Primary structure of a cytosolic malate dehydrogenase of the amitochondriate eukaryote, Trichomonas vaginalis

Convergent evolution of Trichomonas vaginalis lactate dehydrogenase from malate dehydrogenase

Lactate dehydrogenase (LDH) is present in the amitochondriate parasitic protist Trichomonas vaginalis and some but not all other trichomonad species. The derived amino acid sequence of T. vaginalis LDH (TvLDH) was found to be more closely related to the cytosolic malate dehydrogenase (MDH) of the same species than to any other LDH. A key difference between the two T. vaginalis sequences was that Arg91 of MDH, known to be important in coordinating the C-4 carboxyl of oxalacetate/malate, was replaced by Leu91 in LDH. The change Leu91Arg by site-directed mutagenesis converted TvLDH into an MDH. The reverse single amino acid change Arg91Leu in TvMDH, however, gave a product with no measurable LDH activity. Phylogenetic reconstructions indicate that TvLDH arose from an MDH relatively recently.

Analysis of a ubiquitous promoter element in a primitive eukaryote: early evolution of the initiator element

Typical metazoan core promoter elements, such as TATA boxes and Inr motifs, have yet to be identified in early-evolving eukaryotes, underscoring the extensive divergence of these organisms. Towards the identification of core promoters in protists, we have studied transcription of protein-encoding genes in one of the earliest-diverging lineages of Eukaryota, that represented by the parasitic protist Trichomonas vaginalis. A highly conserved element, comprised of a motif similar to a metazoan initiator (Inr) element, surrounds the start site of transcription in all examined T. vaginalis genes. In contrast, a metazoan-like TATA element appears to be absent in trichomonad promoters. We demonstrate that the conserved motif found in T. vaginalis protein-encoding genes is an Inr promoter element. This trichomonad Inr is essential for transcription, responsible for accurate start site selection, and interchangeable between genes, demonstrating its role as a core promoter element. The sequence requirements of the trichomonad Inr are similar to metazoan Inrs and can be replaced by a mammalian Inr. These studies show that the Inr is a ubiquitous, core promoter element for protein-encoding genes in an early-evolving eukaryote. Functional and structural similarities between this protist Inr and the metazoan Inr strongly indicate that the Inr promoter element evolved early in eukaryotic evolution.

Gene Transcription in Trichomonas vaginalis

Since the cloning of the first gene from the flagellated, parasitic protist Trichomonas vaginalis in 1990, at least a partial sequence has been obtained from over 100 genes. Molecular and biochemical analyses using these genes have enhanced our understanding of metabolism, organelle biogenesis, drug susceptibility, phylogeny and basic properties of transcription in trichomonads. Here, David Liston and Patricia Johnson discuss the available data on the regulation of transcription of protein-coding genes in T. vaginalis.

Molecular characterization of a sarcoplasmic-endoplasmic reticulum Ca+2 ATPase gene from Trichomonas vaginalis

DNA fragments homologous to P-type cation translocating ATPase genes were identified in Trichomonas vaginalis by polymerase chain reaction (PCR) amplification. The genomic locus corresponding to one PCR fragment, TVCA1, contains a 3,055 base-pair open reading frame encoding a 108,162 dalton protein composed of 981 amino acids. TVCA1 lacks introns, is present in a single copy, and is expressed as a 3.1 kb transcript with short 5' and 3' untranslated regions. Separate primer extension experiments map the 5' end of the TVCA1 transcript to 12 and 16 nucleotide bases (nt) upstream of the methionine initiation codon. The message polyadenylation site is located 62 nt downstream of the protein termination codon at a CA dinucleotide. The TVCA1 protein sequence shares 57-58% similarity with rabbit, schistosome, trypanosome and malarial sarcoplasmic-endoplasmic reticulum calcium (SERCA) pumps, and significantly lower similarity with plasma membrane calcium pumps and cation translocating ATPases of other ion specificities. Structural and functional domains identified in P-type ATPases as well as 61/68 residues specifically implicated in SERCA pump activity are conserved in TVCA1. However, TVCA1 lacks binding sites for phospholamban regulation, thapsigargin inhibition and the calmodulin dependent protein kinase site phosphorylation present in other SERCA pumps.