The Production of a Diabetic Mouse Using Constructs Encoding Porcine Insulin Promoter-Driven Mutant Human Hepatocyte Nuclear Factor-1.ALPHA

Hepatitis C virus regulates proprotein convertase subtilisin/kexin type 9 promoter activity

Proprotein convertase subtilisin/kexin type 9 (PCSK9) is a secretory serine protease mainly expressed in liver. Although PCSK9 has been shown to inhibit hepatitis C virus (HCV) entry and replication, whether HCV regulates PCSK9 transcription has not been well studied. PCSK9 promoter activity is modulated by numerous transcription factors including sterol-regulatory element binding protein (SREBP)-1a, -1c, -2, hepatocyte nuclear factor-1 (HNF-1), and forkhead box O3 (FoxO3). Since they are differently regulated by HCV, we studied the effects of these transcription factors on PCSK9 promoter activity in the context of HCV infection and replication. We demonstrated that PCSK9 promoter activity was up-regulated after HCV infection and in HCV genomic replicon cells. We also studied the effects of HCV proteins on the PCSK9 promoter activity. While HCV structural proteins core, E1, and E2 had no effect, NS2, NS3, NS3-4A, NS5A and NS5B enhanced, and p7 and NS4B decreased PCSK9 promoter activity. Furthermore, we showed that transcription factors SREBP-1c, HNF-1α and specificity protein 1 increased PCSK9 promoter activity in HCV replicon cells, whereas SREBP-1a, HNF-1β and FoxO3 had an inhibitory effect. These results demonstrated the molecular mechanisms of how HCV modulates PCSK9 promoter activity and advanced our understanding on the mutual interactions between HCV and PCSK9.

Diabetic phenotype of transgenic pigs introduced by dominant-negative mutant hepatocyte nuclear factor 1α

AIM

The present study aimed to identify the characteristics of genetically modified pigs carrying a mutant human gene as a research model for diabetes and its complications.

METHODS

We developed a transgenic cloned pig (founder, male) carrying a mutant gene, i.e., human HNF-1α (P291fsinsC), which is responsible for maturity-onset diabetes of the young type 3. Transgenic progeny obtained via the artificial insemination of wild type (WT) sows with the cryopreserved sperm derived from the founder pig was pathologically examined.

RESULTS

The transgenic progeny maintained a high blood glucose level (>200mg/dL). Additionally, the oral glucose tolerance test results showed that the recovery of blood glucose levels in the transgenic progeny was significantly delayed compared with that in the WT semi-siblings. Hypoplasia of the islets of Langerhans was confirmed by the histopathological image of the pancreas, based on the hyperglycemia noted in the progeny being ascribed to decreased insulin secretion. Retinal hemorrhage and cotton-wool spots, i.e., findings consistent with non-proliferative diabetic retinopathy, were detected, and these progressed over time. The histopathological image of the renal glomeruli showed a nodular lesion that is characteristic of diabetic nephropathy in humans.

CONCLUSIONS

These data demonstrated that the genetically modified pig that we developed is a promising model for research on diabetes and its complications.

Genetically modified pig models for human diseases

Genetically modified animal models are important for understanding the pathogenesis of human disease and developing therapeutic strategies. Although genetically modified mice have been widely used to model human diseases, some of these mouse models do not replicate important disease symptoms or pathology. Pigs are more similar to humans than mice in anatomy, physiology, and genome. Thus, pigs are considered to be better animal models to mimic some human diseases. This review describes genetically modified pigs that have been used to model various diseases including neurological, cardiovascular, and diabetic disorders. We also discuss the development in gene modification technology that can facilitate the generation of transgenic pig models for human diseases.

Characterization of the ICSI-mediated gene transfer method in the production of transgenic pigs

Understanding the behavior of transgenes introduced into oocytes or embryos is essential for evaluating the methodologies for transgenic animal production. We investigated the expression pattern of a transgene transferred to porcine eggs by intracytoplasmic sperm injection-mediated gene transfer (ICSI-MGT) or pronuclear microinjection (PN injection). The introduction of the EGFP gene by ICSI-MGT yielded significantly more embryos with non-mosaic transgene expression (P < 0.01). In the ICSI-MGT group, 61.5% (24/39) of the embryos were EGFP-positive in all their component blastomeres at the morula stage, while fewer than 10% of such embryos were EGFP-positive in the PN-injection group. Using three types of transgenes, ranging from 3.0 to 7.5 kb in size, we confirmed that approximately one in four fetuses obtained by ICSI-MGT was transgenic, suggesting that ICSI-MGT is a practical method for transgenic pig production. Southern blot analysis of 12 transgenic fetuses produced by ICSI-MGT revealed that the number of integrated transgene copies varied from 1 to 300, with no correlation between transgene size and the number of integrated copies. Fluorescence in situ hybridization analysis revealed that the transgenes were randomly integrated into a single site on the host chromosomes. Together, these data indicate that multiple-copy, single-site integration of a transgene is the primary outcome of ICSI-MGT in the pig and that ICSI-MGT is less likely than PN injection to cause transgene integration in a mosaic manner.

Specific transgene expression in mouse pancreatic beta-cells under the control of the porcine insulin promoter

The availability of regulatory sequences directing tissue-specific expression of transgenes in genetically modified mice and large animals is a prerequisite for the development of adequate models for human diseases. The rat insulin 2 gene (Ins2) promoter, widely used to achieve transgene expression in pancreatic beta-cells of mice, also directs expression to extrapancreatic tissues and performs poorly in isolated pancreatic islets of human, mouse, and pig. To evaluate whether the full 5' untranslated region (UTR) of the porcine insulin gene (INS) confers robust and specific expression in beta-cells we generated an expression cassette containing 1500bp of the porcine INS 5' UTR and the 3' UTR of the bovine growth hormone gene (GH). The cassette was designed to allow easy exchange of the sequences to be expressed and easy removal of the vector backbone from the expression cassette. To evaluate the properties of the cassette, we initially inserted a cDNA encoding human betacellulin, a growth factor known to affect structural and functional parameters of beta-cells. After confirming the functionality and specificity of the construct in vitro, transgenic mouse lines were generated by pronuclear DNA microinjection. Using RT-PCR, immunohistochemistry and immunofluorescence, we show that transgenic mice expressed human betacellulin exclusively in beta-cells. Confirming the proposed insulinotropic effect of betacellulin, transgenic mice showed improved glucose tolerance. We conclude that the newly designed expression cassette containing 1500bp of the porcine insulin promoter 5' UTR confers robust and specific transgene expression to beta-cells in vitro and in transgenic mice.

Dominant-negative mutant hepatocyte nuclear factor 1alpha induces diabetes in transgenic-cloned pigs

Pigs have been recognized as an excellent biomedical model for investigating a variety of human health issues. We developed genetically modified pigs that exhibit the apparent symptoms of diabetes. Transgenic cloned pigs carrying a mutant human hepatocyte nuclear factor 1alpha gene, which is known to cause the type 3 form of maturity-onset diabetes of the young, were produced using a combined technology of intracytoplasmic sperm injection-mediated gene transfer and somatic cell nuclear transfer. Although most of the 22 cloned offspring obtained died before weaning, four pigs that lived for 20-196 days were diagnosed as diabetes mellitus with nonfasting blood glucose levels greater than 200 mg/dl. Oral glucose tolerance test on a cloned pig also revealed a significant increase of blood glucose level after glucose loading. Histochemical analysis of pancreas tissue from the cloned pigs showed small and irregularly formed Langerhans Islets, in which poor insulin secretion was detected.