Bart W. Swinkels

Topogenesis of Microbody Enzymes - a Sequence Comparison of the Genes for the Glycosomal (microbody) and Cytosolic Phosphoglycerate Kinases of Trypanosoma-brucei

To determine how microbody enzymes enter microbodies, we are studying the genes for cytosolic and glycosomal (microbody) isoenzymes in Trypanosoma brucei. We have found three genes (A, B and C) coding for phosphoglycerate kinase (PGK) in a tandem array in T. brucei. Gene B codes for the cytosolic and gene C for the glycosomal isoenzyme. Genes B and C are 95% homologous, and the predicted protein sequences share approximately 45% amino acid homology with other eukaryote PGKs. The microbody isoenzyme differs from the cytosolic form and other PGKs in two respects: a high positive charge and a carboxy‐terminal extension of 20 amino acids. Our results show that few alterations are required to redirect a protein from cytosol to microbody. From a comparison of our results with the unpublished data for three other glycosomal glycolytic enzymes we infer that the high positive charge represents the major topogenic signal for uptake of proteins into glycosomes.

Characterization of the gene for the microbody (glycosomal) triosephosphate isomerase of Trypanosoma brucei.

To determine how microbody enzymes enter microbodies, we are studying the genes for glycosomal (microbody) enzymes in Trypanosoma brucei. Here we present our results for triosephosphate isomerase (TIM), which is found exclusively in the glycosome. We found a single TIM gene without introns, having one major polyadenylated transcript of 1500 nucleotides with a long untranslated tail of approximately 600 nucleotides. By a novel method, suitable for low abundance transcripts, we demonstrate that TIM mRNA contains the 35‐nucleotide leader sequence (mini‐exon) also found on several other trypanosome mRNAs. The TIM gene and a DNA segment of at least 6 kbp upstream of the gene are transcribed at an equal rate in isolated nuclei, suggesting that the gene is part of a much larger transcription unit. The predicted protein is of the same size as TIMs from other organisms and shares approximately 50% amino acid homology with other eukaryote TIMs, somewhat less with prokaryote TIMs. Trypanosome TIM is the most basic of all TIMs sequenced thus far. This is, in part, due to the presence of two clusters of positively charged residues in the molecule which may act as a signal for entry into glycosomes.

Common elements on the surface of glycolytic enzymes from Trypanosoma brucei may serve as topogenic signals for import into glycosomes.

In Trypanosoma brucei, a major pathogenic protozoan parasite of Central Africa, a number of glycolytic enzymes present in the cytosol of other organisms are uniquely segregated in a microbody‐like organelle, the glycosome, which they are believed to reach post‐translationally after being synthesized by free ribosomes in the cytosol. In a search for possible topogenic signals responsible for import into glycosomes we have compared the amino acid sequences of four glycosomal enzymes: triosephosphate isomerase (TIM), glyceraldehyde‐phosphate dehydrogenase (GAPDH), phosphoglycerate kinase (PGK) and aldolase (ALDO), with each other and with their cytosolic counterparts. Each of these enzymes contains a marked excess of positive charges, distributed in two or more clusters along the polypeptide chain. Modelling of the three‐dimensional structures of TIM, PGK and GAPDH using the known structural coordinates of homologous enzymes from other organisms indicates that all three may have in common two ‘hot spots’ about 40 A apart, which themselves include a pair of basic amino acid residues separated by a distance of about 7 A. The sequence of glycosomal ALDO, for which no three‐dimensional information is available, is compatible with the presence of the same configuration on the surface of this enzyme. We propose that this feature plays an essential role in the import of enzymes into glycosomes.

The topogenic signal of the glycosomal (microbody) phosphoglycerate kinase of Crithidia fasciculata resides in a carboxy-terminal extension.

To determine how microbody proteins enter microbodies, we have previously compared the genes for the cytosolic and glycosomal (microbody) phosphoglycerate kinases (PGKs) of Trypanosoma brucei and found the microbody enzyme to differ from other PGKs and the cytosolic form in two respects: a high net positive charge and a C‐terminal extension of 20 amino acids (Osinga et al., 1985). Here we present the comparison of the genes for the cytosolic and glycosomal PGKs of Crithidia fasciculata, another kinetoplastid organism. The amino acid sequences of the two Crithidia isoenzymes are virtually identical, except for a C‐terminal extension of 38 amino acids. We conclude that this extension must direct the glycosomal PGK to the glycosome. The extensions of the Crithidia and Trypanosoma enzymes are both rich in small hydrophobic and hydroxyl amino acids.

A phosphoglycerate kinase-related gene conserved between Trypanosoma brucei and Crithidia fasciculata

Trypanosoma brucei and Crithidia fasciculata both contain three different phosphoglycerate kinase (PGK) genes, A, B and C, in a tandem array. The genes B and C encode the major PGKs: the cytosolic and glycosomal PGKs, respectively. The PGK-A genes of both Trypanosomatid species encode open reading frames related to PGK, which have most active site residues conserved, but contain an insert of 80 amino acids at approximately position 80 of the 420 amino acids average PGK sequence. The deduced amino acid sequence of these inserts is conserved between T. brucei and C. fasciculata (48% positional identity), indicating its functional importance. Although we have not been able to demonstrate PGK activity in the PGK-A gene product, we consider it likely that this gene codes for a minor PGK with special function.