Targeted disruption of the murine erythroid band 3 gene results in spherocytosis and severe haemolytic anaemia despite a normal membrane skeleton.

Band 3 is the most abundant integral protein of the red blood cell membrane. It performs two critical biological functions: maintaining ionic homeostasis, by transporting Cl- and HCO3-ions, and providing mechanical stability to the erythroid membrane. Erythroid band 3 (AE1) is one of three anion exchangers that are encoded by separate genes. The AE1 gene is transcribed by two promoters: the upstream promoter produces erythroid band 3, whereas the downstream promoter initiates transcription of the band 3 isoform in kidney. To assess the biological consequences of band 3 deficiency, we have selectively inactivated erythroid but not kidney band 3 by gene targeting in mice. Although no death in utero occurred, the majority of homozygous mice die within two weeks after birth. The erythroid band 3 null mice show retarded growth, spherocytic red blood cell morphology and severe haemolytic anaemia. Remarkably, the band 3-/- red blood cells assembled normal membrane skeleton thus challenging the notion that the presence of band 3 is required for the stable biogenesis of membrane skeleton. The availability of band 3-/- mice offers a unique opportunity to investigate the role of erythroid band 3 in the regulation of membrane-skeletal interactions, anion transport and the invasion and growth of malaria parasite into red blood cells.

Delineating minimal protein domains and promoter elements for transcriptional activation by lentivirus Tat proteins.

Lentivirus Tat proteins comprise a novel class of RNA-binding transcriptional activators that are essential for viral replication. In this study, we performed a series of protein fusion experiments to delineate the minimal protein domains and promoter elements required for Tat action. We show that a 15-amino-acid region of equine infectious anemia virus (EIAV) Tat protein, when fused to the GAL4 or LexA DNA binding domain, can activate transcription in appropriate promoter contexts. In the natural human immunodeficiency virus type 1 long terminal repeat, activation by Tat is dependent on multiple binding sites for the cellular transcription factor SP1. We delineate a 114-amino-acid region of the SP1 glutamine-rich activation domain that when fused to the GAL4 DNA binding domain can support transcription activation by Tat. Using these Tat and SP1 derivatives, we show that Tat activation can be reconstructed on a completely synthetic promoter lacking all cis-acting elements unique to the human immunodeficiency virus long terminal repeat. Our results indicate that lentivirus Tat proteins have essential properties of typical cellular transcriptional activators and define useful reagents for studying the detailed mechanism of Tat action.

The type 1 human immunodeficiency virus Tat binding protein is a transcriptional activator belonging to an additional family of evolutionarily conserved genes.

The type 1 human immunodeficiency virus Tat protein is a powerful transcriptional activator when bound to an RNA structure (TAR) present at the extreme 5' terminus of viral mRNA. Since transcriptional activation requires binding of Tat to RNA, it has been suggested that Tat enhances initiation or elongation through a direct interaction with cellular transcription factors. Here we show through protein fusion experiments that the previously identified cellular Tat binding protein, TBP-1, although unable to bind DNA, is a strong transcriptional activator when brought into proximity of several promoter elements. Transcriptional activity depends upon the integrity of at least two highly conserved domains: one resembling a nucleotide-binding motif and the other motif common to proteins with helicase activity. Our studies further reveal that TBP-1 represents one member of a large, highly conserved gene family that encodes proteins demonstrating strong amino acid conservation across species. Finally, we identified a second family member that, although 77% similar to TBP-1, does not activate transcription from the promoters examined. This finding, together with the observation that TBP-1 does not activate each promoter examined, suggests that this gene family may encode promoter-specific transcriptional activators.

The HIV-1 Tat protein activates transcription from an upstream DNA-binding site: implications for Tat function.

The Tat protein of human immunodeficiency virus type 1 (HIV-1) activates transcription following binding to nascent trans-activation response (TAR) RNA downstream of the transcription start site. Because Tat functions when bound to RNA, and in a position-dependent manner, it has been proposed that Tat works by a novel mechanism. Here, we perform a series of protein fusion experiments that reveal striking similarities between Tat and conventional cellular activators. Most significantly, we demonstrate that Tat can function when bound to upstream promoter DNA. This activity depends on a region within Tat that is also required for Tat to function when bound to TAR RNA. In contrast, the arginine-rich region of Tat, which is required for binding to TAR RNA, is dispensable for the function of DNA-bound Tat. When bound either to RNA or DNA Tat activity requires cooperation with promoter-bound cellular transcription factors. Finally, we show that Tat and a strong acidic activator stimulate transcription to comparable levels. On the basis of these and other results we suggest that Tat and acidic activators act on a similar step in the transcription process.