Carlos Fernández-Tornero

A novel solenoid fold in the cell wall anchoring domain of the pneumococcal virulence factor LytA.

Choline binding proteins are virulence determinants present in several Gram-positive bacteria. Because anchorage of these proteins to the cell wall through their choline binding domain is essential for bacterial virulence, their release from the cell surface is considered a powerful target for a weapon against these pathogens. The first crystal structure of a choline binding domain, from the toxin-releasing enzyme pneumococcal major autolysin (LytA), reveals a novel solenoid fold consisting exclusively of β-hairpins that stack to form a left-handed superhelix. This unique structure is maintained by choline molecules at the hydrophobic interface of consecutive hairpins and may be present in other choline binding proteins that share high homology to the repeated motif of the domain.

A systematic screen for protein–lipid interactions in Saccharomyces cerevisiae

Protein–metabolite networks are central to biological systems, but are incompletely understood. Here, we report a screen to catalog protein–lipid interactions in yeast. We used arrays of 56 metabolites to measure lipid‐binding fingerprints of 172 proteins, including 91 with predicted lipid‐binding domains. We identified 530 protein–lipid associations, the majority of which are novel. To show the data sets biological value, we studied further several novel interactions with sphingolipids, a class of conserved bioactive lipids with an elusive mode of action. Integration of live‐cell imaging suggests new cellular targets for these molecules, including several with pleckstrin homology (PH) domains. Validated interactions with Slm1, a regulator of actin polarization, show that PH domains can have unexpected lipid‐binding specificities and can act as coincidence sensors for both phosphatidylinositol phosphates and phosphorylated sphingolipids.

Crystal structure of the 14-subunit RNA polymerase I

Protein biosynthesis depends on the availability of ribosomes, which in turn relies on ribosomal RNA production. In eukaryotes, this process is carried out by RNA polymerase I (Pol I), a 14-subunit enzyme, the activity of which is a major determinant of cell growth. Here we present the crystal structure of Pol I from Saccharomyces cerevisiae at 3.0 Å resolution. The Pol I structure shows a compact core with a wide DNA-binding cleft and a tightly anchored stalk. An extended loop mimics the DNA backbone in the cleft and may be involved in regulating Pol I transcription. Subunit A12.2 extends from the A190 jaw to the active site and inserts a transcription elongation factor TFIIS-like zinc ribbon into the nucleotide triphosphate entry pore, providing insight into the role of A12.2 in RNA cleavage and Pol I insensitivity to α-amanitin. The A49–A34.5 heterodimer embraces subunit A135 through extended arms, thereby contacting and potentially regulating subunit A12.2.

Sperm Coating Mechanism from the 1.8 A Crystal Structure of Pdc-109-Phosphorylcholine Complex

Bovine seminal plasma PDC-109 binds to sperm surface choline lipids and promotes sperm capacitation by stimulating the efflux of cholesterol and phospholipids. The structure of PDC-109 with bound phosphorylcholine was solved using MAD data of a single platinum site. Its two globular (40 x 50 x 20 A(3)) Fn2 domains are linked and clustered by a short polypeptide. The choline binding sites lie at the same face of the molecule. Phosphorylcholine binds to the Fn2 domains through a cation-pi interaction between the quaternary ammonium group and a core tryptophan, plus hydrogen bonding between hydroxyls of exposed tyrosines and the phosphate group. The structure of the PDC-109-oPC complex provides a structural ground for the sperm membrane-coating mechanism underlying PDC-109-induced capacitation.

The Histone Fold Subunits of Drosophila Chrac Facilitate Nucleosome Sliding Through Dynamic DNA Interactions.

ABSTRACT The chromatin accessibility complex (CHRAC) is an abundant, evolutionarily conserved nucleosome remodeling machinery able to catalyze histone octamer sliding on DNA. CHRAC differs from the related ACF complex by the presence of two subunits with molecular masses of 14 and 16 kDa, whose structure and function were not known. We determined the structure of Drosophila melanogaster CHRAC14-CHRAC16 by X-ray crystallography at 2.4-Å resolution and found that they dimerize via a variant histone fold in a typical handshake structure. In further analogy to histones, CHRAC14-16 contain unstructured N- and C-terminal tail domains that protrude from the handshake structure. A dimer of CHRAC14-16 can associate with the N terminus of ACF1, thereby completing CHRAC. Low-affinity interactions of CHRAC14-16 with DNA significantly improve the efficiency of nucleosome mobilization by limiting amounts of ACF. Deletion of the negatively charged C terminus of CHRAC16 enhances DNA binding 25-fold but leads to inhibition of nucleosome sliding, in striking analogy to the effect of the DNA chaperone HMGB1 on nucleosome sliding. The presence of a surface compatible with DNA interaction and the geometry of an H2A-H2B heterodimer may provide a transient acceptor site for DNA dislocated from the histone surface and therefore facilitate the nucleosome remodeling process.

Structural basis of transcription initiation by bacterial RNA polymerase holoenzyme.

Background: Cellular RNA polymerases start transcription by de novo RNA priming. Results: Structures and biochemical studies of initially transcribing complexes elucidate the de novo transcription initiation and early stage of RNA transcription. Conclusion: 5′-end of RNA in the transcribing complex starts σ ejection from core enzyme. Significance: Insights from this study can be applicable to all cellular RNA polymerases. The bacterial RNA polymerase (RNAP) holoenzyme containing σ factor initiates transcription at specific promoter sites by de novo RNA priming, the first step of RNA synthesis where RNAP accepts two initiating ribonucleoside triphosphates (iNTPs) and performs the first phosphodiester bond formation. We present the structure of de novo transcription initiation complex that reveals unique contacts of the iNTPs bound at the transcription start site with the template DNA and also with RNAP and demonstrate the importance of these contacts for transcription initiation. To get further insight into the mechanism of RNA priming, we determined the structure of initially transcribing complex of RNAP holoenzyme with 6-mer RNA, obtained by in crystallo transcription approach. The structure highlights RNAP-RNA contacts that stabilize the short RNA transcript in the active site and demonstrates that the RNA 5′-end displaces σ region 3.2 from its position near the active site, which likely plays a key role in σ ejection during the initiation-to-elongation transition. Given the structural conservation of the RNAP active site, the mechanism of de novo RNA priming appears to be conserved in all cellular RNAPs.

A conformational switch between transcriptional repression and replication initiation in the RepA dimerization domain.

Plasmids are natural vectors for gene transfer. In Gram-negative bacteria, plasmid DNA replication is triggered when monomers of an initiator protein (Rep) bind to direct repeats at the origin sequence. Rep dimers, which are inactive as initiators, bind to an inverse repeat operator, repressing transcription of the rep gene. Rep proteins are composed of N-terminal dimerization and C-terminal DNA-binding domains. Activation of Rep is coupled to dimer dissociation, converting the dimerization domain into a second origin-binding module. Although the structure of the monomeric F plasmid initiator (mRepE) has been determined, the molecular nature of Rep activation remains unknown. Here we report the crystal structure of the dimeric N-terminal domain of the pPS10 plasmid initiator (dRepA). dRepA has a winged-helix fold, as does its homologous domain in mRepE. However, dimerization transforms an interdomain loop and β-strand (monomeric RepE) into an α-helix (dimeric RepA). dRepA resemble the C terminus of eukaryotic and archaeal Cdc6, giving clues to the phylogeny of DNA replication initiators.

Conformational flexibility of RNA polymerase III during transcriptional elongation

RNA polymerase (Pol) III is responsible for the transcription of genes encoding small RNAs, including tRNA, 5S rRNA and U6 RNA. Here, we report the electron cryomicroscopy structures of yeast Pol III at 9.9 Å resolution and its elongation complex at 16.5 Å resolution. Particle sub‐classification reveals prominent EM densities for the two Pol III‐specific subcomplexes, C31/C82/C34 and C37/C53, that can be interpreted using homology models. While the winged‐helix‐containing C31/C82/C34 subcomplex initiates transcription from one side of the DNA‐binding cleft, the C37/C53 subcomplex accesses the transcription bubble from the opposite side of this cleft. The transcribing Pol III enzyme structure not only shows the complete incoming DNA duplex, but also reveals the exit path of newly synthesized RNA. During transcriptional elongation, the Pol III‐specific subcomplexes tightly enclose the incoming DNA duplex, which likely increases processivity and provides structural insights into the conformational switch between Pol III‐mediated initiation and elongation.

Two New Crystal Forms of the Choline-binding Domain of the Major Pneumococcal Autolysin: Insights into the Dynamics of the Active Homodimer

Very little is known about the in vivo regulation of the catalytic activity of the major pneumococcal autolysin (LytA), a surface-exposed enzyme that rules the self-destruction of pneumococcal cells through degradation of their peptidoglycan backbone. Two new crystal forms of the cell wall anchoring domain of LytA were obtained, and their structures were solved and refined to 2.4A and 2.8A resolution. The domain is a homodimer with a boomerang-like shape in which the tertiary structure of each monomer is comprised by six independent beta hairpins arranged in a superhelical fashion. Choline molecules at the hydrophobic interface of consecutive hairpins maintain this unique structure. The C-terminal hairpin (last 13 residues of LytA) in the solenoid is responsible for the formation of the catalytically active homodimer. Although the general fold in the structures derived from both crystal forms is essentially the same, two different conformations of the basic homodimer are observed. Biochemical approaches have demonstrated the fundamental role of the 11 C-terminal residues in the catalytic activity of LytA. The studies reported here reveal the importance of some amino acid residues at the C terminus in the determination of the relative distance of the active dimeric form of the autolysin, which appears to be essential for the catalytic activity of this enzyme.

Structure of the Drosophila nucleosome core particle highlights evolutionary constraints on the H2A-H2B histone dimer

We determined the 2.45 Å crystal structure of the nucleosome core particle from Drosophila melanogaster and compared it to that of Xenopus laevis bound to the identical 147 base‐pair DNA fragment derived from human α‐satellite DNA. Differences between the two structures primarily reflect 16 amino acid substitutions between species, 15 of which are in histones H2A and H2B. Four of these involve histone tail residues, resulting in subtly altered protein–DNA interactions that exemplify the structural plasticity of these tails. Of the 12 substitutions occurring within the histone core regions, five involve small, solvent‐exposed residues not involved in intraparticle interactions. The remaining seven involve buried hydrophobic residues, and appear to have coevolved so as to preserve the volume of side chains within the H2A hydrophobic core and H2A‐H2B dimer interface. Thus, apart from variations in the histone tails, amino acid substitutions that differentiate Drosophila from Xenopus histones occur in mutually compensatory combinations. This highlights the tight evolutionary constraints exerted on histones since the vertebrate and invertebrate lineages diverged. Proteins 2008.