RNA synthesis and turnover during density-inhibited growth and encystment of Acanthamoeba castellanii

Biological characteristics and pathogenicity of Acanthamoeba

Acanthamoeba is an opportunistic protozoa, which exists widely in nature and is mainly distributed in soil and water. Acanthamoeba usually exists in two forms, trophozoites and cysts. The trophozoite stage is one of growth and reproduction while the cyst stage is characterized by cellular quiescence, commonly resulting in human infection, and the lack of effective monotherapy after initial infection leads to chronic disease. Acanthamoeba can infect several human body tissues such as the skin, cornea, conjunctiva, respiratory tract, and reproductive tract, especially when the tissue barriers are damaged. Furthermore, serious infections can cause Acanthamoeba keratitis, granulomatous amoebic encephalitis, skin, and lung infections. With an increasing number of Acanthamoeba infections in recent years, the pathogenicity of Acanthamoeba is becoming more relevant to mainstream clinical care. This review article will describe the etiological characteristics of Acanthamoeba infection in detail from the aspects of biological characteristic, classification, disease, and pathogenic mechanism in order to provide scientific basis for the diagnosis, treatment, and prevention of Acanthamoeba infection.

Whole Organism Model to Study Molecular Mechanisms of Differentiation and Dedifferentiation

Cancer recurrence has remained a significant challenge, despite advances in therapeutic approaches. In part, this is due to our incomplete understanding of the biology of cancer stem cells and the underlying molecular mechanisms. The phenomenon of differentiation and dedifferentiation (phenotypic switching) is not only unique to stem cells but it is also observed in several other organisms, as well as evolutionary-related microbes. Here, we propose the use of a primitive eukaryotic unicellular organism, Acanthamoeba castellanii, as a model to study the molecular mechanisms of cellular differentiation and dedifferentiation.

Acanthamoeba castellanii cysts: new ultrastructural findings

During Acanthamoeba castellanii trophozoite-cysts differentiation, four morphological stages were identified by scanning electron microscopy: trophozoite, precyst, immature cysts, and mature cysts. Fluorescence microscopy reveals the presence of small cumulus of actin in the cytoplasm of precysts after treatment with rhodamine phalloidin. By the contrary, in mature cysts, fluorescence was not observed. However, when excystation was induced, large fluorescent patches were present. By transmission electron microscopy, encysting amebas showed small cytoplasmic vesicles containing fibrillar material, surrounded by a narrow area of thin fibrils. Similar appearance was observed in pseudopods and phagocytic invaginations. In addition, large aggregates of rod-shape elements, similar to the chromatoid bodies, described in other amebas, were present in the cytoplasm. These cysts presented large areas with orange fluorescence after treatment with acridine orange.

Acanthamoebadifferentiation: a two-faced drama ofDr Jekyll and Mr Hyde

The ability of cyst-forming protists such asAcanthamoebato escape death by transforming into a cyst form, that is resistant to harsh physiological, environmental and pharmacological conditions, has continued to pose a serious challenge to human and animal health. A complete understanding of the fundamental principles of genome evolution and biochemical pathways of cellular differentiation offers unprecedented opportunities to counter detrimental outcomes.Acanthamoebacan elude inhospitable conditions by forming cysts. Here we unravel the processes involved in the phenotypic switching ofAcanthamoeba, which are critical in our efforts to find potential targets for chemotherapy.

Ultrastructural study of encystation and excystation in Acanthamoeba castellanii

Encystation and excystation of Acanthamoeba castellanii were studied by transmission electron microscopy. The differentiation process was induced in asynchronous cultures grown axenically. Cytoplasmic vesicles containing a dense fibrous material very similar in appearance to the cyst wall were observed in trophozoites induced to encyst. When these trophozoites were incubated with calcofluor white m2r, fluorescence was observed in cytoplasmic vesicles, suggesting that the material contained in these vesicles corresponded to cyst wall precursors. Semithin cryosections of mature cysts with the same treatment showed fluorescence in the ectocyst and a less intense fluorescence in the endocyst, suggesting the presence of cellulose in both structures of the cyst wall. In mature cysts induced to excystation, small structures very similar to electron-dense granules (EDG) previously described in other amoebae were frequently observed. The EDGs were either sparsely distributed in the cytoplasm or associated with the cytoplasmic face of the plasma membrane. Many of them were located near the ostiole. In advanced phases of excystation, endocytic activity was suggested by the formation of endocytic structures and the presence of vacuoles with fibrous content similar to that of the cyst wall. Electron-dense granules in the process of dissolution were also observed in these vacuoles. Furthermore, the formation of a pseudopod suggests a displacement of the amoeba toward the ostiole.

In vitro and in vivo activity of 5-fluorocytosine on Acanthamoeba

The results of our studies indicated that the avirulent Neff strain of Acanthamoeba was more susceptible to the activity of the anti-metabolite 5-fluorocytosine (5-FC) than was the virulent A-1 strain or a mouse brain reisolate of this strain, designated A-3. Results of competition experiments in which cultures were exposed simultaneously to 5-FC and either uracil, thymidine, or both uracil and thymidine demonstrated that the drug was directed against both deoxyribonucleic acid and ribonucleic acid in the avirulent strain, whereas ribonucleic acid was mainly affected in the virulent amebas. Concentrations >10 mug of 5-FC per ml were amebicidal to the avirulent strain; lower concentrations of the drug, which only affected growth slightly, significantly impaired the capacity of the cells to spontaneously encyst in stationary-phase cultures. On the other hand, the virulent strains were capable of growing in the presence of 5-FC (40 mug/ml) after an initial period of susceptibility. After a few transfers in growth medium lacking the drug, 5-FC-treated virulent amebas exhibited growth parameters typical of untreated cells. However, after successive subcultures in drug-free medium, 5-FC-treated cells lost their resistance and were again susceptible to the drug. This result suggested that the capacity of the cells to develop resistance resulted from a drug-induced mechanism. Spontaneous encystment, which was normally minimal in stationary-phase A-1 or A-3 cultures, was enhanced in A-3 but not A-1 cultures treated with 5-FC (>30 mug/ml). Results obtained from experiments to determine the effectiveness of 5-FC in protecting mice experimentally infected with either A-1 or A-3 amebas indicated that the clinical usefulness of 5-FC may be limited by the capacity of the amebas to develop resistance.

The association of TIF-IA and polymerase I mediates promoter recruitment and regulation of ribosomal RNA transcription in Acanthamoeba castellanii

Large amounts of energy are expended for the construction of the ribosome during both transcription and processing, so it is of utmost importance for the cell to efficiently regulate ribosome production. Understanding how this regulation occurs will provide important insights into cellular growth control and into the coordination of gene expression mediated by all three transcription systems. Ribosomal RNA (rRNA) transcription rates closely parallel the need for protein synthesis; as a cell approaches stationary phase or encounters conditions that negatively affect either growth rate or protein synthesis, rRNA transcription is decreased. In eukaryotes, the interaction of RNA polymerase I (pol I) with the essential transcription initiation factor IA (TIF-IA) has been implicated in this downregulation of transcription. In agreement with the first observation that rRNA transcription is regulated by altering recruitment of pol I to the promoter in Acanthamoeba castellanii, we show here that pol I and an 80-kDa homologue of TIF-IA are found tightly associated in pol I fractions competent for specific transcription. Disruption of the pol I-TIF-IA complex is mediated by a specific dephosphorylation of either pol I or TIF-IA. Phosphatase treatment of TIF-IA-containing A. castellanii pol I fractions results in a downregulation of both transcriptional activity and promoter binding, reminiscent of the inactive pol I fractions purified from encysted cells. The fraction of pol I competent for promoter recruitment is enriched in TIF-IA relative to that not bound by immobilized promoter DNA. This downregulation coincides with an altered electrophoretic mobility of TIF-IA, suggesting at least it is phosphorylated.

Resistance, biguanide sorption and biguanide-induced pentose leakage during encystment of Acanthamoeba castellanii

AIMS

This study investigates the effects of biguanides during encystment of Acanthamoeba castellanii.

METHODS AND RESULTS

A non-nutrient encystment system was used to investigate the changes in the levels of sorption (uptake) of three non-cysticidal concentrations (10, 20 and 50 microg ml(-1)) of chlorhexidine diacetate (CHA) and polyhexamethylene biguanide (PHMB) as well as their effects on viability and leakage of pentose sugars during the first 36 h of encystment. Trophozoites treated with CHA or PHMB were more sensitive and generally sorbed more of each biocide than cysts. During encystment, the largest increases in resistance developed between 18 and 36 h for both biguanides with the resistance emerging to biguanide concentrations of 10 or 20 microg ml(-1) between 18 and 24 h. At 50 microg ml(-1) resistance emerged between 24 and 36 h. There was a general decrease in biocide sorption during encystment between 0-24 and 0-21 h for CHA and PHMB, respectively, at a concentration of 50 microg ml(-1). The greatest decline in biguanide-induced pentose leakage was between 0 and 12 h.

CONCLUSIONS

The results suggest that during encystment some of the changes in the susceptibility to CHA or PHMB may be related to decreases in the levels of biocide sorption, which is limited by the developing cyst wall.

SIGNIFICANCE AND IMPACT OF THE STUDY

During encystation, changes occur in biguanide sensitivity. The physical barrier of the cyst wall may be an important factor in limiting biocide sorption.

Analysis of the 5S rRNA gene promoter from Acanthamoeba castellanii

The promoter region of the Acanthamoeba 5S rRNA gene was analysed by in vitro transcription of several 5' and 3' deletion and substitution mutants, as well as a series of linker scanning mutants. The promoter consists of three sequence regions contained entirely within the gene; two of these correspond to the A and C boxes that bind TFIIIA, found in the genes from other genera. In addition, a region immediately 3' to the transcription start site has a strong effect on initiation efficiency. No strict requirement was found for specific sequences 5' to the transcription start site. Substitution of a consensus TATA box at -29 had only a modest effect on transcription, and deletion or substitution of sequences between -15 and -10 as well as -34 and -21 was only modestly more active than the wild-type template. Analysis of 3' deletions sets the 3' end-point of the promoter between +79 and +97, and demonstrates the importance of a T-rich region in transcription termination. Taken together, these results suggest that promoter elements within the Acanthamoeba 5S RNA gene are somewhat redundant, with the exception of a sequence between +50 and +60, which functions in binding TFIIIA. Remarkably, polymerase chain reaction product templates containing only non-specific 5' ends between -6 and +1 relative to the transcription start site are fully functional, demonstrating that no external DNA scaffold is needed for TFIIIB and RNA polymerase III binding, and that productive initiation can be mediated solely by protein-DNA interactions within the coding region of the 5S gene.

Mechanism of cyst specific protein 21 mRNA induction during Acanthamoeba differentiation

The Acanthamoeba cyst specific protein 21 (CSP21) gene is tightly repressed in growing cells and highly induced early during differentiation into a dormant cyst. This increase is mediated by the rate of transcription of the CSP21 gene as determined by nuclear run-on assays. The promoter region of the CSP21 gene was analyzed by transcript start site mapping and in vitro transcription of wild-type or mutant templates, using extracts from growing cells. A sequence located 3' to a modified TATA box completely inhibits transcription and removal of this region permits robust transcription utilizing a start site approximately 35 base pairs downstream of the TATA box. Sequences 5' to the TATA box had no effect on transcription, suggesting that anti-repression is the only mechanism required for CSP21 induction. Fractionation of nuclear extracts yielded a fraction capable of transcription from the CSP21 promoter, and a fraction containing a promoter-specific repressing activity. Anti-repression may thus be a major mechanism regulating differentiation or maintenance of the proliferative cycle in Acanthamoeba.

Distamycin A selectively inhibits Acanthamoeba RNA synthesis and differentiation

The effects of distamycin A on Acanthamoeba transcription, growth and differentiation were determined. Distamycin A inhibits transcription both in vitro and in vivo and can displace from DNA the transcription activator TATA binding protein promoter binding factor (TPBF). Inhibition in vivo is surprisingly selective for large rRNA precursors, 5S rRNA, profilin, S-adenosylmethionine synthetase, and extendin. Transcription from the TATA binding protein (TBP), TPBF, protein disulfide isomerase, tubulin and RNA polymerase II large subunit genes is only slightly inhibited. Moreover the rate of 5S rRNA transcription eventually recovers and exceeds that of untreated cells, while profilin transcription remains inhibited. Distamycin A inhibition is accompanied by a complex pattern of alterations to steady state levels of mRNAs. Actin, profilin and S-adenosylmethionine synthetase mRNAs are degraded, whereas mRNA encoding TBP is increased slightly in abundance. Transcription inhibition is accompanied by cessation of growth and severe morphological changes to Acanthamoeba, which are consistent with loss of production of mRNA encoding cytoskeletal proteins. Distamycin A also prevents starvation-induced differentiation of Acanthamoeba, in part due to complete prevention of cellulose production and cell wall formation.

A specialized form of RNA polymerase I, essential for initiation and growth-dependent regulation of rRNA synthesis, is disrupted during transcription

Only a small proportion (<2%) of RNA polymerase I (pol I) from whole-cell extracts appeared to be competent for specific initiation at the ribosomal gene promoter in a yeast reconstituted transcription system. Initiation-competent pol I molecules were found exclusively in salt-resistant complexes that contain the pol I-specific initiation factor Rrn3p. Levels of initiation-competent complexes in extracts were independent of total Rrn3p content and varied with the growth state of the cells. Although extracts from stationary phase cells contained substantial amounts of Rrn3p and pol I, they lacked the pol I-Rrn3p complex and were inactive in promoter-dependent transcription. Activity was restored by adding purified pol I-Rrn3p complex to extracts from stationary phase cells. The pol I-Rrn3p complex dissociated during transcription and lost its capacity for subsequent reinitiation in vitro, suggesting a stoichiometric rather than a catalytic activity in initiation. We propose that the formation and disruption of the pol I-Rrn3p complex reflects a molecular switch for regulating rRNA synthesis and its growth rate-dependent regulation.

Coordinate regulation of ribosomal component synthesis in Acanthamoeba castellanii: 5S RNA transcription is down regulated during encystment by alteration of TFIIIA activity

Transcription of large rRNA precursor and 5S RNA were examined during encystment of Acanthamoeba castellanii. Both transcription units are down regulated almost coordinately during this process, though 5S RNA transcription is not as completely shut down as rRNA transcription. The protein components necessary for transcription of 5S RNA and tRNA were determined, and fractions containing transcription factors comparable to TFIIIA, TFIIIB, and TFIIIC, as well as RNA polymerase III and a 3'-end processing activity, were identified. Regulation of 5S RNA transcription could be recapitulated in vitro, and the activities of the required components were compared. In contrast to regulation of precursor rRNA, there is no apparent change during encystment in the activity of the polymerase dedicated to 5S RNA expression. Similarly, the transcriptional and promoter-binding activities of TFIIIC are not altered in parallel with 5S RNA regulation. TFIIIB transcriptional activity is unaltered in encysting cells. In contrast, both the transcriptional and DNA-binding activities of TFIIIA are strongly reduced in nuclear extracts from transcriptionally inactive cells. These results were analyzed in terms of mechanisms for coordinate regulation of rRNA and 5S RNA expression.

Regulation of eukaryotic ribosomal RNA transcription by RNA polymerase modification

Forms of RNA polymerase I prepared from growing or encysted Acanthamoeba are equal in the ability to transcribe poly(dl:dC). Polymerase from cysts, whose rRNA genes are transcriptionally inactive, is unable to utilize the rDNA promoter in vitro, whereas the transcription initiation factor from cysts is fully able to bind the promoter and direct transcription. Footprinting shows that polymerase from cysts is functionally inactive because of its inability to bind to the promoter. The polymerase footprint moves downstream the appropriate number of base pairs upon various nucleotide additions, without affecting the factor footprint. These results support our hypothesis that rRNA synthesis in eukaryotes is regulated by polymerase I modification and not by alterations to additional DNA-binding proteins.

In vitro evidence that eukaryotic ribosomal RNA transcription is regulated by modification of RNA polymerase I

We have utilized a cell-free transcription system from Acanthamoeba castellanii to test the functional activity of RNA polymerase I and transcription initiation factor I (TIF-I) during developmental down regulation of rRNA transcription. The results strongly suggest that rRNA transcription is regulated by modification, probably covalent, of RNA polymerase I: (1) The level of activity of TIF-I in extracts from transcriptionally active and inactive cells is constant. (2) The number of RNA polymerase I molecules in transcriptionally active and inactive cells is also constant. (3) In contrast, though the specific activity of polymerase I on damaged templates remains constant, both crude and purified polymerase I from inactive cells have lost the ability to participate in faithful initiation of rRNA transcription. (4) Polymerase I purified from transcriptionally active cells has the same subunit architecture as enzyme from inactive cells. However, the latter is heat denatured 5 times faster than the active polymerase.

Regulation of ribosomal RNA transcription during differentiation of Acanthamoeba castellanii: a review

During the cellular differentiation induced by starvation of Acanthamoeba castellanii, the expression of a number of genes is regulated. Evidence is reviewed that at least one of these, the precursor ribosomal RNA transcription unit, is regulated at the level of transcription. The structure of the rRNA transcription unit and of the RNA polymerases responsible for transcription in Acanthamoeba are reviewed. Utilizing an in vitro transcription system constructed from these components, preliminary evidence has been obtained that pre-rRNA gene expression is regulated by a modification of RNA polymerase I that affects the enzyme's ability to participate efficiently in the initiation of transcription. These results are reviewed in relation to other known mechanisms of transcriptional regulation in eukaryotes.

Coordinate regulation of synthesis of ribosomal proteins during encystation of Acanthamoeba castellanii

The synthesis of ribosomal proteins has been examined during growth and encystment of Acanthamoeba castellanii. Cells have been radiolabelled with [35S]methionine and ribosomal proteins have been extracted either from ribosomes or from total cell extracts. The results show that there is less synthesis of ribosomal proteins relative to total cell proteins soon after transfer of growing cells into non-nutrient medium, suggesting that the synthesis of all ribosomal proteins is under coordinate control. Furthermore, synthesis of ribosomal RNA and ribosomal proteins seems to be regulated coordinately, since within 1 h there is 70-80% decline in synthesis of both. Translation of total RNA in vitro indicates that the relative decrease in the synthesis of ribosomal proteins during development is not only due to a relative decrease in the content of ribosomal protein mRNA. However, a considerable (about 10-fold) and coordinate decrease in the relative content of ribosomal protein mRNA occurs during encystment. These data suggest a difference in the control of the synthesis of total proteins and ribosomal proteins as well as in the regulation of the content of total mRNA and ribosomal protein mRNA. The comparison of patterns of ribosomal proteins indicates that during development no qualitative changes occur. The content of one protein of the small ribosomal subunit is low in growing cells and increases during encystation. Since the differences in the concentration of this protein are neither due to changing levels of the corresponding mRNA nor to changing rates of synthesis, changing affinities of this protein to ribosomes in vivo are suggested.

Ribosomal ribonucleic acid repeat unit of Acanthamoeba castellanii: cloning and restriction endonuclease map

The repeat unit coding for the precursor to 18S, 5.8S, and 26S ribosomal ribonucleic acids (rRNAs) has been cloned from the free-living soil amoeba Acanthamoeba castellanii. The cloned deoxyribonucleic acid (DNA) was mapped with 11 restriction endonucleases and by R-loop mapping. The entire repeat unit is 12 kbp (kilobase pairs) in length and contains sites for EcoRI, SmaI, BglII, SstI, Bam-HI, PstI, KpnI, HindIII, and XbaI but not for XhoI or SalI. All of the repeat units in the nuclear DNA appear to be identical, and no introns were detected. However, the regions which code for the two RNAs which comprise the 26S RNA are separated by a gap of approximately 200 base pairs. Unlike some other lower eukaryotes, the 5S RNA gene is not linked to this repeat unit. A fragment of the repeat unit which contains the initiation sequence of the putative precursor has been subcloned into pBR322 for use in vitro transcription studies.

DNA-dependent RNA polymerases from Acanthamoeba castellanii. Multiple forms of the class III enzyme and levels of activity of the polymerase classes during encystment

Multiple forms of class III DNA-dependent RNA polymerase have been found in a number of higher eukaryotic cells types (Chambon, P. (1975) Annu. Rev. Biochem. 44, 613--638). Similar multiple forms are reported here from a lower eukaryote, the soil amoeba Acanthamoeba castellanii. The levels of activity of all three RNA polymerase classes in whole cell extracts of Acanthamoeba during cellular differentiation were examined. In contrast to our previous observation (Detke, S. and Paule, M.R. (1975) Biochim. Biophys. Acta 383, 67--77) that the amount of the alpha-amanitin-sensitive polymerases (II + III) increase in the nucleus during encystment we find that the amount of polymerases II and III when solubilized from whole cells remains constant. The level of activity of polymerase I, however, remains constant both in nuclei and in whole cell extracts. Thus, the shutdown of ribosomal RNA synthesis occurring during encystment is not due to a decrease in the number of polymerase I molecules in the cell.

DNA-dependent RNA polymerases from Acanthamoeba castellanii: properties and levels of activity during encystment

Three DNA-dependent RNA polymerases have been isolated and partially purified from trophozoites of Acanthamoeba castellanii. Separated by DEAE-Sephadex chromatography, they have been designated polymerases, I, IIa and IIB according to their alpha-amanitin sensitivity and kinetic properties. I is completely insensitive to alpha-amanitin. IIa and IIb are sensitive to low concentrations (0.1 mug/ml) of alpha-amanitin; however, in order to achieve 100% inhibition much higher concentrations (130 mug/ml) are needed. Both I and II (a or b) have rather broad ionic strength optima (0.06--0.10 M (NH4)2SO4). All three prefer denatured over native DNA (I, 4:1; II, 2:1). Polymerase I utilizes magnesium better than manganese as divalent cation whereas II prefers manganese. When Acanthamoeba is transferred to a medium lacking nutrients, the cells undergo a synchronous differentiation resulting in cyst formation. In general agreement with the decrease in the rate of synthesis of its product (rRNA), the amount of polymerase I decreases relative to the amanitin sensitive polymerase(s). However, the absolute amount of polymerase I does not change. Rather, the levels of the amanitin sensitive enzymes increase during the first 10 h of encystment. Since the overall RNA synthesis rate decreases, these results suggest that the transcription rate is not controlled by specific enzyme levels alone.

Changes in transfer ribonucleic acids accompanying encystment in Acanthamoeba castellanii

Transfer ribonucleic acid (tRNA) from exponentially growing cells (trophozoites) and from precysts of Acanthamoeba castellanii were examined by reversed-phase column (RPC-2) chromatography. This system gave excellent resolution of isoaccepting species of tRNA. The tRNAs for 12 amino acids were studied. A comparison of trophozoite and precyst tRNA elution profiles revealed no apparent differences in the number of isoaccepting species of alanyl-, arginyl-, asparaginyl-, glycyl-, leucyl-, lysyl-, methionyl-, phenylalanyl-, tryptophanyl-, or valyl-tRNAs. Seryl-tRNAs from trophozoites were eluted as three components, whereas precyst seryl-tRNAs were eluted as only two components. Precharged trophozoite and precyst isoleucyl-tRNAs were both eluted as single components; however, post-chromatography charging of trophozoite tRNA resulted in three components of activity for tRNA(Ile) and only one component for precyst tRNA(Ile). None of the observed changes could be attributed to differences in synthetases or to the presence of altered tRNA lacking the CCA terminus or partially degraded by nucleases. The possible significance of these observations is discussed.