Functional analysis of the domain organization of Trypanosoma brucei RNase HI

Effects of RNA interference of Trypanosoma brucei structure-specific endonuclease-I on kinetoplast DNA replication

Kinetoplast DNA, the mitochondrial DNA of trypanosomatid protozoa, is a network containing several thousand topologically interlocked DNA minicircles. Kinetoplast DNA synthesis involves release of minicircles from the network, replication of the free minicircles, and reattachment of the progeny back onto the network. One enzyme involved in this process is structure-specific endonuclease-I. This enzyme, originally purified from Crithidia fasciculata, has been proposed to remove minicircle replication primers (Engel, M. L., and Ray, D. S. (1998) Nucleic Acids Res. 26, 4773-4778). We have studied the structure-specific endonuclease-I homolog from Trypanosoma brucei, showing it to be localized in the antipodal sites flanking the kinetoplast DNA disk, as previously shown in C. fasciculata. RNA interference of structure-specific endonuclease-I caused persistence of a single ribonucleotide at the 5' end of both the leading strand and at least the first Okazaki fragment in network minicircles, demonstrating that this enzyme in fact functions in primer removal. Probably because of the persistence of primers, RNA interference also impeded the reattachment of newly replicated free minicircles to the network and caused a delay in kinetoplast DNA segregation. These effects ultimately led to shrinkage and loss of the kinetoplast DNA network and cessation of growth of the cell.

The non-LTR (long terminal repeat) retrotransposon L1Tc from Trypanosoma cruzi codes for a protein with RNase H activity

The deduced amino acid sequence of the region downstream of the reverse transcriptase (RT) motif of the Trypanosoma cruzi L1Tc non-LTR retrotransposon shows a significant homology with the sequence coding for proteins with RNase H activity from different organisms and retroelements. The 25-kDa His(6)-tagged recombinant protein bearing only the L1Tc RNase H domain, named RHL1Tc, exhibits RNase H activity as measured on the [(3)H]poly(rA)/poly(dT) hybrid used as substrate as well as on specific homologous and heterologous [(32)P]RNA/DNA hybrids. The mutation of the conserved aspartic acid at position 39 of the enzyme catalytic site, but not of the serine at position 56 (non-conservative amino acid), abolishes protein RNase H activity. The RNase H activity of the RHL1Tc protein is Mg(2+)-dependent, and it is also active in the presence of the Mn(2+) ion. The optimal condition of RNase H activity is found at pH 8 and 37 degrees C, although it also has significant enzymatic activity at 19 degrees C and pH 6. However, it cannot be excluded that the RNase H activity level and its optimal conditions may be different from that of a protein containing both RT and RNase H domains.

Expression of Moloney murine leukemia virus RNase H rescues the growth defect of an Escherichia coli mutant

A 157-amino-acid fragment of Moloney murine leukemia virus reverse transcriptase encoding RNase H is shown to rescue the growth-defective phenotype of an Escherichia coli mutant. In vitro assays of the recombinant wild-type protein purified from the conditionally defective mutant confirm that it is catalytically active. Mutagenesis of one of the presumptive RNase H-catalytic residues results in production of a protein variant incapable of rescue and which lacks activity in vitro. Analyses of additional active site mutants demonstrate that their encoded variant proteins lack robust activity yet are able to rescue the bacterial mutant. These results suggest that genetic complementation may be useful for in vivo screening of mutant viral RNase H gene fragments and in evaluating their function under conditions that more closely mimic physiological conditions. The rescue system may also be useful in verifying the functional outcomes of mutations based on protein structural predictions and modeling.