Inhibition of gene expression in Entamoeba histolytica with antisense peptide nucleic acid oligomers.

Peptide nucleic acids (PNAs) may be a potent tool for gene function studies in medically important parasitic organisms, especially those that have not before been accessible to molecular genetic knockout approaches. One such organism is Entamoeba histolytica, the causative agent of amebiasis, which infects about 500 million people and is the cause of clinical disease in over 40 million each year, mainly in the tropical and subtropical world. We used PNA antisense oligomers to inhibit expression of an episomally expressed gene (neomycin phosphorotransferase, NPT) and a chromosomal gene (EhErd2, a homolog of Erd2, a marker of the Golgi system in eukaryotic cells) in axenically cultured trophozoites of E. histolytica. Measurement of NPT enzyme activity and EhErd2 protein levels, as well as measurement of cellular proliferation, revealed specific decreases in expression of the target genes, and concomitant inhibition of cell growth, in trophozoites treated with micromolar concentrations of unmodified antisense PNA oligomers.

Entamoeba histolytica contains a gene encoding a homologue to the 54 kDa subunit of the signal recognition particle.

We have determined the nucleotide sequence and predicted amino acid sequence of the 54 kDa subunit of the signal recognition particle (SRP54) from the amitochondrial protist Entamoeba histolytica. The SRP54 gene was isolated from a genomic library using a polymerase chain reaction (PCR) probe. Nucleotide sequence analysis of a 2.3 kb fragment, derived from a 7 kb genomic clone, revealed an open reading frame encoding a protein of 487 amino acids (MW 53.8 kDa). The identities of the predicted amino acid sequence with its homologues from other species were between 24 and 47%. Functional domains previously defined for the SRP54-type proteins were present in the entamoebal sequence, such as the amino-terminal GTP binding domain (G domain) and the carboxy-terminal methionine rich domain (M domain). SRP54 mRNA contains an extra G residue at the 5' end, suggesting that capping of poly-A(+) transcripts is present in E. histolytica. Evolutionary analysis of the SRP54 based on phylogenetic inference placed the E. histolytica sequence as an early divergence of the eukaryotic tree. Although the function of the entamoebal homologue remains to be elucidated, the identification of the SRP54 gene constitutes the first evidence for SRP related proteins in protozoans.

Identification and analysis of the u6 small nuclear RNA gene from Entamoeba histolytica.

Among the small nuclear RNAs (snRNAs) involved in the spliceosomal processing of pre-mRNA, U6 is the most conserved. As a first evidence for the presence of the splicing machinery in the amitochondrial protozoan Entamoeba histolytica (Eh), we have cloned the u6 snRNA gene. We find that in this organism u6 is a single copy gene that is transcribed as a poly(A)- RNA molecule of approximately 105 nucleotides. We have mapped the 5' end of the U6 snRNA transcript, and identified typical elements of a putative polymerase III promoter. This is the first snRNA gene reported in Eh. Sequence analysis indicates that this gene contains all the conserved nucleotides known to be important for U6 snRNA function. These results, in conjunction with the earlier finding of genes that contain pre-mRNA introns, suggest that Eh has a functional spliceosomal complex.

Role of zinc-binding- and hemopexin domain-encoded sequences in the substrate specificity of collagenase and stromelysin-2 as revealed by chimeric proteins.

The relationship of enzyme structure to substrate specificity for the matrix metalloproteinases interstitial collagenase and stromelysin-2 has been investigated by analysis of the cleavage specificity of recombinant human collagenase-stromelysin-2 hybrid proteins and C terminally truncated collagenase and stromelysin-2. Two series of chimeric proteins were devised by progressive substitution of exon-encoded domains. The recombinant proteins were expressed in COS-7 cells as protein A-fusion proteins and purified on an IgG affinity matrix. Treatment with 4-amino-phenylmercuric acetate released active metalloproteinase of the sizes predicted for the chimeric proteins. Active forms of both the chimeric protein series and the short form enzymes expressed both casein- and gelatin-degrading activities. Like stromelysin, the catalytic activity of stromelysin-2 was contained in the N-terminal domain (encoded by exons 1-5) and was apparently independent of the C-terminal domain (encoded by exons 6-10). Only full-length collagenase displayed a triple helicase (collagenolytic) activity; no combination of N- or C-terminal collagenase domains fused with stromelysin-2 domains had such activity. This suggests that the triple helicase activity is a composite of elements derived from both halves of the collagenase molecule. C terminally truncated collagenase (exons 1-5) and a hybrid of collagenase exons 1-5 and stromelysin-2 exons 6-10 cleaved denatured type I collagen (gelatin) to generate diagnostic peptides in gelatin fingerprint assays. When exon 5 (the exon encoding the zinc-binding domain) was derived from stromelysin-2, the enzyme specificity in the fingerprint assay changed to that of native stromelysin-2. In contrast, when exon 5 was derived from collagenase, the specificity reflected that of the parent enzyme. Our data also suggest that mismatching of exons 2 and 5 destabilizes the enzyme, presumably by altering the geometry of the propeptide-zinc-binding site interaction. We conclude that the loss of triple helicase collagenolytic activity is not accompanied by a shift to the broad specificity characteristic of stromelysin. Rather, the zinc-binding domain confers a distinct cleavage specificity on each metalloproteinase.

A transferrin-independent iron uptake activity in Plasmodium falciparum-infected and uninfected erythrocytes.

Non-heme iron is essential for the asexual growth of the human malaria parasite Plasmodium falciparum in mature erythrocytes. Utilization of iron bound to serum transferrin by the parasitized cells has been postulated, but direct evidence for its specific delivery has not been reported. Here we demonstrate that normal levels of transferrin in human serum are not required for intraerythrocytic P. falciparum growth: culture medium immunodepleted 500-1000 fold in human transferrin was capable of supporting parasitemias and rates of invasion comparable to those observed in non-depleted medium. 55Fe bound to transferrin was not taken up by infected cells. A transferrin-independent non-heme iron uptake activity was, however, detected in both infected and uninfected erythrocytes when iron was presented to the cells as 55Fe-NTA or 55Fe-citrate. Although the uptake activity was not parasite specific, the radiolabel was found in association with parasites mechanically released from the infected erythrocytes, indicating that it is delivered to the intracellular organism. Evidence is presented that the transferrin-independent iron uptake activity is time-, temperature- and concentration-dependent, but apparently not energy-dependent.

Structure-function relationships in the collagenase family member transin.

We have developed a system for studying the proteinase activity of a collagenase family member, transin. Cos cells transfected with a vector designed to direct synthesis of a secretable fusion protein between staphylococcal protein A and transin secrete a latent proteinase, activable by 4-aminophenylmercuric acetate, which binds to IgG-Sepharose. Treatment with 4-aminophenylmercuric acetate leads to cleavage of the fusion protein and elution of the active proteinase transin. Based on results obtained with this system we propose that transin comprises an N-terminal proteinase domain and an independent C-terminal hemopexin-like domain. The latter domain is not required for binding of inhibitors or for maintenance of transin in its inactive form. The sequence PRCGVPDV is present in the proenzyme forms of collagenase family proteinases just upstream from the N termini of the active enzymes. We show that mutations within this sequence lead to transin variants with a much increased tendency to undergo spontaneous activation. Finally, we show that mutations within a region of transin having sequence similarity to the zinc-binding site of bacterial metalloproteinases inactivate the proteinase activity of transin, lending support to the notion that this region represents part of transin's active site.