Marina Lusic

Regulation of HIV-1 gene expression by histone acetylation and factor recruitment at the LTR promoter

In HIV‐1 infected cells, the LTR promoter, once organized into chromatin, is transcriptionally inactive in the absence of stimulation. To examine the chromosomal events involved in transcriptional activation, we analyzed histone acetylation and factor recruitment at contiguous LTR regions by a quantitative chromatin immunoprecipitation assay. In chronically infected cells treated with a phorbol ester, we found that acetylation of both histones H3 and H4 occurs at discrete nucleosomal regions before the onset of viral mRNA transcription. Concomitantly, we observed the recruitment of known cellular acetyl‐transferases to the promoter, including CBP, P/CAF and GCN5, as well as that of the p65 subunit of NF‐κB. The specific contribution of the viral Tat transactivator was assayed in cells harboring the sole LTR. We again observed nucleosomal acetylation and the recruitment of specific co‐factors to the viral LTR upon activation by either recombinant Tat or a phorbol ester. Strikingly, P/CAF was found associated with the promoter only in response to Tat. Taken together, these results contribute to the elucidation of the molecular events underlying HIV‐1 transcriptional activation.

Acetylation of HIV-1 integrase by p300 regulates viral integration

Integration of HIV‐1 into the human genome, which is catalyzed by the viral protein integrase (IN), preferentially occurs near transcriptionally active genes. Here we show that p300, a cellular acetyltransferase that regulates chromatin conformation through the acetylation of histones, also acetylates IN and controls its activity. We have found that p300 directly binds IN both in vitro and in the cells, as also specifically demonstrated by fluorescence resonance energy transfer technique analysis. This interaction results in the acetylation of three specific lysines (K264, K266, K273) in the carboxy‐terminus of IN, a region that is required for DNA binding. Acetylation increases IN affinity to DNA, and promotes the DNA strand transfer activity of the protein. In the context of the viral replication cycle, point mutations in the IN acetylation sites abolish virus replication by specifically impairing its integration capacity. This is the first demonstration that HIV‐1 IN activity is specifically regulated by post‐translational modification.

Nuclear architecture dictates HIV-1 integration site selection

Long-standing evidence indicates that human immunodeficiency virus type 1 (HIV-1) preferentially integrates into a subset of transcriptionally active genes of the host cell genome. However, the reason why the virus selects only certain genes among all transcriptionally active regions in a target cell remains largely unknown. Here we show that HIV-1 integration occurs in the outer shell of the nucleus in close correspondence with the nuclear pore. This region contains a series of cellular genes, which are preferentially targeted by the virus, and characterized by the presence of active transcription chromatin marks before viral infection. In contrast, the virus strongly disfavours the heterochromatic regions in the nuclear lamin-associated domains and other transcriptionally active regions located centrally in the nucleus. Functional viral integrase and the presence of the cellular Nup153 and LEDGF/p75 integration cofactors are indispensable for the peripheral integration of the virus. Once integrated at the nuclear pore, the HIV-1 DNA makes contact with various nucleoporins; this association takes part in the transcriptional regulation of the viral genome. These results indicate that nuclear topography is an essential determinant of the HIV-1 life cycle.

Transcription-dependent gene looping of the HIV-1 provirus is dictated by recognition of pre-mRNA processing signals.

Summary HIV-1 provirus, either as a chromosomal integrant or as an episomal plasmid in HeLa cells, forms a transcription-dependent gene loop structure between the 5′LTR promoter and 3′LTR poly(A) signal. Flavopiridol-mediated inhibition of RNA polymerase II elongation blocks 5′ to 3′LTR juxtaposition, indicating that this structure is maintained during transcription. Analysis of mutant or hybrid HIV-1 plasmids demonstrates that replacement of the 5′LTR promoter with CMV or the 3′LTR poly(A) signal with a synthetic element (SPA) permits gene loop formation, suggesting that these interactions are not retroviral specific. In addition, activation of the 5′LTR poly(A) signal or inactivation of the 3′LTR poly(A) signal abolishes gene loop formation. Overall, we demonstrate that both ongoing transcription and pre-mRNA processing are essential for gene loop formation, and predict that these structures represent a defining feature of active gene transcription.

Acetylation of Conserved Lysines in the Catalytic Core of Cyclin-Dependent Kinase 9 Inhibits Kinase Activity and Regulates Transcription

ABSTRACT Promoter clearance and transcriptional processivity in eukaryotic cells are fundamentally regulated by the phosphorylation of the carboxy-terminal domain of RNA polymerase II (RNAPII). One of the kinases that essentially performs this function is P-TEFb (positive transcription elongation factor b), which is composed of cyclin-dependent kinase 9 (CDK9) associated with members of the cyclin T family. Here we show that cellular GCN5 and P/CAF, members of the GCN5-related N-acetyltransferase family of histone acetyltransferases, regulate CDK9 function by specifically acetylating the catalytic core of the enzyme and, in particular, a lysine that is essential for ATP coordination and the phosphotransfer reaction. Acetylation markedly reduces both the kinase function and transcriptional activity of P-TEFb. In contrast to unmodified CDK9, the acetylated fraction of the enzyme is specifically found in the insoluble nuclear matrix compartment. Acetylated CDK9 associates with the transcriptionally silent human immunodeficiency virus type 1 provirus; upon transcriptional activation, it is replaced by the unmodified form, which is involved in the elongating phase of transcription marked by Ser2-phosphorylated RNAPII. Given the conservation of the CDK9 acetylated residues in the catalytic task of virtually all CDK proteins, we anticipate that this mechanism of regulation might play a broader role in controlling the function of other members of this kinase family.

The TRIM Family Protein KAP1 Inhibits HIV-1 Integration

The integration of viral cDNA into the host genome is a critical step in the life cycle of HIV-1. This step is catalyzed by integrase (IN), a viral enzyme that is positively regulated by acetylation via the cellular histone acetyl transferase (HAT) p300. To investigate the relevance of IN acetylation, we searched for cellular proteins that selectively bind acetylated IN and identified KAP1, a protein belonging to the TRIM family of antiviral proteins. KAP1 binds acetylated IN and induces its deacetylation through the formation of a protein complex which includes the deacetylase HDAC1. Modulation of intracellular KAP1 levels in different cell types including T cells, the primary HIV-1 target, revealed that KAP1 curtails viral infectivity by selectively affecting HIV-1 integration. This study identifies KAP1 as a cellular factor restricting HIV-1 infection and underscores the relevance of IN acetylation as a crucial step in the viral infectious cycle.

Concerted action of cellular JNK and Pin1 restricts HIV-1 genome integration to activated CD4+ T lymphocytes

Long-standing evidence indicates that quiescent human peripheral blood T lymphocytes (PBLs) do not support efficient HIV infection. In resting PBLs, reverse transcription of viral RNA takes longer than in activated cells, partially because formation of the late products of reverse transcription is decreased by RNA binding by apolipoprotein B mRNA–editing enzyme, catalytic polypeptide-like 3G (APOBEC3G). In a subsequent step, integration of the viral complementary DNA that is eventually formed is markedly impaired. Here we show that cellular c-Jun N-terminal kinase (JNK), an enzyme that is not expressed in resting CD4+ T cells, regulates permissiveness to HIV-1 infection, and we unravel a new, sequential post-translational pathway of protein modification that regulates viral DNA integration. We found that, in activated T lymphocytes, viral integrase, which mediates HIV-1 cDNA integration into the host cell genome, is phosphorylated by JNK on a highly conserved serine residue in its core domain. Phosphorylated integrase, in turn, becomes a substrate for the cellular peptidyl prolyl-isomerase enzyme Pin1, which catalyzes a conformational modification of integrase. These concerted activities increase integrase stability and are required for efficient HIV-1 integration and infection. Lack of these modifications restricts viral infection in nonactivated, primary CD4+ T lymphocytes.

Recruitment of human cyclin T1 to nuclear bodies through direct interaction with the PML protein

Human cyclin T1, the cyclin partner of Cdk9 kinase in the positive transcription elongation factor b (P‐TEFb), is an essential cellular cofactor that is recruited by the human immunodeficiency virus type 1 (HIV‐1) Tat transactivator to promote transcriptional elongation from the HIV‐1 long terminal repeat (LTR). Here we exploit fluorescence resonance energy transfer (FRET) to demonstrate that cyclin T1 physically interacts in vivo with the promyelocytic leukaemia (PML) protein within specific subnuclear compartments that are coincident with PML nuclear bodies. Deletion mutants at the C‐terminal region of cyclin T1 are negative for FRET with PML and fail to localize to nuclear bodies. Cyclin T1 and PML are also found associated outside of nuclear bodies, and both proteins are present at the chromatinized HIV‐1 LTR promoter upon Tat transactivation. Taken together these results suggest that PML proteins regulate Tat‐ mediated transcriptional activation by modulating the availability of cyclin T1 and other essential cofactors to the transcription machinery.

Proximity to PML Nuclear Bodies Regulates HIV-1 Latency in CD4+ T Cells

Nuclear bodies (NBs), characterized by the presence of the promyelocytic leukemia (PML) protein, are important components of the nuclear architecture, contributing to genetic and epigenetic control of gene expression. In investigating the mechanisms mediating HIV-1 latency, we determined that silenced but transcriptionally competent HIV-1 proviruses reside in close proximity to PML NBs and that this association inhibits HIV-1 gene expression. PML binds to the latent HIV-1 promoter, which coincides with transcriptionally inactive facultative heterochromatic marks, notably H3K9me2, at the viral genome. PML degradation and NB disruption result in strong activation of viral transcription as well as release of G9a, the major methyltransferase responsible for H3K9me2, and loss of facultative heterochromatin marks from the proviral DNA. Additionally, HIV-1 transcriptional activation requires proviral displacement from PML NBs by active nuclear actin polymerization. Thus, nuclear topology and active gene movement mediate HIV-1 transcriptional regulation and have implications for controlling HIV-1 latency and eradication.

Transcriptional competence of the integrated HIV‐1 provirus at the nuclear periphery

Spatial distribution of genes within the nucleus contributes to transcriptional control, allowing optimal gene expression as well as constitutive or regulated gene repression. Human immunodeficiency virus type 1 (HIV‐1) integrates into host chromatin to transcribe and replicate its genome. Lymphocytes harbouring a quiescent but inducible provirus are a challenge to viral eradication in infected patients undergoing antiviral therapy. Therefore, our understanding of the contribution of sub‐nuclear positioning to viral transcription may also have far‐reaching implications in the pathology of the infection. To gain an insight into the conformation of chromatin at the site of HIV‐1 integration, we investigated lymphocytes carrying a single latent provirus. In the silenced state, the provirus was consistently found at the nuclear periphery, associated in trans with a pericentromeric region of chromosome 12 in a significant number of quiescent cells. After induction of the transcription, this association was lost, although the location of the transcribing provirus remained peripheral. These results, extended to several other cell clones, unveil a novel mechanism of transcriptional silencing involved in HIV‐1 post‐transcriptional latency and reinforce the notion that gene transcription may also occur at the nuclear periphery.