Francisco J. Murillo

Growth phase dependence of the activation of a bacterial gene for carotenoid synthesis by blue light.

Myxococcus xanthus responds to blue light by producing carotenoid pigments. A mutation at a gene named carC is known to block the metabolism of phytoene, a carotenoid precursor, and this gene has now been cloned and sequenced. We show here that gene carC, which is homologous to phytoene dehydrogenase genes from other organisms, is tightly regulated by light through a mechanism that operates only when the cells have reached the stationary phase or are starved of a carbon source. A genetic element that mediates the effect of the growth phase has been identified. Gene carC is integrated with another unlinked carotenogenic gene in a single ‘light regulon’ controlled by common trans‐acting genetic elements. A potential −35 site for the binding of sigma factors has been found upstream of the carC transcriptional start. However, the −10 region shows no similarity with analogous sites at promoters of other Gram‐negative bacteria.

Light-dependent gene regulation by a coenzyme B12-based photoreceptor

Cobalamin (B12) typically functions as an enzyme cofactor but can also regulate gene expression via RNA-based riboswitches. B12-directed gene regulatory mechanisms via protein factors have, however, remained elusive. Recently, we reported down-regulation of a light-inducible promoter in the bacterium Myxococcus xanthus by two paralogous transcriptional repressors, of which one, CarH, but not the other, CarA, absolutely requires B12 for activity even though both have a canonical B12-binding motif. Unanswered were what underlies this striking difference, what is the specific cobalamin used, and how it acts. Here, we show that coenzyme B12 (5′-deoxyadenosylcobalamin, AdoB12), specifically dictates CarH function in the dark and on exposure to light. In the dark, AdoB12-binding to the autonomous domain containing the B12-binding motif foments repressor oligomerization, enhances operator binding, and blocks transcription. Light, at various wavelengths at which AdoB12 absorbs, dismantles active repressor oligomers by photolysing the bound AdoB12 and weakens repressor–operator binding to allow transcription. By contrast, AdoB12 alters neither CarA oligomerization nor operator binding, thus accounting for its B12-independent activity. Our findings unveil a functional facet of AdoB12 whereby it serves as the chromophore of a unique photoreceptor protein class acting in light-dependent gene regulation. The prevalence of similar proteins of unknown function in microbial genomes suggests that this distinct B12-based molecular mechanism for photoregulation may be widespread in bacteria.

The structure of an ECF-sigma-dependent, light-inducible promoter from the bacterium Myxococcus xanthus.

Expression of the Myxococcus xanthus gene crtI is controlled by a light‐inducible promoter. The activity of this promoter depends on CarQ, a σ factor of the extracytoplasmic function (ECF) subfamily. Here, we show that the minimum DNA stretch reproducing normal expression of crtI extends from a few bases upstream of the −35 position to a site well downstream of the transcriptional start. The downstream DNA contains an enhancer‐like element that remains active when displaced upstream of the promoter. Experimental evidence is provided for the activity of the crtI promoter being critically dependent on a pentanucleotide sequence centred at the −31 position. The similarity of this sequence with the consensus for ECF‐σ‐dependent promoters from other bacteria is discussed. The activity of the crtI promoter also depends on certain basepairs at the −10 region. Hence, the operation of ECF‐σ‐factors seems to require binding to two different DNA sites, although the −10 sequences of different ECF‐σ‐dependent promoters are unrelated to one another, and the ECF‐σ‐factors themselves lack the conserved domain known to mediate binding of other σ‐factors to the −10 DNA site.

Clustering and co‐ordinated activation of carotenoid genes in Myxococcus xanthus by blue light

Blue light activates carotenoid production in the non‐photosynthetic, Gram‐negative bacterium Myxococcus xanthus. Light is known to stimulate the expression of two unlinked genes for carotenoid synthesis, carB and carC, through a mechanism in which the regulatory genes carA, carQ and carR take part. Genes carQ and carR are linked together at a separate locus, whereas carA is linked to carB. We have introduced Tn5 at various sites between carA and carB. Chemical analyses of the mutant strains demonstrate the presence in this region of a cluster of genes for carotenoid synthesis. Gene expression analysis strongly argues for most (or all) of the genes in the cluster being transcribed from a single, light‐inducible promoter under the control of genes carA, carQ and carR.

Vitamin B12 partners the CarH repressor to downregulate a photoinducible promoter in Myxococcus xanthus

A light‐inducible promoter, PB, drives expression of the carB operon in Myxococcus xanthus. Repressed by CarA in the dark, PB is activated when CarS, produced in the light, sequesters CarA to prevent operator‐CarA binding. The MerR‐type, N‐terminal domain of CarA, which mediates interactions with both operator and CarS, is linked to a C‐terminal oligomerization module with a predicted cobalamin‐binding motif. Here, we show that although CarA does bind vitamin B12, mutating the motif involved has no effect on its ability to repress PB. Intriguingly, PB could be repressed in the dark even with no CarA, so long as B12 and an intact CarA operator were present. We have discovered that this effect of B12 depends on the gene immediately downstream of carA. Its product, CarH, also consists of a MerR‐type, N‐terminal domain that specifically recognizes the CarA operator and CarS, linked to a predicted B12‐binding C‐terminal oligomerization module. The B12‐mediated repression of PB in the dark is relieved by deleting carH, by mutating the DNA‐ or B12‐binding residues of CarH, or by illumination. Our findings unveil parallel regulatory circuits that control a light‐inducible promoter using a transcriptional factor repertoire that includes a paralogous gene pair and vitamin B12.

The Stigmatella aurantiaca Homolog of Myxococcus xanthus High-Mobility-Group A-Type Transcription Factor CarD: Insights into the Functional Modules of CarD and Their Distribution in Bacteria

Transcriptional factor CarD is the only reported prokaryotic analog of eukaryotic high-mobility-group A (HMGA) proteins, in that it has contiguous acidic and AT hook DNA-binding segments and multifunctional roles in Myxococcus xanthus carotenogenesis and fruiting body formation. HMGA proteins are small, randomly structured, nonhistone, nuclear architectural factors that remodel DNA and chromatin structure. Here we report on a second AT hook protein, CarD(Sa), that is very similar to CarD and that occurs in the bacterium Stigmatella aurantiaca. CarD(Sa) has a C-terminal HMGA-like domain with three AT hooks and a highly acidic adjacent region with one predicted casein kinase II (CKII) phosphorylation site, compared to the four AT hooks and five CKII sites in CarD. Both proteins have a nearly identical 180-residue N-terminal segment that is absent in HMGA proteins. In vitro, CarD(Sa) exhibits the specific minor-groove binding to appropriately spaced AT-rich DNA that is characteristic of CarD or HMGA proteins, and it is also phosphorylated by CKII. In vivo, CarD(Sa) or a variant without the single CKII phosphorylation site can replace CarD in M. xanthus carotenogenesis and fruiting body formation. These two cellular processes absolutely require that the highly conserved N-terminal domain be present. Thus, three AT hooks are sufficient, the N-terminal domain is essential, and phosphorylation in the acidic region by a CKII-type kinase can be dispensed with for CarD function in M. xanthus carotenogenesis and fruiting body development. Whereas a number of hypothetical proteins homologous to the N-terminal region occur in a diverse array of bacterial species, eukaryotic HMGA-type domains appear to be confined primarily to myxobacteria.

Expression of Tn5-derived kanamycin resistance in the fungus Phycomyces blakesleeanus

SummaryA plasmid, carrying the Tn5 gene for kanamycin resistance lacking its own promoter, has successfully been used in the selection of DNA sequences of the fungus Phycomyces blakesleeanus having promoter activity in Escherichia coli. Many of these sequences were also effective in promoting resistance to kanamycin when the corresponding chimeric plasmids were introduced in the fungus via spheroplast transformation. The selected phenotype was easily propagated through vegetative spores and behaved as a stable character since it was not appreciably lost in the absence of selection.

A novel regulatory gene for light‐induced carotenoid synthesis in the bacterium Myxococcus xanthus

Myxococcus xanthus cells respond to blue light by producing carotenoids. Light triggers a network of regulatory actions that lead to the transcriptional activation of the carotenoid genes. By screening the colour phenotype of a collection of Tn 5‐lac insertion mutants, we have isolated a new mutant devoid of carotenoid synthesis. We map the transposon insertion, which co‐segregates with the mutant phenotype, to a previously unknown gene designated here as carF . An in frame deletion within carF causes the same phenotype as the Tn 5 ‐ lac insertion. The carF deletion prevents the activation of the normally light‐inducible genes, without affecting the expression of any of the regulatory genes known to be expressed in a light‐independent manner. Until now, the switch that sets off the regulatory cascade had been identified with light‐driven inactivation of protein CarR, an antisigma factor. The exact mechanism of this inactivation has remained elusive. We show by epistatic analysis that the carF gene product participates in the light‐dependent inactivation of CarR. The predicted CarF amino acid sequence reveals no known prokaryotic homologues. On the other hand, CarF is remarkably similar to Kua, a family of proteins of unknown function that is widely distributed among eukaryotes.

Accumulation of carotenoids in structural and regulatory mutants of the Bacterium Myxococcus xanthus

SummaryAccumulation of carotenoids in Myxococcus xanthus is absolutely dependent on illumination with blue light. We report the analysis of the carotenoids of dark- and light-grown cultures of the wild type and several previously characterized mutants. A carR mutant produces the same carotenoids in the dark as the wild type grown in the light. This agrees with previous evidence indicating that the carR gene codes for a general negative regulator of the system. A cis-dominant mutation in the gene carA causes constitutive expression of the light-inducible gene carB, which is linked to carA. In the dark, the carA mutant produces high levels of phytoene, the first C40 colourless carotenoid precursor; in the light, it produces the same carotenoids as the wild type. Since a mutation in carB blocks accumulation of phytoene, we propose that carB, and probably other linked genes also controlled by carA, code for enzymes involved in the synthesis of phytoene. This is virtually the only carotene accumulated by strains mutated in the gene carC, which is unlinked to the others. Thus carC codes for phytoene dehydrogenase, the enzyme that converts phytoene into coloured carotenoids. The results presented here also provide evidence for control of carotenogenesis by an endproduct that is independent of the blue light effect.

Light-dependent gene regulation in nonphototrophic bacteria

Bacteria sense and respond to light, a fundamental environmental factor, by employing highly evolved machineries and mechanisms. Cellular systems exist to harness light energy usefully as in phototrophic bacteria, to combat photo-oxidative damage stemming from the highly reactive species generated on absorption of light energy, and to link the light stimulus to DNA repair, taxis, development, and virulence. Recent findings on the genetic response to light in nonphototrophic bacteria highlight the ingenious transcriptional regulatory mechanisms and the panoply of factors that have evolved to perceive and transmit the signal, and to bring about finely tuned gene expression.