Separation of Prodigiosenes and Identification as Prodigiosin Syntrophic Pigment from Mutant Pairs of Serratia marcescens

Countercurrent distribution is capable of resolving mixtures of closely related prodigiosene pigments. Syntrophic pigment produced by several pairs of Serratia marcescens color mutants was identified as prodigiosin (2-methyl-3-amyl-6-methoxyprodigiosene) by countercurrent distribution, soda lime pyrolysis, and other techniques. The metabolic block of mutant strain H-462, derived from parent strain HY, was located between the blocks of mutant strains OF and WF, both derived from parent strain Nima.     

Role of L-proline in the biosynthesis of prodigiosin.

Nonproliferating cells of Serratia marcescens, wild-type strain Nima, synthesized the pigment, prodigiosin, when saline suspensions were incubated with aeration at 27 degrees C in the presence of proline or alanine. Mutants PutS1 and PutS2 derived from strain Nima formed prodigiosin from alanine, but not from proline, unless alanine also was added. Strain Nima utilized proline as a sole source of carbon and of nitrogen for growth, whereas Put mutants did not. Investigation of enzymes degrading proline showed that the wild-type strain contained proline oxidase, which was absent in Put mutants. The wild type, as well as the mutants, utilized alanine as the sole source of carbon and nitrogen for growth. Although nonproliferating cells of Put mutants failed to synthesize prodigiosin from proline, addition of L-[U-14C]proline to suspensions metabolizing and synthesizing the pigment because of addition of alanine resulted in the incorporation of radioactive label into prodigiosin, as well as into cellular protein. Since Put mutants could not catabolize proline, the incorporation of [14C]proline into the prodigiosin molecule indicated that proline was incorporated directly into the pigment.     

Thiamine-induced Formation of the Monopyrrole Moiety of Prodigiosin

Thiamine stimulates the production of a red pigment, which is chromatographically and spectrophotometrically identical to prodigiosin, by growing cultures of Serratia marcescens mutant 9-3-3. This mutant is blocked in the formation of 2-methyl-3-amylpyrrole (MAP), the monopyrrole moiety of prodigiosin, but accumulates 4-methoxy-2,2,'-bipyrrole-5-carboxaldehyde (MBC) and can couple this compound with MAP to form prodigiosin. Addition of thiamine caused production of MAP, and as little as 0.02 mg of thiamine per ml in a peptone-glycerol medium stimulated production of measurable amounts of prodigiosin. Phosphate salts and another type of peptone decreased the thiamine-induced formation of prodigiosin; yeast extract and glycerol enhanced the formation of this substance. Thiamine also enhanced production of prodigiosin by wild-type strain Nima of S. marcescens. The thiamine antagonists, oxythiamine and pyrithiamine, inhibited thiamine-induced production of MAP and of prodigiosin by the mutant strain 9-3-3, formation of prodigiosin by the wild-type strain Nima, and production of MAP by another mutant, strain WF. The pyrimidine moiety of thiamine was only 10% as effective as the vitamin; the thiazole moiety, only 4%; and the two moieties together, 25%. Various other vitamins tested did not stimulate formation of prodigiosin by strain 9-3-3. Thiamine did not stimulate production of prodigiosin by a single-step mutant that showed the same phenotypic block in prodigiosin biosynthesis as strain 9-3-3. This is not surprising since strain 9-3-3 originated as a result of two mutational events. One event may involve thiamine directly, and the other may involve the biosynthesis of MAP. Thiamine is probably involved in the regulation of the biosynthesis of MAP, because the vitamin or inhibitory antagonists must be added during the early phases of growth in order to be effective.     

Effect of Iron and Salt on Prodigiosin Synthesis in Serratia marcescens

Serratia marcescens wild-types ATCC 264 and Nima grew but did not synthesize prodigiosin in a glycerol-alanine medium containing 10 ng of Fe per ml. Wild-type 264 required the addition of 0.2 mug of Fe per ml for maximal growth and prodigiosin synthesis; Nima required 0.5 mug of Fe per ml. Three percent, but not 0.1%, sea salts inhibited prodigiosin synthesis in a complex medium containing up to 10 mug of Fe per ml. NaCl was the inhibitory sea salt component. The inhibition was not specific for NaCl; equimolar concentrations of Na(2)SO(4), KCl, and K(2)SO(4) also inhibited prodigiosin synthesis. Experiments with strains 264 and Nima and with mutant WF which cannot synthesize 4-methoxy-2-2'-bipyrrole-5-carboxyaldehyde (MBC), the bipyrrole moiety of prodigiosin, and with mutant 9-3-3 which cannot synthesize the monopyrrole moiety 2-methyl-3-amylpyrrole (MAP) showed that both MBC synthesis and the reaction condensing MAP and MBC to form prodigiosin were relatively more sensitive to NaCl inhibition than the MAP-synthesizing step. The capacity of whole cells to condense MAP and MBC was present, but inactive, in cells grown in NaCl; removal of the NaCl from non-proliferating salt-grown cells restored the activity. Other evidence suggests the existence of a common precursor to the MAP- and MBC-synthesizing pathways.     

Biosynthesis of prodigiosin by non-proliferating wild-type Serratia marcescens and mutants deficient in catabolism of alanine, histidine, and proline.

Mutants of Serratia marcescens Nima, designated as Aut, Hut, or Put, did not utilize L-alanine, L-histidine, or L-proline, respectively, as a sole carbon source but did utilize other amino acids or glycerol as carbon sources. The bacteria were permeable to alanine, histidine, and proline but lacked the enzymes responsible for degradation of these amino acids. The Aut mutant contained no L-alanine dehydrogenase activity, whereas the Hut and Put mutants contained only 7 and 4% of the histidase and proline oxidase activities, respectively, found in the wild-type strain. Rates of oxygen uptake and protein synthesis were significantly lower when the mutants were incubated in the presence of amino acids they could not degrade. Studies of L-[14C]alanine, L-[14C]histidine, and L-[14C]proline incorporation into prodigiosin synthesized by these mutants and the wild-type strain revealed that proline was incorporated intact, whereas all of alanine except the carboxyl group was incorporated into the pigment molecule. Histidine did not enter prodigiosin directly. These data suggested that the presence of unique biosynthetic pathways, independent of primary metabolism, leads to formation of prodigiosin from specific amino acids.     

Cloning and expression in Escherichia coli of Serratia marcescens genes encoding prodigiosin biosynthesis

Prodigiosin, the bright red pigment produced by many strains of Serratia marcescens, is synthesized by a bifurcated pathway that terminates in the enzymatic condensation of the two final products, a monopyrrole and a bipyrrole . Sau3A fragments of S. marcescens ( Nima ) DNA were introduced into a strain of Escherichia coli K-12 by use of the cosmid vector pHC79 , and transformed clones were selected based on resistance to ampicillin. Among 879 transformants screened, 2 could be induced to synthesize prodigiosin when supplied with either one or both terminal products of the bifurcated pathway. Data are presented to support the idea that production of prodigiosin is not usually mediated by a plasmid.     

Biosynthesis of Prodigiosin, a Secondary Metabolite of Serratia marcescens

Prodigiosenes (prodigiosin and prodigiosin-like pigments) are known to be synthesized by only one genus of Eubacteriales and by two genera of Actinomycetales. Biosynthesis by Serratia marcescens occurs over a relatively narrow range of temperatures, although the bacteria grow over a broad range. When cultures of S. marcescens were incubated at 27 C in 1.0% casein hydrolysate, viable count and protein attained maximal values within 24 to 48 h, whereas prodigiosin did not reach a maximum until 96 h. The greatest amount of pigment was synthesized when cultures were in the senescent phase of growth. Suspensions of nonproliferating bacteria incubated at 27 C in only L-alanine also synthesized prodigiosin, although at a slower rate than growing cultures. Kinetics of growth for the wild-type, red S. marcescens and a white mutant were identical when incubated at 27 C, but the wild type produced abundant pigment. These results plus other data obtained from the literature suggest that prodigiosin is a secondary metabolite. The importance of this proposal to understanding the function of prodigiosin in S. marcescens is discussed.     

Macromolecular syntheses during biosynthesis of prodigiosin by Serratia marcescens.

Amino acids that were utilized as sole sources of carbon and nitrogen for growth of Serratia marcescens Nima resulted in biosynthesis of prodigiosin in non-proliferating bacteria. Addition of alanine, proline, or histidine to non-proliferating cells incubated at 27 C increased the rate of protein synthesis and also caused biosynthesis of prodigiosin. No increase in the rate of protein synthesis was observed upon the addition of amino acids that did not stimulate prodigiosin biosynthesis. Increased rates of synthesis of ribonucleic acid (RNA) and of deoxyribonucleic acid (DNA) (a small amount) also occurred after addition of amino acids that resulted in biosynthesis of prodigiosin. After incubation of 24 h, the total amount of protein in suspensions of bacteria to which alanine or proline was added increased 67 and 98%, respectively. Total amounts of DNA and of RNA also increased before synthesis of prodigiosin. The amounts of these macromolecules did not increase after addition of amino acids that did not induce biosynthesis of progidiosin. However, macromolecular synthesis was not related only to prodigiosin biosynthesis because the rates of DNA, RNA, and protein synthesis also increased in suspensions of bacteria incubated with proline at 39 C, at which temperature no prodigiosin was synthesized. The quantities of DNA, RNA, and protein synthesized were lower in non-proliferating cells than in growing cells. The data indicated that amino acids causing biosynthesis of prodigiosin in non-proliferating cells must be metabolized and serve as sources of carbon and of nitrogen for synthesis of macromolecules and intermediates. Prodigiosin was synthesized secondarily to these primary metabolic events.     

Biosynthesis of enniatin by washed cells of Fusarium sambucinum

Biosynthesis of the depsipeptide membrane ionophore--enniatin B by the washed mycelium Fusarium sambucinum Fuck 52 377 was studied. Metabolic precursors of enniatin B, alpha-ketovaleric acid, 14C-L-valine, and 14CH3-methionine, were added to the system after starvation. The amino acid content in the metabolic pool increased 1.5 times after addition of alpha-ketovaleric acid, 2.2 times after that of valine, and 2.5 times after addition of methionine. 14C-L-valine and 14CH3-methionine were incorporated into the molecule of enniatin B. Valine methylation in the molecule occurred at the level of synthesized depsipeptide. Amino acids of the metabolic pool performed the regulatory function in the synthesis.     

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.     

Metabolism of tRNA in rats with aflatoxin B1-induced hepatomas

This study describes effects of aflatoxin B1-induced hepatomas on RNA metabolism in rats. At 4 and 24 hours after the administration of L-(14CH3)-methionine, tRNA was isolated from the livers and hydrolyzed enzymatically to nucleosides which were quantitatively measured by HPLC. Radioactivity of the nucleosides was also determined. The data indicate that although tRNA methylation may be more rapid in livers with hepatomas, catabolism of tRNA in tumorous tissue is slower than in control livers. The large increase in some radioactive methylated nucleosides and bases by the tumor-bearing rats during the 24-hour period following the administration of labeled methionine indicates increased turnover of mRNA and rRNA as well as tRNA. Since degradation of tumor tRNA appears to be delayed, the excessive amounts of the urinary methylated nucleosides must be derived from RNA in nonneoplastic tissue.     

Methylation of ribonuclease and albumin by methyl cobalamin

The capacity of methyl cobalamine (14CH3-B12) to methylate RNase and albumin in in vitro systems was studied. Under the experimental conditions, 14CH3-B12 methylated proteins about 100--1000 times more actively than S-adenosyl-methionine, a universal donor of methyl groups. The nature of buffer and pH 2 to 8 had no noticeable effect on the methylating capacity of 14CH3-B12. However, at higher pH rate of incorporation of methyl groups slightly increased. The 14CH3-groups incorporated into RNase amino acids remained stable upon illumination, in the presence of KCN in the incubation medium, and when heated in 20% HCl for 24--72 hr at 105 degrees. Methylation did not influence the enzymic properties of RNase. The automatic amino acid analyzer showed three peaks of the label of modified amino acids in the hydrolzates of methylated RNase, one of which corresponded to methylated methionine.     

Preparation and properties of three specific active derivatives of ribonuclease A obtained by methylation of methionine residues in 8 M urea.

In 8 M urea at low pH, CH3I reacts specifically with the four methionine residues of ribonuclease A, and all four residues react at the same rate. Uon removal of the denaturant, only unmodified ribonuclease and 3 of the 15 possible derivatives modified on methionine refold to regenerate activity. All the enzymatic activity is recored after chromatography on IRC-50 and the four active proteins separate from each other and from the 12 inactive derivatives, which are not eluted from the resin under the conditions used. By the use of 14CH3I, performic acid oxidation, chymotryptic digestion, and separation of the resulting peptides by ion exchange, the active species were determined to be unmodified ribonuclease, CH3Met-29-RNase, CH3Met-79-RNase, and CH3Met-29, CH3Met-79-RNase. these proteins have melting temperatures of 63, 58, 43, and 36 degrees, respectively, at pH 6.3-70. Methylation at methionine-29 or -79 has no effect on enzymatic activity. Conversely, methylation at methionine-13 or -30 prevents refolding to an active conformation at 25 degrees elution from IRC-50. These results are consistent with the positions of the four methionine residues in crystals of ribonuclease A and ribonuclease S as determined by X-ray diffraction.     

Effect of methylation on the stability of cytochrome c of Saccharomyces cerevisiae in vivo

The in vivo stability of methylated and unmethylated cytochrome c in Saccharomyces cerevisiae was studied by pulse-labeling the hemoproteins with [methyl-3H]-methionine and/or [2-14C]methionine and following the fate of these proteins under anaerobiosis and in the presence of cycloleucine. These two conditions will respectively block further cytochrome c synthesis and inhibit methylation by lowering the cellular S-adenosyl-L-methionine pool and, thus, permit an unambiguous interpretation of the data. The results showed that the rate of degradation of unmethylated cytochrome c was constant throughout the chase period, while methylated cytochrome c degradation was seen only in the later part of cold chase. At the end of the chase period (40 h), the extent of degradation of the unmethylated species was three times higher than the methylated species. This indicated that the methylation of cytochrome c has a protective effects against the intracellular proteolytic enzyme attack on itself. Furthermore, this protective effect was considerably reduced in the petite mutant, which lacks high affinity cytochrome c binding sites, functional cytochrome c reductase, and oxidase, and possesses a less integrated and organized mitochondrial membrane. These results led us to the conclusion that the mechanism of methylated cytochrome c stabilization is best explained by a higher efficacy of binding to the mitochondria.     

Isolation and characterization ofSerratia marcescens mutants defective in prodigiosin biosynthesis

Mutants deficient in the biosynthesis of prodigiosin have been obtained by treatingSerratia marcescens with high doses of ultraviolet radiation. Mutants were selected on the basis of the color characteristics of their colonies when grown on peptone glycerol medium. New types of mutants, with unusual blocks in the biosynthetic pathway of prodigiosin, were obtained. All the mutants were classified under a new scheme on the basis of the syntrophic pigmentation characteristic and infrared spectroscopic analysis of their pigment. By these criteria mutants could be distinguished into eight distinct classes. Classes I to III include mutants of the three classes (M1, B3, and B1) reported previously [Morrison, DA (1966) J Bacteriol 91:1599–1604] and several new ones. Mutants blocked in the methylamylpyrrole (MAP) arm of the bifurcated pathway were assigned to class I. A class II mutant was distinguished by its inability to synthesize methoxybipyrrolecarboxyaldehyde (MBC), but was able to produce norprodigiosin. Class III mutants were deficient in the synthesis of hydroxybipyrrolecarboxaldehyde (HBC). Double mutants were obtained with defects in the expression of both MBC and MAP and were assigned to class IV. Mutants of class V were unable to synthesize HBC and MAP, but could form MBC when furnished with exogenous HBC. Class VI and VII mutants were defective in the synthesis of all three precursors, but differed in their ability to perform the coupling step. Finally, a mutant of class VIII was found to produce the three intermediates, but was deficient in prodigiosin or norprodigiosin biosynthesis, indicative of a defect in the enzymatic condensation of MAP with the bipyrroles MBC and HBC. The anomalous pattern of syntrophism among certain interclass mutants suggests that the physiology of pigment formation inS. marcescens is quite complex.     

Biosynthesis of antibiotic prodiginines in the marine bacterium Hahella chejuensis KCTC 2396

AIMS: Hahella chejuensis KCTC 2396 produces red pigments, showing antibacterial and algicidal activities. The main red-coloured metabolite of the pigments was identified as antibiotic prodigiosin. With the expectation that the red pigments are a mixture of a series of close relatives, the aim of the present study is to detect new antibiotic prodigiosin analogues and to analyse the biosynthetic pattern for prodiginines in KCTC 2396. METHODS AND RESULTS: Except prodigiosin, the other constituents in the red pigments were confirmed as well-known dipyrrolyldipyrromethene prodigiosin, norprodigiosin, and undecylprodiginine. Additionally, four new prodigiosin analogues, each of which was distinguished from prodigiosin (C(5)), according to differences in alkyl chain length (C(3)-C(7)), were detected in small quantities by liquid chromatography mass spectrometry/mass spectrometry spectroscopy. Owing to the presence of a cytotoxic methoxy group, it is expected that all the new prodigiosin analogues are bioactive. CONCLUSIONS: Four characterized prodiginines, including prodigiosin and four new prodigiosin analogues are produced in different ratio in KCTC 2396. All of the prodiginines possess a common linear tripyrrolyl structure and a cytotoxic methoxy group. SIGNIFICANCE AND IMPACT OF THE STUDY: This study shows for the first time that KCTC 2396 is able to produce antibiotic prodigiosin, undecylprodiginine and new prodigiosin analogues in a mixture of pigments. It is also shown that KCTC 2396 possesses a novel system for the simultaneous production of multiple prodiginines in a single micro-organism.     

Methylation of the Cellular Lipid of Methionine-requiring Agrobacterium tumefaciens

Mutants of Agrobacterium tumefaciens requiring methionine for growth on a solid basal medium were induced by the use of N-methyl-N'-nitro-N-nitrosoguanidine. In addition to the difference of mutant strains, the extent of methionine dependency differed in a liquid basal medium and in the presence of aspartate or fumarate. When ((14)C-methyl)-methionine was added to strain WM-11 growing in a prescribed basal medium, incorporation of (14)C into the cellular "residue" fraction and polar "N-methylated" lipid fraction depended strictly on cellular growth and on external methionine concentration. However, a net synthesis of the "cyclopropane" fatty acid fraction occurred even during the maximal stationary phase if excess methionine was present.     

Inhibition of quorum sensing in Serratia marcescens AS-1 by synthetic analogs of N-acylhomoserine lactone

Quorum sensing is a regulatory system for controlling gene expression in response to increasing cell density. N-Acylhomoserine lactone (AHL) is produced by gram-negative bacteria, which use it as a quorum-sensing signal molecule. Serratia marcescens is a gram-negative opportunistic pathogen which is responsible for an increasing number of serious nosocomial infections. S. marcescens AS-1 produces N-hexanoyl homoserine lactone (C(6)-HSL) and N-(3-oxohexanoyl) homoserine lactone and regulates prodigiosin production, swarming motility, and biofilm formation by AHL-mediated quorum sensing. We synthesized a series of N-acyl cyclopentylamides with acyl chain lengths ranging from 4 to 12 and estimated their inhibitory effects on prodigiosin production in AS-1. One of these molecules, N-nonanoyl-cyclopentylamide (C(9)-CPA), had a strong inhibitory effect on prodigiosin production. C(9)-CPA also inhibited the swarming motility and biofilm formation of AS-1. A competition assay revealed that C(9)-CPA was able to inhibit quorum sensing at four times the concentration of exogenous C(6)-HSL and was more effective than the previously reported halogenated furanone. Our results demonstrated that C(9)-CPA was an effective quorum-sensing inhibitor for S. marcescens AS-1.     

Incorporation of proline into prodigiosin by a Put mutant of Serratia marcesens.

A Put mutant of Serratia marcescens, deficient in proline oxidase and therefore unable to degrade proline, was used to assay for an enzymatic reaction responsible for incorporation of proline into prodigiosin. The reaction had a pH optimum of 7.5 and a Km of 1.1 X 10(-4) M at 27 C. At temperatures above 27 C, the velocity of the reaction decreased with increasing temperature and little activity was detected at 42 C. Activity of the enzyme was directly proportional to the quantity of pigment formed and was inhibited by thioproline, a substrate analog. These data suggested the presence of a unique and specific enzyme in the biosynthetic pathway for prodigiosin.     

Incorporation of proline into prodigiosin by a Put mutant of Serratia marcesens.

A Put mutant of Serratia marcescens, deficient in proline oxidase and therefore unable to degrade proline, was used to assay for an enzymatic reaction responsible for incorporation of proline into prodigiosin. The reaction had a pH optimum of 7.5 and a Km of 1.1 X 10(-4) M at 27 C. At temperatures above 27 C, the velocity of the reaction decreased with increasing temperature and little activity was detected at 42 C. Activity of the enzyme was directly proportional to the quantity of pigment formed and was inhibited by thioproline, a substrate analog. These data suggested the presence of a unique and specific enzyme in the biosynthetic pathway for prodigiosin.