Claire Robinson scite author profile

The major physiological function of milk is the transport of amino acids, carbohydrates, lipids and minerals to mammalian offspring. Caseins, the major milk proteins, are secreted in the form of a micelle consisting of protein and calcium-phosphate.We have analysed the role of the milk protein α-casein by inactivating the corresponding gene in mice. Absence of α-casein protein significantly curtails secretion of other milk proteins and calcium-phosphate, suggesting a role for α-casein in the establishment of casein micelles. In contrast, secretion of albumin, which is not synthesized in the mammary epithelium, into milk is not reduced. The absence of α-casein also significantly inhibits transcription of the other casein genes. α-Casein deficiency severely delays pup growth during lactation and results in a life-long body size reduction compared to control animals, but has only transient effects on physical and behavioural development of the pups. The data support a critical role for α-casein in casein micelle assembly. The results also confirm lactation as a critical window of metabolic programming and suggest milk protein concentration as a decisive factor in determining adult body weight.

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Recombinase mediated cassette exchange into genomic targets using an adenovirus vector

Sorrell

Robinson

Smith

et al. 2010

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Recombinase mediated cassette exchange (RMCE) is a process in which site-specific recombinases exchange one gene cassette flanked by a pair of incompatible target sites for another cassette flanked by an identical pair of sites. Typically one cassette is present in the host genome, whereas the other gene cassette is introduced into the host cell by chemical or biological means. We show here that the frequency of cassette exchange is dependent on the relative and absolute quantities of the transgene cassette and the recombinase. We were able to successfully modify genomic targets not only by electroporation or chemically mediated gene transfer but also by using an adenovirus vector carrying both the transgene cassette to be inserted and the recombinase coding region. RMCE proceeds efficiently in cells in which the adenovirus vector is able to replicate. In contrast, insufficient quantities of the transgene cassette are produced in cells in which the virus cannot replicate. Additional transfection of the transgene cassette significantly enhances the RMCE frequency. This demonstrates that an RMCE system in the context of a viral vector allows the site directed insertion of a transgene into a defined genomic site.

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Circulating human factor IX produced in keratin promoter transgenic mice: a feasibility study for gene therapy of haemophilia B

Alexander¹,

Bidichandani²,

Cousins³

et al. 1995

Hum Mol Genet

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It has previously been suggested that keratinocytes might provide a suitable target cell for delivery of factor IX to the systemic circulation for gene therapy of haemophilia B. Here, an investigation of the use of cellular gene promoters specific for keratinocytes was undertaken to examine whether factor IX could be passed from the epidermis to the systemic circulation. Utilizing two bovine cytokeratin gene promoters, BKIII and BKVI, three lines of transgenic mice were generated with targeted expression of human factor IX in the epidermis. All three transgenic mouse lines secreted epidermally derived human factor IX into the blood system. Most effective factor IX expression (46 ng/ml steady-state levels of circulating human factor IX) was obtained utilizing the BKVI gene promoter, the human homologue of K10, which is expressed exclusively in differentiated keratinocytes, localized distal to the basement membrane. This report demonstrates, for the first time, that human factor IX can be efficiently synthesized and secreted from keratinocytes in situ, and can cross the epidermal basement membrane to reach the systemic circulation. The transgenic mouse model will provide a good in vivo system with which to optimize the efficiency of different keratin gene promoter constructs for delivery of therapeutic gene products to the serum, especially for those promoters, such as K10, which are not effectively expressed in vitro.

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Regulation of genes encoding proteolytic enzymes during mammary gland development

Sorrell¹,

Szymanowska²,

Boutinaud³

et al. 2005

Journal of Dairy Research

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The mammary gland undergoes extensive tissue remodelling during each lactation cycle. During pregnancy, the epithelial compartment of the gland is vastly expanded (Benaud et al. 1998). At the end of lactation the epithelial cells undergo apoptosis and adipocyte differentiation is induced (Lilla et al. 2002). Ductal and alveolar growth during puberty and pregnancy, and the involution process require the action of proteolytic enzymes (including matrix metalloproteinases, plasminogen and membrane-peptidases) and the corresponding genes are activated during these periods (Benaud et al. 1998; Alexander et al. 2001). Matrix metalloproteinases (MMP) are expressed in several cell types of the mammary gland including stromal fibroblasts (e.g., MMP3, MMP2), epithelial cells (e.g., MMP7 or MMP9), adipocytes (e.g., MMP2) and lymphoid cells (e.g., MMP9) (Crawford et al. 1996; Lund et al. 1996; Wiseman et al. 2003). A number of knock-out mice, which are deficient for individual MMP genes (e.g., MMP2, MMP3) or plasminogen, display alterations to mammary gland structure and impairment of lactation (Lund et al. 1999; Wiseman et al. 2003).

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Claire Robinson

Milk Lacking α-Casein Leads to Permanent Reduction in Body Size in Mice

Recombinase mediated cassette exchange into genomic targets using an adenovirus vector

Circulating human factor IX produced in keratin promoter transgenic mice: a feasibility study for gene therapy of haemophilia B

Regulation of genes encoding proteolytic enzymes during mammary gland development

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