Functional expression of Trypanosoma congolense pyroglutamyl peptidase type 1 and development of reverse genetics tools.

Mucache, Hermogenes Neves.

06 November 2013

Trypanosoma congolense is a protozoan parasite transmitted by tsetse flies. It causes bovine trypanosomosis, the major disease for livestock in sub-Saharan Africa. Control methods include trypanocidal drugs and vector control, but none is fully satisfactory, due to resistance and environmental issues. A method that would have the greatest impact on controlling the disease is vaccination. However, development of a conventional vaccine has been hampered by the mechanism of antigenic variation, which allows the parasite to evade the host’s immune system. An alternative strategy in vaccine design is to target the bioactive compounds released by dead and dying trypanosomes. This approach is termed ‘‘anti-disease’’, and does not affect the survival of the parasite but targets the pathogenic factors released by the trypanosomes. The development of a successful anti-disease vaccine necessitates knowledge of all pathogenic factors involved in the disease process. Several macromolecules, primarily peptidases, have been implicated in the pathogenesis of trypanosomosis. Pyroglutamyl peptidase type I (PGP) was shown to be involved in abnormal degradation of thyrotropin- and gonadotropin-releasing hormones in rodents infected with T. brucei, but to date no data are available on the T. congolense PGP. Molecular cloning and expression in E. coli of the coding sequence of T. congolense PGP, as well as the enzymatic characterisation of the recombinant protein, are reported here, completed by the development of reverse genetics tools for studies of gene function. A 678 bp PCR fragment covering the complete open reading frame of PGP was cloned and sequenced. The deduced amino acid sequence showed 52% and 29% identity with the T. brucei and Leishmania major enzymes respectively. The catalytic residues Glu, Cys and His described in Bacilus amyloliquefaciens PGP are conserved in the T. congolense sequence. PGP was expressed in bacterial systems as a soluble active, 26 kDa enzyme. The recombinant enzyme showed activity specific for the fluorescent substrate pGlu-AMC, with a kcat/Km of 1.11 s-1μM. PGP showed activity in the pH 6.5-10 range, with maximal activity at pH 9.0. The enzyme was strongly inhibited by sulfhydryl-blocking reagents such as iodoacetic acid and iodoacetamide with a kass of 125 M-1 s-1 and 177 M-1 s-1 respectively. Antibodies raised in chickens against the recombinant enzyme allowed the detection of native PGP in both procyclic and bloodstream T. congolense developmental stages, and displayed complete inhibition of the enzyme in vitro at physiological concentrations. To get insight into the role of PGP in parasite biology and trypanosomosis progression, two types of vectors for reverse genetics studies were developed. For RNA interference, a 400 bp 3′ end segment of the PGP open reading frame was cloned into the plasmid p2T7Ti, that will allow PGP gene down-regulation upon integration into the genome of an engineered tetracycline-inducible strain such as TRUM:29-13. For gene knock-out, several rounds of molecular engineering were carried-out in order to create two plasmid vectors, pGL1184-based (blasticidin resistance) and pGL1217-based (neomycin resistance), each bearing 200 bp-long regions at the 5′ and 3′ ends of the PGP open reading frame. In subsequent studies, taking advantage of the recent advances in culture and transformation of T. congolense, these plasmids will allow the creation of single and double knock-out mutants of PGP. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2012.

Trypanosomiasis in animals--Vaccination.

Livestock--Trypanotolerance.

Trypanosoma.

Theses--Biochemistry.

Studying trypanosomal peptidase antigen targets for the diagnosis of animal African trypanosomiasis.

Eyssen, Lauren Elizabeth-Ann.

09 September 2014

The lack of a vaccine candidate due to antigenic variation by trypanosomal parasites, the causative agents of human and animal African trypanosomiasis, requires the disease to be controlled by surveillance, diagnosis and appropriate treatment schedules. Due to the non-specific symptoms along with the toxicity and side effects of the current trypanocides, diagnosis needs to be accurate, cost effective and applicable to active case finding in mostly rural settings. Trypanosomal proteases have been identified as virulence factors as they are essential to the parasites‟ survival. Here the diagnostic potential of previously described virulence factors, oligopeptidase B (OPB), pyroglutamyl peptidase (PGP) and the full length and catalytic domain of the cathepsin L-like peptidases (CATLFL and CATL respectively) from T. congolense (Tc) as well as OPB and CATL from T. vivax (Tv), was determined. These antigens were recombinantly expressed, purified and used to generate antibodies in chickens. The purified recombinant antigens were tested in an inhibition and indirect ELISA format using two separate blinded serum panels consisting of sera from non-infected and experimentally infected cattle, one each for T. congolense and for T. vivax. The tested sera were diluted 1:10 for the TcCATLFL, TcCATL antigens whilst the TvCATL antigen used a 1:100 serum dilution. The TcCATLFL, TcCATL and TvCATL antigens had the highest diagnostic potential in the indirect ELISA format with a 90.91, 92.21% accuracy at the second cut-off and a 77.22% accuracy at the third cut-off along with 0.8084, 0.7785 and 0.8813 area under curve (AUC) values respectively. These antigens show potential for development of lateral flow tests to detect T. congolense and T. vivax infections in cattle. The recently discovered metacaspases (MCAs) have been implicated in caspase-like activity and differentiation in T. b. brucei, T. cruzi and L. major and are considered to be virulence factors. The putative metacaspase 5 gene from T. congolense (TcMCA5) was successfully cloned, expressed within inclusion bodies, resolubilised and refolded using immobilised metal affinity chromatography. Recombinant TcMCA5 was successfully refolded as evident by the hydrolysis of the synthetic peptide substrate, Z-Gly-Gly-Arg-AMC. Autocatalytic processing was observed within the inclusion bodies and the products were purified along with the full length recombinant protein. Anti-TcMCA5 IgY antibodies, raised in chickens, were able to detect the native TcMCA5 along with the autocatalytic processed products within the lysate of the procyclic T. congolense (strain IL 3000) parasites. The diagnostic potential of TcMCA5 still requires verification. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2013.

Trypanosomiasis in animals--Vaccination.

Livestock--Trypanotolerance.

Trypanosoma.

Theses--Biochemistry.

Molecular analysis of the congopain gene family.

Kalundi, Erastus Mulinge.

January 2008

Animal trypanosomosis is a major constraint in livestock production in Sub-Saharan Africa. With the emergence of resistance against trypanocidal drugs, the cost and environmental concerns raised by vector control, and the challenge of antigenic variation in vaccine development, alternative control measures are being sought. An anti-disease strategy, whereby the immune response or chemotherapy is aimed towards pathogenic factors rather than the parasite itself, constitutes such a novel approach. Congopain is the major cysteine protease in Trypanosoma congolense, and upon release in the bloodstream of infected cattle, acts as a pathogenic factor. It is therefore an attractive candidate for an anti-disease vaccine. It was hence deemed necessary to investigate the variability of congopain-like cysteine proteases before attempting to design drugs and vaccines based on the inhibition of congopain. Most congopain-like cysteine protease genes of T. congolense exist in a single locus of 12-14 copies organised as tandem repeats of 2 kb gene units. A gene unit library of 120 clones was constructed out of several cosmid clones selected in a previous study that contained various lengths of the congopain locus. Some 24 gene unit clones were sequenced, and it was found that congopain genes cluster in three sub-families, named CP1 (8 clones), CP2 (12 clones) and CP3 (4 clones). The latter most characteristically shows a substitution of the active site cysteine by a serine. Isoform specific primers were designed and used to verify the proportions of the three isoforms (one third CP1, half CP2 and a sixth CP3) in the remaining clones of the library. Since this first study was conducted in one isolate, IL 3000, the results were subsequently validated in a large array of isolates, of T. congolense, as well as T. vivax and T. brucei subspecies, by a PCR approach. Finally, to gain access to copies of congopain genes that are not present in the locus, but rather scattered in the genome, an attempt was made to construct a 2 kb size-restricted genomic library. Only 206 clones could be produced, of which a mere 8 coded for congopain-like proteases. The fact that 7 out of 8 of these clones belong to CP3 (thought to be inactive) suggested a cloning artefact, possibly related to the activity of the cloned proteases. Overall, all congopain genes appear very conserved in a given species, with 87-99% identity at protein level. The pre- and pro-region were the most conserved, while the catalytic domain was the most variable, especially around the active site cysteine, with frequent replacement by a serine residue, and in one instance by phenylalanine. The histidine residue of the catalytic triad was also substituted by either a serine or a tyrosine in some instances. The proenzyme cleavage site sequence was also variable, with APEA being the predominant N-terminal sequence. RT-PCR analyses indicated that CP1, CP2 and CP3 mRNA are all present in the bloodstream forms of T. congolense, showing that these variants are likely to be expressed. The conclusion of this study is that, given the high overall conservation of congopain genes in the genome, for the purpose of anti-disease vaccine, it is likely that a single immunogen will suffice to raise antibody able to inhibit all circulating congopain-like cysteine proteases. For chemotherapy however, a more in-depth enzymatic characterisation of the mutants, involving functional recombinant expression, will have to be undertaken. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2008.

Cysteine proteinases.

Trypanosomiasis in animals--Vaccination.

Molecular structure.

Genes.

Theses--Biochemistry.

Recombinant expression and evaluation of a- and b- tubulin from Trypanosoma congolense as vaccine candidates for African trypanosomiasis.

Bartlett, Cara-Lesley.

January 2010

African trypanosomiasis is caused by protozoan parasites known as trypanosomes, which are transmitted by the tsetse fly, affecting both humans and animals. Trypanosoma congolense is one of the main trypanosome species affecting cattle and causes the disease known as nagana. Control of animal African trypanosomiasis currently relies on chemotherapy and vector control methods, neither of which has proven satisfactory. An effective vaccine against trypanosomiasis would be the most cost effective solution to control the disease; however, due to the phenomenon of antigenic variation, intrinsic to the parasite’s outer coat of variable surface glycoprotein, this has not yet been achieved. Recent vaccine efforts have been centred on identification of invariant parasite antigens for use as vaccine candidates. Trypanosome cytoskeleton components have in recent years been shown to be capable of providing a protective immune response against trypanosome infection. These include tubulin proteins, which form the main components of the cytoskeleton, as well as microtubule associated proteins (MAPs) and paraflagellar rod proteins. In the present study α- and β-tubulin from T. congolense were recombinantly expressed and their immuno-protective potential in mice assessed. Amplification of both α- and β-tubulin ORFs from T. congolense genomic DNA was followed by cloning of the amplicons into the T-vector pTZ57R/T, and thereafter sub-cloning into the bacterial expression vector, pET238a and the yeast expression vector pPICZαA28. Only the α-tubulin amplicon was successfully sub-cloned into pICZAαA28; however, no protein expression was achieved upon transfection of the methylotrophic yeast, Pichia pastoris, with this construct. Subcloning of both α- and β-tubulin inserts into pET28a was successful. Expression of recombinant α- and β-tubulin as fusion proteins with a histidine tag, both at a size of 55 kDa, was achieved in Escherichia coli host BL21 (DE3). Recombinant proteins were successfully purified using nickel chelate chromatography under denaturing conditions. Refolding was first attempted by dilution of purified denatured proteins in a refolding buffer followed by reconcentration, but was largely unsuccessful. A second, more successful refolding method was performed wherein denatured proteins were refolded by application of a decreasing gradient of urea, while bound to a nickel chelate column. Native tubulin from cultured T.congolense procyclics was successfully purified and renatured using a polymerisation/depolymerisation method for use as a control for immunisation. Mice were immunised separately with refolded recombinant α- and β-tubulin, native tubulin or an irrelevant protein VP4AA expressed in the same way as the tubulins. ELISA analysis confirmed the production of antibodies against each protein. Parasitaemia developed in all mice following challenge with T. congolense. Only the group immunised with β-tubulin recorded no deaths during the monitoring period despite the presence of parasitaemia, with 60% of mice immunised with α-tubulin or VP4AA and the no antigen control and no mice from the native tubulin immunised group surviving. The results showed that partial protection against trypanosomiasis caused by T. congolense infection was achieved in the group immunised with β-tubulin and suggest that β-tubulin may have vaccine potential. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2010.

Livestock--Trypanotolerance.

Tubulins.

Trypanosoma.

Trypanosomiasis in animals--Vaccination.

Theses--Biochemistry.