Kaposi's sarcoma herpesvirus lytic replication compromises apoptotic response to p53 reactivation in virus-induced lymphomas.

Primary effusion lymphomas (PELs) are aggressive Kaposi's sarcoma herpesvirus (KSHV)-induced malignancies with median survival time <6 months post-diagnosis. Mutations in the TP53 gene seldom occur in PELs, suggesting that genetic alterations in the TP53 are not selected during PEL progression. We have reported that p53 reactivation by an inhibitor of the p53-MDM2 interaction, Nutlin-3, induces selective and massive apoptosis in PEL cells leading to efficient anti-tumor activity in a subcutaneous xenograft model for PEL. Here, we show compelling anti-tumor activity of Nutlin-3 in the majority of intraperitoneal PEL xenografts in vivo. Interestingly, our results demonstrate that spontaneous induction of viral lytic replication in tumors could drastically attenuate the p53-dependent apoptotic response to Nutlin-3. Moreover, viral reactivation compromised p53-dependent apoptosis in PEL cells treated with genotoxic anti-cancer agents doxorubicin and etoposide. We have recently demonstrated that the Ser/Thr kinases Pim 1 and 3 are required to trigger induction of the lytic replication cascade of KSHV. We have now assessed the ability of a novel Pim kinase inhibitor to restore the Nutlin-3-induced cytotoxicity in lytic PEL cells. PEL cells induced to lytic replication by phorbol esters showed 50% inhibition of active viral replication following treatment with the Pim kinase inhibitor. Importantly, co-treatment of these cells with the kinase inhibitor and Nutlin-3 resulted in a robust restoration of the Nutlin-3-induced cell death. These results highlight the potential impact of activation of viral lytic replication on disease progression and response to treatment in KSHV-induced lymphomas.

Tumour-homing peptides: tools for targeting, imaging and destruction.

Each normal organ and pathological condition contains organ- or disease-specific molecular tags on its vasculature that constitute a vascular 'zip code' system. Tissue-selective tumour metastasis may also depend on vascular addresses. We have used phage display peptide libraries to map disease-specific differences in the vasculature. By using this technology, we have isolated several peptides which are targeted specifically to tumour blood vessels, lymphatic vessels and/or tumour cells. Some of the tumour-homing peptides recognize common angiogenesis markers and are capable of binding to several types of tumour, whereas other peptides recognize tumour-type-specific differences. We have also shown that the vasculature of a pre-malignant lesion differs from that of a full-blown tumour and also from the vasculature of the corresponding normal organ. Our peptides have revealed molecules that act as novel biomarkers of this vascular heterogeneity. Interestingly, some of our homing peptides are able to penetrate the target cells. This internalization differs from that of the Tat, penetratins and other related peptides in that our peptides enter the cell in a cell-type-specific manner. These peptides appear to be able to concentrate in the target tissue, making them particularly efficient delivery vectors for the targeting of drugs, other therapeutic moieties and imaging agents.

A heparan sulfate-targeted conditionally replicative adenovirus, Ad5.pk7-Delta24, for the treatment of advanced breast cancer.

Conditionally replicating adenoviruses (CRAds) that replicate in tumor but less in normal cells are promising anticancer agents. A major determinant of their potency is their capacity for infecting target cells. The primary receptor for serotype 5 adenovirus (Ad5), the most widely used serotype in gene therapy, is the coxsackie-adenovirus receptor (CAR). CAR is expressed variably and often at low levels in various tumor types including advanced breast cancer. We generated a novel p16/retinoblastoma pathway-dependent CRAd, Ad5.pK7-Delta24, with a polylysine motif in the fiber C-terminus, enabling CAR-independent binding to heparan sulfate proteoglycans (HSPG). Ad5.pK7-Delta24 mediated effective oncolysis of all breast cancer cell lines tested. Further, we utilized noninvasive, fluorescent imaging for analysis of antitumor efficacy in an orthotopic model of advanced hormone refractory breast cancer. A therapeutic benefit was seen following both intratumoral and intravenous delivery. Murine biodistribution similar to Ad5, proven safe in trials, suggests feasibility of clinical safety testing. Interestingly, upregulation of CAR was seen in low-CAR M4A4-LM3 breast cancer cells in vivo, which resulted in better than expected efficacy also with an isogenic CRAd with an unmodified capsid. These results suggest utility of Ad5.pK7-Delta24 and the orthotopic model for further translational studies.

Solution structures and integrin binding activities of an RGD peptide with two isomers.

The Arg-Gly-Asp (RGD) sequence serves as the primary integrin recognition site in extracellular matrix proteins, and peptides containing this sequence can mimic the activities of the matrix proteins. Depending on the context of the RGD sequence, an RGD-containing peptide may bind to all of the RGD-directed integrins, to a few, or to only a single one. We have previously isolated from a phage-displayed peptide library a cyclic peptide that binds avidly to the alpha(v)beta3 and alpha(v)beta5 integrins but does not bind to other closely related integrins. This peptide, ACDCRGDCFCG, exists in two natural configurations depending on internal disulfide bonding. The peptide with the 1-4; 2-3 disulfide bond arrangement accounts for most of the alpha(v) integrin binding activity, whereas the 1-3; 2-4 peptide is about 10-fold less potent. Solution structure analysis by nuclear magnetic resonance reveals an entirely different presentation of the RGD motif in the two isomers of RGD-4C. These results provide new insight into the ligand recognition specificity of integrins.

Deterministic diffractive diffusers for displays.

A LCD backlighting device that uses a diffractive light extractor has been developed for applications in which pointlike light sources are employed. The novel system eliminates the images of light sources, which appear as bright lines emanating from each source in the conventional diffractive approach. In addition, the system illuminates the LCD uniformly: Modulation of the diffractive structure as a function of position is used to control the output field of this extended planar light source.

Effects of palmitoylation of replicase protein nsP1 on alphavirus infection.

The membrane-associated alphavirus RNA replication complex contains four virus-encoded subunits, the nonstructural proteins nsP1 to nsP4. Semliki Forest virus (SFV) nsP1 is hydrophobically modified by palmitoylation of cysteines 418 to 420. Here we show that Sindbis virus nsP1 is also palmitoylated on the same site (cysteine 420). When mutations preventing nsP1 palmitoylation were introduced into the genomes of these two alphaviruses, the mutant viruses remained viable and replicated to high titers, although their growth was slightly delayed. The subcellular distribution of palmitoylation-defective nsP1 was altered in the mutant: it no longer localized to filopodial extensions, and a fraction of it was soluble. The ultrastructure of the alphavirus replication sites appeared normal, and the localization of the other nonstructural proteins was unaltered in the mutants. In both wild-type- and mutant-virus-infected cells, SFV nsP3 and nsP4 could be extracted from membranes only by alkaline solutions whereas the nsP2-membrane association was looser. Thus, the membrane binding properties of the alphavirus RNA replication complex were not determined by the palmitoylation of nsP1. The nsP1 palmitoylation-defective alphaviruses produced normal plaques in several cell types, but failed to give rise to plaques in HeLa cells, although they induced normal apoptosis of these cells. The SFV mutant was apathogenic in mice: it caused blood viremia, but no infectious virus was detected in the brain.

Electron-beam-fabricated asymmetric transmission gratings for microspectroscopy.

Asymmetric transmission gratings operating in the resonance domain are designed by modeling of the dose-controlled electron-beam lithography process with Gaussian convolution. We aim to exceed some efficiency limit eta(s) over a specified spectral range and to maximize eta(s). The resultant continuous-profile gratings are fabricated by electron-beam lithography and proportional reactive-ion etching into SiO(2). We demonstrate gratings with good signal-to-noise ratio and a diffraction efficiency greater than 40% for wavelengths from 400 to 750 nm.

Alphavirus replicase protein NSP1 induces filopodia and rearrangement of actin filaments.

Expression of the NSP1 protein of Semliki Forest virus and Sindbis virus in cultured cells induced filopodia-like extensions containing NSP1 but not F actin. The actin stress fibers disappeared, whereas vimentin, keratin, and tubulin networks remained intact. The effects of NSP1 were dependent on its palmitoylation but not on its enzymatic activities and were also observed in virus-infected cells.

Critical residues of Semliki Forest virus RNA capping enzyme involved in methyltransferase and guanylyltransferase-like activities.

The Semliki Forest virus (SFV) replicase protein nsP1 has methyltransferase (MT) and guanylyltransferase-like (GT) activities, which are involved in the capping of viral mRNAs. MT catalyzes the transfer of the methyl group from S-adenosylmethionine (AdoMet) to position 7 of GTP, and this reaction is followed by GT-catalyzed formation of the covalent complex m7GMP-nsP1. These reactions are virus specific and thus potential targets for inhibitors of virus replication. We have mutated residues of SFV nsP1, which are conserved in related proteins of the large alphavirus-like superfamily. Mutations of D64, D90, R93, C135, C142, and Y249 to alanine destroyed or greatly reduced the MT activity of nsP1. All MT-negative mutants lost also the GT activity, confirming that methylation of GTP is an essential prerequisite for the synthesis of the covalent guanylate complex. Mutation of H38 prevented the GT reaction without destroying MT activity. Conservation of residues essential for both reactions in the alphavirus-like superfamily implies that they use a capping mechanism similar to that for the alphaviruses. Residues D64 and D90 were necessary for AdoMet binding, as measured by UV cross-linking. Secondary structure predictions of nsP1 and other proteins of the superfamily place these residues in positions corresponding to AdoMet-binding sites of cellular methyltransferases, suggesting that they all may be structurally related.

The effects of palmitoylation on membrane association of Semliki forest virus RNA capping enzyme.

The nonstructural protein Nsp1 of Semliki Forest virus has guanine-7-methyltransferase and guanylyltransferase-like activities, required in the capping of viral mRNAs. It is palmitoylated and tightly associated with the cytoplasmic surface of the plasma membrane, endosomes, and lysosomes. To localize the acylation site(s) and the putative membrane-targeting domain, a number of deletions were made in the nsp1 gene. Most deletions resulted in the expression of nonpalmitoylated, enzymatically inactive, cytoplasmic protein. Palmitate could be released from Nsp1 with neutral hydroxylamine, indicating a thioester linkage to a cysteine residue. Therefore we mutated the conserved cysteine residues of Nsp1 to alanine. Triple mutation of Cys418, Cys419, and Cys420 resulted in nonpalmitoylated Nsp1, which was enzymatically active and still associated with membranes. However, it could be released from the membranes with 1 M NaCl, whereas 50 mM sodium carbonate (pH 12) was required to release wild type Nsp1, suggesting a conversion from an integral to a peripheral membrane protein. Indirect confocal immunofluorescence microscopy showed that the nonpalmitoylated Nsp1 colocalized with the plasma membrane marker, concanavalin A. However, it was not detected in filopodia, which were heavily stained in cells expressing wild type Nsp1. These results indicate that the acylation of Nsp1 was not needed for its targeting to the plasma membrane, but it was necessary for the migration to the filopodial extensions of the plasma membrane.

Synthesis of Semliki Forest virus RNA polymerase components nsP1 through nsP4 in Saccharomyces cerevisiae by expression of cDNA encoding the nonstructural polyprotein.

A Semliki Forest virus nonstructural polyprotein, P1234, expressed in the yeast Saccharomyces cerevisiae in the absence of a replicative RNA template appeared to be properly cleaved into nsP1 to nsP4. All nsPs were membrane associated, and nsP2 was also transported to the nucleus. The membrane fraction containing nsPs showed guanine-7-methyltransferase and guanylyltransferase-like activities, typical for Semliki Forest virus nsP1.

The alphavirus replicase protein nsP1 is membrane-associated and has affinity to endocytic organelles.

In alphavirus-infected cells the four virus-specific nonstructural proteins (nsP1-nsP4) are located on modified endosomes and lysosomes known as type I cytopathic vacuoles. In this paper, we show that when nsP1 was expressed alone in HeLa cells with the aid of the recombinant T7 RNA polymerase vaccinia (vTF7-3) virus system, it was tightly associated with intracellular smooth membranes. The membrane association may be due to acylation, since nsP1 could be labeled with [3H]palmitic acid in both Semliki Forest virus-infected and nsP1-transfected HeLa cells. Release of the 3H-label by alkaline methanolysis suggests that the palmitate was associated with nsP1 via an ester bond. Pulse-chase experiments done on nsP1-transfected cells revealed that this protein was rapidly associated with the membranes. After synchronizing the synthesis of the nsP1 gene product in transfected cells, nsP1 appeared first at the plasma membrane and thereafter on vesicles, many of which contained the endosomal transferrin receptor marker. Later, nsP1 appeared on large vacuoles, which contained the lysosome specific h-lamp-1 protein. Membrane association of nsP1, and its affinity to endosomes and lysosomes, suggest a role of this protein in the biogenesis of the alphavirus-specific RNA replication complex.

Expression of Semliki Forest virus nsP1-specific methyltransferase in insect cells and in Escherichia coli.

We have expressed the Semliki Forest virus (SFV)-specific nonstructural protein nsP1 both in insect cells and in Escherichia coli in the absence of other viral proteins. A substantial amount of nsP1 was synthesized in Sf9 cells infected with the recombinant Autographa californica nuclear polyhedrosis virus (AcNPV) AcNPV-nsP1. These cells had a high level of guanine-7-methyltransferase activity compared with that of wild-type AcNPV-infected cells. The methyltransferase activity and nsP1 were mostly in the mitochondrial pellet fraction (P15). The enzymatic activity was increased by treatment with deoxycholate (DOC), as in the case of SFV-infected BHK cells. The material released by DOC treatment from P15 of the AcNPV-nsP1-infected cells was analyzed by gel filtration and sucrose gradient centrifugation. Both the methyltransferase activity and nsP1 were in aggregates. nsP1 expressed in E. coli at 37 degrees C sedimented at 15,000 x g, whereas after expression at 15 degrees C, both nsP1 and methyltransferase activity were in the supernatant fraction. Paradoxically, the activity from E. coli was completely inhibited by Triton X-100 and DOC. Sucrose gradient analysis showed that even the "soluble" nsP1-methyltransferase was in aggregates. The methyltransferase activities in the P15 fractions of SFV-infected BHK cells and AcNPV-nsP1-infected Sf9 cells and in E. coli catalyzed linear incorporation of the [3H]methyl group from S-adenosylmethionine to GTP for a 60-min period. The enzymes from the three sources had similar substrate specificities and Km values for S-adenosylmethionine. In addition to GTP, they all methylated dGTP and GpppG, but not m7GTP or GpppA, or in vitro-transcribed RNAs with GpppA and GpppG caps. The unique properties of SFV-specific nsP1 methyltransferase are discussed.