An iso-15 : 0 O-alkylglycerol moiety is the key structure of the E-signal in Myxococcus xanthus

Transcriptomic analysis of Myxococcus xanthus csgA, fruA, and mrpC mutants reveals extensive and diverse roles of key regulators in the multicellular developmental process

BACKGROUND

The bacterium Myxococcus xanthus provides an important multicellular model for understanding stress responses. The regulatory proteins CsgA, FruA, and MrpC are essential to survive prolonged starvation by forming fruiting bodies, which are mounds containing hardy round spores formed from vegetative rods, but the genome-wide pathways affected by these proteins remain poorly understood. Only a fruA mutant transcriptome and MrpC ChIP-seq have been reported. We describe RNA-seq transcriptome analysis of csgA, fruA, and mrpC mutants relative to a wild-type laboratory strain midway during the starvation-induced developmental process, when mounds, but not spores, have formed.

RESULTS

We show that CsgA, FruA, and MrpC broadly impact developmental gene expression, with over 60% of the genes differentially expressed in one or more mutants. Building upon previous investigations, we found that strongly regulated genes in the mrpC mutant correlate with MrpC DNA-binding sites located ~ 80 bp upstream of transcriptional start sites. We also confirmed that FruA directly or indirectly regulates many genes negatively, as well as many others positively. CsgA regulates indirectly and its strongest effects are positive. MrpC strongly stimulates fruA transcription and FruA accumulation, impacting many genes, but our results reveal that MrpC is also a strong negative or positive regulator of hundreds of genes independently of FruA. Indeed, we observed nearly every possible pattern of coregulation, unique regulation, and counterregulation by comparing the wild-type and mutant transcriptomes, indicating diverse roles of CsgA, FruA, and MrpC in the developmental gene regulatory network. The genes most strongly regulated were coregulated in two or three of the mutants. Each set of genes exhibiting differential expression in one or more mutants was analyzed for enrichment of gene ontology (GO) terms or KEGG pathways, and predicted protein-protein interactions. These analyses highlighted enrichment of pathways involved in cellular signaling, protein synthesis, energetics, and envelope function. In particular, we describe how CsgA, FruA, and MrpC control production of ribosomes, lipid signals, and peptidoglycan intermediates during development.

CONCLUSIONS

By comparing wild-type and mutant transcriptomes midway in development, this study documents individual and coordinate regulation of crucial pathways by CsgA, FruA, and MrpC, providing a valuable resource for future investigations.

Plasmalogens and Photooxidative Stress Signaling in Myxobacteria, and How it Unmasked CarF/TMEM189 as the Δ1'-Desaturase PEDS1 for Human Plasmalogen Biosynthesis

Plasmalogens are glycerophospholipids with a hallmark sn-1 vinyl ether bond that endows them with unique physical-chemical properties. They have proposed biological roles in membrane organization, fluidity, signaling, and antioxidative functions, and abnormal plasmalogen levels correlate with various human pathologies, including cancer and Alzheimer’s disease. The presence of plasmalogens in animals and in anaerobic bacteria, but not in plants and fungi, is well-documented. However, their occurrence in the obligately aerobic myxobacteria, exceptional among aerobic bacteria, is often overlooked. Tellingly, discovery of the key desaturase indispensable for vinyl ether bond formation, and therefore fundamental in plasmalogen biogenesis, emerged from delving into how the soil myxobacterium Myxococcus xanthus responds to light. A recent pioneering study unmasked myxobacterial CarF and its human ortholog TMEM189 as the long-sought plasmanylethanolamine desaturase (PEDS1), thus opening a crucial door to study plasmalogen biogenesis, functions, and roles in disease. The findings demonstrated the broad evolutionary sweep of the enzyme and also firmly established a specific signaling role for plasmalogens in a photooxidative stress response. Here, we will recount our take on this fascinating story and its implications, and review the current state of knowledge on plasmalogens, their biosynthesis and functions in the aerobic myxobacteria.

Global gene expression analysis of the Myxococcus xanthus developmental time course

To accurately identify the genes and pathways involved in the initiation of the Myxococcus xanthus multicellular developmental program, we have previously reported a method of growing vegetative populations as biofilms within a controllable environment. Using a modified approach to remove up to ~90% rRNAs, we report a comprehensive transcriptional analysis of the M. xanthus developmental cycle while comparing it with the vegetative biofilms grown in rich and poor nutrients. This study identified 1522 differentially regulated genes distributed within eight clusters during development. It also provided a comprehensive overview of genes expressed during a nutrient-stress response, specific development time points, and during development initiation and regulation. We identified several differentially expressed genes involved in key central metabolic pathways suggesting their role in regulating myxobacterial development. Overall, this study will prove an important resource for myxobacterial researchers to delineate the regulatory and functional pathways responsible for development from those of the general nutrient stress response.

The Myxobacterium Myxococcus xanthus Can Sense and Respond to the Quorum Signals Secreted by Potential Prey Organisms

The myxobacterium Myxococcus xanthus is a predatory member of the soil microfauna, able to consume bacteria (Gram-negative, Gram-positive), archaea, and fungi. Many potential prey of M. xanthus communicate amongst themselves using acyl homoserine lactones (AHLs) as quorum signals. M. xanthus cannot itself produce AHLs, but could potentially benefit by responding to exogenous AHLs produced during signaling between proximal prey. Four AHLs of different side chain length were tested and all found to delay sporulation of M. xanthus vegetative cells, and to stimulate germination of myxospores, increasing the proportion of predatory vegetative cells in the population. The predatory activity and expansion rates of M. xanthus colonies were also found to be stimulated by AHLs. Thermally inactivated AHLs had no effect on M. xanthus cells, and the response to AHLs depended (non-linearly) on the length of AHL side chain, suggesting that the effect of AHLs was mediated by specific signaling within M. xanthus, rather than being a consequence of the chemical or physical properties of AHLs. Therefore, it seems that the presence of xenic quorum signaling molecules enhances the predatory activity of M. xanthus. AHLs increase the proportion of the population capable of predation, and stimulate the motility and predatory activity of vegetative cells. We therefore propose that in the wild, M. xanthus uses AHLs as markers of nearby prey, potentially eavesdropping on the conversations between prey organisms.

Myxobacteria: Moving, Killing, Feeding, and Surviving Together

Myxococcus xanthus, like other myxobacteria, is a social bacterium that moves and feeds cooperatively in predatory groups. On surfaces, rod-shaped vegetative cells move in search of the prey in a coordinated manner, forming dynamic multicellular groups referred to as swarms. Within the swarms, cells interact with one another and use two separate locomotion systems. Adventurous motility, which drives the movement of individual cells, is associated with the secretion of slime that forms trails at the leading edge of the swarms. It has been proposed that cellular traffic along these trails contributes to M. xanthus social behavior via stigmergic regulation. However, most of the cells travel in groups by using social motility, which is cell contact-dependent and requires a large number of individuals. Exopolysaccharides and the retraction of type IV pili at alternate poles of the cells are the engines associated with social motility. When the swarms encounter prey, the population of M. xanthus lyses and takes up nutrients from nearby cells. This cooperative and highly density-dependent feeding behavior has the advantage that the pool of hydrolytic enzymes and other secondary metabolites secreted by the entire group is shared by the community to optimize the use of the degradation products. This multicellular behavior is especially observed in the absence of nutrients. In this condition, M. xanthus swarms have the ability to organize the gliding movements of 1000s of rods, synchronizing rippling waves of oscillating cells, to form macroscopic fruiting bodies, with three subpopulations of cells showing division of labor. A small fraction of cells either develop into resistant myxospores or remain as peripheral rods, while the majority of cells die, probably to provide nutrients to allow aggregation and spore differentiation. Sporulation within multicellular fruiting bodies has the benefit of enabling survival in hostile environments, and increases germination and growth rates when cells encounter favorable conditions. Herein, we review how these social bacteria cooperate and review the main cell–cell signaling systems used for communication to maintain multicellularity.