Matrix Metalloproteinases -14, -9 and -2 are Localized to the Podosome and Involved in Podosome Development in the A7r5 Smooth Muscle Cell.

AIM: The purpose of the study was to localize matrix metalloproteinase (MMP)-14, -9, and -2 in the A7r5 smooth muscle cell and to understand the interaction between these MMPs and the cytoskeleton. This interaction was observed under non-stimulating and phorbol 12, 13-dibutyrate (PDBu)-stimulating conditions. METHODS: Confocal microscopy was utilized to define the localizations of MMPs and tissue inhibitor of matrix metalloproteinases (TIMPs) in the A7r5 cell and to determine interaction between MMPs and the cytoskeleton. Under PDBu-stimulating conditions, the presence of MMP active forms and activity by gel zymography was evaluated in the A7r5 cell. Actin and microtubule-polymerization inhibitors were used to evaluate MMP interaction with the cytoskeleton and the cytoskeleton was observed on matrix and within a Type I collagen gel. RESULTS: MMP-14, -9, and -2 were localized to the podosome in the A7r5 smooth muscle cell and interactions were seen with these MMPs and the actin cytoskeleton. PDBu-stimulation induced increases in the protein abundance of the active forms of the MMPs and MMP-2 activity was increased. MMPs also interact with a-actin and not ß-tubulin in the A7r5 cell. Galardin, also known as GM-6001, was shown to inhibit podosome formation and prevented MMP localization to the podosome. This broad spectrum MMP inhibitor also prevented collagen gel contraction and prevented cell adhesion and spreading of A7r5 cells within this collagen matrix. CONCLUSION: MMPs are important in the formation and function of podosomes in the A7r5 smooth muscle cell. MMPs interact with a-actin and not ß-tubulin in the A7r5 cell. Podosomes play an important role in cell migration and understanding the function of podosomes can lead to insights into cancer metastasis and cardiovascular disease.

FRET analysis of actin-myosin interaction in contracting rat aortic smooth muscle.

We examined the interaction of smooth muscle myosin with alpha-actin and beta-actin isoforms during the contraction of A7r5 smooth muscle cells and rat aortic smooth muscle. The techniques of confocal microscopy and fluorescence resonance energy transfer (FRET) analysis were utilized in examining A7r5 cells and rat aortic rings contracted with phorbol 12,13-dibutyrate. Visual evaluation of confocal images of A7r5 smooth muscle cells contracted by phorbol 12,13-dibutyrate indicated significant disassociation of myosin from alpha-actin but not beta-actin. Whole-cell FRET analysis confirmed these observations (alpha-actin-myosin -67%, beta-actin-myosin -2%). Time course studies further showed that alpha-actin-myosin complex increased significantly (40%) within 1.5 min after the addition of phorbol 12,13-dibutyrate and then declined as contraction progressed. FRET analysis of rat aortic rings at different intervals of contraction indicated significant increases in alpha-actin-myosin at the initiation (79%) and plateau (67%) in force development, but not during the intermediate period of slowly developing tension (-4%). By comparison, beta-actin-myosin complex was unchanged except during slow force development, in which the association was significantly decreased (-30%). Similar to that of alpha-actin-myosin, Alexa 488 - phalloidin staining fluorescence indicated increased tissue F-actin content at the initiation (21%) and plateau (62%) in force. FRET images indicated the development of thickened cables and patches of alpha-actin-myosin in tissue throughout the interval of contraction. The results provide direct evidence of dynamic remodeling of the contractile protein during vascular smooth muscle contraction and suggest that FRET analysis may be a powerful tool for assessment of tissue protein-protein associations.

PGF2alpha-associated vascular smooth muscle hypertrophy is ROS dependent and involves the activation of mTOR, p70S6k, and PTEN.

Prostaglandin F2alpha (PGF2alpha) increases reactive oxygen species (ROS) and induces vascular smooth muscle cell (VSMC) hypertrophy by largely unknown mechanism(s). To investigate the signaling events governing PGF2alpha-induced VSMC hypertrophy we examined the ability of the PGF2alpha analog, fluprostenol to elicit phosphorylation of Akt, the mammalian target of rapamycin (mTOR), ribosomal protein S6 kinase (p70S6k), glycogen synthase kinase-3beta (GSK-3beta), phosphatase and tensin homolog (PTEN), extracellular signal-regulated kinase 1/2 (ERK1/2) and Jun N-terminal kinase (JNK) in growth arrested A7r5 VSMC. Fluprostenol-induced hypertrophy was associated with increased ROS, mTOR translocation from the nucleus to the cytoplasm, along with Akt, mTOR, GSK-3beta, PTEN and ERK1/2 but not JNK phosphorylation. Whereas inhibition of phosphatidylinositol 3-kinase (PI3K) by LY-294002 blocked fluprostenol-induced changes in total protein content, pre-treatment with rapamycin or with the MEK1/2 inhibitor U0126 did not. Taken together, these findings suggest that fluprostenol-induced changes in A7r5 hypertrophy involve mTOR translocation and occur through PI3K-dependent mechanisms.

Load-induced focal adhesion mechanotransduction is altered with aging in the Fischer 344/NNiaHSd x Brown Norway/BiNia rat aorta.

The focal adhesion kinase (FAK) pathway has emerged as a critical component for mediating numerous cellular responses including control of cell growth, differentiation, and adaptation. Here we compared the expression, basal activation, and the ability of increased intraluminal pressure to activate FAK and focal adhesion-associated proteins in the aorta of adult (6 months old) and very aged (36 months old) Fischer 344/NNiaHSd x Brown Norway/BiNia (F344/NXBN) rats. Immunoblot analysis showed increases in the aortic content of FAK (15%), FAK related non-kinase (p41-FRNK) (28%), Src (92%), RhoA (41%), and paxillin (23%) in the very aged aortae. Increased age significantly changed the basal phosphorylation status of FAK and paxillin. Application of aortic intraluminal pressure (200 mm Hg) amplified the phosphorylation of FAK (Tyr 925), Src (Tyr 416), and paxillin (Tyr 188) in adult animals while aortic loading in the very aged animals failed to induce FAK (Tyr 925) phosphorylation. Aging did not alter the load-induced regulation of RhoA; however, FRNK (p41) translocation between cytosolic and membrane compartments was increased. These results confirm previous observations that FAK and focal adhesion-associated proteins are mechanically regulated and expand these studies to suggest that FAK mechanotransduction is altered with aging.

Aging alters mechanical and contractile properties of the Fisher 344/Nnia X Norway/Binia rat aorta.

Vascular mechanical and contractile properties were compared in adult (6 months old) and very-aged (36 months old) Fischer 344/NNiaHSd X Brown Norway/BiNia (F344/NXBN) rats. Our previous work has indicated that aging is associated with aortic medial thickening. This morphological alteration was accompanied by a leftward shift in the aortic stress/strain curve indicating increased vessel stiffness in very-aged animals. Disruption of the endothelium as well as pretreatment of tissues with the nitric oxide (NO) donor sodium nitroprusside eliminated differences, suggesting a link between deficient endothelial NO release and reduced compliance in very-aged aortae. In addition, the Rho kinase inhibitor Y-27632 increased vessel compliance in both adult and very-aged tissues suggesting that the Rho cascade contributed to the stress/strain relationship. Maximal force developed in response to high potassium (K(+)) was reduced by approximately 70% in intact and endothelium-denuded aortae from very-aged rats. In contrast to contractile force development, calcium-dependent stress relaxation was increased in very-aged aorta. Finally, gel electrophoresis indicated a significantly higher tissue content of myosin heavy chain and a higher ratio of SM1/SM2 isoforms with aging. The results suggest multiple molecular changes with aging, which may be expected to alter vascular tissue function.

Differential actin isoform reorganization in the contracting A7r5 cell.

In the present study, we investigated the reorganization of alpha- and beta-actin in the contracting A7r5 smooth muscle cell. The remodeling of these actin variants was markedly different in response to increasing concentrations of phorbol 12, 13-dibutyrate (PDBu). At the lowest concentrations (< or =10(-7) mol/L), cells showed an approximately 70% loss in alpha-actin stress fibers with robust transport of this isoform to podosomes. By comparison, beta-actin remained in stress fibers in cells stimulated at low concentrations (< or =10(-7) mol/L) of PDBu. However, at high concentrations (> or =10(-6)mol/L) approximately 50% of cells showed transport of beta-actin to podosomes. Consistent with these findings, staining with phalloidin indicated a significant decrease in the whole-cell content of F-actin with PDBu treatment. However, staining with DNase I indicated no change in the cellular content of G-actin, suggesting reduced access of phalloidin to tightly packed actin in the podosome core. Inhibition of protein kinase C (staurosporine, bisindolymaleimide) blocked PDBu-induced (5 x 10(-8) mol/L) loss in alpha-actin stress fibers or reversed podosome formation with re-establishment of alpha-actin stress fibers. By comparison, these inhibitors caused partial loss of beta-actin stress fibers. The results support our earlier conclusion of independent remodeling of alpha- and beta-actin cytoskeletal structure and suggest that the regulation of these structures is different.

Aging alters vascular mechanotransduction: pressure-induced regulation of p70S6k in the rat aorta.

Physical forces are important regulators of vascular structure and function though it is unknown how aging may affect the ability of the vasculature to respond to mechanical stimuli. We investigated the pressure-induced activation of ribosomal S6-kinase (p70S6k) and its pathway-related proteins (Akt, GSK-3beta, SHP-2, PTEN) in aortae from young adult (6 month), aged (30 month), and very aged (36 month) Fischer 344 x Brown Norway F1 hybrid rats. With aging, the aortic tissue content of Akt. SHP-2, and PTEN was significantly increased while total p70S6k and GSK-3beta were unchanged. By comparison, the basal phosphorylation of p70S6k at Thr 389 and Thr 421/Ser 424 was increased ( approximately 40%) and unchanged, respectively, while Akt decreased (approximately 37%), GSK-3beta was unchanged, SHP-2 increased (approximately 73.5%), and PTEN increased (approximately 120%) in the aortae of very aged rats. Acute pressurization of aortae resulted in similar increases in phosphorylation of Akt among the different age groups. By comparison, pressure-induced phosphorylation of p70S6k at Thr 389, GSK-3beta and SHP-2 decreased; whereas, PTEN dephosphorylation was increased in 36-month versus 6-month aortae. The results indicate marked alterations in the p70S6k signaling pathway with aging. The implications of these findings on age-associated vessel remodeling are discussed.

Regulation of p70S6k, GSK-3beta, and calcineurin in rat striated muscle during aging.

In this study we compared the content and phosphorylation levels of several molecules believed to regulate muscle hypertrophy and fiber type changes in the extensor digitorum longus (EDL), soleus, diaphragm, and heart of adult (6 months), aged (30 months), and very aged (36 months) Fischer 344 x Brown Norway rats. With aging, the mass of the EDL and soleus decreased significantly (approximately 38% and approximately 36%, respectively), the diaphragm's mass remained unchanged while the mass of the heart increased (approximately 35%). Western blotting demonstrated that calcineurin (CnA), the 70-kDa ribosomal S6 kinase (p70(S6k)), glycogen synthase kinase-3beta (GSK-3beta), and the phosphorylated forms of GSK-3beta and p70(S6k) (p-GSK-3beta(Ser9) and p-p70(S6kThr389)) were regulated differently with aging and between muscle types. Total p70(S6k), GSK-3beta, and p-GSK-3beta(Ser9) decreased in the aged-atrophic EDL and soleus while p-p70(S6kThr389) increased. Although total p70(S6k) content diminished in the continuously active diaphragm, phosphorylation of p70(S6k )remained unchanged. Conversely, the expression of GSK-3beta and p-GSK-3beta(Ser9) increased in the diaphragm. With aging, the amount of p-p70(S6kThr389) decreased approximately 56% in the heart while p-GSK-3beta( Ser9) increased approximately 193%. Interestingly, CnA content remained unchanged in the diaphragm, increased approximately 204% in the EDL, and decreased approximately 30% and approximately 65% with aging in the soleus and heart, respectively. These results indicate remarkable differences in the regulation of molecules thought to govern protein synthesis and changes in contractile protein expression.

Effects of aging on pressure-induced MAPK activation in the rat aorta.

With increasing age, the cardiovascular system experiences substantial alterations in cellular morphology and function. Whilst the factors regulating these changes are unknown, the mitogen-activated protein kinase (MAPK) pathways have emerged as critical components for mediating numerous cellular responses including control of cell growth, differentiation and adaptation. Here we compare the expression, basal activation and the ability of increased pressure to activate the MAPK pathways in adult (6-month-old), aged (30-month-old) and very aged (36-month-old) Fischer 344xBrown Norway F1 hybrid rats. Histochemical analysis demonstrated an age-related increase in tunica media thickness of approximately 11 and 21% in aortae from aged and very aged animals, respectively. Western blot analysis of the MAPK family extracellular signal-regulated kinase (ERK 1/2), p38, and c-Jun NH2 -terminal kinase (JNK) MAPKs showed differential expression and activation among these proteins with age. Expression of ERK 1/2, p38, and JNK were unchanged, slightly increased (10+/-17.5%) or significantly increased (72.3+/-27%), respectively, in very aged aortae. In contrast, basal activation levels of these proteins were reduced (-26.2+/-7.4%), markedly increased (97.0+/-16.8%), and slightly increased (14.4+/-4.5%), respectively, in very aged compared with 6-month rat aortae. An acute increase of aortic intraluminal pressure (200 mmHg) indicated that ERK 1/2 regulation differed from p38 or JNK. Pressure loading-induced phosphorylation of ERK1/2 was unchanged or increased with aging while p38 and JNK phosphorylation was attenuated (P<0.01). These observations confirm previous conclusions that MAPK proteins are regulated mechanically and expand these studies to suggest that MAPK expression and the control of activation are changed with aging.

Effect of fasting on vascular contractility in lean and obese Zucker rats.

We compared the effects of fasting (36 h) on blood pressure and aortic contractile responsiveness in lean and obese Zucker rats. Fasting of lean animals resulted in a significant loss in body weight (-9.1 +/- 0.1%) and reduction in systolic blood pressure (-11.4 +/- 1.9 mmHg). Fasting plasma triacylglycerols (-76%) and beta-hydroxybutryic acid (beta-HBA) (+ 218%) were significantly decreased and increased, respectively. The fasting plasma concentrations of insulin (-72%) were significantly decreased, whereas glucose and epinephrine (Epi) were not changed in lean rats. The fasting of obese rats also resulted in weight loss (-5.6 +/- 1.3%) but did not cause a significant reduction of blood pressure. The plasma total cholesterol (+18%) was increased, triacylglycerols (-42%) were decreased and beta-HBA levels were unchanged in fasted obese rats. Similar to lean animals, the insulin levels of fasted obese rats were significantly decreased (-85%), whereas glucose and Epi concentrations were not significantly changed. Fasting of lean animals had no effect on the maximal contractile response of aortae to high K(+) and phorbol 12, 13 dibutyrate (PDBu) but significantly reduced the response to norepinephrine (NE) (% reference: fed, 61.1 +/- 11.0; fasted, 45.6 +/- 4.5). In addition, the concentration for half-maximal response (ED(50)) to NE was increased in fasted lean rats (fed, 1.8+/-0.2 x 10(-8)M; fasted, 3.0+/-0.3 x 10(-8)M). By comparison, fasting of obese rats had no significant effect on the contractile response to K(+), NE, or PDBu. The results show that short-term food withdrawal induces significant changes in vascular contractile properties of lean but not obese rats. Because fasting-induced changes were variable depending on the agonist, the results further suggest that the mechanism did not involve a general loss or enhancement in functional status.

Microtubule-dependent PKC-alpha localization in A7r5 smooth muscle cells.

Using laser scanning confocal, fluorescence resonance energy transfer (FRET), and atomic force (AFM) microscopy, we investigated association of protein kinase C (PKC)-alpha with microtubules during stimulus-induced relocalization in A7r5 smooth muscle cells. Confocal microscopy with standard immunostaining techniques confirmed earlier observations that colchicine disruption of microtubules blocked PKC-alpha localization in the perinuclear region of the cell caused by phorbol 12,13-dibutyrate (PDBu; 10-6M). Dual immunostaining suggested colocalization of PKC-alpha and beta-tubulin in both unstimulated and PDBu-treated cells. This finding was verified by FRET microscopy, which indicated that association of PKC-alpha was heterogeneous in distribution and confined primarily to microtubules in the perinuclear region. FRET analysis further showed that association between the molecules was not lost during colchicine-induced dissolution of microtubules, suggesting formation of tubulin-PKC-alpha complexes in the cytosol. Confocal imaging indicated that perinuclear microtubular structure was more highly sensitive to colchicine dissolution than other regions of the cell. Topographic imaging of fixed cells by AFM indicated a well-defined elevated structure surrounding the nucleus that was absent in colchicine-treated cells. It was calculated that the volume of the nuclear sleevelike structure of microtubules increased approximately fivefold in PDBu-treated cells, suggesting a probable increase in microtubular mass. In light of PKC-alpha localization, increased colchicine sensitivity, and their volume change in stimulated cells, the results suggest that perinuclear microtubules form a specialized structure that may be more dynamically robust than in other regions of the cell. PKC-alpha could contribute to this dynamic activity. Alternatively, perinuclear microtubules could act as a scaffold for regulatory molecule interaction at the cell center.

Myosin remodelling in the contracting A7r5 smooth muscle cell.

AIM: Using confocal microscopy and standard immunohistochemical techniques, changes in the structure of alpha-actin and beta-actin as well as the distribution of myosin II were studied in the contracting A7r5 smooth muscle cell. RESULTS: Prior to stimulation, each of the three proteins were incorporated into filamentous structures extending the length of the cell body. At 30 min after stimulation by phorbol 12, 13 dibutyrate (PDBu), the system of densely packed beta-actin fibres was retained. By comparison, alpha-actin and myosin were observed to undergo significant remodelling, characterized by loss in fibre structure and the formation of brightly fluorescing peripheral bodies. Co-immunoprecipitation of alpha-actin and myosin II suggested an association between the proteins. Consistent with this observation, dual immunostaining for alpha-actin and myosin revealed strong co-localization of the two proteins prior to stimulation. Following PDBu stimulation myosin II was observed to partially disassociate from alpha-actin structure but showed significant co-localization with alpha-actin filaments and peripheral bodies throughout the interval of contraction. The use of cytochalasin B to block actin polymerization or the selective dissolution of alpha-actin cable structure by thapsigargin produced similar patterns of change in alpha-actin structure and the localization of myosin II. CONCLUSION: The results support the concept of myosin liability and potential for remodelling. The results suggest that myosin undergoes extensive relocalization in association with alpha-actin remodelling which may be an important determinant of contractile function in the A7r5 smooth muscle cell.

Effect of vitamin A deficiency on cardiovascular function in the rat.

Selected parameters of cardiovascular function were evaluated in vitamin A-deficient rats at 70 days of age. Resting heart rate was increased by an average of 100 bpm (21.4+/-2.7%), whereas resting systolic blood pressure was normal in vitamin A-deficient animals. The maximal contractile force developed per milligram weight of tissue by aortic rings excised from vitamin A-deficient animals was reduced in response to high potassium (-25.0+/-8.7%) and phorbol 12,13-dibutyrate (-36.8+/-8.4%) but was only slightly reduced in response to norepinephrine (-17.8+/-11.1%). Intimal rubbing to remove the endothelium had no effect on the loss in contractile responsiveness, and the relaxant response to acetylcholine was similar between control and vitamin A-deficient tissue groups. This suggests that the decrease in contractility of vascular smooth muscle from the vitamin A-deficient rats did not involve altered release of endothelium-derived vasoactive factors. Western blot analysis suggested a reduction in the protein levels of several differentiation markers including alpha-actin (-22%), calponin (-37%), desmin (-37%), and vinculin (-40%), whereas the level of PKCalpha was unchanged from control values. Our findings indicate a significant decrease in contractile responsiveness of aortic smooth muscle of the vitamin A-deficient rat that may be associated with a down regulation in the expression of contractile-related proteins.

PKC-alpha shows variable patterns of translocation in response to different stimulatory agents.

Reports from numerous laboratories suggest that protein kinase C (PKC) translocation to substrate target sites may vary depending on cell type and experimental conditions. We have proposed that acutely variable targeting of PKC to different substrate sites could greatly expand the functional properties of individual isoforms in individual cell types (Li et al., 2001). Confocal microscopy and PKC alpha-enhanced green fluorescent protein (PKC alpha-EGFP) fusion protein expression were utilized to investigate the spatial and temporal pattern of PKC alpha translocation to different stimulating agents in A7r5 smooth muscle cells. Phorbol 12, 13 dibutyrate (PDBu 10(-8) M) caused a slow but irreversible relocation of the fusion protein from the cytosol to the plasmalemma. By comparison, thapsigargin (10(-5) M) and A23 187 (2 x 10(-5) M) induced a rapidly transient translocation to the cell membrane which was completed within 4 min. In contrast to these agents, angiotensin II (Ang II, 10(-6) M) caused only partial relocalization of cytosolic PKC alpha-EGFP to brightly fluorescing patches at the cell periphery. Localization at peripheral patches was completed within seconds and the fusion protein returned to the cytosol within 2 min. The PKC inhibitor staurosporine blocked cellular contraction to PDBu but not A(23 187) and had no effect on PKC alpha-EGFP translocation. By comparison, the calcium chelators EDTA and BAPTA-AM blocked the contraction to A(23 187), attenuated the contraction to PDBu, and abolished the translocation of PKC alpha-EGFP by both agents. The results show that in a single cell type the spatial and temporal characteristics of individual PKC isoform translocation may differ markedly. This further suggests the existence of potentially complex mechanisms which regulate the rate and location of target site availability.

Proteomic approaches within the NCI early detection research network for the discovery and identification of cancer biomarkers.

In the postgenome era, proteomics provides a powerful approach for the analysis of normal and transformed cell functions, for the identification of disease-specific targets, and for uncovering novel endpoints for the evaluation of chemoprevention agents and drug toxicity. Unfortunately, the genomic information that has greatly expounded the genetic basis of cancer does not allow an accurate prediction of what is actually occurring at the protein level within a given cell type at any given time. The gene expression program of a given cell is affected by numerous factors in the in vivo environment resulting from tissue complexity and organ system orchestration, with cells acting in concert with each other and responding to changes in their microenvironment. Repositories of genomic information can be considered master "inventory lists" of genes and their maps, which need to be supplemented with protein-derived information. The National Cancer Institute's Early Detection Research Network is employing proteomics, or "protein walking", in the discovery and evaluation of biomarkers for cancer detection and for the identification of high-risk subjects. Armed with microdissection techniques, including the use of Laser Capture Microdissection (LCM) to procure pure populations of cells directly from human tissue, the Network is facilitating the development of technologies that can overcome the problem of tissue heterogeneity and address the need to identify markers in easily accessible biological fluids. Proteomic approaches complement plasma-based assays of circulating DNA for cancer detection and risk assessment. LCM, coupled with downstream proteomics applications, such as two-dimensional polyacrylamide gel electrophoresis and SELDI (surface enhanced laser desorption ionization) separation followed by mass spectrometry (MS) analysis, may greatly facilitate the characterization and identification of protein expression changes that track normal and disease phenotypes. We highlight recent work from Network investigators to demonstrate the potential of proteomics to identify proteins present in cancer tissues and body fluids that are relevant for cancer screening.

Proteomic approaches to biomarker discovery in prostate and bladder cancers.

Proteomic technologies, including high resolution two-dimensional electrophoresis (2-DE), antibody/protein arrays, and advances in mass spectrometry (MS), are providing the tools needed to discover and identify disease associated biomarkers. Although application of these technologies to search for potential diagnostic/prognostic biomarkers associated with prostate and bladder cancer have been somewhat limited to date, proteins either overexpressed or underexpressed have been detected in both these urological cancers. Recent advances in mass spectrometry, especially platforms that permit rapid "fingerprint" profiling of multiple biomarkers, and tandem mass spectrometers for protein identification, will most assuredly enhance the discovery, identification, and characterization of potential cancer associated biomarkers. Furthermore, application of laser capture microdissection microscopes has provided a rapid and reproducible approach to procure pure populations of cells. This technology coupled to 2-DE and MS has significantly aided the elucidation of the differential expression profiles between disease, benign and normal prostate and bladder cell populations. Finally, development and application of learning algorithms and bioinformatics to the data generated by these proteomic technologies will be essential in determining the clinical potential of a protein biomarker. The purpose of this review is to provide the reader with an overview of the application of these technologies in the search and identification of potential diagnostic/prognostic biomarkers for prostate and bladder cancers.

Concentration-dependent phorbol stimulation of PKCalpha localization at the nucleus or subplasmalemma in A7r5 cells.

The subcellular translocation of PKCalpha was studied in A7r5 cells by confocal microscopy through use of standard immunohistologic staining and PKCalpha-enhanced green fluorescent protein (PKCalpha-EGFP) fusion protein expression. The results from both methods were consistent in indicating that PKCalpha, observed to be diffusely distributed in the unstimulated cell, was translocated primarily to either the perinuclear region of the cell or to subplasmalemmal sites depending on the concentration of phorbol 12, 13 dibutyrate (PDBu) used to activate the response. Translocation of PKCalpha to the perinucleus but not the plasmalemma was blocked by the use of colchicine to disrupt cell microtubules. However, there was little evidence of significant colocalization of PKCalpha with the microtubular cytoskeleton during the interval of translocation. By comparison, cytochalasin B disruption of actin microfilaments had no significant effect on PKCalpha translocation to either the plasmalemma or the perinucleus. The results indicate that the target site of PKCalpha translocation may vary with activating stimulus strength in A7r5 cells and that the translocation of the isoform to perinuclear target loci depends on an intact microtubular cytoskeleton. This suggests that multiple pathways are available for the redistribution of PKCalpha that may employ different mechanisms to regulate the movement and/or docking of the isoform at specific target sites.

Regulation of expression and activity of four PKC isozymes in confluent and mechanically stimulated UMR-108 osteoblastic cells.

The transcript (mRNA), protein levels, enzyme activity, and cellular localization of four protein kinase C (PKC) isozymes identified in rat osteogenic sarcoma cells (UMR-108) were studied at confluent density and during mechanical stress (cyclic stretch). Western blot analysis indicated that growth to confluent density significantly increased the protein levels of cPKC-alpha (11.6-fold), nPKC-delta (5.3-fold), and nPKC-epsilon (22.0-fold) but not aPKC-zeta. Northern blot analysis indicated a significant (2.3-fold) increase in the 10 kb transcript of cPKC-alpha, a slight (1.3-fold) increase in that of nPKC-epsilon but no detectable change in that of the remaining isozymes. Enzyme activity assays of the individually immunoprecipitated isozymes yielded detectable kinase activity only for PKC-alpha, PKC-delta, and PKC-epsilon and only in confluent cells, corroborating the selective increase of these isozymes at confluent density. The UMR-108 cells showed a dramatic orientation response to mechanical stress with cell reshaping and alignment of the cell long axis perpendicular to the axis of force, remodeling of the actin cytoskeleton, and the appearance of multiple peripheral sites which stained for actin, vinculin, and PKC in separate experiments. Longer term mechanical stress beyond 24 h, however, resulted in no significant change in the mRNA level, protein level, or enzyme activity of any of the four PKC isozymes investigated. The results indicate that there are isozyme-selective increases in the protein levels of PKC isozymes of osteoblastic UMR-108 cells upon growth to confluence which may be regulated at the transcriptional or the post-transcriptional level. The results from UMR-108 cells support the earlier proposal (Carvalho RS, Scott JE, Suga DM, Yen EH. 1994. J Bone Miner Res 9(7):999-1011) that PKC could be involved in the early phase of mechanotransduction in osteoblasts through the activation of focal adhesion assembly/disassembly and the remodeling of the actin cytoskeleton.

Proteomics in early detection of cancer.

Early detection is critical in cancer control and prevention. Biomarkers help in this process by providing valuable information about a the status of a cell at any given point in time. As a cell transforms from nondiseased to neoplastic, distinct changes occur that could be potentially detected through the identification of the appropriate biomarkers. Biomarker research has benefited from advances in technology such as proteomics. We discuss here ongoing research in this field, focusing on proteomic technologies. The advances in two-dimensional electrophoresis and mass spectrometry are discussed in light of their contribution to biomarker research. Chip-based techniques, such as surface-enhanced laser desorption, and ionization and emerging methods, such as tissue and antibody arrays, are also discussed. The development of bioinformatic tools that have and are being developed in parallel to proteomics is also addressed. This report brings into focus the efforts of the Early Detection Research Network at the National Cancer Institute in harnessing scientific expertise from leading institutions to identify and validate biomarkers for early detection and risk assessment.

Quantitation of serum prostate-specific membrane antigen by a novel protein biochip immunoassay discriminates benign from malignant prostate disease.

The lack of a sensitive immunoassay for quantitating serum prostate-specific membrane antigen (PSMA) hinders its clinical utility as a diagnostic/prognostic biomarker. An innovative protein biochip immunoassay was used to quantitate and compare serum PSMA levels in healthy men and patients with either benign or malignant prostate disease. PSMA was captured from serum by anti-PSMA antibody bound to ProteinChip arrays, the captured PSMA detected by surface-enhanced laser desorption/ionization mass spectrometry, and quantitated by comparing the mass signal integrals to a standard curve established using purified recombinant PSMA. The average serum PSMA value for prostate cancer (623.1 ng/ml) was significantly different (P < 0.001) from that for benign prostate hyperplasia (117.1 ng/ml) and the normal groups (age <50, 272.9 ng/ml; age >50, 359.4 ng/ml). These initial results suggest that serum PSMA may be a more effective biomarker than prostate-specific antigen for differentiating benign from malignant prostate disease and warrants additional evaluation of the surface-enhanced laser desorption/ionization PSMA immunoassay to determine its diagnostic utility.