Genomic organization and functional characterization of the Leishmania major Friedlin ribosomal RNA gene locus.

The sequence and gene organization of the ribosomal RNA (rRNA) genes of Leishmania major Friedlin (LmjF) were determined. Interestingly, the rDNA repeat unit contained a duplicated 526 bp fragment at the 3' end of the unit with two copies of the LSUepsilon rRNA gene. Our results suggested the presence of only approximately 24 copies of the rRNA unit per diploid genome in LmjF. Repetitive elements (IGSRE) of 63 bp occurred in the intergenic spacer (IGS) between the LSUepsilon and the SSU rRNA genes. Among the different rDNA units, the region containing the IGSRE fluctuated in length from approximately 1.3 to approximately 18 kb. The transcription initiation site (TIS) of the rRNA unit was localized by primer extension to 1043 bp upstream of the SSU gene and 184 bp downstream of the IGSRE. Sequence comparison among several species of Leishmania showed a high degree of conservation around the TIS. Moreover, the IGSRE also showed considerable similarity between Leishmania species. In transient transfection assays, a fragment containing the TIS directed a 164- to 178-fold increase in luciferase activity over the no-insert control, indicating the presence of a promoter within this 391 bp fragment. The LmjF promoter region was also functional in other species of Leishmania. Nuclear run-on analyses demonstrated that only the rRNA-coding strand is transcribed, downstream of this RNA polymerase I (pol I) promoter. These experiments also suggested that transcription terminates upstream of the IGSRE.

The Leishmania genome project: new insights into gene organization and function.

The sequencing of Leishmania major Friedlin chromosome 1 (Chr1), Chr3, and Chr4 has been completed. and several other chromosomes are well underway. The complete genome sequence should be available by 2003. Over 1,000 full-length new genes have been identified, with the majority (approximately 75%) having unknown function. Many of these may be Leishmania (or kinetoplastid) specific. Most interestingly, the genes are organized into large (> 100-500 kb) polycistronic clusters of adjacent genes on the same DNA strand. Chr1 contains two such clusters organized in a "divergent" manner, i.e., the mRNAs for the two sets of genes are both transcribed towards the telomeres. Nuclear run-on analysis suggests that transcription is initiated in both directions within the "divergent" region. Chr3 and Chr4 contain two "convergent" clusters, with a single "divergent" gene at one telomere of Chr3. Sequence analysis of several genes from the LD1 region of Chr35 indicates a high degree of sequence conservation between L. major and L. donovani/L. infantum within protein-coding open reading frames (ORFs), with a lower degree of conservation within the non-coding regions. Immunization of mice with recombinant antigen from two of these genes, BTI (formerly ORFG) and ORFF, results in significant reduction in parasite burden following Leishmania challenge. Recombinant ORFF antigen shows promise as a serodiagnostic. We have also developed a tetracycline-regulated promoter system, which allows us to modulate gene expression in Leishmania.

Genomic organization and gene function in Leishmania.

Sequencing of the Leishmania major Friedlin genome is well underway with chromosome 1 (Chr1) and Chr3 having been completely sequenced, and Chr4 virtually complete. Sequencing of several other chromosomes is in progress and the complete genome sequence may be available as soon as 2003. A large proportion ( approximately 70%) of the newly identified genes remains unclassified, with many of these being potentially Leishmania- (or kinetoplastid-) specific. Most interestingly, the genes are organized into large (>100-300 kb) polycistronic clusters of adjacent genes on the same DNA strand. Chr1 contains two such clusters organized in a 'divergent' manner, i. e. the mRNAs for the two sets of genes are both transcribed towards the telomeres. Chr3 contains two 'convergent' clusters, with a single 'divergent' gene at one telomere, with the two large clusters separated by a tRNA gene. We have characterized several genes from the LD1 (Leishmania DNA 1) region of Chr35. BT1 (formerly ORFG) encodes a biopterin transporter and ORFF encodes a nuclear protein of unknown function. Immunization of mice with recombinant antigens from these genes results in significant reduction in parasite burden following Leishmania challenge. Recombinant ORFF antigen shows promise as a serodiagnostic. We have also developed a tetracycline-regulated promoter system, which allows us to modulate gene expression in Leishmania.

The size difference between leishmania major friedlin chromosome one homologues is localized to sub-telomeric repeats at one chromosomal end.

Leishmania species are members of the evolutionarily ancient protozoan order Kinetoplastidae and are important human pathogens. The Leishmania genome is relatively small (approximately 34 Mbp) and is distributed among 36 chromosome pairs, ranging in size from 0.3 to 2.5 Mbp. The smallest chromosome of Leishmania major Friedlin, chrl, consists of three homologues which differ in size by approximately 29 kb. Previous sequence and Southern analyses of all three homologues reveal a conserved chromosomal core, consisting of coding and adjacent 'non-informational' sequence. Here we show the size difference between homologues is largely restricted to variation in both the number and content of several sub-telomeric repetitive elements localized on one chromosomal end. These repetitive elements also occur on other chromosomes, but some are more dispersed in the Leishmania genome than others.

A new family of Pneumocystis carinii genes related to those encoding the major surface glycoprotein.

A new family of Pneumocystis carinii genes (called MSR for MSG-related) that encodes peptides related to the major surface glycoprotein (MSG) is described. Members of the MSR sequence family are linked to MSG genes and are located near the ends of at least 13 chromosomes. Transcripts encoding different MSR isoforms were present in a single population of P. carinii f. sp. carinii, showing that multiple MSR genes were expressed. Two size classes of MSR mRNA, 2.4 and 3.5 kb, were detected. Both sizes of MSR mRNA lacked the upstream conserved sequence (UCS), which is found on the 5' end of MSG mRNAs because MSG genes must be linked to the UCS to be transcribed. The absence of the UCS from MSR mRNAs suggests that expression of MSR genes does not require linkage to the UCS locus.

Expression, structure, and location of epitopes of the major surface glycoprotein of Pneumocystis carinii f. sp. carinii.

The major surface glycoprotein (MSG) of Pneumocystis carinii f. sp. carinii consists of a heterogeneous family of proteins that are encoded by approximately 100 unique genes. A genomic expression library was screened with a panel of MSG-specific monoclonal antibodies (MAbs) to identify conserved and rare epitopes. All of the antibodies reacted with epitopes that are encoded within the 5' end of MSG. The results from the expression screening identified antibodies that recognize highly conserved, moderately conserved, and rare epitopes. Four MAbs (MAbs RA-F1, RA-E7, RA-G10, and RB-E3) reacted with a maltose binding protein-MSG-B fusion protein ([MBP]MSG-B41-1065) by immunoblotting and enzyme-linked immunosorbent assay. Three of the MAbs (MAbs RA-F1, RA-G10, and RA-E7) reacted with the same continuous epitope that was localized to amino acids 278 to 290 of MSG-B. Comparison of the sequence of the RA-F1-, RA-G10-, and RA-E7-reactive epitope to the deduced amino acid sequences of multiple MSGs demonstrated that it is highly conserved. The reactivity of RB-E3 with MSG-B was shown to be dependent on amino acids 184 to 192, which may comprise a portion of a discontinuous epitope.

Identification of a putative precursor to the major surface glycoprotein of Pneumocystis carinii.

The major surface glycoprotein (MSG) of Pneumocystis carinii f. sp. carinii is a family of proteins encoded by a family of heterogeneous genes. Messenger RNAs encoding different MSGs each begin with the same 365-bp sequence, called the Upstream Conserved Sequence (UCS), which is in frame with the contiguous MSG sequence. The UCS contains several potential start sites for translation. To determine if translation of MSG mRNAs begins in the UCS, polyclonal antiserum was raised against the 123-amino-acid peptide encoded by the UCS. The anti-UCS serum reacted with a P. carinii protein that migrated at 170 kDa; however, it did not react with the mature MSG protein, which migrates at 116 kDa. A 170-kDa protein was immunoprecipitated with anti-UCS serum and shown to react with a monoclonal antibody against a conserved MSG epitope. To explore the functional role of the UCS in the trafficking of MSG, the nucleotide sequence encoding the UCS peptide was ligated to the 5' end of an MSG gene and incorporated into a recombinant baculovirus. Insect cells infected with the UCS-MSG hybrid gene expressed a 160-kDa protein which was N-glycosylated. By contrast, insect cells infected with a baculovirus carrying an MSG gene lacking the UCS expressed a nonglycosylated 130-kDa protein. These data suggest that in P. carinii, translation begins in the UCS to produce a pre-MSG protein, which is subsequently directed to the endoplasmic reticulum and processed to the mature form by proteolytic cleavage.

Residence at the expression site is necessary and sufficient for the transcription of surface antigen genes of Pneumocystis carinii.

The major surface glycoprotein (MSG) of P. carinii f. sp. carinii is a family of proteins encoded by a family of heterogeneous genes. Messenger RNAs encoding different MSG isoforms start with the same sequence, called the upstream conserved sequence (UCS), which is encoded by a single locus. The mechanism by which the UCS becomes part of different MSG mRNAs is not obvious because at least 15 loci, which are distributed throughout the genome, encode MSGs. One possibility is that attachment to the UCS locus is required for the transcription of an MSG gene. The alternative to this expression site model is that mRNAs acquire the UCS by RNA splicing. To distinguish between these two models, UCS/MSG junctions in the genome were compared with UCS/MSG junctions in mRNA. The UCS/MSG junctions in the mRNA matched those in the genome, as would be expected if splicing did not contribute to the attachment of the UCS to the 5' ends of MSG mRNAs. Given that few if any MSG mRNAs lack the UCS, the correspondence between the UCS/MSG junctions in transcripts and those in the genome indicates that attachment to the UCS is both necessary and sufficient for transcription of an MSG gene.

Translocation of surface antigen genes to a unique telomeric expression site in Pneumocystis carinii.

The surface of Pneumocystis carinii sp. f. carinii contains an antigen known as major surface glycoprotein (MSG), which is encoded by about 100 heterogeneous genes. Expression of MSG genes is not well understood. Previous work identified a sequence termed UCS, which is present at the beginning of nearly all MSG mRNAs, and which is likely to be involved in regulation of MSG gene transcription. Here we show that the UCS was present in one copy per haploid genome, but that different MSG genes were linked to the unique UCS locus in different members of a P. c. carinii population, predicting that individual organisms transcribe a limited number of MSG genes. This prediction was supported by indirect immunofluorescence observations. Comparison of three different populations of P. c. carinii showed that each contained a different set of MSG genes linked to the UCS, suggesting that UCS-MSG junctions are formed by recombination during population growth. Both the UCS and MSG genes were shown to be located at the ends of chromosomes, suggesting that the mechanism for UCS-MSG recombination is reciprocal exchange.

Antigenic variation by positional control of major surface glycoprotein gene expression in Pneumocystis carinii.

Major cell surface glycoproteins (MSGs) of Pneumocystis carinii play a crucial role in host-parasite interactions during P. carinii pneumocystosis in AIDS patients. Genes encoding MSGs are repeated and dispersed throughout the genome and are highly polymorphic. MSG gene expression was found to be mediated by a DNA element that was termed the upstream conserved sequence (UCS). The UCS element maps to a single chromosome, is attached to expressed MSG genes, and encodes the sequence found at the 5' ends of most MSG mRNAs. The UCS is not highly repeated, but P. carinii populations contain many different MSG genes attached to the UCS, suggesting that different organisms in the population have different MSG genes attached to the UCS. Such genetic heterogeneity may be generated by recombination between MSG genes at the UCS locus and one or more of the dozens of MSG genes located elsewhere in the genome.

Transcription factor genes from rat Pneumocystis carinii.

Genes encoding the TFIID TATA-box binding protein (TBP) from two probable species of rat Pneumocystis carinii (prototype and variant) were sequenced. The two P. carinii TBP gene sequences were 91% identical to each other, and 65-77% identical to TBP genes from other species. A cDNA from one of the two P. carinii TBP genes was sequenced, which showed that four small introns resided in identical positions within the TBP genes from the prototype and variant rat P. carinii. Conservation of the 180 amino acids that constitute the conserved core of TBP was 97% between the P. carinii TBP, which were 95% and 97% identical to conserved core sequences of TBP from Saccharomyces cerevisiae and Schizosaccharomyces pombe respectively.

A tandem repeat of rat-derived Pneumocystis carinii genes encoding the major surface glycoprotein.

A fragment from the genome of rat-derived Pneumocystis carinii was found to contain two MSG genes arranged as a direct repeat. The sequences from one gene (MSG B), the region between the two genes, and part of the second gene (MSG A) were determined. The two MSG genes were not identical in sequence. The open reading frames of MSG A and MSG B encode non-identical proteins, both of which are similar to that encoded by a previously published cDNA. The MSG B gene sequence showed no evidence of introns. The 5' and 3' untranslated regions of the MSG gene pair were highly conserved, but the regions immediately upstream of the open reading frames of MSG A and B were different from the region upstream of a previously characterized MSG cDNA. Primers designed to extend upstream of the 5' end of MSG and downstream of the 3' end of MSG were used in a polymerase chain reaction with total genomic P. carinii DNA as template. Presumptive intergenic amplification products from this reaction were cloned and sequenced. The sequences of these regions were similar but distinct, indicating that tandem arrangement of MSG genes is a common organizational motif.

Genes encoding antigenic surface glycoproteins in Pneumocystis from humans.

Pneumocystis is a eukaryotic microbe that causes pneumocystosis, an AIDS-associated pneumonia. Pneumocystosis also occurs in many other mammalian species, and animal-derived organisms have been extensively utilized in Pneumocystis research. Pneumocystis from diverse hosts contain a large glycoprotein (gpA/MSG) on the surface. Antibodies elicited against gpA/MSG of Pneumocystis from humans sometimes cross-react with epitopes on proteins of similar size from Pneumocystis from other host species. Here we report the isolation and partial sequence of two presumptive gpA/MSG genes from human-derived Pneumocystis. The cloned human-derived Pneumocystis gpA/MSG genes and predicted peptides were different from those previously isolated from Pneumocystis from rats and ferrets. The genome of human-derived Pneumocystis contained multiple copies of sequences related to the two cloned gpA/MSG genes.