George C. Hill

CYP51 from Trypanosoma cruzi A PHYLA-SPECIFIC RESIDUE IN THE B′ HELIX DEFINES SUBSTRATE PREFERENCES OF STEROL 14α-DEMETHYLASE

A potential drug target for treatment of Chagas disease, sterol 14α-demethylase from Trypanosoma cruzi (TCCYP51), was found to be catalytically closely related to animal/fungi-like CYP51. Contrary to the ortholog from Trypanosoma brucei (TB), which like plant CYP51 requires C4-monomethylated sterol substrates, TCCYP51 prefers C4-dimethylsterols. Sixty-six CYP51 sequences are known from bacteria to human, their sequence homology ranging from ∼25% between phyla to ∼80% within a phylum. TC versus TB is the first example of two organisms from the same phylum, in which CYP51s (83% amino acid identity) have such profound differences in substrate specificity. Substitution of animal/fungi-like Ile105 in the B′ helix to Phe, the residue found in this position in all plant and the other six CYP51 sequences from Trypanosomatidae, dramatically alters substrate preferences of TCCYP51, converting it into a more plant-like enzyme. The rates of 14α-demethylation of obtusifoliol and its 24-demethyl analog 4α-,4α-dimethylcholesta-8,24-dien-3β-ol(norlanosterol) increase 60- and 150-fold, respectively. Turnover of the three 4,4-dimethylated sterol substrates is reduced ∼3.5-fold. These catalytic properties correlate with the sterol binding parameters, suggesting that Phe in this position provides necessary interactions with C4-monomethylated substrates, which Ile cannot. The CYP51 substrate preferences imply differences in the post-squalene portion of sterol biosynthesis in TC and TB. The phyla-specific residue can be used to predict preferred substrates of new CYP51 sequences and subsequently for the development of new artificial substrate analogs, which might serve as highly specific inhibitors able to kill human parasites.

Biochemical and molecular properties of the Trypanosoma brucei alternative oxidase.

The protozoal parasite Trypanosoma brucei depends on a mitochondrial non-cytochrome terminal oxidase known as the trypanosome alternative oxidase (TAO) in its mammalian host. We have recently cloned the cDNA from T. brucei bloodstream form and have characterized a 33 kDa mitochondrial protein as TAO. Here we report that the TAO is a single copy gene in T. brucei and its expression is down regulated at the level of transcript abundance during differentiation from the bloodstream to the procyclic trypanosomes. Like other alternative oxidases (AOXs) cloned from different plants and fungi, TAO possesses the conserved sequences at the centrally located predicted membrane spanning domains and the signature sequence at the C-terminal hydrophilic domain for a pair of putative iron binding motifs (E-X-X-H). Phylogenetic analysis of the deduced protein sequences of eight different alternative oxidases cloned from different plants and fungi revealed that TAO is more closely related to the alternative oxidases of the fungi clade than that of plants. TAO has been functionally expressed in Escherichia coli. In the first of the two putative iron binding motifs, site-directed mutagenesis of E215 to A, L, N and Q resulted in the loss of the ability of the TAO gene to complement the heme deficiency of the E. coli mutants (SASX41B and GE1387) by conferring on them a CN-insensitive pathway of respiration. The conservative substitution of E215 by aspartate and histidine reduced the growth of the E. coli auxotrophs by approximately 80%. The mutations apparently did not have any effect on the stability of the expressed protein as revealed by the immunoblot analysis of the bacterial protein using TAO monoclonal antibody, which we have developed. Together, these points suggest that E215 plays an important role in the function of TAO. The steady state level of TAO mRNA is down-regulated in the procyclic stage presumably accounting for the low levels of TAO protein in these forms.

Identification and Partial Purification of a Stage‐Specific 33 kDa Mitochondrial Protein as the Alternative Oxidase of the Trypanosoma brucei brucei Bloodstream Trypomastigotes

ABSTRACT. The glycerophosphate oxidase (GPO), the unique terminal oxidase of bloodstream trypanosome (TAO), appears to be functionally similar to the alternative oxidases of some plants and higher fungi. Immunoblotting of mitochondrial proteins of bloodstream trypomastigotes of Trypanosoma brucei brucei with monoclonal or polyclonal antibodies to Sauromatum guttatum (voodoo lily) and Symplocarpus foetidus (skunk cabbage) alternative oxidases respectively revealed two proteins of about 33 kDa (p33) and 68 kDa (p68). These proteins are not present in procyclic trypomastigotes. Electrophoresis under rigorous denaturing conditions indicated p68 to be the dimer of p33. Indirect immunofluorescent studies of bloodstream and procyclic trypomastigotes with monoclonal antibody to plant alternative oxidase also showed the localization of 33 kDa protein in the mitochondria of the bloodstream trypomastigotes. The functional TAO activity could be solubilized efficiently from the mitochondrial membrane of the bloodstream trypomastigotes by 1% NP‐40 or 10 mM lauryl maltoside. When fractionated by Superose 12 gel filtration chromatography, p33 was co‐purified with the TAO enzymatic activity. The apparent molecular size of the active enzyme complex was found to be 160 kDa. Gradual disappearance of the 33 kDa protein and the TAO enzymatic activity were well correlated during in vitro differentiation of the bloodstream to procyclic trypomastigotes. This study implies that the net biosynthesis of p33, an essential subunit of TAO, is decreased during differentiation from bloodstream to procyclic trypomastigotes.

Trypanosome Alternative Oxidase is Regulated Post-transcriptionally at the Level of RNA Stability

Abstract In the bloodstream form of African trypanosomes, trypanosome alternative oxidase (TAO), the non-cytochrome ubiquinol:oxidoreductase, is the only terminal oxidase of the mitochondrial electron transport system. TAO is developmentally regulated during mitochondrial biogenesis in this parasite. During in vitro differentiation of Trypanosoma brucei from the bloodstream to the procyclic form, the overall rate of oxygen consumption decreased about 80%. The mode of respiration changed over a 2- to 3-wk period from a cyanide-insensitive, SHAM-sensitive pathway to a predominantly cyanide-sensitive pathway. The TAO protein level gradually decreased to the level present in the procyclic forms during this 3-wk period. However, within the first week of differentiation, the TAO transcript level decreased about 90% and then in the following weeks it reached the level present in the established procyclic form, that is about 20% of that in bloodstream forms. Like other trypanosomatid genes TAO transcript synthesis remains unaltered in fully differentiated bloodstream and procyclic trypanosomes. The half-life of the TAO mRNA was about 3.2 h in the procyclic trypanosomes, whereas the TAO transcript level remained unaltered even after 4 h of incubation with actinomycin D in bloodstream forms. Inhibition of protein synthesis resulted in about a four-fold accumulation of the TAO transcript in the procyclic trypanosomes, comparable to the level present in the bloodstream forms. Thus, TAO is regulated at the level of mRNA stability and de novo protein synthesis is required for the reduction of the TAO mRNA pool in the procyclic form.

Characterization of a novel developmentally regulated gene from Trypanosoma brucei encoding a potential phosphoprotein

We have isolated a cDNA clone corresponding to a single-copy nuclear gene that is upregulated at the mRNA level during in vitro differentiation of bloodstream trypomastigotes of strains of both Trypanosoma brucei brucei and Trypanosoma brucei rhodesiense to procyclic forms. Transcript levels begin to increase within minutes of introduction of bloodstream forms into culture and peak well before cultures exhibit a procyclic morphology. This increase in transcript levels was found to occur both in the absence of protein synthesis and in a nontransforming strain blocked very early in the developmental program, both conditions under which accumulation of procyclic acidic repetitive protein (PARP) transcripts did not occur in control experiments. DNA sequence analysis reveals an open reading frame sufficient to encode a protein of approximately 50 kDa within the cDNA, but data base searches for homology at either the amino acid or nucleotide level revealed no related sequences. A high density of kinase consensus target sites in the deduced amino acid sequence suggests that the gene product may be a phosphoprotein.

Trypanosoma rhodesiense: Mitochondrial proteins of bloodstream and procyclic trypomastigotes

One- and two-dimensional gel electrophoresis of the solubilized mitochondrial proteins of bloodstream and procyclic trypomastigote Trypanosoma brucei rhodesiense and radiolabeling of proteins in the presence of cycloheximide were used to identify proteins synthesized in the trypanosome mitochondrion. The proteins which comprise the mitochondrion were found to be very similar in both bloodstream and procyclic trypomastigotes, but do differ in their level of synthesis. A protein putatively identified as subunit II of cytochrome oxidase (EC 1.9.3.1) was detected in mitochondria from both the procyclic and bloodstream organisms. The presence of this protein in bloodstream trypomastigotes and the overall similarity of protein content in the trypanosome mitochondria is noteworthy in view of the fact that bloodstream trypomastigotes have a repressed mitochondrion with no detectable tricarboxylic acid cycle or cytochrome electron transport chain.

A comparison of the amino acid sequences of Crithidia fasciculata and Trypanosoma rhodesiense cytochromes c.

Apocytochrome c was isolated from procyclic trypomastigotes of Trypanosoma rhodesiense EATRO 1895 and purified on Amberlite IRC-50 ion-exchange resin. Tryptic peptides were generated from the purified apoprotein and a partial amino acid sequence was determined. A comparison of the amino acid sequence of Crithidia fasciculata with the partial amino acid sequence of T. rhodesiense reveals significant homology.