Nathalie Chevalier

The expression and intracellular distribution of phosphoglycerate kinase isoenzymes in Trypanosoma cruzi

In this paper, we report the subcellular distribution of phosphoglycerate kinase (PGK) in epimastigotes of Trypanosoma cruzi. Approximately 80% of the PGK activity was found in the cytosol, 20% in the glycosomes. Western blot analysis suggested that two isoenzymes of 56 and 48 kDa, respectively, are responsible for the glycosomal PGK activity, whereas the cytosolic activity should be attributed to a single PGK of 48 kDa. In analogy to the situation previously reported for PGK in Trypanosoma brucei, these isoenzymes were called PGKA, C and B, respectively. However, in T. cruzi, PGKA seems not to be a minor enzyme like its counterpart in T. brucei. Whereas PGKC behaved as a soluble glycosomal matrix protein, PGKA appeared to be present at the inner surface of the organelles membrane. After alkaline carbonate treatment, the enzyme remained associated with the particulate fraction of the organelles. Upon solubilization of glycosomes with Triton X-114, PGKA was recovered from the detergent phase, indicating its (partial) hydrophobic character and therefore, a possible hydrophobic interaction with the membrane. The PGKA gene was cloned and sequenced, but the predicted amino-acid sequence did not reveal an obvious clue as to the mechanism by which the enzyme is attached to the glycosomal membrane.

Ubiquitination of the glycosomal matrix protein receptor PEX5 in Trypanosoma brucei by PEX4 displays novel features.

Trypanosomatids contain peroxisome-like organelles called glycosomes. Peroxisomal biogenesis involves a cytosolic receptor, PEX5, which, after its insertion into the organellar membrane, delivers proteins to the matrix. In yeasts and mammalian cells, transient PEX5 monoubiquitination at the membrane serves as the signal for its retrieval from the organelle for re-use. When its recycling is impaired, PEX5 is polyubiquitinated for proteasomal degradation. Stably monoubiquitinated TbPEX5 was detected in cytosolic fractions of Trypanosoma brucei, indicative for its role as physiological intermediate in receptor recycling. This modifications resistance to dithiothreitol suggests ubiquitin conjugation of a lysine residue. T. brucei PEX4, the functional homologue of the ubiquitin-conjugating (UBC) enzyme responsible for PEX5 monoubiquitination in yeast, was identified. It is associated with the cytosolic face of the glycosomal membrane, probably anchored by an identified putative TbPEX22. The involvement of TbPEX4 in TbPEX5 ubiquitination was demonstrated using procyclic ∆PEX4 trypanosomes. Surprisingly, glycosomal matrix protein import was only mildly affected in this mutant. Since other UBC homologues were upregulated, it might be possible that these have partially rescued PEX4s function in PEX5 ubiquitination. In addition, the altered expression of UBCs, notably of candidates involved in cell-cycle control, could be responsible for observed morphological and motility defects of the ∆PEX4 mutant.

Purification and characterisation of the phosphoglycerate kinase isoenzymes of Trypanosoma brucei expressed in Escherichia coli.

The Trypanosoma brucei phosphoglycerate kinase (PGK) glycosomal and cytosolic isoenzymes have been overexpressed in Escherichia coli and purified to near-homogeneity. Both enzymes were similar to the corresponding natural proteins with respect to their physicochemical and kinetic properties. In addition, a mutant of the glycosomal PGK lacking the 20 amino acid long C-terminal extension was overexpressed and purified. Various properties of this truncated glycosomal PGK were examined and it was found that in some aspects the protein behaved quite differently when compared with its natural counterpart. This was notably the case for the apparent Km for 3-phosphoglyceric acid, its sensitivity to inhibitors and its response to salts and guanidine HCl. However, its Vmax was found to be similar to that of the natural glycosomal PGK. These results suggest that the changes in the C-terminus caused a conformational change effecting the 3-phosphoglyceric acid binding site located at the N-terminal domain of the protein.

Insights Into the Enzymatic Mechanism of 6-Phosphogluconolactonase from Trypanosoma brucei Using Structural Data and Molecular Dynamics Simulation

Trypanosoma brucei is the causative agent of African sleeping sickness. Current work for the development of new drugs against this pathology includes evaluation of enzymes of the pentose phosphate pathway (PPP), which first requires a clear understanding of their function and mechanism of action. In this context, we focused on T. brucei 6-phosphogluconolactonase (Tb6PGL), which converts delta-6-phosphogluconolactone into 6-phosphogluconic acid in the second step of the PPP. We have determined the crystal structure of Tb6PGL in complex with two ligands, 6-phosphogluconic acid and citrate, at 2.2 A and 2.0 A resolution, respectively. We have performed molecular dynamics (MD) simulations on Tb6PGL in its empty form and in complex with delta-6-phosphogluconolactone, its natural ligand. Analysis of the structural data and MD simulations allowed us to propose a detailed enzymatic mechanism for 6PGL enzymes.

6-Phosphofructo-2-kinase and fructose-2,6-bisphosphatase in Trypanosomatidae. Molecular characterization, database searches, modelling studies and evolutionary analysis.

Fructose 2,6‐bisphosphate is a potent allosteric activator of trypanosomatid pyruvate kinase and thus represents an important regulator of energy metabolism in these protozoan parasites. A 6‐phosphofructo‐2‐kinase, responsible for the synthesis of this regulator, was highly purified from the bloodstream form of Trypanosoma brucei and kinetically characterized. By searching trypanosomatid genome databases, four genes encoding proteins homologous to the mammalian bifunctional enzyme 6‐phosphofructo‐2‐kinase/fructose‐2,6‐bisphosphatase (PFK‐2/FBPase‐2) were found for both T. brucei and the related parasite Leishmania major and four pairs in Trypanosoma cruzi. These genes were predicted to each encode a protein in which, at most, only a single domain would be active. Two of the T. brucei proteins showed most conservation in the PFK‐2 domain, although one of them was predicted to be inactive due to substitution of residues responsible for ligating the catalytically essential divalent metal cation; the two other proteins were most conserved in the FBPase‐2 domain. The two PFK‐2‐like proteins were expressed in Escherichia coli. Indeed, the first displayed PFK‐2 activity with similar kinetic properties to that of the enzyme purified from T. brucei, whereas no activity was found for the second. Interestingly, several of the predicted trypanosomatid PFK‐2/FBPase‐2 proteins have long N‐terminal extensions. The N‐terminal domains of the two polypeptides with most similarity to mammalian PFK‐2s contain a series of tandem repeat ankyrin motifs. In other proteins such motifs are known to mediate protein–protein interactions. Phylogenetic analysis suggests that the four different PFK‐2/FBPase‐2 isoenzymes found in Trypanosoma and Leishmania evolved from a single ancestral bifunctional enzyme within the trypanosomatid lineage. A possible explanation for the evolution of multiple monofunctional enzymes and for the presence of the ankyrin‐motif repeats in the PFK‐2 isoenzymes is presented.

Studies on the organization of the docking complex involved in matrix protein import into glycosomes of Trypanosoma brucei.

Trypanosoma brucei contains peroxisome-like organelles designated glycosomes because they sequester the major part of the glycolytic pathway. Import of proteins into the peroxisomal matrix involves a protein complex associated with the peroxisomal membrane of which PEX13 is a component. Two very different PEX13 isoforms have recently been identified in T. brucei. A striking feature of one of the isoforms, TbPEX13.1, is the presence of a C-terminal type 1 peroxisomal-targeting signal (PTS1), the tripeptide TKL, conserved in its orthologues in all members of the Trypanosomatidae family so far studied, but absent from TbPEX13.2 and the PEX13s in all other organisms. Despite their differences, both TbPEX13s function as part of a docking complex for cytosolic receptors with bound matrix proteins to be imported. We further characterized TbPEX13.1s function in glycosomal matrix-protein import. It provides a frame to anchor another docking complex component, PEX14, to the glycosomal membrane or information to correctly position it within the membrane. To investigate the possible function of the C-terminal TKL, we determined the topology of the C-terminal half of TbPEX13.1 in the membrane and show that its SH3 domain, located immediately adjacent to the PTS1, is at the cytosolic face.