N-acetyl D-glucosamine stimulates growth in procyclic forms of Trypanosoma brucei by inducing a metabolic shift.

SUMMARYThe lectin-inhibitory sugars D-glucosamine (GlcN) and N-acetyl D-glucosamine (GlcNAc) are known to enhance susceptibility of the tsetse fly vector to infection with Trypanosoma brucei. GlcNAc also stimulates trypanosome growth in vitro in the absence of any factor derived from the fly. Here, we show that GlcNAc cannot be used as a direct energy source, nor is it internalized by trypanosomes. It does, however, inhibit glucose uptake by binding to the hexose transporter. Deprivation of D-glucose leads to a switch from a metabolism based predominantly on substrate level phosphorylation of D-glucose to a more efficient one based mainly on oxidative phosphorylation using L-proline. Procyclic form trypanosomes grow faster and to higher density in D-glucose-depleted medium than in D-glucose-rich medium. The ability of trypanosomes to use L-proline as an energy source can be regulated depending upon the availability of D-glucose and here we show that this regulation is a graded response to D-glucose availability and determined by the overall metabolic state of the cell. It appears, therefore, that the growth stimulatory effect of GlcNAc in vitro relates to the switch from D-glucose to L-proline metabolism. In tsetse flies, however, it seems probable that the effect of GlcNAc is independent of this switch as pre-adaptation to growth in proline had no effect on tsetse infection rate.

Mutational analysis of the [Het-s] prion analog of Podospora anserina. A short N-terminal peptide allows prion propagation.

The het-s locus is one of nine known het (heterokaryon incompatibility) loci of the fungus Podospora anserina. This locus exists as two wild-type alleles, het-s and het-S, which encode 289 amino acid proteins differing at 13 amino acid positions. The het-s and het-S alleles are incompatible as their coexpression in the same cytoplasm causes a characteristic cell death reaction. We have proposed that the HET-s protein is a prion analog. Strains of the het-s genotype exist in two phenotypic states, the neutral [Het-s*] and the active [Het-s] phenotype. The [Het-s] phenotype is infectious and is transmitted to [Het-s*] strains through cytoplasmic contact. het-s and het-S were associated in a single haploid nucleus to generate a self-incompatible strain that displays a restricted and abnormal growth. In the present article we report the molecular characterization of a collection of mutants that restore the ability of this self-incompatible strain to grow. We also describe the functional analysis of a series of deletion constructs and site-directed mutants. Together, these analyses define positions critical for reactivity and allele specificity. We show that a 112-amino-acid-long N-terminal peptide of HET-s retains [Het-s] activity. Moreover, expression of a mutant het-s allele truncated at position 26 is sufficient to allow propagation of the [Het-s] prion analog.

The protein product of the het-s heterokaryon incompatibility gene of the fungus Podospora anserina behaves as a prion analog.

The het-s locus of Podospora anserina is a heterokaryon incompatibility locus. The coexpression of the antagonistic het-s and het-S alleles triggers a lethal reaction that prevents the formation of viable heterokaryons. Strains that contain the het-s allele can display two different phenotypes, [Het-s] or [Het-s*], according to their reactivity in incompatibility. The detection in these phenotypically distinct strains of a protein expressed from the het-s gene indicates that the difference in reactivity depends on a posttranslational difference between two forms of the polypeptide encoded by the het-s gene. This posttranslational modification does not affect the electrophoretic mobility of the protein in SDS/PAGE. Several results suggest a similarity of behavior between the protein encoded by the het-s gene and prions. The [Het-s] character can propagate in [Het-s*] strains as an infectious agent, producing a [Het-s*] --> [Het-s] transition, independently of protein synthesis. Expression of the [Het-s] character requires a functional het-s gene. The protein present in [Het-s] strains is more resistant to proteinase K than that present in [Het-s*] mycelium. Furthermore, overexpression of the het-s gene increases the frequency of the transition from [Het-s*] to [Het-s]. We propose that this transition is the consequence of a self-propagating conformational modification of the protein mediated by the formation of complexes between the two different forms of the polypeptide.