Transcription of the heat shock 70 locus in Trypanosoma brucei

The Hsp70/J-protein machinery of the African trypanosome, Trypanosoma brucei

The etiological agent of the neglected tropical disease African trypanosomiasis, Trypanosoma brucei, possesses an expanded and diverse repertoire of heat shock proteins, which have been implicated in cytoprotection, differentiation, as well as progression and transmission of the disease. Hsp70 plays a crucial role in proteostasis, and inhibition of its interactions with co-chaperones is emerging as a potential therapeutic target for numerous diseases. In light of genome annotations and the release of the genome sequence of the human infective subspecies, an updated and current in silico overview of the Hsp70/J-protein machinery in both T. brucei brucei and T. brucei gambiense was conducted. Functional, structural, and evolutionary analyses of the T. brucei Hsp70 and J-protein families were performed. The Hsp70 and J-proteins from humans and selected kinetoplastid parasites were used to assist in identifying proteins from T. brucei, as well as the prediction of potential Hsp70-J-protein partnerships. The Hsp70 and J-proteins were mined from numerous genome-wide proteomics studies, which included different lifecycle stages and subcellular localisations. In this study, 12 putative Hsp70 proteins and 67 putative J-proteins were identified to be encoded on the genomes of both T. brucei subspecies. Interestingly there are 6 type III J-proteins that possess tetratricopeptide repeat-containing (TPR) motifs. Overall, it is envisioned that the results of this study will provide a future context for studying the biology of the African trypanosome and evaluating Hsp70 and J-protein interactions as potential drug targets.

Post-transcriptional regulation of the trypanosome heat shock response by a zinc finger protein

In most organisms, the heat-shock response involves increased heat-shock gene transcription. In Kinetoplastid protists, however, virtually all control of gene expression is post-transcriptional. Correspondingly, Trypanosoma brucei heat-shock protein 70 (HSP70) synthesis after heat shock depends on regulation of HSP70 mRNA turnover. We here show that the T. brucei CCCH zinc finger protein ZC3H11 is a post-transcriptional regulator of trypanosome chaperone mRNAs. ZC3H11 is essential in bloodstream-form trypanosomes and for recovery of insect-form trypanosomes from heat shock. ZC3H11 binds to mRNAs encoding heat-shock protein homologues, with clear specificity for the subset of trypanosome chaperones that is required for protein refolding. In procyclic forms, ZC3H11 was required for stabilisation of target chaperone-encoding mRNAs after heat shock, and the HSP70 mRNA was also decreased upon ZC3H11 depletion in bloodstream forms. Many mRNAs bound to ZC3H11 have a consensus AUU repeat motif in the 3'-untranslated region. ZC3H11 bound preferentially to AUU repeats in vitro, and ZC3H11 regulation of HSP70 mRNA in bloodstream forms depended on its AUU repeat region. Tethering of ZC3H11 to a reporter mRNA increased reporter expression, showing that it is capable of actively stabilizing an mRNA. These results show that expression of trypanosome heat-shock genes is controlled by a specific RNA-protein interaction. They also show that heat-shock-induced chaperone expression in procyclic trypanosome enhances parasite survival at elevated temperatures.

Heat shock causes a decrease in polysomes and the appearance of stress granules in trypanosomes independently of eIF2(alpha) phosphorylation at Thr169

In trypanosomes there is an almost total reliance on post-transcriptional mechanisms to alter gene expression; here, heat shock was used to investigate the response to an environmental signal. Heat shock rapidly and reversibly induced a decrease in polysome abundance, and the consequent changes in mRNA metabolism were studied. Both heat shock and polysome dissociation were necessary for (1) a reduction in mRNA levels that was more rapid than normal turnover, (2) an increased number of P-body-like granules that contained DHH1, SCD6 and XRNA, (3) the formation of stress granules that remained largely separate from the P-body-like granules and localise to the periphery of the cell and, (4) an increase in the size of a novel focus located at the posterior pole of the cell that contain XRNA, but neither DHH1 nor SCD6. The response differed from mammalian cells in that neither the decrease in polysomes nor stress-granule formation required phosphorylation of eIF2alpha at the position homologous to that of serine 51 in mammalian eIF2alpha and in the occurrence of a novel XRNA-focus.

The trypanosome transcriptome is remodelled during differentiation but displays limited responsiveness within life stages

BACKGROUND

Trypanosomatids utilise polycistronic transcription for production of the vast majority of protein-coding mRNAs, which operates in the absence of gene-specific promoters. Resolution of nascent transcripts by polyadenylation and trans-splicing, together with specific rates of mRNA turnover, serve to generate steady state transcript levels that can differ in abundance across several orders of magnitude and can be developmentally regulated. We used a targeted oligonucleotide microarray, representing the strongly developmentally-regulated T. brucei membrane trafficking system and approximately 10% of the Trypanosoma brucei genome, to investigate both between-stage, or differentiation-dependent, transcriptome changes and within-stage flexibility in response to various challenges.

RESULTS

6% of the gene cohort are developmentally regulated, including several small GTPases, SNAREs, vesicle coat factors and protein kinases both consistent with and extending previous data. Therefore substantial differentiation-dependent remodeling of the trypanosome transcriptome is associated with membrane transport. Both the microarray and qRT-PCR were then used to analyse transcriptome changes resulting from specific gene over-expression, knockdown, altered culture conditions and chemical stress. Firstly, manipulation of Rab5 expression results in co-ordinate changes to clathrin protein expression levels and endocytotic activity, but no detectable changes to steady-state mRNA levels, which indicates that the effect is mediated post-transcriptionally. Secondly, knockdown of clathrin or the variant surface glycoprotein failed to perturb transcription. Thirdly, exposure to dithiothreitol or tunicamycin revealed no evidence for a classical unfolded protein response, mediated in higher eukaryotes by transcriptional changes. Finally, altered serum levels invoked little transcriptome alteration beyond changes to expression of ESAG6/7, the transferrin receptor.

CONCLUSION

While trypanosomes regulate mRNA abundance to effect the major changes accompanying differentiation, a given differentiated state appears transcriptionally inflexible. The implications of the absence of a transcriptome response in trypanosomes for both virulence and models of life cycle progression are discussed.

Identification and characterisation of a regulatory region in the Toxoplasma gondii hsp70 genomic locus

Toxoplasma gondii is an important human and veterinary pathogen. The induction of bradyzoite development in vitro has been linked to temperature, pH, mitochondrial inhibitors, sodium arsenite and many of the other stressors associated with heat shock protein induction. Heat shock or stress induced activation of a set of heat shock protein genes, is characteristic of almost all eukaryotic and prokaryotic cells. Studies in other organisms indicate that heat shock proteins are developmentally regulated. We have established that increases in the expression of bag1/hsp30 and hsp70 are associated with bradyzoite development. The T. gondii hsp70 gene locus was cloned and sequenced. The regulatory regions of this gene were analysed by deletion analysis using beta-galactosidase expression vectors transiently transfected into RH strain T. gondii. Expression was measured at pH 7.1 and 8.1 (i.e. pH shock) and compared to the expression obtained with similar constructs using BAG1 and SAG1 promoters. A pH-regulated region of the Tg-hsp70 gene locus was identified which has some similarities to heat shock elements described in other eukaryotic systems. Green fluorescent protein expression vectors driven by the Tg-hsp70 regulatory region were constructed and stably transfected into T. gondii. Expression of green fluorescent protein in these parasites was induced by pH shock in those lines carrying the Tg-hsp70 regulatory constructs. Gel shift analysis was carried out using oligomers corresponding to the pH-regulated region and a putative DNA binding protein was identified. These data support the identification of a pH responsive cis-regulatory element in the T. gondii hsp70 gene locus. A model of the interaction of hsp70 and small heat shock proteins (e.g. BAG1) in development is presented.

Identification of a putative regulatory element in the 3'-untranslated region that controls expression of HSP70 in Leishmania infantum

The regulation of HSP70 gene expression in Leishmania infantum, in contrast to most eukaryotes, occurs by mechanisms that operate exclusively at the post-transcriptional level. During the normal growth of L. infantum promastigotes at 26 degrees C the mRNAs derived from the sixth gene of the HSP70 locus are more abundant than the mRNAs derived from the other five HSP70 genes, but only the latter transcripts accumulate after incubation at 37 degrees C. Here, it was found that the full-length 3'untranslated region (UTR) and downstream sequences of the HSP70 genes are necessary for a correct polyadenylation of both types of transcripts and responsible for the differences in the steady-state levels of the transcripts. Also, it was found that the addition of the 3'-UTR-I (common to the first five genes of the L. infantum HSP70 gene cluster) to a reporter gene is sufficient to achieve an accumulation of the corresponding transcripts at 37 degrees C. This effect was, furthermore, found to be strand dependent. A progressive shortening of the 1063-base 3'-UTR-I has shown that the temperature-dependent accumulation was lost after deletion of 364-nucleotides from the 3' end. In addition, the accumulation of reporter transcripts at 37 degrees C was not observed in a plasmid construct containing an internal deletion (region 699-816) of the 3'-UTR-I. Thus, our data suggest that RNAs derived from L. infantum HSP70 genes 1-5 contain a cis-acting sequence that functions as a positive element during heat shock.

Uniform distribution of transcription complexes over the entire Leishmania donovani clpB (hsp 100) gene locus

We have analyzed the RNA polymerase density on the Leishmania donovani clpB gene locus. Our results show an even distribution of RNA polymerase over the clpB locus indicating an undiscriminative transcription. We conclude that, unlike the hsp70 genes, the clpB gene is not transcribed individually, but rather as part of a larger, polycistronic transcription unit.

The 3' untranslated region of the hsp 70 genes maintains the level of steady state mRNA in Trypanosoma brucei upon heat shock

An increase in the transcriptional efficiency at elevated temperatures is a characteristic of transcription of heat shock protein (hsp) coding genes in most eukaryotes analyzed to date. The regulatory mechanism for hsp 70 genes expression in Trypanosoma brucei does not follow the conventional transcriptional induction mechanism. The hsp 70 locus of T.brucei appears in a permanently activated state, and transcriptional induction of hsp 70 genes by heat shock does not occur in this organism. Therefore, the differential expression of the hsp 70 genes in trypanosomes is, to a large extent, post-transcriptionally controlled. Mechanisms of post-transcriptional control of the hsp 70 gene expression were investigated. Procyclic trypanosomes were normally maintained at approximately 25 degreesC. Incubation of procyclic trypanosomes at 41 degreesC drastically reduced the steady state mRNA levels of many protein coding genes. In contrast, the expression of the hsp 70 genes is either maintained at a high level or is up-regulated. The hsp 70 intergenic region promoter together with its 3' splice acceptor sites and the 5' untranslated region (UTR) are not sufficient to maintain or up-regulate the mRNA level of a reporter gene upon heat shock. However, addition of the 3' UTR of hsp 70 genes to a reporter gene, driven by different promoters, maintained a high level expression of the mRNA during heat shock. These results suggested that the 3' UTR of the hsp 70 genes is primarily responsible for the maintenance of mRNA level during heat shock, while mRNA containing the 3' UTR from many other genes may be rapidly degraded by heat shock induced processes.

Conserved organization of genes in trypanosomatids

Trypanosomatids are unicellular protozoan parasites which constitute some of the most primitive eukaryotes. Leishmania spp, Trypanosoma cruzi and members of the Trypanosoma brucei group, which cause human diseases, are the most studied representatives of this large family. Here we report a comparative analysis of a large genomic region containing glucose transporter genes in three Salivarian trypanosomes (T. brucei, T. congolense and T. vivax), T. cruzi and Leishmania donovani. In T. brucei, the 8 kb (upstream) and 14 kb (downstream) regions flanking the glucose transporter genes cluster contain two and six new genes, respectively, six of them encoding proteins homologous to known eukaryotic proteins (phosphatidylinositol 3 kinase, ribosomal protein S12, DNAJ and three small G-proteins--Rab1, YPT6 and ARL3). This gene organization is identical in T. brucei, T. congolense and T. vivax suggesting that Salivarian trypanosomes have a high level of conservation in gene organization. In T. cruzi and Leishmania, the overall organization of this cluster is conserved, with insertion of additional genes when compared with T. brucei. Phylogenetic reconstitution based on glucose transporters is in accord with the monophyly of the genus Trypanosoma and the early separation of T. vivax within Salivarian trypanosomes. On the basis of gene organization, biochemical characteristics of isoforms and phylogeny, we discuss the genesis of the glucose transporter multigene family in Salivarian trypanosomes.

Transcription of protein-coding genes in trypanosomes by RNA polymerase I

In eukaryotes, RNA polymerase (pol) II transcribes the protein-coding genes, whereas RNA pol I transcribes the genes that encode the three RNA species of the ribosome [the ribosomal RNAs (rRNAs)] at the nucleolus. Protozoan parasites of the order Kinetoplastida may represent an exception, because pol I can mediate the expression of exogenously introduced protein-coding genes in these single-cell organisms. A unique molecular mechanism, which leads to pre-mRNA maturation by trans-splicing, facilitates pol I-mediated protein-coding gene expression in trypanosomes. Trans-splicing adds a capped 39-nucleotide mini-exon, or spliced leader transcript, to the 5' end of the main coding exon posttranscriptionally. In other eukaryotes, the addition of a 5' cap, which is essential for mRNA function, occurs exclusively as a result of RNA pol II-mediated transcription. Given the assumption that cap addition represents the limiting factor, trans-splicing may have uncoupled the requirement for RNA pol II-mediated mRNA production. A comparison of the alpha-amanitin sensitivity of transcription in naturally occurring trypanosome protein-coding genes reveals that a unique subset of protein-coding genes-the variant surface glycoprotein (VSG) expression sites and the procyclin or the procyclic acidic repetitive protein (PARP) genes-are transcribed by an RNA polymerase that is resistant to the mushroom toxin alpha-amanitin, a characteristic of transcription by RNA pol I. Promoter analysis and a pharmacological characterization of the RNA polymerase that transcribes these genes have strengthened the proposal that the VSG expression sites and the PARP genes represent naturally occurring protein-coding genes that are transcribed by RNA pol I.

Transcription of the Leishmania major Hsp70-I gene locus does not proceed through the noncoding region

Primary transcripts in kinetoplastid protozoa are generally assumed to be multicistronic. We have analyzed the transcription in the gene locus which encodes the 70-kDa heat shock protein by using nuclear run-on analysis. We find that RNA synthesis in the Hsp70-I gene locus either is terminated or pauses within the intergenic region approximately 250 nt downstream of the polyadenylation site. We therefore propose a discontinuous mode of transcription in the Hsp70 genes of Leishmania major.

Analysis of post-transcriptional regulation operating on transcription products of the tandemly linked Leishmania infantum hsp70 genes

The genomic organization and expression of the hsp70 genes of Leishmania infantum were examined. In the cluster there are at least six copies of the hsp70 genes arranged in a head-to-tail tandem of 3. 8-kilobase repetition units. The hsp70 gene copy (gene 6) located at the 3' end of the tandem has a 3'-untranslated region highly divergent in sequence relative to the 3'-untranslated region of the rest of hsp70 gene copies (genes 1-5). Nuclease S1 protection assays indicated that the steady-state level of the mRNAs derived from gene 6 is about 50-fold more abundant than the transcript level derived from genes 1-5. Nuclear run-on assays showed, however, that all hsp70 genes are transcribed at similar rates. Thus, it is likely that the differences in the steady-state levels of the transcripts from the hsp70 genes should be associated with variations in their processing or maturation rates. While the abundance of the mRNAs derived from hsp70 genes 1-5 is increased by heat shock, the hsp70 gene 6 mRNA level remains unaffected. Our data showed that ongoing protein synthesis is required for the maintenance of the heat inducement, depicting, thus, a post-transcriptional mechanism of positive regulation involving a labile protein factor that would be either induced or activated during heat shock.

Molecular characterization of the D surface protein gene subfamily in Paramecium tetraurelia

When Paramecium tetraurelia expresses the D serotype, detectable by serum tests, high molecular mRNA could be isolated, which corresponds to the molecular mass of the D surface protein. Using this D specific mRNA as a probe for screenings in different genomic libraries a subfamily of five very similar genes was found, named alpha-51D, gamma 1-51D, gamma 2-51D, delta-51D, and epsilon-51D. Each of them is about 8-kb long, they show regions of identity to each other, and there is no evidence that any are defective genes or pseudogenes. Up to now serotype D is the only known serotype showing this phenomenon. Another novel feature is that two of the D isogenes are closely linked. The sequence for the entire coding region of the alpha-51D gene has been determined, as well as the upstream and downstream noncoding regions. Its deduced amino acid sequence shows the same characteristic cysteine periodicity displayed by all other immobilization antigen (i-ag) genes from Paramecium. However, in contrast to most other such genes, tandem repeats are missing from the 7599-bp long coding region of the alpha-51D gene. When the sequences of the type 51D genes are compared to each other, the similarity is very high and extends to coding as well as to noncoding regions. Similarity within noncoding regions is usually only observed for allelic i-ag genes. We conclude that the type D genes constitute a family of isogenes that are nonallelic. They contain slightly different consensus sequences with possible functions as regulatory regions.

An RNA polymerase II promoter in the hsp70 locus of Trypanosoma brucei

To study of structure of RNA polymerase (pol) II transcription units a nd the influence of temperature on the regulation of gene expression in Trypanosoma brucei, and hsp70 intergenic region promoter was characterized. In T. brucei, the hsp70 locus contains, from 5' to 3', a cognate hsp70-related gene (gene 1) which is separated by about 6 kb of DNA from a cluster of five identical hsp70 genes (genes 2 to 6). Transcription proceeds on the entire 23-kb locus, and polycistronic transcription occurs in hsp70 genes 2 to 6. Transcription of hsp70 genes 2 to 6 is only moderately sensitive to UV irradiation, indicating that it cannot be driven by a single far-upstream promoter, which suggests that promoters could be located in the region close to the hsp70 coding region. Transient transformations demonstrated that sequences located upstream of hsp70 gene 2 and in the intergenic region between hsp70 genes 2 and 3 are able to direct transcription of the reporter gene, the chloramphenicol acetyltransferase (CAT) gene. The plasmid DNA driven by the hsp70 intergenic region promoter gave CAT activity approximately 85-fold above to background level. This is equivalent to approximately 1% of that derived from a CAT plasmid driven by the procyclic acidic repetitive protein gene promoter, which is controlled by RNA pol I. The hsp70 intergenic region promoter can drive alpha-amanitin-sensitive transcription at an internal position of the chromosome as well as an episome, suggesting that it is controlled by RNA pol II. However, this hsp70 intergenic region promoter, along with the 3' splice site and the 5' untranslated region of the hsp70 genes that controls the transcription of the reporter gene, cannot up-regulate the expression of the reporter gene during heat shock. This result is consistent with the previous observation that expression of the hsp70 genes in T. brucei is mainly controlled at the posttranscriptional level.

Post-transcriptional control of hsp70 mRNA in Trypanosoma brucei

The control of hsp70 mRNA levels was investigated using transgenic bloodstream and procyclic trypanosomes. Heat shock of procyclic and bloodstream trypanosomes caused no significant change in overall protein synthesis, but led to a 2-3-fold increase in the relative hsp70 mRNA level in bloodstream trypanosomes. Incubation of procyclic trypanosomes at 35 degrees C for up to 18 h increased the level of hsp70 mRNA only marginally. The expression of actin and hsp70 mRNAs was markedly reduced in late log phase procyclic trypanosomes but PARP mRNA levels remained constant. Measurements of phleomycin-binding-protein RNAs bearing 3'- and 5'-untranslated regions from the actin, PARP or hsp70 loci indicated that both the heat-shock and cell-density effects were mediated by the untranslated regions. No significant promoter activity was detected in the different hsp70 locus intergenic regions in transient assays.

Control of gene expression in trypanosomes

Trypanosomes are protozoan agents of major parasitic diseases such as Chagas' disease in South America and sleeping sickness of humans and nagana disease of cattle in Africa. They are transmitted to mammalian hosts by specific insect vectors. Their life cycle consists of a succession of differentiation and growth phases requiring regulated gene expression to adapt to the changing extracellular environment. Typical of such stage-specific expression is that of the major surface antigens of Trypanosoma brucei, procyclin in the procyclic (insect) form and the variant surface glycoprotein (VSG) in the bloodstream (mammalian) form. In trypanosomes, the regulation of gene expression is effected mainly at posttranscriptional levels, since primary transcription of most of the genes occurs in long polycistronic units and is constitutive. The transcripts are processed by transsplicing and polyadenylation under the influence of intergenic polypyrimidine tracts. These events show some developmental regulation. Untranslated sequences of the mRNAs seem to play a prominent role in the stage-specific control of individual gene expression, through a modulation of mRNA abundance. The VSG and procyclin transcription units exhibit particular features that are probably related to the need for a high level of expression. The promoters and RNA polymerase driving the expression of these units resemble those of the ribosomal genes. Their mutually exclusive expression is ensured by controls operating at several levels, including RNA elongation. Antigenic variation in the bloodstream is achieved through DNA rearrangements or alternative activation of the telomeric VSG gene expression sites. Recent discoveries, such as the existence of a novel nucleotide in telomeric DNA and the generation of point mutations in VSG genes, have shed new light on the mechanisms and consequences of antigenic variation.

Mechanisms of stage-regulated gene expression in kinetoplastida

During their life cycle, trypanosomatid parasites of mammals encounter substantially different environments in their hosts and insect vectors, to which they must adapt by undergoing a series of differentiation processes. At the molecular level, these processes must be the direct result of an elaborate series of changes in stage-regulated expression of a wide range of gene products. How are these changes accomplished? In this review, Sheila Graham discusses some recent advances in understanding the mechanisms of gene expression in trypanosomatids, and examines some clues to some intriguingly complex means of regulating life cycle stage-specific gene expression.

A foreign transcription unit in the inactivated VSG gene expression site of the procyclic form of Trypanosoma brucei and formation of large episomes in stably transformed trypanosomes

Transcription of the variant surface glycoprotein (VSG) gene expression site (ES) in Trypanosoma brucei is inactivated upon differentiation from the bloodstream form to the insect-adapted, procyclic form. This paper demonstrates that a foreign transcription unit, containing a procyclic acidic repetitive protein (PARP) gene promoter driving a neomycin phosphotransferase (neo) gene, can be fully active once integrated at the lingering, transcriptionally inactive VSG ES of procyclic trypanosomes. Following targeting into the ES two types of transformants were identified. Type one transformants were generated by integration of the PARP-neo gene into the region downstream of the long 70-bp repeat array of the silent telomeric ES encoding VSG gene 118. alpha-amanitin-resistant transcription at the neo locus proceeded from the PARP promoter to approximately 2.5 kb downstream of the integration site and terminated in front of the VSG 118 gene. Type two transformants contained variously sized large episomes (ranging from 135 kb to 500 kb), consisting of tandemly linked input plasmids. Transcription of the neo gene in the episomes was also resistant to alpha-amanitin. The presence of large amounts of the active episomal PARP promoter did not significantly affect the transcription of most RNA polymerase II transcribed genes, but resulted in a significant and equal reduction of the transcriptional efficiency of the endogenous PARP genes and VSG gene promoter sequences. This observation suggests that transcription of the PARP gene and the VSG gene expression sites in insect form trypanosomes may share a common transcriptional machinery.

Hsp70 in parasites: as an inducible protective protein and as an antigen

The heat shock (HS) response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stresses. It has been demonstrated that heat shock proteins (HSP) play major roles in many cellular processes, and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology, from cancer research to interaction between host and parasites. This review deals with the hsp70 gene family and with its protein product, hsp70, as an antigen when pathogens infect humans. Members of HSP have been shown to be major antigens of many pathogenic organisms when they experience a major temperature shift upwards at the onset of infection and become targets for host B and T cells.

A regulatory role for the 5' and 3' untranslated regions in differential expression of hsp83 in Leishmania

Exposure of Leishmania promastigotes to temperatures typical of mammals result in a stress response, which is accompanied by an increase in the steady state level of heat shock transcripts and their translation. Accumulation of the heat shock protein (hsp83) mRNA occurs due to differential decay rates at the altered temperatures, while transcription is unaffected. A similar pattern of post-transcriptional regulation was observed for a transfected chloramphenicol acetyltransferase (CAT) gene, which was flanked at both ends by intergenic regions (IR) of hsp83. Shortening the 5' untranslated region (UTR) by 100 nts produced an active CAT enzyme, but abolished the temperature-dependent regulation of the CAT-hsp83 mRNA turn-over. The 3' UTR is also involved in the temperature-dependent degradation of hsp83 mRNA, since exchange of the hsp83 3' UTR with a parallel fragment from a non-heat shock gene abolished the differential turn-over of CAT mRNA. Thus, the regulated decay of hsp83 mRNA is controlled by sequence or conformational elements present in both upstream and downstream UTRs. Like the endogenous hsp83, translation of CAT mRNA which contained hsp83 UTRs was higher at 35 degrees C. This was observed only with transcripts in which stability increased at elevated temperatures. Modifications which abolished the temperature dependence of CAT mRNA decay, eliminated its elevated translation at the higher temperatures. The correlation suggests a mechanistic link between the translational machinery and mRNA stability.

Conservation of heat-shock proteins in Trypanosoma cruzi

Heat shock is an integral part of the life cycle of Trypanosoma cruzi. Here, Edson Rondinelli reviews the parasite's response to stress.

Sequence and genomic organization of the hsp70 genes of Leishmania amazonensis

The sequence and genomic organization of hsp70 genes in Leishmania amazonensis were examined. Maps of overlapping cosmid clones revealed that seven L. amazonensis hsp70 genes are organized into a 24-kb locus containing 3.5-kb tandem repeats. Cosmids covering a different chromosomal region indicated that an eighth hsp70 sequence is located at a distant site. Southern blot data suggested the existence of additional hsp70 genes or pseudogenes. One complete 3.5-kb genomic repeat unit, including coding and intergenic regions, was sequenced. The predicted L. amazonensis HSP70 protein had approximately 95% sequence identity with Leishmania donovani or Leishmania major HSP70, 81-85% identity with trypanosome HSP70, and 68 or 72% identity with human HSP70 or HSP70 cognate, respectively. The GGMP tetrapeptide repeat found in other trypanosomatid HSP70 proteins is absent from the L. amazonensis sequence. Intergenic sequences of L. amazonensis and L. major differed mainly in the presence of short gaps in the L. amazonensis sequence. Potential regulatory heat shock elements were identified in the upstream sequence. Several cDNA clones were also isolated, and two different poly(A) addition sites 100 nucleotides apart were identified.

Differential response to RNA trans-splicing signals within the phosphoglycerate kinase gene cluster in Trypanosoma brucei

In trypanosomatids, nuclear pre-mRNA splicing is exclusively a trans-splicing reaction in which a capped, 39 nt exon, the mini-exon, is positioned 5' to an open reading frame. Differential RNA splicing might reflect specific mini-exon and 3' splice site interactions. To test this hypothesis, we compared the efficiency of mini-exon addition to three natural 3' splice acceptor sites (SASs) located within a single pre-mRNA transcript. In Trypanosoma brucei, the phosphoglycerate kinase A, B and C genes (PGK A, B and C) are co-expressed as three consecutive sequences on a polycistronic pre-mRNA. This pre-mRNA gives rise to unequal amounts of PGK A, B and C mRNAs. When the SAS from each gene was placed upstream of the luciferase open reading frame and the resultant constructs transiently transfected into T. brucei procyclic cells, luciferase activity levels indicated differential SAS utilization. Enzyme activity was low when the SAS from the A gene was present. Levels were indistinguishable when the B and C SASs were compared. After replacing luciferase with chloramphenicol acetyl transferase in the test constructs, enzyme activities were shown to directly correlate with mRNA amounts. Thus, poor splicing efficiency accounts for the differential expression of the PGK A mRNA during PGK pre-mRNA maturation. This reaction appears to reflect the polypyrimidine pattern within the 3' splice acceptor site.

Predicted amino acid sequence and genomic organization of Trypanosoma cruzi hsp 60 genes

We describe the isolation of a Trypanosoma cruzi protein-coding gene that exhibited about 50% identity with members of the family of heat shock protein (hsp) 60 genes. Since this homology extended for most of the predicted 562 amino acid open reading frame and was comparable to the level of sequence identity between the individual hsp 60 genes from diverged species, we conclude that we have isolated and characterized a T. cruzi hsp 60 gene. The T. cruzi hsp 60 genes are arranged in tandem arrays, and the presence of restriction fragment length polymorphisms (RFLPs) among the different hsp 60 genes suggests the presence of several separate gene arrays encoding hsp 60 members.

Effect of heat-shock on Plasmodium falciparum viability, growth and expression of the heat-shock protein 'PFHSP70-I' gene

Cultures of the human malaria parasite Plasmodium falciparum were subjected to heat-shock for varying times and temperatures and then tested for their viability, growth and expression of heat-shock protein. Results show that the majority of parasites remained viable after heat-shock but their growth was affected. However, the expression of the heat-shock protein 'PFHSP70-I' gene was enhanced after heat-shock. We conclude that malarial parasites are able to survive in vivo during fever probably due to the overexpression of the heat-shock protein gene.

The biology of the heat shock response in parasites

The heat shock response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stress. It has been shown that heat shock proteins play major roles in many cellular processes and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology and from cancer research to interactions between host and parasite. In this review, Bruno Maresca and Luisella Carratu deal with some of the unique characteristics of the heat shock response in parasitic organisms.

Regulation of hsp70 expression in Trypanosoma cruzi by temperature and growth phase

The steady-state level of the hsp70 mRNAs of Trypanosoma cruzi cultured at different temperatures and growth conditions has been analyzed by Northern blotting. We show that only one size class of hsp70 mRNA, of about 2.2 kb, is transcribed from the hsp70 cluster and that its transcription is constitutive at 28 degrees C. However, after a heat shock treatment at 37 degrees C for 2 h of logarithmically growing parasites, the abundance of the hsp70 mRNA increased about 4-fold. A similar increase was observed at 28 degrees C when the parasite culture reached the stationary phase of growth. On the other hand, a heat shock at 42 degrees C did not change the steady state level of the 2.2-kb size class of hsp70 mRNA. However, accumulation of transcripts of high molecular weight was detected when stationary growing parasites were cultured at 42 degrees C for 2 h. Also at 37 degrees C the steady state level of the alpha- and beta-tubulin mRNAs of logarithmically growing parasites exhibited a slight increase but only after a period of 24 h. Analysis by one-dimensional immunoblots of the Hsp70 levels showed that at 37 degrees C the abundance of the protein was 4-fold higher than at 28 degrees C. Immunoblots of high-resolution two-dimensional gel electrophoresis showed, moreover, that various isoforms of this protein are constitutively expressed at 28 degrees C and that some of them have a specific pattern of induction at 37 degrees C. We observed, moreover, that the heat shock induces the expression of a series of proteins while it causes repression of others.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Evidence for segmental gene conversion between a cognate hsp 70 gene and the temperature-sensitively transcribed hsp70 genes of Trypanosoma brucei

The protozoan parasite Trypanosoma brucei expresses several heat shock proteins of 70 kDa (hsp70). We show that, from 5' to 3', a diverged cognate hsp70 gene (gene 1) is separated by about 6 kb of DNA from a cluster of five identical hsp70 genes (genes 2-6). The hsp70 cognate gene has a predicted open reading frame of 676 amino-acids. The steady-state mRNA levels of gene 1 are unaffected by temperature shifts up to 42 degrees C. Hsps of diverse organisms share several fully conserved amino acid domains in the N-terminal region of the hsp70 proteins. These conserved amino acid domains are also observed in the T. brucei hsp70 genes 1-6. However they are, in contrast to the heat shock genes of other eukaryotes, encoded by nucleotide sequence blocks that are identical in all six hsp70 genes. These conserved domains, located in the 5' coding region, range in size from several to hundreds of nucleotides and are separated by highly diverged nucleotide sequences. The nucleotide sequence conservation between hsp70 gene 1 and hsp70 genes 2-6 indicates that selective sequence homogenization, presumably through gene conversion, maintained the amino acid sequence conservation.