DNA-dependent RNA polymerase III from Acanthamoeba castellanii: comparison of the catalytic properties of the trophozoite and cyst enzymes

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.

Nucleic acids of Entamoeba histolytica

This review will concentrate on certain aspects of the nucleic acids of Entamoeba histolytica. Utilization and synthesis of purines and pyrimidines will initially be briefly discussed, e.g. salvage vs. de novo pathways, uptake studies and recognition of at least 4 transport loci. Data will be presented which show that the distribution and synthesis of RNA (to a lesser extent DNA) in the nucleus is basically the opposite one finds in other eukaryotes, viz. most RNA (ribosomal?) is synthesized (or accumulates) in the peripheral chromatin (functional equivalent of nucleolus?). The DNA is distributed and synthesized primarily throughout the nucleus. It is usually so dispersed that it will not stain with e.g. the standard Feulgen technique, unless the DNA condenses around the endosome (not a nucleolar equivalent) prior to nuclear division. Isolation of rRNA was difficult due, in part, to potent and difficult to inhibit RNase(s), some of which are apparently intimately bound to ribosomal subunits. The 25S (1.3 kDa), 17S (0.8 kDa) and 5S rRNA were recovered after isolation with a high salt SDS-DEP technique. This is the only procedure which enables us to obtain high yields of 25S rRNA; guanidine or guanidinium which permits isolation of intact functional mRNA results in isolation of small amounts of 25S RNA relative to 17S RNA. The 25S RNA is "nicked" (apparently during nuclear processing) and dissociates readily into 17S (0.7 kDa) and 16S (0.6 kDa) species, and a more rigidly bound 5.8S species. A small amount of "unnicked" 25S RNA was recovered with guanidine.(ABSTRACT TRUNCATED AT 250 WORDS)

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.