Abstract: The present invention relates to DNA molecules which encode antagonists of vertebrate growth hormones obtained by mutation of at least the amino acid corresponding to Glu-119 in bovine growth hormone. The DNA molecules may be used to express the antagonists, either in cell culture, or in the cells of the patient of interest. The antagonist so expressed may be used to inhibit GH activity in a subject.

Abstract: The present invention relates to antagonists of vertebrate growth hormones obtained by mutation of the third alpha helix of such proteins (especially bovine or human GHs). These mutants-have growth-inhibitory or other GH-antagonizing effects. These novel hormones may be administered exogenously to animals, or transgenic animals may be made that express the antagonist. Animals have been made which exhibited a reduced growth phenotype. The invention also describes methods of treating acromegaly, gigantism, cancer, diabetes, vascular eye diseases (diabetic retinopathy, retinopathy of prematurity, age-related macular degeneration, retinopathy of sickle-cell anemia, etc.) as well as nephropathy and other diseases, by administering an effective amount of a growth hormone antagonist. The invention also provides pharmaceutical formulations comprising one or more growth hormone antagonists.

Abstract: The present invention relates to antagonists of vertebrate growth hormones obtained by mutation of the third alpha helix of such proteins (especially bovine or human GHs). These mutants have growth-inhibitory or other GH-antagonizing effects. These novel hormones may be administered exogenously to mammals. The antagonists may be used to reduce the activity of growth hormone in a mammal, especially one suffering from diabetes, diabetic retinopathy, diabetic nephropathy, a growth hormone secreting tumor, acromegaly, or gigantism.

Abstract: The present invention is directed to mammalian yolk sac stem cells. In particular, it relates to the characterization, culturing, long-term expansion and uses of yolk sac stem cells for in vivo reconstitution and therapy. Yolk sac stem cells isolated from the early embryonic yolk sac prior to blood island formation exhibit a homogeneous morphology and a primitive cell surface phenotype without the expression of mature leukocyte markers and major histocompatibility complex-encoded antigens. The cells can be cultured and expanded long-term with minimal differentiation, and without alteration of their pluripotency. However, such cells can be induced to express various blood cell markers upon stimulation with specific cytokines. In addition, the cells also express certain endothelial cell markers and growth characteristics. Such yolk sac cells may be particularly effective in the reconstitution of a lymphohematopoietic system, as they are capable of forming both endothelial cells and blood cells.