Increased hippocampal neurogenesis and accelerated response to antidepressants in mice with specific deletion of CREB in the hippocampus: role of cAMP response-element modulator τ.

The transcription factor cAMP response element-binding protein (CREB) has been implicated in the pathophysiology of depression as well as in the efficacy of antidepressant treatment. However, altering CREB levels appears to have differing effects on anxiety- and depression-related behaviors, depending on which brain region is examined. Furthermore, many manipulations of CREB lead to corresponding changes in other CREB family proteins, and the impact of these changes has been largely ignored. To further investigate the region-specific importance of CREB in depression-related behavior and antidepressant response, we used Creb(loxP/loxP) mice to localize CREB deletion to the hippocampus. In an assay sensitive to chronic antidepressant response, the novelty-induced hypophagia procedure, hippocampal CREB deletion, did not alter the response to chronic antidepressant treatment. In contrast, mice with hippocampal CREB deletion responded to acute antidepressant treatment in this task, and this accelerated response was accompanied by an increase in hippocampal neurogenesis. Upregulation of the CREB-family protein cAMP response-element modulator (CREM) was observed after CREB deletion. Viral overexpression of the activator isoform of CREM, CREMτ, in the hippocampus also resulted in an accelerated response to antidepressants as well as increased hippocampal neurogenesis. This is the first demonstration of CREMτ within the brain playing a role in behavior and specifically in behavioral outcomes following antidepressant treatment. The current results suggest that activation of CREMτ may provide a means to accelerate the therapeutic efficacy of current antidepressant treatment.

Differential effects of acute and repeated citalopram in mouse models of anxiety and depression.

Clinically, SSRIs are widely prescribed in the treatment of several anxiety disorders, although very few pre-clinical studies have observed a beneficial effect of this class of drugs in animal models of anxiety. Furthermore, the biphasic pattern observed clinically, an exacerbation of anxiety followed by beneficial effects, is rarely observed in animal studies. In the present study we document this clinical phenomenon in several behavioural paradigms. While a single injection of citalopram induced anxiogenic effects, three administrations of citalopram were sufficient to elicit anxiolytic effects. Congruent with these data, we observed that short-term repeated administration of citalopram was accompanied by increased activation of cAMP response element-binding protein (CREB) in the hippocampus and desensitization of 5-HT1A receptors, two phenomena well associated with chronic rather than acute actions of antidepressants. Moreover, effects of citalopram were abolished in CREBalphaDelta mutant animals in the elevated zero maze (EZM) and tail suspension test (TST), but not in novelty-induced hypophagia (NIH). Further, the desensitization of 5-HT1A receptors elicited by citalopram was not affected by CREB deficiency. The significance of the EZM and TST paradigms in predicting therapeutic efficacy is well known while effects in NIH and 5-HT1A sensitization are less well-established. These data demonstrate that behavioural responses to citalopram are dependent on the frequency of its administration, and that these responses are differentially dependent on CREB function.

Roles of accessory subunits in alpha4beta2(*) nicotinic receptors.

Accessory subunits in heteromeric nicotinic receptors (AChRs) do not take part in forming ACh binding sites. alpha5 and beta3 subunits can function only as accessory subunits. We show that both alpha5 and beta3 efficiently assemble in human alpha4beta2(*) AChRs expressed in permanently transfected human embryonic kidney (HEK) cell lines. Only (alpha4beta2)(2)alpha5, not (alpha4beta2)(2)beta3 AChRs, have been detected in brain. The alpha4beta2alpha5 line expressed 40% more AChRs than the parent alpha4beta2 line and was equally sensitive to up-regulation by nicotine. The alpha4beta2beta3 line expressed 25-fold more AChRs than the parental line and could not be further up-regulated by nicotine. Relative sensitivity to activation by ACh depends on the accessory subunit, beta2 conferring the greatest sensitivity, alpha5 less, and beta3 and alpha4 much less. Accessory subunits form binding sites for positive allosteric modulators, as illustrated by the observation that alpha5 conferred high sensitivity to galanthamine. In the presence of alpha5 or beta3, stable, partially degraded, dead end intermediates accumulated within the cells. These may have the form alpha5alpha4beta2alpha5. The efficiency with which alpha5 and beta3 assemble with alpha4 and beta2 and the necessity of avoiding formation of potentially toxic intermediates may explain why alpha5 and beta3 seem to be transcribed at low levels in brain. Autosomal dominant nocturnal frontal lobe epilepsy can be caused by the alpha4 mutation S247F. This mutant did not produce functional AChRs unless cells were cotransfected with alpha5, beta3, or alpha6 to replace alpha4 as accessory subunit.

The proteasome inhibitor bortezomib (Velcade) sensitizes some human tumor cells to Apo2L/TRAIL-mediated apoptosis.

On testing a panel of different human cancer cell lines, we observed that the proteasome inhibitor bortezomib could dramatically sensitize some lines to the apoptotic effects of Apo2L/TRAIL. Certain renal, colon, or breast tumor cell lines were dramatically sensitized, whereas other tumor lines from the same tissue of origin remained resistant. This sensitization did not correlate with either the p53 status of the individual tumor cell lines or their intrinsic sensitivity to Apo2L/TRAIL. Colon cancer cell lines lacking p53 or Bax were sensitized by bortezomib, suggesting that neither p53 nor Bax levels were crucial for sensitization. Although the molecular basis of bortezomib sensitization of tumor cells to Apo2L/TRAIL remains to be determined, this combination can have an enhanced apoptotic effect over either agent alone for certain human cancer cells.

Selective deletion of a cell cycle checkpoint kinase (ATR) reduces neurogenesis and alters responses in rodent models of behavioral affect.

Hippocampal function has been implicated in mood and anxiety disorders, as well as in the response to antidepressant (AD) treatment. However, the significance of new neurons in the therapeutic mechanism of ADs remains unclear. In this study, the proliferation of new neurons was inhibited through conditional deletion of ataxia telangeictasia-mutated and rad-3 related (ATR), a cell cycle checkpoint kinase, and cellular and behavioral outcomes following AD exposure were evaluated. ATR was conditionally deleted by microinjecting a Cre recombinase-expressing virus into the hippocampus of floxed-ATR mice. Behavioral assessment in multiple rodent models of affective state revealed anxiolytic-like behavior in the elevated zero maze, marble burying test, and novelty-induced hypophagia (NIH) test. The efficacy of chronic desipramine (DMI) treatment was evaluated in the NIH test, as this paradigm is thought to be sensitive to increases in neurogenesis by chronic AD exposure. Chronic exposure to DMI reduced hyponeophagia in the NIH test in control mice, whereas DMI had no behavioral effect in ATR-deleted mice. Although DMI did not alter cell proliferation in either group, it did produce a robust increase in dendritic spine density in control mice, indicative of enhanced neuronal plasticity. This effect of DMI on spine density was severely attenuated following ATR deletion. These findings demonstrate that reductions in basal neurogenesis produce an anxiolytic phenotype and reduce AD efficacy in behaviors requiring chronic exposure. Furthermore, attenuated capacity for synaptic remodeling may underlie these behaviors. ATR deletion may serve as a valuable model to study the various proposed roles of newborn neurons in the hippocampus.