Barbara A. Christy

Blood-derived angioblasts accelerate blood-flow restoration in diabetic mice

Endothelial cell progenitors, angioblasts, have been detected in the peripheral blood of adult humans, mice, and rabbits. These cells have been shown to incorporate into the endothelium of newly forming blood vessels in pathological and nonpathological conditions. Here we investigated the possibility that the CD34-expressing leukocytes (CD34(+) cells) that appear to be enriched for angioblasts could be used to accelerate the rate of blood-flow restoration in nondiabetic and diabetic mice undergoing neovascularization due to hindlimb ischemia. CD34(+) cells did not accelerate the restoration of flow in nondiabetic mice, but dramatically increased it in diabetic mice. Furthermore, CD34(+) cells derived from type 1 diabetics produced fewer differentiated endothelial cells in culture than did their type 2 diabetic- or nondiabetic-derived counterparts. In vitro experiments suggest that hyperglycemia per se does not alter the ability of angioblasts to differentiate or of angioblast-derived endothelial cells to proliferate. In contrast, hyperinsulinemia may enhance angioblast differentiation but impair angioblast-derived endothelial cell survival or proliferation. Our findings suggest that CD34(+) cells may be a useful tool for therapeutic angiogenesis in diabetics.

Degradation of Id proteins by the ubiquitin–proteasome pathway

Id proteins act as negative regulators of bHLH transcription factors by forming transcriptionally inactive protein complexes. The proposed function of these proteins includes promotion of cell growth and cell cycle progression, induction of apo‐ptosis, and inhibition of cellular differentiation. We investigated the role of the ubiquitin‐mediated proteolytic pathway in the degradation of the Id3 protein. We found Id3 to be a short‐lived protein and estimated the half‐life to be ~20 min in 293 cells. Using specific inhibitors of the 26S proteasome and mutant fibroblast cells with a temperature‐sensitive defect in the essential E1 ubiquitin‐activating enzyme, we show that Id3 and the related Id1 and Id2 proteins are degraded through the ubiquitin‐proteasome pathway. We found the Id4 protein to be much less sensitive to inhibitors of the 26S proteasome, but its degradation was dependent on the E1 enzyme. In addition, we observed that coexpression of the bHLH protein E47 with Id3 significantly reduced the rate of degradation of Id3, suggesting that Id3 is less susceptible to degradation by the 26S proteasome when complexed to a bHLH protein.—Bounpheng, M. A., Dimas, J. J., Dodds, S. G., Christy, B. A. Degradation of Id proteins by the ubiquitin‐proteasome pathway. FASEB J. 13, 2257–2264 (1999)

Synaptic Regulation of Immediate Early Gene Expression in Primary Cultures of Cortical Neurons

Abstract: Neuronal stimulation can rapidly activate several immediate early genes that code for transcription factors. We have used primary cortical cultures to study the regulation of four of these genes, c‐fos, c‐jun, jun‐B, and zif268. Im‐munocytochemical studies with antibodies to Jun‐B, c‐Jun, and c‐Fos demonstrate intense staining in the nuclei of a subset of cortical neurons in mature cultures (21–25 days in vitro) but not young cultures (3–7 days in vitro). To assess whether this immunoreactivity may be induced by spontaneous synaptic activity that develops with a similar profile, we examined the effects of agents that reduce this synaptic activity. Tetrodotoxin or N‐methyl‐d‐aspartate receptor antagonists suppress basal immunoreactivity to Jun‐B and c‐Fos, but not c‐Jun, indicating that the basal level of c‐Jun expression is not dependent on electrical activity. Pierotoxin, an agent that increases synaptic excitation indirectly by blocking inhibitory synaptic currents mediated by γ‐aminobutyric acidA receptors, markedly increases the percentage of neurons displaying immunoreactivity to c‐Fos, c‐Jun, Jun‐B, and Zif268. Northern analysis suggests that the increases in immunostaining induced by picrotoxin are secondary to a rapid increase in mRNA for these proteins. These findings provide evidence for rapid transcriptional regulation of immediate early genes in cortical neurons by synaptic activity.

Characterization of natural Epstein-Barr virus infection and replication in smooth muscle cells from a leiomyosarcoma

Cells from a leiomyosarcoma tumor (LMS‐1) from a patient with the acquired immunodeficiency syndrome (AIDS) were explanted, cultured in vitro, and studied by phase‐contrast microscopy for morphologic and growth characteristics, immunostaining for cell markers, EBER in situ hybridization and polymerase chain reaction for detection of Epstein‐Barr virus (EBV), and immunostaining for expression of EBV antigens. The cells exhibited very slow growth in vitro, with unusual elliptical and spindle‐shaped morphology and fragmentation of the cytoplasm into long, tapering, cytoplasmic processes. Greater than 90% of cells expressed diffuse distribution of the smooth muscle isoform of actin by immunoperoxidase staining. Approximately 25% of cells expressed very bright fluorescence by immunostaining of the smooth muscle isoforms of calponin and actin. The majority of cells demonstrated a weak signal for CD21; approximately 5–10% of cells showed a strong signal that was confined to cell surfaces. The cultured cells harbored EBV, and infectious EBV continued to be detected by polymerase chain reaction and virus culture through several passages in vitro. Several EBV antigens were expressed, including latent antigen EBNA‐1, immediate‐early antigen BZLF1, early antigen EA‐D, and late antigens, including viral capsid antigen p160, gp125, and membrane antigen gp350. Human umbilical cord lymphocytes that were transformed with virus isolated from cultured cells yielded immortalized cell lines that expressed EBV antigens similar to other EBV‐transformed lymphocyte cell lines. These results confirm that EBV is capable of lytic infection of smooth muscle cells with expression of a repertoire of latent and replicative viral products and production of infectious virus. EBV infection of smooth muscle cells may contribute to the oncogenesis of leiomyosarcomas. J. Med. Virol. 57:36–46, 1999.

The Zinc Finger Transcription Factor Zif268/Egr-1 Is Essential for Schwann Cell Expression of the p75 NGF Receptor

Nerve injury alters the function of Schwann cells from quiescent, myelin forming cells to proliferating cells that facilitate nerve repair. The transcription factor, Zif268, may be involved in transmitting injury-related signals since its expression is rapidly induced by nerve transection in vivo and without intervening protein synthesis by injury-related signals in vitro. Expression of the low-affinity p75 nerve growth factor receptor (NGFRp75) by Schwann cells after nerve injury closely correlated with the zif268 expression profile, and Zif268 transactivated the NGFRp75 promoter in transient transfection assays. Conversely, the NGFRp75 gene was not expressed when Zif268 protein was depleted by stable transfection of antisense cDNA. Moreover, nuclear proteins corresponding to Zif268 bound to the NGFRp75 promoter by Southwestern blotting, indicating that a direct interaction of Zif268 with the NGFR gene is required for its expression in Schwann cells.

Characterization of the mouse JAB1 cDNA and protein.

JAB1 was originally described as a transcriptional coactivator of c-Jun and Jun D. Recent data suggests that JAB1 is a component of a large protein complex, the JAB1 signalosome in mammals and the COP9 complex in plants. The JAB1 signalosome is implicated in the phosphorylation of selected transcription factors, while the COP9 complex is involved in repression of photomorphogenesis in Arabidopsis. In this study, we describe the partial characterization of mouse JAB1 (mJAB1). The murine JAB1 protein is encoded by a gene located on mouse chromosome 1. mJAB1 mRNA is abundantly expressed in a variety of adult tissues as well as in mouse embryos. The JAB1 protein was readily detectable in many cell types and localized to both the nucleus and cytoplasm. Endogenous JAB1 protein is relatively stable and its degradation is not perturbed by blocking 26S proteasome activity, suggesting that this protein is not degraded by the ubiquitin-mediated proteolytic pathway.

p53 as an intervention target for cancer and aging

p53 is well known for suppressing tumors but could also affect other aging processes not associated with tumor suppression. As a transcription factor, p53 responds to a variety of stresses to either induce apoptosis (cell death) or cell cycle arrest (cell preservation) to suppress tumor development. Yet, the effect p53 has on the non-cancer aspects of aging is complicated and not well understood. On one side, p53 could induce cellular senescence or apoptosis to suppress cancer but as an unintended consequence enhance the aging process especially if these responses diminish stem and progenitor cell populations. But on the flip side, p53 could reduce growth and growth-related stress to enable cell survival and ultimately delay the aging process. A better understanding of diverse functions of p53 is essential to elucidate its influences on the aging process and the possibility of targeting p53 or p53 transcriptional targets to treat cancer and ameliorate general aging.

Reciprocal Id expression and myelin gene regulation in Schwann cells

Id proteins are thought to act as dominant negative antagonists of basic helix-loop-helix (bHLH) transcription factors that direct differentiation in various cell types. We found that Schwann cells express all four Id-family genes and that their transcript levels were reciprocally regulated in pairs during nerve maturation in vivo and cAMP-mediated differentiation in vitro. The rapid induction as part of the early response to axonal membranes and cytokines suggested that Id3 is involved in myelin gene repression. An inverse relationship between Id1/3 and myelin P0 expression was consistent with a role for these two Id proteins as inhibitors of differentiation, and Id1/3 proteins strongly repressed myelin gene promoter activity. Nuclear factors isolated from Schwann cells and intact sciatic nerves were found to bind three different HLH recognition sequences (E boxes) in the proximal region of the P0 promoter, and production of these DNA binding complexes was altered during differentiation. These data support the concept that Id proteins regulate myelin gene expression by controlling the formation of specific bHLH DNA binding complexes with different E-box preferences.

SULT2B1b Sulfotransferase: Induction by Vitamin D Receptor and Reduced Expression in Prostate Cancer

An elevated tumor tissue androgen level, which reactivates androgen receptor in recurrent prostate cancer, arises from the intratumor synthesis of 5α-dihydrotestosterone through use of the precursor steroid dehydroepiandrosterone (DHEA) and is fueled by the steroidogenic enzymes 3β-hydroxysteroid dehydrogenase (3β-HSD1), aldoketoreductase (AKR1C3), and steroid 5-alpha reductase, type 1 (SRD5A1) present in cancer tissue. Sulfotransferase 2B1b (SULT2B1b) (in short, SULT2B) is a prostate-expressed hydroxysteroid SULT that converts cholesterol, oxysterols, and DHEA to 3β-sulfates. DHEA metabolism involving sulfonation by SULT2B can potentially interfere with intraprostate androgen synthesis due to reduction of free DHEA pool and, thus, conversion of DHEA to androstenedione. Here we report that in prostatectomy specimens from treatment-naive patients, SULT2B expression is markedly reduced in malignant tissue (P < .001, Mann-Whitney U test) compared with robust expression in adjacent nonmalignant glands. SULT2B was detected in formalin-fixed specimens by immunohistochemistry on individual sections and tissue array. Immunoblotting of protein lysates of frozen cancer and matched benign tissue confirmed immunohistochemistry results. An in-house-developed rabbit polyclonal antibody against full-length human SULT2B was validated for specificity and used in the analyses. Ligand-activated vitamin D receptor induced the SULT2B1 promoter in vivo in mouse prostate and increased SULT2B mRNA and protein levels in vitro in prostate cancer cells. A vitamin D receptor/retinoid X receptor-α-bound DNA element (with a DR7 motif) mediated induction of the transfected SULT2B1 promoter in calcitriol-treated cells. SULT2B knockdown caused an increased proliferation rate of prostate cancer cells upon stimulation by DHEA. These results suggest that the tumor tissue SULT2B level may partly control prostate cancer growth, and its induction in a therapeutic setting may inhibit disease progression.

Changes in structure and methylation pattern in a cluster of thymidine kinase genes.

Cell line 101 is a thymidine kinase (TK)-positive derivative of Ltk- which contains ca. 20 copies of the herpes simplex virus TK gene organized in a tandem array. DNA methylation at three sites within the gene and flanking sequences was inversely correlated with expression: the sites were unmethylated in line 101, methylated in each of 4 TK-negative derivatives of 101, and unmethylated in each of 21 TK-positive derivatives derived from them. The same three sites were affected in most of the 20 copies of the TK gene, whereas other sites between them were not affected. Although the entire gene cluster was never lost, indicating that integration into the genome was stable, internal rearrangements occurred at a high frequency. The rearrangements had no obvious correlation with the state of methylation or with the expression of the genes.