Recent studies have demonstrated the importance of coagulation factor X (FX) in adenovirus (Ad) serotype 5-mediated liver transduction in vivo. FX binds to the adenovirus hexon hypervariable regions (HVRs). Here, we perform a systematic analysis of FX binding to Ad5 HVRs 5 and 7, identifying domains and amino acids critical for this interaction. We constructed a model of the Ad5-FX interaction using crystallographic and cryo-electron microscopic data to identify contact points. Exchanging Ad5 HVR5 or HVR7 from Ad5 to Ad26 (which does not bind FX) diminished FX binding as analyzed by surface plasmon resonance, gene delivery in vitro, and liver transduction in vivo. Exchanging Ad5-HVR5 for Ad26-HVR5 produced deficient virus maturation. Importantly, defined mutagenesis of just 2 amino acids in Ad5-HVR5 circumvented this and was sufficient to block liver gene transfer.In addition, mutation of 4 amino acids in Ad5-HVR7 or a single mutation at position 451 also blocked FX-mediated effects in vitro and in vivo. We therefore define the regions and amino acids on the Ad5 hexon that bind with high affinity to FX thereby better defining adenovirus infectivity pathways. These vectors may be useful for gene therapy applications where evasion of liver transduction is a prerequisite. (Blood. 2009;114:965-971) IntroductionAdenovirus (Ad)-based vectors are used frequently for preclinical gene delivery and therapy and have been used in more than 25% of gene therapy clinical trials conducted to date. Although adenovirus serotype 5 is the most commonly used serotype, the human and nonhuman adenovirus families are large, and many of these are being exploited in diverse clinical applications, such as cancer gene therapy and vaccination. [1][2][3][4] However, the use of Ad vectors as gene delivery tools has raised several safety concerns. The importance of such issues was highlighted in the recent STEP trial in which patients were vaccinated against human immunodeficiency virus using an Ad5 gene delivery vector. The trial was terminated because the vaccine did not function as expected, but actually increased infection rates in those patients with preexisting antibodies to Ad5. Together with other adverse events in humans transduced with Ad5, 5 this highlights the importance of understanding fundamental aspects of Ad biology.In vitro, the interaction of the Ad5 fiber and the coxsackie and adenovirus receptor (CAR) is the major pathway for Ad cell binding. 6,7 Similarly, engagement with integrins by the penton base protein mediates internalization after cell binding. 8 Although other candidate receptors for Ad5 have emerged since the interaction with CAR was identified, 9,10 the role of these receptors in gene transfer after intravascular gene delivery has not been substantiated.It is well established that Ad5 predominantly transduces rodent liver after intravascular injection, 11 however mutations of the Ad5 fiber and/or penton show limited effects on liver gene transfer mediated by Ad5 (reviewed in Nicklin et al 12 ). Thereafter, it w...
Last-generation adenovirus vectors, also called helper-dependent or gutless adenovirus, are very attractive for gene therapy because the associated in vivo immune response is highly reduced compared to first-and second-generation adenovirus vectors, while maintaining high transduction efficiency and tropism. Nowadays, gutless adenovirus is administered in different organs, such as the liver, muscle or the central nervous system achieving high-level and long-term transgene expression in rodents and primates. However, as devoid of all viral coding regions, gutless vectors require viral proteins supplied in trans by a helper virus. To remove contamination by a helper virus from the final preparation, different systems based on the excision of the helper-packaging signal have been generated. Among them, Cre-loxP system is mostly used, although contamination levels still are 0.1-1% too high to be used in clinical trials. Recently developed strategies to avoid/reduce helper contamination were reviewed. Gene Therapy (2005) 12, S18-S27.
A major limitation for adenoviral transduction in vivo is the profound liver tropism of adenovirus type 5 (Ad5). Recently, we demonstrated that coagulation factor X (FX) binds to Ad5-hexon protein at high affinity to mediate hepatocyte transduction after intravascular delivery. We developed novel genetically FX-binding ablated Ad5 vectors with lower liver transduction. Here, we demonstrate that FX-binding ablated Ad5 predominantly localize to the liver and spleen 1 hour after injection; however, they had highly reduced liver transduction in both control and macrophagedepleted mice compared with Ad5. At high doses in macrophage-depleted mice, FX-binding ablated vectors transduced the spleen more efficiently than Ad5. Immunohistochemical studies demonstrated transgene colocalization with CD11c ؉ , ER-TR7 ؉ , and MAdCAM-1 ؉ cells in the splenic marginal zone. Systemic inflammatory profiles were broadly similar between FX-binding ablated Ad5 and Ad5 at low and intermediate doses, although higher levels of several inflammatory proteins were observed at the highest dose of FX-binding ablated Ad5. Subsequently, we generated a FX-binding ablated virus containing a high affinity Ad35 fiber that mediated a significant improvement in lung/liver ratio in macrophage-depleted CD46 ؉ mice compared with controls. Therefore, this study documents the biodistribution and reports the retargeting capacity of IntroductionOf the 54 different adenoviral serotypes isolated to date, adenovirus serotype 5 (Ad5) has been the most commonly used vector in gene therapy clinical trials. This is, in part, due to clear advantages over alternate strategies including the relatively easy manipulation of its viral genome and feasible scale-up production to high titers (up to 10 13 viral particles (vp)/mL). Nevertheless, Ad5 presents 2 substantial limitations that have required attention to optimize the use of Ad5 in gene therapy. These include the observation that the majority of the human population has pre-existing neutralizing antibodies against Ad5 1-3 and the profound liver tropism observed for Ad5 after intravascular delivery. 4,5 For this reason, fundamental aspects of Ad5 biology need to be further studied to provide safer and target-specific Ad5 gene therapy vectors. The mechanism of Ad5-mediated gene transfer has now been relatively well characterized. In vitro studies have shown that Ad5 and those Ads from subspecies A, C, D, E, and F may use the coxsackievirus and Ad receptor (CAR) as a primary binding receptor. [6][7][8][9] This interaction occurs via the fiber knob domain with subsequent interaction of the Ad5 penton base with cellular integrins (␣v3 and ␣v5), mediating capsid internalization. 10,11 Although CAR and integrin-binding ablated mutant Ad vectors show a substantial reduction in transduction in vitro, these vectors still predominantly transduce hepatocytes in vivo after intravascular administration. 12,13 Injection of Ad5 into the bloodstream leads to a complex series of interactions that impact on the resulting biodistri...
Achieving high efficiency, targeted gene delivery with adenoviral vectors is a long-standing goal in the field of clinical gene therapy. To achieve this, platform vectors must combine efficient retargeting strategies with detargeting modifications to ablate native receptor binding (i.e. CAR/integrins/heparan sulfate proteoglycans) and “bridging” interactions. “Bridging” interactions refer to coagulation factor binding, namely coagulation factor X (FX), which bridges hepatocyte transduction in vivo through engagement with surface expressed heparan sulfate proteoglycans (HSPGs). These interactions can contribute to the off-target sequestration of Ad5 in the liver and its characteristic dose-limiting hepatotoxicity, thereby significantly limiting the in vivo targeting efficiency and clinical potential of Ad5-based therapeutics. To date, various approaches to retargeting adenoviruses (Ad) have been described. These include genetic modification strategies to incorporate peptide ligands (within fiber knob domain, fiber shaft, penton base, pIX or hexon), pseudotyping of capsid proteins to include whole fiber substitutions or fiber knob chimeras, pseudotyping with non-human Ad species or with capsid proteins derived from other viral families, hexon hypervariable region (HVR) substitutions and adapter-based conjugation/crosslinking of scFv, growth factors or monoclonal antibodies directed against surface-expressed target antigens. In order to maximize retargeting, strategies which permit detargeting from undesirable interactions between the Ad capsid and components of the circulatory system (e.g. coagulation factors, erythrocytes, pre-existing neutralizing antibodies), can be employed simultaneously. Detargeting can be achieved by genetic ablation of native receptor-binding determinants, ablation of “bridging interactions” such as those which occur between the hexon of Ad5 and coagulation factor X (FX), or alternatively, through the use of polymer-coated “stealth” vectors which avoid these interactions. Simultaneous retargeting and detargeting can be achieved by combining multiple genetic and/or chemical modifications.
Adenovirus is one of the most complex icosahedral, nonenveloped viruses. Even after its structure was solved at near-atomic resolution by both cryo-electron microscopy and X-ray crystallography, the location of minor coat proteins is still a subject of debate. The elaborated capsid architecture is the product of a correspondingly complex assembly process, about which many aspects remain unknown. Genome encapsidation involves the concerted action of five virus proteins, and proteolytic processing by the virus protease is needed to prime the virion for sequential uncoating. Protein L1 52/55k is required for packaging, and multiple cleavages by the maturation protease facilitate its release from the nascent virion. Light-density particles are routinely produced in adenovirus infections and are thought to represent assembly intermediates. Here, we present the molecular and structural characterization of two different types of human adenovirus light particles produced by a mutant with delayed packaging. We show that these particles lack core polypeptide V but do not lack the density corresponding to this protein in the X-ray structure, thereby adding support to the adenovirus cryo-electron microscopy model. The two types of light particles present different degrees of proteolytic processing. Their structures provide the first glimpse of the organization of L1 52/55k protein inside the capsid shell and of how this organization changes upon partial maturation. Immature, full-length L1 52/55k is poised beneath the vertices to engage the virus genome. Upon proteolytic processing, L1 52/55k disengages from the capsid shell, facilitating genome release during uncoating. IMPORTANCEAdenoviruses have been extensively characterized as experimental systems in molecular biology, as human pathogens, and as therapeutic vectors. However, a clear picture of many aspects of their basic biology is still lacking. Two of these aspects are the location of minor coat proteins in the capsid and the molecular details of capsid assembly. Here, we provide evidence supporting one of the two current models for capsid architecture. We also show for the first time the location of the packaging protein L1 52/55k in particles lacking the virus genome and how this location changes during maturation. Our results contribute to clarifying standing questions in adenovirus capsid architecture and provide new details on the role of L1 52/55k protein in assembly.A denoviruses (AdVs) (1) are among the most complex nonenveloped, icosahedral viruses. The AdV capsid is an icosahedron with a ϳ950-Å maximum diameter and triangulation number pseudo-Tϭ25. Each capsid facet has 12 trimers of the major coat protein, hexon. A pentamer of penton base protein sits at each vertex, in complex with a trimer of the projecting fiber. In addition, correct assembly requires four different minor coat proteins: IIIa, VI, VIII, and IX (2). The icosahedral shell encloses a nonicosahedral core with a linear, double-stranded DNA (dsDNA) genome (35 kbp in human AdV type 5 [H...
Endovenously administered oncolytic viruses extravasate and penetrate poorly into tumors. iRGD is a cyclic peptide that enhances tumor penetration when conjugated or coadministered with different types of molecules such as drugs, nanoparticles or phages. iRGD-mediated tumor penetration occurs in three steps: binding to αv-integrins on tumor vasculature or tumor cells, exposure by proteolysis of a C-terminal motif that binds to neuropilin-1 (NRP-1) and cell internalization. We have genetically inserted the iRGD peptide in the fiber C terminus of ICOVIR15K, an oncolytic tumor-retargeted adenovirus to increase its tumor penetration. In vitro, NRP-1 interaction improved binding and internalization of the virus in different cancer cells overexpressing integrins and NRP-1. However, such NRP-1-mediated internalization did not affect transduction or cytotoxicity. In vivo, iRGD did not change the normal organ transduction pattern, with liver and spleen as main targeted organs. In tumors, however, iRGD enhanced transduction and early adenovirus dissemination through the tumor mass leading to an improved antitumor efficacy.
Current strategies to amplify helper-dependent adenovirus, based on excision of the packaging signal, do not routinely reduce helper adenovirus contamination below 1%. Here, we have tested if reducing the efficiency of the packaging process of the helper adenovirus could impair its packaging without affecting helper-dependent adenovirus production. Interestingly, insertion of attB/attP-PhiC31 sequences flanking the packaging signal significantly lengthens adenovirus cycle up to 60 h without reducing virus viability or production yield. This delay occurs in the absence of PhiC31 recombinase indicating that other mechanisms different from excision of packaging signal must be involved. In addition, at 36 h post-coinfection helper-dependent adenovirus are efficiently produced, while production levels of helper attB/attP-modified adenovirus are 100-1000 times lower than controls. Therefore, these results suggest that attB/attP-mediated packaging impairment of the adenovirus genome is an attractive strategy to significantly reduce helper adenovirus contamination in helper-dependent adenovirus preparations, which in turn would facilitate scaling-up processes for clinical grade preparations.
Serotonin is produced by pulmonary arterial endothelial cells (PAEC) via tryptophan hydroxylase-1 (Tph1). Pathologically, serotonin acts on underlying pulmonary arterial cells, contributing to vascular remodeling associated with pulmonary arterial hypertension (PAH). The effects of hypoxia on PAEC-Tph1 activity are unknown. We investigated the potential of a gene therapy approach to PAH using selective inhibition of PAEC-Tph1 in vivo in a hypoxic model of PAH. We exposed cultured bovine pulmonary arterial smooth muscle cells (bPASMCs) to conditioned media from human PAECs (hPAECs) before and after hypoxic exposure. Serotonin levels were increased in hypoxic PAEC media. Conditioned media evoked bPASMC proliferation, which was greater with hypoxic PAEC media, via a serotonin-dependent mechanism. In vivo, adenoviral vectors targeted to PAECs (utilizing bispecific antibody to angiotensin-converting enzyme (ACE) as the selective targeting system) were used to deliver small hairpin Tph1 RNA sequences in rats. Hypoxic rats developed PAH and increased lung Tph1. PAEC-Tph1 expression and development of PAH were attenuated by our PAEC-Tph1 gene knockdown strategy. These results demonstrate that hypoxia induces Tph1 activity and selective knockdown of PAEC-Tph1 attenuates hypoxia-induced PAH in rats. Further investigation of pulmonary endothelial-specific Tph1 inhibition via gene interventions is warranted.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
hi@scite.ai
334 Leonard St
Brooklyn, NY 11211
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
