Edward M. Campbell

Disruption of the actin cytoskeleton can complement the ability of Nef to enhance human immunodeficiency virus type 1 infectivity.

ABSTRACT The human immunodeficiency virus (HIV) protein Nef has been shown to increase the infectivity of HIV at an early point during infection. Since Nef is known to interact with proteins involved in actin cytoskeleton rearrangements, we tested the possibility that Nef may enhance HIV infectivity via a mechanism that involves the actin cytoskeleton. We find that disruption of the actin cytoskeleton complements the Nef infectivity defect. The ability of disruption of the actin cytoskeleton to complement the Nef defect was specific to envelopes that fuse at the cell surface, including a variety of HIV envelopes and the murine leukemia virus amphotropic envelope. In contrast, the infectivity of HIV virions pseudotyped to enter cells via endocytosis, which is known to complement the HIV Nef infectivity defect and can naturally penetrate the cortical actin barrier, was not altered by actin cytoskeleton disruption. The results presented here suggest that Nef functions to allow the HIV genome to penetrate the cortical actin network, a known barrier for intracellular parasitic organisms.

Proteasome Inhibition Reveals that a Functional Preintegration Complex Intermediate Can Be Generated during Restriction by Diverse TRIM5 Proteins

ABSTRACT The primate TRIM5 proteins constitute a class of restriction factors that prevent host cell infection by retroviruses from different species. The TRIM5 proteins act early after virion entry and prevent viral reverse transcription products from accumulating. We recently found that proteasome inhibitors altered the rhesus monkey TRIM5α restriction of human immunodeficiency virus type 1 (HIV-1), allowing reverse transcription products to accumulate even though viral infection remained blocked. To assess whether sensitivity to proteasome inhibitors was a common feature of primate TRIM5 proteins, we conducted a similar analysis of restriction mediated by owl monkey TRIM-cyclophilin A (CypA) or human TRIM5α. Similar to rhesus monkey TRIM5α restriction, proteasome inhibition prevented owl monkey TRIM-CypA restriction of HIV-1 reverse transcription, even though HIV-1 infection and the output of 2-LTR circles remained impaired. Likewise, proteasome inhibition alleviated human TRIM5α restriction of N-tropic murine leukemia virus reverse transcription. Finally, HIV-1 reverse transcription products escaping rhesus TRIM5α restriction by proteasome inhibition were fully competent for integration in vitro, demonstrating that TRIM5α likely prevents the viral cDNA from accessing chromosomal target DNA. Collectively, these data indicate that the diverse TRIM5 proteins inhibit retroviral infection in multiple ways and that inhibition of reverse transcription products is not necessary for TRIM5-mediated restriction of retroviral infection.

Visualization of a proteasome-independent intermediate during restriction of HIV-1 by rhesus TRIM5α

TRIM5 proteins constitute a class of restriction factors that prevent host cell infection by retroviruses from different species. TRIM5α restricts retroviral infection early after viral entry, before the generation of viral reverse transcription products. However, the underlying restriction mechanism remains unclear. In this study, we show that during rhesus macaque TRIM5α (rhTRIM5α)–mediated restriction of HIV-1 infection, cytoplasmic HIV-1 viral complexes can associate with concentrations of TRIM5α protein termed cytoplasmic bodies. We observe a dynamic interaction between rhTRIM5α and cytoplasmic HIV-1 viral complexes, including the de novo formation of rhTRIM5α cytoplasmic body–like structures around viral complexes. We observe that proteasome inhibition allows HIV-1 to remain stably sequestered into large rhTRIM5α cytoplasmic bodies, preventing the clearance of HIV-1 viral complexes from the cytoplasm and revealing an intermediate in the restriction process. Furthermore, we can measure no loss of capsid protein from viral complexes arrested at this intermediate step in restriction, suggesting that any rhTRIM5α-mediated loss of capsid protein requires proteasome activity.

Role of the cytoskeleton in nuclear import

The role of the cytoskeleton in regulating the intracellular localization of cellular organelles, viruses, and individual proteins has been the subject of much investigation in recent years. While regulated transport through the nuclear pore remains the primary determinant of nuclear localization, it has become clear that the nuclear localization of viruses and some cellular proteins is mediated by the ability of the cytoskeleton, usually microtubules, to direct their perinuclear accumulation in close proximity to the nuclear pore complex. We also discuss how the size of virions and the viscous nature of the cytoplasm would make it very unlikely or even impossible for viruses to achieve this localization by diffusion alone in the absence of active transport mechanisms. This review focuses on the known methods employed by different viruses and proteins to effect their perinuclear accumulation.

Live cell imaging of the HIV-1 life cycle.

Technology developed in the past 10 years has dramatically increased the ability of researchers to directly visualize and measure various stages of the HIV type 1 (HIV-1) life cycle. In many cases, imaging-based approaches have filled critical gaps in our understanding of how certain aspects of viral replication occur in cells. Specifically, live cell imaging has allowed a better understanding of dynamic, transient events that occur during HIV-1 replication, including the steps involved in viral fusion, trafficking of the viral nucleoprotein complex in the cytoplasm and even the nucleus during infection and the formation of new virions from an infected cell. In this review, we discuss how researchers have exploited fluorescent microscopy methodologies to observe and quantify these events occurring during the replication of HIV-1 in living cells.

Gene Therapy Progress and Prospects: Viral trafficking during infection

The intracellular steps involved in viral infection, namely cytoplasmic trafficking and nuclear import, are critical events in the viral life cycle that have lagged behind other areas of viral research. This review examines recent advances in our understanding of these steps for viruses commonly employed as viral gene delivery vectors. Steps governing the cytoplasmic trafficking and nuclear import of Herpes Simplex virus, Human Immunodeficiency virus and Adenovirus are reviewed in this article.

Heat Shock Perturbs TRIM5α Restriction of Human Immunodeficiency Virus Type 1

ABSTRACT TRIM5α restriction factors protect target cells from retroviruses by blocking infection prior to the accumulation of viral reverse transcription (RT) products. Here, we demonstrate that heat shock perturbed owl monkey TRIMCyp and rhesus TRIM5α-mediated restriction of human immunodeficiency virus type 1 (HIV-1) late RT products and 2-long terminal repeat circles. Heat shock partially rescued HIV-1 infection from TRIMCyp restriction, and this rescue became more profound when combined with the presence of the proteasome inhibitor MG132. This indicates that viral RT products rescued from restriction by either heat shock treatment or the presence of MG132 are on a productive pathway, supporting a model in which TRIM5α proteins restrict retroviruses in multiple phases that are differentially sensitive to heat shock and proteasome inhibitors.

Heat shock perturbs TRIM5alpha restriction of human immunodeficiency virus type 1.

ABSTRACT TRIM5α restriction factors protect target cells from retroviruses by blocking infection prior to the accumulation of viral reverse transcription (RT) products. Here, we demonstrate that heat shock perturbed owl monkey TRIMCyp and rhesus TRIM5α-mediated restriction of human immunodeficiency virus type 1 (HIV-1) late RT products and 2-long terminal repeat circles. Heat shock partially rescued HIV-1 infection from TRIMCyp restriction, and this rescue became more profound when combined with the presence of the proteasome inhibitor MG132. This indicates that viral RT products rescued from restriction by either heat shock treatment or the presence of MG132 are on a productive pathway, supporting a model in which TRIM5α proteins restrict retroviruses in multiple phases that are differentially sensitive to heat shock and proteasome inhibitors.