Anne Dam Jensen

Directed evolution of gene-shuffled IFN-α molecules with activity profiles tailored for treatment of chronic viral diseases

Type I IFNs are unusually pleiotropic cytokines that bind to a single heterodimeric receptor and have potent antiviral, antiproliferative, and immune modulatory activities. The diverse effects of the type I IFNs are of differential therapeutic importance; in cancer therapy, an enhanced antiproliferative effect may be beneficial, whereas in the therapy of viral infections (such as hepatitis B and hepatitis C), the antiproliferative effects lead to dose limiting bone marrow suppression. Studies have shown that various members of the natural IFN-α family and engineered variants, such as IFN-con1, vary in the ratios between various IFN-mediated cellular activities. We used DNA shuffling to explore and confirm the hypothesis that one could simultaneously increase the antiviral and Th1-inducing activity and decrease the antiproliferative activity. We report IFN-α hybrids wherein the ratio of antiviral:antiproliferative and Th1-inducing: antiproliferative potencies are markedly increased with respsect to IFN-con1 (75- and 80-fold, respectively). A four-residue motif that overlaps with the IFNAR1 binding site and is derived by cross breeding with a pseudogene contributes significantly to this phenotype. These IFN-αs have an activity profile that may result in an improved therapeutic index and, consequently, better clinical efficacy for the treatment of chronic viral diseases such as hepatitis B virus, human papilloma virus, HIV, or chronic hepatitis C.

Typical Danish Caucasian type 2 diabetic patients do not commonly carry genetic variants in GIP and GLP-1 encoding regions of the proGIP and proglucagon genes

BACKGROUND The enteroinsular-axis is abnormal in type 2 diabetics, which contributes to the diabetic phenotype. The effect of the incretin hormone gastric inhibitory polypeptide (GIP) and the secretion of the incretin hormone glucagon-like peptide-1 (GLP-1) are thus greatly diminished. The explanation for these changes could be changes in the structure of either of the hormones or their receptors. Thus, the aim of this study was to study the occurrence of genetic variants in the GIP and GLP-1 encoding regions of the proGIP and proglucagon genes in type 2 diabetic patients and matched control subjects. METHODS AND RESULTS Genomic DNA was extracted from buffy coats from 12 Caucasian type 2 diabetics and 12 healthy subjects, matched with respect to sex, age and BMI. The GIP and GLP-1 sequences were amplified using specific primers using the polymerase chain reaction (PCR). The amplified products were then sequenced. No germ-line mutations were identified in the GIP and the GLP-1 encoding regions of the proGIP and proglucagon genes in either the type 2 diabetic or the control subjects. CONCLUSIONS The perturbed incretin effect in type 2 diabetics is not commonly caused by genetic variants in either the GIP or the GLP-1 encoding genes in type 2 diabetics.