Peptidoglycan Salvage Enables the Periodontal Pathogen Tannerella forsythia to Survive within the Oral Microbial Community

<i>Tannerella forsythia</i> is an anaerobic, fusiform Gram-negative oral pathogen strongly associated with periodontitis, a multibacterial inflammatory disease that leads to the destruction of the teeth-supporting tissue, ultimately causing tooth loss. To survive in the oral habitat, <i>T. forsythia</i> depends on cohabiting bacteria for the provision of nutrients. For axenic growth under laboratory conditions, it specifically relies on the external supply of <i>N</i>-acetylmuramic acid (MurNAc), which is an essential constituent of the peptidoglycan (PGN) of bacterial cell walls. <i>T. forsythia</i> comprises a typical Gram-negative PGN; however, as evidenced by genome sequence analysis, the organism lacks common enzymes required for the <i>de novo</i> synthesis of precursors of PGN, which rationalizes its MurNAc auxotrophy. Only recently insights were obtained into how <i>T. forsythia</i> gains access to MurNAc in its oral habitat, enabling synthesis of the own PGN cell wall. This report summarizes <i>T. forsythia</i>’s strategies to survive in the oral habitat by means of PGN salvage pathways, including recovery of exogenous MurNAc and PGN-derived fragments but also polymeric PGN, which are all derived from cohabiting bacteria either via cell wall turnover or decay of cells. Salvage of polymeric PGN presumably requires the removal of peptides from PGN by an unknown amidase, concomitantly with the translocation of the polymer across the outer membrane. Two recently identified exo-lytic <i>N</i>-acetylmuramidases (Tf_NamZ1 and Tf_NamZ2) specifically cleave the peptide-free, exogenous (nutrition source) PGN in the periplasm and release the MurNAc and disaccharide substrates for the transporters Tf_MurT and Tf_AmpG, respectively, whereas the peptide-containing, endogenous (the self-cell wall) PGN stays unattached. This review also outlines how <i>T. forsythia</i> synthesises the PGN precursors UDP-MurNAc and UDP-<i>N</i>-acetylglucosamine (UDP-GlcNAc), involving homologs of the <i>Pseudomonas</i> sp. recycling enzymes AmgK/MurU and a monofunctional uridylyl transferase (named Tf_GlmU*), respectively.

Multidrug and efflux transporters of the model microbe Dictyostelium

The evolutionarily ubiquitous multidrug and toxin efflux (MATE) proteins mediate anticancer and antibiotic resistance, while transporting toxins, ions and flavonoids in plants. MATEs of the model amoeba Dictyostelium discoideum have not been studied although sequences of its pair group with the two Homo sapiensMATEs. Ddmate1 and 2 are both transcribed, Ddmate2 more so, with peaks in vegetative and slug life-cycle stages. Ddmate1 was upregulated in response to a toxin, ethidium bromide, at the lowest concentration tested. Removing MATE function by inhibitor or mutation increased intracellular levels of various compounds, confirming these as efflux transporters. Plasma membrane localisation was revealed using a GFP-MATE1 reporter-line. MATE1 and MATE2 phenotypes indicated roles beyond detoxification: on Klebsiella lawns these mutants produced significantly smaller plaques than WT, and their axenic growth rates were also lower. The transporters’ impact on use of Dictyostelium for novel drug research was tested using flavonoids. LCMS and fluorescence-imaging revealed differential flavonoid uptake. Flavanones such as naringenin did not cross into cells, whereas flavonols localised to mitochondria and cytoplasm. Ddmate1 transcription was upregulated, however, in response to naringenin, which is known to reduce levels of kidney-disease protein PKD2 in both Dictyostelium and animal cells. Increased flavonol intracellular concentrations confirmed that efflux not import was impeded in MATE1 and MATE2, and kaempferol therefore further reduced MATE1-cells’ growth. These D. discoideum MATEs may usefully model the HsMATEs, aid understanding of flavonoids’ effects, and should be considered when using this model eukaryote to screen drugs.

Vitamin supplementation increases the virulence of Entamoeba histolytica grown axenically

As a consequence of axenic growth and the elimination of accompanying bacterial flora, Entamoeba histolytica virulence decreases rapidly, and pathogenicity is lost. This paper evaluated the impact of vitamin supplementation on the pathogenicity of E. histolytica. Growth of E. histolytica trophozoites, cultured axenically in PEHPS (a Spanish acronym for the main ingredients – casein peptone, liver, pancreas extract and bovine serum) medium, with or without vitamins, exhibited a similar growth rate. However, the vitamin-enriched PEHPS preparations expressed 2.65 times more haemolytic activity (at 60 min: 98 vs 48%, P < 0.05), 2.5 times more phospholipase A2 activity at 150 min of incubation and generated more hepatic abscesses (88 vs 60%, P = 0.05) than the preparations without vitamins. The haemolytic and phospholipase A2 activity for the PEHPS − V preparations were restored following vitamin supplementation with A and D. These data highlight, for the first time, that vitamins and specifically vitamin A and D were essential for the recovery of amoebic virulence, lost through axenic growth.

Neurofibromin controls macropinocytosis and phagocytosis in Dictyostelium

Cells use phagocytosis and macropinocytosis to internalise bulk material, which in phagotrophic organisms supplies the nutrients necessary for growth. Wildtype Dictyostelium amoebae feed on bacteria, but for decades laboratory work has relied on axenic mutants that can also grow on liquid media. We used forward genetics to identify the causative gene underlying this phenotype. This gene encodes the RasGAP Neurofibromin (NF1). Loss of NF1 enables axenic growth by increasing fluid uptake. Mutants form outsized macropinosomes which are promoted by greater Ras and PI3K activity at sites of endocytosis. Relatedly, NF1 mutants can ingest larger-than-normal particles using phagocytosis. An NF1 reporter is recruited to nascent macropinosomes, suggesting that NF1 limits their size by locally inhibiting Ras signalling. Our results link NF1 with macropinocytosis and phagocytosis for the first time, and we propose that NF1 evolved in early phagotrophs to spatially modulate Ras activity, thereby constraining and shaping their feeding structures.