We describe here a semi-permeabilized cell-system which reconstitutes the efficient synthesis, translocation, folding, assembly and degradation of membrane and secretory proteins. Cells grown in culture were treated with the detergent digitonin which selectively permeabilized the plasma membrane leaving the cellular organelles, such as the endoplasmic reticulum (ER) and trans-Golgi network intact. These permeabilized cells were added to an in vitro translation system, either wheatgerm or reticulocyte lysate, supplemented with RNA coding for either membrane or secretory proteins. Efficient translocation and modification of proteins by these cells was demonstrated by protease protection, photocross-linking of nascent chains to components of the translocation apparatus and by post-translational modifications such as glycosylation or hydroxylation. A comparison was made between the ability of semi-permeabilized cells and microsomal vesicles to fold and assemble proteins. The results show that the intact ER within these cells can assemble proteins much more efficiently than vesicularized ER. Furthermore, the semi-permeabilized cells carried out the redox-dependent degradation of tissue-type plasminogen activator. This system has all the advantages of conventional cell-free systems, including speed and, importantly, the ability to manipulate the components of the assay, while retaining intracellular organelles and, therefore, allowing cellular processes to occur as they would in the intact cell.
Identification of microbial community members in complex environmental samples is time consuming and repetitive. Here, ribosomal sequences and hidden Markov models are used in a novel approach to rapidly assign fungi to their presumptive genera. The ITS1 and ITS2 fragments from a range of axenic, anaerobic gut fungal cultures, including several type strains, were isolated and the RNA secondary structures predicted for these sequences were used to generate a fingerprinting program. The methodology was then tested and the algorithms improved using a collection of environmentally derived sequences, providing a rapid indicator of the fungal diversity and numbers of novel sequence groups within the environmental sample from which they were derived. While the methodology was developed to assist in investigations involving the rumen ecosystem, it has potential generic application in studying diversity and population dynamics in other microbial ecosystems.
The gut fungi are an unusual group of zoosporic fungi occupying a unique ecological niche, the anaerobic environment of the rumen. They exhibit two basic forms, with nuclear migration throughout the hyphal mass for polycentric species and with concentration of nuclear material in a zoosporangium for monocentric species. Differentiation between isolates of these fungi is difficult using conventional techniques. In this study, DNA-based methodologies were used to examine the relationships within and between two genera of monocentric gut fungi gathered from various geographical locations and host animals. The ribosomal ITS1 sequence from 16 mono-and 4 polycentric isolates was PCR-amplified and sequenced ; the sequences obtained were aligned with published sequences and phylogenetic analyses were performed. These analyses clearly differentiate between the two genera and reflect the previously published physiological conclusions that Neocallimastix spp. constitute a more closely related genus than the relatively divergent genus Piromyces. The analyses place two type species N. frontalis and N. hurleyensis together but, contrary to a recent suggestion in the literature, place them apart from the other agreed species N. patriciarum. In situ hybridization and slot-blotting were investigated as potential methods for detection of and differentiation between monocentric gut fungi. DNA slot-blot analysis using ribosomal sequences is able to differentiate between gut fungal genera and thus has considerable potential for use in ecological studies of these organisms.
A glucoamylase ::green fluorescent protein fusion (GLA ::sGFP) was constructed which allows the green fluorescent protein to be used as an in vivo reporter of protein secretion in Aspergillus niger. Two secretory fusions were designed for secretion of GLA ::sGFP which employed slightly different lengths of the glucoamylase protein (GLA499 and GLA514). Expression of GLA ::sGFP revealed that fluorescence was localized in the hyphal cell walls and septa, and that fluorescence was most intense at hyphal apices. Extracellular GLA ::sGFP was detectable by Western blotting only in the supernatant of young cultures grown in soya milk medium. In older cultures, acidification of the medium and induction of proteases were probably responsible for the loss of extracellular and cell wall fluorescence and the inability to detect GLA ::sGFP by Western analysis. A strain containing the GLA : :sGFP construct was subjected to UV mutagenesis and survivors screened for mutations in the general secretory pathway. Three mutants were isolated that were unable to form a halo on either starch or gelatin medium. All three mutants grew poorly compared to the parental strain. Fluorescence microscopy revealed that for two of the mutants, GLA ::sGFP accumulated intracellularly with no evidence of wall fluorescence, whereas for the third mutant, wall fluorescence was observed with no evidence of intracellular accumulation. These results indicate that the GLA ::sGFP fusion constructs can be used as convenient fluorescent markers to study the dynamics of protein secretion in vivo and as a tool in the isolation of mutants in the general secretory pathway.
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