Confirmation and variability of the Allee effect in Dictyostelium discoideum cell populations,possible role of chemical signaling within cell clusters

In studies of the unicellular eukaryote Dictyostelium discoideum, many have anecdotally observed that cell dilution below a certain "threshold density” causes cells to undergo a period of slow growth (lag). However, little is documented about the slow growth phase and the reason for different growth dynamics below and above this threshold density. In this paper, we extend and correct our earlier work to report an extensive set of experiments, including the use of new cell counting technology, that set this slow-to-fast growth transition on a much firmer biological basis. We show that dilution below a certain density (around 10E4 cells/ml) causes cells to grow slower on average and exhibit a large degree of variability: sometimes a sample does not lag at all, while sometimes it takes many moderate density cell cycle times to recover back to fast growth. We perform conditioned media experiments to demonstrate that a chemical signal mediates this endogenous phenomenon. Finally, we argue that while simple models involving fluid transport of signal molecules or cluster-based signaling explain typical behavior, they do not capture the high degree of variability between samples but nevertheless favor an intra-cluster mechanism.

Imaging Promoter Assay of Adenylyl Cyclase A Gene in Dictyostelium discoideum during Fruiting Body Formation by Dual-Color Bioluminescence Microscopy

Cyclic adenosine monophosphate (cAMP), which is derived from adenosine triphosphate through adenylyl cyclase A (acaA), acts as an intracellular secondary messenger and an extracellular chemotactic substance in important biological processes. In the social amoebae Dictyostelium discoideum, cAMP mediates cell aggregation, development, and differentiation to spore and stalk cells during fruiting body formation. The acaA gene is transcribed under the control of three different alternative promoters. This study aimed to develop a promoter assay for acaA in D. discoideum using bioluminescence microscopy. Here, we inserted green- and red-emitting luciferase genes into downstream of promoter regions 1 and 3, respectively. Promoter activities were visualized by bioluminescence microscopy. We confirmed the differential expression of acaA under the control of promoters 1 and 3 at the different stages of D. discoideum development. We also demonstrated the application of dual-color bioluminescence imaging in the development of an imaging promoter assay.

Reactive/Less-cooperative individuals advance population’s synchronization: Modeling of Dictyostelium discoideum concerted signaling during aggregation phase

Orchestrated chemical signaling of single cells sounds to be a linchpin of emerging organization and multicellular life form. The social amoeba Dictyostelium discoideum is a well-studied model organism to explore overall pictures of grouped behavior in developmental biology. The chemical waves secreted by aggregating Dictyostelium is a superb example of pattern formation. The waves are either circular or spiral in shape, according to the incremental population density of a self-aggregating community of individuals. Here, we revisit the spatiotemporal patterns that appear in an excitable medium due to synchronization of randomly firing individuals, but with a more parsimonious attitude. According to our model, a fraction of these individuals are less involved in amplifying external stimulants. Our simulations indicate that the cells enhance the system’s asymmetry and as a result, nucleate early sustainable spiral territory zones, provided that their relative population does not exceed a tolerable threshold.

Generation of a Mitochondrial Protein Compendium in Dictyostelium Discoideum

The social amoeba Dictyostelium discoideum is a well-established model to study numerous cellular processes including cell motility, chemotaxis, and differentiation. As energy metabolism is involved in these processes, mitochondrial genetics and bioenergetics are of interest, though many features of Dictyostelium mitochondria differ from metazoans. A comprehensive inventory of mitochondrial proteins is critical to understanding mitochondrial processes and their involvement in various cellular pathways. Here, we utilized high-throughput multiplexed protein quantitation and homology analyses to generate a high-confidence mitochondrial protein compendium. Our proteomic approach, which utilizes quantitative mass spectrometry in combination with mathematical modeling, was validated through mitochondrial targeting sequence prediction and live-cell imaging. Our final compendium consists of 1082 proteins. Within our D. discoideum mitochondrial proteome, we identify many proteins that are not present in humans, yeasts, or the ancestral alpha-proteobacteria, which can serve as a foundation for future investigations into the unique mitochondria of Dictyostelium. Additionally, we leverage our compendium to highlight the complexity of metabolic reprogramming during starvation-induced development. Our compendium lays a foundation to investigate mitochondrial processes that are unique in protists, as well as for future studies to understand the functions of conserved mitochondrial proteins in health and diseases using D. discoideum as the model.

Disruption of vacuolin microdomains in the host Dictyostelium discoideum increases resistance to Mycobacterium marinum-induced membrane damage and infection

Mycobacterium tuberculosis (Mtb), the causative agent of tuberculosis, manipulates the host phagosome maturation pathway to replicate intracellularly. Mycobacterium marinum, a closely-related species, and Dictyostelium discoideum, a social amoeba and alternative phagocytic host, have been used as models to study host-pathogen interactions occurring during mycobacterial infections. Vacuolins, functional homologues of the mammalian flotillins, organize membrane microdomains and play a role in vesicular trafficking. Various pathogens have been reported to manipulate their membrane association and function. During infection of D. discoideum with M. marinum, Vacuolin C was specifically and highly induced and all three vacuolin isoforms were enriched at the mycobacteria-containing-vacuole (MCV). In addition, absence of vacuolins reduced escape from the MCV and conferred resistance to M. marinum infection. Moreover, ESAT-6, the membrane-disrupting virulence factor of M. marinum, was less associated with membranes when vacuolins were absent. Together, these results suggest that vacuolins are important host factors that are manipulated by mycobacteria to inflict membrane damage and escape from their compartment.

Generation of a mitochondrial protein compendium in Dictyostelium discoideum

The social amoeba Dictyostelium discoideum is a well-established model to study numerous cellular processes including cell motility, chemotaxis, and differentiation. As energy metabolism is involved in these processes, mitochondrial genetics and bioenergetics are of interest, though many features of Dictyostelium mitochondria differ from metazoans. A comprehensive inventory of mitochondrial proteins is critical to understanding mitochondrial processes and their involvement in various cellular pathways. Here, we utilized high-throughput multiplexed protein quantitation and homology analyses to generate a high-confidence mitochondrial protein compendium. Our proteomic approach, which utilizes quantitative mass spectrometry in combination with mathematical modeling, was validated through mitochondrial targeting sequence prediction and live-cell imaging. Our final compendium consists of 1082 proteins. Within our D. discoideum mitochondrial proteome, we identify many proteins that are not present in humans, yeasts, or the ancestral alpha-proteobacteria, which can serve as a foundation for future investigations into the unique mitochondria of Dictyostelium. Additionally, we leverage our compendium to highlight the complexity of metabolic reprogramming during starvation-induced development. Our compendium lays a foundation to investigate mitochondrial processes that are unique in protists, as well as for future studies to understand the functions of conserved mitochondrial proteins in health and diseases using D. discoideum as the model.