The striatal-enriched protein tyrosine phosphatase gates long-term potentiation and fear memory in the lateral amygdala.

BACKGROUND: Formation of long-term memories is critically dependent on extracellular-regulated kinase (ERK) signaling. Activation of the ERK pathway by the sequential recruitment of mitogen-activated protein kinases is well understood. In contrast, the proteins that inactivate this pathway are not as well characterized. METHODS: Here we tested the hypothesis that the brain-specific striatal-enriched protein tyrosine phosphatase (STEP) plays a key role in neuroplasticity and fear memory formation by its ability to regulate ERK1/2 activation. RESULTS: STEP co-localizes with the ERKs within neurons of the lateral amygdala. A substrate-trapping STEP protein binds to the ERKs and prevents their nuclear translocation after glutamate stimulation in primary cell cultures. Administration of TAT-STEP into the lateral amygdala (LA) disrupts long-term potentiation (LTP) and selectively disrupts fear memory consolidation. Fear conditioning induces a biphasic activation of ERK1/2 in the LA with an initial activation within 5 minutes of training, a return to baseline levels by 15 minutes, and an increase again at 1 hour. In addition, fear conditioning results in the de novo translation of STEP. Inhibitors of ERK1/2 activation or of protein translation block the synthesis of STEP within the LA after fear conditioning. CONCLUSIONS: Together, these data imply a role for STEP in experience-dependent plasticity and suggest that STEP modulates the activation of ERK1/2 during amygdala-dependent memory formation. The regulation of emotional memory by modulating STEP activity may represent a target for the treatment of psychiatric disorders such as posttraumatic stress disorder (PTSD), panic, and anxiety disorders.

Requirement of different mitochondrial targeting sequences of the yeast mitochondrial transcription factor Mtf1p when synthesized in alternative translation systems.

Mitochondrial (mt) translocation of the nuclearly encoded mt transcription factor Mtf1p appears to occur independent of a cleavable presequence, mt receptor, mt membrane potential or ATP [Biswas and Getz (2002) J. Biol. Chem. 277, 45704-45714]. To understand further the import strategy of Mtf1p, we investigated the import of the wild-type and N-terminal-truncated Mtf1p mutants synthesized in two different in vitro translation systems. These Mtf1p derivatives were generated either in the RRL (rabbit reticulocyte lysate) or in the WGE (wheat germ extract) translation system. Under the in vitro import conditions, the RRL-synthesized full-length Mtf1p but not the N-terminal-truncated Mtf1p product was efficiently imported into mitochondria, suggesting that the N-terminal sequence is important for its import. On the other hand, when these Mtf1p products were generated in the WGE system, surprisingly, the N-terminal-truncated products, but not the full-length protein, were effectively translocated into mitochondria. Despite these differences between the translation systems, in both cases, import occurs at a low temperature and has no requirement for a trypsin-sensitive mt receptor, mt membrane potential or ATP hydrolysis. Together, these observations suggest that, in the presence of certain cytoplasmic factors (derived from either RRL or WGE), Mtf1p is capable of using alternative import signals present in different regions of the protein. This appears to be the first example of usage of different targeting sequences for the transport of a single mt protein into the mt matrix.

Jun, Fos and Krox in the thalamus after C-fiber stimulation: coincident-input-dependent expression, expression across somatotopic boundaries, and nucleolar translocation.

Expression of the inducible transcription factors Jun, Fos and Krox is commonly used to map neurons in the brain that are activated by sensory inputs. However, some neurons known to be electrically excited by such inputs do not always express these factors. In particular, stimulation of hindlimb sensory nerve C-fibers induces expression of c-Fos in the medial thalamus (the mediodorsal, intermediodorsal, centrolateral and centromedial), but not in the lateral thalamus (the ventroposterolateral, ventroposteromedial and posterior group). We hypothesized that c-Fos expression might only occur in these lateral areas after more complex stimulation patterns, or that only other transcription factors can be induced in these areas by such stimuli. Thus we examined the effects of single, repeated and coincident C-fiber inputs on expression of six inducible transcription factors in the medial, lateral and reticular thalamus of the rat. A weak C-fiber input caused by noxious mechanical stimulation of the skin of one hindpaw did not induce expression of c-Fos, FosB, Krox-20 or Krox-24; but it did reduce the basal expressions of c-Jun and JunD in both the medial and lateral areas. An intense input produced by electrical stimulation of all the C-fibers in one sciatic nerve also failed to induce expression of c-Fos, FosB, Krox-20 or Krox-24 in the medial or lateral areas. However, in the medial thalamus it increased c-Jun and reduced the basal expression of JunD, whereas in the lateral thalamus it had no effect on c-Jun but again reduced the basal expression of JunD. With repeated stimulation, i.e. when the noxious stimulus was applied to the contralateral hindpaw 6 h after the sciatic stimulation, there was again no induction of c-Fos, FosB or Krox-20 in the medial thalamus; but there was an increase in c-Jun and Krox-24, and a decrease in JunD levels. In the lateral thalamus the repeated stimulation again failed to induce c-Fos, but the expressions of FosB, c-Jun and Krox-24 were increased, and that of JunD was again reduced. With coincident stimulation, i.e. when a stimulus was applied to each hindpaw simultaneously, c-Fos and Krox-24 remained absent; but there was a marked induction of FosB and Krox-20, a strong repression of c-Jun, and no effect or a reduction of the basal levels of JunD. This coincident stimulation also caused FosB to appear in the nucleolus of many thalamic neurons. MK-801, but not L-NAME, blocked all these changes. In summary, noxious stimulation affects the expression of all transcription factors in the medial, lateral and reticular thalamus in a complex manner depending upon the inducible transcription factor considered, the thalamic nucleus, and the stimulation paradigm. The expression of some transcription factors uniquely after simultaneous inputs suggests they act as coincidence detectors at the gene level.

Increased association of brain protein kinase C with the receptor for activated C kinase-1 (RACK1) in bipolar affective disorder.

BACKGROUND: Membrane protein kinase C (PKC) activity is increased in frontal cortex of subjects with bipolar affective disorder, and lithium was demonstrated to inhibit PKC translocation to membranes. Protein kinase C is anchored to the membrane via the receptor for activated C kinase-1 (RACK1), suggesting that interactions between these proteins may be altered in bipolar disease. METHODS: The levels of RACK1 coimmunoprecipitating with PKC isozymes were compared in homogenates of frontal cortex slices from postmortem bipolar subjects and matched control subjects. RESULTS: Receptor for activated C kinase-1 was located exclusively in membranes and, in control brains, the levels of RACK1 that coimmunoprecipitated with most PKC isozymes were increased by stimulation with the PKC activator, phorbol 12-myristate, 13-acetate (PMA). The association of RACK1 with membrane gammaPKC and zetaPKC was increased under basal conditions in bipolar relative to control brains. Stimulation with PMA increased the amount of RACK1 that coimmunoprecipitated with the alpha, beta, gamma, delta, and varepsilonPKC isozymes, but not zetaPKC, in bipolar tissues over that elicited in control tissues. CONCLUSIONS: These data suggest that the increased association of RACK1 with PKC isozymes may be responsible for the increases in membrane PKC and in its activation that were previously observed in frontal cortex of bipolar affective disorder brains.

Kinetics of the RNA-DNA helicase activity of Escherichia coli transcription termination factor rho. 1. Characterization and analysis of the reaction.

The kinetics of the ATP-dependent RNA-DNA helicase activity of Escherichia colitranscription termination factor rho have been analyzed. Helicase substrates were assembled using 255 nt and 391 nt RNA sequences from the trp t' RNA transcript of E. coli. These RNA sequences each carry a rho "loading site" at a position near the 5'-end, and a rho-dependent terminator sequence at the 3'-end to which complementary approximately 20 nt DNA oligonucleotides have been annealed. A rapid ( approximately 30 s) pre-steady-state burst of helicase activity (DNA oligomer release), followed by a slow linear phase, is observed in reactions carried out at low salt concentrations (50 mM KCl). Using poly(rC) or poly(dC) as traps for the rho that is released after one round of activity, we have shown that the first (burst) phase of the reaction represents the processive translocation of prebound rho hexamers from the rho loading site to the 3'-end of the RNA molecule. The slow phase of the reaction is complex and represents a combination of many different processes, including the slow release of RNA from rho, the reannealing of complementary DNA oligonucleotides to the RNA substrate, and the recycling of rho hexamers onto additional RNA molecules. Reactions carried out at higher salt concentrations (150 mM KCl) consist of only one phase, since under these conditions rho dissociates more rapidly from the RNA, with an amplitude corresponding to several DNA oligomers removed per rho hexamer. Thus, rho can recycle and function as a catalytic helicase under reaction conditions resembling those found in the cell.

Kinetics of the RNA-DNA helicase activity of Escherichia coli transcription termination factor rho. 2. Processivity, ATP consumption, and RNA binding.

The RNA-binding and RNA-DNA helicase activities of the Escherichia coli transcription termination factor rho have been investigated using natural RNA molecules that are 255 and 391 nucleotide residues in length and that contain the trp t' rho-dependent termination sequence of E. coli. Helicase substrates were prepared from these RNA molecules by annealing one or more DNA oligomers to complementary sequences located at or near the 3'-ends of the RNA molecules to form defined RNA-DNA hybrid sequences ranging in length from 20 to 100 bp. By comparing the fraction of the RNA molecules bound to rho with the fraction of bound DNA oligomers removed from the RNA during one round of the helicase reaction, we have shown that rho translocates processively at 37 degrees C in buffer containing 50 mM KCl. Helicase reactions and ATPase measurements were performed in parallel in the presence of RNA molecules containing RNA-DNA hybrids of various lengths, and we show that both the rate of translocation of the rho hexamer along the RNA chain and the rate of ATP consumption are similar, whether or not DNA is hybridized to the RNA transcript. By combining measurements of translocation and ATPase rates, we estimate that rho consumes approximately 1-2 ATP molecules in translocating over 1 nucleotide residue of the RNA chain at 37 degrees C in 50 mM KCl. The ATPase activity of rho remains the same after one round of the helicase reaction, indicating that rho appears to hydrolyze ATP at the same rate, whether it is translocating along the RNA, separating RNA-DNA hybrids, or bound at the 3'-end of the RNA substrate. We also show that rho binds cooperatively ( approximately 2-4 rho hexamers per RNA chain) to the RNA substrates under our standard helicase reaction conditions. However, cooperative binding is not essential for helicase activity, since this binding stoichiometry can be reduced to approximately 1.5 rho hexamers per 255-nucleotide residue RNA chain by blocking approximately 100 nt of either end of the rho binding site of the helicase substrate with complementary DNA oligonucleotides, with no change in helicase properties. The implications of these results for models of rho helicase function and for the role of rho in termination are discussed.