Expression and secretion of a lytic polysaccharide monooxygenase by a fast-growing cyanobacterium.

BACKGROUND: Cyanobacteria have the potential to become next-generation cell factories due to their ability to use CO2, light and inorganic nutrients to produce a range of biomolecules of commercial interest. Synechococcus elongatus UTEX 2973, in particular, is a fast-growing, genetically tractable, cyanobacterium that has garnered attention as a potential biotechnological chassis. To establish this unique strain as a host for heterologous protein production, we aimed to demonstrate expression and secretion of the industrially relevant TfAA10A, a lytic polysaccharide monooxygenase from the Gram-positive bacterium Thermobifida fusca. RESULTS: Two variations of TfAA10A were successfully expressed in S. elongatus UTEX 2973: One containing the native N-terminal, Sec-targeted, signal peptide and a second with a Tat-targeted signal peptide from the Escherichia coli trimethylamine-N-oxide reductase (TorA). Although the TorA signal peptide correctly targeted the protein to the plasma membrane, the majority of the TorA-TfAA10A was found unprocessed in the plasma membrane with a small fraction of the mature protein ultimately translocated to the periplasm. The native Sec signal peptide allowed for efficient secretion of TfAA10A into the medium with virtually no protein being found in the cytosol, plasma membrane or periplasm. TfAA10A was demonstrated to be correctly cleaved and active on the model substrate phosphoric acid swollen cellulose. Additionally, expression and secretion only had a minor impact on cell growth. The secretion yield was estimated at 779 ± 40 µg L-1 based on densitometric analysis. To our knowledge, this is the highest secretion yield ever registered in cyanobacteria. CONCLUSIONS: We have shown for the first time high-titer expression and secretion of an industrially relevant and catalytically active enzyme in S. elongatus UTEX 2973. This proof-of-concept study will be valuable for the development of novel and sustainable applications in the fields of bioremediation and biocatalysis.

The involvement of demethylation in the myeloid-specific function of the mouse M lysozyme gene downstream enhancer.

Lysozyme gene expression is a specific marker for the macrophage/granulocyte lineage of hematopoietic differentiation in mammals, its expression being gradually increased during maturation. Analysis of the mechanisms regulating mouse M lysozyme gene expression during myeloid differentiation revealed a complicated pattern of DNase I hypersensitive sites (HS sites) within the flanking regions of the gene. The HS-3 site, located in the 3'-flanking region of the gene, overlapped with an enhancer element, which is the only strong enhancer identified in the vicinity of the gene. We demonstrate a positive correlation between undermethylation of the entire 3'-flanking region, the appearance of the HS-3 site, and M lysozyme gene expression during in vitro differentiation of hematopoietic stem cells. We furthermore show that methylation of a single CpG site within the enhancer core element, only observed in immature macrophage cells in vivo, is sufficient to inhibit nuclear factor binding to this element in vitro and to inhibit its transactivation potential in DNA transfection experiments.

The mouse M-lysozyme gene domain: identification of myeloid and differentiation specific DNasel hypersensitive sites and of a 3'-cis acting regulatory element.

The mouse M-lysozyme gene is exclusively expressed in myeloid cells of the blood system being progressively turned on upon cell differentiation. In this study the mechanism controlling this tissue- and differentiation stage-specific gene expression was analyzed at the level of chromatin structure. A complex pattern consisting of constitutive and differentiation dependent DNasel hypersensitive sites (HSs) was found in a set of various myeloid cell lines, representing different stages of maturity. The chromatin of a lymphoid cell line, which does not express the lysozyme gene, is completely insensitive to DNasel digestion. Chromatin analysis of two multipotent hematopoietic stem cell lines which can be differentiated in vitro to mature myeloid cells confirmed that these identified DNasel HSs are specific for distinct differentiation stages, rather than being a characteristic feature of the cell lines. Additionally, the stem cell studies revealed that the hypersensitivity of the chromatin domain is already established at the multipotent stage. DNA fragments spanning a cell type- and differentiation stage-specific cluster of HSs in the 3' region of the gene showed enhancer activity in all cell types tested. In the light of this lack of specificity, we suggest that cell type-specific modification of the chromatin structure in this region may play a role in determining the binding of a widespread transcription factor, and hence contribute to the time specificity of lysozyme M gene expression.