Base J originally found in kinetoplastida is also a minor constituent of nuclear DNA of Euglena gracilis

We have analyzed DNA of EUGLENA: gracilis for the presence of the unusual minor base beta-D-glucosyl-hydroxymethyluracil or J, thus far only found in kinetoplastid flagellates and in DIPLONEMA: Using antibodies specific for J and post-labeling of DNA digests followed by two-dimensional thin-layer chromatography of labeled nucleotides, we show that approximately 0.2 mole percent of EUGLENA: DNA consists of J, an amount similar to that found in DNA of Trypanosoma brucei. By staining permeabilized EUGLENA: cells with anti-J antibodies, we show that J is rather uniformly distributed in the EUGLENA: nucleus, and does not co-localize to a substantial extent with (GGGTTA)(n) repeats, the putative telomeric repeats of EUGLENA: Hence, most of J in EUGLENA: appears to be non-telomeric. Our results add to the existing evidence for a close phylogenetic relation between kinetoplastids and euglenids.

Tandemly repeated DNA is a target for the partial replacement of thymine by beta-D-glucosyl-hydroxymethyluracil in Trypanosoma brucei

In the DNA of African trypanosomes a small fraction of thymine is replaced by the modified base beta-D-glucosyl-hydroxymethyluracil (J). The function of this large base is unknown. The presence of J in the silent variant surface glycoprotein gene expression sites and the lack of J in the transcribed expression site indicates that DNA modification might play a role in control of gene repression. However, the abundance of J in the long telomeric repeat tracts and in subtelomeric arrays of simple repeats suggests that J may also have specific functions in repetitive DNA. We have now analyzed chromosome-internal repetitive sequences in the genome of Trypanosoma brucei and found J in the minichromosomal 177-bp repeats, in the long arrays of 5S RNA gene repeats, and in the spliced-leader RNA gene repeats. No J was found in the rDNA locus or in dispersed repetitive transposon-like elements. Remarkably, the rDNA of T. brucei is not organized in long arrays of tandem repeats, as in many other eukaryotes. T. brucei contains only approximately 15-20 rDNA repeat units that are divided over six to seven chromosomes. Our results show that J is present in many tandemly repeated sequences, either at a telomere or chromosome internal. The presence of J might help to stabilize the long arrays of repeats in the genome.

The modified base J is the target for a novel DNA-binding protein in kinetoplastid protozoans

DNA from Kinetoplastida contains the unusual modified base beta-D-glucosyl(hydroxymethyl)uracil, called J. Base J is found predominantly in repetitive DNA and correlates with epigenetic silencing of telomeric variant surface glycoprotein genes in Trypanosoma brucei. We have now identified a protein in nuclear extracts of bloodstream stage T.brucei that binds specifically to J-containing duplex DNA. J-specific DNA binding was also observed with extracts from the kinetoplastids Crithidia fasciculata and Leishmania tarentolae. We purified the 90 kDa C.fasciculata J-binding protein 50 000-fold and cloned the corresponding gene from C.fasciculata, T.brucei and L.tarentolae. Recombinant proteins expressed in Escherichia coli demonstrated J-specific DNA binding. The J-binding proteins show 43-63% identity and are unlike any known protein. The discovery of a J-binding protein suggests that J, like methylated cytosine in higher eukaryotes, functions via a protein intermediate.

Biosynthesis and function of the modified DNA base beta-D-glucosyl-hydroxymethyluracil in Trypanosoma brucei

beta-D-Glucosyl-hydroxymethyluracil, also called J, is a modified DNA base conserved among kinetoplastid flagellates. In Trypanosoma brucei, the majority of J is present in repetitive DNA but the partial replacement of thymine by J also correlates with transcriptional repression of the variant surface glycoprotein (VSG) genes in the telomeric VSG gene expression sites. To gain a better understanding of the function of J, we studied its biosynthesis in T. brucei and found that it is made in two steps. In the first step, thymine in DNA is converted into hydroxymethyluracil by an enzyme that recognizes specific DNA sequences and/or structures. In the second step, hydroxymethyluracil is glucosylated by an enzyme that shows no obvious sequence specificity. We identified analogs of thymidine that affect the J content of the T. brucei genome upon incorporation into DNA. These analogs were used to study the function of J in the control of VSG gene expression sites. We found that incorporation of bromodeoxyuridine resulted in a 12-fold decrease in J content and caused a partial derepression of silent VSG gene expression site promoters, suggesting that J might strengthen transcriptional repression. Incorporation of hydroxymethyldeoxyuridine, resulting in a 15-fold increase in the J content, caused a reduction in the occurrence of chromosome breakage events sometimes associated with transcriptional switching between VSG gene expression sites in vitro. We speculate that these effects are mediated by the packaging of J-containing DNA into a condensed chromatin structure.

beta-D-glucosyl-hydroxymethyluracil is a conserved DNA modification in kinetoplastid protozoans and is abundant in their telomeres

The unusual DNA base beta-D-glucosyl-hydroxymethyluracil, called "J, " replaces approximately 0.5-1% of Thy in DNA of African trypanosomes but has not been found in other organisms thus far. In Trypanosoma brucei, J is located predominantly in repetitive DNA, and its presence correlates with the silencing of telomeric genes. Using antibodies specific for J, we have developed sensitive assays to screen for J in a range of organisms and have found that J is not limited to trypanosomes that undergo antigenic variation but is conserved among Kinetoplastida. In all kinetoplastids tested, including the human pathogens Leishmania donovani and Trypanosoma cruzi, J was found to be abundantly present in the (GGGTTA)n telomere repeats. Outside Kinetoplastida, J was found only in Diplonema, a small phagotrophic marine flagellate, in which we also identified 5-MeCyt. Fractionation of Diplonema DNA showed that the two modifications are present in a common genome compartment, which suggests that they may have a similar function. Dinoflagellates appear to contain small amounts of modified bases that may be analogs of J. The evolutionary conservation of J in kinetoplastid protozoans suggests that it has a general function, repression of transcription or recombination, or a combination of both. T. brucei may have recruited J for the control of genes involved in antigenic variation.

The role of transferrin-receptor variation in the host range of Trypanosoma brucei

Trypanosoma brucei is a unicellular parasite transmitted between African mammals by tsetse flies. T. brucei multiplies freely in the bloodstream of many different mammals, and survives by antigenic variation of the main component of its surface coat, variant surface glycoprotein (VSG). Trypanosomes take up transferrin through a heterodimeric transferrin receptor, the genes for which are expressed in telomeric expression sites along with the VSG gene. There are up to 20 of these expression sites per trypanosome nucleus, but usually only one is active at a time. Different expression sites encode transferrin receptors that are similar but not identical. Here we show that these small differences between transferrin receptors can have profound effects on the binding affinity for transferrins from different mammals, and on the ability of trypanosomes to grow in the sera of these mammals. Our results suggest that the ability to switch between different transferrin-receptor genes allows T. brucei to cope with the large sequence diversity in the transferrins of its hosts.

Localization of the modified base J in telomeric VSG gene expression sites of Trypanosoma brucei

African trypanosomes such as Trypanosoma brucei undergo antigenic variation in the bloodstream of their mammalian hosts by regularly changing the variant surface glycoprotein (VSG) gene expressed. The transcribed VSG gene is invariably located in a telomeric expression site. There are multiple expression sites and one way to change the VSG gene expressed is by activating a new site and inactivating the previously active one. The mechanisms that control expression site switching are unknown, but have been suggested to involve epigenetic regulation. We have found previously that VSG genes in silent (but not active) expression sites contain modified restriction endonuclease cleavage sites, and we have presented circumstantial evidence indicating that this is attributable to the presence of a novel modified base beta-D-glucosyl-hydroxymethyluracil, or J. To directly test this, we have generated antisera that specifically recognize J-containing DNA and have used these to determine the precise location of this modified thymine in the telomeric VSG expression sites. By anti J-DNA immunoprecipitations, we found that J is present in telomeric VSG genes in silenced expression sites and not in actively transcribed telomeric VSG genes. J was absent from inactive chromosome-internal VSG genes. DNA modification was also found at the boundaries of expression sites. In the long 50-bp repeat arrays upstream of the promoter and in the telomeric repeat arrays downstream of the VSG gene, J was found both in silent and active expression sites. This suggests that silencing results in a gradient of modification spreading from repetitive DNA flanks into the neighboring expression site sequences. In this paper, we discuss the possible role of J in silencing of expression sites.

A ribosomal DNA promoter replacing the promoter of a telomeric VSG gene expression site can be efficiently switched on and off in T. brucei

Trypanosoma brucei survives in the mammalian blood-stream by regularly changing its variant surface glycoprotein (VSG) coat. The active VSG gene is located in a telomeric expression site, and coat switching occurs either by replacing the transcribed VSG gene or by changing the expression site that is active. To determine whether VSG expression site control requires promoter-specific sequences, we replaced the active VSG expression site promoter in bloodstream-form T. brucei with a ribosomal DNA (rDNA) promoter. These transformants were fully infective in laboratory animals, and the rDNA promoter, which is normally constitutively active, was efficiently inactivated and reactivated in the context of the VSG gene expression site. As there is no sequence similarity between the VSG expression site promoter and the rDNA promoter, VSG expression site control does not involve sequences specific to the VSG expression site promoter. We conclude that an epigenetic mechanism, such as telomeric silencing, is involved in VSG expression site control in bloodstream-form T. brucei.

Genomic organization of an invariant surface glycoprotein gene family of Trypanosoma brucei

The genomic organization of a gene family for the invariant surface glycoprotein, ISG75 (invariant surface glycoprotein with a molecular mass of 75 kDa), from Trypanosoma brucei is described. In T. brucei strain 427 ISG75 genes are present in tandem arrays at two loci, A and B, containing 5 and 2 copies, respectively. At the 3'-end of locus A, a single gene was identified that encodes a structural isoform of ISG75. This isoform contains a unique amino-terminal domain, whereas the rest of the protein is nearly identical to the polypeptides encoded by the other genes. This isoform is transcribed into a stable mRNA, but the expression of the derived polypeptide was below the detection limit. The ISG75 gene clusters are present on chromosomal bands 9' and 10, supporting the hypothesis of Gottesdiener et al. [25] that these bands contain allelic chromosomes. The total number of ISG75 genes is strain dependent, but at least one copy of the unique isoform is present in every variant tested.

VSG gene expression site control in insect form Trypanosoma brucei

When the African trypanosome Trypanosoma brucei is taken up from mammals by a tse-tse fly, it replaces its variant surface glycoprotein (VSG) coat by a procyclin coat. Transcription of VSG genes stops in the fly, but transcription of sequences derived from the promoter area of the VSG expression site(s) remains high. Whether this is due to continuing high activity of one promoter or to low activity of many promoters was unclear. We have used the small differences between the sequences of different expression sites to show that multiple expression site promoters are active in insect form trypanosomes. This is confirmed by the low expression of single copy marker genes introduced into the transcribed area. However, if the expression site promoter is removed from the genomic location of the expression site and inserted in the non-transcribed spacer of the ribosomal DNA (rDNA), it is derepressed. Derepression of transcription can also be accomplished by replacing the promoter of an expression site by an rDNA promoter. We conclude that the down-regulation of VSG gene expression site promoters in insect form trypanosomes is affected by both the DNA sequence of the promoter and the genomic context in which it resides.

Reconstitution of a surface transferrin binding complex in insect form Trypanosoma brucei

In the bloodstream of the mammalian host, Trypanosoma brucei takes up host transferrin by means of a high-affinity uptake system, presumably a transferrin receptor. Transferrin-binding activity is seen in the flagellar pocket and is absent in insect form trypanosomes. By transfection we have reconstituted a transferrin-binding complex in insect form trypanosomes. Formation of this complex requires the products of two genes that are part of a variant surface glycoprotein expression site, expression site-associated gene (ESAG) 6 (encoding a protein with GPI-anchor) and ESAG 7 (encoding a protein without any obvious membrane attachment). This complex can be precipitated by transferrin-Sepharose and by an antibody directed only against the ESAG 6 protein. Transfection of ESAG 6 or 7 alone did not result in transferrin binding. In the transfected trypanosomes, the products of ESAG 6 alone and the combination of ESAG 6 and 7 did not exclusively localize to the flagellar pocket, but were present all over the surface of the trypanosome. The reconstituted transferrin-binding complex also did not result in the uptake of transferrin. Additional proteins present in bloodstream trypanosomes, but not in sufficient amounts in insect form trypanosomes, may therefore be required for the correct routing of the transferrin-binding complex to the flagellar pocket, and for its rapid internalization after ligand binding.

Stable transformation of Trypanosoma brucei

We have further analyzed parameters affecting stable transformation of Trypanosoma brucei. Linear DNA was much more efficient than circular DNA and in the vast majority of transformants analyzed the plasmid DNA had inserted into the chromosomes by homologous recombination. The presence of non-homologous (vector) DNA at one or both ends of linear constructs inhibited transformation efficiency. Less than 1 kb of homologous flanking sequence was sufficient for efficient targeting of a marker gene into the tubulin gene array. When transformants with a single neomycin phosphotransferase (neo(r)) gene replacing a beta-tubulin gene were selected for higher levels of G418 resistance, the neo(r) gene was amplified and spread through the tubulin gene cluster. The additional neo(r) gene copies were adjacent in the tubulin gene array and were added to the array rather than replacing beta-tubulin genes. These results are compatible with asymmetric post-replication recombination (unequal sister chromatid exchange) as the mechanism for neo(r) gene amplification. Starting with a circular construct containing the neo(r) gene between tubulin intergenic regions, we obtained a single transformant that maintained the neo(r) genes as an extrachromosomal plasmid. We show this plasmid to consist of a circular pentamer of the input construct. All other attempts to derive a shuttle vector that replicates extrachromosomally in T. brucei were unsuccessful. Our experiments extend previous observations suggesting that T. brucei has a strong preference for chromosomal insertion of exogenous DNA by homologous recombination.

Insertion of the promoter for a variant surface glycoprotein gene expression site in an RNA polymerase II transcription unit of procyclic Trypanosoma brucei

The variant-specific surface glycoprotein (VSG) genes of Trypanosoma brucei are invariably expressed near the ends of chromosomes (telomeres). We have targeted a VSG gene expression site (ES) promoter driving a selectable marker gene (neomycin phosphotransferase) into a chromosome-internal transcription unit, the tubulin gene array of procyclic trypanosomes. To avoid read through transcription of the marker gene from the tubulin promoter, we targeted the ES promoter in inverse orientation relative to tubulin gene transcription. The only correctly targeted transformant obtained contained the marker gene close to the border of the tubulin gene array, and expression of this gene was relatively low. Possible reasons for the low targeting efficiency and expression level are discussed.

A ribosomal RNA gene promoter at the telomere of a mini-chromosome in Trypanosoma brucei

The parasitic protozoan Trypanosoma brucei has some hundred mini-chromosomes of 50-150 kb, which mainly consist of telomeric repeats, sub-telomeric repeats and internal 177-bp repeats. Their primary function seems to be to expand the repertoire of non-transcribed sub-telomeric variant surface glycoprotein (VSG) genes. Here we report that two of the smaller mini-chromosomes (55 and 60 kb) contain sequences homologous to the ribosomal RNA gene promoter region. We have targeted by homologous recombination the neomycin phosphotransferase (neo(r)) gene behind the promoter on the 55 kb chromosome and show that this promoter mediates the efficient synthesis of properly trans-spliced and polyadenylated neo mRNA. The resulting high resistance to G418 (a neo analogue) is stable in the absence of drug showing that mitotic segregation of this mini-chromosome is precise. Downstream of the transcription start the wild-type version of the ribosomal promoter is flanked by telomeric repeats. The absence of the sub-telomeric repeats found in other T.brucei chromosome ends suggests that the rDNA-telomeric junction has been formed by de novo addition of telomeric repeats to a broken chromosome end (healing). Our results provide a plausible explanation for the alpha-amanitin-resistant transcription of telomeric repeats in T.brucei reported by Rudenko and Van der Ploeg and they show that trypanosomes can efficiently use RNA polymerase I for the expression of sub-telomeric genes, supporting the notion that the alpha-amanitin-resistant transcription of sub-telomeric VSG genes may also be catalyzed by this enzyme.

Efficient production of functional mRNA mediated by RNA polymerase I in Trypanosoma brucei

The unicellular eukaryote Trypanosoma brucei evades the immune defence of its mammalian host by antigenic variation. The genes for variant-specific surface glycoproteins (VSGs) are expressed within large multicistronic transcription units. Mature messenger RNAs are produced by trans-splicing and polyadenylation. A remarkable feature of the transcription of VSG genes is its insensitivity to the RNA polymerase II inhibitor alpha-amanitin. This has led to the speculation that RNA polymerase I, normally only involved in the transcription of ribosomal RNA genes, also mediates expression of these surface antigen genes. In higher eukaryotes, however, transcripts produced by RNA polymerase I were found to be poor substrates for processing into mature mRNAs. In contrast, we show here that the RNA polymerase I of T. brucei can mediate the efficient production of functional mRNA for neomycin phosphotransferase. This exceptional ability may be related to the unusual way in which pre-mRNAs are capped in trypanosomes. In most eukaryotes, mRNAs are modified at their 5' end by a capping activity associated with RNA polymerase II; in trypanosomes, mRNAs acquire their 5'-cap from capped mini-exon donor RNA by trans-splicing, a process that could be independent of the RNA polymerase producing the pre-mRNA.

Alpha-amanitin-resistant transcription units in trypanosomes: a comparison of promoter sequences for a VSG gene expression site and for the ribosomal RNA genes

Transcription of the predominant surface antigen genes in Trypanosoma brucei is unusual in its resistance to the RNA polymerase inhibitor alpha-amanitin, a property typical for rDNA transcription in eukaryotes. Transcription of most other protein-coding genes in trypanosomes is sensitive to alpha-amanitin. To investigate whether RNA polymerase I, the polymerase that transcribes rRNA genes, can give rise to functional mRNAs in trypanosomes, we have fused the putative promoter of the T.brucei rRNA genes to the chloramphenicol acetyl transferase (CAT) gene and determined CAT activity after transient expression of chimeric constructs in procyclic trypanosomes. We show here that the rRNA promoter yields the same high CAT activity as the promoters for the two predominant surface antigen genes of trypanosomes, the Variant-specific Surface Glycoprotein (VSG) gene of bloodstream trypanosomes and the procyclin gene of insect-form trypanosomes, both of which are also transcribed by an alpha-amanitin-insensitive RNA polymerase. RNA polymerase I of trypanosomes seems therefore able to synthesize pre-mRNAs that are effectively processed into translatable mRNAs. Dissection of the promoter segments showed the minimal elements for a VSG gene expression site promoter to be confined to a segment of -60 to +77 bp, overlapping the most 5' putative transcription start sites as determined in vivo by RNase protection experiments. For the ribosomal promoter region a segment of -258 to +200 bp relative to the putative transcription start site was sufficient for maximal CAT activity. There is a precise requirement for specific nucleotides at the rRNA transcription start site. We detect no homology between the sequences required for promoter function of the three alpha-amanitin-resistant transcription units, rRNA, VSG and procyclin (parp) genes. This suggests that the sequence-specific recognition of these promoters either occurs by common factors detecting sequence homologies that escape us, or by separate factors that bind to different DNA sequences but interact with a common alpha-amanitin-resistant RNA polymerase.

Antigenic variation in Trypanosoma brucei: a telomeric expression site for variant-specific surface glycoprotein genes with novel features

African trypanosomes evade the immune response of their host by periodically changing their variant surface glycoprotein (VSG) coat. Each coat is encoded by a separate VSG gene. Expressed genes are in a telomeric expression site (ES) and there are several sites in each trypanosome. To study the transcription control of VSG genes in Trypanosoma brucei we have analyzed an ES, called the dominant ES (DES), that readily switches off and on. The promoter area of the DES is very similar to that of the 221 ES (Zomerdijk et al., 1990). It can be switched off and on in vivo without detectable DNA alterations in the vicinity of the transcription start and it can drive high transient expression of a reporter gene in transfection experiments. However, there are also two major differences between the DES and the 221 ES. First, one version of the DES contains an additional upstream transcription unit overlapping the VSG gene ES promoter. The presence of this upstram transcription is dispensable, however, for the VSG gene ES promoter is active, even if transcription through this start from the upstream promoter is blocked using UV light. Moreover, a second version of the DES present in another trypanosome variant does not produce these upstream transcripts. Secondly, we find that the inactivation of DES transcription in one trypanosome variant is accompanied by DNA alterations in the DES upstream (greater than 2 kb) of the transcription start; reactivation of DES transcription is accompanied by another alteration far upstream. Although we cannot exclude that these DNA rearrangements are incidental, our results raise the possibility that the activity of ES promoters is negatively controlled in cis by far upstream sequences not included in transfection constructs and that alterations in these sequences may lead to (in)activation of the promoter.

The promoter for a variant surface glycoprotein gene expression site in Trypanosoma brucei

The variant-specific surface glycoprotein (VSG) gene 221 of Trypanosoma brucei is transcribed as part of a 60 kb expression site (ES). We have identified the promoter controlling this multigene transcription unit by the use of 221 chromosome-enriched DNA libraries and VSG gene 221 expression site specific transcripts. The start of transcription was determined by hybridization and RNase protection analysis of nascent RNA. The 5' ends of the major transcripts coming from the initiation region map at nucleotide sequences that do not strongly resemble rRNA transcriptional starts even though the transcripts are synthesized by an RNA polymerase highly resistant to alpha-amanitin. The cloned VSG gene 221 ES transcription initiation region promotes high CAT gene expression, when reintroduced by electroporation into T. brucei. We show that the activity of this expression site is controlled at or near transcription initiation in bloodstream trypanosomes. The 221 ES is inactivated without any sequence alteration within 1.4 kb of the transcription start site. This excludes mechanisms of promoter inactivation involving DNA rearrangements in the vicinity of the transcription start site, e.g. promoter inversion or conversion.