The Escherichia coli Yej transporter is required for the uptake of translation inhibitor microcin C

Microcin C (McC), a peptide-nucleotide antibiotic, targets aspartyl-tRNA synthetase. By analyzing a random transposon library, we identified Escherichia coli mutants resistant to McC. Transposon insertions were localized to a single locus, yejABEF, which encodes components of a putative inner membrane ABC transporter. Analysis of site-specific mutants established that all four components of the transporter are required for McC sensitivity. Since aspartyl-tRNA synthetase in yej mutant extracts was fully sensitive to McC, we conclude that yej mutations interfere with McC uptake and that YejABEF is the only inner membrane transporter responsible for McC uptake in E. coli. Other substrates of YejABEF remain to be identified.     

Extended targeting potential and improved synthesis of Microcin C analogs as antibacterials

Microcin C (McC) (1) is a potent antibacterial compound produced by some Escherichia coli strains. McC functions through a Trojan-Horse mechanism: it is actively taken up inside a sensitive cell through the function of the YejABEF-transporter and then processed by cellular aminopeptidases. Processed McC (2) is a non-hydrolysable aspartyl-adenylate analog that inhibits aspartyl-tRNA synthetase (AspRS). A new synthesis is described that allows for the production of a wide variety of McC analogs in acceptable amounts. Using this synthesis a number of diverse compounds was synthesized with altered target specificity. Further characteristics of the YejABEF transporters were determined using these compounds.     

Peptide‐nucleotide antibiotic Microcin C is a potent inducer of stringent response and persistence in both sensitive and producing cells

Microcin C (McC) is a peptide‐nucleotide antibiotic that inhibits aspartyl‐tRNA synthetase. Here, we show that McC is a strong inducer of persistence in Escherichia coli. Persistence induced by McC is mediated by (p)ppGpp and requires chromosomally encoded toxin‐antitoxin modules. McC‐producing cells have increased persistence levels due to a combined effect of McC imported from the cultured medium and intracellularly synthesized antibiotic. McC‐producing cells also induce persistence in sensitive cells during co‐cultivation, underscoring complex interactions in bacterial communities where an antagonistic compound produced by one community member can benefit other members by increasing their ability to withstand antibiotics.     

Synthetic Microcin C Analogs Targeting Different Aminoacyl-tRNA Synthetases

Microcin C (McC) is a potent antibacterial agent produced by some strains of Escherichia coli. McC consists of a ribosomally synthesized heptapeptide with a modified AMP attached through a phosphoramidate linkage to the α-carboxyl group of the terminal aspartate. McC is a Trojan horse inhibitor: it is actively taken inside sensitive cells and processed there, and the product of processing, a nonhydrolyzable aspartyl-adenylate, inhibits translation by preventing aminoacylation of tRNA^Asp by aspartyl-tRNA synthetase (AspRS). Changing the last residue of the McC peptide should result in antibacterial compounds with targets other than AspRS. However, mutations that introduce amino acid substitutions in the last position of the McC peptide abolish McC production. Here, we report total chemical synthesis of three McC-like compounds containing a terminal aspartate, glutamate, or leucine attached to adenosine through a nonhydrolyzable sulfamoyl bond. We show that all three compounds function in a manner similar to that of McC, but the first compound inhibits bacterial growth by targeting AspRS while the latter two inhibit, respectively, GluRS and LeuRS. Our approach opens a way for creation of new antibacterial Trojan horse agents that target any 1 of the 20 tRNA synthetases in the cell.Microcins are small (<10-kDa) ribosomally synthesized peptide antibiotics produced by Enterobacteriaceae (17). Three microcins, B, C, and J, form a subgroup of posttranslationally modified microcins. Members of this subgroup have highly unusual structures and inhibit cellular enzymes that are validated targets for antibacterial drug development (25). Posttranslationally modified microcins are attractive as drug candidates because of their strong antibacterial action and because virtually limitless numbers of their derivatives can be generated by means of mutation, chemical synthesis, or both. Microcin B (McB), a 43-residue peptide with thiazole and indole rings (13), inhibits DNA gyrase (21). Microcin J, a 21-amino-acid peptide, assumes an unusual threaded lasso structure (2, 23, 27) and inhibits bacterial RNA polymerase (1, 18). The structure of the subject of this study, McC (compound 1) is shown in Fig. ​Fig.1a.1a. McC is a heptapeptide with a formylated N-terminal methionine and a C-terminal aspartate whose α-carboxyl group is covalently linked to adenosine through an N-acyl phosphoramide bond (10, 14). The phosphoramidate of McC is additionally modified by an O-propylamine group (9).Open in a separate windowFIG. 1.Structures and synthesis of McC analogs. (a) Structures of microcin C (compound 1) and its processing product (compound 2). (b) Structures of synthetic McC analogs 7 to 9 and their expected processing products, compounds 4 to 6, which are established inhibitors of AspRS, GluRS, and LeuRS, respectively. (c) Structure of Asp-AMP (compound 3), the natural reaction intermediate of AspRS. Compounds 2 and 4 are nonhydrolyzable analogs of this compound. (d) Synthesis of compounds 7 to 9, which starts from compounds 4 to 6. Hereto the hexapeptide was coupled to the sulfamoyl precursors 4-6 via the coupling agent DIC, followed by removal of the Fmoc protecting group: (i) Fmoc-MRTGNA-OH, HOBt, DIC, DIPEA; (ii) Et₃N/DMF (1:1 [vol/vol]).The passage of McC through the inner layer of the Escherichia coli cell wall is carried out by the YejABEF transporter (19). Once inside the cell, McC is specifically processed by one of the several broad-specificity E. coli cytoplasmic aminopeptidases (12). The product of processing, modified aspartyl-adenylate (compound 2) (15), closely resembles Asp-AMP (compound 3) (Fig. ​(Fig.1c),1c), the natural reaction intermediate of the tRNA^Asp aminoacylation reaction catalyzed by AspRS. However, because the bond between the α-carboxyl of C-terminal aspartate and the phosphoramidate nitrogen is nonhydrolyzable, compound 2 inhibits AspRS. Unprocessed McC has no effect on tRNA^Asp aminoacylation, while processed McC has no effect on McC-sensitive cells at concentrations at which intact McC strongly inhibits cell growth. Thus, McC is a Trojan horse inhibitor (22): the peptide part allows McC to enter sensitive cells, where it gets processed, liberating the inhibitory part of the drug.Aminoacyl-tRNA synthetases (aaRSs) carry out the condensation of genetically encoded amino acids with cognate tRNAs. When 1 of the 20 aaRSs present in the cell is inhibited, the corresponding tRNA is not charged. This leads to protein synthesis inhibition and cell growth arrest. In principle, variation of the last amino acid of the McC peptide, the product of the mccA gene, should allow investigators to obtain McC derivatives targeting aaRSs other than AspRS. Unfortunately, the results of systematic structure-activity analyses of the McC peptide revealed that substitutions in the seventh codon of mccA invariably prevented McC production, presumably by interfering with posttranslational modifications of the MccA peptide by the McC maturation enzymes (11). Indeed, in vitro analysis showed that the C-terminal asparagine of MccA is required for the addition of the adenosine moiety by the MccB protein (24).Aminoacyl-sulfamoyl adenosines are well-known nanomolar inhibitors of their corresponding aaRSs (5, 20, 26). However, these compounds show low in vivo activities due to limited membrane permeability and the absence of a transporter for these compounds. Here, we show that through chemical attachment of aminoacyl-sulfamoyl adenosines to the first 6 amino acids of the MccA peptide, potent antibacterial agents can be generated. The new compounds share the Trojan horse mechanism of action with McC but target aaRSs specified by the last amino acid of the peptide moiety.     

Structural and functional characterization of microcin C resistance peptidase MccF from Bacillus anthracis

Microcin C (McC) is heptapeptide adenylate antibiotic produced by Escherichia coli strains carrying the mccABCDEF gene cluster encoding enzymes, in addition to the heptapeptide structural gene mccA, necessary for McC biosynthesis and self-immunity of the producing cell. The heptapeptide facilitates McC transport into susceptible cells, where it is processed releasing a non-hydrolyzable aminoacyl adenylate that inhibits an essential aminoacyl-tRNA synthetase. The self-immunity gene mccF encodes a specialized serine peptidase that cleaves an amide bond connecting the peptidyl or aminoacyl moieties of, respectively, intact and processed McC with the nucleotidyl moiety. Most mccF orthologs from organisms other than E. coli are not linked to the McC biosynthesis gene cluster. Here, we show that a protein product of one such gene, MccF from Bacillus anthracis (BaMccF), is able to cleave intact and processed McC, and we present a series of structures of this protein. Structural analysis of apo-BaMccF and its adenosine monophosphate complex reveals specific features of MccF-like peptidases that allow them to interact with substrates containing nucleotidyl moieties. Sequence analyses and phylogenetic reconstructions suggest that several distinct subfamilies form the MccF clade of the large S66 family of bacterial serine peptidases. We show that various representatives of the MccF clade can specifically detoxify non-hydrolyzable aminoacyl adenylates differing in their aminoacyl moieties. We hypothesize that bacterial mccF genes serve as a source of bacterial antibiotic resistance.     

The RimL Transacetylase Provides Resistance to Translation Inhibitor Microcin C

Peptide-nucleotide antibiotic microcin C (McC) is produced by some Escherichia coli strains. Inside a sensitive cell, McC is processed, releasing a nonhydrolyzable analog of aspartyl-adenylate, which inhibits aspartyl-tRNA synthetase. The product of mccE, a gene from the plasmid-borne McC biosynthetic cluster, acetylates processed McC, converting it into a nontoxic compound. MccE is homologous to chromosomally encoded acetyltransferases RimI, RimJ, and RimL, which acetylate, correspondingly, the N termini of ribosomal proteins S18, S5, and L12. Here, we show that E. coli RimL, but not other Rim acetyltransferases, provides a basal level of resistance to McC and various toxic nonhydrolyzable aminoacyl adenylates. RimL acts by acetylating processed McC, which along with ribosomal protein L12 should be considered a natural RimL substrate. When overproduced, RimL also makes cells resistant to albomycin, an antibiotic that upon intracellular processing gives rise to a seryl-thioribosyl pyrimidine that targets seryl-tRNA synthetase. We further show that E. coli YhhY, a protein related to Rim acetyltransferases but without a known function, is also able to detoxify several nonhydrolyzable aminoacyl adenylates but not processed McC. We propose that RimL and YhhY protect bacteria from various toxic aminoacyl nucleotides, either exogenous or those generated inside the cell during normal metabolism.     

Identification of human erythrocyte blood group antigens on the C3b/C4b receptor.

The Knops/McCoy (Kn/McC) human erythrocyte blood group system belongs to the category of blood group Ag that generate so-called "high titer low avidity" antibodies in immunized transfusion recipients. Screening of red cells lacking certain high titer low avidity Ag demonstrated markedly diminished CR1 expression on McC(d-) and Kn/McC "null" (Kn(a-)McC(a-b-c-d-e-f-] erythrocytes. Additional testing by other methods confirmed these data, and biochemical assays demonstrated no detectable immunoreactive CR1 protein in membranes from Kn/McC null red cells. Human antisera to various Kn/McC Ag were then used to demonstrate that many of these antisera could be used to isolate a protein of identical m.w. to that isolated from the same cells using murine mAb CR1 antisera. Finally, protein isolated by using murine mAb anti-CR1 reacted specifically with anti-Kn/McC antibodies, demonstrating the identity of the Kn/McC and CR1 proteins. Thus, CR1 protein bears the human erythrocyte Kn/McC blood group Ag.     

Production of a bi-specific monoclonal antibody recognizing mouse kappa light chains and horseradish peroxidase

Summary The production of a bi-specific monoclonal antibody that simultaneously recognizes mouse kappa light chains and horseradish peroxidase (HRP) for use as a general developing reagent in a wide variety of immunobased techniques is described. This antibody, named McC10, was produced by the fusion of an aminopterin-sensitive interspecies hybridoma which secretes rat monoclonal antibodies against HRP (RAP₂·Ag) and splenocytes from a rat immunized with whole mouse immunoglobulin (Ig)G. The hybrid-hybridoma generated from this fusion expresses and secretes rat Igs of the IgG₁ and IgG_2a subclasses, as determined by radial immunodiffusion. In competitive binding solid-phase enzymatic assays, McC10 was found to cross-react with all four mouse IgG subclasses as well as mouse kappa light chains. In contrast, in this type of assay, McC10 did not appear to recognize mouse IgA, IgM or lambda light chains. However, IgM-bearing kappa light chains were recognized by immunocytochemistry. Epitope specificity of this bi-specific antibody was more clearly determined on immunoblots where McC10 was found to exclusively recognize mouse kappa light chains and display no cross-reactivity with mouse Ig heavy chains nor with kappa light chains from rat or rabbit. In addition, McC10 was used successfully in two-step immunocytochemistry (ICC) for the localization of enkephalin, nerve growth factor (NGF) receptor and paired helical filament-immunoreactive sites in rat brain, rat skin and human brain, respectively, using mouse IgG's and IgM's as primary antibodies. McC10 compared favourably with peroxidase-anti-peroxidase (PAP) ICC with respect to sensitivity but was markedly superior with respect to specificity when used in fixed human brain or rat skin. This study demonstrates some of the potential advantages of using an epitope specific monoclonal bi-specific developing reagent like McC10 in an immunobased technique like ICC. Its potential use in a variety of other immunobased procedures is discussed.     

Structural basis for microcin C7 inactivation by the MccE acetyltransferase

The antibiotic microcin C7 (McC) acts as a bacteriocide by inhibiting aspartyl-tRNA synthetase and stalling the protein translation machinery. McC is synthesized as a heptapeptide-nucleotide conjugate, which is processed by cellular peptidases within target strains to yield the biologically active compound. As unwanted processing of intact McC can result in self-toxicity, producing strains utilize multiple mechanisms for autoimmunity against processed McC. We have shown previously that the mccE gene within the biosynthetic cluster can inactivate processed McC by acetylating the antibiotic. Here, we present the characterization of this acetylation mechanism through biochemical and structural biological studies of the MccE acetyltransferase domain (MccE(AcTase)). We have also determined five crystal structures of the MccE-acetyl-CoA complex with bound substrates, inhibitor, and reaction product. The structural data reveal an unexpected mode of substrate recognition through π-stacking interactions similar to those found in cap-binding proteins and nucleotidyltransferases. These studies provide a rationale for the observation that MccE(AcTase) can detoxify a range of aminoacylnucleotides, including those that are structurally distinct from microcin C7.     

Escherichia coli peptidase A, B, or N can process translation inhibitor microcin C

The heptapeptide-nucleotide microcin C (McC) targets aspartyl-tRNA synthetase. Upon its entry into a susceptible cell, McC is processed to release a nonhydrolyzable aspartyl-adenylate that inhibits aspartyl-tRNA synthetase, leading to the cessation of translation and cell growth. Here, we surveyed Escherichia coli cells with singly, doubly, and triply disrupted broad-specificity peptidase genes to show that any of three nonspecific oligopeptidases (PepA, PepB, or PepN) can effectively process McC. We also show that the rate-limiting step of McC processing in vitro is deformylation of the first methionine residue of McC.     

Production of a bi-specific monoclonal antibody recognizing mouse kappa light chains and horseradish peroxidase. Applications in immunoassays

The production of a bi-specific monoclonal antibody that simultaneously recognizes mouse kappa light chains and horseradish peroxidase (HRP) for use as a general developing reagent in a wide variety of immunobased techniques is described. This antibody, named McC10, was produced by the fusion of an aminopterin-sensitive interspecies hybridoma which secretes rat monoclonal antibodies against HRP (RAP2.Ag) and splenocytes from a rat immunized with whole mouse immunoglobulin (Ig)G. The hybrid-hybridoma generated from this fusion expresses and secretes rat Igs of the IgG1 and IgG2a subclasses, as determined by radial immunodiffusion. In competitive binding solid-phase enzymatic assays, McC10 was found to cross-react with all four mouse IgG subclasses as well as mouse kappa light chains. In contrast, in this type of assay, McC10 did not appear to recognize mouse IgA, IgM or lambda light chains. However, IgM-bearing kappa light chains were recognized by immunocytochemistry. Epitope specificity of this bi-specific antibody was more clearly determined on immunoblots where McC10 was found to exclusively recognize mouse kappa light chains and display no cross-reactivity with mouse Ig heavy chains nor with kappa light chains from rat or rabbit. In addition, McC10 was used successfully in two-step immunocytochemistry (ICC) for the localization of enkephalin, nerve growth factor (NGF) receptor and paired helical filament-immunoreactive sites in rat brain, rat skin and human brain, respectively, using mouse IgG's and IgM's as primary antibodies. McC10 compared favourably with peroxidase-anti-peroxidase (PAP) ICC with respect to sensitivity but was markedly superior with respect to specificity when used in fixed human brain or rat skin.(ABSTRACT TRUNCATED AT 250 WORDS)     

The production of a “universal developer” for the immunological detection of human IgG and its application in immunodiagnostics

Summary This study describes the development of a bispecific monoclonal antibody capable of the simultaneous recognition of horseradish peroxidase (HRP) and human IgG. This antibody, coded McC2, has been applied in a novel manner as a universal developing reagent for the detection of human IgG. McC2 cross-reacts with all human IgG subtypes and was found to recognise an epitope on the Fe portion of human IgG. McC2 does not cross-react with human IgM or IgA. This bi-specific antibody belongs to the mouse IgG₁ subclass. McC2 was used for the detection of human IgG in a simple one step enzyme-linked immunosorbant assay (ELISA). Use of this bi-specific antibody in this assay resulted in an excellent signal to noise ratio with background in negative control wells virtually nonexistent. McC2 was also applied in a clinical diagnostic test for the detection of auto anti-nuclear antibodies in patient sera. McC2 was substituted, in a blind study, for a HRP-conjugated second antibody supplied with the test kit. All sera were tested both with the kit's second antibody and McC2. When using McC2, we obtained no false positive results whereas five false positives were obtained when using the kit's second antibody. However, one false negative result was obtained with the use of McC2 as a developing reagent while none were noted with the use of the kit's second antibody.This study demonstrates the potential use of bi-specific universal developers in a wide variety of immunobased techniques as well as the potential advantages for the production of a complete panel of bi-specific developing monoclonal antibodies against IgGs from a number of different species.     

Microcin C: Biosynthesis,Mode of Action,and Potential as a Lead in Antibiotics Development

The natural compound Microcin C (McC) is a Trojan horse inhibitor of aspartyl tRNA synthetases endowed with strong antibacterial properties, in which a heptapeptide moiety is responsible for active transport of the inhibitory metabolite part into the bacterial cell. The intracellularly formed aspartyl AMP analogue carries a chemically more stable phosphoramidate linkage, in comparison to the labile aspartyl-adenylate, and in addition is esterified with a 3-aminopropyl moiety. Therefore, this compound can target aspartyl-tRNA synthetase. The biochemical production and secretion of McC, and the possibilities to develop new classes of antibiotics using the McC Trojan horse concept in combination with sulfamoylated adenosine analogues will be discussed briefly.     

Microcin C: biosynthesis and mechanisms of bacterial resistance

Nonhydrolyzable aminoacyl-adenylates that inhibit protein synthesis provide a promising route towards the development of novel antibiotics whose mechanism of action limits the appearance of bacterial drug resistance. The 'Trojan horse' antibiotic microcin C (McC) consists of a nonhydrolyzable aspartyl-adenylate that is efficiently imported into bacterial cells owing to a covalently attached peptide carrier. Once inside the cell, the carrier is removed by proteolytic processing to release a potent aspartyl tRNA synthetase inhibitor. The focus of this article is on the mechanism of biosynthesis of McC. We also examine the strategies utilized by McC-producing strains to overcome toxicity due to unwanted, premature processing of the drug. This article will discuss how McC biosynthesis can be systematically manipulated for the development of derivatives that will target the entire battery of aminoacyl tRNA synthetases in various bacteria.     

Amino acid residues required for maturation, cell uptake, and processing of translation inhibitor microcin C

Microcin C (McC), a peptide-nucleotide Trojan horse antibiotic, targets aspartyl-tRNA synthetase. We present the results of a systematic mutational study of the 7-amino-acid ribosomally synthesized peptide moiety of McC. Our results define amino acid positions important for McC maturation and cell uptake and processing and open the way for creation of more potent McC-based inhibitors.     

Microcin C: biosynthesis, mode of action, and potential as a lead in antibiotics development

The natural compound Microcin C (McC) is a Trojan horse inhibitor of aspartyl tRNA synthetases endowed with strong antibacterial properties, in which a heptapeptide moiety is responsible for active transport of the inhibitory metabolite part into the bacterial cell. The intracellularly formed aspartyl AMP analogue carries a chemically more stable phosphoramidate linkage, in comparison to the labile aspartyl-adenylate, and in addition is esterified with a 3-aminopropyl moiety. Therefore, this compound can target aspartyl-tRNA synthetase. The biochemical production and secretion of McC, and the possibilities to develop new classes of antibiotics using the McC Trojan horse concept in combination with sulfamoylated adenosine analogues will be discussed briefly.     

Development of a bi-specific monoclonal antibody for simultaneous detection of rabbit IgG and horseradish peroxidase: use as a general reagent in immunocytochemistry and enzyme-linked immunosorbent assay

We describe the development of bi-specific monoclonal antibodies (MAb) capable of simultaneous recognition of rabbit immunoglobulin G (IgG) and horseradish peroxidase (HRP) for use in a variety of immunobased techniques. This bi-specific antibody, named McC8, was produced by fusion of the aminopterin-sensitive mouse hybridoma MAP.Ag.1, which secretes MAb against HRP, and splenocytes from a mouse previously immunized with whole rabbit IgG. The resultant hybrid-hybridoma co-dominantly expresses and secretes the immunoglobulin chains, i.e., IgG1 and IgG2b, of its respective parents, as determined by radial immunodiffusion. The binding sites on rabbit IgG for McC8 were determined on Western blots and in competition solid-phase enzymatic immunoassays with the use of allotype-specific rabbit sera. Both these techniques demonstrated that McC8 recognizes the light chain of the rabbit IgG molecule with preferential binding to the B4 kappa light-chain allotype. McC8 was successfully used in two-step immunocytochemistry for localization of calcitonin gene-related peptide (CGRP) in fibers of the superficial layers of the spinal trigeminal nucleus of the rat, as well as for localization of glial fibrillary acidic protein (GFAP)-immunoreactive sites in primary rat septal cell cultures, thus demonstrating its potential as a general developing reagent in conventional immunocytochemistry. McC8 compared favorably with peroxidase-antiperoxidase immunocytochemistry with respect to sensitivity. However, the bi-specific developing reagent proved superior to the conventional peroxidase-antiperoxidase procedure when both were employed in a similar fashion in tissues prone to display high background staining. Finally, McC8 was also employed as a developing reagent in a competitive ELISA designed for quantitation of CGRP with the use of a rabbit anti-CGRP primary antibody. The sensitivity of this quantitative ELISA (190 pg or 50 fmol CGRP per well) renders this bi-specific antibody suitable for use in quantitative immunoassays for detection of relevant peptides in biological systems.     

Complement receptor 1 and the molecular pathogenesis of malaria

Malaria is a pathogenic infection caused by protozoa of the genus plasmodium. It is mainly confined to sub-Saharan Africa, Asia and South America. This disease claims the life of over 1.5 to 2.7 million people per year. Owing to such a high incidence of malarial infections, there is an urgent need for the development of suitable vaccines. For the development of ideal vaccines, it is essential to understand the molecular mechanisms of malarial pathogenesis and the factors that lead to malaria infection. Genetic factors have been proposed to play an important role in malarial pathogenesis. Complement receptor 1 (CR1) is an important host red blood cell protein involved in interaction with malarial parasite. Various polymorphic forms of CR1 have been found to be involved in conferring protection or increasing susceptibility to malaria infections. Low-density allele (L) of CR1 gave contradictory results in different set of studies. In addition, Knops polymorphic forms Sl (a(+)) and McC (a) have been found to contribute more towards the occurrence of cerebral malaria in malaria endemic regions compared to individuals with Sl (a(-)) / McC (a/b) genotype. This article reviews the research currently going on in this area and throws light on as yet unresolved mysteries of the role of CR1 in malarial pathogenesis.     

Naphthoquinone contents of in vitro cultured plants and cell suspensions of Dionaea muscipula and Drosera species

In vitro cultured carnivorous plants were grown on a hormone-free medium. They produced the following naphthoquinones: Dionaea muscipula (plumbagin: 5.3%), Drosera rotundifolia (7-methyljuglone: 0.6%), D. binata (plumbagin: 1.4%), and D. capensis (7-methyljuglone: 0.5%). A red, slow-growing suspension culture of D. muscipula was maintained in a modified McCowns Woody Plant (McC) medium and produced plumbagin (2.59%) after 30 days growth. A suspension culture of D. rotundifolia grew slowly as multicoloured small aggregates only in a modified Murashige and Skoog (MS) medium. No quantifiable amounts of naphthoquinones were produced. Several cell lines of D. capensis were developed. Green aggregates grown in a modified MS medium contained 7-methyljuglone (0.33%) and differentiated into plants when placed onto hormone-free medium. Pink cultures grown in modified McC medium contained 7-methyljuglone (1.24%), while dark red cultures produced ca. 1% in both modified McC and MS media. Though the latter medium was significantly better with regard to biomass production, cells excreted a mucin when cultured in both media (0.21 g dry mucin/g dry cells in McC) and (0.16 g dry mucin/g dry cells in MS). Effects of the presence or absence of light during the growth period of 30 days showed that there was no effect on biomass and only slight effects on mucin production and naphthoquinone contents.