Reduced lecithin:retinol acyltransferase expression in human breast cancer.

Retinoids, vitamin A (retinol) and related metabolites, have been shown to be important in regulating cell growth and differentiation. We have shown that expression of the enzyme lecithin:retinol acyltransferase (LRAT), which converts retinol to retinyl esters, is reduced in several human carcinomas as compared with adjacent normal tissue from the same organs. The purpose of this research was to determine if aspects of retinoid signaling are impaired in human breast cancer. We evaluated LRAT protein expression in neoplastic and adjacent, non-neoplastic glandular breast tissue specimens from human patients. We evaluated 26 specimens from patients diagnosed with breast cancer between 2003 and 2005. Representative paraffin-embedded tissue blocks from each tumor, with each containing adjacent non-neoplastic glandular breast tissue, were examined by immunohistochemistry with affinity purified antibodies to human LRAT protein. LRAT protein was prominently detected throughout the non-neoplastic glandular breast tissue in all of the specimens. Areas of ductal carcinoma in situ and well-differentiated invasive breast carcinomas showed an intensity of staining with the LRAT antibody which was similar to that of the adjacent normal tissue. Expression of LRAT protein progressively decreased with a reduction in the degree of tumor differentiation in invasive breast carcinomas. LRAT protein levels correlate better with the degree of ductal tumor differentiation than does estrogen receptor status in this study. Furthermore, normal human breast epithelium exhibits intense LRAT staining, indicating a major role for LRAT in human breast physiology.

Palmitoyl transferase activity of lecithin retinol acyl transferase.

Lecithin retinol acyl transferase (LRAT) has the essential role of catalyzing the transfer of an acyl group from the sn-1 position of lecithin to vitamin A to generate all-trans-retinyl esters (tREs). In vitro studies had shown previously that LRAT also can exchange palmitoyl groups between RPE65, a tRE binding protein essential for vision, and tREs. This exchange is likely to be of regulatory significance in the operation of the visual cycle. In the current study, the substrate specificity of LRAT is explored with palmitoylated amino acids and dipeptides as RPE65 surrogates. Both O- and S-substituted palmitoylated analogues are excellent substrates for tLRAT, a readily expressed and readily purified form of LRAT. Using vitamin A as the palmitoyl acceptor, tREs are readily formed. The cognate of these reactions occurs in crude retinal pigment epithelial (RPE) membranes as well. RPE membranes containing LRAT transfer palmitoyl groups from radiolabeled [1-(14)C]-l-alpha-dipalmitoyl diphosphatidylcholine (DPPC) to RPE65. Palmitoyl transfer is abolished by preincubation with a specific LRAT antagonist both in membranes and with purified tLRAT. These experiments are consistent with an expanded role for LRAT function as a protein palmitoyl transferase.

Small molecule RPE65 antagonists limit the visual cycle and prevent lipofuscin formation.

The accumulation of the lipofuscin fluorophores in retinal pigment epithelial (RPE) cells leads to the blinding degeneration characteristic of Stargardt disease and related forms of macular degeneration. RPE lipofuscin, including the fluorophore A2E, forms in large part as a byproduct of the visual cycle. Inhibiting visual cycle function with small molecules is required to prevent the formation of the retinotoxic lipofuscins. This in turn requires identification of rate-limiting steps in the operation of the visual cycle. Specific, non-retinoid isoprenoid compounds are described here, and shown through in both in vitro and in vivo experiments, to serve as antagonists of RPE65, a protein that is essential for the operation of the visual cycle. These RPE65 antagonists block regeneration of 11-cis-retinal, the chromophore of rhodopsin, thereby demonstrating that RPE65 is at least partly rate-limiting in the visual cycle. Furthermore, chronic treatment of a mouse model of Stargardt disease with the RPE65 antagonists abolishes the formation of A2E. Thus, RPE65 is also on the rate-limiting pathway to A2E formation. These nontoxic isoprenoid RPE65 antagonists are candidates for the treatment of forms of macular degeneration wherein lipofuscin accumulation is an important risk factor. These antagonists will also be used to probe the molecular function of RPE65 in vision.

Specificity of binding of all-trans-retinyl ester to RPE65.

Membrane-bound RPE65 (mRPE65) is a binding protein for all-trans-retinyl esters, which are the substrates for the isomerization reaction that completes the visual cycle. RPE65 is essential for rhodopsin regeneration and, hence, for vision. As RPE65 appears to be part of the rate-limiting pathway in the visual cycle, specific antagonists of the molecule will be important in evaluating its full physiological role. The protein is known to stereoselectively bind all-trans-retinyl esters (tREs), with dissociation constants in the 50 nM range. This study explores the overall binding specificity of RPE65 with respect to both retinoids and other isoprenoids in an effort to define the specificity of binding, and to begin the process of designing specific antagonists for it. The nature of the specificity directed toward the three main structural elements (retinoid, linker, and acyl moieties) in the tRE molecule is reported. In the all-trans-retinyl ester series, binding affinity increased as a function of the hydrophobicity of the fatty acyl group. In the linker region, binding affinities were little affected by amide, ketone, and ether replacements for the carboxy ester moiety of the naturally occurring tRE ligand. Finally, modifications in the all-trans-retinoid moiety are also tolerated. For example, E,E-farnesyl palmitate binds with approximately the same affinity as does all-trans-retinyl palmitate. Other isoprenoid analogues also bind, as do truncated retinoids in the beta-ionone series. Therefore, mRPE65 is a moderately specific retinoid binding protein directed at long chain all-trans-retinyl esters.

On the mechanism of isomerization of all-trans-retinol esters to 11-cis-retinol in retinal pigment epithelial cells: 11-fluoro-all-trans-retinol as substrate/inhibitor in the visual cycle.

The synthesis of 11-fluoro-all-trans-retinol (11-F-tROL), which is shown to be an excellent substrate for processing by visual cycle enzymes, is described. It is isomerized to its 11-cis congener subsequent to its esterification by lecithin retinol acyl transferase (LRAT) approximately as well as is vitamin A itself. The enzymatic turnover of 11-F-tROL is unaccompanied by enzyme inhibition. The previously reported lack of isomerization of this substrate had been suggested as evidence for a carbonium mechanism in the critical enzymatic isomerization pathway in vision. The mechanism of this process remains unknown.

A palmitoylation switch mechanism in the regulation of the visual cycle.

RPE65 is essential for the biosynthesis of 11-cis-retinal, the chromophore of rhodopsin. Here, we show that the membrane-associated form (mRPE65) is triply palmitoylated and is a chaperone for all-trans-retinyl esters, allowing their entry into the visual cycle for processing into 11-cis-retinal. The soluble form of RPE65 (sRPE65) is not palmitoylated and is a chaperone for vitamin A, rather than all-trans-retinyl esters. Thus, the palmitoylation of RPE65 controls its ligand binding selectivity. The two chaperones are interconverted by lecithin retinol acyl transferase (LRAT) acting as a molecular switch. Here mRPE65 is a palmitoyl donor, revealing a new acyl carrier protein role for palmitoylated proteins. When chromophore synthesis is not required, mRPE65 is converted into sRPE65 by LRAT, and further chromophore synthesis is blocked. The studies reveal new roles for palmitoylated proteins as molecular switches and LRAT as a palmitoyl transferase whose role is to catalyze the mRPE65 to sRPE65 conversion.

The specific binding of retinoic acid to RPE65 and approaches to the treatment of macular degeneration.

RPE65 is essential in the operation of the visual cycle and functions as a chaperone for all-trans-retinyl esters, the substrates for isomerization in the visual cycle. RPE65 stereospecifically binds all-trans-retinyl esters with a K(D) of 47 nM. It is shown here by using a quantitative fluorescence technique, that Accutane (13-cis-retinoic acid), a drug used in the treatment of acne but that causes night blindness, binds to RPE65 with a K(D) of 195 nM. All-trans-retinoic acid binds with a K(D) of 109 nM. The binding of the retinoic acids to RPE65 is competitive with all-trans-retinyl ester binding, and this competition inhibits visual cycle function. A retinoic acid analog that binds weakly to RPE65 is not inhibitory. These data suggest that RPE65 function is rate-limiting in visual cycle function. They also reveal the target through which the retinoic acids induce night blindness. Finally, certain forms of retinal and macular degeneration are caused by the accumulation of vitamin A-based retinotoxic products, called the retinyl pigment epithelium-lipofuscin. These retinotoxic products accumulate during the normal course of rhodopsin bleaching and regeneration after the operation of the visual cycle. Drugs such as Accutane may represent an important approach to reducing the accumulation of the retinotoxic lipofuscin by inhibiting visual cycle function. The identification of RPE65 as the visual cycle target for the retinoic acids makes it feasible to develop useful drugs to treat retinal and macular degeneration while avoiding the substantial side effects of the retinoic acids.

Roles of cysteine 161 and tyrosine 154 in the lecithin-retinol acyltransferase mechanism.

Lecithin-retinol acyltransferase (LRAT) catalyzes the transfer of an acyl moiety from the sn-1 position of lecithin to vitamin A, generating all-trans-retinyl esters. LRAT is a unique enzyme and is the founder member of an expanding group of proteins of largely unknown function. In an effort to understand the mechanism of LRAT action, it was of interest to assign the amino acid residues responsible for the two pK(a) values of 8.22 and 9.95 observed in the pH vs rate profile. Titrating C161 of LRAT with a specific affinity labeling agent at varying pH values shows that this residue has a pK(a) = 8.03. Coupled with previous studies, this titration reveals the catalytically essential C161 as the residue responsible for the ascending limb of the pH vs rate profile. Site-specific mutagenic experiments on the lysine and tyrosine residues of LRAT reveal that only the highly conserved tyrosine 154 is essential for catalytic activity. This residue is likely to be responsible for the pK(a) = 9.95 found in the pH vs rate profile. Thus, LRAT has three essential residues (C161, Y154, and H60), all of which are conserved in the LRAT family of enzymes.

Reduced lecithin: retinol acyltransferase expression correlates with increased pathologic tumor stage in bladder cancer.

PURPOSE: Retinoids, which include vitamin A (retinol; ROL) and its derivatives, have been investigated in the treatment of bladder cancer. We have shown that expression of the enzyme lecithin:ROL acyltransferase (LRAT), which converts ROL to retinyl esters, is reduced in several human cancers. Here we evaluated expression of LRAT protein and mRNA in normal and malignant bladder tissue specimens from human patients. We also examined the effect of retinoids on LRAT expression in bladder cancer cell lines. EXPERIMENTAL DESIGN: We evaluated 49 bladder cancer specimens for LRAT protein expression using immunohistochemistry with affinity-purified antibodies to human LRAT. LRAT mRNA expression was assessed using reverse transcription-PCR in bladder specimens from an additional 16 patients. We examined the effect of retinoic acid and ROL on LRAT mRNA expression in five human bladder cancer cell lines. RESULTS: LRAT protein was detected throughout the nonneoplastic bladder epithelium in all of the specimens. In bladder tumors, LRAT protein expression was reduced compared with the nonneoplastic epithelium or was completely absent in 7 of 32 (21.9%) superficial tumors versus 16 of 17 (94.1%) invasive tumors (P < 0.001). All of the non-neoplastic bladder specimens tested (11 of 11) showed LRAT mRNA expression, compared with 5 of 8 (62%) superficial tumors and 0 of 5 (0%) invasive tumors (P = 0.001). Three of five human bladder cancer cell lines expressed LRAT mRNA independent of retinoid exposure, whereas in two cell lines LRAT mRNA expression was induced by retinoid treatment. CONCLUSIONS: We report a significant reduction in LRAT expression in bladder cancer. Moreover, we demonstrate an inverse correlation of LRAT mRNA and protein expression with increasing tumor stage. These data suggest that loss of LRAT expression is associated with invasive bladder cancer.

Molecular logic of 11-cis-retinoid biosynthesis in a cone-dominated species.

The biochemical pathway to visual chromophore biosynthesis in rod-dominated animals involves minimally a two component system in which all-trans-retinyl esters, generated by the action of lecithin retinol acyltransferase (LRAT) on vitamin A, are processed into 11-cis-retinol by isomerohydrolase. Possible differences in retinoid metabolism in cone-dominated animals have been noted in the literature, so it was of interest to explore whether these differences are tangential or fundamental. Central to this issue is whether cone-dominated animals use an isomerohydrolase (IMH)-based mechanism in the predominant pathway to 11-cis-retinoids. Here, it is shown that all-trans-retinyl esters (tREs) are the direct precursors of 11-cis-retinol formation in chicken retinyl pigment epithelium/retina preparations. This conclusion is based on at least three avenues of evidence. First, reagents that block tRE synthesis from vitamin A also block 11-cis-retinol synthesis. Second, pulse-chase experiments also establish that tREs are the precursors to 11-cis-retinol. Finally, 11-cis-retinyl-bromoacetate, a known affinity-labeling agent of isomerohydrolase, also blocks chromophore biosynthesis in the cone system.

Lecithin retinol acyltransferase is a founder member of a novel family of enzymes.

Lecithin retinol acyltransferase (LRAT) catalyzes the reversible esterification of vitamin A using lecithin as the acyl donor. LRAT is the founder member of a new class of enzymes, which include class II tumor suppressors, proteins essential for development, and putative proteases. All of these proteins possess Cys and His residues homologous to C161 and H60 of LRAT. These two residues are shown here to be essential for LRAT activity and are part of a catalytic dyad reminiscent of that found in thiol proteases. However, the local primary sequence contexts of C161 and H60 of LRAT and family are not at all homologous to those found in the approximately 20 thiol protease families. Moreover, LRAT shows pKs of 8.3 and 10.8, compared to approximately 4.0 and 8.5 observed in the thiol proteases. LRAT also contains Gln177 and Asp67 residues, which are largely conserved in the homologues. However, neither of these residues is essential for catalysis. Thiol proteases often contain catalytically essential Asp or Gln residues. It is concluded that LRAT is the founder member of a new class of Cys-His enzymes with diverse functions.

RPE65 operates in the vertebrate visual cycle by stereospecifically binding all-trans-retinyl esters.

RPE65 is a major protein of unknown function found associated with the retinyl pigment epithelial (RPE) membranes [Hamel, C. P., Tsilou, E., Pfeffer, B. A., Hooks, J. J., Detrick, B., and Redmond, T. M. (1993) J. Biol. Chem. 268, 15751-15757; Bavik, C. O., Levy, F., Hellman, U., Wernstedt, C., and Eriksson, U. (1993) J. Biol. Chem. 268, 20540-20546]. RPE65 knockouts fail to synthesize 11-cis-retinal, the chromophore of rhodopsin, and accumulate all-trans-retinyl esters in the RPE. Previous studies have also shown that RPE65 is specifically labeled with all-trans-retinyl ester based affinity labeling agents, suggesting a retinyl ester binding role for the protein. In the present work, we show that purified RPE65 binds all-trans-retinyl palmitate (tRP) with a K(D) = 20 pM. These quantitative experiments are performed by measuring the quenching of RPE65 fluorescence by added tRP. The binding for tRP is highly specific because 11-cis-retinyl palmitate binds with a K(D) = 14 nM, 11-cis-retinol binds with a K(D) = 3.8 nM, and all-trans-retinol (vitamin A) binds with a K(D) = 10.8 nM. This stereospecificity for tRP is to be compared to the binding of retinoids to BSA, where virtually no discrimination is found in the binding of the same retinoids. This work provides further evidence that RPE65 functions by binding to and mobilizing the highly hydrophobic all-trans-retinyl esters, allowing them to enter the visual cycle.

Specific inactivation of isomerohydrolase activity by 11-cis-retinoids.

The endergonic trans-->cis isomerization of retinoids is an essential element in rhodopsin regeneration in vertebrates. All-trans-retinyl esters, which are generated by lecithin retinol acyltransferase (LRAT), are on the isomerization pathway. The critical isomerohydrolase activity, which catalyzes the trans-->cis isomerization/hydrolysis reaction of all-trans-retinyl esters, remains to be identified. It is demonstrated here that 11-cis-retinyl bromoacetate (cRBA) is a potent and specific inactivator of the bovine retinyl pigment epithelial (RPE) isomerohydrolase activity, with a measured K(I)=0.19 microM and a pseudo-first-order rate of inactivation k(inh)=1.83 x 10(-3) s(-1). This demonstrates that the isomerization is indeed enzyme-mediated. This inactivator should facilitate the identification and study of isomerohydrolase, or at least an essential component of it. Labeling of crude RPE membranes with 3H-cRBA reveals the presence of several labeled bands that may be isomerohydrolase candidates.

Stereospecificity of short Rev-derived peptide interactions with RRE IIB RNA.

The essential HIV-1 regulatory protein Rev binds to the Rev responsive element (RRE) of the HIV-1 mRNA. A short alpha-helical peptide derived from Rev (Rev 34-50) and a truncated form of the RRE sequence (RRE IIB) provide a useful in vitro system to study the interactions between Rev and RRE. The current studies focus on evaluating the specificity of the binding interactions between Rev 34-50 and RRE IIB. The binding of L- and D-Rev peptides to natural and enantiomeric RRE IIB RNA was studied by fluorescence spectroscopy. D-Rev and L-Rev peptides bind to RRE IIB with similar affinities. CD measurements are consistent with a nonhelical, probably beta-hairpin, conformation for D-Rev in the complex. The binding affinities of D/L Rev peptides to L-RRE IIB RNA are also similar to those with natural D-RRE IIB. Furthermore, the conformations of L- and D-peptides when bound to L-RRE are reciprocal to the conformations of these peptides in complex with D-RRE. RNA footprinting studies show that L- and D-Rev peptides bind to the same site on RRE IIB. Our results demonstrate lack of stereospecificity in RRE RNA-Rev peptide interactions. However, it is quite possible that the interactions between full-length Rev protein and RRE are highly specific.

Purification and characterization of a transmembrane domain-deleted form of lecithin retinol acyltransferase.

Lecithin retinol acyltransferase (LRAT) catalyzes the esterification of all-trans-retinol into all-trans-retinyl ester, an essential reaction in the vertebrate visual cycle. Since all-trans-retinyl esters are the substrates for the isomerization reaction that generates 11-cis-retinoids, this esterification reaction is essential in the operation of the visual cycle. In addition, LRAT is the founder member of a series of proteins, which are of novel sequence and have unknown functions. Native LRAT is an integral membrane protein and has never been purified. To obtain a pure LRAT, the N- and C-transmembrane termini were deleted and replaced with a poly His tag for the purpose of purification. This truncated form of LRAT, referred to as tLRAT, has been expressed in bacteria and fully purified. tLRAT is catalytically active and processes all-trans-retinol at least 10-fold more efficiently than 11-cis-retinol, the precursor to the visual chromophore. While tLRAT can be robustly expressed in bacteria, it requires detergent for extraction, as the enzyme still contains hydrophobic domains, which may interact. Indeed, tLRAT can oligomerize and forms dimers. Native LRAT also forms functional homodimers. These studies pave the way for the preparation of large-scale amounts of pure tLRAT for further mechanistic and structural studies.

A cleavable affinity biotinylating agent reveals a retinoid binding role for RPE65.

Retinal pigment epithelial (RPE) membranes contain the full biochemical apparatus capable of processing all-trans-retinol (vitamin A) into 11-cis-retinal, the visual chromophore. As many of these proteins are integral membrane proteins and resistant to traditional methods of identification, alternate methods of identifying these proteins are sought. The approach described here involves affinity biotinylation with alkali cleavable linkers. A vitamin A containing affinity-labeling haloacetate is described which facilitates the identification of retinoid binding proteins (RBPs). Treatment of crude bovine RPE membranes with (3R)-3-[boc-lys(biotinyl)-O]-all-trans-retinol chloroacetate 1 in the low micromolar range led to the specific labeling of RPE65 and lecithin retinol acyltransferase (LRAT). Only RPE65 is labeled at 5 microM 1 at 4 degrees C. Labeled RPE65 was readily isolated by binding the labeled protein to avidin-containing beads, followed by cleavage of the protein from the beads at pH 11. Trypsin digestion of RPE65 modified by 1, followed by mass spectrometry, demonstrates that C231 and C448 are alkylated by 1. These studies validate the approach that was used, and furthermore demonstrate that RPE65, a major membrane-associated protein of the RPE, is a RBP.

All-trans-retinyl esters are the substrates for isomerization in the vertebrate visual cycle.

The identification of the critical enzyme(s) that carries out the trans to cis isomerization producing 11-cis-retinol during the operation of the visual cycle remains elusive. Confusion exists in the literature as to the exact nature of the isomerization substrate. At issue is whether it is an all-trans-retinyl ester or all-trans-retinol (vitamin A). As both putative substrates interconvert rapidly in retinal pigment epithelial membranes, the choice of substrate can be ambiguous. The two enzymes that effect interconversion of all-trans-retinol and all-trans-retinyl esters are lecithin retinol acyl transferase (LRAT) and retinyl ester hydrolase (REH). The retinyl ester or all-trans-retinol pools are radioactively labeled separately in the presence of inhibitors of LRAT and REH, effectively preventing their interconversion. Pulse-chase experiments unambiguously demonstrate that all-trans-retinyl esters, and not all-trans-retinol, are the precursors of 11-cis-retinol. When the all-trans-retinyl ester pool is radioactively labeled, the resulting 11-cis-retinol is labeled with the same specific activity as the precursor ester. The converse is true with vitamin A. These data unambiguously establish all-trans-retinyl esters as the precursors of 11-cis-retinol.

Synthesis of (+),(-)-neamine and their positional isomers as potential antibiotics.

The syntheses of (+)-neamine 1, (-)-neamine ent-1 and their positional isomers 2, 3, ent-2 and ent-3 are reported as potential new scaffolds for novel aminoglycoside antibiotics. These isomers exhibit similar inhibitory activities, as shown using an in vitro translation assay. A simple model is proposed to explain this lack of stereospecific binding to the ribosomal RNA.

Stereospecificity of aminoglycoside-ribosomal interactions.

Aminoglycoside antibiotics bind to the A-site decoding region of bacterial rRNA causing mistranslation and/or premature message termination. Aminoglycoside binding to A-site RNA decoding region constructs is established here to be only weakly stereospecific. Mirror-image prokaryotic A-site decoding region constructs were prepared in the natural D-series and the enantiomeric L-series and tested for binding to a series of aminoglycosides. In general, aminoglycosides bind to the D-series decoding region constructs with 2-3-fold higher affinities than they bind to the enantiomeric L-series. Moreover, L-neamine, the enantiomer of naturally occurring D-neamine, was prepared and shown to bind approximately 2-fold more weakly than D-neamine to the natural series decoding region construct, a result consistent with weakly stereospecific binding. The binding of naturally occurring D-neamine and its synthetic L-enantiomer was further evaluated with respect to binding to prokaryotic and eukaryotic ribosomes. Here, weak stereospecifcity was again observed with L-neamine being the more potent binder by a factor of approximately 2. However, on a functional level, unnatural L-neamine proved to inhibit in vitro translation with significantly lower potency (approximately 5-fold) than D-neamine. In addition, both L- and D-neamine are bacteriocidal toward Gram-(-) bacteria. L-Neamine inhibits the growth of E. coli and P. aeruginosa with 8- and 3-fold higher MIC than D-neamine. Interestingly, L-neamine also inhibits the growth of aminoglycoside-resistant E. coli, which expresses a kinase able to phosphorylate and detoxify aminoglycosides of the D-series. These observations suggest that mirror-image aminoglycosides may avoid certain forms of enzyme-mediated resistance.

Decoding region bubble size and aminoglycoside antibiotic binding.

Aminoglycoside antibiotics promiscuously bind to structurally diverse RNA molecules containing internal bubbles and bulges with affinities in the microM range. An interesting exception is found in the human 12S mitochondrial decoding region where aminoglycoside binding, unlike in the case of its bacterial and human cytoplasmic counterparts, is absent. Mutations that reduce the size of the bubble in the 12S decoding region immediately restore aminoglycoside binding, giving the system chemical switch like behavior.