Mitochondrial respiratory complex function and the phenotypic consequences of dysfunction.

Dictyostelium provides a well established model system for the study of mitochondrial biology and disease. Mitochondrial dysfunction in Dictyostelium has been generated by knockout of nonessential nuclear genes encoding mitochondrial proteins, by knockout of targeted mitochondrial genes in a subset of the mitochondria, and by knock down of essential nuclear-encoded mitochondrial proteins. The resulting effects on mitochondrial electron transport and membrane potential can be studied by directly measuring the activities, composition, and assembly or stability of individual mitochondrial respiratory complexes and by using fluorescent probes to assay the mitochondrial membrane potential in vivo. Assays for these are described here. The complexities of mammalian developmental biology have obscured the phenotype-genotype relationships in mitochondrial disease and this has inhibited understanding of the underlying cytopathological mechanisms. By contrast, the Dictyostelium model has revealed a characteristic constellation of downstream phenotypic outcomes that, e.g., point to/show common underlying cytopathological mechanisms in mitochondrial disease. These aberrant phenotypes arise from chronic hyperactivity of the energy-sensing protein kinase AMPK and the assay of the most prominent of them is described here.

Monitoring autophagy in Dictyostelium.

Autophagy is an intracellular degradation mechanism essential for cell survival and maintenance of cellular homeostasis, differentiation, and development. Recent research has highlighted the impact of autophagy in neurodegenerative diseases and aging. We are still far from fully understanding the molecular mechanism of autophagy and its regulation, essential for its future use as a therapeutic target. In the last years many different techniques have been developed to study this process and some of them have been successfully used in Dictyostelium. We describe here the use of confocal microscopy to detect the pattern of different autophagic markers and the differences expected in strains deficient in autophagy. Autophagy dysfunction might also lead to the formation of intracellular ubiquitinated protein aggregates that can be easily detected by immunofluorescence. In addition, we describe two different techniques that allow the assessment of the so-called autophagic flux, the progression of autophagosomes until their fusion with lysosomes. The first one is a proteolytic cleavage assay of cytosolic markers such as GFP-PgkA and the second the visualization of the RFP-GFP-Atg8 marker by confocal microscopy.

Ndufaf5 deficiency in the Dictyostelium model: new roles in autophagy and development.

Ndufaf5 (also known as C20orf7) is a mitochondrial complex I (CI) assembly factor whose mutations lead to human mitochondrial disease. Little is known about the function of the protein and the cytopathological consequences of the mutations. Disruption of Dictyostelium Ndufaf5 leads to CI deficiency and defects in growth and development. The predicted sequence of Ndufaf5 contains a putative methyltransferase domain. Site-directed mutagenesis indicates that the methyltransferase motif is essential for its function. Pathological mutations were recreated in the Dictyostelium protein and expressed in the mutant background. These proteins were unable to complement the phenotypes, which further validates Dictyostelium as a model of the disease. Chronic activation of AMP-activated protein kinase (AMPK) has been proposed to play a role in Dictyostelium and human cytopathology in mitochondrial diseases. However, inhibition of the expression of AMPK gene in the Ndufaf5-null mutant does not rescue the phenotypes associated with the lack of Ndufaf5, suggesting that novel AMPK-independent pathways are responsible for Ndufaf5 cytopathology. Of interest, the Ndufaf5-deficient strain shows an increase in autophagy. This phenomenon was also observed in a Dictyostelium mutant lacking MidA (C2orf56/PRO1853/Ndufaf7), another CI assembly factor, suggesting that autophagy activation might be a common feature in mitochondrial CI dysfunction.

A proteolytic cleavage assay to monitor autophagy in Dictyostelium discoideum.

Dictyostelium discoideum is a good model of autophagy. However, the lack of autophagic flux techniques hinders the assessment of new mutants or drugs. One of these techniques, which has been used successfully in yeast and mammalian cells, but has not yet been described in Dictyostelium, is based on the presence of proteolytic fragments derived from autophagic degradation of expressed fusion proteins. Lysosomotropic agents such as NH 4Cl penetrate acidic compartments and raise their pH, thus allowing the accumulation and measurement of these cleaved fragments, which otherwise would be rapidly degraded. We have used this property to detect the presence of free GFP fragments derived from the fusion protein GFP-Tkt-1, a cytosolic marker. We demonstrate that this proteolytic event is dependent on autophagy and can be used to detect differences in the level of autophagic flux among different mutant strains. Moreover, treatment with NH4Cl also facilitates the assessment of autophagic flux by confocal microscopy using the marker RFP-GFP-Atg8.

The Dictyostelium model for mitochondrial disease.

Mitochondrial diseases are a diverse family of genetic disorders caused by mutations affecting mitochondrial proteins encoded in either the nuclear or the mitochondrial genome. By impairing mitochondrial oxidative phosphorylation, they compromise cellular energy production and the downstream consequences in humans are a bewilderingly complex array of signs and symptoms that can affect any of the major organ systems in unpredictable combinations. This complexity and unpredictability has limited our understanding of the cytopathological consequences of mitochondrial dysfunction. By contrast, in Dictyostelium the mitochondrial disease phenotypes are consistent, measurable "readouts" of dysregulated intracellular signalling pathways. When the underlying genetic defects would produce coordinate, generalized deficiencies in multiple mitochondrial respiratory complexes, the disease phenotypes are mediated by chronic activation of an energy-sensing protein kinase, AMP-activated protein kinase (AMPK). This chronic AMPK hyperactivity maintains mitochondrial mass and cellular ATP concentrations at normal levels, but chronically impairs growth, cell cycle progression, multicellular development, photosensory and thermosensory signal transduction. It also causes the cells to support greater proliferation of the intracellular bacterial pathogen, Legionella pneumophila. Notably however, phagocytic and macropinocytic nutrient uptake are impervious both to AMPK signalling and to these types of mitochondrial dysfunction. Surprisingly, a Complex I-specific deficiency (midA knockout) not only causes the foregoing AMPK-mediated defects, but also produces a dramatic deficit in endocytic nutrient uptake accompanied by an additional secondary defect in growth. More restricted and specific phenotypic outcomes are produced by knocking out genes for nuclear-encoded mitochondrial proteins that are not required for respiration. The Dictyostelium model for mitochondrial disease has thus revealed consistent patterns of sublethal dysregulation of intracellular signalling pathways that are produced by different types of underlying mitochondrial dysfunction.

Autophagy in Dictyostelium: genes and pathways, cell death and infection.

The use of simple organisms to understand the molecular and cellular function of complex processes is instrumental for the rapid development of biomedical research. A remarkable example has been the discovery in S. cerevisiae of a group of proteins involved in the pathways of autophagy. Orthologues of these proteins have been identified in humans and experimental model organisms. Interestingly, some mammalian autophagy proteins do not seem to have homologues in yeast but are present in Dictyostelium, a social amoeba with two distinctive life phases, a unicellular stage in nutrient-rich conditions that differentiates upon starvation into a multicellular stage that depends on autophagy. This review focuses on the identification and annotation of the putative Dictyostelium autophagy genes and on the role of autophagy in development, cell death and infection by bacterial pathogens.

MidA is a putative methyltransferase that is required for mitochondrial complex I function.

Dictyostelium and human MidA are homologous proteins that belong to a family of proteins of unknown function called DUF185. Using yeast two-hybrid screening and pull-down experiments, we showed that both proteins interact with the mitochondrial complex I subunit NDUFS2. Consistent with this, Dictyostelium cells lacking MidA showed a specific defect in complex I activity, and knockdown of human MidA in HEK293T cells resulted in reduced levels of assembled complex I. These results indicate a role for MidA in complex I assembly or stability. A structural bioinformatics analysis suggested the presence of a methyltransferase domain; this was further supported by site-directed mutagenesis of specific residues from the putative catalytic site. Interestingly, this complex I deficiency in a Dictyostelium midA(-) mutant causes a complex phenotypic outcome, which includes phototaxis and thermotaxis defects. We found that these aspects of the phenotype are mediated by a chronic activation of AMPK, revealing a possible role of AMPK signaling in complex I cytopathology.

Vacuole membrane protein 1, autophagy and much more.

Vacuole membrane protein 1 (Vmp1) is a putative transmembrane protein that has been associated with different functions including autophagy, cell adhesion, and membrane traffic. Highly similar proteins are present in lower eukaryotes and plants although a homologue is absent in the fungi lineage. We have recently described the first loss-of-function mutation for a Vmp1 homologue in a model system, Dictyostelium discoideum. Our results give a more comprehensive view of the intricate roles played by this new gene. Dictyostelium Vmp1 is an endoplasmic reticulum-resident protein. Cells deficient in Vmp1 display pleiotropic defects in the context of the secretory pathway such as organelle biogenesis, the endocytic pathway, and protein secretion. The biogenesis of the contractile vacuole, an organelle necessary to survive under hypoosmotic conditions, is compromised as well as the structure of the endoplasmic reticulum and the Golgi apparatus. Transmission electron microscopy also shows abnormal accumulation of aberrant double-membrane vesicles, suggesting a defect in autophagosome biogenesis or maturation. The expression of a mammalian Vmp1 in the Dictyostelium mutant complements the phenotype suggesting a functional conservation during evolution. We are taking the first steps in understanding the function of this fascinating protein and recent studies have brought us more questions than answers about its basic function and its role in human pathology.

Dictyostelium transcriptional responses to Pseudomonas aeruginosa: common and specific effects from PAO1 and PA14 strains.

BACKGROUND: Pseudomonas aeruginosa is one of the most relevant human opportunistic bacterial pathogens. Two strains (PAO1 and PA14) have been mainly used as models for studying virulence of P. aeruginosa. The strain PA14 is more virulent than PAO1 in a wide range of hosts including insects, nematodes and plants. Whereas some of the differences might be attributable to concerted action of determinants encoded in pathogenicity islands present in the genome of PA14, a global analysis of the differential host responses to these P. aeruginosa strains has not been addressed. Little is known about the host response to infection with P. aeruginosa and whether or not the global host transcription is being affected as a defense mechanism or altered in the benefit of the pathogen. Since the social amoeba Dictyostelium discoideum is a suitable host to study virulence of P. aeruginosa and other pathogens, we used available genomic tools in this model system to study the transcriptional host response to P. aeruginosa infection. RESULTS: We have compared the virulence of the P. aeruginosa PAO1 and PA14 using D. discoideum and studied the transcriptional response of the amoeba upon infection. Our results showed that PA14 is more virulent in Dictyostelium than PA01using different plating assays. For studying the differential response of the host to infection by these model strains, D. discoideum cells were exposed to either P. aeruginosa PAO1 or P. aeruginosa PA14 (mixed with an excess of the non-pathogenic bacterium Klebsiella aerogenes as food supply) and after 4 hours, cellular RNA extracted. A three-way comparison was made using whole-genome D. discoideum microarrays between RNA samples from cells treated with the two different strains and control cells exposed only to K. aerogenes. The transcriptomic analyses have shown the existence of common and specific responses to infection. The expression of 364 genes changed in a similar way upon infection with one or another strain, whereas 169 genes were differentially regulated depending on whether the infecting strain was either P. aeruginosa PAO1 or PA14. Effects on metabolism, signalling, stress response and cell cycle can be inferred from the genes affected. CONCLUSION: Our results show that pathogenic Pseudomonas strains invoke both a common transcriptional response from Dictyostelium and a strain specific one, indicating that the infective process of bacterial pathogens can be strain-specific and is more complex than previously thought.

Vacuole membrane protein 1 is an endoplasmic reticulum protein required for organelle biogenesis, protein secretion, and development.

Vacuole membrane protein 1 (Vmp1) is membrane protein of unknown molecular function that has been associated with pancreatitis and cancer. The social amoeba Dictyostelium discoideum has a vmp1-related gene that we identified previously in a functional genomic study. Loss-of-function of this gene leads to a severe phenotype that compromises Dictyostelium growth and development. The expression of mammalian Vmp1 in a vmp1(-) Dictyostelium mutant complemented the phenotype, suggesting a functional conservation of the protein among evolutionarily distant species and highlights Dictyostelium as a valid experimental system to address the function of this gene. Dictyostelium Vmp1 is an endoplasmic reticulum protein necessary for the integrity of this organelle. Cells deficient in Vmp1 display pleiotropic defects in the secretory pathway and organelle biogenesis. The contractile vacuole, which is necessary to survive under hypoosmotic conditions, is not functional in the mutant. The structure of the Golgi apparatus, the function of the endocytic pathway and conventional protein secretion are also affected in these cells. Transmission electron microscopy of vmp1(-) cells showed the accumulation of autophagic features that suggests a role of Vmp1 in macroautophagy. In addition to these defects observed at the vegetative stage, the onset of multicellular development and early developmental gene expression are also compromised.