; 5-fluorocytosine; yeast-like; calcium; acid production; dimorphism

Alguns fungos filamentosos apresentam o fenômeno de dimorfismo, sendo que as alterações da estrutura morfológica podem induzir alterações metabólicas. A linhagem de Aspergillus niger 10v10, produtora de ácido cítrico foi submetida à ação mutagênica da radiação ultravioleta selecionando mutantes sensíveis ou resistentes ao antifúngico 5-fluorocitosina (5-FC). Os mutantes selecionados como sensíveis a 5-FC apresentaram uma alteração morfológica com desenvolvimento leveduriforme. Nestes mutantes foram avaliados o efeito da alteração de pH, a adição de sais (KH2PO4, NH4NO3, MgSO4e MnCl2), a presença de estabilizadores osmóticos, cloreto de cálcio, e o seu efeito sobre a reversão morfológica e a produção de ácido. A reversão morfológica para a forma filamentosa ocorreu apenas na presença de CaCl2 (500mM) para as linhagens mutantes 1 e 2, enquanto que a produção de ácido ocorreu nas duas formas, leveduriforme e filamentosa.

Aspergillus niger; 5-fluorocitosina; leveduriforme; cálcio; produção de ácido; dimorfismo

GENERAL MICROBIOLOGY

Reversion by calcium of a yeast-like development to the original filamentous form, of the 10V10 5-fluorocytosine-sensitive mutant of Aspergillus niger

Reversão pelo cálcio de um desenvolvimento leveduriforme para a forma filamentosa original em um mutante sensível a 5-fluorocitosina na linhagem 10V10 de Aspergillus niger

Rosangela de Carvalho Goulart^I; José Moacir Marin^II,^* * Corresponding Author. Mailing address: Departamento de Morfologia, Estomatologia e Fisiologia - USP, Faculdade de Odontologia de Ribeirão Preto, Campus USP. Via do Café, s/n. 14040-904, Ribeirão Preto, SP, Brasil. Fax: (+5516) 633-0999. E-mail: jmmarin@forp.usp.br

^IFaculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, SP, Brasil

^IIDepartamento de Morfologia, Estomatologia e Fisiologia, Faculdade de Odontologia de Ribeirão Preto, Universidade de São Paulo, Ribeirão Preto, SP, Brasil

ABSTRACT

Some filamentous fungi present the phenomenon of dimorphism, their morphological structure alterations being capable of inducing metabolism changes. The Aspergillus niger strain 10v10, a producer of citric acid, was submitted to the mutagenic action of ultraviolet irradiation which respectively selects mutants sensitive or resistant to the antifungi agent 5 fluorocytosine (5-FC). 5-FC sensitive mutants presented a morphological alteration to a yeast-like form. The effects of pH changes, addition of salts (KH₂PO₄, NH₄NO₃, MgSO4 and MgCl₂), the presence of osmotic stabilizers, as well as of calcium chloride, on morphological reversal and acid production were studied. Morphological reversal to the filamentous form was observed only in the presence of CaCl₂ (500mM) for the mutants strains 1 and 2, while the acid production occurred in both, yeast-like and filamentous forms.

Key words:Aspergillus niger, 5-fluorocytosine, yeast-like, calcium, acid production, dimorphism

RESUMO

Alguns fungos filamentosos apresentam o fenômeno de dimorfismo, sendo que as alterações da estrutura morfológica podem induzir alterações metabólicas. A linhagem de Aspergillus niger 10v10, produtora de ácido cítrico foi submetida à ação mutagênica da radiação ultravioleta selecionando mutantes sensíveis ou resistentes ao antifúngico 5-fluorocitosina (5-FC). Os mutantes selecionados como sensíveis a 5-FC apresentaram uma alteração morfológica com desenvolvimento leveduriforme. Nestes mutantes foram avaliados o efeito da alteração de pH, a adição de sais (KH₂PO₄, NH₄NO₃, MgSO₄e MnCl₂), a presença de estabilizadores osmóticos, cloreto de cálcio, e o seu efeito sobre a reversão morfológica e a produção de ácido. A reversão morfológica para a forma filamentosa ocorreu apenas na presença de CaCl₂ (500mM) para as linhagens mutantes 1 e 2, enquanto que a produção de ácido ocorreu nas duas formas, leveduriforme e filamentosa.

Palavras-chave:Aspergillus niger, 5-fluorocitosina, leveduriforme, cálcio, produção de ácido, dimorfismo

INTRODUCTION

Some fungi are dimorphic, presenting two morphological forms, filamentous or yeast-like depending on environmental factors, fungal physiological condition or the fungal genome. They include saprobic forms such as Mycotypha sp, Aspergillus parasiticus and Mucor sp, as well as several important mammalian pathogens such as Blastomyces dermatidis, Histoplasma capsulatum and Sporothrix schenkii (9,11).

Aspergillus niger is a filamentous fungus of high industrial value due to its use in the manufacture of citric acid; it is utilized among others, by the pharmaceutical, alimentary and cosmetic industries. The 10v10 strain of Aspergillus niger has been utilized as a producer of citric acid in surface fermentation processes (2).

Microorganisms deficient in protein synthesis, supply citric acid in higher yields. A frequently utilized technique to promote that deficiency is the employment of antibiotics or antimicotics to obtain protein synthesis resistant, or sensitive microorganism (20). In the presence of cytosine, the antimicotic drug 5-fluorocytosine (5-FC) is carried in to the cell's interior, altering protein and DNA synthesis (5,7).

During the process of selection of 5-FC sensitive mutants, the appearance of yeast-like characteristics among these mutants was noted. The objective of the present work was to evaluate the reversal to the filamentous form of such mutants, and the possible influence of this change on citric acid production.

MATERIALS AND METHODS

Microorganism

Aspergillus niger 10v10, a local citric acid producer used in a surface fermentation process by the industry in the past, kindly supplied by Dr. João Lucio de Azevedo - Escola Superior de Agricultura Luiz de Queiroz/USP, was used as the parental strain to obtain mutants, studied in the present work.

Culture media

Dextrose Sabouraud Agar at 4% (SB 4%) was utilized for strain maintenance. FCL medium (20) containing (g/L): glucose-120, ammonium sulfate-3.0, monobasic potassium phosphate-1.0, dibasic potassium phosphate-1.0, magnesium sulfate-0.5, manganese sulfate-0.014, ferric chloride-0.01, was utilized. The pH was initially adjusted to 3.0, with hydrochloric acid. For the isolation of sensitive or resistant mutants to 5-FC, the FCL medium was supplemented with 5-FC (0.1 µg/mL). The 4% SB medium was also employed to verify the effects of salts and osmotic stabilizers (KCl, MgSO₄ and Sorbitol); to study the effect of calcium on the morphology, 500 mM CaCl₂was added to the medium.

Mutagenesis of the parental strain of A. niger 10V10

Briefly, conidia from 5-7 day old colonies were collected in Tween 80 solution (0.1% v/v) and the suspension adjusted to 10⁶/mL with saline (NaCl 0.85%w/v); 0.5 mL of the conidia suspension plus 9.5 mL of saline was put on a Petri dish and submitted to ultraviolet light treatment (Philips TUV,15w,254nm) for 15 min. under magnetic agitation as described before (12). Ten mL of the irradiated suspension were inoculated into 50 mL of FCL/ 5-FC medium, in 250 mL Erlenmeyer flasks, and incubated for 72 h in a water bath, at 30ºC, with a 125 rpm shaking movement, as described before (20). After each 24 h period, the FCL/5-FC was filtered through glass wool, so that the conidia that had germinated in the presence of 5-FC, would remain in the glass wool to be seeded into the SB/ 5-FC medium. Non-germinated conidia, considered sensitive, were collected from the filtrate; following centrifugation at 10,000 g for 2 min, they were washed with sterile distilled water, suspended in 0.5 mL of the FCL medium and re-inoculated into 50 mL of the FCL/5-FC medium. After completing the 72-h incubation period, the filtrate containing the sensitive conidia was seeded on Petri dishes containing the SB medium, to obtain isolated colonies.

Confirmation of sensitivity or resistance of selected A. niger mutants

Isolated mutants showing yeast-like morphology were inoculated into the 4% SB medium containing 5-FC (0.1 µg/mL) and incubated for 48 h at 30ºC. SB medium without 5-FC, was utilized to evaluate fungi growth. Mutants showing only growth in the 5-FC-free medium were considered to be sensitive to the drug; mutants presenting growth in both SB 4% 5-FC containing and 5-FC-free media were considered to be resistant to the drug. All mutants chosen were maintained on SB 4% plates at 4ºC, following the 48 h, 30ºC growth period.

Effect of pH alteration on chosen mutant strains

Selected yeast-like mutant strains were seeded in 4% SB and the medium pH adjusted with 0.5M HCl or 0.5M NaOH to evaluate growth at pH 4, 6 and 8, respectively. Yeast-like mutants were inoculated and incubated at 37ºC for 48 hours.

Effect of the addition of NH₄NO₃, MgSO₄, MnCl₂and KH₂PO₄

Different salts were added at different concentrations to the 4% SB plated medium as follows: NH₄NO₃(0.4; 0.8; 1.2; 1.6; 2.0; 2.4 g/L); MgSO₄(0.01;0.02; 0.03; 0.04; 0.05; 0.06 g/L); MnCl₂(0.012; 0.018; 0.024; 0.030; 0.036; 0.048 mg/L) and KH₂O₄(0.2; 0.4; 0.8;1.0; 1.2; 1.4 g/L). The yeast-like strains were inoculated into dishes containing the various salt concentrations, incubated at 30ºC and their growth followed for 72 h.

Addition of osmotic stabilizers to the culture medium

The three osmotic stabilizers, KCl 0.6 M, MgSO₄ 1.2 M and Sorbitol 1.2 M, were added to the culture medium and the plates incubated with the yeast-like mutant strain for 72 h at 30ºC.

Effect of CaCl₂

The yeast-like mutant strains were inoculated into 100 mL of the FCL medium containing 500 mM CaCl₂in 250 mL Erlenmeyer flasks, and incubated at 30ºC, with a 125 rpm shaking motion for nine days. The flasks with the cultures were then kept in the laboratory for further observation.

Citric fermentation, determination of titratable acidity and dry weight of the mycelia

Fermentation to citric acid was performed on a laboratory scale by the submerse procedure, using 250mL Erlenmeyer flasks, containing 100 mL of the FCL culture medium, at 30ºC, with constant shaking at 125 rpm, for nine days, in a Dubnoff bath. Following this period of fermentation, the biomass formed was separated from the liquid medium by filtration, washed with distilled water, and maintained in an oven at 98ºC for 24 h; following drying, it was weighed to obtain the weight of the mycelia (16), The determination of the total acidity produced was made by titration with 0.1 N NaOH and a phenolphthalein indicator (20).

RESULTS

Mutagenesis induced by ultraviolet irradiation of the conidia of the parental strain A. niger 10v10, and the inoculation into liquid FCL media containing 5-FC, permitted the isolation of eight mutants of strain 10v10, presenting wrinkled, brain-like colonies with a creamy-like consistency. After secondary subculture, the colonies presented growing bright, smooth, white mucoid aspect, denominated yeast-like. They were classified as 5-FC-sensitive. Nine 5-FC-resistant, filamentous mutants, of sporulated, dark brown to black colored colonies, showing morphological characteristics similar to those of the parental strain of A. niger 10v10, were also isolated, but not utilized in the present work.

The yeast-like mutant strains, were kept in 4% SB medium, and analyzed for the effects of pH changes, addition of salts, of osmotic stabilizers or CaCl₂, as shown on Table 1.

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Mutants strains 1, 2, 5 and 6 were selected to be photographed under the optical microscope during the four following months. Added at a 500-mM concentration, CaCl₂ promoted morphological reversion of the yeast-like mutant strains 1 and 2, to the filamentous condition. As it can be observed in Fig. 1- a, b, ^c and ^d both strains initially showed globular cells, subsequent budding characteristic of the yeast-like state, and finally cell grouping and formation of hyphae, characterizing the filamentous original fungus.

Mutant strains 5 and 6 presented a microscopic appearance, which remained unchanged during the four months of the photographic follow- up. The cylindrical cell aspect can be seen on Fig. 1(e and f).

The parental strain of A. niger 10v10 was developed to be utilized in processes of surface fermentation (2). In the present work, the submerged fermentation process was utilized, the parental strain serving as control. After nine days of fermentation, the dry weight of the mycelium of each mutant yeastlike strain and the accumulation of the titratable acidity produced, were measured (Table 2). Only the four selected mutants (1,2,5,6) were evaluated.

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The yield of acid produced by the strains which underwent morphological reversal from the yeast-like to the filamentous form, was greater in the filamentous form for mutant 1 than in the yeast-like form and smaller in the filamentous form for mutant 2 than in the yeast-like form (Table 2). The dry weight of strain 1 presented only a slight variation according to their morphological state however, strain 2 when in the filamentous form, showed a significant increase in dry weight (Table 2).

DISCUSSION

Studies of great importance, involving pathogenic fungi have been centered on the investigation of dimorphism, employing the technique of inducing hyphae growth and examination of one or more of their specific properties (1,3). Factors inducing hyphae development of C. albicans are quite varied, and include pH, minerals, vitamins, amino acids and carbohydrates (11).The pH and temperature activate genetic elements related to fungi morphology, that regulate the formation of either yeast-like, or filamentous forms. Yeast-like cells of C. albicans grow at pH 4.5 and 25ºC, while filamentous growth is induced by pH 6.8 at 37ºC. Penicillium marnefei grows in culture at 25ºC on Sabouraud agar as a mycelial fungus, typical of the genus; however, it shows yeast-like cells when growing at 37ºC in vitro on appropriate media, or in vivo in infected animals and humans (19).Generally, in vitro conditions used to induce hyphae formation require a pH close to neutrality (3,19).

Change of pH to 4, 6 or 8, and of temperature to 37ºC, tested in this work, did not yield filamentous development by mutant yeast-like strains of A. niger 10v10; this does not agree with the results obtained by others (3,19), that verified the expression of morphology changes associated to pH.

No morphological reversal was observed by us in the presence of various concentrations of MgSO₄, MnCl₂or KH₂PO₄, that permitted yeast-like development of the strains studied. The salts tested are related to the yield of citric acid production and some morphological changes of the fungi, observed in their presence or absence. Several authors (4,13,21,22) have verified such morphological alterations.

Osmotic stabilizers are widely used to maintain protoplasm integrity following the removal of the cell wall. Among the most common ones utilized, are inorganic salts, sugars and sugar alcohols. In general, inorganic salts have been proven to be most efficient for yeasts (24). In the presently studied mutant strains, KCl, Sorbitol and MgSO₄, useful as osmotic stabilizers, did not lead to morphological reversion.

Detroy and Ciegler (4), verified hyphae - yeast-like dimorphism in Aspergillus parasiticus in respectively, the presence or absence of manganese ions in the culture medium, observing also that the addition of amino acids, vitamins, and traces of other metals did not induce significant effects on morphogenetic development_. The cultures were mostly yeast-like in the presence of 7.3x10^-4mM manganese; however, high manganese concentrations resulted in hyphae formation.

Calcium is an important element for growth, metabolism and differentiation of several fungi and yeasts (6,23). It participates in multiple regulatory functions including sporulation, ramification, tip growth and hyphae reorientation, direction of localized stimuli, bud germination, regulation of dimorphism, sexual reproduction and control of the cell cycle has been described (23). At high concentration, calcium is toxic; for this reason, cells utilize a complex homeostatic system to maintain low levels of calcium concentration (6).

Pera and Callieri (18), verified that the addition of 0.5 g/L of CaCl₂ to the culture medium, promoted an increase in mycelium ramification in the filamentous strain of A. niger. The presence of short and tall ramifications of the hyphae, stimulated pellet formation, as it was also observed by others (10,15).

Madi et al. (14) studied the effect of the addition of calcium to cultures of Aureobasidium pullulans, In the presence of low

Ca²⁺concentrations, increased formation of yeast-like cells and reduced morphology transition were observed. When the concentration of Ca²⁺ was raised, the development of a 3-4 mm diameter pellet was observed, with a predominance of filamentous development. In the present study, 500-mM CaCl₂ induced the formation of hyphae in yeastlike mutant strains of A. niger 10v10. It must be observed that the induction of yeast-like mutants was found only for the 10v10 strain; other strains like N402 (8) did not show this effect after the same treatment, even if repeated several times.

A long time interval, of approximately 120 days, was required to obtain the yeast-like reversion to filamentous form, as also observed by Paula et al.(17) who, in their experiments, obtained morphological reversion of Scopulariosis brevicaulis after a two-month period of cultivation. This indicated that the strains remained for a long time in a transition state, of partial reversal. In the present study, strains 5 and 6 did not show reversal after four months, indicating that their morphological stability remained in a transition phase between filament and yeast, as also previously verified (17).

5-FC employed in chemotherapy of systemic candidiasis, interferes with nucleic acid synthesis. It is taken into fungal cells by a cytosine permease, deaminated to 5-fluorouracil, converted to the nucleosideo triphosphate and incorporated into RNA, where it causes miscoding. In addition, 5-FC is converted to deoxynucleoside, which inhibits thymidylate synthase and thereby DNA biosynthesis (7).However, there still exist doubts about its side effects.

Acid production, a characteristic of the A. niger 10v10 strain, was found both in the yeast-like mutants, and in the revertant filamentous form (Table 2).

In summary, this study shows the induction of the yeast-like development in A. niger strain 10v10 and its reversion to filamentous morphology in some mutants, in the presence of 500mM calcium chloride.

ACKNOWLEDGEMENT

The authors thank the National Council for Technological Development- CNPq, Brazil, for a scholarship to R.C.G.

Submitted: June 01, 2004; Returned to authors for corrections: July 18, 2005; Approved: September 12, 2005

1. Blas, G.S. Fungi pathogenic to humans: molecular aspects of dimorphism. In: Orora, D.K.; Ajello, L.; Mukurji, K.J. (Ed). Handbook of applied mycology, humans, animals and insect, v.2New York: Marcel Dekker, 1991.
2. Bonatelli Jr., R; Azevedo, J.L.; Valent, G.U. Parasexuality in a citric acid producing strains of Aspergillus niger Rev. Brasil. Genet., 6(30), 399-405, 1983.
3. Buffo, J.; Herman, M.A.; Soll, D.R. A characterization of pH-regulated dimorphism in Candida albicans, Mycopathology, 85(1-2), 21-30, 1984.
4. Detroy, R.W.; Ciegler, A. Induction of yeastlike development in Aspergillus parasiticus J. Gen. Microbiol., 65, 259-264, 1971.
5. Diasio, R.B.; Benett, J.E.; Myers, C.E. Mode of action of 5- fluorocytosine. Biochem. Pharmacol, 27, 703-707, 1978.
6. Gadd, G.; Brunton, A.H. Calcium involvement in dimorphism of Ophiostoma ulmi, the dutch elm disease fungus, and characterization of calcium uptake by yeast cells and germ tubes. J. Gen. Microbiol., 138, 1561-1571, 1992.
7. Georgopapadakou, N.H.; Walsh, T.J. Antifungal agents: chemotherapeutic targets and immunologic strategies.Ant. agents Chemoth.,40(2), 279-291, 1996.
8. Goosen, T.; Bloemheuvel, G.; Gysler, C.; Bie, D.A.; van den Broek, H.W.J.; Swart, K. Transformation of Aspergillus niger using the homologous orotidine-5-fosphate-decarboxylase gene. Curr. Genet., 11, 499-503, 1987.
9. Griffin, D.H. Fungal Physiology Wiley-Liss, New York, USA, 1994.
10. Haq, I.U; Ali, S.; Qadeer, M.A.; Iqbal, J. Effect of copper íons on mould morphology and citric acid productivity by Aspergillus niger using molasses based media. Process Biochem., 37, 1085-1090, 2002.
11. Kerridge, D. Fungal dimorphism: a sideways look. In: Bossche, H.V.; Odds, F.C.; Kerridge, D. (Ed). Dimorphic fungi in biology and medicine. New York: Plenum Press, 1993, p.3-10.
12. Kirimura, K.; Sarangbin, S.; Rugsaseel, S.; Usami, S. Citric acid production by 2-deoxyglucose-resistant mutant strains of Aspergillus niger Appl. Microbiol. Biotechnol., 36, 573-577, 1992.
13. Kisser, M.; Kubicek, C.P.; Rohr, M. Influence of manganese on morphology and cell wall composition of Aspergillus niger during citric acid fermentation.Arch. Microbiol., 128, 26-33, 1980.
14. Madi, N.; Mcneil, B.; Harvey, L.M. Effect of exogenous calcium on morphological development and biopolymer synthesis in the fungus Aureobasidium pullulans.Enzymol. Microbiol. Technol.,21, 102-107, 1997.
15. Metz, B.; Kossen, N.W.F. The growth of mould in the form of pellet. Biotech. Bioeng, 19, 781-799, 1977.
16. Netto, G.S.O.F.; Rosato, Y.B. Influence of nitrogen source on development of two strains of Aspergillus nidulans Rev. Microbiol., 18(1), 83-86, 1987.
17. Paula, C.R.; Purchio, A.; Gambale, W.; Correa, B. Dimorphism of Scopulariopsis brevicaulis: morphogenesis of the mould to yeast phase. Mycopathology, 100, 69-74, 1987.
18. Pera, L.M.; Callieri, D.A. Influence of calcium on fungal growth and citric acid production during fermentation of a sugarcane molasses-based medium by a strain of Aspergillus nigerWorld J. Microbiol. Biotech., 15, 647-649,1999.
19. Pitt, J.I. The genus Penicillium and its teleomorphic states Eupenicillium and Talaromyces Academic Press, New York, 1979.
20. Rugsaseel, S.; Kirimura, K.; Usami, S. Citric acid accumulation by cycloheximide-sensitive mutant strains of Aspergillus niger Appl. Microbiol. Biotech., 45, 28-35, 1996.
21. Shu, P.; Johnson, M.J. Effect of the composition of the sporulation medium on citric acid production by Aspergillus niger in submerged culture.J. Bacteriol, 54, 161-167, 1947.
22. Tomlinson, N.; Campbell, J.J.R.; Trussel, P.C. The influence of zinc, iron, copper and manganese on the production of citric acid by Aspergillus niger J. Bacteriol, 59, 217-227, 1950.
23. Torralba, S.; Heath, J.B. Cytoskeletal and Ca²⁺ regulation of hyphal tip growth and initiation. Curr. Develop. Biol., 51, 135-187, 2001.
24. Turner, G.; Balance, D.J. Cloning and Transformation in Aspergillus in gene Manipulations in Fungi (Ed) Bennett, J.W.; Lasure, L.L. Academic Press, Orlando USA, 1985.

*

Corresponding Author. Mailing address: Departamento de Morfologia, Estomatologia e Fisiologia - USP, Faculdade de Odontologia de Ribeirão Preto, Campus USP. Via do Café, s/n. 14040-904, Ribeirão Preto, SP, Brasil. Fax: (+5516) 633-0999. E-mail:

jmmarin@forp.usp.br

Publication Dates

Publication in this collection
20 Feb 2006
Date of issue
Sept 2005

History

Accepted
12 Sept 2005
Reviewed
18 July 2005
Received
01 June 2004

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Blas, G.S. Fungi pathogenic to humans: molecular aspects of dimorphism. In: Orora, D.K.; Ajello, L.; Mukurji, K.J. (Ed). Handbook of applied mycology, humans, animals and insect, v.2New York: Marcel Dekker, 1991.

[2] 2. Bonatelli Jr., R; Azevedo, J.L.; Valent, G.U. Parasexuality in a citric acid producing strains of Aspergillus niger Rev. Brasil. Genet., 6(30), 399-405, 1983.

[3] 3. Buffo, J.; Herman, M.A.; Soll, D.R. A characterization of pH-regulated dimorphism in Candida albicans, Mycopathology, 85(1-2), 21-30, 1984.

[4] 4. Detroy, R.W.; Ciegler, A. Induction of yeastlike development in Aspergillus parasiticus J. Gen. Microbiol., 65, 259-264, 1971.

[5] 5. Diasio, R.B.; Benett, J.E.; Myers, C.E. Mode of action of 5- fluorocytosine. Biochem. Pharmacol, 27, 703-707, 1978.

[6] 6. Gadd, G.; Brunton, A.H. Calcium involvement in dimorphism of Ophiostoma ulmi, the dutch elm disease fungus, and characterization of calcium uptake by yeast cells and germ tubes. J. Gen. Microbiol., 138, 1561-1571, 1992.

[7] 7. Georgopapadakou, N.H.; Walsh, T.J. Antifungal agents: chemotherapeutic targets and immunologic strategies.Ant. agents Chemoth.,40(2), 279-291, 1996.

[8] 8. Goosen, T.; Bloemheuvel, G.; Gysler, C.; Bie, D.A.; van den Broek, H.W.J.; Swart, K. Transformation of Aspergillus niger using the homologous orotidine-5-fosphate-decarboxylase gene. Curr. Genet., 11, 499-503, 1987.

[9] 9. Griffin, D.H. Fungal Physiology Wiley-Liss, New York, USA, 1994.

[10] 10. Haq, I.U; Ali, S.; Qadeer, M.A.; Iqbal, J. Effect of copper íons on mould morphology and citric acid productivity by Aspergillus niger using molasses based media. Process Biochem., 37, 1085-1090, 2002.

[11] 11. Kerridge, D. Fungal dimorphism: a sideways look. In: Bossche, H.V.; Odds, F.C.; Kerridge, D. (Ed). Dimorphic fungi in biology and medicine. New York: Plenum Press, 1993, p.3-10.

[12] 12. Kirimura, K.; Sarangbin, S.; Rugsaseel, S.; Usami, S. Citric acid production by 2-deoxyglucose-resistant mutant strains of Aspergillus niger Appl. Microbiol. Biotechnol., 36, 573-577, 1992.

[13] 13. Kisser, M.; Kubicek, C.P.; Rohr, M. Influence of manganese on morphology and cell wall composition of Aspergillus niger during citric acid fermentation.Arch. Microbiol., 128, 26-33, 1980.

[14] 14. Madi, N.; Mcneil, B.; Harvey, L.M. Effect of exogenous calcium on morphological development and biopolymer synthesis in the fungus Aureobasidium pullulans.Enzymol. Microbiol. Technol.,21, 102-107, 1997.

[15] 15. Metz, B.; Kossen, N.W.F. The growth of mould in the form of pellet. Biotech. Bioeng, 19, 781-799, 1977.

[16] 16. Netto, G.S.O.F.; Rosato, Y.B. Influence of nitrogen source on development of two strains of Aspergillus nidulans Rev. Microbiol., 18(1), 83-86, 1987.

[17] 17. Paula, C.R.; Purchio, A.; Gambale, W.; Correa, B. Dimorphism of Scopulariopsis brevicaulis: morphogenesis of the mould to yeast phase. Mycopathology, 100, 69-74, 1987.

[18] 18. Pera, L.M.; Callieri, D.A. Influence of calcium on fungal growth and citric acid production during fermentation of a sugarcane molasses-based medium by a strain of Aspergillus nigerWorld J. Microbiol. Biotech., 15, 647-649,1999.

[19] 19. Pitt, J.I. The genus Penicillium and its teleomorphic states Eupenicillium and Talaromyces Academic Press, New York, 1979.

[20] 20. Rugsaseel, S.; Kirimura, K.; Usami, S. Citric acid accumulation by cycloheximide-sensitive mutant strains of Aspergillus niger Appl. Microbiol. Biotech., 45, 28-35, 1996.

[21] 21. Shu, P.; Johnson, M.J. Effect of the composition of the sporulation medium on citric acid production by Aspergillus niger in submerged culture.J. Bacteriol, 54, 161-167, 1947.

[22] 22. Tomlinson, N.; Campbell, J.J.R.; Trussel, P.C. The influence of zinc, iron, copper and manganese on the production of citric acid by Aspergillus niger J. Bacteriol, 59, 217-227, 1950.

[23] 23. Torralba, S.; Heath, J.B. Cytoskeletal and Ca²⁺ regulation of hyphal tip growth and initiation. Curr. Develop. Biol., 51, 135-187, 2001.

[24] 24. Turner, G.; Balance, D.J. Cloning and Transformation in Aspergillus in gene Manipulations in Fungi (Ed) Bennett, J.W.; Lasure, L.L. Academic Press, Orlando USA, 1985.

Brasil

Brasil

Reversion by calcium of a yeast-like development to the original filamentous form, of the 10V10 5-fluorocytosine-sensitive mutant of Aspergillus niger

Reversão pelo cálcio de um desenvolvimento leveduriforme para a forma filamentosa original em um mutante sensível a 5-fluorocitosina na linhagem 10V10 de Aspergillus niger

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