gpwac of the T4-type bacteriophages: structure, function, and evolution of a segmented coiled-coil protein that controls viral infectivity.

The wac gene product (gpwac) or fibritin of bacteriophage T4 forms the six fibers that radiate from the phage neck. During phage morphogenesis these whiskers bind the long tail fibers (LTFs) and facilitate their attachment to the phage baseplate. After the cell lysis, the gpwac fibers function as part of an environmental sensing device that retains the LTFs in a retracted configuration and thus prevents phage adsorption in unfavorable conditions. A comparative analysis of the sequences of 5 wac gene orthologs from various T4-type phages reveals that the approximately 50-amino-acid N-terminal domain is the only highly conserved segment of the protein. This sequence conservation is probably a direct consequence of the domain's strong and specific interactions with the neck proteins. The sequence of the central fibrous region of gpwac is highly plastic, with only the heptad periodicity of the coiled-coil structure being conserved. In the various gpwac sequences, the small C-terminal domain essential for initiation of the folding of T4 gpwac is replaced by unrelated sequences of unknown origin. When a distant T4-type phage has a novel C-terminal gpwac sequence, the phage's gp36 sequence that is located at the knee joint of the LTF invariably has a novel domain in its C terminus as well. The covariance of these two sequences is compatible with genetic data suggesting that the C termini of gpwac and gp36 engage in a protein-protein interaction that controls phage infectivity. These results add to the limited evidence for domain swapping in the evolution of phage structural proteins.

The archaeal sRNA binding protein L7Ae has a 3D structure very similar to that of its eukaryal counterpart while having a broader RNA-binding specificity.

The ribosomal L7Ae protein of archaea has the peculiarity to be a component of the C/D and H/ACA snRNPs, that guide rRNA post-transcriptional modifications. Its yeast (Snu13p) and human (15.5kDa protein) homologs are only found in C/D snoRNPs and the (U4/U6, U5) spliceosomal tri-snRNP. By using a large variety of RNAs, we compared the RNA-binding specificities of the recombinant Pyrococcus abyssi L7Ae and Saccharomyces cerevisiae Snu13 proteins. Unlike Snu13p, protein L7Ae binds terminal loops closed by two A:G and G:A pairs and canonical K-turn structures with similar efficiencies, provided that the terminal loop contains at least 5nt. In contrast to Snu13p, binding of protein L7Ae to canonical K-turn structures is not dependent on the identity of the residue at position 2 in the bulge. The peculiar KT-15 motif of P. abyssi 23S rRNA, that is recognized by L7Ae, does not associate with Snu13p. To get more information on the P. abyssi L7Ae protein, we solved its X-ray structure at 1.9A resolution. In spite of their sequence divergence, the free P. abyssi and bound H. marismortui proteins were found to have highly similar structures. Only a limited number of side-chain conformational changes occur at the protein-RNA interface upon RNA binding. In particular, one ion pair that is formed by residues Glu43 and Lys46 in the free protein is disrupted in the ribosomal 50S subunit, so that, residue Glu43 can interact with the RNA residue G264. The Glu43-Lys46 ion pair of protein L7Ae belongs to a complex network of ion pairs that may participate to protein thermostability.

RNA-binding strategies common to cold-shock domain- and RNA recognition motif-containing proteins.

Numerous RNA-binding proteins have modular structures, comprising one or several copies of a selective RNA-binding domain generally coupled to an auxiliary domain that binds RNA non-specifically. We have built and compared homology-based models of the cold-shock domain (CSD) of the Xenopus protein, FRGY2, and of the third RNA recognition motif (RRM) of the ubiquitous nucleolar protein, nucleolin. Our model of the CSD(FRG)-RNA complex constitutes the first prediction of the three-dimensional structure of a CSD-RNA complex and is consistent with the hypothesis of a convergent evolution of CSD and RRM towards a related single-stranded RNA-binding surface. Circular dichroism spectroscopy studies have revealed that these RNA-binding domains are capable of orchestrating similar types of RNA conformational change. Our results further show that the respective auxiliary domains, despite their lack of sequence homology, are functionally equivalent and indispensable for modulating the properties of the specific RNA-binding domains. A comparative analysis of FRGY2 and nucleolin C-terminal domains has revealed common structural features representing the signature of a particular type of auxiliary domain, which has co-evolved with the CSD and the RRM.

From genetic to structural characterization of a new class of RNA-binding domain within the SacY/BglG family of antiterminator proteins.

SacY is the prototype of a family of regulatory proteins able to prevent transcription termination. It interacts with a 29 nucleotide RNA sequence able to fold into a stem-loop structure and partially overlapping with a terminator sequence located in the 5' leader mRNA region of the gene it controls. We show here that the N-terminal fragment of SacY, SacY(1-55), and the corresponding fragments of other members of the family have antiterminator activities with efficiency and specificity identical to those of the full-length proteins. In vitro, this activity correlates with the specific affinity of SacY(1-55) for its RNA target. UV melting experiments demonstrate that SacY(1-55) binding stabilizes the RNA target structure. The NMR solution structure of SacY(1-55) is very similar to that obtained in the crystal (van Tilbeurgh et al., 1997): the peptide is folded as a symmetrical dimer without any structural homology with other RNA-binding domains yet characterized. According to a preliminary NMR analysis of the SacY(1-55)-RNA complex, the protein dimer is not disrupted upon RNA binding and several residues implicated in RNA recognition are located at the edge of the dimer interface. This suggests a new mode of protein-RNA interaction.

Crystal structure of a new RNA-binding domain from the antiterminator protein SacY of Bacillus subtilis.

SacY belongs to a family of, at present, seven bacterial transcriptional antiterminators. The RNA-binding and antitermination capacity of SacY resides in the 55 amino acids at the N-terminal [SacY(1-55)]. The crystal structure at 2 A resolution shows that SacY(1-55) forms a dimer in the crystal, in accordance with the NMR solution structure. The structure of the monomer is a four-stranded beta-sheet with a simple beta1beta2beta3beta4 topology. One side of the sheet is covered by a long surface loop and the other side forms the dimer interface. The dimer is stabilized by the orthogonal stacking of the two beta-sheets. The crystal structure is in excellent agreement with the NMR solution structure (r.m.s. distance for C alpha coordinates is 1.3 A). The structure of SacY(1-55) reveals a new RNA-binding motif.

Crystallization of the RNA-binding domain of the transcriptional antiterminator protein SacY from Bacillus subtilis.

SacY is the antiterminator protein involved in the induction by sucrose of the expression of the levansucrase gene (sacB) of Bacillus subtilis. In the presence of sucrose, SacY is activated and prevents premature termination of transcription by binding to a RNA-antiterminator (RAT) sequence partially overlapping with the terminator sequence. SacY consists of a RNA-binding N-terminal domain, SacY(1-55), and a regulatory domain, SacY(56-280), sensitive to the sucrose concentration. SacY(1-55) is in itself capable of binding to the RAT sequence and preventing termination independently of the sucrose concentration. In this paper we describe the overexpression, the purification, and the crystallization of SacY(1-55). We obtained six different crystal forms, some of them diffracting to high resolution (> 1.5 A). Self rotation function calculations indicated the presence of a dimer in the asymmetric unit, which is in agreement with a proposed oligomeric state in solution as observed by high-resolution NMR measurements. The crystallization of some site-directed cysteine mutants opens the way of solving the structure by multiple isomorphous replacement.