AIBP augments cholesterol efflux from alveolar macrophages to surfactant and reduces acute lung inflammation.

Acute respiratory distress syndrome (ARDS) is characterized by an excessive pulmonary inflammatory response. Removal of excess cholesterol from the plasma membrane of inflammatory cells helps reduce their activation. The secreted apolipoprotein A-I binding protein (AIBP) has been shown to augment cholesterol efflux from endothelial cells to the plasma lipoprotein HDL. Here, we find that AIBP was expressed in inflammatory cells in the human lung and was secreted into the bronchoalveolar space in mice subjected to inhalation of LPS. AIBP bound surfactant protein B and increased cholesterol efflux from alveolar macrophages to calfactant, a therapeutic surfactant formulation. In vitro, AIBP in the presence of surfactant reduced LPS-induced p65, ERK1/2 and p38 phosphorylation, and IL-6 secretion by alveolar macrophages. In vivo, inhalation of AIBP significantly reduced LPS-induced airspace neutrophilia, alveolar capillary leak, and secretion of IL-6. These results suggest that, similar to HDL in plasma, surfactant serves as a cholesterol acceptor in the lung. Furthermore, lung injury increases pulmonary AIBP expression, which likely serves to promote cholesterol efflux to surfactant and reduce inflammation.

Preparation and characterization of the antibody recognizing AMACR inside its catalytic center.

Alpha-methylacyl-CoA racemase (AMACR) catalyzes the ß-oxidation of fatty acids and is overexpressed in carcinomas in various organs, while its inactivation results in the inhibition of cancer growth. In the present study, we prepared and characterized 20 different mouse monoclonal antibodies against human AMACR. In the course of biopanning of a phage peptide commercial library against in-house prepared 6H9 and 2A5, and commercial 13H4 antibodies, 10 phage mimotopes recognized by each type of the antibody were selected. Using the program Pepitope and the crystal structure of AMACR from Mycobacterium tuberculosis, we reveal for the first time, at least to the best of our knowledge, that the epitopes recognizing the antibody against AMACR are composed of conformation sequences localized inside the AMACR catalytic center. When delivered into live HeLa cells using cationic lipid-based PULSin reagent, the specific antibodies against AMACR were co-localized with peroxisomes. The in-house made 6H9 antibody exhibited a low level of this co-localization compared to the commercially available 63340 antibody, and did not inhibit the growth rate of HeLa and T98G cells. The results obtained suggest that antibody against AMACR may possess anti-AMACR catalytic activity and needs to be further investigated as a potential drug for use in anticancer therapy. On the whole, in this study, we generated several clones of AMACR antibodies and demonstrated that these antibodies can be colonized into live cells. Currently, we are testing the growth inhibitory properties of these antibodies against AMACR.

A Novel Monoclonal Antibody Against Alpha-Methylacyl-CoA Racemase Applicable for Paraffin-Embedded Tissues and Diagnostics of Prostate Cancer.

AMACR (alpha-methylacyl-CoA racemase) has been recently described as a prostate cancer-specific gene that encodes a protein involved in the beta-oxidation of branched chain fatty acids. Expression of AMACR protein is found in prostatic adenocarcinoma, but not in benign prostatic tissue. Thus, monoclonal antibodies (mAbs) for AMACR detection are an important tool for the diagnosis of AMACR-positive cancers. However, only a few mAbs, especially those applicable for immunohistochemistry (IHC), have been established to date. In this study, we describe the generation of a new hybridoma clone G8 producing anti-AMACR antibodies. G8 mAb specifically binds human AMACR and was successfully used in immunoblotting and immunofluorescence on paraformaldehyde-fixed cells and in IHC of paraffin-embedded tumor specimens. These results indicate that this new anti-AMACR mAb G8 would be useful in the diagnosis of AMACR-related cancers and would be a strong tool in both basic and clinical research on AMACR.

The value of triple antibody (34ßE12 + p63 + AMACR) cocktail stain in radical prostatectomy specimens with crushed surgical margins.

BACKGROUND: Triple antibody cocktail immunohistochemical staining is routinely used as an ancillary method to establish a diagnosis of prostate cancer in biopsies with small foci of atypical glands. Crush artefact can distort surgical margins in radical prostatectomy specimens, occasionally making it difficult to diagnose a positive margin. AIM: To investigate the ability of a cocktail stain to distinguish carcinoma from benign prostatic glands at the edge of crushed margins in prostatectomy specimens. METHODS: 10 radical prostatectomy specimens with crushed benign glands at the surgical margins, and 20 with crushed margins positive for carcinoma were retrieved from the pathology archives. The latter included 16 (80%) with positive apical margins, 2 (10%) incised intraprostatic margins, and 1 (5%) soft tissue margin. Two-colour triple antibody stain using a cocktail of antibodies against α-methylacyl coenzyme A racemase (AMACR), high molecular weight keratin and p63 was performed on all the selected cases. RESULTS: In 10/10 specimens with crushed benign glands, basal cell staining continued to be detectable, while AMACR staining was negative in all cases (0/10). In the positive margin cases, none of the crushed glands expressed basal cell marker staining (0/20), whereas 14/20 (70%) of the cases showed variable levels of AMACR positivity at the inked margin. CONCLUSION: Two-colour triple antibody cocktail stain is useful in the assessment of most, but not all, surgical margins with crushed artefact in prostatectomy specimens by helping to establish whether glands are malignant or benign.

Routine dual-color immunostaining with a 3-antibody cocktail improves the detection of small cancers in prostate needle biopsies.

We performed dual-color immunostaining with a 3-antibody cocktail (α-methylacyl coenzyme-A racemase, CK34betaE12, and p63) on prostate biopsies from 200 patients. Current practice (hematoxylin and eosin staining followed by dual-color immunostaining on selected cases) was compared with a protocol in which routine dual-color immunostaining was provided in all cases. In the original pathology reports, adenocarcinoma was diagnosed in 87/200 (43%) patients. Small foci interpreted as putative cancers were detected with dual-color immunostaining in 14/113 patients who were originally diagnosed with a nonmalignant lesion. All of the suggested cancerous foci were independently reevaluated by 5 pathologists. A diagnosis of adenocarcinoma was assessed by consensus in 8 cases, and atypical small acinar proliferation was diagnosed in 1 case. Consensus was not reached in 5 cases. Six of the foci reclassified as cancer were of Gleason score 3 + 3 = 6, while 2 were graded as Gleason score 4 + 4 = 8. The feasibility of routine dual-color immunostaining was also tested by analyzing the time spent on microscopic assessment. Because small, atypical lesions expressing α-methylacyl coenzyme-A racemase (blue chromogen) were easy to detect using dual-color immunostaining, the microscopic analysis of dual-color immunostaining and hematoxylin-eosin staining was faster than that of hematoxylin-eosin staining alone that was later followed by dual-color immunostaining in selected cases (median 251 seconds versus 299 seconds, P < .0001). We concluded that routine dual-color immunostaining of all prostate biopsies would produce better diagnostic sensitivity with a smaller microscopy workload for the pathologist. However, minute foci interpreted as cancer with dual-color immunostaining need to be confirmed with hematoxylin-eosin staining, and minimal criteria for a definitive diagnosis of cancer are still lacking.

Collecting duct carcinoma of the kidney: an immunohistochemical evaluation of the use of antibodies for differential diagnosis.

Collecting duct carcinoma is a highly aggressive renal epithelial malignancy, although it accounts for less than 1% of the incidence of renal epithelial neoplasms. Differential diagnoses between collecting duct carcinoma, pelvic urothelial carcinoma with marked invasion to the renal parenchyma (invasive urothelial carcinoma), and papillary renal cell carcinoma is often challenging. In our current study, we examined the utility of using commercially available antibodies, in conjunction with lectin histochemistry, for such differential diagnoses. We examined 17 cases of collecting duct carcinoma, 10 cases of invasive urothelial carcinoma and 15 cases of papillary renal cell carcinoma (type 1, 6 cases; type 2, 9 cases) in these evaluations. Our results indicated that Ulex europaeus agglutinin 1, E-cadherin, and c-KIT were frequently positive in collecting duct carcinoma and invasive urothelial carcinoma, in comparison with papillary renal cell carcinoma, which had negative results for CD10 and alpha-methylacyl CoA racemase. We found, however, that collecting duct carcinoma showed positivity for high-molecular-weight cytokeratin and low-molecular-weight cytokeratin at a low frequency compared with invasive urothelial carcinoma, and that these distinctions need further careful evaluation. In addition, high-molecular-weight cytokeratin positivity was not a reliable marker for collecting duct carcinoma. We conclude that Ulex europaeus agglutinin 1 reactivity and positivity for E-cadherin and c-KIT are effective in distinguishing collecting duct carcinoma from papillary renal cell carcinoma, and that negative results for alpha-methylacyl CoA racemase and CD10 are potentially useful hallmarks of this distinction also. In contrast, a differential diagnosis for collecting duct carcinoma and invasive urothelial carcinoma will require careful examination of multiple routinely stained specimens, particularly in cases of in situ neoplastic lesions in the pelvic mucosa.

Age-associated changes in alpha-methyl CoA racemase (AMACR) expression in nonneoplastic prostatic tissues.

Alpha-methyl CoA racemase (AMACR) is overexpressed in several human cancers, most notably colon and prostate. AMACR expression in the prostate has been investigated primarily in patients, in an older age group, treated for prostatic carcinoma and benign prostatic hypertrophy. No studies have assessed the age distribution of AMACR expression in normal men. Archival paraffin-embedded prostate tissue from 41 organ donor men (age range, 13-63 years) with no evidence of prostate neoplasia was stained with a monoclonal antibody for AMACR. Intensity was graded on a scale of 0 to 3. Semi-quantitative analysis of staining in acinar cells was used to generate a composite score (CS) [Sigma(% area x intensity)] for each case. Nondonor cases with foci of prostate cancer and high-grade prostatic intraepithelial neoplasia (PIN) were used as external positive controls for AMACR. These sections were also stained for Ki-67, to assess proliferative index. The 41 cases encompassed different age groups (13-20 years, N = 11; 20-45 years, N = 17; >45 years, N = 13). Acinar cells showed granular cytoplasmic staining. Focal positive staining was also seen in the prostatic urethra and the periurethral glands. There was wide variation in the level of expression within each age group. The level of expression seen in subjects younger than 45 years was higher (mean CS = 41.3; median CS = 22.5) than that seen in subjects older than 45 years (mean CS = 8.8; median CS = 9.0) with a P value of 0.01. Most cases in the control set of prostatic adenocarcinoma cases showed moderate to strong staining. A negative correlation was seen evaluating CS and age in subjects 20 years of age and older (r = -0.47). Ki-67 staining was variable. 1) AMACR expression can be seen in benign prostatic glandular epithelium, across all age groups. However, it is age-related, with significantly lower expression in subjects younger than 45 years. This could account for the negative staining reported in benign glands, due to biased sampling of the older population. 2) Focal positive staining is seen in the prostatic urethra and periurethral glands in 71% of the cases, with no age correlation. This is of concern because this epithelium could potentially be misinterpreted as foci of PIN. 3) The low expression of AMACR in benign glands in the older age group makes this marker useful in detecting malignancy. However, AMACR staining should be interpreted with caution and the diagnosis of PIN or prostate cancer should be rendered only with convincing histologic evidence. 4) Ki-67 staining was very variable and showed no correlation with age and AMACR expression levels. AMACR expression had no correlation with proliferative index.

Humoral immune response to alpha-methylacyl-CoA racemase and prostate cancer.

BACKGROUND: Although prostate-specific antigen (PSA) is a prototypic biomarker for prostate cancer, it has poor specificity. Expression of alpha-methylacyl-CoA racemase (AMACR), which is involved in the conversion of R-stereoisomers of branched-chain fatty acids to S-stereoisomers, has been shown to be specifically increased in prostate cancer epithelia. However, attempts to detect AMACR in circulation have not been successful. Hence, we determined whether an immune response to AMACR could be used as a serum biomarker for prostate cancer. METHODS: Sera from patients with biopsy-proven prostate cancer and from control subjects were screened for a humoral immune response to selected tumor antigens, including AMACR, by using protein microarrays (46 patients, 28 control subjects). Humoral immune response to AMACR was then validated using high-throughput immunoblot analysis (151 patients, 259 control subjects) and enzyme-linked immunosorbent assay (ELISA) (54 patients, 55 control subjects). Receiver operating characteristic curves were used to determine the sensitivity and specificity of the immune response to AMACR to detect prostate cancer. RESULTS: Immunoreactivity against AMACR was statistically significantly higher in sera from patients with prostate cancer than in control subjects by all three techniques (P(protein microarray) =.009, P(immunoblot)<.001, P(ELISA) =.011). High-throughput immunoblot analysis revealed that, in subjects with intermediate PSA levels (4-10 ng/mL), the immune response against AMACR was more sensitive and specific than was PSA in distinguishing sera from prostate cancer patients relative to control subjects (sensitivity and specificity of 77.8% and 80.6% versus 45.6% and 50%, respectively; area under the curve of 0.789 versus 0.492; P<.001). CONCLUSION: Assays to detect a humoral immune response against AMACR may have the potential to supplement PSA screening in identifying patients with clinically significant prostate cancer, especially those with intermediate PSA levels.

[Value of the antibody cocktail anti p63 + anti p504s for the diagnosis of prostatic cancer]. / Apport d'un cocktail d'anticorps anti-(p63 + p504s) dans le diagnostic de cancer de prostate.

UNLABELLED: Numerous lesions of the prostate, such as atrophy, adenomatous atypical hyperplasia (adenosis) or PIN can be misdiagnosed with prostatic cancer, and confused with ASAP, leading to perform additional biopsies. In such lesions, the pathologist can perform an immunohistochemical study with the anti-high molecular weight cytokeratin antibody CK903 (34bE12), which confirms the absence of basal cells and supports the diagnosis of prostatic cancer. AIM OF THE STUDY: To compare markers of basal cells (cytokeratin 5/6, p63) and the marker of prostatic carcinomatous glands (p504s) or alpha methylacyl-CoA racemase (AMACR). MATERIAL AND METHODS: Retrospective study of 44 cases of paraffin-embedded prostatic specimens (36 biopsies, 4 PER, 1 adenomectomy and 3 radical prostatectomies), consisting in 20 cases of prostatic carcinomas (2 intraductal, 12 Gleason 6 (3+3), 4 Gleason 7 (4+3), 2 Gleason 8 (4+4)), 11 ASAP, 9 PIN (2 low grade, 7 high grade (2 isolated)), and 10 benign lesions (8 atrophy, 1 atypical adenomatous hyperplasia and 1 case of clear cell cribriform hyperplasia). All cases were tested with antibodies to CK 5/6, and with a cocktail to p63 and p504s, after heat antigenic retrieval on NEXES Ventana processor. RESULTS: Basal cells of normal prostatic glands stained with CK5/6 and p63 in 91,3% and 100% of cases, independently from the fixation procedure (Bouin or Formalin). Carcinomas had a p63-/p504s+ profile, PIN were p63+/p504s+, and benign lesions were p63+/p504s-. We observed an increase in sensitivity: p63/p504s (100%), CK5/6 (80%), p63 (90%), p504s (95%), and specificity: p53/p504s (90%), CK5/6 (87.5%), p63 (90.5%), p504s (90.9%). CONCLUSION: Our results show that the use of a cocktail to p63/p504s is more specific than the use of CK5/6 alone this technique supports a diagnosis of prostatic cancer in 40% of cases previously considered as ASAP.

Use of p63/P504S monoclonal antibody cocktail in immunohistochemical staining of prostate tissue.

Diagnosis of prostate needle biopsies can be challenging, particularly when the atypical areas of interest are very small. The utility of immunostains for high-molecular-weight cytokeratin (34betaE12) to highlight prostatic basal cells in these cases is well established, and recent reports also document the utility of immunostains for p63 (a marker that stains the nuclei of prostate basal cells) for this purpose. Several investigators have demonstrated that immunostaining for P504S, a cytoplasmic protein that is overexpressed in a high percentage of prostate cancers and in many cases of high-grade prostatic intraepithelial neoplasia (PIN), can also be of use in the diagnosis of prostate biopsies. Because of the cytoplasmic localization of P504S and nuclear localization of p63, the authors hypothesized that a cocktail of these two antibodies might allow simultaneous demonstration of P504S and p63 using a single immunostain. In this report the authors describe the successful use of a cocktail of p63/P504S for immunohistochemical staining of prostate tissue. Two different staining approaches were investigated, with essentially identical results. This cocktail localizes P504S in the cytoplasm of prostate carcinoma cells and high-grade PIN and demonstrates the nuclei of prostatic basal cells, providing information on both the status of P504S and the presence or absence of basal cells with a single immunostain. This cocktail can be of great utility in the examination of diagnostically challenging prostate specimens.

Diagnostic usefulness of monoclonal antibody P504S in the workup of atypical prostatic glandular proliferations.

We stained 37 prostate needle biopsies and 3 transurethral resections (TURP) containing atypical foci and 20 morphologically unequivocal prostate cancer biopsies, including 4 with foamy features, with P504S. Of 20 biopsies with unequivocal cancer, 18 showed variable P504S staining (sensitivity, 90%); 1 minute cancer and 1 foamy cancer lacked P504S staining. Of 40 cases with atypical foci (biopsies, 37; TURP, 3), 9 were diagnosed as high-grade prostatic intraepithelial neoplasia (HGPIN), 2 were excluded, and 29 had foci of atypical small glandular proliferation. Of these 29 cases, 7 were highly suggestive of cancer, 2 of which lacked P504S staining. In 22 cases with benign atypical foci, 11 were diagnosed as postatrophic hyperplasia (none expressed P504S) and 7 as atypical adenomatous hyperplasia (AAH; 1 showed focal weak P504S staining). Of 9 HGPIN specimens, 8 showed predominantly diffuse, moderate P504S staining. P504S has slightly lower sensitivity for detection of prostate cancer than found previously. Heterogeneous expression patterns may explain negativity in some biopsy specimens with minute cancer. In atypical small glandular proliferations, diffuse positive P504S staining in atypical glands strongly supports a cancer diagnosis, but negative staining does not exclude it. P504S seems to have low sensitivity for detecting foamy prostate cancer. Most HGPINs show diffuse moderate P504S staining. AAH may show focal P504S staining. We recommend using P504S along with morphologic examination and conventional basal cell markers.

Detection of alpha-methylacyl-coenzyme A racemase in postradiation prostatic adenocarcinoma.

OBJECTIVES: To assess the utility of alpha-methylacyl-coenzyme A racemase (AMACR), also known as P504S, immunohistochemistry in the detection of postradiation prostatic adenocarcinoma in surgical specimens. Pathologic diagnosis of postradiation prostate cancer is difficult because of the radiation-induced cytologic changes in benign and malignant epithelial cells. AMACR/P504S is a recently identified molecular marker for prostatic adenocarcinoma. It has been demonstrated that AMACR is overexpressed in the vast majority of prostatic adenocarcinoma cases by cDNA microarray, RNA analysis, Western blotting, and immunohistochemistry. METHODS: A total of 80 prostate glands, including 40 irradiated prostate specimens (28 with adenocarcinoma and 12 benign prostates) and 40 nonirradiated prostate specimens (20 with adenocarcinoma and 20 benign prostates), were examined. The specimens were obtained after salvage radical prostatectomy (n = 25), transurethral resection (n = 4), or needle biopsy (n = 11). All samples were immunohistochemically analyzed for AMACR. RESULTS: All 48 carcinoma cases (28 of 28 irradiated and 20 of 20 nonirradiated specimens) showed strongly positive AMACR/P504S immunostaining. AMACR immunostaining was negative for all irradiated (n = 12) and nonirradiated (n = 20) benign prostates, as well as the irradiated benign glands adjacent to carcinoma. 34betaE12 confirmed the presence of basal cells in all benign prostates (32 of 32) and the absence of basal cells in carcinoma (0 of 48). CONCLUSIONS: Our results demonstrate that AMACR is a highly specific and sensitive indicator of postradiation prostate cancer. AMACR immunostaining facilitates the challenging differentiation between prostatic adenocarcinoma and radiation-induced atypia in benign prostatic epithelium and may be of exceptional value in limited needle biopsies.

P504S immunohistochemical detection in 405 prostatic specimens including 376 18-gauge needle biopsies.

P504S is a recently described, prostate cancer-specific gene that encodes a protein involved in the beta-oxidation of branched chain fatty acids. A recent study has shown that immunohistochemical detection of P504S gene product is a sensitive and specific marker of prostatic carcinoma in formalin-fixed, paraffin-embedded tissues. We performed a detailed analysis of P504S protein expression in a large series of prostate and bladder specimens with special emphasis on staining in specific morphologic patterns of prostatic adenocarcinoma, posthormonal and radiation therapy cases, and invasive urothelial carcinoma. A total of 366 prostate needle core biopsies from 124 patients with prostate cancer, 10 biopsies from 2 patients without prostate cancer, 28 prostatectomy specimens (16 with specific morphologic patterns, 7 posthormonal therapy and 5 postradiation therapy specimens), 5 bladder specimens with invasive urothelial carcinoma, and a single transurethral resection specimen from a patient with hormonally treated prostate cancer and invasive urothelial carcinoma were stained with P504S monoclonal antibody at a 1:250 dilution using standard heat-induced epitope retrieval and avidin-biotin technique. Extent (0, no staining; 1+, 1-10% staining; 2+, 11-50% staining; 3+, > or =51% staining) and location (luminal, subluminal, and diffuse cytoplasmic) of immunoreactivity in carcinoma and benign tissues were recorded. A total of 153 of 186 biopsies (82%) with prostatic adenocarcinoma stained for P504S. Pseudohyperplastic, atrophic, ductal, and mucinous prostatic carcinomas stained similarly, as did cases treated with hormone or radiotherapy. In 81 of 377 (21%) foci of benign prostatic tissue there was staining that was almost always focal, faint, and noncircumferential. Seminal vesicles did not stain for P504S. Five of six (83%) specimens with invasive urothelial carcinoma had 2+ staining and one case had focal staining. We conclude that immunohistochemistry for P504S has potential utility in the diagnosis of prostate cancer, including those treated by hormones and radiation. Circumferential luminal to subluminal and diffuse cytoplasmic staining is the most specific staining pattern for prostatic carcinoma and is almost never associated with benign prostatic tissue. However, a negative P504S immunostain does not automatically rule out prostate cancer, as 18% of cases were negative. Additionally, occasional benign glands, high-grade prostatic intraepithelial neoplasia, atypical adenomatous hyperplasia, and urothelial carcinoma may express P504S. Therefore, we think that P504S is best used only in conjunction with strict light microscopic correlation and preferably with high molecular weight cytokeratin immunostaining.

Involvement of coenzyme A esters and two new enzymes, an enoyl-CoA hydratase and a CoA-transferase, in the hydration of crotonobetaine to L-carnitine by Escherichia coli.

Two proteins (CaiB and CaiD) were found to catalyze the reversible biotransformation of crotonobetaine to L-carnitine in Escherichia coli in the presence of a cosubstrate (e.g., gamma-butyrobetainyl-CoA or crotonobetainyl-CoA). CaiB (45 kDa) and CaiD (27 kDa) were purified in two steps to electrophoretic homogeneity from overexpression strains. CaiB was identified as crotonobetainyl-CoA:carnitine CoA-transferase by MALDI-TOF mass spectrometry and enzymatic assays. The enzyme exhibits high cosubstrate specificity to CoA derivatives of trimethylammonium compounds. In particular, the N-terminus of CaiB shows significant identity with other CoA-transferases (e.g., FldA from Clostridium sporogenes, Frc from Oxalobacter formigenes, and BbsE from Thauera aromatica) and CoA-hydrolases (e.g., BaiF from Eubacterium sp.). CaiD was shown to be a crotonobetainyl-CoA hydratase using MALDI-TOF mass spectrometry and enzymatic assays. Besides crotonobetainyl-CoA CaiD is also able to hydrate crotonyl-CoA with a significantly lower Vmax (factor of 10(3)) but not crotonobetaine. The substrate specificity of CaiD and its homology to the crotonase confirm this enzyme as a new member of the crotonase superfamily. Concluding these results, it was verified that hydration of crotonobetaine to L-carnitine proceeds at the CoA level in two steps: the CaiD catalyzed hydration of crotonobetainyl-CoA to L-carnitinyl-CoA, followed by a CoA transfer from L-carnitinyl-CoA to crotonobetaine, catalyzed by CaiB. When gamma-butyrobetainyl-CoA was used as a cosubstrate (CoA donor), the first reaction is the CoA transfer. The optimal ratios of CaiB and CaiD during this hydration reaction, determined to be 4:1 when crotonobetainyl-CoA was used as cosubstrate and 5:1 when gamma-butyrobetainyl-CoA was used as cosubstrate, are different from that found for in vivo conditions (1:3).

2-Arylpropionyl-CoA epimerase: partial peptide sequences and tissue localization.

The R-enantiomers of 2-arylpropionic acids (2-APAs) such as ibuprofen (IBU) exhibit the phenomenon of species- and substrate-dependent metabolic chiral inversion. Only R-enantiomers are activated to acyl-CoA-thioesters by an acyl-CoA-synthetase via an adenylate intermediate. The acyl-CoA-thioesters are substrates for an epimerase, which is responsible for chiral inversion. A 42 kDa epimerase from the cytosolic fraction of rat livers was isolated and purified to homogeneity. Polyclonal antibodies were raised against the epimerase in rabbits. The anti-epimerase antibodies were used for affinity column chromatography to separate homogeneous protein for amino acid sequence analysis. Sequence data analysis of 3 internal peptide sequences showed 50% and more homology with regions of enzymes involved in fatty acid metabolism. The polyclonal anti-epimerase antibodies were used to analyze the tissue distribution of the in guinea pigs and rats by Western blot analysis. Furthermore, the correlation of inversion enzyme activity in various tissues under comparable incubation conditions and cross-reactivity in Western blot analysis was investigated.

Induction, identification, and cell-free translation of mRNAs coding for peroxisomal proteins in Candida tropicalis.

Peroxisomes have been purified from Candida tropicalis grown on oleic acid and shown to be nearly pure by marker enzyme analysis, electron microscopy, and comparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. They contain approximately 20 polypeptides, among which acyl-CoA oxidase, trifunctional hydratase-dehydrogenase-epimerase, and catalase have been identified. Rabbit antisera have been elicited that react with these three proteins. When C. tropicalis is grown on alkanes, a dozen mRNAs are strikingly induced. Nine of the 12 induced mRNAs code for polypeptides that comigrate in sodium dodecyl sulfate-polyacrylamide gel electrophoresis with peroxisomal proteins, among which three have been identified immunochemically as the acyl-CoA oxidase, the trifunctional protein, and catalase. These results indicate that some genes coding for peroxisomal proteins are strongly expressed during growth of C. tropicalis on alkanes. The data are consistent with evidence in other species that peroxisomes form by the post-translational incorporation of newly made proteins into pre-existing peroxisomes, generally without proteolytic processing, followed by peroxisome division.

Accelerated aging due to enzymatic racemization.

Thermodynamic racemization may be a cause of aging. Racemases might accelerate the aging process. If enzymatic racemization does accelerate aging, then the use of chemical or immunological inhibitors of racemases might retard aging.