A helical turn motif in Mss4 is a critical determinant of Rab binding and nucleotide release.

Monomeric Rab GTPases function as ubiquitous regulators of intracellular membrane trafficking. Mss4, an evolutionarily conserved Rab accessory factor, promotes nucleotide release from exocytic but not endocytic Rab GTPases. Here we describe the results of a high-resolution crystallographic and mutational analysis of Mss4. The 1.65 A crystal structure of Mss4 reveals a network of direct and water-mediated interactions that stabilize a partially exposed structural subdomain derived from four highly conserved but nonconsecutive sequence elements. The conserved subdomain contains the invariant cysteine residues required for Zn2+ binding as well as the residues implicated in the interaction with Rab GTPases. A strictly conserved DPhiPhi motif, consisting of an invariant aspartic acid residue (Asp 73) followed by two bulky hydrophobic residues (Met 74 and Phe 75), encodes a prominently exposed 3(10) helical turn in which the backbone is well-ordered but the side chains of the conserved residues are highly exposed and do not engage in intramolecular interactions. Substitution of any of these residues with alanine dramatically impairs nucleotide release activity toward Rab3A, indicating that the DPhiPhi motif is a critical element of the Rab interaction epitope. In particular, mutation of Phe 75 results in a defect as severe as that observed for mutation of Asp 96, which is located near the zinc binding site at the opposite end of the conserved subdomain. Despite severe defects, however, none of the mutant proteins is catalytically dead. Taken together, the results suggest a concerted mechanism in which distal elements of the conserved Rab interaction epitope cooperatively facilitate nucleotide release.

Structural basis of 3-phosphoinositide recognition by pleckstrin homology domains.

Lipid second messengers generated by phosphoinositide (PI) 3-kinases regulate diverse cellular functions through interaction with pleckstrin homology (PH) domains in modular signaling proteins. The PH domain of Grp1, a PI 3-kinase-activated exchange factor for Arf GTPases, selectively binds phosphatidylinositol 3,4,5-trisphosphate with high affinity. We have determined the structure of the Grp1 PH domain in the unliganded form and bound to inositol 1,3,4,5-tetraphosphate. A novel mode of phosphoinositide recognition involving a 20-residue insertion within the beta6/beta7 loop explains the unusually high specificity of the Grp1 PH domain and the promiscuous 3-phosphoinositide binding typical of several PH domains including that of protein kinase B. When compared to other PH domains, general determinants of 3-phosphoinositide recognition and specificity can be deduced.

Preliminary X-ray diffraction studies of an RNA pseudoknot that inhibits HIV-1 reverse transcriptase.

Crystals of a 26-nucleotide pseudoknot RNA, PK26, have been grown. The RNA was produced using phosphoramidite chemistry and was purified by denaturing polyacrylamide electrophoresis. The crystallization was robust with respect to changes in the number of nucleotides and to the salt used as precipitant. The crystals belong to space group P4(1)22 or P4(3)22 with unit-cell dimensions a = b = 61.6, c = 98.9 A. The best crystals diffract X-rays to 2.9 A. Three different sequences incorporating a single 5-bromo-deoxyuridine or 5-bromo-uridine nucleotide were also crystallized. Two of these derivatives are being used to determine the structure by multiple isomorphous replacement.

The structure of an RNA dodecamer shows how tandem U-U base pairs increase the range of stable RNA structures and the diversity of recognition sites.

BACKGROUND: Non-canonical base pairs are fundamental building blocks of RNA structures. They can adopt geometries quite different from those of canonical base pairs and are common in RNA molecules that do not transfer sequence information. Tandem U-U base pairs occur frequently, and can stabilize duplex formation despite the fact that a single U-U base pair is destabilizing. RESULTS: We determined the crystal structure of the RNA dodecamer GGCGCUUGCGUC at 2.4 A resolution. The molecule forms a duplex containing tandem U-U base pairs, which introduce an overall bend of 11-12 degrees in the duplex resulting from conformational changes at each interface between the tandem U-U base pairs and a flanking duplex sequence. The formation of the U-U base pairs cause small changes in several backbone torsion angles; base stacking is preserved and two hydrogen bonds are formed per base pair, explaining the stability of the structure. CONCLUSIONS: Tandem U-U base pairs can produce stable structures not accessible to normal A-form RNA, which may allow the formation of specific interfaces for RNA-RNA or RNA-protein recognition. These base-pairs show an unusual pattern of hydrogen-bond donors and acceptors in the major and minor grooves, which could also act as a recognition site.

Data reduction from twinned RNA crystals.

Methods were developed to process diffraction data from epitaxically twinned crystals. Four programs for data reduction and two display programs were developed to augment the data-reduction program XDS [Kabsch (1988). J. Appl. Cryst. 21, 916-924]. The programs can be generalized for use with other data-reduction software that provides the user with a list of the reflections used to determine lattice constants and crystal orientation. LATTICE_VIEW generates a PDB file containing 'water molecules' at the reciprocal-space coordinates of the strong spots found in the initial data frames. The PDB file is visualized to identify spots that belong to the same lattice, obtain unit-cell dimensions for a lattice, and assess data quality. VECTOR_MATCH is used to find additional spots belonging to a lattice. ACCOUNT4 determines which spots have been processed by XDS. COMFORT discards reflections that are too close to a reflection in another lattice. The display programs provide useful visual information on the quality of the crystal orientations used. Data with an R(merge) of 7.1% at 2.4 A resolution were obtained from epitaxically twinned crystals of an RNA dodecamer. The data were of sufficient quality to solve the structure with a combination of molecular replacement and single isomorphous replacement methods.

The Refined Three-Dimensional Structure of Pectate Lyase E from Erwinia chrysanthemi at 2.2 A Resolution.

The crystal structure of pectate lyase E (PelE; EC 4.2.2.2) from the enterobacteria Erwinia chrysanthemi has been refined by molecular dynamics techniques to a resolution of 2.2 A and an R factor (an agreement factor between observed structure factor amplitudes) of 16.1%. The final model consists of all 355 amino acids and 157 water molecules. The root-mean-square deviation from ideality is 0.009 A for bond lengths and 1.721[deg] for bond angles. The structure of PelE bound to a lanthanum ion, which inhibits the enzymatic activity, has also been refined and compared to the metal-free protein. In addition, the structures of pectate lyase C (PelC) in the presence and absence of a lutetium ion have been refined further using an improved algorithm for identifying waters and other solvent molecules. The two putative active site regions of PelE have been compared to those in the refined structure of PelC. The analysis of the atomic details of PelE and PelC in the presence and absence of lanthanide ions provides insight into the enzymatic mechanism of pectate lyases.

Crystallization and structure determination of RNA.

Progress in the synthesis, purification and crystallization of RNA has resulted in the determination of several X-ray crystal structures of RNA molecules over the past few years. Methods proven and under development will lead to future structure determinations and shed light on the structural basis for RNA's many functions.

Functional implications of structure-based sequence alignment of proteins in the extracellular pectate lyase superfamily.

Pectate lyases are plant virulence factors that degrade the pectate component of the plant cell wall. The enzymes share considerable sequence homology with plant pollen and style proteins, suggesting a shared structural topology and possibly functional relationships as well. The three-dimensional structures of two Erwinia chrysanthemi pectate lyases, C and E, have been superimposed and the structurally conserved amino acids have been identified. There are 232 amino acids that superimpose with a root-mean-square deviation of 3 A or less. These amino acids have been used to correct the primary sequence alignment derived from evolution-based techniques. Subsequently, multiple alignment techniques have allowed the realignment of other extracellular pectate lyases as well as all sequence homologs, including pectin lyases and the plant pollen and style proteins. The new multiple sequence alignment reveals amino acids likely to participate in the parallel beta helix motif, those involved in binding Ca2+, and those invariant amino acids with potential catalytic properties. The latter amino acids cluster in two well-separated regions on the pectate lyase structures, suggesting two distinct enzymatic functions for extracellular pectate lyases and their sequence homologs.

The Three-Dimensional Structure of Pectate Lyase E, a Plant Virulence Factor from Erwinia chrysanthemi.

The three-dimensional structure of pectate lyase E (PelE) has been determined by crystallographic techniques at a resolution of 2.2 A. The model includes all 355 amino acids but no solvent, and refines to a crystallographic refinement factor of 20.6%. The polypeptide backbone folds into a large right-handed cylinder, termed a parallel [beta] helix. Loops of various sizes and conformations protrude from the central helix and probably confer function. A putative Ca2+-binding site as well as two cationic sites have been deduced from the location of heavy atom derivatives. Comparison of the PelE and recently determined pectate lyase C (PelC) structures has led to identification of a putative polygalacturonate-binding region in PelE. Structural differences relevant to differences in the enzymatic mechanism and maceration properties of PelE and PelC have been identified. The comparative analysis also reveals a large degree of structural conservation of surface loops in one region as well as an apparent aromatic specificity pocket in the amino-terminal branch. Also discussed is the sequence and possible functional relationship of the pectate lyases with pollen and style plant proteins.

Unusual structural features in the parallel beta-helix in pectate lyases.

BACKGROUND: A new type of domain structure, an all parallel beta class, has recently been observed in two pectate lyases, PelC and PelE. The atomic models have been analyzed to determine whether the new tertiary fold exhibits unusual structural features. RESULTS: The polypeptide backbone exhibits no new types of secondary structural elements. However, novel features occur in the amino acid side chain interactions. The side chain atoms form linear stacks that include asparagine ladders, serine stacks, aliphatic stacks, and ringed-residue stacks. A new type of beta-sandwich between parallel beta-sheets is observed with properties that are more characteristic of antiparallel beta-sheets. CONCLUSION: An analysis of the PelC and PelE structures, belonging to an all parallel beta structural class, reveals novel amino acid side chain interactions, a new type of beta-sandwich and an atypical amino acid composition of parallel beta-sheets. The findings are relevant to three-dimensional structural predictions.