In vivo analysis of trypanosome mitochondrial RNA function by artificial site-specific RNA endonuclease-mediated knockdown

Trypanosomes possess a unique mitochondrial genome called the kinetoplast DNA (kDNA). Many kDNA genes encode pre-mRNAs that must undergo guide RNA-directed editing. In addition, alternative mRNA editing gives rise to diverse mRNAs and several kDNA genes encode open reading frames of unknown function. To better understand the mechanism of RNA editing and the function of mitochondrial RNAs in trypanosomes, we have developed a reverse genetic approach using artificial site-specific RNA endonucleases (ASREs) to directly silence kDNA-encoded genes. The RNA-binding domain of an ASRE can be programmed to recognize unique 8-nucleotide sequences, allowing the design of ASREs to cleave any target RNA. Utilizing an ASRE containing a mitochondrial localization signal, we targeted the extensively edited mitochondrial mRNA for the subunit A6 of the F₀F₁ ATP synthase (A6) in the procyclic stage of Trypanosoma brucei. This developmental stage, found in the midgut of the insect vector, relies on mitochondrial oxidative phosphorylation for ATP production with A6 forming the critical proton half channel across the inner mitochondrial membrane. Expression of an A6-targeted ASRE in procyclic trypanosomes resulted in a 50% reduction in A6 mRNA levels after 24 h, a time-dependent decrease in mitochondrial membrane potential (ΔΨm), and growth arrest. Expression of the A6-ASRE, lacking the mitochondrial localization signal, showed no significant growth defect. The development of the A6-ASRE allowed the first in vivo functional analysis of an edited mitochondrial mRNA in T. brucei and provides a critical new tool to study mitochondrial RNA biology in trypanosomes.     

In vivo plasmid DNA electrotransfer

In vivo electrotransfer is a physical technique for gene delivery in various mammalian tissues, which involves the injection of plasmid DNA into a target tissue and administration of an electric field. Its ease of performance, as well as recent understanding of its mechanism and applications to different mammalian tissues such as skeletal muscle, liver, brain and tumors, makes it a powerful technique. It could be used in gene therapy and as a laboratory tool to study gene functions.     

Cross-ligation and exchange reaction of RNA catalyzed by hairpin ribozymes.

The catalytic domain in the minus strand of the satellite RNA of tobacco ringspot virus (sTobRV(-)) assumes a hairpin-like secondary structure. This ribozyme catalyzes a cross-ligation reaction between substrate RNAs of different lengths. We constructed ribozymes to probe the activities of ligation and RNA fragment exchange.     

In vivo plasmid construction by integrative recombination within a 156 bp sequence homology

pHG165, a pBR322 copy number derivative of pUC8, has a 38-bp polylinker multiple cloning site located at the 5′ end of lacα. A further 156 bp, 3′ to the multiple cloning site, completes the coding sequence for the production of the β galactosidase α peptide. We describe the use of in vivo plasmid-chromosone cointegrates as a construction method that in this instance has enabled us to cross out the pHG165 multiple cloning site to obtain a wild-type β-galactosidase sequence for the α peptide. Because the DNA sequence available for homologous recombination was only 156 bp in length, the frequency of crosses that removed the multiple cloning site was less than 1 × 10⁻⁹. These crosses were easily obtained, however, after amplification by ampicillin selection.     

In vivo inhibition of Novikoff cytoplasmic messenger RNA methylation by S-tubercidinylhomocysteine.

The analogue S-tubercidinylhomocysteine (STH) has been used to study the methylation of mRNA in vivo. Partial inhibition of cytoplasmic poly(A)-RNA methylation was observed using a level of inhibitor which still permitted cell growth. Characterization of the partially methylated mRNA indicated the presence of cap structures lacking 2'-O-methylnucleosides, m7GpppN', which are normally not found in mammalian mRNA. Inhibition of additional methylated sites in mRNA at the second 2'-O-methynucleoside, and at internal N6-methyladenosine was also observed Methylation of 7-methylguanosine was not affected under the conditions used in these experiments. The methylnucleoside composition of cap structures differed in STH-inhibited and uninhibited cells. These results indicate that a completely methylated cap is not required for transport of mRNA into the cytoplasm. Furthermore, it may now be possible to assess in vivo the sequential nature of mRNA methylation and its potential role in mRNA processing.     

Cleavage of specific sites of RNA by designed ribozymes

Two ribozymes were designed for site-specific cleavage of RNA. A UA site in an undecaribonucleotide was cleaved by a ribozyme consisting of two partially paired oligoribonucleotides with chain lengths of 19 and 15. The other ribozyme, which consists of a 19-mer and a 13-mer, recognized a UC sequence at positions 42 and 43 of 5 S rRNA.     

Hydrolysis of plasmid DNA and RNA by amino alkyl naphthalimide as metal-free artificial nuclease

A strategy of dimethylamino alkyldiimide conjugated with an intercalator of naphthalimide for hydrolysis of DNA was suggested and evaluated. 4 can hydrolyze 4 kb plasmid DNA into 2 kb fragments with GC and GG selectivity, which represents a novel example of sequence- or site-selective metal-free DNA artificial nuclease. Results also show it could hydrolyze RNA efficiently.     

In vitro activity of minimised hammerhead ribozymes.

A number of minimised hammerhead ribozymes (minizymes) which lack stem II have been kinetically characterised. These minizymes display optimal cleavage activity at temperatures around 37 degrees C. The cleavage reactions of the minizymes are first order in hydroxide ion concentration up to around pH 9.3 above which the cleavage rate constants decline rapidly. The reactions show a biphasic dependence on magnesium-ion concentration; one of the interactions has an apparent dissociation constant of around 20 mM while the other appears to be very weak, showing no sign of saturation at 200 mM MgCl2. The minizymes are significantly less active than comparable, full-size ribozymes when cleaving short substrates. However, at a particular site in a transcribed TAT gene from HIV-1, minizymes are more effective than ribozymes.     

In vivo analysis of the plasmid pAM beta 1 resolution system.

The promiscuous plasmid pAM beta 1 from Gram-positive bacteria encodes a resolution system which differs from that of Tn3 in that (i) it requires a histone-like protein and an unusual resolvase-DNA interaction to promote recombination and (ii) it mediates in vivo DNA inversion in plasmid substrates. In this in vivo analysis, the pAM beta 1 resolution site is narrowed down to a 99 bp segment, the strand exchange is mapped within 10 bp and the serine residue at position 10 of the resolvase is shown to be essential for enzyme activity. In addition, data showing that the resolution system does not promote DNA inversion in the Bacillus subtilis chromosome are presented. Implications of this observation are discussed.     

In vivo electroporation and stable transformation of skin cells of newborn mice by plasmid DNA.

The skin cells of newborn mice were stably transformed in vivo with the aid of electroporation. The plasmid DNA was introduced subcutaneously followed by high-voltage pulses applied to the skin pleat. NEO-resistant colonies were found in primary cell cultures obtained from the treated skin. The experiments show that in vivo electroporation can be used for the introduction of plasmid DNA into skin cells of mouse.