A major prolactin-binding complex on human milk fat globule membranes contains cyclophilins A and B: the complex is not the prolactin receptor.

Prolactin (PRL) in milk influences maturation of gastrointestinal epithelium and development of both the hypothalamo-pituitary and immune systems of offspring. Here, we demonstrate that most PRL in human milk is part of a novel, high-affinity, multicomponent binding complex found on the milk fat globule membrane and not in whey. To examine properties of the complex, a sensitive ELISA was developed such that human PRL (hPRL) binding to the complex was measured by loss of hPRL detectability; thus, as much as 50 ng of hPRL was undetectable in the presence of 10 µl of human milk. Using the same methodology, no comparable complex formation was observed with human serum or amniotic fluid. hPRL complexation in milk was rapid, time dependent, and cooperative. Antibodies to or competitors of the hPRL receptor (placental lactogen and growth hormone) showed the hPRL receptor was not involved in the complex. However, hPRL complexation was antagonized by cyclosporine A and anti-cyclophilins. The complex was very stable, resisting dissociation in SDS, urea, and dithiothreitol. Western analysis revealed an ∼75-kDa complex that included hPRL, cyclophilins A and B, and a 16-kDa cyclophilin A. Compared with noncomplexed hPRL, complexed hPRL in whole milk showed similar activation of STAT5 but markedly delayed activation of ERK. Alteration of signaling suggests that complex formation may alter hPRL biological activity. This is the first report of a unique, multicomponent, high-capacity milk fat reservoir of hPRL; all other analyses of milk PRL have utilized defatted milk.

Distribution of prolactin receptors suggests an intraductal role for prolactin in the mouse and human mammary gland, a finding supported by analysis of signaling in polarized monolayer cultures.

Despite the important role of prolactin (PRL) in mammary gland development and function, little is known about the distribution of the different forms of the prolactin receptor (PRLR) under various physiological circumstances. Here, the distribution of the long (LF) and the short (S3 in mouse) receptor common to both mice and rats was determined by immunofluorescence on frozen sections of virgin, pregnant and lactating mouse mammary gland. Myoepithelial cells were consistently and intensely stained for both receptors. For luminal cells at all stages (ducts and alveoli), a large proportion of PRLR staining was unexpectedly present on the apical face. In the non-lactating state, no basal staining of luminal cells was detectable. During lactation, a proportion of both receptors moved to the basolateral surface. In vitro, HC11 cells showed constitutive expression of LF but expression of S3 only upon the formation of adherent junctions. Tight junction formation was accelerated by incubation in pseudo-phosphorylated PRL, as measured by transepithelial resistance and the expression and placement of the tight junction protein, zonula occludens-1. Once an intact monolayer had formed, all LF and S3 receptors were apical (akin to the non-lactating state) and only apical application of PRL activated the Jak2-STAT5 and ERK pathways. By contrast, basolateral application of PRL resulted in a reduction in basal ERK phosphorylation, suggesting an involvement of a dual specificity protein phosphatase. Normal human breast samples also showed apical PRLRs. These results demonstrate important contextual aspects of PRL-PRLR interactions with implications for the analysis of the role of PRL in breast cancer.

A molecular mimic of phosphorylated prolactin (S179D PRL) secreted by eukaryotic cells has a conformation with an increased positive surface charge compared to that of unmodified prolactin.

S179D prolactin (S179D PRL) is a pseudophosphorylated form of human PRL which has potent antitumor and anti-angiogenic activities in vivo. This molecule binds to the same forms of the PRL receptor (PRLR) as unmodified PRL, yet this binding results in different intracellular signaling and biological end points. Since it is now clear that PRLRs are predimerized and therefore that ligand binding must initiate signaling by inducing a conformational change in the receptor dimer, we hypothesized that S179D PRL had an altered conformation compared to unmodified PRL. The conformation of the ligand-receptor ternary complex would therefore also have an altered conformation, and thus, different signaling molecules would be activated. Here we present evidence in support of this hypothesis by demonstrating, in contrast to unmodified PRL, that S179D PRL has reduced nickel and zinc binding capacity and a higher affinity for heparin and DEAE. Conformational changes have occurred since these features are counterintuitive on the basis of the simple substitution of a serine with a negatively charged aspartate residue. To demonstrate that these particular properties of S179D PRL were not due to misfolding of the molecule during production, S179D PRL was expressed in two different mammalian cell lines. Also investigated was the potential for production of S179D PRL as a soluble cytoplasmic, or secreted periplasmic, protein in Escherichia coli.

S179D prolactin primarily uses the extrinsic pathway and mitogen-activated protein kinase signaling to induce apoptosis in human endothelial cells.

We have demonstrated that S179D prolactin (PRL) is potently antiangiogenic in vivo. Here, we examined apoptosis in human endothelial cells, using procaspase-8 and cytochrome c release as markers of the extrinsic and intrinsic pathways, respectively. Both pathways converge at caspase-3, which is responsible for cleavage of DNA fragmentation factor (DFF45). A 3-d incubation in 50 ng/ml S179D PRL quadrupled the number of early apoptotic cells; this effect was doubled at 100 ng/ml and became maximal at 500 ng/ml. DFF45 and procaspase 8 cleavage were detectable at 100 ng/ml. Cytochrome c, however, was unaffected until 500 ng/ml. The p21 increased at 24 h, whereas a change in p53 required both triple the time and higher doses. The p21 promoter activity was maximal at 50 ng/ml, whereas 500 ng/ml were required to see a significant change in the Bax promoter (a measure of p53 activity). Because S179D PRL and basic fibroblast growth factor (bFGF) have both been shown to activate ERK, the effect of S179D PRL on bFGF-induced ERK signaling was examined. S179D PRL blocked ERK phosphorylation in response to bFGF, whereas continued coincubation caused a delayed and prolonged activation of ERK. PD98059 inhibited this delayed activation of ERK and effects of S179D PRL on all measures except p53 levels or activity of the Bax promoter. We conclude that S179D PRL blocks bFGF-induced ERK signaling and yet uses ERK in a different time frame to elevate p21 and activate the extrinsic pathway. Prolonged incubations and high concentrations additionally activate the intrinsic pathway using an alternate intracellular signal.

Time course proteomic profiling of human myocardial infarction plasma samples: an approach to new biomarker discovery.

BACKGROUND: The aim of this study was to identify novel candidate biomarker proteins differentially expressed in the plasma of patients with early stage acute myocardial infarction (AMI) using SELDI-TOF-MS as a high throughput screening technology. METHODS: Ten individuals with recent acute ischemic-type chest pain (<12 h duration) and ST-segment elevation AMI (1STEMI) and after a second AMI (2STEMI) were selected. Blood samples were drawn at six times after STEMI diagnosis. The first stage (T0) was in Emergency Unit before receiving any medication, the second was just after primary angioplasty (T2), and the next four stages occurred at 12 h intervals after T0. Individuals (n=7) with similar risk factors for cardiovascular disease and normal ergometric test were selected as a control group (CG). Plasma proteomic profiling analysis was performed using the top-down (i.e. intact proteins) SELDI-TOF-MS, after processing in a Multiple Affinity Removal Spin Cartridge System (Agilent). RESULTS: Compared with the CG, the 1STEMI group exhibited 510 differentially expressed protein peaks in the first 48 h after the AMI (p<0.05). The 2STEMI group, had ~85% fewer differently expressed protein peaks than those without previous history of AMI (76, p<0.05). Among the 16 differentially-regulated protein peaks common to both STEMI cohorts (compared with the CG at T0), 6 peaks were persistently down-regulated at more than one time-stage, and also were inversed correlated with serum protein markers (cTnI, CK and CKMB) during 48 h-period after IAM. CONCLUSIONS: Proteomic analysis by SELDI-TOF-MS technology combined with bioinformatics tools demonstrated differential expression during a 48 h time course suggests a potential role of some of these proteins as biomarkers for the very early stages of AMI, as well as for monitoring early cardiac ischemic recovery.

Periplasmic expression of human growth hormone via plasmid vectors containing the lambdaPL promoter: use of HPLC for product quantification.

The influence of different factors acting on Escherichia coli periplasmic expression of recombinant human growth hormone (hGH) in shake flask cultures has been investigated. Bacterial vectors containing the phage lambdaP(L) promoter, which is temperature activated, were utilized. Four different signal peptides were compared: DsbA, npr, STII and one derived from the natural hGH signal peptide, this last used as a reference. Other factors such as medium composition, optimized induction and expression conditions, and different bacterial strains were also studied. The determination of hGH, carried out directly in osmotic shock fluids, was based on an isocratic reversed-phase high-performance liquid chromatography method, which allows direct, rapid evaluation of the quality and quantity of hGH being secreted in the bacterial periplasmic space immediately after or even during fermentation. The level of hGH production increased 2.5-fold compared with the reference vector, reaching a level of 3.9 +/- 0.63 micro g/ml/A(600) (n = 6; coefficient of variation = 16.2%). The expression level was affected by the signal peptide and by the induction conditions, being more effective when activation started in the early logarithmic phase which, however, exhibited remarkably different optical density (OD) according to medium composition. Our results thus indicate that 6 h activation at 40-42 degrees C, starting with an OD (A(600)) of approximately 3 in a very rich medium, were conditions capable of providing the maximum secretion level for a vector utilizing the DsbA signal sequence and E.coli W3110 or RB791 as host cells.