Asymptomatic Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) Infection in a Rehabilitation Facility: Evolution of the Presence of Nasopharyngeal SARS-CoV-2 and Serological Antibody Responses

At the start of the UK coronavirus disease 2019 epidemic, this rare point prevalence study revealed that one-third of patients (15 of 45) in a London inpatient rehabilitation unit were found to be infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) but asymptomatic. We report on 8 patients in detail, including their clinical stability, the evolution of their nasopharyngeal viral reverse-transcription polymerase chain reaction (RT-PCR) burden, and their antibody levels over time, revealing the infection dynamics by RT-PCR and serology during the acute phase. Notably, a novel serological test for antibodies against the receptor binding domain of SARS-CoV-2 showed that 100% of our asymptomatic cohort remained seropositive 3—6 weeks after diagnosis.

Y44A Mutation in the Acidic Domain of HIV-2 Tat Impairs Viral Reverse Transcription and LTR-Transactivation

HIV transactivator protein (Tat) plays a pivotal role in viral replication through modulation of cellular transcription factors and transactivation of viral genomic transcription. The effect of HIV-1 Tat on reverse transcription has long been described in the literature, however, that of HIV-2 is understudied. Sequence homology between Tat proteins of HIV-1 and 2 is estimated to be less than 30%, and the main difference lies within their N-terminal region. Here, we describe Y44A-inactivating mutation of HIV-2 Tat, studying its effect on capsid production, reverse transcription, and the efficiency of proviral transcription. Investigation of the mutation was performed using sequence- and structure-based in silico analysis and in vitro experiments. Our results indicate that the Y44A mutant HIV-2 Tat inhibited the activity and expression of RT (reverse transcriptase), in addition to diminishing Tat-dependent LTR (long terminal repeat) transactivation. These findings highlight the functional importance of the acidic domain of HIV-2 Tat in the regulation of reverse transcription and transactivation of the integrated provirions.

K63-Linked Ubiquitin Is Required for Restriction of HIV-1 Reverse Transcription and Capsid Destabilization by Rhesus TRIM5α

ABSTRACTTRIM5α is an antiviral restriction factor that inhibits retroviral infection in a species-specific fashion. TRIM5α binds to and forms assemblies around the retroviral capsid. Following binding, poorly understood, ubiquitin-dependent events lead to the disassembly of the viral core, prior to the accumulation of viral reverse transcription products in the target cell. It is also known that assemblies of TRIM5α and other TRIM family proteins can be targets of autophagic degradation. The goal of this study was to define the role of specific ubiquitin linkages in the retroviral restriction and autophagic degradation of TRIM5α and delineate any connection between these two processes. To this end, we generated fusion proteins in which the catalytic domains of different deubiquitinase (DUB) enzymes, with different specificities for polyubiquitinated linkages, were fused to the N-terminal RING domain of Rhesus macaque TRIM5α. We assessed the role of ubiquitination in restriction and the degree to which specific types of ubiquitination are required for the association of TRIM5α with autophagic proteins. We determined that K63-linked ubiquitination by TRIM5α is required to induce capsid disassembly and to inhibit reverse transcription of HIV, while the ability to inhibit HIV-1 infection was not dependent on K63-linked ubiquitination. We also observed that K63-linked ubiquitination is required for the association of TRIM5α with autophagosomal membranes and the autophagic adapter protein p62.IMPORTANCEAlthough the mechanisms by which TRIM5α can induce the abortive disassembly of retroviral capsids have remained obscure, numerous studies have suggested a role for ubiquitination and cellular degradative pathways. These studies have typically relied on global perturbation of cellular degradative pathways. Here, through the use of linkage-specific deubiquitinating enzymes tethered to TRIM5α, we delineate the ubiquitin linkages which drive specific steps in restriction and degradation by TRIM5α, providing evidence for a noncanonical role for K63-linked ubiquitin in the process of retroviral restriction by TRIM5α and potentially providing insight into the mechanism of action of other TRIM family proteins.

The SAM domain of mouse SAMHD1 is critical for its activation and regulation

ABSTRACTHuman SAMHD1 (hSAMHD1) is a retroviral restriction factor that blocks HIV-1 infection by depleting the cellular nucleotides required for viral reverse transcription. SAMHD1 is allosterically activated by nucleotides that induce assembly of the active tetramer. Although the catalytic core of hSAMHD1 has been studied extensively, previous structures have not captured the regulatory SAM domain. In this study, we determined the first crystal structure of full-length SAMHD1 by capturing mouse SAMHD1 (mSAMHD1) structures in three different nucleotide bound states. Although mSAMHD1 and hSAMHD1 are highly similar in sequence and function, we found that mSAMHD1 possesses a more complex nucleotide-induced activation process, highlighting the regulatory role of the SAM domain. Our results provide new insights into the regulation of SAMHD1 activity, thereby will facilitate the improvement of HIV mouse models and the development of new therapies for certain cancers and autoimmune diseases.

Kill HIV by Starvation–Mechanism of Allosteric Activation of SAMHD1

SAMHD1, a deoxyribonucleoside triphosphate triphosphohydrolase (dNTPase), prevents the infection of blood cells by retroviruses, including HIV, by depleting the cellular dNTP pool available for viral reverse transcription. SAMHD1 is a major regulator of cellular dNTP levels in mammalian cells. Mutations in SAMHD1 are associated with the autoimmune condition Aicardi Goutières Syndrome (AGS), whose clinical manifestations resemble congenital viral infection. The catalytic activity of SAMHD1 is regulated by allosteric binding of dGTP, which enables SAMHD1 monomers/dimers to assemble into the catalytically active tetrameric form. We have determined the crystal structure of the tetrameric human SAMHD1-dGTP complex. The structure reveals an elegant allosteric mechanism of activation via dGTP-induced assembly of the tetrameric complex from two inactive dimers. Intriguingly, GTP can also activate SAMHD1, and our data further show the binding promiscuity of other dNTPs at the allosteric site. These findings suggest a regulation system that may have a profound effect on the balancing of cellular dNTP pools. These results provide the basis for a mechanistic understanding of SAMHD1 function in HIV restriction, the pathogenesis of AGS, and regulation of cellular dNTP levels.

Structural features of antiviral DNA cytidine deaminases

The APOBEC3 (A3) family of cytidine deaminases plays a vital role for innate defense against retroviruses. Lentiviruses such as HIV-1 evolved the Vif protein that triggers A3 protein degradation. There are seven A3 proteins, A3A-A3H, found in humans. All A3 proteins can deaminate cytidines to uridines in single-stranded DNA (ssDNA), generated during viral reverse transcription. A3 proteins have either one or two cytidine deaminase domains (CD). The CDs coordinate a zinc ion, and their amino acid specificity classifies the A3s into A3Z1, A3Z2, and A3Z3. A3 proteins occur as monomers, dimers, and large oligomeric complexes. Studies on the nature of A3 oligomerization, as well as the mode of interaction of A3s with RNA and ssDNA are partially controversial. High-resolution structures of the catalytic CD2 of A3G and A3F as well as of the single CD proteins A3A and A3C have been published recently. The NMR and X-ray crystal structures show globular proteins with six α-helices and five β sheets arranged in a characteristic motif (α1-β1-β2/2′-α2-β3-α3-β4-α4-β5-α5-α6). However, the detailed arrangement and extension of individual structure elements and their relevance for A3 complex formation and activity remains a matter of debate and will be highlighted in this review.

DDX3 DEAD-Box RNA Helicase Inhibits Hepatitis B Virus Reverse Transcription by Incorporation into Nucleocapsids

ABSTRACT Viruses utilize host factors in many steps of their life cycles. Yet, little is known about host factors that contribute to the life cycle of hepatitis B virus (HBV), which replicates its genome by reverse transcription. To identify host factors that contribute to viral reverse transcription, we sought to identify cellular proteins that interact with HBV polymerase (Pol) by using affinity purification coupled with mass spectrometry. One of the HBV Pol-interacting host factors identified was DDX3 DEAD-box RNA helicase, which unwinds RNA in an ATPase-dependent manner. Recently, it was shown that DDX3 is essential for both human immunodeficiency virus and hepatitis C virus infection. In contrast, we found that the ectopic expression of DDX3 led to significantly reduced viral DNA synthesis. The DDX3-mediated inhibition of viral DNA synthesis did not affect RNA encapsidation, a step prior to reverse transcription, and indicated that DDX3 inhibits HBV reverse transcription. Mutational analysis revealed that mutant DDX3 with an inactive ATPase motif, but not that with an inactive RNA helicase motif, failed to inhibit viral DNA synthesis. Our interpretation is that DDX3 inhibits viral DNA synthesis at a step following ATP hydrolysis but prior to RNA unwinding. Finally, OptiPrep density gradient analysis revealed that DDX3 was incorporated into nucleocapsids, suggesting that DDX3 inhibits viral reverse transcription following nucleocapsid assembly. Thus, DDX3 represents a novel host restriction factor that limits HBV infection.

Differentially Stimulated CD4+ T Cells Display Altered Human Immunodeficiency Virus Infection Kinetics: Implications for the Efficacy of Antiviral Agents

ABSTRACT The activation state of CD4+ T cells plays a crucial role in the establishment of a productive human immunodeficiency virus infection. Here, we show that T cells stimulated for 1 day demonstrated delayed kinetics of viral reverse transcription and integration compared to cells stimulated for 2 days prior to infection. As a result, the efficiency of reverse transcription and integration inhibitors differs in these differentially stimulated cells. These studies increase our understanding of how T cells support viral replication and provide insight regarding the efficiency of antiretroviral therapy in lymphoid compartments.