Plk1-mediated phosphorylation of UAP56 regulates the stability of UAP56.

Polo-like kinase 1 (Plk1) is a conserved serine/threonine protein kinase that plays pivotal roles during the cell cycle and cell proliferation. Although a number of important targets have been identified, the mechanism of Plk1-regulated pathways and the bulk of the Plk1 interactome are largely unknown. Here, we demonstrate that Plk1 interacts with the DExH/D RNA helicase, UAP56. The protein levels of UAP56 and Plk1 are inversely correlated during the cell cycle. We also show that Plk1 phosphorylates UAP56 in vitro and in vivo and that Plk1-dependent phosphorylation of UAP56 triggers ubiquitination and degradation of UAP56 through proteasomes. This result suggests that Plk1-mediated phosphorylation of UAP56 regulates the stability of UAP56. Our results will be helpful in further understanding mRNA metabolism, cell cycle progression, and the link between mRNA metabolism and cellular function.

A mWAP-hLF hybrid gene locus gave extremely high level expression of human lactoferrin in the milk of transgenic mice.

The production of pharmaceuticals by current mammary gland bioreactor techniques is limited by the low expression level of foreign proteins. We describe here a novel method that solves this problem. A successive three-step gap-repair strategy was developed to replace the genomic coding sequence in mouse whey acidic protein (mWAP) gene locus with that of human lactoferrin (hLF) precisely from the start code to the end code. A 50-kb mWAP-hLF hybrid gene locus was constructed, and corresponding transgenic mice were generated. An extremely high-level expression of rhLF in the milk was demonstrated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot. The expression level ranged from 16.7 to 29.8 g/l among five transgenic lines, as indicated by the ELISA assay. Importantly, the expressed rhLF maintained the same antibacterial activity as the native hLF. Our strategy can very likely also be used for the efficient expression of other valuable pharmaceutical proteins.

[A successive three-step 'Gap-repair' method to generate the mWAP-hLF hybrid gene locus].

To generate a mWAP-hLF hybrid locus that the transcription of human lactoferrin (hLF) genomic sequence is directed by the up & down stream regulatory sequence of murine whey acidic protein (mWAP) gene locus, we describe here a successive three-step 'Gap-repair' method. First, a gap-repair vector based on pBR322 vector backbone by inserting six joint homologous arms was constructed. Then using 'Gap-repair 'method mediated by Red recombination system of lambda-prophage in Escherichia coli, in the first step, the 8 kb 3' flanking region of the mWAP gene was subcloned from the Bacterial artificial chromosome which harbors the mWAP gene locus(mWAP BAC) into the gap-repair vector; in the second step, the 29 kb hLF genomic sequence from the ATG code to the TAA code was subcloned from the hLF BAC; in the third step, the 12 kb 5' flanking region of the mWAP gene was subcloned from the mWAP BAC. Finally, all these three DNA fragments were automatically combined together without any gap in the gap-repair vector, and a 49 kb mWAP-hLF hybrid locus that the hLF genomic sequence was flanked by the 5' & 3' flanking region of mWAP gene locus was constructed. The result was confirmed by PCR, restriction enzyme digestion and sequencing. Our method provide a new way for the construction of large mammary-gland expression vector.