Human Immunodeficiency Virus Type 1 Nef Protein Targets CD4 to the Multivesicular Body Pathway

The Nef protein of human immunodeficiency virus type 1 downregulates the CD4 coreceptor from the surface of host cells by accelerating the rate of CD4 endocytosis through a clathrin/AP-2 pathway. Herein, we report that Nef has the additional function of targeting CD4 to the multivesicular body (MVB) pathway for eventual delivery to lysosomes. This targeting involves the endosomal sorting complex required for transport (ESCRT) machinery. Perturbation of this machinery does not prevent removal of CD4 from the cell surface but precludes its lysosomal degradation, indicating that accelerated endocytosis and targeting to the MVB pathway are separate functions of Nef. We also show that both CD4 and Nef are ubiquitinated on lysine residues, but this modification is dispensable for Nef-induced targeting of CD4 to the MVB pathway.Primate immunodeficiency viruses infect helper T lymphocytes and cells of the macrophage/monocyte lineage by binding of their viral envelope glycoprotein, Env, to a combination of two host cell-specific surface proteins, CD4 and either the CCR5 or CXCR4 chemokine receptors (reviewed in reference 62). Ensuing fusion of the viral envelope with the host cell plasma membrane delivers the viral genetic material into the cytoplasm. Remarkably, the most highly transcribed viral gene in the early phase of infection does not encode an enzyme or structural protein but an accessory protein named Nef. Early expression of Nef is thought to reprogram the host cell for optimal replication of the virus. Indeed, Nef has been shown to enhance virus production (19, 24, 59, 74) and to promote progression to AIDS (23, 47, 48), making it an attractive candidate for pharmacologic intervention.Nef is an N-terminally myristoylated protein with a molecular mass of 27 kDa for human immunodeficiency virus type 1 (HIV-1) and 35 kDa for HIV-2 and simian immunodeficiency virus (27, 29, 50, 65). Nef has been ascribed many functions, the best characterized of which is the downregulation of the CD4 coreceptor from the surface of infected cells (28, 35, 57). CD4 downregulation is believed to prevent superinfection (8, 52) and to preclude the cellular retention of newly synthesized Env (8, 49), thus allowing the establishment of a robust infection (30, 71).The molecular mechanism by which Nef downregulates CD4 has been extensively studied. A consensus has emerged that Nef accelerates the endocytosis of cell surface CD4 (2, 64) by linking the cytosolic tail of CD4 to the heterotetrameric (α-β2-μ2-σ2) adaptor protein-2 (AP-2) complex (17, 25, 34, 45, 67). Determinants in the CD4 tail bind to a hydrophobic pocket comprising tryptophan-57 and leucine-58 on the folded core domain of Nef (34). On the other hand, a dileucine motif (i.e., ENTSLL, residues 160 to 165) (14, 22, 32) and a diacidic motif (i.e., DD, residues 174 and 175) (3) (residues correspond to the NL4-3 clone of HIV-1) within a C-terminal, flexible loop of Nef bind to the α and σ2 subunits of AP-2 (17, 18, 25, 51). AP-2, in turn, binds to clathrin, leading to the concentration of CD4 within clathrin-coated pits (15, 33). These pits eventually bud from the plasma membrane as clathrin-coated vesicles that deliver internalized CD4 to endosomes. In essence, then, Nef acts as a connector that confers on CD4 the ability to be rapidly internalized in a manner similar to endocytic receptors (75).Unlike typical endocytic recycling receptors like the transferrin receptor or the low-density lipoprotein receptor, however, CD4 that is forcibly internalized by Nef does not return to the cell surface but is delivered to lysosomes for degradation (4, 64, 68). Thus, expression of Nef decreases both the surface and total levels of CD4. What keeps internalized CD4 from returning to the plasma membrane? We hypothesized that Nef might additionally act on endosomes to direct CD4 to lysosomes. This is precisely the fate followed by signaling receptors, transporters, and other transmembrane proteins that undergo ubiquitination-mediated internalization and targeting to the multivesicular body (MVB) pathway (40, 46). This targeting involves the endosomal sorting complex required for transport (ESCRT), including the ESCRT-0, -I, -II, and -III complexes, which function to sort ubiquitinated cargoes into intraluminal vesicles of MVBs for eventual degradation in lysosomes (40, 46). Herein, we show that Nef indeed plays a novel role in targeting internalized CD4 from endosomes to the MVB pathway in an ESCRT-dependent manner. We also show that both Nef and CD4 undergo ubiquitination on lysine residues, but, strikingly, this modification is not required for CD4 targeting to the MVB pathway.     

Analysis of Human Immunodeficiency Virus Type 1 Viremia and Provirus in Resting CD4+ T Cells Reveals a Novel Source of Residual Viremia in Patients on Antiretroviral Therapy

Highly active antiretroviral therapy (HAART) can reduce human immunodeficiency virus type 1 (HIV-1) viremia to clinically undetectable levels. Despite this dramatic reduction, some virus is present in the blood. In addition, a long-lived latent reservoir for HIV-1 exists in resting memory CD4⁺ T cells. This reservoir is believed to be a source of the residual viremia and is the focus of eradication efforts. Here, we use two measures of population structure—analysis of molecular variance and the Slatkin-Maddison test—to demonstrate that the residual viremia is genetically distinct from proviruses in resting CD4⁺ T cells but that proviruses in resting and activated CD4⁺ T cells belong to a single population. Residual viremia is genetically distinct from proviruses in activated CD4⁺ T cells, monocytes, and unfractionated peripheral blood mononuclear cells. The finding that some of the residual viremia in patients on HAART stems from an unidentified cellular source other than CD4⁺ T cells has implications for eradication efforts.Successful treatment of human immunodeficiency virus type 1 (HIV-1) infection with highly active antiretroviral therapy (HAART) reduces free virus in the blood to levels undetectable by the most sensitive clinical assays (18, 36). However, HIV-1 persists as a latent provirus in resting, memory CD4⁺ T lymphocytes (6, 9, 12, 16, 48) and perhaps in other cell types (45, 52). The latent reservoir in resting CD4⁺ T cells represents a barrier to eradication because of its long half-life (15, 37, 40-42) and because specifically targeting and purging this reservoir is inherently difficult (8, 25, 27).In addition to the latent reservoir in resting CD4⁺ T cells, patients on HAART also have a low amount of free virus in the plasma, typically at levels below the limit of detection of current clinical assays (13, 19, 35, 37). Because free virus has a short half-life (20, 47), residual viremia is indicative of active virus production. The continued presence of free virus in the plasma of patients on HAART indicates either ongoing replication (10, 13, 17, 19), release of virus after reactivation of latently infected CD4⁺ T cells (22, 24, 31, 50), release from other cellular reservoirs (7, 45, 52), or some combination of these mechanisms. Finding the cellular source of residual viremia is important because it will identify the cells that are still capable of producing virus in patients on HAART, cells that must be targeted in any eradication effort.Detailed analysis of this residual viremia has been hindered by technical challenges involved in working with very low concentrations of virus (13, 19, 35). Recently, new insights into the nature of residual viremia have been obtained through intensive patient sampling and enhanced ultrasensitive sequencing methods (1). In a subset of patients, most of the residual viremia consisted of a small number of viral clones (1, 46) produced by a cell type severely underrepresented in the peripheral circulation (1). These unique viral clones, termed predominant plasma clones (PPCs), persist unchanged for extended periods of time (1). The persistence of PPCs indicates that in some patients there may be another major cellular source of residual viremia (1). However, PPCs were observed in a small group of patients who started HAART with very low CD4 counts, and it has been unclear whether the PPC phenomenon extends beyond this group of patients. More importantly, it has been unclear whether the residual viremia generally consists of distinct virus populations produced by different cell types.Since the HIV-1 infection in most patients is initially established by a single viral clone (23, 51), with subsequent diversification (29), the presence of genetically distinct populations of virus in a single individual can reflect entry of viruses into compartments where replication occurs with limited subsequent intercompartmental mixing (32). Sophisticated genetic tests can detect such population structure in a sample of viral sequences (4, 39, 49). Using two complementary tests of population structure (14, 43), we analyzed viral sequences from multiple sources within individual patients in order to determine whether a source other than circulating resting CD4⁺ T cells contributes to residual viremia and viral persistence. Our results have important clinical implications for understanding HIV-1 persistence and treatment failure and for improving eradication strategies, which are currently focusing only on the latent CD4⁺ T-cell reservoir.     

Effect of Preexisting Immunity on Oncolytic Adenovirus Vector INGN 007 Antitumor Efficacy in Immunocompetent and Immunosuppressed Syrian Hamsters

Immune responses against adenovirus (Ad) vectors pose a possible concern for the outcome of treatment efficacy. To address the role of preexisting immunity in oncolytic Ad vector antitumor efficacy following intratumoral injection of vector as well as tumor-to-tissue spread of the vector, we employed the Syrian hamster model. These animals are immunocompetent, and their tumors and tissues are permissive for replication of Ad type 5 (Ad5). We used the adenovirus death protein-overexpressing Ad5-based vector INGN 007. Subcutaneous tumors were established in groups of hamsters that were or were not immunized with Ad5. Half of the hamsters in these groups were immunosuppressed with cyclophosphamide. For all groups, tumors injected with INGN 007 grew significantly more slowly than those injected with buffer. Under immunocompetent conditions, there was no significant effect of preexisting immunity on vector antitumor efficacy. Soon after the tumors in naïve animals were injected with vector, the hamsters developed neutralizing antibody (NAb) and the difference in NAb titers between the naïve and immunized groups diminished. Under immunosuppressed conditions, preexisting NAb did significantly reduce vector efficacy. Thus, NAb do reduce vector efficacy to some extent, but immunosuppression is required to observe the effect. Regarding vector toxicity, there was spillover of vector from the tumor to the liver and lungs in naïve immunocompetent hamsters, and this was nearly eliminated in the immunized hamsters. Thus, preexisting immunity to Ad5 does not affect INGN 007 antitumor efficacy following intratumoral injection, but immunity prevents vector spillover from the tumor to the liver and lungs.Oncolytic (replication-competent) viral vectors are being investigated as a treatment for cancer (2, 19, 25, 27). Recently, an oncolytic adenovirus serotype 5 (Ad5)-based vector was approved for cancer therapy in humans for the first time (14, 42). Oncolytic vectors based on Ad, reovirus, herpes simplex virus type 1 (HSV-1), poxvirus, poliovirus, Newcastle disease virus, measles virus, and vesicular stomatitis virus (VSV) are being studied extensively in both preclinical and clinical settings (16, 20, 24). Oncolytic Ad vectors are popular due to the Ad safety profile and ease of manipulation and handling (6, 13, 18, 23).Oncolytic Ad vectors infect and kill cancer cells as a result of the normal Ad life cycle by replicating in cells and releasing progeny viruses. These vectors rely on replication and spread through the tumor to achieve efficacy. A majority of the human population is seropositive for Ad5, which is acquired as a childhood infection (4, 15, 39). Elimination of the vector by preexisting immunity to Ad or vector elimination by the adaptive immune response generated after administration of the vector poses a possible concern with respect to achieving significant antitumor efficacy. A key question is whether the oncolytic Ad vector can efficiently eliminate tumor cells faster than its own clearance by the immune system. Several studies show that suppressing the immune system enhances the efficacy of oncolytic vectors (10, 12, 31).Alternatively, studies show that activation of the adaptive immune system by the vector might increase tumor cell killing, thereby increasing vector antitumor efficacy (11, 21, 27, 34). Studies with oncolytic HSV and VSV show that these vectors induce long-term antitumor immunity (11, 21, 27, 34). Therefore, apart from direct cell lysis, oncolytic vectors may be able to achieve antitumor efficacy by activating the antitumor immune response. Therefore, induced or preexisting immunity to the vector can be either a hurdle or beneficial for vector efficacy.Most efforts to address the effect of preexisting immunity were performed by gene transfer studies with replication-defective Ad vectors (28, 41). These studies showed that preexisting immunity significantly reduces gene transfer and expression in the target organ. In contrast, other studies showed that preexisting immunity does not prevent gene transfer (26) and does not affect vector antitumor efficacy (1). Little work has been done to address the role of induced or preexisting immunity on the efficacy and toxicity of oncolytic Ad vectors (3, 39). Studies with these vectors have been difficult because of a lack of immunocompetent and permissive animal models. Ad replication is generally species specific, and human Ads replicate poorly in cells from most nonhuman species. Consequently, Ad vectors are commonly evaluated in immunodeficient mice bearing human tumor xenografts. However, this model cannot adequately address the effect of the host immune system on the vector-infected tumor or the toxicity of the vector in normal tissues.We recently developed a novel Syrian hamster model for the study of oncolytic Ad5-based vectors (30). These animals are both replication permissive for Ad5 and immunocompetent. In the present study, we modeled the effect of preexisting immunity to Ad5 on the efficacy of an oncolytic Ad vector, INGN 007, and the spillover of the vector from the site of injection to the liver and lungs.     

Improved Adenovirus Type 5 Vector-Mediated Transduction of Resistant Cells by Piggybacking on Coxsackie B-Adenovirus Receptor-Pseudotyped Baculovirus

Taking advantage of the wide tropism of baculoviruses (BVs), we constructed a recombinant BV (BV^CAR) pseudotyped with human coxsackie B-adenovirus receptor (CAR), the high-affinity attachment receptor for adenovirus type 5 (Ad5), and used the strategy of piggybacking Ad5-green fluorescent protein (Ad5GFP) vector on BV^CAR to transduce various cells refractory to Ad5 infection. We found that transduction of all cells tested, including human primary cells and cancer cell lines, was significantly improved using the BV^CAR-Ad5GFP biviral complex compared to that obtained with Ad5GFP or BV^CARGFP alone. We determined the optimal conditions for the formation of the complex and found that a high level of BV^CAR-Ad5GFP-mediated transduction occurred at relatively low adenovirus vector doses, compared with transduction by Ad5GFP alone. The increase in transduction was dependent on the direct coupling of BV^CAR to Ad5GFP via CAR-fiber knob interaction, and the cell attachment of the BV^CAR-Ad5GFP complex was mediated by the baculoviral envelope glycoprotein gp64. Analysis of the virus-cell binding reaction indicated that the presence of BV^CAR in the complex provided kinetic benefits to Ad5GFP compared to the effects with Ad5GFP alone. The endocytic pathway of BV^CAR-Ad5GFP did not require Ad5 penton base RGD-integrin interaction. Biodistribution of BV^CAR-Ad5Luc complex in vivo was studied by intravenous administration to nude BALB/c mice and compared to Ad5Luc injected alone. No significant difference in viscerotropism was found between the two inocula, and the liver remained the preferred localization. In vitro, coagulation factor X drastically increased the Ad5GFP-mediated transduction of CAR-negative cells but had no effect on the efficiency of transduction by the BV^CAR-Ad5GFP complex. Various situations in vitro or ex vivo in which our BV^CAR-Ad5 duo could be advantageously used as gene transfer biviral vector are discussed.Adenoviruses (Ads) are extensively used today as gene transfer vectors for in vitro, ex vivo, and in vivo gene transfer protocols (reviewed in reference 65). Cell entry of human Ad type 5 (Ad5), the serotype most widely used as a gene vector, occurs most efficiently by the receptor-mediated endocytosis pathway (reviewed in references 64 and 65), via the coxsackievirus B-adenovirus receptor (CAR) (3, 77) and αvβ3/αvβ5 integrins (84, 85), although alternative receptors have been described (11, 12, 14, 27). Cell surface expression of CAR differs with different cell types, and this represents one of the major determinants of the efficiency of Ad5-mediated transduction (43). The ubiquitous nature of CAR is responsible for transduction of nontarget tissues by Ad vectors. Paradoxically, many target cells such as dermal fibroblasts, synoviocytes, mesenchymal stem cells (MSCs), peripheral blood mononuclear cells (PBMCs), and dendritic cells (DCs), express no or very low levels of CAR at their surface and are relatively resistant to Ad transduction (14, 15, 19). Much work has been done with different strategies to promote the entry of Ad5 into CAR-defective cells. These strategies include (i) the genetic modification of Ad capsid proteins to carry cell ligands (2, 15, 20, 28, 49, 50), (ii) pseudotyping Ad5 vectors with fibers from other serotypes (13, 57, 74, 86), (iii) using bispecific adapters or peptides (25, 40), (iv) chemical modification of Ad (9, 42), and (v) tethering on nanoparticles (7). The limitations to these strategies are that modifications of the Ad capsid are susceptible to negatively affecting the virus growth or viability, due to an alteration of virion assembly, stability, the viral uncoating process, and/or intracellular trafficking (13, 51).Other viruses which are gaining popularity as gene transfer vectors are the baculoviruses (BVs). Autographa californica multiple nucleopolyhedrosis virus (AcMNPV) is an insect virus with a large double-stranded DNA genome packaged in a membrane-enveloped, rod-shaped protein capsid (70). Since the 1980s, the BV-insect cell expression system has been highly exploited for the production of recombinant proteins. In the mid-1990s, it was shown that recombinant BVs carrying reporter genes under cytomegalovirus (CMV) or retroviral Rous sarcoma virus promoter efficiently expressed reporter genes in mammalian cells (6, 22, 38, 41, 44, 69), as well as in avian cells (72) and fish cells (45). Since then, BVs have been reported to transduce numerous cells originating from species as various as humans, bovines, and fish (8, 32, 41, 73). As gene transfer vectors, BVs have been found to be rapidly inactivated by human serum complement (23), but exposing decay-accelerating factor (DAF) at the surface of BV by fusion with the baculoviral envelope glycoprotein can overcome this inactivation (33). BVs also have a good biosafety profile due to their incapacity to replicate in mammalian cells (31).Taking advantage of the ability of BVs to transduce a large repertoire of cells of invertebrate and vertebrate origins, including human primary cells, we investigated whether a recombinant AcMNPV could act as a carrier or macroadapter for Ad5 vectors to enter Ad5-refractory cells. To this aim, we pseudotyped AcMNPV virions with the high-affinity receptor for Ad5, the human CAR glycoprotein (BV^CAR), to enable the formation of complexes between vector particles of BV^CAR and Ad5-green fluorescent protein (Ad5GFP) mediated by Ad5 fiber and CAR interaction. We found that transduction of cell lines which were poorly permissive to Ad5, including human cancer cells and primary cells, was significantly improved using this strategy of piggybacking Ad5 vector on BV^CAR. More importantly, the increase in BV^CAR-Ad5-mediated transduction was obtained with a low range of Ad5 inputs, i.e., at multiplicities of infection (MOI) of less than 50 Ad5 vector particles per cell. We also found that the cell transduction enhancement observed with BV^CAR-Ad5 required the direct coupling of Ad5 to BV^CAR via fiber-CAR binding and that the cell attachment of the complex was mediated by the baculoviral envelope glycoprotein gp64. Kinetic analysis of virus-cell binding showed that the presence of BV^CAR in the complex was beneficial to Ad5 vector, not only in terms of tropism but also in terms of number of cell-bound virions and rate of cell attachment. In addition, the endocytic pathway of BV^CAR-Ad5 did not require Ad5 penton base RGD-integrin interaction. When administered in vivo to nude BALB/c mice, BV^CAR-Ad5 complex showed the same biodistribution as that of control Ad5 vector injected alone. In vitro, transduction of CAR-negative cells by BV^CAR-Ad5 was insensitive to coagulation factor X (FX), in contrast to Ad5 vector alone.Our novel strategy of gene delivery using the BV^CAR-Ad5 duo could be advantageously applied to various situations in vitro or ex vivo, e.g., for transducing Ad5-refractory cells when Ad5 capsid modifications cannot be envisaged, when oncolytic Ads need to be delivered to tumors via nonpermissive cell carriers belonging to the immune system, or when the simultaneous delivery of two transgenes by two separate vectors might be beneficial in terms of timing and/or level of cellular expression of the transgene products.     

Effect of B-Cell Depletion on Viral Replication and Clinical Outcome of Simian Immunodeficiency Virus Infection in a Natural Host

Simian immunodeficiency virus (SIV)-infected African nonhuman primates do not progress to AIDS in spite of high and persistent viral loads (VLs). Some authors consider the high viral replication observed in chronic natural SIV infections to be due to lower anti-SIV antibody titers than those in rhesus macaques, suggesting a role of antibodies in controlling viral replication. We therefore investigated the impact of antibody responses on the outcome of acute and chronic SIVagm replication in African green monkeys (AGMs). Nine AGMs were infected with SIVagm.sab. Four AGMs were infused with 50 mg/kg of body weight anti-CD20 (rituximab; a gift from Genentech) every 21 days, starting from day −7 postinfection up to 184 days. The remaining AGMs were used as controls and received SIVagm only. Rituximab-treated AGMs were successfully depleted of CD20 cells in peripheral blood, lymph nodes (LNs), and intestine, as shown by the dynamics of CD20⁺ and CD79a⁺ cells. There was no significant difference in VLs between CD20-depleted AGMs and control monkeys: peak VLs ranged from 10⁷ to 10⁸ copies/ml; set-point values were 10⁴ to 10⁵ SIV RNA copies/ml. Levels of acute mucosal CD4⁺ T-cell depletion were similar for treated and nontreated animals. SIVagm seroconversion was delayed for the CD20-depleted AGMs compared to results for the controls. There was a significant difference in both the timing and magnitude of neutralizing antibody responses for CD20-depleted AGMs compared to results for controls. CD20 depletion significantly altered the histological structure of the germinal centers in the LNs and Peyer''s patches. Our results, although obtained with a limited number of animals, suggest that humoral immune responses play only a minor role in the control of SIV viral replication during acute and chronic SIV infection in natural hosts.In marked contrast to pathogenic human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) infections of humans and macaques, which are characterized by the constant progression to AIDS in a variable time frame (26), African monkey species naturally infected with SIV are generally spared from any signs of disease (reviewed in references 53 and 71).There are currently three animal models of SIV infection in natural hosts: SIVagm infection of African green monkeys (AGMs), SIVsmm infection of sooty mangabeys, and SIVmnd-1 and SIVmnd-2 infection of mandrills (53, 71). SIV infection in natural hosts is characterized by the following: (i) active viral replication, with set-point viral loads (VLs) similar to or even higher than those found in pathogenic infections (44-46, 49, 50, 52, 61-63); (ii) transient depletion of peripheral CD4⁺ T cells during primary infection, which rebound to preinfection levels during chronic infection (12, 30, 44-46, 49, 62); (iii) significant CD4⁺ T-cell depletion in the intestine, which can be partially restored during chronic infection in spite of significant viral replication (21, 48); (iv) low levels of CD4⁺ CCR5⁺ cells in blood and tissues (47); (v) transient and moderate increases in immune activation and T-cell proliferation during acute infection, with a return to baseline levels during the chronic phase (44-46, 49, 50, 52, 61-63), as a result of an anti-inflammatory milieu which is rapidly established after infection (14, 30); and (vi) no significant increase in CD4⁺ T-cell apoptosis during either acute or chronic infection (37, 48), thus avoiding enteropathy and microbial translocation, which control excessive immune activation and prevent disease progression by allowing CD4⁺ T-cell recovery in the presence of high VLs (21, 48). Hence, the current view is that the main reason behind the lack of disease progression in natural African hosts lies in a better adaptation of the host in response to the highly replicating virus. A better understanding of the mechanisms underlying the lack of disease in natural hosts for SIV infection may provide important clues for understanding the pathogenesis of HIV infection (53, 71).To date, it is still unknown whether or not immune responses are responsible for the lack of disease progression in natural hosts, since data are scarce. Studies of cellular immune responses are significantly more limited than is the case with pathogenic infection, and although not always in agreement (3, 13, 28, 29, 73, 76), their convergence point is that cellular immune responses are not essentially superior to those observed in pathogenic infections (3, 13, 28, 29, 73, 76). This observation is not surprising in the context of the high viral replication in natural hosts. Data are even scarcer on the role of humoral immune responses in the control of disease progression in natural hosts. However, several studies reported that anti-SIV antibody titers are lower in SIV infections of natural hosts, with a lack of anti-Gag responses being characteristic of natural SIV infections in African nonhuman primates (1, 6, 24, 25, 42, 43, 71). Because the viral replication in SIVagm-infected AGMs is of the same magnitude or higher than that in pathogenic infections of rhesus macaques (RMs), it has been hypothesized that these high VLs may be a consequence of the lower antibody titers. Moreover, a recent study has also shown that B cells in lymph nodes (LNs) of AGMs are activated at an earlier time point than is the case for SIVmac251-infected RMs, which implies that humoral immune responses may be important in controlling SIV replication in the natural hosts (9). Conversely, it has been shown that passively transferring immunoglobulins from animals naturally infected with SIVagm prior to infection with a low dose of SIVagm did not prevent infection in AGMs (42, 60), which is in striking contrast to results in studies of pathogenic infections, which convincingly demonstrated with animal models that intravenously administered or topically applied antibodies can protect macaques against intravenous or mucosal simian-human immunodeficiency virus challenge (34-36, 54, 72).Previous CD20⁺ B-cell-depletion studies during pathogenic RM infections have indicated that humoral immune responses may be important for controlling both the postpeak VL and disease progression (38, 57). However, these studies used strains that are highly resistant to neutralization (SIVmac251 and SIVmac239), making it difficult to assess the role that antibodies have in controlling SIV replication and disease progression. Moreover, our recent results suggested a limited impact of humoral immune responses in controlling replication of a neutralization-sensitive SIVsmm strain in rhesus macaques (18).To investigate the effect that CD20⁺ B cells and antibodies have on SIV replication in natural hosts, we have depleted CD20⁺ B cells in vivo in AGMs infected with SIVagm.sab92018. We assessed the impact of humoral immune responses on the control of viral replication and other immunological parameters, and we report that ablating humoral immune responses in SIVagm-infected AGMs does not significantly alter the course of virus replication or disease progression.     

Proliferation Capacity and Cytotoxic Activity Are Mediated by Functionally and Phenotypically Distinct Virus-Specific CD8 T Cells Defined by Interleukin-7Rα (CD127) and Perforin Expression

Cytotoxicity and proliferation capacity are key functions of antiviral CD8 T cells. In the present study, we investigated a series of markers to define these functions in virus-specific CD8 T cells. We provide evidence that there is a lack of coexpression of perforin and CD127 in human CD8 T cells. CD127 expression on virus-specific CD8 T cells correlated positively with proliferation capacity and negatively with perforin expression and cytotoxicity. Influenza virus-, cytomegalovirus-, and Epstein-Barr virus/human immunodeficiency virus type 1-specific CD8 T cells were predominantly composed of CD127⁺ perforin⁻/CD127⁻ perforin⁺, and CD127⁻/perforin⁻ CD8 T cells, respectively. CD127⁻/perforin⁻ and CD127⁻/perforin⁺ cells expressed significantly more PD-1 and CD57, respectively. Consistently, intracellular cytokine (gamma interferon, tumor necrosis factor alpha, and interleukin-2 [IL-2]) responses combined to perforin detection confirmed that virus-specific CD8 T cells were mostly composed of either perforin⁺/IL-2⁻ or perforin⁻/IL-2⁺ cells. In addition, perforin expression and IL-2 secretion were negatively correlated in virus-specific CD8 T cells (P < 0.01). As previously shown for perforin, changes in antigen exposure modulated also CD127 expression. Based on the above results, proliferating (CD127⁺/IL-2-secreting) and cytotoxic (perforin⁺) CD8 T cells were contained within phenotypically distinct T-cell populations at different stages of activation or differentiation and showed different levels of exhaustion and senescence. Furthermore, the composition of proliferating and cytotoxic CD8 T cells for a given antiviral CD8 T-cell population appeared to be influenced by antigen exposure. These results advance our understanding of the relationship between cytotoxicity, proliferation capacity, the levels of senescence and exhaustion, and antigen exposure of antiviral memory CD8 T cells.Cytotoxic CD8 T cells are a fundamental component of the immune response against viral infections and mediate an important role in immunosurveillance (7, 10, 55), and the induction of vigorous CD8 T-cell responses after vaccination is thought to be a key component of protective immunity (37, 41, 49, 50, 58, 60, 69). Cytotoxic CD8 T cells exert their antiviral and antitumor activity primarily through the secretion of cytotoxic granules containing perforin (pore-forming protein) and several granule-associated proteases, including granzymes (Grms) (5, 15, 20, 44). Several studies have recently advanced the characterization of the mechanism of granule-dependent cytotoxic activity and performed a comprehensive investigation of the content of cytotoxic granules in human virus-specific CD8 T cells (2, 19, 29, 44, 53).Heterogeneous profiles of cytotoxic granules have been identified in different virus-specific memory CD8 T cells and associated with distinct differentiation stages of memory CD8 T cells (2, 19, 29, 44). Furthermore, we have observed a hierarchy among the cytotoxic granules in setting the efficiency of cytotoxic activity and demonstrated that perforin (and to a lesser extent GrmB) but not GrmA or GrmK were associated with cytotoxic activity (29). Recently, a novel mechanism of perforin-dependent granule-independent CTL cytotoxicity has also been demonstrated (45).Major advances in the characterization of antigen (Ag)-specific CD4 and CD8 T cells have been made recently and have aimed at identifying functional profiles that may correlate with protective CD8 T-cell responses (1, 3, 4, 12, 13, 24, 28, 36-38, 40, 41, 49, 50, 56-58, 60, 64, 68). In particular, the functional characterization of antigen-specific T cells was mainly performed on the basis of (i) the pattern of cytokines secreted (i.e., gamma interferon [IFN-γ], tumor necrosis factor alpha [TNF-α], interleukin-2 [IL-2], or macrophage inflammatory protein 1β [MIP-1β]), (ii) the proliferation capacity, and (iii) the cytotoxic capacity (13, 28, 59). Of note, degranulation activity (i.e., CD107a mobilization following specific stimulation) has been used as a surrogate marker of cytotoxic activity (11, 13).The term “polyfunctional” has been used to define T-cell immune responses that, in addition to typical effector functions such as secretion of IFN-γ, TNF-α, or MIP-1β and cytotoxic activity (measured by the degranulation capacity), comprise distinct T-cell populations able to secrete IL-2 and retain proliferation capacity (13, 28, 49, 50). Some evidence indicates that a hallmark of protective immune responses is the presence of polyfunctional T-cell responses (59). Furthermore, the ability to secrete IL-2 was shown to be linked to proliferation capacity, and both factors have been associated with protective antiviral immunity (13, 28, 49, 50). Although a lack of correlation between degranulation activity and GrmB expression was reported in mice (65), the relationship between degranulation activity and perforin expression has never been comprehensively investigated in mice and in humans.The private α chain of the IL-7 receptor (IL-7Rα, also called CD127) has been suggested to selectively identify CD8 T cells that will become long-lived memory cells (6, 34, 36). Moreover, it was shown in mice (34, 36) and humans (14, 48, 63) that the CD127^high memory-precursor CD8 T cells produced IL-2 in contrast to CD127^low effector CD8 T cells. Of interest, CD127 expression has also been shown to correlate with Ag-specific proliferation capacity in mice (34, 36). A similar correlation was observed in humans, although only for polyclonal stimulations (48). With the exception of studies performed in HIV-1 infection, where an association between CD127 expression and HIV-1 viremia has been shown (21, 22, 42, 48, 54), very limited information is available on the CD127 expression in human virus-specific CD8 T cells other that HIV-1.Although cytotoxic activity and proliferation capacity are key components of the antiviral cellular immune response, the relationship between these functions has been only investigated in nonprogressive HIV-1 infection (46), where these two functions were shown to be related. However, it still remains to be determined whether these functions are mediated by the same or by different T-cell populations.In the present study, we performed a comprehensive characterization of virus-specific CD8 T-cell responses against HIV-1, cytomegalovirus (CMV), Epstein Barr virus (EBV), and influenza virus (Flu) in order to (i) analyze the degree of concordance between degranulation activity and perforin/Grm expression; (ii) identify the relevance of CD127 in identifying virus-specific CD8 T cells endowed with proliferation capacity; (iii) delineate the relationship between proliferation capacity, cytotoxic activity, activation/differentiation stage, and level of exhaustion of CD8 T cells; and (iv) determine the influence of antigen exposure in shaping the functional composition of virus-specific CD8 T cells.Our data indicate that cytotoxic (as defined by perforin expression) and proliferating (as defined by CD127 expression or IL-2 secretion) virus-specific CD8 T cells are contained within distinct CD8 T-cell populations. Furthermore, the proportion of proliferating and cytotoxic T cells within a given virus-specific CD8 T-cell population appears to be influenced by antigen exposure. These results advance our understanding of the relationship between cytotoxicity, proliferative capacity, differentiation stage, and Ag exposure of memory CD8 T cells.     

CD4 T-Cell Help Programs a Change in CD8 T-Cell Function Enabling Effective Long-Term Control of Murine Gammaherpesvirus 68: Role of PD-1-PD-L1 Interactions

We previously showed that agonistic antibodies to CD40 could substitute for CD4 T-cell help and prevent reactivation of murine gammaherpesvirus 68 (MHV-68) in the lungs of major histocompatibility complex (MHC) class II^−/− (CII^−/−) mice, which are CD4 T cell deficient. Although CD8 T cells were required for this effect, no change in their activity was detected in vitro. A key question was whether anti-CD40 treatment (or CD4 T-cell help) changed the function of CD8 T cells or another cell type in vivo. To address this question, in the present study, we showed that adoptive transfer of CD8 T cells from virus-infected wild-type mice or anti-CD40-treated CII^−/− mice caused a significant reduction in lung viral titers, in contrast to those from control CII^−/− mice. Anti-CD40 treatment also greatly prolonged survival of infected CII^−/− mice. This confirms that costimulatory signals cause a change in CD8 T cells enabling them to maintain effective long-term control of MHV-68. We investigated the nature of this change and found that expression of the inhibitory receptor PD-1 was significantly increased on CD8 T cells in the lungs of MHV-68-infected CII^−/−, CD40^−/−, or CD80/86^−/− mice, compared with that in wild-type or CD28/CTLA4^−/− mice, correlating with the level of viral reactivation. Furthermore, blocking PD-1-PD-L1 interactions significantly reduced viral reactivation in CD4 T-cell-deficient mice. In contrast, the absence of another inhibitory receptor, NKG2A, had no effect. These data suggest that CD4 T-cell help programs a change in CD8 T-cell function mediated by altered PD-1 expression, which enables effective long-term control of MHV-68.Murine gammaherpesvirus 68 (MHV-68) is a naturally occurring rodent pathogen which is closely related to Epstein-Barr virus (EBV) and Kaposi''s sarcoma-associated herpesvirus (KSHV) (17, 64). Intranasal administration of MHV-68 to mice results in acute productive infection of lung epithelial cells and a latent infection in various cell types, including B lymphocytes, dendritic cells, epithelial cells, and macrophages (18, 19, 52, 53, 61, 65). The virus induces an inflammatory infiltrate in the lungs, lymph node enlargement, splenomegaly, and mononucleosis comprising increased numbers of activated CD8 T cells in the blood (53, 58). It has also been reported to induce lymphoproliferative disease/lymphoma in immunocompromised mice (30, 55, 60). Thus, the pathogenesis resembles that of EBV in humans, although structurally, the virus is more closely related to KSHV.Infectious MHV-68 is cleared from the lungs by a T-cell-dependent mechanism 10 to 15 days after infection (18, 53, 56). In wild-type mice, the lungs remain clear of replicating virus thereafter. Although CD4 T cells are not essential for primary clearance of replicating virus, they are required for effective long-term control (11). Thus, major histocompatibility complex (MHC) class II^−/− mice that lack CD4 T cells or mice rendered CD4 deficient by antibody treatment initially clear infectious virus from the lungs. However, infectious virus reactivates in the lungs 10 to 15 days later and gradually increases in titer (11, 43). The infected CD4-deficient mice eventually die, apparently from long-term lung damage due to continuing lytic viral replication (11). MHC class II^−/− mice do not produce antibody to T-dependent antigens (10). Cytotoxic T-lymphocyte (CTL) epitopes have been identified in open reading frame (ORF) 6 (p56, H-2D^b-restricted), and ORF 61 (p79, H-2K^b-restricted) gene products, which appear to encode early lytic-phase proteins (32, 49). The epitopes are presented during two distinct phases during MHV-68 infection, which changes the pattern of CTL dominance (32, 51). However, there is no significant difference in the numbers of CD8 T cells specific for each epitope in wild-type mice and CD4 T-cell-deficient mice (4, 50). In addition, CTL activity measured in vitro does not differ substantially in the lungs of wild-type mice or CD4 T-cell-deficient mice (4, 11, 50). Furthermore, postexposure vaccination with the p56 epitope failed to prevent viral reactivation in class II^−/− mice, despite dramatically expanding the number of CD8 T cells specific for the peptide (5). In contrast, vaccination of wild-type mice against these epitopes reduced lytic viral titers in the lung dramatically on subsequent challenge with MHV-68. B-cell-deficient mice clear MHV-68 with the kinetics of wild-type mice and do not show viral reactivation in the lungs (13, 61), suggesting that antibody is not essential for control of the virus. Depletion of CD4 T cells during the latent phase of infection in B-cell-deficient mice does not induce viral reactivation, whereas depletion of both CD4 and CD8 T-cell subsets provokes viral reactivation in the lungs (52). Short-term depletion of both CD4 and CD8 T-cell subsets during the latent phase of infection in wild-type mice does not lead to viral reactivation probably due to the presence of neutralizing antibody (11). Taken together, these results suggest that CD4 and CD8 T cells and B cells play overlapping roles in preventing or controlling reactivation of MHV-68 during the latent phase of infection. However, the B-cell- and CD8 T-cell-mediated control mechanisms do not develop in the absence of CD4 T cells.We, and others, have previously shown that the costimulatory molecule CD28 is not required for long-term control of MHV-68 (28, 29). However, interestingly, mice lacking both of the ligands for CD28, CD80 and CD86, show viral reactivation in the lung (21, 35). Our previously published data showed that agonistic antibodies to CD40 could substitute for CD4 T-cell function in the long-term control of MHV-68 (46). CD8 T-cell receptor-positive (TCR+) cells were required for this effect, while antibody production was not restored (45, 46). MHV-68-infected CD40L^−/− mice (7) and CD40^−/− mice (29) also showed viral reactivation in the lungs. However, no change in CD8 CTL activity was detected in in vitro assays following anti-CD40 treatment (46). A key question was whether anti-CD40 treatment (or CD4 T-cell help) caused a direct change in CD8 T-cell function or whether both CD8 T cells and an independent anti-CD40-sensitive step were required for viral control. To address this question, we used adoptive transfer of CD8 T cells from MHV-68-infected wild-type mice, anti-CD40-treated mice, or control MHC class II^−/− mice to MHV-68-infected class II^−/− recipients. We also investigated whether anti-CD40 treatment prolonged survival in addition to reducing lung viral titers. The heterodimeric molecule CD94/NKG2A has been implicated in negatively regulating the CD8 T-cell response to polyomavirus (38) and herpes simplex virus (HSV) (54), while the inhibitory receptor PD-1 (programmed death 1) has been implicated in T-cell exhaustion following infection with several other persistent viruses (2, 15, 20, 22, 26, 36, 39-41, 57, 67). In the present study, we investigated the effect of signaling via various costimulatory molecules on the expression of NKG2A and PD-1 and how these molecules influenced viral control.     

Cryo-Electron Microscopy Structure of Adenovirus Type 2 Temperature-Sensitive Mutant 1 Reveals Insight into the Cell Entry Defect

The structure of the adenovirus type 2 temperature-sensitive mutant 1 (Ad2ts1) was determined to a resolution of 10 Å by cryo-electron microscopy single-particle reconstruction. Ad2ts1 was prepared at a nonpermissive temperature and contains the precursor forms of the capsid proteins IIIa, VI, and VIII; the core proteins VII, X (mu), and terminal protein (TP); and the L1-52K protein. Cell entry studies have shown that although Ad2ts1 can bind the coxsackievirus and Ad receptor and undergo internalization via αv integrins, this mutant does not escape from the early endosome and is targeted for degradation. Comparison of the Ad2ts1 structure to that of mature Ad indicates that Ad2ts1 has a different core architecture. The Ad2ts1 core is closely associated with the icosahedral capsid, a connection which may be mediated by preproteins IIIa and VI. Density within hexon cavities is assigned to preprotein VI, and membrane disruption assays show that hexon shields the lytic activity of both the mature and precursor forms of protein VI. The internal surface of the penton base in Ad2ts1 appears to be anchored to the core by interactions with preprotein IIIa. Our structural analyses suggest that these connections to the core inhibit the release of the vertex proteins and lead to the cell entry defect of Ad2ts1.Cryo-electron microscopy (cryo-EM) studies of adenovirus (Ad) combined with atomic resolution structures of component proteins (hexon, penton base, fiber, and protease) have led to a detailed structural model for the mature Ad virion (31). While the Ad protein capsid is icosahedral, the core does not follow the overall symmetry of the particle, and thus the core is not well represented in cryo-EM structures (43). The core is composed of the 36-kb double-stranded DNA (dsDNA) genome complexed with four viral proteins (V, VII, mu, and terminal protein [TP]) and the virally encoded cysteine protease. The core of the mature virion may also contain a few copies of the L1-52K protein (7), a possible scaffolding protein that is present in higher copy numbers in assembling virions (18).The capsid contains the major capsid proteins, hexon, penton base, and fiber, together with four minor capsid proteins (IIIa, VI, VIII, and IX). Cryo-EM difference mapping analyses have led to revised assignments for the locations of the minor capsid proteins, with protein IX on the exterior and the other three proteins on the inner capsid surface (9, 38). A scanning transmission EM study indicated that four trimers of protein IX stabilize the group of nine hexons in the center of each facet (11). However, more recent cryo-EM studies indicated that only the N-terminal domain of protein IX forms these trimeric assemblies (37, 38), while the C-terminal domain, which has a long predicted α-helix with strong propensity for coiled coil formation, associates in helical bundles at the facet edges (38). Two cryo-EM studies support the assignment of the tetrameric helical bundle on the capsid exterior to the C-terminal domain of protein IX (10, 23). Curiously, 12 monomers of protein IX per facet assemble into four trimers with their N-terminal domains and three tetramers with their C-terminal domains.The internal location for protein IIIa below the penton base and surrounding peripentonal hexons was confirmed by a study of virions with N-terminally tagged protein IIIa (39). Although the locations for proteins VI and VIII have not been experimentally confirmed, these proteins are more than likely on the internal side of the capsid, as there is no remaining unassigned cryo-EM density on the exterior of the capsid. In addition, proteins VI and VIII are two of the viral proteins that are produced in precursor form and cleaved by the viral protease during maturation of the assembled virion (22). The protease is presumed to be packaged within the interior of the virion, and therefore the assignment of proteins VI and VIII to the interior of the capsid where they would be accessible to the protease is logical. Density within the internal cavity of all 240 hexon trimers in the Ad capsid has been assigned to protein VI on the basis of biochemical and temperature sensitivity studies (38, 51).Ad cell entry begins with attachment of the Ad fiber to either coxsackievirus and Ad receptor (3) or CD46 (12), which serve as the primary attachment receptors for Ad on most cell types (31). Internalization via clathrin-mediated endocytosis is triggered by association of the Ad penton base with αv integrins (49). Escape from the endosome is facilitated by the membrane lytic activity of protein VI, which is released from the virion in the low-pH environment of the early endosome (50). The stepwise dismantling of the Ad virion during cell entry has been described biochemically (15) but has not been fully characterized structurally. After endosomal escape, the partially uncoated Ad virion is transported along microtubules (44) to the nucleus, where the viral genome is inserted into the nucleus via a nuclear pore complex.Propagation of an Ad2 temperature-sensitive mutant (Ad2ts1) at nonpermissive temperatures (>39°C) results in the synthesis of virions that have an uncoating defect (28, 30, 46). Although these Ad2ts1 particles are capable of interacting with coxsackievirus and Ad receptor and undergoing internalization via association with αv integrins, they are unable to escape the early endosome and thus are targeted for degradation in lysosomes (13, 14). The Ad2ts1 genetic defect is a point mutation (P137L) in protease that is linked to a defect in packaging into the virion (33). In wild-type Ad virions, the protease is activated inside nascent virions by the viral DNA as well as an 11-amino-acid peptide from the C-terminal end of protein VI (22). The Ad protease mediates the maturational cleavage of six structural proteins, i.e., IIIa, VI, VII, VIII, mu, and TP, as well as the presumed scaffolding protein L1-52K (26, 47, 48). In Ad2ts1 particles these cleavages do not occur. The presence of the precursor forms of these proteins in Ad2ts1 is associated with greater capsid stability (42, 50).Here we present a cryo-EM structural study of the Ad2ts1 particle that provides insight into the cell entry defect of this temperature-sensitive mutant. Comparison of the Ad2ts1 structure with that of a mature Ad virion indicates that the major differences are in the interior of the virion.     

Adeno-Associated Virus Replication Induces a DNA Damage Response Coordinated by DNA-Dependent Protein Kinase

The parvovirus adeno-associated virus (AAV) contains a small single-stranded DNA genome with inverted terminal repeats that form hairpin structures. In order to propagate, AAV relies on the cellular replication machinery together with functions supplied by coinfecting helper viruses such as adenovirus (Ad). Here, we examined the host cell response to AAV replication in the context of Ad or Ad helper proteins. We show that AAV and Ad coinfection activates a DNA damage response (DDR) that is distinct from that seen during Ad or AAV infection alone. The DDR was also triggered when AAV replicated in the presence of minimal Ad helper proteins. We detected autophosphorylation of the kinases ataxia telangiectasia mutated (ATM) and DNA-dependent protein kinase catalytic subunit (DNA-PKcs) and signaling to downstream targets SMC1, Chk1, Chk2, H2AX, and XRCC4 and multiple sites on RPA32. The Mre11 complex was not required for activation of the DDR to AAV infection. Additionally, we found that DNA-PKcs was the primary mediator of damage signaling in response to AAV replication. Immunofluorescence revealed that some activated damage proteins were found in a pan-nuclear pattern (phosphorylated ATM, SMC1, and H2AX), while others such as DNA-PK components (DNA-PKcs, Ku70, and Ku86) and RPA32 accumulated at AAV replication centers. Although expression of the large viral Rep proteins contributed to some damage signaling, we observed that the full response required replication of the AAV genome. Our results demonstrate that AAV replication in the presence of Ad helper functions elicits a unique damage response controlled by DNA-PK.Replication of viral genomes produces a large amount of extrachromosomal DNA that may be recognized by the cellular DNA damage machinery. This is often accompanied by activation of DNA damage response (DDR) signaling pathways and recruitment of cellular repair proteins to sites of viral replication. Viruses therefore provide good model systems to study the recognition and response to DNA damage (reviewed in reference 48). The Mre11/Rad50/Nbs1 (MRN) complex functions as a sensor of chromosomal DNA double-strand breaks (DSBs) and is involved in activation of damage signaling (reviewed in reference 41). The MRN complex also localizes to DNA DSBs and is found at viral replication compartments during infection with a number of DNA viruses (6, 40, 47, 70, 75, 77, 87, 93). The phosphatidylinositol 3-kinase-like kinases (PIKKs) ataxia telangiectasia mutated (ATM), ATM and Rad3-related kinase (ATR), and the catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs) are involved in the signal transduction cascades activated by DNA damage (reviewed in references 43, 51, and 71). These kinases respond to distinct types of damage and regulate DSB repair during different phases of the cell cycle (5), either through nonhomologous end-joining (NHEJ) or homologous recombination pathways (reviewed in references 63, 81, and 86). The DNA-PK holoenzyme is composed of DNA-PKcs and two regulatory subunits, the Ku70 and Ku86 heterodimer. DNA-PK functions with XRCC4/DNA ligase IV to repair breaks during NHEJ, and works with Artemis to process DNA hairpin structures during VDJ recombination and during a subset of DNA DSB events (46, 50, 86). While the kinase activity of DNA-PKcs leads to phosphorylation of a large number of substrates in vitro as well as autophosphorylation of specific residues (reviewed in references 16 and 85), it is currently unclear how DNA-PKcs contributes to signaling in cells upon different types of damage.The adeno-associated virus (AAV) genome consists of a molecule of single-stranded DNA with inverted terminal repeats (ITRs) at both ends that form double-hairpin structures due to their palindromic sequences (reviewed in reference 52). The ITRs are important for replication and packaging of the viral genome and for integration into the host genome. Four viral Rep proteins (Rep78, Rep68, Rep52, and Rep40) are also required for replication and packaging of the AAV genome into virions assembled from the Cap proteins. Although the Rep and Cap genes are replaced in recombinant AAV vectors (rAAV) that retain only the ITRs flanking the gene of interest, these vectors can be replicated by providing Rep in trans (reviewed in reference 7). Productive AAV infection requires helper functions supplied by adenovirus (Ad) or other viruses such as herpes simplex virus (HSV) (reviewed in reference 27), together with components of the host cell DNA replication machinery (54, 55, 58). In the presence of helper viruses or minimal helper proteins from Ad or HSV, AAV replicates in the nucleus at centers where the viral DNA and Rep proteins accumulate (35, 76, 84, 89). Cellular and viral proteins involved in AAV replication, including replication protein A (RPA), Ad DNA-binding protein (DBP), and HSV ICP8, localize with Rep proteins at these viral centers (29, 33, 76).A number of published reports suggest associations between AAV and the cellular DNA damage machinery. For example, transduction by rAAV vectors is increased by genotoxic agents and DNA damaging treatments (1, 62, 91) although the mechanisms involved remain unclear. Additionally, the ATM kinase negatively regulates rAAV transduction (64, 92), and we have shown that the MRN complex poses a barrier to both rAAV transduction and wild-type AAV replication (11, 67). UV-inactivated AAV particles also appear to activate a DDR involving ATM and ATR kinases that perturbs cell cycle progression (39, 60, 88). It has been suggested that this response is provoked by the AAV ITRs (60) and that UV-treated particles mimic stalled replication forks in infected cells (39). In addition to AAV genome components, the viral Rep proteins have been observed to exhibit cytotoxicity and induce S-phase arrest (3, 65).The role of cellular repair proteins in AAV genome processing has also been explored by examining the molecular fate of rAAV vectors, which are converted into circular and concatemeric forms that persist episomally (18, 19, 66). Proteins shown to regulate circularization in cell culture include ATM and the MRN complex (14, 64), while in vivo experiments using mouse models have implicated ATM and DNA-PK in this process (14, 20, 72). Additionally, DNA-PKcs and Artemis have recently been shown to cleave the ITR hairpins of rAAV vectors in vivo in a tissue-dependent manner (36). Despite these studies, it is not clear how damage response factors function together and how they impact AAV transduction and replication in human cells.In this study we examined the cellular response to AAV replication in the context of Ad infection or helper proteins. We show that coinfection with AAV and Ad activates a DDR that is distinct from that seen during infection with Ad alone. The ATM and DNA-PKcs damage kinases are activated and signal to downstream substrates, but the response does not require the MRN complex and is primarily mediated by DNA-PKcs. Although expression of the large Rep proteins induced some DDR events, full signaling appeared to require AAV replication and was accompanied by accumulation of DNA-PK at viral replication compartments. Our results demonstrate that AAV replication induces a unique DNA damage signal transduction response and provides a model system for studying DNA-PK.     

Virus Entry via the Alternative Coreceptors CCR3 and FPRL1 Differs by Human Immunodeficiency Virus Type 1 Subtype

Human immunodeficiency virus type 1 (HIV-1) infects target cells by binding to CD4 and a chemokine receptor, most commonly CCR5. CXCR4 is a frequent alternative coreceptor (CoR) in subtype B and D HIV-1 infection, but the importance of many other alternative CoRs remains elusive. We have analyzed HIV-1 envelope (Env) proteins from 66 individuals infected with the major subtypes of HIV-1 to determine if virus entry into highly permissive NP-2 cell lines expressing most known alternative CoRs differed by HIV-1 subtype. We also performed linear regression analysis to determine if virus entry via the major CoR CCR5 correlated with use of any alternative CoR and if this correlation differed by subtype. Virus pseudotyped with subtype B Env showed robust entry via CCR3 that was highly correlated with CCR5 entry efficiency. By contrast, viruses pseudotyped with subtype A and C Env proteins were able to use the recently described alternative CoR FPRL1 more efficiently than CCR3, and use of FPRL1 was correlated with CCR5 entry. Subtype D Env was unable to use either CCR3 or FPRL1 efficiently, a unique pattern of alternative CoR use. These results suggest that each subtype of circulating HIV-1 may be subject to somewhat different selective pressures for Env-mediated entry into target cells and suggest that CCR3 may be used as a surrogate CoR by subtype B while FPRL1 may be used as a surrogate CoR by subtypes A and C. These data may provide insight into development of resistance to CCR5-targeted entry inhibitors and alternative entry pathways for each HIV-1 subtype.Human immunodeficiency virus type 1 (HIV-1) infects target cells by binding first to CD4 and then to a coreceptor (CoR), of which C-C chemokine receptor 5 (CCR5) is the most common (6, 53). CXCR4 is an additional CoR for up to 50% of subtype B and D HIV-1 isolates at very late stages of disease (4, 7, 28, 35). Many other seven-membrane-spanning G-protein-coupled receptors (GPCRs) have been identified as alternative CoRs when expressed on various target cell lines in vitro, including CCR1 (76, 79), CCR2b (24), CCR3 (3, 5, 17, 32, 60), CCR8 (18, 34, 38), GPR1 (27, 65), GPR15/BOB (22), CXCR5 (39), CXCR6/Bonzo/STRL33/TYMSTR (9, 22, 25, 45, 46), APJ (26), CMKLR1/ChemR23 (49, 62), FPLR1 (67, 68), RDC1 (66), and D6 (55). HIV-2 and simian immunodeficiency virus SIVmac isolates more frequently show expanded use of these alternative CoRs than HIV-1 isolates (12, 30, 51, 74), and evidence that alternative CoRs other than CXCR4 mediate infection of primary target cells by HIV-1 isolates is sparse (18, 30, 53, 81). Genetic deficiency in CCR5 expression is highly protective against HIV-1 transmission (21, 36), establishing CCR5 as the primary CoR. The importance of alternative CoRs other than CXCR4 has remained elusive despite many studies (1, 30, 70, 81). Expansion of CoR use from CCR5 to include CXCR4 is frequently associated with the ability to use additional alternative CoRs for viral entry (8, 16, 20, 63, 79) in most but not all studies (29, 33, 40, 77, 78). This finding suggests that the sequence changes in HIV-1 env required for use of CXCR4 as an additional or alternative CoR (14, 15, 31, 37, 41, 57) are likely to increase the potential to use other alternative CoRs.We have used the highly permissive NP-2/CD4 human glioma cell line developed by Soda et al. (69) to classify virus entry via the alternative CoRs CCR1, CCR3, CCR8, GPR1, CXCR6, APJ, CMKLR1/ChemR23, FPRL1, and CXCR4. Full-length molecular clones of 66 env genes from most prevalent HIV-1 subtypes were used to generate infectious virus pseudotypes expressing a luciferase reporter construct (19, 57). Two types of analysis were performed: the level of virus entry mediated by each alternative CoR and linear regression of entry mediated by CCR5 versus all other alternative CoRs. We thus were able to identify patterns of alternative CoR use that were subtype specific and to determine if use of any alternative CoR was correlated or independent of CCR5-mediated entry. The results obtained have implications for the evolution of env function, and the analyses revealed important differences between subtype B Env function and all other HIV-1 subtypes.     

Detection of Infectious Adenoviruses in Environmental Waters by Fluorescence-Activated Cell Sorting Assay

Methods for rapid detection and quantification of infectious viruses in the environment are urgently needed for public health protection. A fluorescence-activated cell-sorting (FACS) assay was developed to detect infectious adenoviruses (Ads) based on the expression of viral protein during replication in cells. The assay was first developed using recombinant Ad serotype 5 (rAd5) with the E1A gene replaced by a green fluorescent protein (GFP) gene. Cells infected with rAd5 express GFP, which is captured and quantified by FACS. The results showed that rAd5 can be detected at concentrations of 1 to 10⁴ PFU per assay within 3 days, demonstrating a linear correlation between the viral concentration and the number of GFP-positive cells with an r² value of >0.9. Following the same concept, FACS assays using fluorescently labeled antibodies specific to the E1A and hexon proteins, respectively, were developed. Assays targeting hexon showed greater sensitivity than assays targeting E1A. The results demonstrated that as little as 1 PFU Ads was detected by FACS within 3 days based on hexon protein, with an r² value greater than 0.9 over a 4-log concentration range. Application of this method to environmental samples indicated positive detection of infectious Ads in 50% of primary sewage samples and 33% of secondary treated sewage samples, but none were found in 12 seawater samples. The infectious Ads ranged in quantity between 10 and 165 PFU/100 ml of sewage samples. The results indicate that the FACS assay is a rapid quantification tool for detecting infectious Ads in environmental samples and also represents a considerable advancement for rapid environmental monitoring of infectious viruses.Waterborne viral infection is one of the most important causes of human morbidity in the world. There are hundreds of different types of human viruses present in human sewage, which, if improperly treated, may become the source of contamination in drinking and recreational waters (6, 12, 19). Furthermore, as water scarcity intensifies in the nation, so has consideration of wastewater reuse as a valid and essential alternative for resolving water shortages (31).Currently, routine viral monitoring is not required for drinking or recreational waters, nor is it required for wastewater that is discharged into the environment. This lack of a monitoring effort is due largely to the lack of methods that can rapidly and sensitively detect infectious viruses in environmental samples. In the past 20 years, tremendous progress has been made in detection of viruses in the environment based on molecular technology (32, 33, 35). PCR and quantitative real-time PCR (qPCR) methods have improved both the speed and sensitivity of viral detection compared with detection by the traditional tissue culture method (2, 11, 17, 18). However, they provide little information on viral infectivity, which is crucial for human health risk assessment (22-24, 35). Our previous work using a real-time PCR assay to detect human adenoviruses (Ads) in sewage could not differentiate the infectious viruses in the secondary treated sewage from those killed by chlorination disinfection (15). In this research, we pursued an innovative approach to detecting infectious viruses in water using fluorescence-activated cell sorting (FACS). This method is rapid and sensitive, with an established record in microbiological research (29, 34, 39).FACS is a specialized type of flow cytometry which provides a method for counting and sorting a heterogeneous mixture of biological cells into two or more kinds, one cell at a time, based upon the specific light-scattering and fluorescent characteristics of each cell (4, 25, 34, 38). It is a useful method since it provides fast and quantitative recording of fluorescent signals from individual cells (14, 16, 34, 47). The FACS viral assay is based on the expression of viral protein inside the recipient cell during viral replication (16). Specific antibody labeled with fluorescence is bound to the target viral protein, which results in fluorescence emission from infected cells. Viral particles outside the cell will not be captured, because the size of virus is below the detection limit of flow cytometry. Therefore, detection of cells, which can be captured with fluorescently labeled viral antibody, is a definitive indication of the presence of infectious virus.This research used human Ads as the target for development of the FACS method. The rationale for this choice is as follows. (i) Ads are important human pathogens that may be transmitted by water consumption and water spray (aerosols) (26, 32). The health hazard associated with exposure to Ads has been demonstrated by epidemiological data and clinical research (1, 7, 9, 35, 40, 43). (ii) Ads are among the most prevalent human viruses identified in human sewage and are frequently detected in marine waters and the Great Lakes (17, 32, 33, 35). (iii) Ads are more resistant to UV disinfection than any other bacteria or viruses (3, 5, 10, 24, 41, 42, 44). Thus, they may survive wastewater treatment as increasing numbers of wastewater treatment facilities switch from chlorination to UV to avoid disinfection by-products. (iv) Some serotypes of Ads, including enteric Ad 40 and 41, are fastidious. They are difficult to detect by plaque assay, and a routine assay of infectivity takes 7 to 14 days (8, 20).In this study, recombinant Ad serotype 5 (rAd5) with the E1A gene (the first transcribed gene after infection) replaced by a green fluorescent protein (GFP) gene was first used to test for sensitivity and speed of the assay. Two other viral proteins were then used as targets for development of FACS assays using Ad serotype 2 (Ad2) and Ad41. This study demonstrated the feasibility, sensitivity, and reliability of the assay for detection of infectious Ads in environmental samples.     

Characterization of Respiratory Syncytial Virus M- and M2-Specific CD4 T Cells in a Murine Model

CD4 T cells have been shown to play an important role in the immunity and immunopathogenesis of respiratory syncytial virus (RSV) infection. We identified two novel CD4 T-cell epitopes in the RSV M and M2 proteins with core sequences M_213-223 (FKYIKPQSQFI) and M2_27-37 (YFEWPPHALLV). Peptides containing the epitopes stimulated RSV-specific CD4 T cells to produce gamma interferon (IFN-γ), interleukin 2 (IL-2), and other Th1- and Th2-type cytokines in an I-A^b-restricted pattern. Construction of fluorochrome-conjugated peptide-I-A^b class II tetramers revealed RSV M- and M2-specific CD4 T-cell responses in RSV-infected mice in a hierarchical pattern. Peptide-activated CD4 T cells from lungs were more activated and differentiated, and had greater IFN-γ expression, than CD4 T cells from the spleen, which, in contrast, produced greater levels of IL-2. In addition, M_209-223 peptide-activated CD4 T cells reduced IFN-γ and IL-2 production in M- and M2-specific CD8 T-cell responses to D^b-M_187-195 and K^d-M2_82-90 peptides more than M2_25-39 peptide-stimulated CD4 T cells. This correlated with the fact that I-A^b-M_209-223 tetramer-positive cells responding to primary RSV infection had a much higher frequency of FoxP3 expression than I-A^b-M2_26-39 tetramer-positive CD4 T cells, suggesting that the M-specific CD4 T-cell response has greater regulatory function. Characterization of epitope-specific CD4 T cells by novel fluorochrome-conjugated peptide-I-A^b tetramers allows detailed analysis of their roles in RSV pathogenesis and immunity.CD4 T lymphocytes play an important role in the resolution of primary viral infections and the prevention of reinfection by regulating a variety of humoral and cellular immune responses. CD4 T cells provide cytokines and other molecules to support the differentiation and expansion of antigen-specific CD8 T cells, which are major effectors for both virus clearance and immunopathology during primary infection with respiratory syncytial virus (RSV) (3, 17, 42, 43). CD4 T-cell help is mandatory for an effective B-cell response (14), which is necessary for producing neutralizing antibodies that prevent secondary RSV infection (12, 18, 21). A concurrent CD4 T-cell response also promotes the maintenance of CD8 T-cell surveillance and effector capacity (9). Previous studies have shown that interleukin 2 (IL-2) from CD4 T cells can restore CD8 T-cell function in lungs (10) and that IL-2 supplementation can increase the production of gamma interferon (IFN-γ) by CD8 T cells upon peptide stimulation in vitro (45).While CD4 T cells are important for providing support to host immunity, they have also been associated with immunopathogenesis by playing a key role in the Th2-biased T-cell response (34, 46), which may be the common mechanism of enhanced lung pathology and other disease syndromes shown in murine studies (2, 16, 17, 19, 35). Earlier studies showed the positive association of formalin-inactivated RSV (FI-RSV) immunization-mediated enhanced illness upon subsequent natural RSV infection with a Th2-biased CD4 T-cell response (19, 44). Th2-orientated CD4 T cells elicit severe pneumonia with extensive eosinophilic infiltrates in the lungs of FI-RSV-immunized mice (13, 24, 48). Patients with severe RSV disease showed an elevated Th2/Th1 cytokine ratio in nasal secretions and peripheral blood mononuclear cells (27, 29, 31, 38). Increased disease severity has also been associated with polymorphisms in Th2-related cytokine genes, such as the IL-4, IL-4 receptor, and IL-13 genes (11, 23, 36). Th2 cytokines from CD4 T cells can also diminish the CD8 T-cell response and delay viral clearance (4, 8).The evaluation of CD4 T-cell responses in viral infection is particularly relevant in the RSV model because of the association of RSV and allergic inflammation, which is largely mediated by CD4 T cells. Understanding the influence of CD4 T cells on CD8 T-cell responses and other immunological effector mechanisms is central to understanding RSV pathogenesis and developing preventive vaccine strategies for RSV. Our lab and others have demonstrated that CD8 T cells target RSV M and M2 proteins with cytolytic effector activities (28, 30, 39). In this study, we found that both RSV M and M2 proteins also contain CD4 T-cell epitopes. These epitopes have 11-mer amino acid core sequences and are associated with the major histocompatibility complex (MHC) class II molecule I-A^b. Fluorochrome-conjugated peptide-I-A^b molecule tetrameric complexes can identify RSV M- and M2-specific CD4 T cells from CB6F1 mice following RSV infection in a hierarchical pattern. Peptides containing the epitopes can stimulate CD4 T cells from RSV M or M2 DNA-immunized and virus-challenged mice and can lead to the production of IFN-γ, IL-2, and other Th1- and Th2-type cytokines that can modulate the CD8 T-cell response to RSV M and M2. We also found that CD4 T cells from the lungs and spleens of immunized mice have different phenotype and cytokine profiles upon in vitro stimulation. These observations suggest a regulatory role for CD4 T cells in the host response to RSV infection. The development of novel MHC class II tetramer reagents allows the characterization of epitope-specific CD4 T-cell responses to RSV and will enable the investigation of basic mechanisms by which CD4 T cells affect pathogenesis and immunity to viral infections.     

The Receptor Complex Associated with Human T-Cell Lymphotropic Virus Type 3 (HTLV-3) Env-Mediated Binding and Entry Is Distinct from,but Overlaps with,the Receptor Complexes of HTLV-1 and HTLV-2

Little is known about the transmission or tropism of the newly discovered human retrovirus, human T-cell lymphotropic virus type 3 (HTLV-3). Here, we examine the entry requirements of HTLV-3 using independently expressed Env proteins. We observed that HTLV-3 surface glycoprotein (SU) binds efficiently to both activated CD4⁺ and CD8⁺ T cells. This contrasts with both HTLV-1 SU, which primarily binds to activated CD4⁺ T cells, and HTLV-2 SU, which primarily binds to activated CD8⁺ T cells. Binding studies with heparan sulfate proteoglycans (HSPGs) and neuropilin-1 (NRP-1), two molecules important for HTLV-1 entry, revealed that these molecules also enhance HTLV-3 SU binding. However, unlike HTLV-1 SU, HTLV-3 SU can bind efficiently in the absence of both HSPGs and NRP-1. Studies of entry performed with HTLV-3 Env-pseudotyped viruses together with SU binding studies revealed that, for HTLV-1, glucose transporter 1 (GLUT-1) functions at a postbinding step during HTLV-3 Env-mediated entry. Further studies revealed that HTLV-3 SU binds efficiently to naïve CD4⁺ T cells, which do not bind either HTLV-1 or HTLV-2 SU and do not express detectable levels of HSPGs, NRP-1, and GLUT-1. These results indicate that the complex of receptor molecules used by HTLV-3 to bind to primary T lymphocytes differs from that of both HTLV-1 and HTLV-2.The primate T-cell lymphotropic virus (PTLV) group of deltaretroviruses consists of three types of human T-cell lymphotropic viruses (HTLVs) (HTLV-1, HTLV-2, HTLV-3), their closely related simian T-cell lymphotropic viruses (STLVs) (STLV-1, STLV-2, STLV-3), an HTLV (HTLV-4) for which a simian counterpart has not been yet identified, and an STLV (STLV-5) originally described as a divergent STLV-1 (5-7, 30, 35, 37, 38, 45, 51, 53). HTLV-1 and HTLV-2, which have a 70% nucleotide homology, differ in both their pathobiology and tropism (reviewed in reference 13). While HTLV-1 causes a neurological disorder (tropical spastic paraparesis/HTLV-1-associated myelopathy) and a hematological disease (adult T-cell leukemia/lymphoma) (15, 42, 55), HTLV-2 is only rarely associated with tropical spastic paraparesis/HTLV-1-associated myelopathy-like disease and is not definitively linked to any lymphoproliferative disease (12, 20). In vivo, both HTLV-1 and HTLV-2 infect T cells. Although HTLV-1 is primarily found in CD4⁺ T cells, other cell types in the peripheral blood of infected individuals have been found to contain HTLV-1, including CD8⁺ T cells, dendritic cells, and B cells (19, 29, 33, 36, 46).Binding and entry of retroviruses requires specific interactions between the Env glycoproteins on the virus and cell surface receptor complexes on target cells. For HTLV-1, three molecules have been identified as important for entry, as follows: heparan sulfate proteoglycans (HSPGs), neuropilin-1 (NRP-1), and glucose transporter 1 (GLUT-1) (16, 22, 26, 28, 29, 34, 39, 44). Recent studies support a model in which HSPG and NRP-1 function during the initial binding of HTLV-1 to target cells, and GLUT-1 functions at a postattachment stage, most likely to facilitate fusion (29, 34, 49). Efficient HTLV-2 binding and entry requires NRP-1 and GLUT-1 but not HSPGs (16, 26, 39, 49).This difference in the molecules required for binding to target cells reflects differences in the T-cell tropisms of these two viruses. Activated CD4⁺ T cells express much higher levels of HSPGs than CD8⁺ T cells (26). In infected individuals, HTLV-1 is primarily found in CD4⁺ T cells, while HTLV-2 is primarily found in CD8⁺ T cells (21, 43, 46). In vitro, HTLV-1 preferentially transforms CD4⁺ T cells while HTLV-2 preferentially transforms CD8⁺ T cells, and this difference has been mapped to the Env proteins (54).We and others have reported the discovery of HTLV-3 in two Cameroonese inhabitants (6, 7, 53). We recently uncovered the presence of a third HTLV-3 strain in a different population living several hundred kilometers away from the previously identified groups (5), suggesting that this virus may be common in central Africa. Since the HTLV-3 sequences were obtained by PCR amplification of DNA isolated from peripheral blood mononuclear cells (PBMCs) of infected individuals, little is known about its tropism and pathobiology in vivo. Based on the correlation between HSPG expression levels and viral tropisms of HTLV-1 and HTLV-2, we reasoned that knowledge about the HTLV-3 receptors might provide insight into the tropism of this virus. We therefore generated vectors expressing HTLV-3 Env proteins and used them to begin to characterize the receptor complex used by HTLV-3 to bind and enter cells.