Study of hypothalamic leptin receptor expression in low-birth-weight piglets and effects of leptin supplementation on neonatal growth and development.

Low birth weight resulting from intrauterine growth retardation (IUGR) is a risk factor for further development of metabolic diseases. The pig appears to reproduce nearly all of the phenotypic pathological consequences of human IUGR and is likely to be more relevant than rodents in studies of neonatal development. In the present work, we characterized the model of low-birth-weight piglets with particular attention to the hypothalamic leptin-sensitive system, and we tested whether postnatal leptin supplementation can reverse the precocious signs of adverse metabolic programming. Our results demonstrated that 1) IUGR piglets present altered postnatal growth and increased adiposity; 2) IUGR piglets exhibit abnormal hypothalamic distribution of leptin receptors that may be linked to further disturbance in food-intake behavior; and 3) postnatal leptin administration can partially reverse the IUGR phenotype by correcting growth rate, body composition, and development of several organs involved in metabolic regulation. We conclude that IUGR may be characterized by altered leptin receptor distribution within the hypothalamic structures involved in metabolic regulation and that leptin supplementation can partially reverse the IUGR phenotype. These results open interesting therapeutic perspectives in physiopathology for the correction of defects observed in IUGR.

Leptin expression in the ovine mammary gland: putative sequential involvement of adipose, epithelial, and myoepithelial cells during pregnancy and lactation.

We examined the ability of the ovine mammary gland to synthesize leptin throughout pregnancy and lactation. Leptin gene expression was assayed by real-time reverse transcription and polymerase chain reaction in mammary gland from ewes at 15, 80, 106, 112, or 141 d of pregnancy and at 0 (30 min after parturition), 3, 48, or 70 d of lactation. Leptin mRNA level was high at the beginning (the first 80 d) and at the end of pregnancy and was lower at mid-pregnancy and throughout lactation. Furthermore, during these periods of mammary leptin expression, the location of leptin protein, as determined by immunohistochemical analysis, changed within mammary tissue. It was located in adipose cells during early stages of pregnancy, in epithelial cells after full cell differentiation just before parturition, and in myoepithelial cells after parturition. These data, compared with published data on leptin receptor gene expression, provide evidence that leptin could be produced by different cell types of the mammary gland and could act as a paracrine factor on mammary cell growth and differentiation via adipose-epithelial cells and myoepithelial-epithelial cell interactions.

Identification of leptin receptors in human breast cancer: functional activity in the T47-D breast cancer cell line.

To evaluate whether leptin plays a putative role in breast tumorigenesis, we studied the expression of its long and short receptor isoforms in various tumoral breast tissues. We applied semiquantitative RT-PCR method to RNA extracted from 20 breast cancer biopsies and two human breast cancer cell lines (T47-D and MCF-7). Our results showed the expression of both leptin receptor transcripts in all tumoral tissues examined. By in situ hybridization experiments, we localized leptin receptors in proliferating epithelial cells. Study of leptin effects on human breast cancer cells growth was performed by [3H]-thymidine incorporation method and colorimetric MTT assay. We demonstrated that leptin (50-100 ng/ml) significantly stimulates proliferation of the human breast cancer cell line T47-D (P<0.05). Western blot analysis indicated that leptin induces a time-dependent activation of mitogen-activated protein kinases (MAPKinase) 1 and 2 in T47-D cell line. Moreover, the specific MAPK-inhibitor PD 98059 blocked cell proliferation induced by leptin. In conclusion, we demonstrate that leptin receptors are expressed in breast cancer and that leptin induces proliferation in the T47-D cell line via activation of the MAPKinases pathway. These data suggest that leptin and its receptors may be implicated in mammary cell proliferation and in breast cancer pathogenesis.

Expression of BRCA1 gene in ewe mammary epithelial cells during pregnancy: regulation by growth hormone and steroid hormones.

OBJECTIVE: Steroid hormones (estradiol and progesterone) in association with prolactin and growth hormone are involved in lobulo alveolar development of the mammary gland during pregnancy. We hypothesized that the BRCA1 gene may be induced by these different hormones. METHODS AND RESULTS: In this study, we have demonstrated by Northern blot and in situ hybridization, that the expression of ovine (o) BRCA1 mRNA in mammary epithelial cells increased dramatically during a short period in the second half of pregnancy (days 70 to 112) and decreased at the end of pregnancy. The increase in oBRCA1 mRNA expression is concomitant with rapid lobulo alveolar growth. Using an in vivo protocol to artificially induce mammary gland development, we demonstrated by the real-time RT-PCR method that growth hormone in association with estrogen, progesterone and hydrocortisone induces an increase of BRCA1 mRNA expression in the ewe mammary gland. Moreover, we showed that estradiol and progesterone induce oBRCA1 expression in primary cultures of ewe mammary gland. CONCLUSIONS: These results suggest that BRCA1 is a potential regulator of the effects of steroid hormones and growth hormone in the induction of mammary epithelial cell proliferation.

Characterization and modulation of a prolactin receptor mRNA isoform in normal and tumoral human breast tissues.

The role of prolactin (PRL) and its specific receptor (R-PRL) in human breast tumorigenesis remains unclear. We have investigated here the presence of extracellular-deleted hPRL-R isoforms in normal human breast, fibrocystic disease, primary breast carcinoma (ductal carcinoma, ductulo-lobular and lobular) and breast cancer cell lines (T47-D and MCF-7). RT-PCR and Southern blot analysis demonstrated the expression of full-length hPRL-R transcript in all samples tested. We also detected a hPRL-R transcript generated by alternative exon 6 splicing. This isoform has a 170 bp deletion in its extracellular sub-domain that induces a frameshift. Thus, the predicted amino-acid sequence should encode a putative soluble protein with the N-terminal sub-domain of the hPRL-R and 10 additional carboxy-terminal residues. This isoform should not bind PRL as previously demonstrated by other experiments. Moreover, the ratio of full-length to deleted form of hPRL-R transcripts differs from normal to tumoral breast tissue. This ratio is higher in tumoral mammary gland than in normal tissue. Our data suggest that the alternative splicing of the hPRL-R gene towards the deleted transcript may be a mechanism to down- or up-regulate the expression of the native transcript of hPRL-R in accordance to the physiological or pathological state of the mammary gland.

Detection and regulation of leptin receptor mRNA in ovine mammary epithelial cells during pregnancy and lactation.

Adipocyte-epithelial cell interactions and their secretions are critical determinants of mammary gland development. In this present study, we examined the possible involvement of leptin and its receptors in the process of mammogenesis/lactogenesis. We demonstrated by reverse transcription and polymerase chain reaction analysis that long and short forms of leptin receptors were expressed in the ovine mammary gland during pregnancy and lactation. Furthermore, quantitative determinations, via ribonuclease protection assays, provided evidence that the level of leptin receptor expression was greatest during mid-pregnancy when active growth of the mammary gland is initiated. Location of the leptin receptors, as determined by in situ hybridization analysis, revealed that leptin receptor transcripts were expressed specifically in mammary epithelial cells. These data provide evidence that leptin, with its receptors, could be an important mediator in regulating mammary gland growth and development.

Cloning of rabbit prolactin cDNA and prolactin gene expression in the rabbit mammary gland.

cDNA clones coding for rabbit prolactin were isolated from a pituitary library using a rat prolactin RNA probe. One cDNA contained 873 bases including the entire coding sequence of rabbit prolactin, its signal peptide and the 5' and 3' untranslated regions of 44 and 145 nucleotides respectively. The deduced amino acid sequence of the cloned prolactin cDNA presented a 93-78% identity with mink, porcine and human prolactins. The prolactin gene transcription was investigated by RT-PCR analysis in several organs of midlactating New Zealand White rabbits. The ectopic transcription of the prolactin gene was examined in more detail in the mammary gland. A strong PCR signal was detected in the mammary gland of virgin does and was also observed during pregnancy and at the beginning of lactation. This PCR signal was very weak in mid-lactating and absent in post-weaning mammary gland.

Development of a constitutively active mutant form of the prolactin receptor, a member of the cytokine receptor family.

The extracellular domain of the PRL receptor (PRL-R) is composed of two subdomains of approximately 100 amino acids, S1 and S2. To explore the functional significance of these subdomains in PRL binding and signal transduction, deletion mutants of S1 or/and S2 subdomains were constructed. We report here the inability of each of these mutant receptor forms to bind PRL after expression in COS-7 cells. We also studied the abilities of these different mutant receptors to respond to hormonal stimulation after transfection of each mutant complementary DNA into CHO-K1 cells along with a chimeric gene containing the promoter of a milk protein gene (beta-lactoglobulin) fused to chloramphenicol acetyltransferase coding sequence. Somewhat unexpectedly, a constitutively (PRL-independent) mutant form of the PRL-R was obtained after deletion of the S2 subdomain. Moreover, we analyzed, in CHO-K1 cells, the biological activity of chimeric receptors constructs in which each subdomain sequence was replaced by an unrelated, but coding, sequence of foreign protein, and we confirmed a specific requirement for the S1 sequence in the constitutive activity. In contrast, the S2 subdomain produced an inhibitory effect on S1 constitutive activity. Cotransfection experiments with the wild-type receptor and the constitutive mutant receptor provided evidence that the wild-type receptor was able to inhibit the constitutive activity of the deleted mutant. Furthermore, in the mouse mammary epithelial cell line HC11, the constitutive PRL-R form was able to induce transcription of the beta-casein gene in the absence of PRL. These results suggest a complex signal transduction process that implicates each extracellular PRL-R subdomain. Possible mechanisms for the constitutive effect are discussed.

Subcellular localization of rev-gene product in visna virus-infected cells.

The 1.4-kb mRNA of visna lentivirus is expressed early during the lytic infection of sheep choroid plexus cell cultures. It encodes for visna early gene 1 (VEG1) product, since renamed rev gene product (or Rev), based on significant amino acid sequence homologies between this protein and the proteins of simian immunodeficiency virus of macaque and human immunodeficiency virus type 2. In this report, we examined the subcellular localization and time course appearance of the Rev protein in visna virus-infected cells. Immunoprecipitation assays of [35S]methionine-labeled cell lysates with antisera raised against the Rev protein revealed a polypeptide of 19 kDa (p19rev). This protein was predominant early in the viral replication cycle and accumulated preferentially in the cytoplasmic/membrane fraction of infected cells. Indirect immunofluorescence staining of infected cells confirmed the cytoplasmic location of visna Rev protein and could reveal in some stained cells a higher concentration of Rev at the cellular plasma membrane. The regulating protein, still present late in the viral lytic cycle, is packaged into mature viral particles along with the structural gag and env gene products.

[Neurotoxicity in mice due to cysteine-rich parts of visna virus and HIV-1 Tat proteins]. / Neurotoxicité chez la souris de portions riches en cystéines des protéines Tat du virus visna et de VIH-1.

The trans-activating visna virus and HIV-1 Tat proteins share, at their amino-acid sequence level, a significant 60% analogy on 17 consecutive residues. These homologous sequences are also found in a part of the short neurotoxin sequence from snake venom. Synthetic peptides representative of the two analogous viral sequences are, after intracerebroventricular injection at doses of 200 micrograms per 20 g mouse, responsible for the death of the injected animal in few hours. The HIV-1 recombinant Tat protein has the same effect. Such observation suggests a direct role of the Tat lentiviral protein in the origin of the neurologic effects associated with visna and HIV-1 infections.

The open reading frame S of visna virus genome is a trans-activating gene.

Soon after infection of ovine cell cultures, visna virus expression is first indicated by the accumulation of two multi-spliced transcripts of 1.2 and 1.6 kb that at present we have renamed 1.4 and 1.7 kb according to their exact length. The early 1.4-kb mRNA encodes for a protein which increases the level of transcripts directed from visna virus long terminal repeat (trans-activation). This trans-activating protein was previously called VEP1 and at present is renamed as the product of the rev gene according to significant amino acid sequence homologies between this protein and the rev gene products of simian immunodeficiency virus and human immunodeficiency virus type 2. In this study, the 1.7-kb mRNA was cloned, sequenced, and in vitro translated. It is 1491 nucleotides long, contains two short open reading frames, (orfs), tat (previously orf S) and rev which is the bipartite trans-acting gene specific for the early 1.4-kb mRNA. The tat gene of visna virus encodes for a protein of 11 kDa which in transient expression assays has a positive transacting effect on transcription as the rev gene product does.

Genetic structure and function of an early transcript of visna virus.

During the early step of the lytic cycle, visna provirus is first transcribed into two small multispliced mRNAs of 1.6 and 1.2 kilobases which may encode factors regulating the replication of visna virus (R. Vigne, V. Barban, G. Quérat, V. Mazarin, I. Gourdou, and N. Sauze, Virology 161:218-227, 1987). By cDNA cloning and nucleotide sequencing, we determined that the 1.2-kilobase mRNA is 1,174 nucleotides long without the 3'-polyadenylated tail and is composed of four exons, two of which originated from the 5' and 3' ends, respectively, of the env gene region. Two overlapping open reading frames are present in each of these two exons. They were translated in vitro and gave rise to three proteins, two of 19 and 17 kilodaltons, termed VEP1, and one of 16.5 kilodaltons, termed STM. Only the VEP1 proteins were recognized by a hyperimmune anti-visna virus serum of infected sheep. Transient-expression assays performed in eucaryotic cells demonstrated that the cDNA clone described here has a trans-acting effect on transcription of the visna virus genes.

Transcription of visna virus during its lytic cycle: evidence for a sequential early and late gene expression.

Visna lentivirus persists in sheep under a restricted form. Following induction events not yet defined at the molecular level, visna virus is activated to replicate productively through a short lytic cycle, the usual expression of visna virus in tissue culture. In an attempt to understand the relationship between latency and lytic replication, we characterized the transcripts of visna virus during its lytic growth by Northern blotting and S1 mapping analyses. The viral transcription pattern is relatively complex with a sequential expression in two steps: (i) an early (24 hr postinfection) expression of two multispliced mRNAs of 1.6 and 1.2 kb, which contain sequences from the 5' end of the genome, sequences from the central part of the genome from the 3' end of pol to the 5' end of env, and 3'-terminal sequences, and (ii) a late (72 hr postinfection) expression of both small mRNAs plus that of four large mRNAs of 9.4, 4.8, 4.3, and 3.7 kb. Except for the 9.4-kb RNA which is the genomic transcript, the three other large transcripts arise by a single splicing event joining 5'-terminal sequences to sequences located at positions 3' to the pol gene. This two-step expression of early and late genes of visna virus represents a novel important feature of the replicative cycle of lentiviruses.