Plant death caused by inefficient induction of antiviral R-gene-mediated resistance may function as a suicidal population resistance mechanism.

Land plant genomes carry tens to hundreds of Resistance (R) genes to combat pathogens. The induction of antiviral R-gene-mediated resistance often results in a hypersensitive response (HR), which is characterized by virus containment in the initially infected tissues and programmed cell death (PCD) of the infected cells. Alternatively, systemic HR (SHR) is sometimes observed in certain R gene-virus combinations, such that the virus systemically infects the plant and PCD induction follows the spread of infection, resulting in systemic plant death. SHR has been suggested to be the result of inefficient resistance induction; however, no quantitative comparison has been performed to support this hypothesis. In this study, we report that the average number of viral genomes that establish cell infection decreased by 28.7% and 12.7% upon HR induction by wild-type cucumber mosaic virus and SHR induction by a single-amino acid variant, respectively. These results suggest that a small decrease in the level of resistance induction can change an HR to an SHR. Although SHR appears to be a failure of resistance at the individual level, our simulations imply that suicidal individual death in SHR may function as an antiviral mechanism at the population level, by protecting neighboring uninfected kin plants.

Vpr and Its Cellular Interaction Partners: R We There Yet?

Vpr is a lentiviral accessory protein that is expressed late during the infection cycle and is packaged in significant quantities into virus particles through a specific interaction with the P6 domain of the viral Gag precursor. Characterization of the physiologically relevant function(s) of Vpr has been hampered by the fact that in many cell lines, deletion of Vpr does not significantly affect viral fitness. However, Vpr is critical for virus replication in primary macrophages and for viral pathogenesis in vivo. It is generally accepted that Vpr does not have a specific enzymatic activity but functions as a molecular adapter to modulate viral or cellular processes for the benefit of the virus. Indeed, many Vpr interacting factors have been described by now, and the goal of this review is to summarize our current knowledge of cellular proteins targeted by Vpr.

Growth properties of macaque-tropic HIV-1 clones carrying vpr/vpx genes derived from simian immunodeficiency viruses in place of their vpr regions.

We have previously generated a macaque-tropic human immunodeficiency virus type 1 (HIV-1mt) clone designated MN4/LSDQgtu by genetic manipulation from a parental virus that replicates poorly in rhesus macaque cells. In rhesus cell line M1.3S and peripheral blood mononuclear cells (PBMCs), MN4/LSDQgtu grows comparably to a standard simian immunodeficiency virus clone derived from the rhesus macaque (SIVmac239) that can induce the acquired immunodeficiency syndrome (AIDS) in the animals. In this study, we further modified the Vpr-coding region of MN4/LSDQgtu genome by introducing vpr gene of an SIV clone from the greater spot-nosed monkey (SIVgsn166) or vpx gene of SIVmac239 to generate four new clones for determining functional importance of the central genomic area. Furthermore, two clones with an additional Gag-p6 mutation were made to ensure the virion-packaging of Vpx. In addition, accessory gene mutant clones of MN4/LSDQgtu with a frame-shift mutation, including a vpr mutant, were constructed and their growth properties were examined. Infection experiments showed that newly constructed viruses all grew poorly to various degrees in M1.3S cells, relative to MN4/LSDQgtu. Together with the previous data, our results here show that vpr/vpx gene in the appropriate context of HIV-1 genome is critical for viral growth ability.

Elicitors, effectors, and R genes: the new paradigm and a lifetime supply of questions.

The plant basal immune system can detect broadly present microbe-associated molecular patterns (MAMPs, also called PAMPs) and induce defenses, but adapted microbes express a suite of effector proteins that often act to suppress these defenses. Plants have evolved other receptors (R proteins) that detect these pathogen effectors and activate strong defenses. Pathogens can subsequently alter or delete their recognized effectors to avoid defense elicitation, at risk of a fitness cost associated with loss of those effectors. Significant research progress is revealing, among other things, mechanisms of MAMP perception, the host defense processes and specific host proteins that pathogen effectors target, the mechanisms of R protein activation, and the ways in which pathogen effector suites and R genes evolve. These findings carry practical ramifications for resistance durability and for future resistance engineering. The present review uses numerous questions to help clarify what we know and to identify areas that are ripe for further investigation.

Hybrid necrosis: autoimmunity as a potential gene-flow barrier in plant species.

Ecological factors, hybrid sterility and differences in ploidy levels are well known for contributing to gene-flow barriers in plants. Another common postzygotic incompatibility, hybrid necrosis, has received comparatively little attention in the evolutionary genetics literature. Hybrid necrosis is associated with a suite of phenotypic characteristics that are similar to those elicited in response to various environmental stresses, including pathogen attack. The genetic architecture is generally simple, and complies with the Bateson-Dobzhansky-Muller model for hybrid incompatibility between species. We survey the extensive literature on this topic and present the hypothesis that hybrid necrosis can result from autoimmunity, perhaps as a pleiotropic effect of evolution of genes that are involved in pathogen response.

HIV-1 genes vpr and nef synergistically damage podocytes, leading to glomerulosclerosis.

This study aimed to identify the causative gene for HIV-1 associated nephropathy, a paradigmatic podocytopathy. A previous study demonstrated that transgenic expression of nonstructural HIV-1 genes selectively in podocytes in mice with FVB/N genetic background resulted in podocyte injury and glomerulosclerosis. In this study, transgenic mice that expressed individual HIV-1 genes in podocytes were generated. Five of six transgenic mice that expressed vpr developed podocyte damage and glomerulosclerosis. Analysis of an established vpr transgenic line revealed that transgenic mice on FVB/N but not on C57BL/6 genetic background developed podocyte injury by 8 wk of age, with later glomerulosclerosis. Four of 11 transgenic mice that expressed nef also developed podocyte injury. One transgenic line was established from the nef founder mouse with the mildest phenotype. Transgenic mice in this line developed mesangial expansion at 3 wk of age and mild focal podocyte damage at 10 wk of age. Mating with FVB/N mice did not augment nephropathy. None of the transgenic mice that expressed vif, tat, rev, or vpu in podocytes, even with the FVB/N genetic background, developed podocyte injury. For testing effects of simultaneous expression of vpr and nef, these two lines were mated. All nef:vpr double-transgenic mice showed severe podocyte injury and glomerulosclerosis by 4 wk of age. In contrast, all vpr or nef single-transgenic mice in the same litter uniformly showed no or much milder podocyte injury. These findings indicate that vpr and nef each can induce podocyte injury with a prominent synergistic interaction.

Endothelial cells promote human immunodeficiency virus replication in nondividing memory T cells via Nef-, Vpr-, and T-cell receptor-dependent activation of NFAT.

Human endothelial cells (ECs) enhance human immunodeficiency virus (HIV) replication within CD4(+) memory T cells by 50,000-fold in a Nef-dependent manner. Here, we report that EC-mediated HIV type 1 replication is also dependent on an intact vpr gene. Moreover, we demonstrate that despite a requirement for engaging major histocompatibility complex (MHC) class II molecules and costimulators, EC-stimulated virus-producing cells (p24(high) T cells) do not proliferate, nor are they arrested in the cell cycle. Rather, they are minimally activated, sometimes expressing CD69 but not CD25, HLA-DR, VLA-1, or effector cytokines. Blocking antibodies to interleukin 2 (IL-2), IL-6, IL-7, or tumor necrosis factor do not inhibit viral replication. Cyclosporine effectively inhibits viral replication, as does disruption of the NFAT binding site in the viral long terminal repeat. Furthermore, in the presence of ECs, suboptimal T-cell receptor (TCR) stimulation with phytohemagglutinin L supports efficient viral replication, and suboptimal stimulation with toxic shock syndrome toxin 1 leads to viral replication selectively in the TCR-stimulated, Vbeta2-expressing T cells. Collectively, these data indicate that ECs provide signals that promote Nef- and Vpr-dependent HIV replication in memory T cells that have been minimally activated through their TCRs. Our studies suggest a mechanism for HIV replication in vivo within the reservoir of circulating memory CD4(+) T cells that persist despite antiretroviral therapy and further suggest that maintenance of immunological memory by MHC class II-expressing ECs via TCR signaling may contribute to HIV rebound following cessation of antiretroviral therapy.

[The function of accessory genes of HIV-1].

Human immunodeficiency virus type 1 (HIV-1) has 4 auxiliary genes, vpr, vpu, nef, and vif, which are dispensable for viral replication in vitro. However, many studies with animal model revealed that these genes play important roles on the viral replication and the development of AIDS in vivo through many complicated mechanisms. Although several key factors involved in the function have been identified, further studies are required for the complete understandings of the action mechanisms. The elucidation of the function of the auxiliary genes on molecular bases leads to the discovery of new therapeutic strategies against HIV and the understanding of basic cellular mechanisms. In this review, we summarize new observations mainly about the interactions between auxiliary genes and host cell functions.

Human immunodeficiency virus type 1 vpr gene induces phenotypic effects similar to those of the DNA alkylating agent, nitrogen mustard.

The product of the human immunodeficiency virus type 1 (HIV-1) vpr gene induces cell cycle arrest in the G2 phase of the cell cycle and is characterized by an accumulation of the hyperphosphorylated form of cdc2 kinase. This phenotype is similar to the effect of DNA-damaging agents, which can also cause cells to arrest at G2. We previously reported that Vpr mimicked some of the effects of a DNA alkylating agent known as nitrogen mustard (HN2). Here we extend these earlier observations by further comparing the activation state of cdc2 kinase, the kinetics of G2 arrest, and the ability to reverse the arrest with chemical compounds known as methylxanthines. Infection of cells synchronized in the G1 phase of the cell cycle with a pseudotyped HIV-1 resulted in arrest at G2 within 12 h postinfection, before the first mitosis. Similar to that induced by HN2, Vpr-induced arrest led to a decrease in cdc2 kinase activity. Vpr-mediated G2 arrest was alleviated by methylxanthines at concentrations similar to those needed to reverse the G2 arrest induced by HN2, and cells proceeded apparently normally through at least one complete cell cycle. These results are consistent with the hypothesis that Vpr induces G2 arrest through pathways that are similar to those utilized by DNA-damaging agents.

Aspectos biomoleculares de la infección por el virus de la inmunodeficiencia humana / Biomolecular aspects of the human immunodeficiency virus infection

El presente artículo de revisión se centra en las consideraciones fundamentales sobre la biología molecular del virus de la inmunodeficiencia humana, el principal de los retrovirus que infectan a los hombres, destacando sus aspectos constitutivos así como genéticos y las alteraciones con la célula huésped. Se presenta además los aspectos morfofuncionales básicos de los linfocitos T CD4 y las interacciones que a nivel de membrana se producen para favorecer la infección por el virus y que explican su fisiopatología. Finalmente, se destacan los eventos intracelulares que conducen a la replicación y ensamblaje viral que producen la muerte celular y explican la inmunosupresión del huésped

Functional analysis of the vpx, vpr, and nef genes of simian immunodeficiency virus.

The role of the vpx, vpr, and nef genes in the replication of simian immunodeficiency virus (SIV) was investigated using point and deletion mutations in these genes. The effects on replication kinetics of single or combined mutants--vpx, vpr, vpx-vpr, vpx-nef, vpr-nef, and vpx-vpr-nef--in established lymphoid CEMx174 and MT-4 cells were negligible, except that the postinfection appearance of vpx-nef, vpr-nef, and vpx-vpr-nef progeny virus was slightly delayed in MT-4 cells. The vpx, but not the vpr, point mutation reverted to wild-type sequences within 12 days after infection, suggesting that stronger selection pressure for Vpx than for Vpr expression might exist in these established cell lines. In contrast to growth in the lymphoid cell lines, replication of vpx-deleted viruses in macaque peripheral blood mononuclear cells (PBMC) was severely impaired, indicating that Vpx is necessary for efficient replication in PBMC. In contrast, the vpr mutant exhibited different degrees of impairment depending on the donor animal used as a source of PBMC. A virus encoding a Vpx-Vpr fusion protein replicated in PBMC comparably to a vpr deletion mutant virus, whereas a frameshift deletion at the vpx-vpr junction of this mutant eliminated virus replication, suggesting that deletion of the C-terminal half of Vpx was partially compensated by the presence of the large Vpr portion in the fusion protein. Deletion of the nef gene did not affect SIVmac replication in PBMC. The Vpx and Vpr proteins expressed in COS-1 cells were detected in the extracellular medium and did not crossreact with Vpr- and Vpx-specific antisera, in spite of extensive amino acid similarity between these proteins. These studies indicate the importance of Vpx and Vpr in SIVmac infection and suggest that these proteins are antigenically and functionally distinct.

The human immunodeficiency virus type 1 vpr gene prevents cell proliferation during chronic infection.

Human immunodeficiency virus type 1 (HIV-1) is a retrovirus that can cause extensive cytopathicity in T cells. However, long-term productive infection of T-cell lines has been described. Here we show that although Vpr has no effect on the initial cytopathic effect of HIV-1, viruses that contain an intact vpr gene are unable to establish a chronic infection of T cells. However, virus with a mutated vpr gene can readily establish such long-term cultures. The effect of Vpr is independent of the env gene and the nef gene. Furthermore, expression of Vpr alone affects the progression of cells in the cell cycle. These results suggest that HIV-1 has evolved a viral gene to prevent chronic infection of T cells.

[Are rap genes anti-oncogenes?]. / Les gènes rap sont-ils des anti-oncogènes?

The products of the ras-related rap genes (rap1 and rap2) are small G-proteins that share a high degree of structural (around 50% of identical amino acids) and functional homology with the products of ras oncogenes. In particular, the sequence of the effector domain of ras and rap proteins is identical, which has prompted speculations that they might compete for interaction with a common effector. In effect, by attempting to identify genes whose expression would be capable of reverting the phenotype of ras-transformed cells, the laboratory of Makoto Noda isolated the Krev-1 gene that was found to encode the same protein as the rap1A gene. Biochemical studies have since shown that the rap1 protein effectively competes with ras proteins for their interaction with the p120-GAP protein, a potential effector of the biological activity of ras proteins that strongly stimulates their GTPase activity; however, p120-GAP does not stimulate the GTPase activity of the rap1 protein. In contrast, the rap2 protein has no effect on the interaction between ras proteins and p120-GAP. Similarly, whereas overexpression of the rap1 protein is able to antagonize the transforming potential of oncogenic ras proteins, a considerable overexpression of normal or mutated rap2 proteins has no effect on cellular proliferation or transformation induced by ras oncogenes. It is therefore concluded that rap genes cannot be considered as anti-oncogenes; whether the physiological function of the rap1 protein is to modulate the activity of ras proteins, or its antagonistic effect is merely attributable to its experimental overexpression remains to be established.

Molecular biology of the human immunodeficiency virus type 1.

The immunodeficiency virus type 1 is a complex retrovirus. In addition to genes that specify the proteins of the virus particle and the replicative enzymes common to all retroviruses, HIV-1 specifies at least six additional proteins that regulate the virus life cycle. Two of these regulatory genes, tat and rev, specify proteins essential for replication. These proteins bind to specific sequences of newly synthesized virus RNA and profoundly affect virus protein expression. Tat and rev appear to be prototypes of novel eukaryotic regulatory proteins. These two genes may play a central role in regulating the rate of virus replication. Three other viral genes, vif, vpu, and vpr, affect the assembly and replication capacity of newly made virus particles. These genes may play a critical role in spread of the virus from tissue to tissue and from person to person. Our understanding of the contribution of each of the virus structural proteins and regulatory genes to the complex life cycle of the virus in natural infections is incomplete. However, enough insight has been gained into the structure and function of each of these components to provide a firm basis for rational antiviral drug development.