Cyclic phosphatidic acid decreases proliferation and survival of colon cancer cells by inhibiting peroxisome proliferator-activated receptor γ.

Cyclic phosphatidic acid (cPA), a structural analog of lysophosphatidic acid (LPA), is one of the simplest phospholipids found in every cell type. cPA is a specific, high-affinity antagonist of peroxisome proliferator-activated receptor gamma (PPARγ); however, the molecular mechanism by which cPA inhibits cellular proliferation remains to be clarified. In this study, we found that inhibition of PPARγ prevents proliferation of human colon cancer HT-29 cells. cPA suppressed cell growth, and this effect was reversed by the addition of a PPARγ agonist. These results indicate that the physiological effects of cPA are partly due to PPARγ inhibition. Our results identify PPARγ as a molecular mediator of cPA activity in HT-29 cells, and suggest that cPA and the PPARγ pathway might be therapeutic targets in the treatment of colon cancer.

Saccade adaptation as a model of learning in voluntary movements.

Motor learning ensures the accuracy of our daily movements. However, we know relatively little about its mechanisms, particularly for voluntary movements. Saccadic eye movements serve to bring the image of a visual target precisely onto the fovea. Their accuracy is maintained not by on-line sensory feedback but by a learning mechanism, called saccade adaptation. Recent studies on saccade adaptation have provided valuable additions to our knowledge of motor learning. This review summarizes what we know about the characteristics and neural mechanisms of saccade adaptation, emphasizing recent findings and new ideas. Long-term adaptation, distinct from its short-term counterpart, seems to be present in the saccadic system. Accumulating evidence indicates the involvement of the oculomotor cerebellar vermis as a learning site. The superior colliculus is now suggested not only to generate saccade commands but also to issue driving signals for motor learning. These and other significant contributions have advanced our understanding of saccade adaptation and motor learning in general.

Learning signals from the superior colliculus for adaptation of saccadic eye movements in the monkey.

Vital to motor learning is information about movement error. Using this information, the brain creates neural learning signals that instruct a plasticity mechanism to produce appropriate behavioral learning. Little is known, however, about brain structures that generate learning signals for voluntary movements. Here we show that signals from the superior colliculus (SC) can drive learning in saccadic eye movements in the monkey. Electrical stimulation of the SC deeper layers, subthreshold for evoking saccades, was applied immediately (approximately 60 ms) after the end of horizontal saccades in one or both directions. The target disappeared during saccades and remained invisible for 1 s to eliminate effects of postsaccadic visual information. Repetitive pairing of saccades with SC stimulation produced a marked, two-dimensional shift in movement endpoint relative to the target location. The elicited endpoint shift took a gradual, approximately exponential course over several hundred saccades as in visually induced saccade adaptation. The shift in movement endpoint remained nearly unchanged after stimulation was discontinued, indicating involvement of neuronal plasticity. When both rightward and leftward saccades were paired with stimulation, their endpoints shifted in similar directions. The endpoint shift was directed contralaterally to the stimulated SC. The direction and size of the endpoint shift depended on the stimulation site in the SC. We propose that the SC, a brainstem structure long known to be crucial for saccade execution, is involved in motor learning and sends signals that dictate the direction of adaptive shift in saccade endpoint.

Role of glycinergic inhibition in shaping activity of saccadic burst neurons.

The immediate premotor signals for saccades are created at the level of medium-lead burst neurons (MLBNs). During fixations, MLBNs receive tonic inhibition from omnipause neurons (OPNs), which use glycine as a neurotransmitter. To elucidate the role of this inhibition, we studied discharge patterns of horizontal MLBNs following iontophoretic application of strychnine, a glycine-receptor antagonist, in alert cats. Three-barrel micropipettes were used for extracellular recording and iontophoresis. After application of strychnine, MLBNs exhibited spontaneous discharge and visual responses during intersaccadic intervals. Spikes were evoked by single-pulse stimulation of the contralateral superior colliculus (SC). These results show that MLBNs receive substantial excitatory input during intersaccadic intervals and that inhibitory action of OPNs is indeed necessary to prevent MLBNs from firing. Strychnine also affected saccade-related activity of MLBNs. The burst of activity, as in normal conditions, declined rapidly before the end of saccades but was followed by low rate spike activity, which continued beyond the end of saccades. This suggests that in normal conditions, the termination of saccades is determined by resumed inhibitory action of OPNs and not by termination of excitatory input to MLBNs. In addition, the firing rate and the number of spikes during saccades increased after strychnine application, suggesting that MLBNs receive glycinergic inhibition of non-OPN origin as well. We conclude that glycinergic inhibition plays essential roles in the maintenance of stable fixation, the termination of saccades, and the regulation of saccade size and velocity.

c-Jun NH(2)-terminal kinase mediates leptin-stimulated androgen-independent prostate cancer cell proliferation via signal transducer and activator of transcription 3 and Akt.

Obesity is associated with advanced prostate cancer. Here we demonstrate that in mouse prostate cancer TRAMP-C1 cells epididymal fat extracts from high-fat diet-fed obese mice stimulate androgen-independent cell growth more significantly than those from low-fat diet-fed lean mice or genetically obese leptin-deficient ob/ob mice in correlation with leptin concentrations. This result suggests that obesity promotes androgen-independent prostate cancer cell growth via adipose leptin. We have reported that added leptin stimulates androgen-independent prostate cancer cell proliferation through c-Jun NH(2)-terminal kinase (JNK). As with JNK, signal transducer and activator of transcription 3 (STAT3) and Akt are implicated in androgen-independent prostate cancer. In this study, we identify novel interaction of these three molecules in leptin-stimulated androgen-independent cell proliferation. Leptin activates JNK, STAT3 and Akt in a biphasic manner with a similar time-course. Pharmacological JNK inhibition suppresses leptin-stimulated DNA binding activity, as well as Ser-727 phosphorylation, of STAT3. Since JNK upregulates STAT3 activity via Ser-727 phosphorylation, JNK mediates leptin-stimulated STAT3 activation through Ser-727 phosphorylation. Moreover, JNK inhibition impairs leptin-stimulated Ser-473 phosphorylation of Akt that is required for its activation. Thus, JNK is involved in leptin-stimulated Akt activation. These findings together indicate that JNK mediates leptin-stimulated androgen-independent prostate cancer cell proliferation via STAT3 and Akt.

Premotor inhibitory neurons carry signals related to saccade adaptation in the monkey.

Cerebellar output changes during motor learning. How these changes cause alterations of motoneuron activity and movement remains an unresolved question for voluntary movements. To answer this question, we examined premotor neurons for saccadic eye movement. Previous studies indicate that cells in the fastigial oculomotor region (FOR) within the cerebellar nuclei on one side exhibit a gradual increase in their saccade-related discharge as the amplitude of ipsiversive saccades adaptively decreases. This change in FOR activity could cause the adaptive change in saccade amplitude because neurons in the FOR project directly to the brain stem region containing premotor burst neurons (BNs). To test this possibility, we recorded the activity of saccade-related burst neurons in the area that houses premotor inhibitory burst neurons (IBNs) and examined their discharge during amplitude-reducing adaptation elicited by intrasaccadic target steps. We specifically analyzed their activity for off-direction (contraversive) saccades, in which the IBN activity would increase to reduce saccade size. Before adaptation, 29 of 42 BNs examined discharged, at least occasionally, for contraversive saccades. As the amplitude of contraversive saccades decreased adaptively, half of BNs with off-direction spike activity showed an increase in the number of spikes (14/29) or an earlier occurrence of spikes (7/14). BNs that were silent during off-direction saccades before adaptation remained silent after adaptation. These results indicate that the changes in the off-direction activity of BNs are closely related to adaptive changes in saccade size and are appropriate to cause these changes.

Functional analysis of human mutations in homeodomain transcription factor PITX3.

BACKGROUND: The homeodomain-containing transcription factor PITX3 was shown to be essential for normal eye development in vertebrates. Human patients with point mutations in PITX3 demonstrate congenital cataracts along with anterior segment defects in some cases when one allele is affected and microphthalmia with brain malformations when both copies are mutated. The functional consequences of these human mutations remain unknown. RESULTS: We studied the PITX3 mutant proteins S13N and G219fs to determine the type and severity of functional defects. Our results demonstrate alterations in DNA-binding profiles and/or transactivation activities and suggest a partial loss-of-function in both mutants with the G219fs form being more severely affected. No anomalies in cellular distribution and no dominant-negative effects were discovered for these mutants. Interestingly, the impairment of the G219fs activity varied between different ocular cell lines. CONCLUSION: The G219fs mutation was found in multiple families affected with congenital cataracts along with anterior segment malformations in many members. Our data suggest that the presence/severity of anterior segment defects in families affected with G219fs may be determined by secondary factors that are expressed in the developing anterior segment structures and may modify the effect(s) of this mutation. The S13N mutant showed only minor alteration of transactivation ability and DNA binding pattern and may represent a rare polymorphism in the PITX3 gene. A possible contribution of this mutation to human disease needs to be further investigated.

Role of STAT3 in liver regeneration: survival, DNA synthesis, inflammatory reaction and liver mass recovery.

The hepatoprotective effect of interleukin-6 (IL-6)/signal transducer and activator of transcription 3 (STAT3) has been well documented. However, reports on the role of IL-6/STAT3 in liver regeneration are conflicting probably due to the fact that the model of Stat3 knockout mice were complicated with obesity and fatty liver, which may cause some secondary effects on liver regeneration. To study the direct role of STAT3 and to circumvent the problems of obesity and fatty liver in liver regeneration, we generated conditional STAT3 knockout in the liver (L-Stat3(-/-)) using a transthyretin-driven Cre-lox method. The L-Stat3(-/-) mice were born with the expected Mendelian frequency and showed no obesity or other obvious phenotype. After partial hepatectomy, mortality in the L-Stat3(-/-) mice was significantly higher than the littermate Stat3(f/+) controls in the early time points (<24 h). Hepatocyte DNA synthesis in the survived L-Stat3(-/-) mice slightly decreased as compared with Stat3(f/+) mice at 40 h after partial hepatectomy, whereas similar hepatocyte DNA synthesis was found at other time points and liver mass could be completely recovered in the L-Stat3(-/-) mice. In another model of liver regeneration induced by subcutaneous injection of carbon tetrachloride (CCl(4)), hepatocyte DNA synthesis in the CCl(4)-treated L-Stat3(-/-) mice also decreased as compared with Stat3(f/+) mice at 40 h after injection but not at other time points. In addition, infiltration of neutrophils and monocyte increased in the liver of CCl(4)-treated L-Stat3(-/-) mice compared to wild-type mice. In conclusion, STAT3 is required for survival in the acute stage after 70% hepatectomy and plays a role in inflammatory reaction after hepatocyte necrosis. However, the hepatocytic STAT3 may have limited role in liver mass recovery although DNA synthesis may be impaired.

Microstimulation of the midbrain tegmentum creates learning signals for saccade adaptation.

Error signals are vital to motor learning. However, we know little about pathways that transmit error signals for learning in voluntary movements. Here we show that microstimulation of the midbrain tegmentum can induce learning in saccadic eye movements in monkeys. Weak electrical stimuli delivered approximately 200 ms after saccades in one horizontal direction produced gradual and marked changes in saccade gain. The spatial and temporal characteristics of the produced changes were similar to those of adaptation induced by real visual error. When stimulation was applied after saccades in two different directions, endpoints of these saccades gradually shifted in the same direction in two dimensions. We conclude that microstimulation created powerful learning signals that dictate the direction of adaptive shift in movement endpoints. Our findings suggest that the error signals for saccade adaptation are conveyed in a pathway that courses through the midbrain tegmentum.

Glycinergic inputs cause the pause of pontine omnipause neurons during saccades.

Pontine omnipause neurons (OPNs) are inhibitory neurons projecting to saccade-related premotor burst neurons. OPNs exhibit sustained discharge during fixations and cease firing before and during saccades. The pause in OPN discharge releases the burst neurons from tonic inhibition, resulting in generation of saccadic eye movements. OPNs are thought to receive two major inhibitory inputs during saccades: an early component that determines the pause onset and a late component that controls the pause duration. Although there is evidence that numerous glycinergic and GABAergic terminals contact OPNs, their physiological roles remain unclear. To reveal functions of glycinergic and GABAergic inputs, we investigated effects of iontophoretic application of strychnine, a glycine receptor antagonist, and bicuculline, a GABAA receptor antagonist, on discharge patterns of OPNs in alert cats. Application of strychnine reduced the ratio of pause duration to saccade duration. Analysis of the timing of pause relative to saccades showed that pause onset was delayed and pause end was advanced. These effects were observed for saccades in all directions. Application of bicuculline, in contrast, had no effect on the OPN pause duration or timing. Both strychnine and bicuculline increased tonic firing rate during intersaccadic intervals. These results suggest that glycinergic, but not GABAergic, afferents convey inhibitory signals that determine the onset as well as duration of pause in OPN activity during saccades.

The location of brainstem neurons with bilateral projections to the motor nuclei of jaw openers in the cat.

Symmetrical motor output is the rule in the masticatory system. We examined morphologically how this functional symmetry might be reflected in the organization of premotor neurons that could mediate excitation of jaw-opener motoneurons. Premotor neurons projecting bilaterally to jaw-opener motoneurons by way of axon collaterals were identified by retrograde dual-labeling with cholera toxin B-conjugated fluorescein isothiocyanate (CTb-FITC) and tetramethylrhodamine (TMR). In each cat, CTb-FITC and TMR were injected into the digastric motoneuron pools, respectively, on the left and right sides. In three animals, 69-147 neurons were labeled with both tracers, comprising approximately 44% of all retrogradely labeled cells. Double-labeled cells were located bilaterally in the trigeminal oral nucleus (Vo) and the adjacent reticular formation (RF), the former containing a larger number of cells. Neurons labeled with only one tracer were also distributed bilaterally in the Vo and RF. The results indicated that the bilaterally projecting premoter neurons identified mainly in the Vo and RF represent neuronal substrates for the symmetry that characterizes most jaw movements.

Adiponectin as a growth inhibitor in prostate cancer cells.

Prostate cancer is associated with obesity. However, the molecular basis of this association is not well known. Adiponectin is a major adipose cytokine that decreases in circulation in obesity and ameliorates obesity. Here, we identify adiponectin as a novel inhibitor in prostate cancer cell growth. Adiponectin occurs in non-proteolytic (full-length adiponectin: f-adiponectin) and proteolytic (globular adiponectin) forms in various oligomeric states (trimer, hexamer, and high molecular weight complex). The 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide assay demonstrates that f-adiponectin inhibits prostate cancer cell growth drastically at subphysiological concentrations. Furthermore, velocity sedimentation analysis shows that the high molecular weight complex of f-adiponectin is the inhibitory form. Moreover, f-adiponectin suppresses leptin- and/or insulin-like growth factor-I (IGF-I)-stimulated, androgen-independent DU145 cell growth, and dihydrotestosterone-stimulated, androgen-dependent LNCaP-FGC cell growth. In addition, f-adiponectin enhances doxorubicin inhibition of prostate cancer cell growth. Therefore, f-adiponectin is a molecular mediator between prostate cancer and obesity, and may be therapeutic to prostate cancer.

Effect of saccadic amplitude adaptation on subsequent adaptation of saccades in different directions.

We have shown previously that adaptation of horizontal saccades exerts facilitating effects on subsequent adaptation of saccades in the same direction. Now we investigated the effect on saccades in different directions. A series of three alternating gain changes was induced by intrasaccadic step (ISS) of the target in two monkeys. The gain of saccades to horizontal or vertical target steps was decreased by backward ISS (conditioning). Then, we used forward ISS to increase their gain back to approximately 1.0. Finally, we induced a gain decrease for saccades to oblique target steps with backward ISS. We analyzed dependency of test adaptation rates on the direction of conditioning saccades. The rate of adaptation of the horizontal component of oblique saccades was significantly larger when conditioned with horizontal saccade adaptation than with vertical saccade adaptation. The rate for the vertical component did not show such differences. Following horizontal saccade adaptation, the horizontal component adapted faster than the vertical component. After vertical saccade adaptation, the vertical component tended to adapt at higher rates. Taken together, the results indicate that horizontal saccade adaptation exerts a facilitating effect on subsequent adaptation of the horizontal component of oblique saccades.

Adiponectin activates c-Jun NH2-terminal kinase and inhibits signal transducer and activator of transcription 3.

Adiponectin, a major adipose cytokine, plays a crucial role in the inhibition of metabolic syndrome by acting on such cell types as muscle cells and hepatocytes. Furthermore, evidence suggests that adiponectin may influence cancer pathogenesis. Adiponectin occurs in non-proteolytic (full-length adiponectin: f-adiponectin) and proteolytic (globular adiponectin: g-adiponectin) forms in various oligomeric states. Different forms of adiponectin show distinct biological effects through differential activation of downstream signaling pathways. Here we identify c-Jun NH(2)-terminal kinase (JNK), and signal transducer and activator of transcription 3 (STAT3) as common downstream effectors of f- and g-adiponectin. f- and g-adiponectin both stimulate JNK activation in prostate cancer DU145, PC-3, and LNCaP-FGC cells, hepatocellular carcinoma HepG2 cells, and C2C12 myoblasts. Furthermore, both f- and g-adiponectin drastically suppress constitutive STAT3 activation in DU145 and HepG2 cells. These suggest that JNK and STAT3 may constitute a universal signaling pathway to mediate adiponectin's pathophysiological effects on metabolic syndrome and cancer.

BCG directly induces cell cycle arrest in human transitional carcinoma cell lines as a consequence of integrin cross-linking.

BACKGROUND: Current models of the mechanism by which intravesical BCG induces an anti-tumor effect in urothelial carcinoma propose a secondary cellular immune response as principally responsible. Our group has demonstrated that BCG mediated cross-linking of alpha51 integrin receptors present on the tumor surface elicits a complex biologic response involving AP1 and NF-kappaB signaling as well as the transactivation of immediate early genes. This study evaluated the direct biologic effect of cross-linking alpha5beta1 integrin on cell cycle progression and apoptosis in two human urothelial carcinoma cell lines. METHODS: Two independent assays (MTT and Colony forming ability) were employed to measure the effect of alpha5beta1 cross-linking (antibody mediated or BCG) on cellular proliferation. Flow cytometry was employed to measure effect of BCG and alpha5beta1 antibody mediated cross-linking on cell cycle progression. Apoptosis was measured using assays for both DNA laddering and Caspase 3 activation. RESULTS: Results demonstrate that integrin cross-linking by BCG, or antibody mediated crosslinking of alpha5beta1 resulted in a decrease in proliferating cell number. BCG treatment or alpha5beta1 cross-linking increased the percentage of cells in G0/G1, in both 253J and T24 cell lines. Peptide mediated blockade of integrin binding site using RGDS reversed the effect BCG on both proliferation and cell cycle arrest. Apoptosis in response to BCG was not identified by either DNA laddering or Caspase 3 activation. CONCLUSION: These findings show that BCG exerts a direct cytostatic effect on human urothelial carcinoma cell lines. Cell cycle arrest at the G1/S interface is a mechanism by which BCG inhibits cellular proliferation. This effect is duplicated by antibody mediated cross-linking of alpha5beta1 and likely occurs as a consequence of crosslink-initiated signal transduction to cell cycle regulatory genes.

2-arachidonoylglycerol: a novel inhibitor of androgen-independent prostate cancer cell invasion.

Endocannabinoids have been implicated in cancer. Increasing endogenous 2-arachidonoylglycerol (2-AG) by blocking its metabolism inhibits invasion of androgen-independent prostate cancer (PC-3 and DU-145) cells. Noladin ether (a stable 2-AG analog) and exogenous CB1 receptor agonists possess similar effects. Conversely, reducing endogenous 2-AG by inhibiting its synthesis or blocking its binding to CB1 receptors with antagonists increases the cell invasion. 2-AG and noladin ether decrease protein kinase A activity in these cells, indicating coupling of the CB1 receptor to downstream effectors. The results suggest that cellular 2-AG, acting through the CB1 receptor, is an endogenous inhibitor of invasive prostate cancer cells.

Autocrine over expression of fibronectin by human transitional carcinoma cells impairs bacillus Calmette-Guerin adherence and signaling.

PURPOSE: Bacillus Calmette-Guerin (BCG) binds to the tumor cell as a result of mycobacterial receptors for fibronectin (FN). Cell surface bound FN serves as a bridge through which BCG attaches to the tumor cell. Despite the importance of FN studies have demonstrated an idiosyncratic decrease in BCG adherence in response to exogenous FN. We evaluated the effect of exogenous and autocrine FN on the ability of BCG to adhere to the tumor cell surface and initiate cellular signaling. MATERIALS AND METHODS: BCG adherence to parental 253J and FN over expressing 253JTGFbeta1-8 cells as well as to the intrinsic FN expressing cell line 647V was quantified using green fluorescent protein-BCG. Experiments were performed to assess the effect of FN on BCG initiated signal transduction through nuclear factor kappaB and AP1. Finally, the integrity of the BCG activated signaling pathway in transforming growth factor-beta1/FN over expressors was assessed using antibody mediated cross-linking of the FN receptor. RESULTS: BCG adherence was decreased in cell lines with high autocrine expression of FN. Exogenous FN prevented BCG induced transactivation of nuclear factor kappaB and AP1 reporter constructs. No BCG stimulated signaling to these reporters could be detected in FN over expressing 253J cells. NonFN dependent alpha5beta1 cross-linking initiated signal transduction in FN over expressing cells. CONCLUSIONS: We propose that by saturating cellular and BCG receptors excess FN expression decreases the ability of cellular or mycobacterial bound FN to bind vacant receptors on BCG or on the cell. Excess FN inhibits BCG adherence and BCG initiated signal transduction.

Memory of learning facilitates saccadic adaptation in the monkey.

A motor learning mechanism called saccadic adaptation ensures accuracy of saccades throughout life despite growth, aging, and some pathologies of the oculomotor plant or nervous system. The present study investigates effects of preceding adaptation on the speed of subsequent adaptation during single experiments. Adaptive changes in gain (movement size divided by target eccentricity) were induced by intrasaccadic step (ISS) of the target. After the gain was altered (control block), we reversed the direction of ISS to bring the gain back to approximately 1.0 (recovery). We then reversed ISS direction again to induce another adaptation (test block). Analyses revealed that the gain changed at a higher rate in the early part of test adaptation than in the corresponding part of control. After approximately 100-300 saccades in the test block, adaptation slowed down. The gain value at which adaptation slowed was correlated with the gain achieved in the control. We further examined effects of a 30 min intervention inserted between recovery and test blocks. When zero-visual-error trials ( approximately 700 saccades) were repeated during this period, the rate of test adaptation was similar to that of control. In contrast, when the animal was deprived of visual inputs during this period, test adaptation was still influenced by preceding learning. We conclude that a memory of previous learning remains during recovery to facilitate subsequent adaptation and that such a memory does not disappear merely with time but is erased actively by repeated zero-error movements. Our results, which cannot be explained by a single mechanism, suggest that the saccadic system is equipped with more than one plasticity process.

Vertical eye movement-related type II neurons with downward on-directions in the vestibular nucleus in alert cats.

The vestibular nuclei and the interstitial nucleus of Cajal (INC) have been regarded as key elements of the velocity-to-position integrator for vertical eye movements. This paper reports a class of type II vestibular neurons that receives input from the INC and carries vertical eye movement signals that appear to represent an intermediate stage of the integration process. Extracellular recordings were made from neurons in and near the vestibular nuclei in alert cats. We encountered 39 neurons that exhibited an intense burst of spikes for downward saccades and a position-related tonic activity during intersaccadic intervals (d-type II neurons). They had a very high saccadic sensitivity (4.3+/-2.7 spikes/deg, mean +/- SD) as well as a high position sensitivity (3.2+/-1.6 (spikes/sec)/deg). Unlike the bursts of motoneurons, the bursts of these neurons declined gradually with an exponential-like time course and lasted well beyond the end of saccades. The mean time constant of the burst decay was 139+/-43 ms. The d-type II neurons were excited with disynaptic or trisynaptic latencies following stimulation of the contralateral vestibular nerve. The responses to vertical head rotations suggested inputs from the contralateral posterior canal. The d-type II neurons were excited with short latencies following stimulation of the ipsilateral INC, suggesting that they receive a direct excitatory input from vertical eye movement-related INC neurons with downward on-directions. The d-type II neurons were located in the rostral portion of the vestibular nuclei and the underlying reticular formation. These results suggest that d-type II neurons may be interposed between the burst-tonic neurons in the INC and pure tonic neurons in the vestibular nuclei and contribute to the oculomotor velocity-to-position integration.