[Prolactin and its cleaved 16 kDa fragment]. / La prolactine et son fragment 16 kDa dans les tissus de mammifères.

Prolactin, owing to its origins, actions and molecular forms, is an ubiquitous and pleiotropic hormone. Indeed prolactin, initially thought to be essentially synthesized in the hypophysis, is also produced by several tissues in mammals. It is involved in more than 300 different biological activities, such as reproduction, developmental immunity and behaviour. It is also described under several molecular forms resulting from co- or post-translational modifications and enzymatic cleavage. Among these, the 16 kDa form, derived from native prolactin, has received particular attention because of its inhibitory effect on angiogenesis. Recent results have suggested an important role of tissue enzymes in the production of this form in several tissues (retina, myocardium and mammary gland). The cleavage leading to the production of 16 kDa prolactin may occur outside the cells, in the interstitial medium and therefore in the vicinity of blood capillaries. This process implies tissue-specific mechanisms of regulation. A better knowledge of the location of the cleavage and of the regulation of these activities of the cleaving enzymes is now essential for controlling the processes. This knowledge will allow a better understanding of the relationships between some pathologies (cardiomyopathy, pre-eclampsia, retinopathy) and modification of the production of the anti-angiogenic form of prolactin.

Endocytic prolactin routes to the secretory pathway in lactating mammary epithelial cells.

Plasma-borne prolactin is carried from blood to milk by transcytosis across the mammary epithelial cell through the endocytic and secretory pathways. To determine the precise route of prolactin endocytosis, intracellular transport of biotinylated prolactin was monitored, in parallel with endocytosis of fluorescein isothiocyanate-conjugated dextran and IgG, by using pulse-chase experiments in lactating mammary fragments and in enzymatically dissociated acini. Biotinylated prolactin was sorted to vesiculo-tubular organelles whereas dextran was very rapidly carried to the lumen and IgG remained accumulated in the basal region of cells. To determine whether prolactin uses routes into and across the Golgi and trans-Golgi network, localisation of biotinylated prolactin was combined with the immunofluorescence detection of caseins and, respectively, p58 and TGN38. Biotinylated prolactin strongly colocalised with caseins during a chase but not all or only very little with p58 and TGN38. To characterise the organelles involved in transcytosis, gold-labelled prolactin, experimentally accumulated in late endosomes and which recovered a normal transport, was localised by electron microscopy. In mammary fragments incubated at low temperature, and in mammary fragments from rats fed with a lipid-deprived diet, transport of gold-labelled prolactin was restored by increasing the temperature and by adding arachidonic acid, respectively. These data demonstrate that a sorting occurs very rapidly between prolactin, dextran and IgG. They suggest that prolactin may reach the biosynthetic pathway after direct fusion between multivesicular bodies and secretory vesicles.