The short interspersed repetitive element of Trypanosoma cruzi, SIRE, is part of VIPER, an unusual retroelement related to long terminal repeat retrotransposons.

The short interspersed repetitive element (SIRE) of Trypanosoma cruzi was first detected when comparing the sequences of loci that encode the TcP2beta genes. It is present in about 1,500-3,000 copies per genome, depending on the strain, and it is distributed in all chromosomes. An initial analysis of SIRE sequences from 21 genomic fragments allowed us to derive a consensus nucleotide sequence and structure for the element, consisting of three regions (I, II, and III) each harboring distinctive features. Analysis of 158 transcribed SIREs demonstrates that the consensus is highly conserved. The sequences of 51 cDNAs show that SIRE is included in the 3' end of several mRNAs, always transcribed from the sense strand, contributing the polyadenylation site in 63% of the cases. This study led to the characterization of VIPER (vestigial interposed retroelement), a 2,326-bp-long unusual retroelement. VIPER's 5' end is formed by the first 182 bp of SIRE, whereas its 3' end is formed by the last 220 bp of the element. Both SIRE moieties are connected by a 1,924-bp-long fragment that carries a unique ORF encoding a complete reverse transcriptase-RNase H gene whose 15 C-terminal amino acids derive from codons specified by SIRE's region II. The amino acid sequence of VIPER's reverse transcriptase-RNase H shares significant homology to that of long terminal repeat retrotransposons. The fact that SIRE and VIPER sequences are found only in the T. cruzi genome may be of relevance for studies concerning the evolution and the genome flexibility of this protozoan parasite.

Analysis of the distribution of SIRE in the nuclear genome of Trypanosoma cruzi.

The short interspersed repetitive element (SIRE) of the nuclear genome of Trypanosoma cruzi was first detected when comparing the sequences of loci that encode the TcP2beta genes. The present study was designed to assess its distribution and organization in the nuclear genome of the parasite. Southern blots of genomic DNA from different strains demonstrated that each one possesses a defined and characteristic pattern of SIRE distribution. The conservation of the SIRE sequence in T. cruzi strains allowed the development of a rapid inter-SIRE PCR reaction that yields strain-specific amplicon profiles. In the T. cruzi CL Brener clone, we found 1500 copies of the element distributed in all chromosomes. 16 genomic fragments containing SIRE (SZs) were isolated and characterized. In fragments SZ10, SZ12 and SZ31, SIRE was linked to TcRel, a novel repeated sequence that constitutes the 3' end of vp85 genes. SIRE was also linked to an unknown open reading frame in fragments SZ14 and SZ23 which might be related to the subtelomeric regions of T. cruzi chromosomes. Further sequencing of SZ fragments revealed that SIRE was also linked to protein coding genes that have not yet been described in kinetoplastids such as the one coding for PRP22 helicase and a thimet oligopeptidase. To allow the rapid-generation genetic markers associated with SIRE, we developed a SIRE-bubble PCR reaction that provided several such markers for the construction of the physical map of chromosome XVI. The results herein demonstrate that SIRE-associated sites (SAS) may be of great help in physical mapping and interpretation of T. cruzi genomic sequence data.

Characterization of a novel trypanosomatid small nucleolar RNA.

Trypanosomes possess unique RNA processing mechanisms including trans- splicing of pre-mRNA and RNA editing of mitochondrial transcripts. The previous finding of a trimethylguanosine (TMG) capped U3 homologue in trypanosomes suggests that rRNA processing may be related to the processing in other eukaryotes. In this study, we describe the first trypanosomatid snoRNA that belongs to the snoRNAs that were shown to guide ribose methylation of rRNA. The RNA, identified in the monogenetic trypanosomatid Leptomonas collosoma, was termed snoRNA-2 and is encoded by a multi-copy gene. SnoRNA-2 is 85 nt long, it lacks a 5' cap and possesses the C and D boxes characteristic to all snoRNAs that bind fibrillarin. Computer analysis indicates a potential for base-pairing between snoRNA-2 and 5.8S rRNA, and 18S rRNA. The putative interaction domains obey the rules suggested for the interaction of guide snoRNA with its rRNA target for directing ribose methylation on the rRNA. However, mapping the methylated sites on the 5.8S rRNA and 18S rRNA indicates that the expected site on the 5.8S is methylated, whereas the site on the 18S is not. The proposed interaction with 5.8S rRNA is further supported by the presence of psoralen cross-link sites on snoRNA-2. GenBank search suggests that snoRNA-2 is not related to any published snoRNAs. Because of the early divergence of the Trypanosomatidae from the eukaryotic lineage, the presence of a methylating snoRNA that is encoded by a multi-copy gene suggests that methylating snoRNAs may have evolved in evolution from self-transcribed genes.

Towards the physical map of the Trypanosoma cruzi nuclear genome: construction of YAC and BAC libraries of the reference clone T. cruzi CL-Brener

Strategies to construct the physical map of the Trypanosoma cruzi nuclear genome have to capitalize on three main advantage of the parasite genome, namely (a) its small size, (b) the fact that all chromosomes can be defined, and many of them can be isolated by pulse field gel electrophoresis, and (c) the fact that simple Southern blots of electrophoretic karyotypes can be used to map sequence tagged sites and expressed sequence tags to chromosomal bands. A major drawback to cope with is the complexity of T. cruzi genetics, that hinders the construction of a comprehensive genetic map. As a first step towards physical mapping, we report the construction and partial characterization of a T. cruzi CL-Brener genomic library in yeast artificial chromosomes (YACs) that consists of 2.770 individual YACs with a mean insert size of 365 kb encompassing around 10 genomic equivalents. Two libraries in bacterial artificial chromosomes (BACs) have been constructed, BACI and BACII. Both libraries represent about three genome equivalents. A third BAC library (BAC III) is being constructed. YACs and BACs are invaluable tools for physical mapping. More generally, they have to be considered as a common resource for research in Chagas disease.

Towards the physical map of the Trypanosoma cruzi nuclear genome: construction of YAC and BAC libraries of the reference clone T. cruzi CL-Brener.

Strategies to construct the physical map of the Trypanosoma cruzi nuclear genome have to capitalize on three main advantages of the parasite genome, namely (a) its small size, (b) the fact that all chromosomes can be defined, and many of them can be isolated by pulse field gel electrophoresis, and (c) the fact that simple Southern blots of electrophoretic karyotypes can be used to map sequence tagged sites and expressed sequence tags to chromosomal bands. A major drawback to cope with is the complexity of T. cruzi genetics, that hinders the construction of a comprehensive genetic map. As a first step towards physical mapping, we report the construction and partial characterization of a T. cruzi CL-Brener genomic library in yeast artificial chromosomes (YACs) that consists of 2,770 individual YACs with a mean insert size of 365 kb encompassing around 10 genomic equivalents. Two libraries in bacterial artificial chromosomes (BACs) have been constructed, BACI and BACII. Both libraries represent about three genome equivalents. A third BAC library (BAC III) is being constructed. YACs and BACs are invaluable tools for physical mapping. More generally, they have to be considered as a common resource for research in Chagas disease.