Negative control glucose dependent mediated by the PreS2 region on the translation efficiency of the reporter Sh-bleomycin gene in Saccharomyces cerevisiae

Saccharomyces cerevisiae is able to sense and respond to environmental changes such as the availability of carbon sources. In a previous work, we showed that the expression of the PreS2-S gene of HBV in yeast was negatively regulated at the translational level dependent of glucose. In this study, we show that the S mRNA is detected in the polysomes indicating its active translation, while the PreS2-S mRNA was mainly found in monosomes. Moreover, we used the gene reporter assay based on Zeocin resistance, to better characterize the PreS2 region responsible for this control. Two chimeric genes composed of the N- and C-terminal part of the PreS2 fused to the Sh-bleomycin gene conferring the resistance to Zeocin were expressed in yeast. We found that the strain expressing the N-terminal part of the PreS2 was sensitive to Zeocin on rich medium with 2% glucose. In contrast, the strain harbouring the C-terminal part of the PreS2 fused to the Sh-bleomycin grew on Zeocin, indicating that the Sh-bleomycin mRNA is efficiently translated, subsequently conferring resistance to Zeocin. Our data suggest the establishment of a translational control via the N-terminal part of the PreS2 mediated by the presence of 2% glucose in the media.

Yeasts as a tool for heterologous gene expression

The yeasts Saccharomyces cerevisiae and Pichia pastoris are attractive hosts for production of human proteins. The main advantages offered by these systems are the well-developed and easily accessible genetic tools, rapid growth, the simple and inexpensive culture media, and many of the cellular and metabolic processes found in higher eukaryotes are conserved in both yeast species. In this chapter, we describe the production of two proteins of therapeutic interest: the human P53 tumor suppressor and the viral HBsAg in P. pastoris and S. cerevisiae using the strong and inducible promoters AOX1 and Gal10/Cyc1, respectively. Besides the production as a goal of both expressions, we also report on an unexpected result that has occurred in S. cerevisiae: The overexpression of human p53 induces yeast cell death with characteristic markers of apoptosis, such as the externalization of phosphatidylserines and DNA strand cleavage.

Glucose dependent [correction of dependant] negative translational control of the heterologous expression of the preS2 HBV antigen in yeast

In the present study, we have compared the expression level of the genes encoding the viral Hepatitis B S and preS2 using two different yeast vectors, a constitutive one (YepIPT) and a galactose-inducible one (YepDP1-8). We showed that the S and preS2 mRNAs were present in equivalent amounts in both systems, while the corresponding proteins showed a different pattern. The S and preS2 proteins were efficiently produced after galactose induction. However, under the constitutive promoter, the S protein was synthesized at the same level in presence of 2% glucose or galactose whereas the preS2 protein was efficiently synthesized on galactose but absent on 2% glucose. The substitution of glucose by non-repressive carbon sources such as 2% galactose, ethanol or glycerol led to a significant expression of preS2. A high level of preS2 expression was also achieved by lowering the glucose concentration. Our data suggest that glucose exerts a concentration dependent negative translational control on the preS2 mRNA.

Genotyping of Tunisian hepatitis B virus isolates based on the sequencing of preS2 and S regions

The S nucleotide sequences of five hepatitis B virus strains isolated from plasma samples of Tunisian patients with chronic hepatitis B were determined; the preS2 region of three of them were sequenced. According to the comparative analysis of S peptide sequences with the reported sequences in the database bank, the five hepatitis B strains were shown to be related to the D genotypic group, subtype ayw. The nature of residues at positions 125 and 127 allowed us to distinguish between each subtype of the D group and to class all five Tunisian sequences in the 'ayw2' subtype. Moreover, two of them (1366 and 523) contained a substitution of the invariant Cys69 by Arg and Cys221 by Phe, respectively. Potential structural modifications due to the Cys-Arg change are discussed.