B M Peterlin

INTERACTIONS BETWEEN THE CLASS II TRANSACTIVATOR AND CREB BINDING PROTEIN INCREASE TRANSCRIPTION OF MAJOR HISTOCOMPATIBILITY COMPLEX CLASS II GENES

ABSTRACT Class II major histocompatibility (class II) genes are regulated in a B-cell-specific and gamma interferon-inducible fashion. The master switch for the expression of these genes is the class II transactivator (CIITA). In this report, we demonstrate that one of the functions of CIITA is to recruit the CREB binding protein (CBP) to class II promoters. Not only functional but also specific binding interactions between CIITA and CBP were demonstrated. Moreover, a dominant negative form of CBP decreased the activity of class II promoters and levels of class II determinants on the surface of cells. Finally, the inhibition of class II gene expression by the glucocorticoid hormone could be attributed to the squelching of CBP by the glucocorticoid receptor. We conclude that CBP, a histone acetyltransferase, plays an important role in the transcription of class II genes.

The human immunodeficiency virus transactivator Tat interacts with the RNA polymerase II holoenzyme.

The human immunodeficiency virus (HIV) encodes a transcriptional transactivator (Tat), which binds to an RNA hairpin called the transactivation response element (TAR) that is located downstream of the site of initiation of viral transcription. Tat stimulates the production of full-length viral transcripts by RNA polymerase II (pol II). In this study, we demonstrate that Tat coimmunoprecipitates with the pol II holoenzyme in cells and that it binds to the purified holoenzyme in vitro. Furthermore, Tat affinity chromatography purifies a holoenzyme from HeLa nuclear extracts which, upon addition of TBP and TFIIB, supports Tat transactivation in vitro, indicating that it contains all the cellular proteins required for the function of Tat. By demonstrating that Tat interacts with the holoenzyme in the absence of TAR, our data suggest a single-step assembly of Tat and the transcription complex on the long terminal repeat of HIV.

Interaction between P-TEFb and the C-Terminal Domain of RNA Polymerase II Activates Transcriptional Elongation from Sites Upstream or Downstream of Target Genes

ABSTRACT Transcriptional elongation by RNA polymerase II (RNAPII) is regulated by the positive transcription elongation factor b (P-TEFb). P-TEFb is composed of Cdk9 and C-type cyclin T1 (CycT1), CycT2a, CycT2b, or CycK. The role of the C-terminal region of CycT1 and CycT2 remains unknown. In this report, we demonstrate that these sequences are essential for the activation of transcription by P-TEFb via DNA, i.e., when CycT1 is tethered upstream or downstream of promoters and coding sequences. A histidine-rich stretch, which is conserved between CycT1 and CycT2 in this region, bound the C-terminal domain of RNAPII. This binding was required for the subsequent expression of full-length transcripts from target genes. Thus, P-TEFb could mediate effects of enhancers on the elongation of transcription.

Mutational analysis of the DRA promoter: cis-acting sequences and trans-acting factors.

Class II major histocompatibility genes are expressed at high levels in B lymphocytes and are gamma interferon (IFN-gamma) inducible in many other cells. Previously, we observed that DRA promoter sequences from positions -150 to +31 determine the tissue specificity of this class II gene. Moreover, Z and X boxes located between positions -145 and -87 conferred B-cell specificity and IFN-gamma inducibility upon a heterologous promoter. In this study, sequences from positions -145 to -35 in the DRA promoter were systematically mutated by using oligonucleotide cassettes. Z (-131 to -125), pyrimidine (-116 to -109), X (-108 to -95), Y (-73 to -61), and octamer (-52 to -45) boxes were required for B-cell specificity and, with the exception of the octamer box, for IFN-gamma inducibility. Z box and sequences flanking Z and X boxes helped to determine low levels of expression in T and uninduced cells. In phenotypically distinct cells, shared and distinct proteins bound to these conserved upstream sequences. However, few correlations between expression and DNA-binding proteins could be made. Similar proteins bound to Z and X boxes, and the Z box most likely represents a duplication of the X box.

Molecular Biology of HIV

This chapter deals with the molecular biology of human and simian immunodeficiency viruses (HIV-1, HIV-2, SIV) (Myers et al., 1993; see also Fultz, 1994; Chapter 1, this volume). They belong to the lentivirus genus of the Retroviridae family and cause acquired immunodeficiency syndrome (AIDS) in humans and monkeys (Coffin, 1992; Gardner et al., 1994). Since their genomes contain many open reading frames (ORFs) and since they evolved complex regulatory pathways, they are also called complex retroviruses [as contrasted with simple retroviruses like murine leukemia virus (MuLV)] (Cullen, 1991; Luciw and Leung, 1992). Most data are presented on HIV-1, which is simply called HIV. However, when necessary, examples from HIV-2 and SIV are included. The chapter starts out with the provirus integrated into the host genome, where the provirus behaves like a regular eukaryotic gene. The chapter follows viral transcription, the creation of new virions, their attachment and entry into CD4+ cells, and concludes with reverse transcription and integration of the provirus into the cellular DNA. Along this journey, structures and functions of viral proteins are highlighted.

Analysis of Ankyrin Repeats Reveals How a Single Point Mutation in RFXANK Results in Bare Lymphocyte Syndrome

ABSTRACT Ankyrin repeats are well-known structural modules that mediate interactions between a wide spectrum of proteins. The regulatory factor X with ankyrin repeats (RFXANK) is a subunit of a tripartite RFX complex that assembles on promoters of major histocompatibility complex class II (MHC II) genes. Although it is known that RFXANK plays a central role in the nucleation of RFX, it was not clear how its ankyrin repeats mediate the interactions within the complex and with other proteins. To answer this question, we modeled the RFXANK protein and determined the variable residues of the ankyrin repeats that should contact other proteins. Site-directed alanine mutagenesis of these residues together with in vitro and in vivo binding studies elucidated how RFXAP and CIITA, which simultaneously interact with RFXANK in vivo, bind to two opposite faces of its ankyrin repeats. Moreover, the binding of RFXAP requires two separate surfaces on RFXANK. One of them, which is located in the ankyrin groove, is severely affected in the FZA patient with the bare lymphocyte syndrome. This genetic disease blocks the expression of MHC II molecules on the surface of B cells. By pinpointing the interacting residues of the ankyrin repeats of RFXANK, the mechanism of this subtype of severe combined immunodeficiency was revealed.

Mutations in the Bare Lymphocyte Syndrome Define Critical Steps in the Assembly of the Regulatory Factor X Complex

ABSTRACT The regulatory factor X (RFX) complex, which contains RFXANK(B), RFXAP, and RFX5, binds to X and S boxes in major histocompatibility complex class II (MHC II) promoters. In the bare lymphocyte syndrome (BLS), which is a human severe combined immunodeficiency, MHC II promoters are neither occupied nor transcribed. Thus, the absence of any one subunit prevents the formation of the RFX complex. Nevertheless, except for a weak binding between RFX5 and RFXAP, no other interactions between RFX proteins have been described. In this study, we demonstrate that RFXANK(B) binds to RFXAP to form a scaffold for the assembly of the RFX complex, which then binds to DNA. Moreover, mutant RFXANK(B) and RFXAP proteins from complementation groups B and D of BLS, respectively, cannot support this interaction. Our data elucidate an intriguing medical situation, where a genetic disease targets two different surfaces that are required for the nucleation of a multisubunit DNA-protein complex.

Interactions between Equine Cyclin T1, Tat, and TAR Are Disrupted by a Leucine-to-Valine Substitution Found in Human Cyclin T1

ABSTRACT Transcriptional transactivators (Tat) from human immunodeficiency and equine infectious anemia viruses (HIV and EIAV) interact with their transactivation response elements (TAR) to increase the rates of viral transcription. Whereas the human cyclin T1 is required for the binding of Tat to TAR from HIV, it is unknown how Tat from EIAV interacts with its TAR. Furthermore, Tat from EIAV functions in equine and canine cells but not in human cells. In this study, we present sequences of cyclins T1 from horse and dog and demonstrate that their N-terminal 300 residues rescue the transactivation of Tat from EIAV in human cells. Although human and equine cyclins T1 bind to this Tat, only the equine cyclin T1 supports the binding of Tat to TAR from EIAV. Finally, a reciprocal exchange of the valine for the leucine at position 29 in human and equine cyclins T1, respectively, renders the human cyclin T1 active and the equine cyclin T1 inactive for Tat transactivation from EIAV. Thus, the collaboration between a specific cyclin T1 and Tat for their high-affinity interaction with TAR is a common theme of lentiviral transactivation.

Binding of Tat to TAR and Recruitment of Positive Transcription Elongation Factor b Occur Independently in Bovine Immunodeficiency Virus

ABSTRACT Transcriptional transactivators (Tat) from many lentiviruses interact with their cognate transactivation response RNA structures (TAR) to increase rates of elongation rather than initiation of transcription. For several of them, the complex of Tat and a species-specific cyclin T1 must be formed before the binding to TAR can occur with high affinity and specificity. In sharp contrast, Tat from the bovine immunodeficiency virus (BIV) binds to its TAR without the help of the cyclin T1. This binding depends on the upper stem and 5′ bulge, but not the central loop in TAR. Moreover, cyclins T1 from different species can mediate effects of this Tat in cells. Unlike the situation with other lentiviruses, Tat transactivation can be rescued simply by linking a heterologous promoter to TAR in permissive cells. Thus, lentiviruses have evolved different strategies to recruit Tat and the positive transcription elongation factor b to their promoters, and interactions between Tat and TAR are independent from those between Tat and the cyclin T1 in BIV.

Transcriptional enhancers in the HLA-DQ subregion.

Using transient expression assays, the HLA-DQ alpha and HLA-DQ beta genes of the human major histocompatibility complex were screened for cis-acting regulatory elements. Two regions in the HLA-DQ alpha gene and one in the HLA-DQ beta gene were identified which fulfilled the criteria for transcriptional enhancers.