Possible roles of HIV-1 nucleocapsid protein in the specificity of proviral DNA synthesis and in its variability.

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it coats the dimeric RNA genome. Due to its nucleic acid binding and annealing activities, NC protein directs the annealing of the tRNA primer to the primer binding site and greatly facilitates minus strand DNA elongation and transfer while protecting the nucleic acids against nuclease degradation. To understand the role of NCp7 in viral DNA synthesis, we examined the influence of NCp7 on self-primed versus primer-specific reverse transcription. The results show that HIV-1 NCp7 can extensively inhibit self-primed reverse transcription of viral and cellular RNAs while promoting primer-specific synthesis of proviral DNA. The role of NCp7 vis-a-vis the presence of mutations in the viral DNA during minus strand elongation was examined. NCp7 maximized the annealing between a cDNA(-) primer containing one to five consecutive errors and an RNA representing the 3' end of the genome. The ability of reverse transcriptase (RT) in the presence of NCp7 to subsequently extend the mutated primers depended upon the position of the mismatch within the primer:template complex. When the mutations were at the polymerisation site, primer extension by RT in the presence of NCp7 was very high, about 40% for one mismatch and 3% for five consecutive mismatches. Mutations within the DNA primer or at its 5' end had little effect on the extension of viral DNA by RT. Taken together these results indicate that NCp7 plays major roles in proviral DNA synthesis within the virion core due to its ability to promote prime-specific proviral DNA synthesis while concurrently inhibiting non-specific reverse transcription of viral and cellular RNAs. Moreover, the observation that NCp7 enhances the incorporation of mutations during minus strand DNA elongation favours the notion that NCp7 is a factor contributing to the high mutation rate of HIV-1.

First glimpses at structure-function relationships of the nucleocapsid protein of retroviruses.

Retroviruses are a family of widespread small animal viruses about 110 nm in diameter, composed of an inner core surrounded by an outer envelope formed of a lipid bilayer of cellular origin in which are anchored viral glycoproteins. The inner core is formed by an outer shell of capsid protein molecules (CA protein) surrounding the dimeric RNA genome in close association with about 2000 molecules of nucleocapsid protein (NC protein) and molecules of reverse transcriptase (RT) and integrase (IN). Conversion of the genomic single-stranded RNA into a double-stranded proviral DNA by RT takes place in the nucleocapsid substructure and involves two DNA strand transfers to generate the long terminal repeats (LTR) required for IN-mediated integration of the proviral DNA into the cellular genome and its expression. In this review we have summarized some of the properties and functions of the nucleocapsid protein of the most intensely studied oncoretroviruses (MuLV and ASLV) and lentiviruses (HIV-1). Recent biochemical and genetic data on retroviral NC proteins have shown that this small viral protein endowed with a strong affinity for nucleic acids exhibits nucleic acid annealing and strand transfer activities and is required for the formation of infectious viral particles. These new activities of NC protein are most probably necessary at the early steps of proviral DNA synthesis. The 3-D structures of HIV-1 and MoMuLV NC proteins, deduced from NMR studies, are characterized by a central globular domain with one (MoMuLV) or two (HIV-1) zinc fingers. This should facilitate a rational approach of new anti-HIV therapies based on inhibition of NC protein functions. Due to space limitations and the very abundant literature on retroviruses, references to articles prior to the publication of the second volume of RNA Tumor Viruses in 1985 (Weiss et al., 1985) will be minimal. We also direct the reader to an excellent review which summarizes recent insights into biochemical and structural aspects of the retroviral enzymes PR, RT and IN (Katz & Skalka, 1994).

Analysis of the nucleic acid annealing activities of nucleocapsid protein from HIV-1.

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it is in tight association with genomic RNA and the tRNA primer. NC protein is necessary for the dimerization and encapsidation of genomic RNA, the annealing of the tRNA primer to the primer binding site (PBS) and the initial strand transfer event. Due to the general nature of NC protein-promoted annealing, its use to improve nucleic acid interactions in various reactions can be envisioned. Parameters affecting NC-promoted nucleic acid annealing of NCp7 from HIV-1 have been analyzed. The promotion of RNA:RNA and RNA:DNA annealing by NCp7 is more sensitive to the concentration of MgCl2 than the promotion of DNA:DNA hybridization. Stimulation of complex formation for all three complexes was efficient at 0-90 mM NaCl, between 23 and 55 degrees C and at pH values between 6.5 and 9.5, inclusive. Parameters affecting NCp7-promoted hybridization of tRNA(Lys,3) to the PBS, which appears to be specific for NC protein, will be discussed. Results implicate the basic regions of NCp7, but not the zinc fingers, in promoting the annealing of complementary nucleic acid sequences. Finally, NCp7 strand transfer activity aids the formation of the most stable nucleic acid complex.

Properties of the lysyl-tRNA synthetase gene and product from the extreme thermophile Thermus thermophilus.

A DNA region carrying lysS, the gene encoding the lysyl-tRNA synthetase, was cloned from the extreme thermophile prokaryote Thermus thermophilus VK-1 and sequenced. The analysis indicated an open reading frame encoding a protein of 492 amino acids. This putative protein has significant homologies to previously sequenced lysyl-tRNA synthetases and displays the three motifs characteristic of class II aminoacyl-tRNA synthetases. The T. thermophilus lysS gene was overexpressed in Escherichia coli by placing it downstream of the E. coli beta-galactosidase gene promoter on plasmid pBluescript and by changing the ribosome-binding site. The overproduced protein was purified by heat treatment of the crude extract followed by a single anion-exchange chromatography step. The protein obtained is remarkably thermostable, retaining nearly 60% of its initial tRNA aminoacylation activity after 5 h of incubation at 93 degrees C. Finally, lethal disruption of the lysRS genes of E. coli could not be compensated for by the addition in trans of the T. thermophilus lysS gene despite the fact that this gene was overexpressed and that its product specifically aminoacylates E. coli tRNA(Lys) in vitro.

Transactivation of the minus-strand DNA transfer by nucleocapsid protein during reverse transcription of the retroviral genome.

Two DNA strand transfers are required during reverse transcription of the RNA genome of retroviruses to complete provirus synthesis. To understand more about the first strand transfer reaction, that of the minus-strand DNA from the 5' to the 3' end of the retroviral genome, we devised an in vitro system mimicking the Moloney murine leukemia virus reverse transcription process. Two RNAs corresponding to the 5' and 3' regions of the genome were used to perform reverse transcription assays. The role of the nucleocapsid protein NCp10, which is tightly bound to the genome in the virus, was investigated in this system as well as the requirement of the 5' and 3' terminal repeats (R sequences) and the poly(A) tail. The results show that NCp10 drastically enhances the strand transfer reaction and that interactions between reverse transcriptase, nucleocapsid protein and viral RNA may be important. Both R sequences are required for an efficient and accurate DNA strand transfer and the poly(A) tail facilitates this reaction. Furthermore, it is probable that both intra- and intermolecular DNA strand transfers occur when the 5' and 3' ends of the genome are present on the same molecule.

Interactions between HIV-1 nucleocapsid protein and viral DNA may have important functions in the viral life cycle.

In the virion core of retroviruses, the genomic RNA is tightly associated with nucleocapsid (NC) protein molecules, forming the nucleocapsid structure. NC protein, a highly basic protein with two zinc fingers, is indispensable for RNA dimerization, encapsidation and the initiation of reverse transcription in avian, murine and human retroviruses. Here we show that NC protein of HIV-1 (NCp7) and NCp7 mutants bind to DNA fragments representing proviral DNA sequences, forming stable complexes. NCp7 and NCp7 mutants form high molecular weight complexes with large DNA fragments and show cooperativity in binding to the DNAs. It appears that the conserved basic residues, and not the zinc fingers, are important for complex formation. In addition, NCp7 and several NCp7 mutants protect DNAs from nuclease digestion while the DNA ends appear to be poorly protected. NCp7 has been found to bind to strong stop cDNA, the initial product of reverse transcription, and to promote the annealing of this cDNA to HIV-1 RNA corresponding to the 3' end of the genome. In addition, NCp7 slightly stimulates an in vitro IN cleavage assay. These results indicate that the interactions between NCp7 and proviral DNA may be important during provirus synthesis and/or prior to integration.

Methionyl-tRNA synthetase from Bacillus stearothermophilus: structural and functional identities with the Escherichia coli enzyme.

The metS gene encoding homodimeric methionyl-tRNA synthetase from Bacillus stearothermophilus has been cloned and a 2880 base pair sequence solved. Comparison of the deduced enzyme protomer sequence (Mr 74,355) with that of the E. coli methionyl-tRNA synthetase protomer (Mr 76,124) revealed a relatively low level (32%) of identities, although both enzymes have very similar biochemical properties (Kalogerakos, T., Dessen, P., Fayat, G. and Blanquet, S. (1980) Biochemistry 19, 3712-3723). However, all the sequence patterns whose functional significance have been probed in the case of the E. coli enzyme are found in the thermostable enzyme sequence. In particular, a stretch of 16 amino acids corresponding to the CAU anticodon binding site in the E. coli synthetase structure is highly conserved in the metS sequence. The metS product could be expressed in E. coli and purified. It showed structure-function relationships identical to those of the enzyme extracted from B. stearothermophilus cells. In particular, the patterns of mild proteolysis were the same. Subtilisin converted the native dimer into a fully active monomeric species (62 kDa), while trypsin digestion yielded an inactive form because of an additional cleavage of the 62 kDa polypeptide into two subfragments capable however of remaining firmly associated. The subtilisin cleavage site was mapped on the enzyme polypeptide, and a gene encoding the active monomer was constructed and expressed in E. coli. Finally, trypsin attack was demonstrated to cleave a peptidic bond within the KMSKS sequence common to E. coli and B. stearothermophilus methionyl-tRNA synthetases. This sequence has been shown, in the case of the E. coli enzyme, to have an essential role for the catalysis of methionyl-adenylate formation.