An Acanthamoeba ubiquitin-fusion protein; cDNA and deduced protein sequence

Cellular characterization of actin gene concerned with contact-dependent mechanisms in Naegleria fowleri

Free-living amoeba, Naegleria fowleri, destroys target cells through contact-dependent mechanisms, such as phagocytosis and/or trogocytosis. A previous experiment showed that the nf-actin gene consisted of 1.2 kbp, produced a 50.1 kDa recombinant protein (Nf-actin), and was localized on the cytoskeleton, pseudopodia and amoebastome. In this study, cellular characterization of the nf-actin gene concerned with contact-dependent mechanisms in N fowleri was performed. The nf-actin gene was amplified from a gene-cloned vector, pEXQP5-T7/NT TOPO. The nf-actin gene was introduced into the Ubi-pEGFP-C2 vector, and Ubi-pEGFP-C2/nf-actin was transfected into N fowleri trophozoites. Strong GFP fluorescence was detected in N fowleri trophozoites transfected with Ubi-pEGFP-C2/nf-actin. Expression of EGFP-Nf-actin protein was detected by Western blot analysis. The nf-actin-overexpressing N fowleri showed significantly increased adhesion activity against extracellular matrix components, fibronectin, collagen I and fibrinogen, compared with wild-type N fowleri. Moreover, nf-actin-overexpressing N fowleri showed increased phagocytic activity and cytotoxicity in comparison with wild-type N fowleri. In summary, the overexpressed nf-actin gene has an important function in ability to increase cell adhesion, cytotoxicity and phagocytosis by N fowleri.

Ubiquitin genes in rainbow trout (Oncorhynchus mykiss)

Ubiquitin is a small protein involved in intracellular proteolysis. It is highly conserved throughout eukaryotic phyla and has been detected in such diverse species as yeast, barley, Drosophila and man. A previous study showed that chromatin of rainbow trout testis contains free ubiquitin with a sequence similar to that of other phyla. In the present study, which focused on rainbow trout but included eleven other species, it is shown that fish ubiquitin genetic organisation and expression are similar to those of other phylogenetic groups through the following set of observations: (a) Multiple loci were detected, (b) These loci encode repeats of ubiquitin, (c) Although the DNA sequences are not conserved, the encoded amino acid sequences are fully conserved, (d) The expression of ubiquitin was influenced by cell culture conditions and viral infection.

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.

Transcription by RNA polymerase II during Acanthamoeba differentiation

The rates of transcription of several protein coding genes during Acanthamoeba differentiation have been examined by nuclear run-on and RNase protection assays. During early encystment, transcription by RNA polymerase II increases approximately 4-fold, whereas transcription by RNA polymerases I and III is decreased, as previously described. The rates of transcription from a wide variety of individual genes are only slightly affected during the first 16 h of encystment, although profilin gene expression is markedly increased. The levels of mRNAs encoding TPBF, TATA binding protein, cyclin-dependent kinase, protein disulfide isomerase, profilin, myosin II heavy chain, ubiquitin and extendin are stable during mature cyst formation, whereas mRNAs encoding actin, S-adenosyl methionine synthase and tubulin are substantially decreased in abundance within 16 h of starvation-induced encystment. We conclude that in contrast to the negative regulation of large rRNA and 5S rRNA synthesis during differentiation, the RNA polymerase II transcription apparatus is not negatively regulated. Control of Acanthamoeba differentiation is likely to be mediated by positive regulation of genes necessary for cyst maturation.

Structure and expression of a cyst specific protein of Acanthamoeba castellanii

The life cycle of Acanthamoeba is divided into a growth-division phase and two distinctive processes of cellular differentiation, termed encystment and excystment. Polyacrylamide gel electrophoresis revealed that a specific protein of 21 kDa in molecular weight occurs in the cyst, but not in the trophozoite stages of A. castellanii Neff strain. This cyst-specific protein, designated as CSP21, was purified from guanidine-HCl extract of cyst wall and anti-CSP21 antibody was produced. Immunoblotting of proteins extracted from a variety of species of Acanthamoeba genus suggested that the antibody is specific for group II amoebae, therefore, providing a useful tool for Acanthamoebae taxonomy. A cDNA clone for A. castellanii CSP21 was isolated by immunoscreening of a cDNA expression library constructed from mRNA of amoebae at encysting stage. The deduced primary structure indicated that CSP21 is a hydrophilic protein showing no significant homology with peptides thus far published. RNA blot analysis showed that the expression of CSP21 mRNA was restricted within early stages of encystment, suggesting that the biosynthesis of CSP21 is regulated at mRNA level.

Nucleotide sequence and developmental expression of Acanthamoeba S-adenosylmethionine synthetase gene

We have isolated and characterized a cDNA (cDNA1) from an Acanthamoeba cDNA library encoding the enzyme S-adenosylmethionine (SAM) synthetase (ATP: L-methionine S-adenosyltransferase; EC 2.5.1.6). The nucleotide sequence exhibits about 61-73% overall similarity to the corresponding gene of other organisms. The cDNA displays extreme codon bias with a preference for C or G in the third position. A putative initiation site and an ATP-binding site are identified. An amino acid content of 388 and a molecular mass of about 44,000 Daltons are deduced for the enzyme. Putative phosphorylation sites which might be involved in regulation of the enzyme are revealed. The cDNA was expressed in Escherichia coli BL21(DE3), and the identity of the protein product confirmed by Western blotting analysis. Northern analyses of the expression of the Acanthamoeba SAM synthetase gene during development revealed a pronounced reduction in the level of transcripts as amoebae converted to cysts.

An Acanthamoeba polyubiquitin gene and application of its promoter to the establishment of a transient transfection system

We have isolated and sequenced a 2388 bp polyubiquitin encoding genomic DNA from Acanthamoeba encompassing two complete and one incomplete ubiquitin units. Codon usage frequency shows extreme bias. The deduced amino acid sequences of each unit are identical to each other and the same as that deduced from a previously sequenced Acanthamoeba castellanii cDNA. The upstream region of this gene, which contained some putative regulatory modules, was recovered by PCR (polymerase chain reaction) amplification and subcloning. This upstream fragment was ligated to the CAT (chloramphenicol acetyltransferase) gene in a eukaryotic expression plasmid and successfully applied to the establishment of an Acanthamoeba transient transfection system. Transfection was performed by electroporation and the optimal voltage was 4500 volts/cm at capacitance 25 microF. DEAE-dextran (25 microg/ml) added into the electroporation buffer increased the transfection efficiency by about 45%. The CAT activity was proportional to the amount of DNA transfected and reached the peak level 48 h after transfection. CAT assays showed that the polyubiquitin gene upstream fragment contains a functional promoter which is about 2.5 times as strong as a viral RSV-LTR promoter when driving CAT expression in Acanthamoeba.

Stable transfection of Acanthamoeba

The promoter activity of an Acanthamoeba polyubiquitin gene was analyzed in its homologous system. A modified calcium phosphate transfection method using a neomycin marker vector was developed to achieve highly efficient transfection of the Acanthamoeba polyubiquitin gene into Acanthamoeba cells. In this transfection procedure, the calcium phosphate-DNA complex was formed gradually in the medium during incubation with cells and precipitated on the cells. The crucial factors for obtaining efficient transfection were the pH (6.95) of the transfection buffer used for the calcium phosphate precipitation and the amount (25 micrograms/96-well tissue culture plate) and form (circular) of transfecting DNA. Under these conditions, Acanthamoeba isolate 1B6 was transfected at an efficiency of about 40% with the constructed vector pOPSBU, a pOP13CAT-based polyubiquitin gene incorporated neomycin resistance vector. Acanthamoeba polyphaga was transfected at an efficiency of about 10% with this vector. Transfection of both Acanthamoeba strains appeared to result in low copy plasmid integration (about two copies per cell are suggested). The chloramphenicol acetyltransferase (CAT) assays showed that the promoter of the Acanthamoeba polyubiquitin gene in the constructed vector was especially strong in A. polyphaga, thus the pOPSBU-Acanthamoeba system may be useful for the construction of cDNA expression libraries, as well as for the expression of cloned genes.