A tissue-specific transcription enhancer from the Drosophila yolk protein 1 gene

The yolk protein 1 gene (yp1) of Drosophila melanogaster is expressed only in the ovarian follicle cells and the fat bodies of adult females. We have previously shown that a different cis-acting DNA region is required for each of these tissue specificities. In this paper we use germ line transformation to localize and characterized one of these tissue-specific regulatory regions. We demonstrate that a 125 bp segment of DNA located 196 bp upstream of the yp1 cap site is sufficient to determine the sex-, stage-, and fat body-specific expression of the yp1 gene. We also find that this region can confer yp1-specific expression on a heterologous Drosophila promoter. This specificity is retained when the region is in different orientations and at different distances from the heterologous promoter. Thus a small regulatory region acts in vivo as a positive enhancer to determine the fat body expression pattern of yp1.     

Cell-selective gene silencing in prostate cancer LNCap cells using prostate-specific membrane antigen promoter and enhancer in vitro and in vivo

RNAi (RNA interference) has been widely used to silence specific genes. However, RNAi may also cause off-target silencing and elicit non-specific side effects. To achieve cell-specific gene silencing, a cell-selective promoter has to be used to drive RNAi expression. Furthermore, different terminators of cell-selective promoters may cause different silencing efficacies. In order to explore the best promoter and terminator combination and prove the cell-selective gene silencing effect of PSMAe/p (prostate-specific membrane antigen enhancer/promoter), we first constructed three plasmids by using PSMAe/p and three different terminators [poly(A), minipoly(A) and poly(U)] to explore the cell-selective driving ability of PSMAe/p by targeting EGFP (enhanced green fluorescent protein) in LNCaP, PC-3, EJ and HEK-293 (human embryonic kidney) cells. Then we chose NS (nucleostemin), an important endogenous gene of prostate cancer, and constructed the NS-targeting shRNA (small-hairpin RNA) expression plasmid by using PSMAe/p-poly(A) combination. Cell proliferation, cell cycle and early apoptosis in vitro and xenograft tumour growth in BALB/c nude mice in vivo were detected after NS knockdown. Results showed that PSMAe/p can drive EGFP silencing in LNCaP, not in PC-3, EJ and HEK-293 cells and PSMAe/p-poly(A) combination achieved the best silencing efficacy. Then PSMAe/p-shNS-poly(A) drives NS knockdown in LNCaP cells, not in PC-3, EJ and HEK-293 cells. Furthermore, RNAi-mediated NS knockdown not only reduces cell proliferation rate, reduces the percentage of S-stage cells and increases the percentage of G1-stage cells and increases the early apoptosis ratio in LNCaP cells in vitro, but also inhibited the LNCaP xenograft tumour growth in BALB/c nude mice in vivo by intratumoural injection. In conclusion, we have demonstrated that PSMAe/p-poly(A) combination is a promising delivery system for targeted RNAi gene therapy of prostate cancer. We showed one effective antitumour strategy by targeting NS protein, an important target in prostate cancer, with PSMAe/p-shNS-poly(A). These results serve as an important step for developing novel strategies to treat prostate cancer.     

Substrate specificity of prostate-specific membrane antigen

A series of putative dipeptide substrates of prostate-specific membrane antigen (PSMA) was prepared that explored alpha- and beta/gamma-linked acidic residues at the P1 position and various chromophores at the P2 position, while keeping the P1' residue constant as L-Glu. Four chromophores were examined, including 4-phenylazobenzoyl, 1-pyrenebutyryl, 9-anthracenylcarboxyl-gamma-aminobutyryl, and 4-nitrophenylbutyryl. When evaluating these chromophores, it was found that a substrate containing 4-phenylazobenzoyl at the P2 position was consumed most efficiently. Substitution at the P1 position with acidic residues showed that only gamma-linked L-Glu and D-Glu were recognized by the enzyme, with the former being more readily proteolyzed. Lastly, binding modes of endogenous substrates and our best synthetic substrate (4-phenylazobenzoyl-Glu-gamma-Glu) were proposed by computational docking studies into an X-ray crystal structure of the PSMA extracellular domain.     

Optimizing phenylethylphosphonamidates for the inhibition of prostate-specific membrane antigen

A series of eight N-2-phenylethylphosphonyl derivatives of glutamic acid was prepared to determine if the inhibitory potency of a phenylethylphosphonyl derivative of glutamic acid against prostate-specific membrane antigen (PSMA) could be improved through rational substitutions on the phenyl ring. The design of these eight analogs was based upon the Topliss batchwise approach. Of the inhibitors from the first generation, the 3,4-dichlorophenyl analog exhibited the greatest improvement over the lead compound which was an unsubstituted phenyl derivative, while the 4-methoxyphenyl analog was essentially void of inhibitory potency against PSMA in single-dose studies. From the potency ranking order of the first generation, the parameter most important to the pharmacophore was determined to be pi + sigma. Attempts to optimize further the potency of inhibitors by preparing a second generation of compounds did not result in structures with greater potency than that of the 3,4-dichlorophenyl analog from the first generation. Based upon K(i) values, the 3,4-dichlorophenyl analog represented a potency improvement of nearly one order of magnitude. These results confirm further the usefulness of the Topliss approach to analog development when large library synthesis cannot be achieved readily.     

A novel cytoplasmic tail MXXXL motif mediates the internalization of prostate-specific membrane antigen

Prostate-specific membrane antigen (PSMA) is a transmembrane protein expressed at high levels in prostate cancer and in tumor-associated neovasculature. In this study, we report that PSMA is internalized via a clathrin-dependent endocytic mechanism and that internalization of PSMA is mediated by the five N-terminal amino acids (MWNLL) present in its cytoplasmic tail. Deletion of the cytoplasmic tail abolished PSMA internalization. Mutagenesis of N-terminal amino acid residues at position 2, 3, or 4 to alanine did not affect internalization of PSMA, whereas mutation of amino acid residues 1 or 5 to alanine strongly inhibited internalization. Using a chimeric protein composed of Tac antigen, the alpha-chain of interleukin 2-receptor, fused to the first five amino acids of PSMA (Tac-MWNLL), we found that this sequence is sufficient for PSMA internalization. In addition, inclusion of additional alanines into the MWNLL sequence either in the Tac chimera or the full-length PSMA strongly inhibited internalization. From these results, we suggest that a novel MXXXL motif in the cytoplasmic tail mediates PSMA internalization. We also show that dominant negative micro2 of the adaptor protein (AP)-2 complex strongly inhibits the internalization of PSMA, indicating that AP-2 is involved in the internalization of PSMA mediated by the MXXXL motif.     

Characterization of the gene for prostate-specific antigen, a human glandular kallikrein

The gene for the human glandular kallikrein, prostate-specific antigen, has been cloned. The sequence of 7130 nucleotides encompassing the gene and 633 bp of 5' and 639 bp of 3' flanking DNA has been determined. The translation initiation site was slightly heterogeneous, yielding 5' non-translated leader sequences of 41 and 35 bp. The gene is divided into five exons, with introns located at positions identical with those found in other glandular kallikrein genes. The nucleotide sequence is very similar to that of the human kallikrein gene hGK-1, with 76 to 93% of the nucleotides being identical in the exons and 76 to 87% in the introns. The similarity also extends approximately 200 bp into the sequence flanking the 5' end of hGK-1 and several other, both human and rodent, glandular kallikrein genes.     

Pseudoirreversible inhibition of prostate-specific membrane antigen by phosphoramidate peptidomimetics

The mode of inhibition for phosphoramidate peptidomimetic inhibitors of prostate-specific membrane antigen was determined by inhibition reversibility experiments. The results revealed that these inhibitors can be classified into three types: pseudoirreversible (compounds 1-3), moderately reversible (compounds 4-9), and rapidly reversible inhibitors (compounds 10 and 11). Representative compounds from each class were further evaluated for their ability to induce cellular internalization of PSMA. Results from these experiments revealed that the pseudoirreversible inhibitor 1 induced the greatest PSMA internalization. The discovery of pseudoirreversible PSMA inhibitors is expected to provide a new avenue of investigation and therapeutic applications for prostate cancer and neurological disorders.     

Phosphoramidate derivatives of hydroxysteroids as inhibitors of prostate-specific membrane antigen

Prostate-specific membrane antigen (PSMA) is a membrane-bound cell surface peptidase which is over-expressed in prostate cancer cells. The enzymatic activities of PSMA are understood but the role of the enzyme in prostate cancer remains conjectural. We previously confirmed the existence of a hydrophobic binding site remote from the enzyme's catalytic center. To explore the specificity and accommodation of this binding site, we prepared a series of six glutamate-containing phosphoramidate derivatives of various hydroxysteroids (1a-1f). The inhibitory potencies of the individual compounds of the series were comparable to a simple phenylalkyl analog (8), and in all cases IC50 values were sub-micromolar. Molecular docking was used to develop a binding model for these inhibitors and to understand their relative inhibitory potencies against PSMA.     

Purification of prostate-specific membrane antigen using conformational epitope-specific antibody-affinity chromatography

Prostate-specific membrane antigen (PSMA) is a type II membrane protein that has attracted significant attention as a target for immunioscintigraphic and radioimmunotherapeutic applications for prostate cancer. However, definitive studies on its substrate and inhibitor specificity as well as protein-protein interactions have been somewhat limited by difficulties in the purification of native PSMA. In this study, we optimized the purification of native PSMA from LNCaP cells using conformational epitope-specific antibody-affinity chromatography. Western blot analysis and an HPLC-based enzymatic activity assay were used to compare the yield and activity of PSMA purified by different methods. The ratio of purified PSMA in a native and active conformation was determined by quantifying the amount of non-native PSMA not retained in a second antibody-affinity isolation. The addition of both a neutralization step and the inclusion of Zn(2+) to the equilibration buffer in desalting step provides considerable enhancement in the yield of active PSMA from LNCaP cells.