Vasopressin and isoproterenol activate adenylate cyclase in the guinea pig inner ear

Cochleas from guinea pigs were perfused by isotonic buffer after punction of the carotid artery. The cochlea tissue was removed from the bony capsule and separated from the mediolus as band with a sharp needle under the microscope. Cell membranes were prepared subsequently from whole tissue. Purified membranes from the inner ear of guinea pigs contain adenylate cyclase which functionally is coupled with membrane receptors for vasopressin and beta-receptors for isoproterenol (epinephrine), respectively. Both hormones stimulate production of cyclic AMP at 37 degrees C. Furthermore, cyclase activity is increased by addition of Gpp (NH)p, a GTP analog. Possible relationships of these molecular events to cochlear events such as glycogenolysis, ionfluxes, transport and secretion mechanisms, and synaptic transmissions are discussed.

[Experimental acceleration of fracture repair by biochemical media (author's transl)]

The influence of calcitonine, amino acids, ribonucleid acids, kallikrein, growth hormone, and cyclic adenosine 3'5' monophosphate on fracture repair was tested in rabbits. To obtain an objective measurement of callus stability the bones were bent mechanically. The force applied and the degree of bending were recorded continuously. The slope of the curve was taken as a parameter of callus stability. In the series with calcitonine no influence on fracture healing was found. Injections of ribonucleic acids, amino acids, kallidrein, and growth hormone demonstrated a limited effect on bone repair. Callus formation was stimulated by adenosine 3'5' monophosphate. Optimal results were achieved by a combination of adenosine 3'5' monophosphate, amino acids, ribonucleic acids, and kallikrein.

[Hormone receptors and hormone action (author's transl)]

All hormones act only on their target tissues. The ability of a tissue to react to a hormone is due to the presence of a receptor in or at the cell. There are two classes of hormone receptors: those bound to the membrane and those present in the cytosol. Peptide hormones generally act through membrane receptors. The interaction of a hormone with its receptors leads to an activation of the adenylate cyclase and the production of cyclo-AMP, the second messenger. In cases where several hormones act on the same tissue (example: adipose tissue) they must interact with their specific receptors, but presumably with the same adenylate cyclase. This interaction is discussed. The receptors for steroid hormones are not membrane-bound, but present in the cytosol. They are specific proteins which bind the hormone rather tightly. This results in a change in protein conformation, sometimes accompanied by a dimerization; the modified receptor is then transferred to the cell nucleus where it stimulates transcription. The control mechanisms of transcription are discussed; the most probable mode of action is removal of a repressor or repressor-like component from chromatin which results in deinhibition of transcription. mRNA is then produced and translated into protein. Post-transcriptional controls have been postulated, but never unequivocally demonstrated.

[Topochemistry of hormone action]

The site of hormone action is the cells of target tissues. Now that ultrastructural research has revealed the complexity of eukaryotic cells, we must ask which cellular structures are involved. Some hormones act at the cell membrane, mainly via adenylate cyclase and the "second messenger" cAMP. The cytosol and the mitochondria, the main sites of intermediate metabolism and enzyme activity, are apparently not involved, although in the past interaction of hormones with enzymes has been postulated. Most of the steroid hormones act at the level of the cell nucleus, regulating transcription of specific genes and inducing enzymes or other proteins. The mechanisms by means of which this regulation is achieved are not fully understood, but it is likely that derepression is involved. The active agent seems to be a complex of the hormone with a receptor protein.