Assessment of oncolytic HSV efficacy following increased entry-receptor expression in malignant peripheral nerve sheath tumor cell lines.

Limited expression and distribution of nectin-1, the major herpes simplex virus (HSV) type-1 entry-receptor, within tumors has been proposed as an impediment to oncolytic HSV (oHSV) therapy. To determine whether resistance to oHSVs in malignant peripheral nerve sheath tumors (MPNSTs) was explained by this hypothesis, nectin-1 expression and oHSV viral yields were assessed in a panel of MPNST cell lines using γ134.5-attenuated (Δγ134.5) oHSVs and a γ134.5 wild-type (wt) virus for comparison. Although there was a correlation between nectin-1 levels and viral yields with the wt virus (R=0.75, P =0.03), there was no correlation for Δγ134.5 viruses (G207, R7020 or C101) and a modest trend for the second-generation oHSV C134 (R=0.62, P=0.10). Nectin-1 overexpression in resistant MPNST cell lines did not improve Δγ134.5 oHSV output. While multistep replication assays showed that nectin-1 overexpression improved Δγ134.5 oHSV cell-to-cell spread, it did not confer a sensitive phenotype to resistant cells. Finally, oHSV yields were not improved with increased nectin-1 in vivo. We conclude that nectin-1 expression is not the primary obstacle of productive infection for Δγ134.5 oHSVs in MPNST cell lines. In contrast, viruses that are competent in their ability to counter the antiviral response may derive benefit with higher nectin-1 expression.

A myeloid cell-binding adenovirus efficiently targets gene transfer to the lung and escapes liver tropism.

Specific and efficient gene delivery to the lung has been hampered by liver sequestration of adenovirus serotype 5 (Ad5) vectors. The complexity of Ad5 liver tropism has largely been unraveled, permitting improved efficacy of Ad5 gene delivery. However, Kupffer cell (KC) scavenging and elimination of Ad5 still represent major obstacles to lung gene delivery strategies. KC uptake substantially reduces bioavailability of Ad5 for target tissues and compensatory dose escalation leads to acute hepatotoxicity and a potent innate immune response. Here, we report a novel lung-targeting strategy through redirection of Ad5 binding to the concentrated leukocyte pool within the pulmonary microvasculature. We demonstrate that this leukocyte-binding approach retargets Ad5 specifically to lung endothelial cells and prevents KC uptake and hepatocyte transduction, resulting in 165,000-fold enhanced lung targeting, compared with Ad5. In addition, myeloid cell-specific binding is preserved in single-cell lung suspensions and only Ad.MBP-coated myeloid cells achieved efficient endothelial cell transduction ex vivo. These findings demonstrate that KC sequestration of Ad5 can be prevented through more efficient uptake of virions in target tissues and suggest that endothelial transduction is achieved by leukocyte-mediated 'hand-off' of Ad.

Asymmetric coding of categorical spatial relations in both language and vision.

Describing certain types of spatial relationships between a pair of objects requires that the objects are assigned different "roles" in the relation, e.g., "A is above B" is different than "B is above A." This asymmetric representation places one object in the "target" or "figure" role and the other in the "reference" or "ground" role. Here we provide evidence that this asymmetry may be present not just in spatial language, but also in perceptual representations. More specifically, we describe a model of visual spatial relationship judgment where the designation of the target object within such a spatial relationship is guided by the location of the "spotlight" of attention. To demonstrate the existence of this perceptual asymmetry, we cued attention to one object within a pair by briefly previewing it, and showed that participants were faster to verify the depicted relation when that object was the linguistic target. Experiment 1 demonstrated this effect for left-right relations, and Experiment 2 for above-below relations. These results join several other types of demonstrations in suggesting that perceptual representations of some spatial relations may be asymmetrically coded, and further suggest that the location of selective attention may serve as the mechanism that guides this asymmetry.

Characterization of infectivity of knob-modified adenoviral vectors in glioma.

Malignant glioma continues to be a major target for gene therapy and virotherapy due to its aggressive growth and the current lack of effective treatment. However, these approaches have been hampered by inefficient infection of glioma cells by viral vectors,particularly vectors derived from serotype 5 adenoviruses (Ad5). This results from limited cell surface expression of the primary adenovirus receptor, coxsackie-adenovirus-receptor (CAR), on tumor cells. To circumvent this problem, Ad fiber pseudotyping,the genetic replacement of either the entire fiber or fiber knob domain with its structural counterpart from another human Ad serotype that recognizes a cellular receptor other than CAR, has been shown to enhance Ad infectivity in a variety of tumor types,including human glioma. Here, we have extended the paradigm of genetic pseudotyping to include fiber domains from non-human or"xenotype" Ads for infectivity enhancement of human glioma cell populations. In this study, we evaluated the gene transfer efficiency of a panel of Ad vectors which express one of five different "xenotype"fiber knob domains, including those derived from murine,ovine, porcine and canine species, in both human glioma cell lines as well as primary glioma tumor cells from patients. Adenovirus vectors displaying either canine Ad or porcine Ad fiber elements had the highest gene transfer to both glioma cell lines and primary tumor cells. The correlation between the viral infectivity of modified adenovirus vectors and expression of human CAR and CD46(an adenovirus type B receptor) on the surfaces of tumor cells was also analyzed. Taken together, human adenovirus vectors modified with "xenotype" fiber elements could be excellent candidates to target human glioma.

Cell vehicle targeting strategies.

Use of cells as therapeutic carriers has increased in the past few years and has developed as a distinct concept and delivery method. Cell-based vehicles are particularly attractive for delivery of biotherapeutic agents that are difficult to synthesize, have reduced half-lives, limited tissue penetrance or are rapidly inactivated upon direct in vivo introduction. Initial studies using cell-based approaches served to identify some of the key factors for the success of this type of therapeutic delivery. These factors include the efficiency of cell loading with a therapeutic payload, the means of cell loading and the nature of therapeutics that cells can carry. However, one important aspect of cell-based delivery yet to be fully investigated is the process of actual delivery of the cell payload in vivo. In this regard, the potential ability of cell carriers to provide site-specific or targeted delivery of therapeutics deserves special attention. The present review focuses on a variety of targeting approaches that may be utilized to improve cell-based therapeutic delivery strategies. The different aspects of targeting that can be applied to cell vehicles will be discussed, including physical methods for directing cell distribution, intrinsic cell-mediated homing mechanisms and the feasibility of engineering cells with novel targeting mechanisms. Development of cell targeting strategies will further advance cell vehicle applications, broaden the applicability of this delivery approach and potentiate therapeutic outcomes.

Inflammatory response, reactive oxygen species, programmed (necrotic-like and apoptotic) cell death and cancer.

In this short review we attempt to establish and/or strengthen connections between clinical, inflammatory manifestation of cancer, inflammatory processes driven by lipoxy-metabolites and their contribution to immortalized phenotype and apoptosis inhibition. Particularly the resemblance between symptoms of inflammation and signs associated with cancer chemotherapy and/or cytokine therapy is illustrated. In this context the role of apoptosis and necrosis in inflammation as well as the role of RedOx processes and lipid-oxidizing enzymes particularly cyclooxygenase-2 (COX-2) and also to lesser extend the 5-lipooxygenase (5-LOX) is highlighted. The multitude of biological effects of reactive oxygen species is shortly summarized and some aspects of it are being discussed in greater detail. Apoptotic cell death is discussed in the context of the "resolve-phase" of an inflammatory response. The disturbance of apoptosis is mainly deliberated in the framework of insufficient removal of immuno-effector cells that may cause autoimmunity. The role of COX-2 in apoptosis resistance is being highlighted mainly in the context of malignant transformation. The mechanism of cell death (apoptotic or necrotic) and its influence on the immune system and potential benefits of necrotic cell death induction during cancer chemotherapy is indicated.

Effect of chronic AT(1) receptor blockade on cardiac Smad overexpression in hereditary cardiomyopathic hamsters.

OBJECTIVE: As the pharmacological suppression of angiotensin has been associated with cardioprotective effects in cardiomyopathy, our primary aim was to determine whether the expression of Smad protein components of the cardiac TGF-beta signaling cascade is modulated by chronic AT(1) receptor blockade. Furthermore, we examined the relationship between cardiac Smad protein expression and altered collagen turnover in the cardiomyopathic heart. METHODS: Male UM-X7. 1 cardiomyopathic (CMP) Syrian hamsters at early (65 days) and late (200 days) stages of cardiomyopathy were subjected to 4 week losartan (15 mg/kg/day) treatment. Expression of left ventricular (LV) receptor-activated (Smad 2) and common-mediator (Smad 4) Smads from control (F1-beta strain) hamsters, non-treated cardiomyopathic (CMP), and losartan-treated CMP animals was assessed. Collagen turnover, including fibrillar collagen synthesis/accretion and cardiac MMP activity was assessed. RESULTS: Elevated mRNA abundance of fibrillar collagens and ANF were present in cardiomyopathic hearts and these trends were normalized in the early stage losartan-treated group. 4-Hydroxyproline and zymographic assays confirmed fibrosis and elevated MMP-1 and -2 activities in CMP hearts. Losartan treatment was associated with a modest reduction of cardiac 4-hydroxyproline concentration, and a significant reduction of both MMP-1 and MMP-2 activities. While TGF-beta(1) mRNAs were elevated in both CMP groups vs. controls, total TGF-beta protein content was not different in CMP vs. controls. In LV preparations containing nuclear extract, elevated Smad 2 and Smad 4 protein expression was noted in cardiomyopathic hearts vs. controls. Losartan treatment of late-stage CMP hamsters was associated with a significant reduction in Smad 2 and a modest reduction of Smad 4 protein expression vs. untreated CMP samples. CONCLUSIONS: Altered cardiac Smad expression, present in both early and late stage cardiomyopathy, is positively correlated with the occurrence of cardiac fibrosis and elevated collagen turnover in failing CMP hearts. Four week AT(1) blockade is associated with normalized expression of cardiac Smad 2 proteins, and these changes occur in parallel with some aspects of collagen turnover in failing cardiomyopathic hearts.

Characterization of the P140K, PVP(138-140)MLK, and G156A O6-methylguanine-DNA methyltransferase mutants: implications for drug resistance gene therapy.

The G156A O6-alkylguanine-DNA alkyltransferase (AGT) mutant protein, encoded by the G156A O6-methylguanine-DNA methyltransferase gene (MGMT), is resistant to O6-benzylguanine (BG) inactivation and, after transduction into hematopoietic progenitors, transmits remarkable resistance to BG and BCNU. As a result, a clinical trial, in which the MGMT gene is transduced into CD34+ cells of patients with cancer, has been approved. A newly identified AGT mutation, P140K, generates dramatically increased BG resistance relative to G156A, and suggests that gene transfer of P140K may confer improved hematopoietic cell protection. To address this hypothesis, we measured BG + BCNU and BG + TMZ resistance in G156A, P140K, or P138M/V139L/P140K (MLK) MGMT-transduced K562 cells. In addition, we performed a detailed characterization of individual properties including BG resistance, activity, and protein stability of these mutants in human hematopoetic K562 cells and E86 retroviral producer cells. In K562 cell extracts, the MLK and P140K mutants retained full activity at doses up to 1 mM BG, while G156A had a BG ED50 of 15 microM, compared with 0.1 microM for wtAGT. In the absence of BG, the G156A protein possessed a 56% reduction in specific O6-methyltransferase activity compared with wtAGT. MLK, P140K, and wtAGT all possessed similar specific activities, although the O6-methyl repair rate of all mutants was reduced 4- to 13-fold relative to wtAGT. The wtAGT, MLK, and P140K proteins were stable, with half-lives of greater than 18 hr. In contrast, only 20% of the G156A protein was stable after 12 hr in cycloheximide and, interestingly, the remaining protein appeared to retain most of the activity present in non-cycloheximide-treated cells. Differences in BG resistance, activity, and stability between P140K, MLK, and G156A suggest that P140K may be the optimal mutant for drug resistance gene transfer. However, hematopoietic K562 cells transduced with MFG-G156A, P140K, or MLK had similar degrees of BG and BCNU as well as BG and TMZ resistance when treated with concentrations of BG (< or =25 microM) achieved in clinical trials, suggesting similar efficacy in many in vivo applications.

A genetic approach to mapping the p53 binding site in the MDM2 protein.

BACKGROUND: The MDM2 oncoprotein binds to the tumor suppressor p53 and inhibits its anti-oncogenic functions. MATERIALS AND METHODS: To determine the amino acids of MDM2 that are critical for binding to p53, a modified two-hybrid screen was performed in yeast. Site-directed mutagenesis was then performed to identify MDM2 residues important for p53 interaction. Mutant MDM2 proteins were subsequently tested for their ability to bind to p53 in vitro and for their ability to regulate p53-mediated transcription in vivo. RESULTS: The yeast genetic screen yielded two Mdm2 mutations (G58D and C77Y) which disrupted binding to p53 in vitro without altering the conformation of MDM2 as determined with conformation-sensitive monoclonal antibodies. Site-directed mutagenesis yielded mutations of two additional amino acids of MDM2 (D68 and V75) that prevented binding to p53 in vitro. The mutant MDM2 proteins were unable to inhibit p53-dependent transcription in vivo, which is consistent with prior indications that a physical interaction between the two proteins is required for MDM2's inhibition of p53. Finally, the crystal structure of the MDM2-p53 complex shows that two of the four critical residues identified here contact p53 directly, while the remaining two residues play important structural roles in the MDM2 domain. CONCLUSIONS: MDM2 residues G58, D68, V75, and C77 are critical for MDM2's interaction with the p53 protein. Mutation of these residues to alanine prevents MDM2's interaction with p53 in vitro, and MDM2's regulation of p53's transcriptional activity in vivo.

Fraud and abuse compliance programs: their time has come.

Two recent developments in Federal law enforcement should prompt healthcare providers to establish or augment programs to detect and prevent Medicare and Medicaid fraud and abuse. New and controversial Federal sentencing guidelines require judges to impose multi-million dollar fines on companies convicted of certain Federal crimes, and substantial civil monetary penalties may be imposed for violation of the Medicare and Medicaid fraud and abuse laws. One of the ways to avoid these penalties is to establish an effective compliance program designed to prevent criminal conduct before it happens.

The microscopic morphology of orthotopic free muscle grafts in rabbits.

The flexor digitorum superficialis muscle was free grafted (without neurovascular anastomoses) in 122 rabbit forelimbs. Histologic nd histochemical examinations through 6 months after grafting were performed. An early ischemic necrosis of the entire graft, except for a few percent of fibers at the very surface, was consistently seen. Subsequently, there occurred a regeneration of muscle with reconstitution of up to 100 percent of normal numbers of fibers. There was a wide variation in the numbers of fibers regenerated; however, the fiber-free areas were then being replaced by connective tissue. Muscle grafts in 1-month-old rabbits regenerated faster and yielded muscle with evidence of more extensive reinnervation and less connective tissue than 3-month-old animals. In the early postgraft period, minced grafts appeared to be as good as whole ones, but after 1 month, they developed far more connective tissue. Differentiation into fast-twitch and slow-twitch muscle fibers and into high- and low-oxidative fibers began at 2 to 3 weeks after grafting but was not extensive until 3 months. At 6 months, grafts showed areas of normal-appearing muscle interspersed with areas that lacked signs of reinnervation. The earliest sign of regeneration is the appearance of several very elongated nuclei encircling each previously anucleate necrotic muscle fiber. A small amount of basophilic cytoplasm then appears around each new nucleus. As blood vessels grow into the graft, a centripetal wave of phagocytosis is seen, taking 2 to 3 weeks and leaving a bed of immature muscle fibers. We believe this to be the first documentation of regeneration's commencing prior to and thus independently of phagocytosis.

Evaluation of cell lines and immunofluorescence and plaque assay procedures for quantifying reoviruses in sewage.

Twelve continuous cell lines were tested to determine their sensitivity to reovirus types 1, 2, and 3 isolated from sewage. Madin-Darby bovine kidney (MDBK), rhesus monkey kidney (LLC-MK2), and human embryonic intestinal (intestinal 407) cells were most sensitive, respectively. In a similar study, MDBK cells were more sensitive than LLC-MK2 and Buffalo green monkey kidney (BGM) cells to sewage-isolated, protamine-precipitated reoviruses which had not been serotyped and had no previous cell contact. Sewage-isolated, protamine-precipitated reoviruses were also used in conjunction with MDBK cells in a comparative evaluation of immunofluorescent cell count and plaque assay procedures. The immunofluorescence assay is more sensitive and more rapid than the plaque assay. Reoviruses in excess of 10(4)/liter of raw sewage were detected by the immunofluorescent cell count assay.