An evolutionary conserved Hexim1 peptide binds to the Cdk9 catalytic site to inhibit P-TEFb.

The positive transcription elongation factor (P-TEFb) is required for the transcription of most genes by RNA polymerase II. Hexim proteins associated with 7SK RNA bind to P-TEFb and reversibly inhibit its activity. P-TEFb comprises the Cdk9 cyclin-dependent kinase and a cyclin T. Hexim proteins have been shown to bind the cyclin T subunit of P-TEFb. How this binding leads to inhibition of the kinase activity of Cdk9 has remained elusive, however. Using a photoreactive amino acid incorporated into proteins, we show that in live cells, cell extracts, and in vitro reconstituted complexes, Hexim1 cross-links and thus contacts Cdk9. Notably, replacement of a phenylalanine, F208, belonging to an evolutionary conserved Hexim1 peptide (202PYNTTQFLM210) known as the "PYNT" sequence, cross-links a peptide within the activation segment that controls access to the Cdk9 catalytic cleft. Reciprocally, Hexim1 is cross-linked by a photoreactive amino acid replacing Cdk9 W193, a tryptophan within this activation segment. These findings provide evidence of a direct interaction between Cdk9 and its inhibitor, Hexim1. Based on similarities with Cdk2 3D structure, the Cdk9 peptide cross-linked by Hexim1 corresponds to the substrate binding-site. Accordingly, the Hexim1 PYNT sequence is proposed to interfere with substrate binding to Cdk9 and thereby to inhibit its kinase activity.

Association of human mitochondrial lysyl-tRNA synthetase with HIV-1 GagPol does not require other viral proteins.

In human, the cytoplasmic (cLysRS) and mitochondrial (mLysRS) species of lysyl-tRNA synthetase are encoded by a single gene. Following HIV-1 infection, mLysRS is selectively taken up into viral particles along with the three tRNALys isoacceptors. The GagPol polyprotein precursor is involved in this process. With the aim to reconstitute in vitro the HIV-1 tRNA3Lys packaging complex, we first searched for the putative involvement of another viral protein in the selective viral hijacking of mLysRS only. After screening all the viral proteins, we observed that Vpr and Rev have the potential to interact with mLysRS, but that this association does not take place at the level of the assembly of mLysRS into the packaging complex. We also show that tRNA3Lys can form a ternary complex with the two purified proteins mLysRS and the Pol domain of GagPol, which mimicks its packaging complex.

A Cyclin T1 point mutation that abolishes positive transcription elongation factor (P-TEFb) binding to Hexim1 and HIV tat.

BACKGROUND: The positive transcription elongation factor b (P-TEFb) plays an essential role in activating HIV genome transcription. It is recruited to the HIV LTR promoter through an interaction between the Tat viral protein and its Cyclin T1 subunit. P-TEFb activity is inhibited by direct binding of its subunit Cyclin T (1 or 2) with Hexim (1 or 2), a cellular protein, bound to the 7SK small nuclear RNA. Hexim1 competes with Tat for P-TEFb binding. RESULTS: Mutations that impair human Cyclin T1/Hexim1 interaction were searched using systematic mutagenesis of these proteins coupled with a yeast two-hybrid screen for loss of protein interaction. Evolutionary conserved Hexim1 residues belonging to an unstructured peptide located N-terminal of the dimerization domain, were found to be critical for P-TEFb binding. Random mutagenesis of the N-terminal region of Cyclin T1 provided identification of single amino-acid mutations that impair Hexim1 binding in human cells. Furthermore, conservation of critical residues supported the existence of a functional Hexim1 homologue in nematodes. CONCLUSIONS: Single Cyclin T1 amino-acid mutations that impair Hexim1 binding are located on a groove between the two cyclin folds and define a surface overlapping the HIV-1 Tat protein binding surface. One residue, Y175, in the centre of this groove was identified as essential for both Hexim1 and Tat binding to P-TEFb as well as for HIV transcription.

Activation of human mitochondrial lysyl-tRNA synthetase upon maturation of its premitochondrial precursor.

The cytoplasmic and mitochondrial species of human lysyl-tRNA synthetase are encoded by a single gene by means of alternative splicing of the KARS1 gene. The cytosolic enzyme possesses a eukaryote-specific N-terminal polypeptide extension that confers on the native enzyme potent tRNA binding properties required for the vectorial transfer of tRNA from the synthetase to elongation factor EF1A within the eukaryotic translation machinery. The mitochondrial enzyme matures from its precursor upon being targeted to that organelle. To understand how the cytosolic and mitochondrial enzymes are adapted to participate in two distinct translation machineries, of eukaryotic or bacterial origin, we characterized the mitochondrial LysRS species. Here we report that cleavage of the precursor of mitochondrial LysRS leads to a mature enzyme with reduced tRNA binding properties compared to those of the cytoplasmic counterpart. This adaptation mechanism may prevent inhibition of translation through sequestration of lysyl-tRNA on the synthetase in a compartment where the bacterial-like elongation factor EF-Tu could not assist in its dissociation from the synthetase. We also observed that the RxxxKRxxK tRNA-binding motif of mitochondrial LysRS is not functional in the precursor form of that enzyme and becomes operational after cleavage of the mitochondrial targeting sequence. The finding that maturation of the precursor is needed to reveal the potent tRNA binding properties of this enzyme has strong implications for the spatiotemporal regulation of its activities and is consistent with previous studies suggesting that the only LysRS species able to promote packaging of tRNA(Lys) into HIV-1 viral particles is the mature form of the mitochondrial enzyme.

Association of mitochondrial Lysyl-tRNA synthetase with HIV-1 GagPol involves catalytic domain of the synthetase and transframe and integrase domains of Pol.

Cytosolic and mitochondrial lysyl-tRNA synthetases (LysRS) are encoded by a single gene and can be distinguished only according to their very N-terminal sequences. It was believed that cytosolic LysRS is packaged into HIV-1 virions via its association with Gag. Using monospecific antibodies, it was later shown that only the mitochondrial LysRS is taken up in viral particles along with tRNA(3)(Lys), the primer for reverse transcription of the HIV-1 genome. In this work, we re-analyzed the interaction between LysRS and GagPol to determine whether the particular N-terminal sequence of mitochondrial LysRS triggers a specific recognition with GagPol, or if differential routing of the two LysRS species in vivo could explain specific and exclusive packaging of the mitochondrial species. Here, we show that LysRS associates with the Pol domain of GagPol. More specifically, the transframe (TF or p6) and integrase (IN) domain proteins of Pol interact with the catalytic domain of LysRS. A model of the assembly of the LysRS-tRNA(3)(Lys)-GagPol packaging complex is proposed, which is consistent with the release of its different components after maturation of GagPol in the virions. The cytoplasmic and mitochondrial LysRS species share an identical catalytic domain. Accordingly, we found that both enzymes have the intrinsic capacity to bind to GagPol in vitro. In addition, both enzymes interact with p38 in vitro, the scaffold protein of the cytoplasmic multi-aminoacyl-tRNA synthetase complex, even though only the cytoplasmic species of LysRS is a bona fide component of this complex. These results suggest that the different LysRS species are strictly targeted in vivo, and open new perspectives for the search of a new class of inhibitors of the HIV-1 development cycle that would block the packaging of tRNA(3)(Lys) into viral particles.