Different molecular forms of circulating prolactin (PRL) are known to occur in several species. As no such information was available in dogs, we assessed the molecular profile of circulating PRL in bitches. Pooled sera from covertly (CTRL) and overtly pseudopregnant (PSPT) diestrous bitches with high or low (> 10 or < 10 ng x mL(-1), respectively) serum PRL (measured by ELISA) were analyzed by Sephadex G-100 and Concanavalin A-Sepharose column chromatography. Four serum PRL fractions were identified and termed big-big, big (> 67 kDa), native (23 kDa) and fragmented (< 20) kDa) PRL. The percentages of these fractions were roughly similar in CTRL and PSPT animals, irrespective of their serum PRL levels (higher in PSPT than in CTRL bitches). A large proportion of glycosylated PRL (between 69 and 100%) was also detected in these sera. We conclude that in dogs, circulating PRL occurs in multiple molecular forms, whose relative abundance is comparable in covertly and overtly pseudopregnant bitches.

Isolation of glycosylated 26 kDa rat prolactin and subsequent proper carbohydrate characterization has so far not been reported. In the present work the hormone isoform was isolated to 95% homogeneity by preparative electrophoretic separation on Mini Prep Cell of rat pituitary homogenate. The isoform was then investigated by 2-mercaptoethanol gradient electrophoresis, Cleveland's sequential SDS-PAGE, digestion with endoproteinase Asp-N and N-glycanase. The glycosidic part of the isoform was examined in O-profiling and its monosaccharide composition obtained by FACE and HPAE-PAD analysis. The outcome of the experimental data is: 1) in contrast to unglycosylated 23 kDa rat prolactin, intra-chain S-S bridging is not affected in 26kDa rat prolactin, neither by transiting through a thiol gradient nor in sequential nonreducing/reducing SDS-PAGE; 2) the conformational availability of Asp residues involved in the endoproteinase Asp-N attack is the same in 23- and 26 kDa rat prolactin; the glycan moiety apparently does not cause steric hindrance at this level; 3) no glycosidic N-linkage could be detected, only O-linkage(s); 4) 26 kDa rat prolactin is no glycosyl-phosphaditylinositol-anchored protein; 5) in O-profiling an oligosaccharide chain of Mr +/- 1.4 kDa was recorded; 6) the monosaccharide composition obtained in FACE is peculiar in the sense that next to Fuc, Man, GalNac, GlcNac and NeuAc also Rib was determined; 7) HPAE-PAD analysis identified NeuAc subtypes; 8) in vitro, glycosylation of rat prolactin modulates immune recognition through steric hindrance of the access to the epitope sites.

Milk is primarily regarded as a food furnishing essential nutrients for infant growth and development, but milk can also serve as a vehicle for mother to neonate transfer of molecules that regulate development. A wide array of biologically active compounds such as hormones, cytokines and enzymes are present in milk, especially early milk. The premise that prolactin (PRL) in milk is an important and possibly essential developmental factor for the newborn is explored. Both PRL and structurally modified isoforms are abundant in early milk and gradually diminish with the progression of lactation. Milk PRL is absorbed and biologically active in the neonate. Assays of PRL variants, experimental paradigms to test them as developmental regulators and the body of evidence supporting the hypothesis that milk PRL regulates differentiation and maturation of neonatal neuroendocrine, reproductive, and immune systems is presented.

It has previously been suggested that the mammary cell could produce prolactin (PRL). This hypothesis was investigated by incubation with [35S]methionine-cysteine followed by SDS-PAGE, immunoblotting and autoradiography of immunoprecipitated PRL, and by electron microscopic analysis after incubation without or with cycloheximide. Immunoreactive 14-, 23-, 25-, 32- and 36-kDa PRL forms were radioactive. By two-dimensional electrophoresis analysis, immunoreactive and radioactive spots, of about 25 kDa and high molecular weight, were also detected. After incubation of mammary epithelial cells with cycloheximide, immunogold electron microscopy showed a drastic decrease of labelling in organelles involved in synthesis and secretion, compared to those incubated in control medium. These results make it possible to conclude that lactating mammary tissue is able to synthesize PRL.

To study the localization of PRL in mammary epithelial cells (MEC) and to characterize PRL forms in serum, milk, and mammary tissue, two groups of lactating rats, a control group and a bromocriptine-treated group, were compared. In serum and milk from control rats, two forms of PRL (25 and 23 kDa) were detected by immunoblotting. In bromocriptine-treated rats, only the 25-kDa form was present. In mammary tissues from control rats, 25-, 23-, and 14-kDa forms of the hormone were detectable, whereas only 25- and 14-kDa forms were present in bromocriptine-treated rats. Immunofluorescence and immunogold electron microscopy revealed that in MEC from control rats, PRL was located in the organelles involved in endocytosis and was also present in rough endoplasmic reticulum, Golgi apparatus, secretory vesicles, and lumen of the acini. In bromocriptine-treated rats, a decrease in the labeling was evidenced in endosomes and multivesicular bodies. On the contrary, labeling associated with the rough endoplasmic reticulum and secretory vesicles was increased. Thus, even when the amount of circulating PRL detected by RIA was strongly decreased, PRL was always detectable in MEC and in the lumen of the acini, suggesting an active participation of MEC in the transport of PRL to milk.

Glycosylated equine prolactin (G-ePRL) and nonglycosylated ePRL were purified to homogeneity from side fractions obtained during isolation of LH/FSH from horse pituitaries. Both PRL forms were isolated together in high yield by the isolation procedure used for glycosylated porcine PRL/(G-pPRL) and pPRL, involving acetone extraction/precipitation, NaCl and isoelectric precipitation, and gel filtration. Purification of G-ePRL required additional Con A chromatography. The N-terminal amino acid sequencing for 32 cycles of G-ePRL and ePRL resulted in sequences identical to the known primary structure of ePRL. Based on MALDI mass spectrometry analysis and SDS-PAGE mobilities, G-ePRL and ePRL had estimated molecular weights of 25,000 and 23,000 Da, respectively. G-ePRL displayed only 60% of the immunoreactivity of ePRL in homologous radioimmunoassay. Using the Nb2 lymphoma cell bioassay, ePRL was found to have about 1/30th the mitogenic activity of bovine PRL; G-ePRL was approximately 1/10th as active as ePRL. Glycosylation of G-ePRL at Asn31 was confirmed by isolation and sequence analysis of an enzymatically derived G-ePRL glycopeptide spanning residues 29-37. Monosaccharide compositions of intact G-ePRL and this glycopeptide were very similar (Man3, GlcNAc2, GalNAc1, Fuc0.6, Gal0.2, NeuAc0.15) and resembled that of G-pPRL. The glycopeptide contained one sulfate residue as determined by ion chromatography after acid hydrolysis, indicating the presence of a sulfated monosaccharide. Comparative carbohydrate analysis of G-ePRL and other G-PRL preparations suggests that the functionally significant Asn31 carbohydrate unit is a fucosylated complex mono- and /or biantennary oligosaccharide terminating with a sulfated GalNAc residue and two or three Man residues.

Rat pituitary homogenates were submitted to differential and density gradient centrifugation. Subcellular fractions as well as the purified secretory granules were examined in electron microscopy, radioimmunological techniques, protease digestion, alkaline treatment and immunoblotting. The global outcome of these experiments was that: 1) the glycosylated rPRL was foremost recorded in the crude secretory granular fraction, also in the microsomal fraction and the cytosol, but virtually not in the plasma membrane fraction; 2) in purified secretory granules glycosylated rPRL appeared as an array of near Mr, such as was formerly obtained by enzymatic deglycosylation; 3) protease digestion and ice-cold alkaline treatment of the secretory granules showed that 23,000 rPRL appears in three different physicochemical states in these organelles: unsequestered within a closed system, membrane-bounded and bound state; 4) likewise treatment of microsomal vesicles showed that 23,000 and glycosylated rPRL are sequestered in these bodies, but apparently 23,000 rPRL appears as both integral membrane-bound and released from the lumen, whereas glycosylated rPRL is chiefly retained as an integral membrane protein. 5) dopamine alters the pattern of glycosylation as well in Mr as in relative percentages of the molecular variants. The systematical occurrence of the array of near Mr glycosylated rPRL is biosynthesized as a pool of proteins with a different degree of glycosylation. On the basis of our data, we speculate that selection of definite molecular variants from this pool could play an important role in the biological function of 23,000 rPRL and that oligosaccharides could perhaps target the glycosylated forms of rPRL to specific sites of action.