Selective activation of the fatty acid synthesis pathway in human prostate cancer.

A substantial subset of breast, colorectal, ovarian, endometrial and prostatic cancers displays markedly elevated expression of immunohistochemically detectable fatty acid synthase, a feature that has been associated with poor prognosis and that may be exploited in anti-neoplastic therapy. Here, using an RNA array hybridisation technique complemented by in situ hybridisation, we report that in prostate cancer fatty acid synthase expression is up-regulated at the mRNA level together with other enzymes of the same metabolic pathway. Contrary to the observations that in many cell systems (including androgen-stimulated LNCaP prostate cancer cells) fatty acid and cholesterol metabolism are co-ordinately regulated so as to supply balanced amounts of lipids for membrane biosynthesis, storage or secretion, no changes in the expression of genes involved in cholesterol synthesis were found. These findings point to selective activation of the fatty acid synthesis pathway and suggest a shift in the balance of lipogenic gene expression in a subgroup of prostate cancers.

Expression of cystatin-related protein and of the C3-component of prostatic-binding protein during postnatal development in the rat ventral prostate and lacrimal gland.

The expression of cystatin-related protein (CRP) and of the C3-component of prostatic-binding protein (PBP) during postnatal development of the rat was studied by Northern blotting, dot blot and in situ hybridisation, and by radioimmunoassay or immunoblotting. In intact male rats, very little or no PBP-C3 could be detected in the prostate at 10 days, but at 20 days there was already strong expression. By in situ hybridisation, the first expression of C3 mRNA was observed at 13 days in the prostate and at 22 days in the lacrimal gland. For CRP, this occurred at 16 and 22 days, respectively. Neither CRP nor C3 was expressed in prepubertal male rats castrated at day 1 or day 10 or in female rats. Androgen treatment of intact male animals did not advance the expression of both mRNAs in the prostate, but did so in the lacrimal gland with first expression of C3 at 19 instead of 22 days and of CRP at 13 instead of 22 days. Identical values were obtained in female rats. Androgen treatment of castrated adult male rats resulted in a more rapid and homogeneous secondary induction. Positive immunostaining for the androgen receptor (AR) was observed in the lacrimal gland at 7 days, but its concentration, estimated by immunoblotting, was still low at 10 days. Maximal levels, reached at 30 days, were markedly higher in male than in female rats. In conclusion, CRP and C3 are induced by androgens in prepubertal rats. The time point of induction, however, is probably determined by other tissue and differentiation-dependent factors in addition to androgens and the AR.

Primary rat lacrimal cells undergo acinar-like morphogenesis on reconstituted basement membrane and express secretory component under androgen stimulation.

Single cells or small cell clusters, isolated from the rat lacrimal gland, were incubated on reconstituted basement membrane (matrigel) in a well-defined serum-free medium. During the first days of culture, cells reassociated and reorganized in structures resembling acini. These multicellular structures, maintained in culture for 2 weeks, consisted of well-polarized cuboidal cells surrounding a central lumen and exhibiting apically located microvilli. Myoepithelial cells were observed at the periphery of the acinar structures. Both in the native lacrimal and in the cultured aggregates, epithelial cells displayed strong immunoreactivity for cytokeratin 8, while myoepithelial cells were immunoreactive for vimentin and alpha-smooth muscle isoactin. These data indicate that the cultured aggregates closely mimic the in vivo architecture of lacrimal glands both by morphology and immunohistochemistry. We further demonstrated the presence of an intact androgen receptor and the ability of the cultured aggregates to respond to androgens with increased secretion of the secretory component. Comparable androgen responses were observed in lacrimal gland cultures of 5-week-old male and female rats. In conclusion, we report a morphologically and functionally differentiated culture system of primary rat lacrimal cells, in which androgen-regulated gene expression was observed. This culture model provides a unique experimental paradigm for studying the effects of hormones, cytokines, and growth factors on the morphogenesis, growth, and functional differentiation of lacrimal glands.

Androgens transcriptionally regulate the expression of cystatin-related protein and the C3 component of prostatic binding protein in rat ventral prostate and lacrimal gland.

In this report, it is demonstrated that the C3 component of prostatic binding protein (PBP) is also expressed and androgen regulated in the exorbital lacrimal gland, as shown previously for cystatin-related protein (CRP), another abundant secretory protein from the ventral prostate. The presence of C3 messenger RNA (mRNA) could be demonstrated by both Northern blot hybridization and PCR amplification and sequencing. The mRNAs encoding the C1 and C2 components of PBP, however, were undetectable. At the protein level, the C3 component in the lacrimal gland is glycosylated and linked by disulfide bridges to a new 10-kDa component not reacting with the PBP antiserum. As shown previously for CRP, the expression of C3 in the lacrimal gland requires the simultaneous presence of androgens and a functional androgen receptor. The effects of castration and androgen treatment on CRP and C3 mRNA concentrations were studied by Northern blot and dot blot hybridization; effects on transcription rates were determined by nuclear run-on assay. Two days after castration, the relative abundance of CRP mRNA had declined significantly (P < 0.01) to 10.5 +/- 1.5% (+/-SEM) of precastration levels in the prostate and to 14.5 +/- 8.0% in the lacrimal gland; the transcription rates declined to 14.3% and 10.0%, respectively. The C3 mRNA level and transcription rate in the prostate showed a more moderate decrease (P < 0.05) to 40.6 +/- 8.5% and 41.7%, but were hardly measurable in the lacrimal gland. Androgen administration resulted in a rapid increase in the transcription rates, which reached or exceeded control levels after 6-9 h of treatment and clearly preceded the increase in mRNA levels. It is concluded that the lacrimal gland, which can be studied conveniently in female and long term androgen-depleted animals offers a suitable model for the study of androgen-regulated gene expression.

Androgenic induction of cystatin-related protein and the C3 component of prostatic binding protein in primary cultures from the rat lacrimal gland.

Cystatin-related protein (CRP) and the C3 component of prostatic binding protein (C3) are synthesized in vivo under androgen control in the lacrimal gland and ventral prostate of adult male rats [1,2]. Androgen administration to female or 7-day castrated male rats, which do not express CRP, can induce its synthesis [3]. In this study, we show androgen-dependent expression of CRP1 and C3 in primary cultures of acinar cells of the lacrimal gland of female rats. Addition of androgens to the culture medium results in the synthesis and secretion of both proteins in a time- and dose-dependent way. Estradiol or progesterone are unable to induce their expression. Dexamethasone in low concentrations and present as a basal component of the serum free defined medium, is needed to sensitize the culture system for androgens. In high concentrations, this synthetic glucocorticoid seems to play a similar role as androgens in CRP1 and C3 regulation.

Androgen regulation of the messenger RNA encoding diazepam-binding inhibitor/acyl-CoA-binding protein in the rat.

Our recent finding that diazepam-binding inhibitor/acyl-CoA-binding protein (DBI/ACBP) expression is regulated by androgens in the human prostatic adenocarcinoma cell line LNCaP, prompted us to study whether androgen regulation of DBI/ACBP also occurs in vivo in the prostate and in other organs of the rat. Northern blot analysis demonstrated that DBI/ACBP transcripts were expressed in male accessory sex organs such as ventral prostate, dorsolateral prostate, seminal vesicles and coagulating glands. Castration caused a 1.7- to 2.7-fold reduction in the levels of DBI/ACBP transcripts over a period of 6 days. Readministration of androgens during the last 3 days led to 4.2- to 7.5- fold higher levels of DBI/ACBP transcripts than in untreated castrates. In situ hybridization revealed that in the ventral prostate, DBI/ACBP transcripts were expressed predominantly in epithelial cells and that the observed effects of androgens were due both to modulation of gene expression per cell and to changes in cell composition. Androgen regulation of DBI/ACBP mRNA expression was also observed in the lacrimal glands, the adrenals, and the submandibular glands, but not in the liver and the kidney. These findings demonstrate that DBI/ACBP is androgen-regulated in vivo in various organs of the rat. In view of the proposed role of DBI/ACBP in the control of multiple biological processes, DBI/ACBP may be one of the target genes by which androgens affect a variety of physiological processes.

Immunocytochemical localization of seminal proteins in salivary and lacrimal glands of the rat.

Antibodies against 10 different secretory proteins from the accessory sex glands of the male rat were used for immunohistochemical studies of salivary and lacrimal glands from intact and castrated rats, at the light- and electron-microscopic levels. In the parotid gland, secretory acinar cells showed immunoreactivity with antibodies against prostatic binding protein, cystatin-related peptide and acid phosphatase (isoenzyme pI 8.0; 5.6) typical of ventral prostate, and seminal vesicle secretion VI. Western blotting analysis indicated that immunoreactivity against prostatic binding protein was attributable to a subunit, presumably C3. Acid phosphatase pI 5.6 showed a molecular weight of 66 kDa, which is at variance with the prostatic form. Immunoreactivity for secretory transglutaminase, derived from the coagulating gland, was restricted to myoepithelial and stromal cells. In castrated animals, the immunoreactivity of acinar cells was reduced to the background level, whereas stromal transglutaminase immunoreactivity was unaltered. The distribution pattern of immunoreactivity for the proteins mentioned was almost identical in the lacrimal gland. Significant differences were however observed in the immunoreactivity of the inframandibular gland, where serous glandular cells were non-immunoreactive for seminal proteins, with the exception of acid phosphatase isoenzyme pI 8.0. Granules present in the convoluted granular ducts were immunoreactive particularly for acid phosphatase (isoenzyme pI 5.6) but much less for cystatin-related peptide; immunoreactivity was reduced after castration. The straight portion of the inframandibular duct system was immunoreactive for transglutaminase, but no influence of castration was visible. The distribution of immunoreactivity for seminal proteins present in the salivary and lacrimal glands and the pronounced androgen-dependence of their expression point to functional relationships of the respective proteins at both glandular sites.

The genes coding for rat cystatin-related prostate protein (Cstrp) map to chromosome 3q41.

Two genes encoding rat cystatin-related prostate protein (Cstrp), previously called CRP (Devos et al., 1993), were mapped to chromosome 3q41 by fluorescent in situ hybridization. The results were confirmed using a panel of mouse-rat hybrids that segregate rat chromosomes. Analysis of genomic DNA indicates that the Cstrp locus comprises probably more than three very similar genes.

Androgen-dependent expression of cystatin-related protein (CRP) in the exorbital lacrimal gland of the rat.

Cystatin-related protein (CRP), also known as 20 (22)-kDa glycoprotein is expressed not only in the ventral prostate, but also in the lacrimal gland of adult male rats. In this study the expression of CRP in androgen-treated female animals is studied. CRP mRNA is absent in the lacrimal gland of untreated adult female rats, but can be induced by androgens, although this induction is slower than in castrated male rats. Estradiol, progesterone or glucocorticoids have no effect. In testicular feminized rats, however, CRP mRNA is not induced in the lacrimal gland by androgens. At the protein level, the presence of CRP in tears of adult male rats is demonstrated. In female animals or castrated male animals CRP can be induced by androgens in a dose-dependent way. Here also the induction is slower in female rats, even during secondary induction after previous full stimulation by androgens. These results indicate that androgens and a functionally normal androgen receptor are essential for the expression of CRP in the lacrimal gland. The time course of induction depends on the dose of androgens, the previous contact with androgens, the duration of the androgen-free interval and the sex of the animals.

Structure of rat genes encoding androgen-regulated cystatin-related proteins (CRPs): a new member of the cystatin superfamily.

Cystatin-related proteins (CRPs) are abundant androgen-regulated secretory glycoproteins that are specifically synthesized in the ventral prostate and lachrymal gland of the rat. Two complete 6-kb genes, Crp1 and Crp2, have been cloned and characterized. They are differentially expressed and encode slightly different proteins. The genes each contain four exons which are interrupted by large introns. An alignment of their sequences demonstrates an overall homology of 90%. The 3' end of a third gene, Crp3, from which only a 1.5-kb fragment was isolated, displays a sequence identity of 84%. These data indicate the existence of a Crp multigene family. The 5' flanking regions of Crp1 and Crp2 are highly homologous and contain a GATAAA sequence 29 nt upstream from the transcription start point. This TATA-box-like element is also found in the promoters of the genes encoding cystatin type-2 proteins. No other recognizable transcription control elements can be detected. Potential binding sites (ARE) for the androgen receptor are scattered throughout the entire genes. The exon/intron organization of the genes encoding CRPs, the size of the exons and their encoding amino acid sequences exhibiting a characteristic spacing of the Cys residues are structural elements displaying a remarkable similarity with the corresponding elements in the genes encoding cystatin type-2 proteins. CRPs must therefore belong to the cystatin superfamily. However, due to their additional domain encoded in an extra exon 2, CRPs must be classified as a new family, type 5.

An effect of androgens on the length of the poly(A)-tail and alternative splicing cause size heterogeneity of the messenger ribonucleic acids encoding cystatin-related protein.

The 22-kilodalton glycoprotein, expressed in the rat ventral prostate under the influence of androgens, is structurally a cystatin-related protein (CRP), as has been shown by copy DNA sequencing. In fact, two slightly different forms (CRP-1 and CRP-2) are expressed in the prostate; one of them (CRP-1) is also expressed in the exorbital lacrymal gland. In both glands, the CRP-1 messenger RNA (mRNA)s are androgen regulated. Moreover, androgens also influence the size of these mRNAs, which show marked heterogeneity (from 760-950 nucleotides). Indeed, the smaller forms are predominant in castrated animals, whereas the large forms are observed immediately after androgen induction. Hybridization with oligo(dT) followed by ribonuclease H treatment revealed that differences in length of the poly(A)-tail are responsible for this effect of androgens. Indeed, two well defined forms of CRP mRNA subsisted after removal of the poly(A)-tail by this treatment. In the less abundant shorter form (CRP-1 delta), 123 nucleotides are deleted by alternative splicing at the junction between the third and the fourth exon. The variant mRNA encodes a truncated protein, wherein the last 27 amino acids are replaced by a hydrophobic stretch of 8 amino acids. No alternative splicing was observed for the CRP-2 mRNA.