Cytotoxic Effect of Prodigiosin,Natural Red Pigment,Isolated from Serratia marcescens UFPEDA 398

Prodigiosin is a secondary metabolite, with red pigmentation, produced by Serratia marcescens. Red pigment is a natural alkaloid whose chemical structure has three pyrrole rings. Prodigiosin has been described for several biological activities, including antitumor, inducing apotosis in T and B lymphocytes. This work aimed to evaluate the cytotoxic activity of prodigiosin in NCHI-292, HEp-2, MCF-7 and HL-60 tumor cell lines. The red pigment was isolated from Serratia marcescens UFPEDA 398 biomass whose fractions were previously separated by column chromatography, purified, identified and further characterized by GC–MS and compared with the computerized library of m/z values. The pigment corresponded to prodigiosin with maximum absorption at 534 nm, molecular weight 323 and structural formula C20H25N3O. During the prodigiosin purification process a purple absorbance fraction at 272.65 nm was also observed. Significant cytotoxic effects of prodigiosin were evidenced for NCHI-292, Hep-2, MCF-7 and HL-60 tumor cell lines. The isolated purple fraction had no cytotoxic effect (IC50 11.3 µg/mL) when compared to prodigiosin (IC50 3.4 µg/mL) for the tumor cell lines studied. The MCF-7 strain was slightly more pigment resistant (IC50 5.1 µg/mL). Therefore, further studies will be needed to elucidate the antitumor mechanisms of prodigiosin action against tumor strains from flow cytometry tests. However, although these data are preliminary, it was evidenced that prodigiosin showed cytotoxic activity in tumor cell lines suggesting promising antitumor properties. In this sense, future studies on the cytotoxic and genotoxic effects of prodigiosin produced by S. marcecsens UFPEDA 398 are suggested.     

A prodiginine pigment toxic to embryos and larvae of Crassostrea virginica

The red pigment produced by a marine Pseudomonas sp. which causes abnormal development and mortality in developing embryos of the American oyster, Crassostrea virginica, was analyzed. A comparative study of a nonpigmented and two pigmented mutants of the red parental strain indicated that virulence was associated and varied with pigmentation. The use of sonicated cells supported lysing of the pseudomonad cells as the most probable means of pigment release. Crude pigment extracted from the red parental strain and its yellow mutant was toxic to developing oyster embryos. Neither the “pigment” extracted from the white mutant nor dimethyl sulfoxide, used for dissolving the extract, was toxic. Three pigment fractions were demonstrated by thin-layer chromatography even after purification. Studies indicate that only the fraction corresponding to R₁ 0.41 was necessary for virulence. The virulent pigment fraction was identified as belonging to the prodiginine group.     

Pigmentation and Acriflavine Resistance in Serratia marcescens

Stable, orange, acriflavine-resistant variants were selected by treatment of a wild-type, red, acriflavine-sensitive strain of Serratia marcescens with acriflavine. Visible, ultraviolet, infrared, and nuclear magnetic resonance spectra of purified pigment from the red strain were identical to those of the pigment from the orange strain, and the orange mutant was not due to a mutation affecting the structure of the pigment, prodigiosin. The color of the red strain was not affected by variations in pH between 5.0 and 8.0, whereas the color of the orange mutant changed from pink to orange over the same pH range. This variation was mimicked by the pH-induced variation in color of prodigiosin purified from either the red, wild-type or the orange, mutant strains. Density-gradient centrifugation of cell fragments after ultrasonic disintegration resulted in characteristic pigmented bands. Biochemical characterization of these pigmented bands showed that they contained pigment and a protein component, but no lipids, polysaccharides, sugars, glucosamine, or phosphates were detected. Further fractionation of these pigmented bands by zone electrophoresis on a sucrose density gradient indicated that some pigment in S. marcescens was specifically attached to protein components.     

Kinetic analysis of growth rate, ATP, and pigmentation suggests an energy-spilling function for the pigment prodigiosin of Serratia marcescens

Serratia marcescens is a gram-negative environmental bacterium and opportunistic pathogen. S. marcescens expresses prodigiosin, a bright red and cell-associated pigment which has no known biological function for producing cells. We present here a kinetic model relating cell, ATP, and prodigiosin concentration changes for S. marcescens during cultivation in batch culture. Cells were grown in a variety of complex broth media at temperatures which either promoted or essentially prevented pigmentation. High growth rates were accompanied by large decreases in cellular prodigiosin concentration; low growth rates were associated with rapid pigmentation. Prodigiosin was induced most strongly during limited growth as the population transitioned to stationary phase, suggesting a negative effect of this pigment on biomass production. Mathematically, the combined rate of formation of biomass and bioenergy (as ATP) was shown to be equivalent to the rate of prodigiosin production. Studies with cyanide inhibition of both oxidative phosphorylation and pigment production indicated that rates of biomass and net ATP synthesis were actually higher in the presence of cyanide, further suggesting a negative regulatory role for prodigiosin in cell and energy production under aerobic growth conditions. Considered in the context of the literature, these results suggest that prodigiosin reduces ATP production by a process termed energy spilling. This process may protect the cell by limiting production of reactive oxygen compounds. Other possible functions for prodigiosin as a mediator of cell death at population stationary phase are discussed.     

Prodigiosin-like Pigments from Actinomadura (Nocardia) pelletieri and Actinomadura madurae

Thirteen red strains of Actinomadura (Nocardia) pelletieri and three of A. madurae were shown to produce prodigiosin-like pigments. Both of the two major pigments which were observed on thin-layer chromatograms had R_F values significantly greater than prodigiosin. The main pigment from A. madurae 953 was shown by mass and nuclear magnetic resonance spectroscopies to be nonylprodigiosin. The major pigment from A. pellitieri had a C₁₁H₂₂ side chain in a ring form, but it was distinctly different from metacycloprodigiosin. “Prodiginine” was proposed as a name for the invariant aromatic portion of the prodigiosin structure.     

Water-Soluble Red Pigment Production by <Emphasis Type="Italic">Paecilomyces sinclairii</Emphasis> and Biological Characterization

Natural pigments have several advantages over synthetic colorants. In this study, the production of red pigment produced by Paecilomyces sinclairii in microbial fermentation was demonstrated and the pigment was purified and characterized. The red pigment was produced from submerged fungal fermentation and fractionated by medium pressure flash chromatography. After fractionation, the spectrophotometric characterization of the red pigment revealed an λ_max at 520 nm. Antimicrobial activity of the red pigment fraction was also studied against Escherichia coli O157 and Pseudomonas aeruginosa PAO1. The fraction (F2-F6) of the red pigment exhibited broad-spectrum antimicrobial activity in both bacteria. These results demonstrate the potential of this pigment in inhibiting bacterial growth and in food processing and other foodrelated applications.     

A reduction in temperature induces bioactive red pigment production in a psychrotolerant Penicillium sp. GEU_37 isolated from Himalayan soil

Filamentous fungi are being globally explored for the production of industrially important bioactive compounds including pigments. In the present study, a cold and pH tolerant fungus strain Penicillium sp (GEU_37), isolated from the soil of Indian Himalaya, is characterized for the production of natural pigments as influenced by varying temperature conditions. The fungal strain produces a higher sporulation, exudation, and red diffusible pigment in Potato Dextrose (PD) at 15 °C as compared to 25 °C. In PD broth, a yellow pigment was observed at 25 °C. While measuring the effect of temperature and pH on red pigment production by GEU_37, 15 °C and pH 5, respectively, were observed to be the optimum conditions. Similarly, the effect of exogenous carbon and nitrogen sources and mineral salts on pigment production by GEU_37 was assessed in PD broth. However, no significant enhancement in pigmentation was observed. Chloroform extracted pigment was separated using thin layer chromatography (TLC) and column chromatography. The two separated fractions i.e., fractions I and II with Rf values 0.82 and 0.73, exhibited maximum light absorption, λ_max, at 360 nm and 510 nm, respectively. Characterization of pigments using GC–MS showed the presence of the compounds such as phenol, 2,4-bis (1,1-dimethylethyl) and eicosene from fraction I and derivatives of coumarine, friedooleanan, and stigmasterole in fraction II. However, LC-MS analysis detected the presence of derivatives of compound carotenoids from fraction II as well as derivative of chromenone and hydroxyquinoline as major compounds from both the fractions along with other numerous important bioactive compounds. The production of such bioactive pigments under low temperature conditions suggest their strategic role in ecological resilience by the fungal strain and may have biotechnological applications.     

Chromatographic Separation of the Pigment Fractions from a Serratia marcescens Strain

A procedure was developed for the separation of pigment fractions in a wild-type Serratia marcescens strain. Separation was achieved by column chromatography and elution with several organic solvents. At least six pigment fractions were obtained from the alumina columns by this technique, whereas only four fractions had been reported previously. Spectral and elemental analyses indicate that, in S. marcescens, prodigiosin is a complex of six fractions, differing in absorption spectra while retaining the general characteristics of the whole pigment.     

Genome-Wide Screening and Identification of Factors Affecting the Biosynthesis of Prodigiosin by Hahella chejuensis,Using Escherichia coli as a Surrogate Host

A marine bacterium, Hahella chejuensis, recently has attracted attention due to its lytic activity against a red-tide dinoflagellate. The algicidal function originates from its red pigment, prodigiosin, which also exhibits immunosuppressive or anticancer activity. Genome sequencing and functional analysis revealed a gene set contained in the hap gene cluster that is responsible for the biosynthesis of prodigiosin. To screen for the factors affecting the prodigiosin biosynthesis, we constructed a plasmid library of the H. chejuensis genomic DNA, introduced it into Escherichia coli strains harboring the hap cluster, and observed changes in production of the red pigment. Among the screened clones, hapXY genes whose products constitute a two-component signal transduction system were elucidated as positive regulators of the pigment production. In addition, an Hfq-dependent, noncoding region located at one end of the hap cluster was confirmed to play roles in regulation. Identification of factors involved in the regulation of prodigiosin biosynthesis should help in understanding how the prodigiosin-biosynthetic pathway is organized and controlled and also aid in modulating the overexpression of prodigiosin in a heterologous host, such as E. coli, or in the natural producer, H. chejuensis.Harmful algal blooms (HABs), commonly called red tide, are a phenomenon in which toxin-producing marine algae rapidly proliferate in the offshore area. The HAB-causing phytoplanktons are reported to interact with other organisms such as bacteria and fungi. Among them, the marine bacteria are known to play important roles in decreasing or developing HABs (3, 5, 14). For instance, Hahella chejuensis, isolated from the coastal area of Marado in South Korea (15), is capable of killing Cochlodinium polykrikoides (12). C. polykrikoides is a major microalga that causes HABs, especially in the Northeast Pacific coastal area (8). The bacterial determinant that kills C. polykrikoides was further characterized as a red pigment referred to as prodigiosin (12). Prodigiosin belongs to a family of tripyrrole antibiotic molecules called prodiginines, which have potential as anticancer agents or immunosuppressants (24). The prodigiosin congener isolated from H. chejuensis also exerts an immunosuppressive effect (11).Through completed genome sequencing of H. chejuensis and its functional analysis, the genomic region involved in biosynthesis of prodigiosin was elucidated (12). This complete set of prodigiosin-biosynthetic genes was named the hap gene cluster. The red pigment prodigiosin was further characterized structurally, and the biosynthetic pathway was proposed by Kim and colleagues (13, 14). Genes of the hap cluster share homology with those in the pig cluster and the red cluster which are involved in prodiginine-biosynthetic intermediates of Serratia marcescens and Streptomyces coelicolor, respectively (7, 23, 25). Enzymes encoded by the genes in the pig and red clusters have been characterized (24). However, gene expression of the hap cluster can be tightly controlled, based on the observation that heterologous expression of the hap cluster alone failed to produce the pigment in Escherichia coli. The recombinant E. coli was able to produce the pigment only when the culture filtrate of H. chejuensis was added to the growth media (12). This result indicates that another regulatory cue is needed for prodigiosin biosynthesis, which prompted us to search for regulatory factors that modulate prodigiosin biosynthesis in H. chejuensis.In this study, regulatory factors for biosynthesis of prodigiosin in H. chejuensis were identified by functional screening. To search for such factors, a plasmid library derived from the genomic DNA of H. chejuensis was constructed and transformed into E. coli strains carrying the hap cluster. In the cases of Serratia marcescens and Streptomyces coelicolor, molecular inputs, such as cell-produced quorum-sensing signal molecules or two-component systems (TCSs) for signal transduction, have been verified as key regulatory signals for prodigiosin biosynthesis so far (4, 9, 10, 20-22). Similarly, some clones of interest uncovered in this study include molecular factors such as those that belong to the TCS. Also, we elucidated that an apparently noncoding region in the hap cluster functions as a key factor of prodigiosin biosynthesis.     

Propionibacterium jensenii Produces the Polyene Pigment Granadaene and Has Hemolytic Properties Similar to Those of Streptococcus agalactiae

The red polyene pigment granadaene was purified and identified from Propionibacterium jensenii. Granadaene has previously been identified only in Streptococcus agalactiae, where the pigment correlates with the hemolytic activity of the bacterium. A connection between hemolytic activity and the production of the red pigment has also been observed in P. jensenii, as nonpigmented strains are nonhemolytic. The pigment and hemolytic activity from S. agalactiae can be extracted from the bacterium with a starch extraction solution, and this solution also extracts the pigment and hemolytic activity from P. jensenii. A partial purification of the hemolytic activity was achieved, but the requirement for starch to preserve its activity made the purification unsuccessful. Partially purified hemolytic fractions were pigmented, and the color intensity of the fractions coincided with the hemolytic titer. The pigment was produced in a soluble form when associated with starch, and the UV-visual spectrum of the extract gave absorption peaks of 463 nm, 492 nm, and 524 nm. The pigment could also be extracted from the cells by a low-salt buffer, but it was then aggregated. The purification of the pigment from P. jensenii was performed, and mass spectrometry and nuclear magnetic resonance analysis revealed that P. jensenii indeed produces granadaene as seen in S. agalactiae.     

Optimized prodigiosin production with Pseudomonas putida KT2440 using parallelized noninvasive online monitoring

The red pigment prodigiosin is of high pharmaceutical interest, due to its potential applications as an antitumor drug and antibiotic agent. As previously demonstrated, Pseudomonas putida KT2440 is a suitable host for prodigiosin production, as it exhibits high tolerance toward the antimicrobial properties of prodigiosin. So far, prodigiosin concentrations of up to 94 mg/L have been achieved in shake flask cultivations. For the characterization and optimization of the prodigiosin production process, the scattered light of P. putida and fluorescence of prodigiosin was measured. The excitation and emission wavelengths for prodigiosin measurement were analyzed by recording 2D fluorescence spectra. The strongest prodigiosin fluorescence was obtained at a wavelength combination of 535/560 nm. By reducing the temperature to 18 °C and using 16 g/L glucose, the prodigiosin concentration was more than doubled compared with the initial cultivation conditions. The obtained results demonstrate the capabilities of parallelized microscale cultivations combined with noninvasive online monitoring of fluorescence for rapid bioprocess development, using prodigiosin as a molecule of current biotechnological interest.     

灵杆菌合成灵菌红素的转录调控

灵菌红素是一种具有多种生物活性的红色素,具有巨大的经济价值和广阔的应用前景。灵杆菌是灵菌红素的生产菌株,同时也是研究灵菌红素合成的模式菌株。本文综述了转录水平上调控灵杆菌合成灵菌红素的研究进展,总结了双(多)组分调控系统、群体感应系统、σ因子和转录因子在调控灵杆菌合成灵菌红素过程中发挥的作用,并对未来的研究方向进行了展望。     

Incorporation of methionine into prodigiosin

Addition of proline to suspensions of nonpigmented, nonproliferating cells of Serratia marcescens induced biosynthesis of the pigment, prodigiosin. If methionine was included with proline, 4 times as much prodigiosin was formed, although the amount synthesized in the presence of methionine alone was nil. Uniformly ¹⁴C-labelled proline and methionine were incorporated into prodigiosin to about 30% the extent of their incorporation into cellular protein. Experiments with [carboxy-¹⁴C]-, and [Me-¹⁴C] methionine established that isotope from the methyl group was utilized preferentially for biosynthesis of prodigiosin.     

Influence of Environmental Factors and Medium Composition on Vibrio gazogenes Growth and Prodigiosin Production

Vibrio gazogenes ATCC 29988 growth and prodigiosin synthesis were studied in batch culture on complex and defined media and in chemostat cultures on defined medium. In batch culture on complex medium, a maximum growth rate of 0.75 h⁻¹ and a maximum prodigiosin concentration of 80 ng of prodigiosin · mg of cell protein⁻¹ were observed. In batch culture on defined medium, maximum growth rates were lower (maximum growth rate, 0.40 h⁻¹), and maximum prodigiosin concentrations were higher (1,500 ng · mg of protein⁻¹). In batch culture on either complex or defined medium, growth was characterized by a period of logarithmic growth followed by a period of linear growth; on either medium, prodigiosin biosynthesis was maximum during linear growth. In batch culture on defined medium, the initial concentration of glucose optimal for growth and pigment production was 3.0%; higher levels of glucose suppressed synthesis of the pigment. V. gazogenes had an absolute requirement for Na⁺; optimal growth occurred in the presence of 100 mM NaCl. Increases in the concentration of Na⁺ up to 600 mM resulted in further increases in the concentration of pigment in the broth. Prodigiosin was synthesized at a maximum level in the presence of inorganic phosphate concentrations suboptimal for growth. Concentrations of KH₂PO₄ above 0.4 mM caused decreased pigment synthesis, whereas maximum cell growth occurred at 1.0 mM. Optimal growth and pigment production occurred in the presence of 8 to 16 mg of ferric ion · liter⁻¹, with higher concentrations proving inhibitory to both growth and pigment production. Both growth and pigment production were found to decrease with increased concentrations of p-aminobenzoic acid. The highest specific concentration of prodigiosin (3,480 ng · mg protein⁻¹) was observed in chemostat cultures at a dilution rate of 0.057 h⁻¹. The specific rate of prodigiosin production at this dilution rate was approximately 80% greater than that observed in batch culture on defined medium. At dilution rates greater than 0.057 h⁻¹, the concentration of cells decreased with increasing dilution rate, resulting in a profile comparable to that expected for linear growth kinetics. No explanation could be found for the linear growth profiles obtained for both batch and chemostat cultures.     

Cyclic-AMP inhibition of fimbriae and prodigiosin production by Serratia marcescens is strain-dependent

The cyclic-nucleotide 3′,5′-cyclic AMP (cAMP) is an ancient and widespread regulatory molecule. Previous studies have shown that fimbria production and secondary metabolite production are inhibited by cAMP in the prokaryote Serratia marcescens. This study used genetic manipulations to test the strain specificity of cAMP–cyclic-AMP receptor protein regulation of fimbria production and of the red pigment, prodigiosin. A surprising amount of variation was observed, as multicopy expression of the cAMP-phosphodiesterase gene, cpdS, conferred either an increase or decrease in fimbriae-dependent yeast agglutination and prodigiosin production depending upon the strain background. Mutation of crp, the gene coding for the cAMP-receptor protein, similarly conferred strain-dependent phenotypes. This study shows that three distinct biological properties, modulated by a conserved genetic regulatory molecule, can vary significantly among strains. Such variation can complicate the functional analysis of bacterial phenotypic properties which are dependent upon global genetic regulators such as cAMP.     

Prodigiosin from <Emphasis Type="BoldItalic">Vibrio</Emphasis> sp. DSM 14379; A New UV-Protective Pigment

Pigments such as melanin, scytonemin and carotenoids protect microbial cells against the harmful effects of ultraviolet (UV) radiation. The role in UV protection has never been assigned to the prodigiosin pigment. In this work, we demonstrate that prodigiosin provides a significant level of protection against UV stress in Vibrio sp. DSM 14379. In the absence of pigment production, Vibrio sp. was significantly more susceptible to UV stress, and there was no difference in UV survival between the wild-type strain and non-pigmented mutant. The pigment’s protective role was more important at higher doses of UV irradiation and correlated with pigment concentration in the cell. Pigmented cells survived high UV exposure (324 J/m²) around 1,000-fold more successfully compared to the non-pigmented mutant cells. Resistance to UV stress was conferred to the non-pigmented mutant by addition of exogenous pigment extract to the growth medium. A level of UV protection equivalent to that exhibited by the wild-type strain was attained by the non-pigmented mutant once the prodigiosin concentration had reached comparable levels to those found in the wild-type strain. In co-culture experiments, prodigiosin acted as a UV screen, protecting both the wild-type and non-pigmented mutants. Our results suggest a new ecophysiological role for prodigiosin.     

Exploring the bioactive potential of <Emphasis Type="Italic">Serriatia marcescens</Emphasis> VITAPI (Acc: 1933637) isolated from soil

BACKGROUND

Serratia is one of the most important groups of bacteria which produces proteolytic enzymes effectively and known to possess anti-inflammatory properties. The main focus of the current study was to extract the enzyme serratiopeptidase and pigment prodigiosin from Serratia mascescens. Prodigiosin is a red colored pigment produced by the bacterium Serratia marcescens. It is emerging as a valuable molecule because of its large applications. It has already been proved that pigmented strain of Serratia marcescens is less virulent than non-pigmented strains. Moreover the strain we have obtained is from farm soil which indicates that prodigiosin production can be carried safely using this strain.

METHODS

In the present study, the isolate VITASP strain was confirmed by morphological, biochemical and molecular studies. The enzyme and pigment were analyzed for anti-oxidant, anti-inflammatory and cytotoxic properties.

RESULTS

The isolate was further confirmed and identified as Serratia marcescens with 99% similarity. The extracted pigment showed potent radical scavenging effect with 86% and the enzyme was found to inhibit 83%, which was significant in comparison to ascorbic acid standard. The in vitro anti-inflammatory effect of pigment in controlled experimental conditions revealed its protection at 88% and the enzyme with 90%. Aspirin was used as the reference drug. The present findings exhibited a concentration dependent inhibition. The cytotoxic bioassay of pigment showed the IC₅₀ value as (50) μg/mL with 63% cytotoxicity which was statistically significant compared to positive control.

CONCLUSION

Therefore, it appears to be an essential remedial and application research. It may turn out to be highly beneficial to mankind in solving many problems associated with human health.

     

THE PREPARATION AND PROPERTIES OF BACTERIAL CHROMATOPHORE FRACTIONS

Chromatophore material from the bacterium Rhodopseudomonas spheroides was freed of ribosomes by centrifugation in 27 per cent RbCl and then separated into "heavy" and "light" fractions by centrifugation through a sucrose gradient. The fractions differed from one another in the following ways. (a) The isopycnic density of the heavy fraction was between 1.15 and 1.18 gm/ml and that of the light fraction was 1.14 gm/ml. (b) The heavy fraction was able to bind ribosomes; the light fraction was not. (c) The light fraction was homogeneous in the ultracentrifuge and had a sedimentation constant, extrapolated to infinite dilution, of 153 s_20,w. The heavy fraction was grossly heterogeneous. (d) Both the amount of bacteriochlorophyll relative to protein and the ratio of bacteriochlorophyll to carotenoids were greater in the light fraction. (e) The spectra of the two fractions in the near infra-red were different. Comparisons of the chromatophore fractions from cells with different amounts of bacteriochlorophyll showed that the specific bacteriochlorophyll contents of the two fractions did not change to the same extent as did that of the whole cells. The amount of heavy fraction from pigmented cells was roughly independent of the cellular pigment content and was about equal to that from pigment-free cells. The amount of light fraction depended on the pigment content of the cells; no light fraction was obtained from cells devoid of bacteriochlorophyll. The cytochrome complements of both fractions underwent quantitative as well as qualitative changes with varying growth conditions. The size of the photosynthetic unit in R. spheroides appeared to increase as the total cellular bacteriochlorophyll content increased; however, the number of units per light fraction particle remained constant.     

Defects in Prodigiosin Formation by L-Forms of Serratia marcescens

An L-form of Serratia marcescens has previously been shown incapable of producing the red pigment, prodigiosin, characteristic of the parent bacteria. Mutants of S. marcesens, unable to form one or the other of the two prodigiosin precursors, 4-methoxy-2,2'-bipyrrole-5-carboxaldehyde or 2-methyl-3-n-amylpyrrole, were used to test the nature of the L-form defect. The L-forms failed to form sufficient amounts of either precursor to be detected by the appropriate mutant, and, when furnished the precursors, failed to couple them to form prodigiosin.