The role of E2F1 in the development of hypertrophic cardiomyopathy.

The overexpression of the transcription factor, E2F1, induces hypertrophy and apoptosis with cell cycle re-entry in cardiomyocytes in vitro and in vivo, suggesting that targeting E2F1 may have therapeutic potential. Accordingly, we tested the hypothesis that blocking the E2F1-mediated signal transduction pathway prevents cardiac hypertrophy by treating E2F1 knockout mice (E2F1-/-) with either isoproterenol (ISO) or Angiotensin II (ANG). Echocardi-ography was used to measure left ventricular mass index and myocardial performance index, a measure of combined systolic and diastolic left ventricular function. In control mice (E2F1+/+) both ISO and ANG treatments induced cardiac hypertrophy, and impaired ventricular function in ANG treated mice. In contrast to previously published work, E2F1-/- mice also demonstrated a similar pattern of cardiac hypertrophy and function after either treatment. Atrial natriuretic peptide, a molecular marker of hypertrophy and necropsy-determined body weight-normalized left ventricle mass were similarly increased in ISO and ANG treated E2F1+/+ and E2F-/- mice, supporting the echocardiographic data. These data indicate that E2F1 is not necessary for the development of cardiac hypertrophy although studies using an overexpression approach suggest a causal role of E2F1. The reason for this discrepancy is unclear, although it is possible that other E2F-family members (e.g., E2F2) may play a compensatory role. In conclusion, our data demonstrate that cardiac hypertrophy can be induced in an E2F1-independent fashion and suggest that in contrast to previous reports, targeting E2F1 may not be a good therapeutic approach.

Down-regulation of serum gonadotropins is as effective as estrogen replacement at improving menopause-associated cognitive deficits.

Declining levels of estrogen in women result in increases in gonadotropins such as luteinizing hormone (LH) through loss of feedback inhibition. LH, like estrogen, is modulated by hormone replacement therapy. However, the role of post-menopausal gonadotropin increases on cognition has not been evaluated. Here, we demonstrate that the down-regulation of ovariectomy-driven LH elevations using the gonadotropin releasing hormone super-analogue, leuprolide acetate, improves cognitive function in the Morris water maze and Y-maze tests in the absence of E2. Furthermore, our data suggest that these effects are independent of the modulation of estrogen receptors alpha and beta, or activation of CYP19 and StAR, associated with the production of endogenous E2. Importantly, pathways associated with improved cognition such as CaMKII and GluR1-Ser831 are up-regulated by leuprolide treatment but not by chronic long-term E2 replacement suggesting independent cognition-modulating properties. Our findings suggest that down-regulation of gonadotropins is as effective as E2 in modulating cognition but likely acts through different molecular mechanisms. These findings provide a potential novel protective strategy to treat menopause/age-related cognitive decline and/or prevent the development of AD.

Cell cycle re-entry and mitochondrial defects in myc-mediated hypertrophic cardiomyopathy and heart failure.

While considerable evidence supports the causal relationship between increases in c-Myc (Myc) and cardiomyopathy as a part of a "fetal re-expression" pattern, the functional role of Myc in mechanisms of cardiomyopathy remains unclear. To address this, we developed a bitransgenic mouse that inducibly expresses Myc under the control of the cardiomyocyte-specific MHC promoter. In adult mice the induction of Myc expression in cardiomyocytes in the heart led to the development of severe hypertrophic cardiomyopathy followed by ventricular dysfunction and ultimately death from congestive heart failure. Mechanistically, following Myc activation, cell cycle markers and other indices of DNA replication were significantly increased suggesting that cell cycle-related events might be a primary mechanism of cardiac dysfunction. Furthermore, pathological alterations at the cellular level included alterations in mitochondrial function with dysregulation of mitochondrial biogenesis and defects in electron transport chain complexes I and III. These data are consistent with the known role of Myc in several different pathways including cell cycle activation, mitochondrial proliferation, and apoptosis, and indicate that Myc activation in cardiomyocytes is an important regulator of downstream pathological sequelae. Moreover, our findings indicate that the induction of Myc in cardiomyocytes is sufficient to cause cardiomyopathy and heart failure, and that sustained induction of Myc, leading to cell cycle re-entry in adult cardiomyocytes, represents a maladaptive response for the mature heart.

Down-regulation of aminolevulinate synthase, the rate-limiting enzyme for heme biosynthesis in Alzheimer's disease.

Heme is an essential cell metabolite, intracellular regulatory molecule, and protein prosthetic group. Given the known alterations in heme metabolism and redox metal distribution and the up-regulation of heme oxygenase enzyme in Alzheimer's disease (AD), we hypothesized that heme dyshomeostasis plays a key role in the pathogenesis. To begin testing this hypothesis, we used qRT-PCR to quantify the expression of aminolevulinate synthase (ALAS1) and porphobilinogen deaminase (PBGD), rate-limiting enzymes in the heme biosynthesis pathway. The relative expression of ALAS1 mRNA, the first and rate-limiting enzyme for heme biosynthesis under normal physiological conditions, was significantly (p<0.05) reduced by nearly 90% in AD compared to control. Coordinately, the relative expression of PBGD mRNA, which encodes porphobilinogen deaminase, the third enzyme in the heme synthesis pathway and a secondary rate-limiting enzyme in heme biosynthesis, was also significantly (p<0.02) reduced by nearly 60% in AD brain compared to control and significantly related to apolipoprotein E genotype (p<0.005). In contrast, the relative expression of ALAD mRNA, which encodes aminolevulinate dehydratase, the second and a non-rate-limiting enzyme for heme biosynthesis, was unchanged between the two groups. Taken together, our results suggest regulation of cerebral heme biosynthesis is profoundly altered in AD and may contribute toward disease pathogenesis by affecting cell metabolism as well as iron homeostasis.

The neuronal expression of MYC causes a neurodegenerative phenotype in a novel transgenic mouse.

Many different proteins associated with the cell cycle, including cyclins, cyclin-dependent kinases, and proto-oncogenes such as c-MYC (MYC), are increased in degenerating neurons. Consequently, an ectopic activation of the cell cycle machinery in neurons has emerged as a potential pathogenic mechanism of neuronal dysfunction and death in many neurodegenerative diseases, including Alzheimer's disease. However, the exact role of cell cycle re-entry during disease pathogenesis is unclear, primarily because of the lack of relevant research models to study the effects of cell cycle re-entry on mature neurons in vivo. To address this issue, we developed a new transgenic mouse model in which forebrain neurons (CaMKII-MYC) can be induced to enter the cell cycle using the physiologically relevant proto-oncogene MYC to drive cell cycle re-entry. We show that such cell cycle re-entry results in neuronal cell death, gliosis, and cognitive deficits. These findings provide compelling evidence that dysregulation of cell cycle re-entry results in neurodegeneration in vivo. Our current findings, coupled with those of previous reports, strengthen the hypothesis that neurodegeneration in Alzheimer's disease, similar to cellular proliferation in cancer, is a disease that results from inappropriate cell cycle control.

Evidence for the novel expression of human kallikrein-related peptidase 3, prostate-specific antigen, in the brain.

Human kallikrein-related peptidase 3 (hK3), also known as prostate-specific antigen (PSA), is a 33 kDa single chain glycoprotein belonging to the kallikrein family of serine proteases. With chymotrypsin-like enzymatic activity, hK3 is directly and indirectly involved in a number of diverse biological functions including male fertility, the regulation of cell proliferation, and the inhibition of angiogenesis. The gene encoding hK3, hKLK3, is located on chromosome 19 and its expression has been shown to be regulated by steroid hormones through androgen receptor-mediated transcription. hK3 was once thought to be exclusively expressed and secreted by prostatic epithelial cells, hence the initial name of prostate-specific antigen, but has since been isolated in several nonprostatic tissues and ongoing characterization of alternative splicing variants has found at least 13 distinct mRNA transcripts. The detection of hK3 in cerebrospinal fluid prompted the hypothesis that hK3 may be produced in the brain. To test this notion, in this study we used RT-PCR amplification of brain tissue total RNA and examined hK3 protein by immunohistochemical, and immunoblot analysis. RT-PCR revealed several hK3 mRNA transcripts in the brain. Confirming these findings, both immunohistochemical staining and western immunoblotting showed evidence for hK3 protein in neuronal cells. Taken together, our findings support the expression of hK3 in neuronal cells reinforcing the concept of hK3 as a ubiquitous protein with more multifarious biological activity than previously believed. Ongoing research seeks to elucidate the functional significance of hK3 in brain cells.