The td intron endonuclease I-TevI makes extensive sequence-tolerant contacts across the minor groove of its DNA target.

I-TevI, a double-strand DNA endonuclease encoded by the mobile td intron of phage T4, has specificity for the intronless td allele. Genetic and physical studies indicate that the enzyme makes extensive contacts with its DNA substrate over at least three helical turns and around the circumference of the helix. Remarkably, no single nucleotide within a 48 bp region encompassing this interaction domain is essential for cleavage. Although two subdomains (DI and DII) contain preferred sequences, a third domain (DIII), a primary region of contact with the enzyme, displays much lower sequence preference. While DII and DIII suffice for recognition and binding of I-TevI, all three domains are important for formation of a cleavage-competent complex. Mutational, footprinting and interference studies indicate predominant interactions of I-TevI across the minor groove and phosphate backbone of the DNA. Contacts appear not to be at the single nucleotide level; rather, redundant interactions and/or structural recognition are implied. These unusual properties provide a basis for understanding how I-TevI recognizes T-even phage DNA, which is heavily modified in the major groove. These recognition characteristics may increase the range of natural substrates available to the endonuclease, thereby extending the invasive potential of the mobile intron.     

The Desmoglein-Specific Cytoplasmic Region Is Intrinsically Disordered in Solution and Interacts with Multiple Desmosomal Protein Partners

The desmoglein-specific cytoplasmic region (DSCR) is a conserved region of unknown structure and function that uniquely defines the desmoglein family of cell adhesion molecules. It is the site of caspase cleavage during apoptosis, and its mutation is linked to cardiomyopathy. Here, we reveal that a 276-residue DSCR construct of human desmoglein 1 is intrinsically disordered and forms an interaction hub for desmosomal proteins. In solution, it contains 6.5% helical and 10.3% β-strand structure based on circular dichroism spectroscopy. A single monomeric state with a predominantly unfolded structure is found by size-exclusion chromatography and analytical ultracentrifugation. Thermal stability assays and nuclear magnetic resonance spectroscopy reveal a nonglobular structure under a range of solution conditions. However, the introduction of detergent micelles increases structure to 18% helical and 16% β-strand character, suggesting an inducible structure. The DSCR exhibits weak but specific interactions with plakoglobin, the plakin domain of desmoplakin, plakophilin 1, and the cytoplasmic domain of desmocollin 1. The desmoglein 1 membrane proximal region also interacts with all four DSCR ligands, strongly with plakoglobin and plakophilin and more weakly with desmoplakin and desmocollin 1. Thus, the DSCR is an intrinsically disordered functional domain with an inducible structure that, along with the membrane proximal region, forms a flexible scaffold for cytoplasmic assembly at the desmosome.     

SegG endonuclease promotes marker exclusion and mediates co-conversion from a distant cleavage site

Bacteriophages T2 and T4 are closely related T-even phages. However, T4 genetic markers predominate in the progeny of mixed infections, a phenomenon termed marker exclusion. One region previously mapped where the frequency of T2 markers in the progeny is extremely low is located around gene 32. Here, we describe SegG, a GIY-YIG family endonuclease adjacent to gene 32 of phage T4 that is absent from phage T2. In co-infections with T2 and T4, cleavage in T2 gene 32 by T4-encoded SegG initiates a gene conversion event that results in replacement of T2 gene 32 markers with the corresponding T4 sequence. Interestingly, segG inheritance is limited, apparently because of the physical separation of its cleavage and insertion sites, which are 332 base-pairs apart. This contrasts with efficient inheritance of the phage T4 td group I intron and its endonuclease, I-TevI, for which the distance separating the I-TevI cleavage site and td insertion site is 23 base-pairs. Furthermore, we show that co-conversion tracts generated by repair of SegG and I-TevI double-strand breaks contribute to the localized exclusion of T2 markers. Our results demonstrate that the endonuclease activities of SegG and I-TevI promote the spread of these two endonucleases to progeny phage, consistent with their role as selfish genetic elements, and also provide a mechanism by which the genetic contribution of T2 markers to progeny phage is reduced.     

Configuration of the catalytic GIY-YIG domain of intron endonuclease I-TevI: coincidence of computational and molecular findings

I-TevI is a member of the GIY-YIG family of homing endonucleases. It is folded into two structural and functional domains, an N-terminal catalytic domain and a C-terminal DNA-binding domain, separated by a flexible linker. In this study we have used genetic analyses, computational sequence analysis andNMR spectroscopy to define the configuration of theN-terminal domain and its relationship to the flexible linker. The catalytic domain is an alpha/beta structure contained within the first 92 amino acids of the 245-amino acid protein followed by an unstructured linker. Remarkably, this structured domain corresponds precisely to the GIY-YIG module defined by sequence comparisons of 57 proteins including more than 30 newly reported members of the family. Although much of the unstructured linker is not essential for activity, residues 93-116 are required, raising the possibility that this region may adopt an alternate conformation upon DNA binding. Two invariant residues of the GIY-YIG module, Arg27 and Glu75, located in alpha-helices, have properties of catalytic residues. Furthermore, the GIY-YIG sequence elements for which the module is named form part of a three-stranded antiparallel beta-sheet that is important for I-TevI structure and function.     

Extension of juxtamembrane domain of diphtheria toxin receptor arrests translocation of diphtheria toxin fragment A into cytosol

Diphtheria toxin (DT) binds to the EGF-like domain of the DT receptor (DTR), followed by internalization and translocation of the enzymatically active fragment A into the cytosol. The juxtamembrane domain (JM) of the DTR is the linker domain connecting the transmembrane and EGF-like domains. We constructed mutants of DTRs with altered JMs and studied their abilities for DT intoxication. Although DTR mutants with extended JMs showed normal DT binding activity, the cells expressing the mutants showed both reduced translocation of DT fragment A into the cytosol and reduced sensitivity to DT, when compared with cells expressing wild-type DTR. These results indicate that the JM contributes to DT intoxication by providing a space appropriate for the interaction of DT with the cell membrane. The present study also indicates that consideration of epitopes of an immunotoxins would be an important factor in the design of potent immunotoxins.     

Identification of the catalytic subdomain of the VS ribozyme and evidence for remarkable sequence tolerance in the active site loop

We show here that the ribozyme domain of the Neurospora VS ribozyme consists of separable upper and lower subdomains. Deletion analysis demonstrates that the entire upper subdomain (helices III/IV/V) is dispensable for site-specific cleavage activity, providing experimental evidence that the active site is contained within the lower subdomain and within the substrate itself. We demonstrate an important role in cleavage activity for a region of helix VI called the 730 loop. Surprisingly, several loop sequences, sizes, and structures at this position can support site-specific cleavage, suggesting that a variety of non-Watson-Crick structures, rather than a specific loop structure, in this region of the ribozyme can contribute to formation of the active site.     

Mutagenesis of the DI/DIII linker in dengue virus envelope protein impairs viral particle assembly

The dengue virus (DV) envelope (E) protein is important in mediating viral entry and assembly of progeny virus during cellular infection. Domains I and III (DI and DIII, respectively) of the DV E protein are connected by a highly conserved but poorly ordered region, the DI/DIII linker. Although the flexibility of the DI/DIII linker is thought to be important for accommodating the structural rearrangements undergone by the E protein during viral entry, the function of the linker in the DV infectious cycle is not well understood. In this study, we performed site-directed mutagenesis on conserved residues in the DI/DIII linker of the DV2 E protein and showed that the resulting mutations had little or no effect on the entry process but greatly affected virus assembly. Biochemical fractionation and immunofluorescence microscopy experiments performed on infectious virus as well as in a virus-like particle (VLP) system indicate that the DI/DIII linker mutants express the DV structural proteins at the sites of particle assembly near the ER but fail to form infectious particles. This defect is not due to disruption of E's interaction with prM and pr in immature and mature virions, respectively. Serial passaging of the DV2 mutant E-Y299F led to the identification of a mutation in the membrane-proximal stem region of E that fully compensates for the assembly defect of this DI/DIII linker mutant. Together, our results suggest a critical and previously unidentified role for the E protein DI/DIII linker region during the DV2 assembly process.     

Coincidence of cleavage sites of intron endonuclease I-TevI and critical sequences of the host thymidylate synthase gene

To maximize spread of their host intron or intein, many homing endonucleases recognize nucleotides that code for important and conserved amino acid residues of the target gene. Here, we examine the cleavage requirements for I-TevI, which binds a stretch of thymidylate synthase (TS) DNA that codes for functionally critical residues in the TS active site. Using an in vitro selection scheme, we identified two base-pairs in the I-TevI cleavage site region as important for cleavage efficiency. These were confirmed by comparison of I-TevI cleavage efficiencies on mutant and on wild-type substrates. We also showed that nicking of the bottom strand by I-TevI is not affected by mutation of residues surrounding the bottom-strand cleavage site, unlike other homing endonucleases. One of these two base-pairs is universally conserved in all TS sequences, and is identical with a previously identified cleavage determinant of I-BmoI, a related GIY-YIG endonuclease that binds a homologous stretch of TS-encoding DNA. The other base-pair is conserved only in a subset of TS genes that includes the I-TevI, but not the I-BmoI, target sequence. Both the I-TevI and I-BmoI cleavage site requirements correspond to functionally critical residues involved in an extensive hydrogen bond network within the TS active site. Remarkably, these cleavage requirements correlate with TS phylogeny in bacteria, suggesting that each endonuclease has individually adapted to efficiently cleave distinct TS substrates.     

102 Genome engineering nucleases derived from GIY-YIG homing endonucleases

Efficient targeted manipulation of complex genomes requires highly specific endonucleases to generate double-strand breaks at defined locations (Bibikova et al., 2003; Bogdanove and Voytas, 2011). The predominantly engineered nucleases, zinc-finger nucleases (ZFNs), and TAL effector nucleases (TALENs) use the catalytic domain of FokI as the nuclease portion. This domain, however, functions as a dimer to nonspecifically cleave DNA meaning that ZFNs and TALENs must be designed in head-to-head pairs to target a desired sequence. To overcome this limitation and expand the toolbox of genome editing reagents, we used the N-terminal catalytic domain and interdomain linker of the monomeric GIY-YIG homing endonuclease I-TevI to create I-TevI-zinc-fingers (Tev-ZFEs), and I-TevI-TAL effectors (Tev-TALs) (Kleinstiver et al. 2012). We also made I-TevI fusions to LAGLIDADGs homing endonucleases (I-Tev-LHEs). All the three fusions showed activity on model substrates on par with ZFNs and TALENs in yeast-based recombination assays. These proof-of-concept experiments demonstrate that the catalytic domain of GIY-YIG homing endonucleases can be targeted to relevant loci by fusing the domain to characterize DNA-binding platforms. Recent efforts have focused on improving the Tev-TAL platform by (1) understanding the spacing requirements between the nuclease cleavage site and the DNA binding site, (2) probing the DNA binding requirements of the I-TevI linker domain, and (3) demonstrating activity in mammalian systems.     

Molecular Dynamics Simulations of the Unfolding of the Starch Binding Domain from Aspergillus niger Glucoamylase

Abstract

The 600 ps molecular dynamics simulations to investigate the unfolding of the starch binding domain from Aspergillus niger glucoamylase were conducted in vacuum as well as in an external field with the dielectric constant of 80 with temperature jump technique. Electrostatic interactions play an important role in determining the stability of the β-strands in this domain. The starch binding site 1 is less stable than site 2 since it is more exposed to the surface. The disulfide bond between C509 and C604 is unstable since these two residues are located near the flexible linker domain and in the mobile loop region between β-strands 6 and 7, respectively. The melting temperature, at which the total residual β-strand content is 50% that of the solution structure, is about 544K for the simulations with dielectric constant of 80, leading to the estimated unfolding timescale of 0.48 ms in vitro. In addition, the unfolding of the starch binding domain is proposed to initiate from the interior region by the lost of the integrity of the secondary structure.     

Monomer-monomer interactions propagate structural transitions necessary for pore formation by the cholesterol-dependent cytolysins

The assembly of the cholesterol-dependent cytolysin (CDC) oligomeric pore complex requires a complex choreography of secondary and tertiary structural changes in domain 3 (D3) of the CDC monomer structure. A point mutation was identified in the archetype CDC, perfringolysin O, that blocks detectable D3 structural changes and traps the membrane-bound monomers in an early and reversible stage of oligomer assembly. Using this and other mutants we show that specific D3 structural changes are propagated from one membrane-bound monomer to another. Propagation of these structural changes results in the exposure of a β-strand in D3 that allows it to pair and form edge-on interactions with a second β-strand of a free membrane-bound monomer. Pairing of these strands establishes the final geometry of the pore complex and is necessary to drive the formation of the β-barrel pore. These studies provide new insights into how structural information is propagated between membrane-bound monomers of a self-assembling system and the interactions that establish the geometry of the final pore complex.     

Catalytic domain structure and hypothesis for function of GIY-YIG intron endonuclease I-TevI

I-TevI, a member of the GIY-YIG family of homing endonucleases, consists of an N-terminal catalytic domain and a C-terminal DNA-binding domain joined by a flexible linker. The GIY-YIG motif is in the N-terminal domain of I-TevI, which corresponds to a phylogenetically widespread catalytic cartridge that is often associated with mobile genetic elements. The crystal structure of the catalytic domain of I-TevI, the first of any GIY-YIG endonuclease, reveals a novel alpha/beta-fold with a central three-stranded antiparallel beta-sheet flanked by three helices. The most conserved and putative catalytic residues are located on a shallow, concave surface and include a metal coordination site. Similarities in the three-dimensional arrangement of the catalytically important residues and the cation-binding site with those of the His-Cys box endonuclease I-PpoI suggest the possibility of mechanistic relationships among these different families of homing endonucleases despite completely different folds.     

An RNA domain within the 5' untranslated region of the tomato bushy stunt virus genome modulates viral RNA replication

The terminal half of the 5' untranslated region (UTR) in the (+)-strand RNA genome of tomato bushy stunt virus was analyzed for possible roles in viral RNA replication. Computer-aided thermodynamic analysis of secondary structure, phylogenetic comparisons for base-pair covariation, and chemical and enzymatic solution structure probing were used to analyze the 78 nucleotide long 5'-terminal sequence. The results indicate that this sequence adopts a branched secondary structure containing a three-helix junction core. The T-shaped domain (TSD) formed by this terminal sequence is closed by a prominent ten base-pair long helix, termed stem 1 (S1). Deletion of either the 5' or 3' segment forming S1 (coordinates 1-10 or 69-78, respectively) in a model subviral RNA replicon, i.e. a prototypical defective interfering (DI) RNA, reduced in vivo accumulation levels of this molecule approximately 20-fold. Compensatory-type mutational analysis of S1 within this replicon revealed a strong correlation between formation of the predicted S1 structure and efficient DI RNA accumulation. RNA decay studies in vivo did not reveal any notable changes in the physical stabilities of DI RNAs containing disrupted S1s, thus implicating RNA replication as the affected process. Further investigation revealed that destabilization of S1 in the (+)-strand was significantly more detrimental to DI RNA accumulation than (-)-strand destabilization, therefore S1-mediated activity likely functions primarily via the (+)-strand. The essential role of S1 in DI RNA accumulation prompted us to examine the 5'-proximal secondary structure of a previously identified mutant DI RNA, RNA B, that lacks the 5' UTR but is still capable of low levels of replication. Mutational analysis of a predicted S1-like element present within a cryptic 5'-terminal TSD confirmed the importance of the former in RNA B accumulation. Collectively, these data support a fundamental role for the TSD, and in particular its S1 subelement, in tombusvirus RNA replication.     

Functional dissection of N-acetylglutamate synthase (ArgA) of Pseudomonas aeruginosa and restoration of its ancestral N-acetylglutamate kinase activity

In many microorganisms, the first step of arginine biosynthesis is catalyzed by the classical N-acetylglutamate synthase (NAGS), an enzyme composed of N-terminal amino acid kinase (AAK) and C-terminal histone acetyltransferase (GNAT) domains that bind the feedback inhibitor arginine and the substrates, respectively. In NAGS, three AAK domain dimers are interlinked by their N-terminal helices, conforming a hexameric ring, whereas each GNAT domain sits on the AAK domain of an adjacent dimer. The arginine inhibition of Pseudomonas aeruginosa NAGS was strongly hampered, abolished, or even reverted to modest activation by changes in the length/sequence of the short linker connecting both domains, supporting a crucial role of this linker in arginine regulation. Linker cleavage or recombinant domain production allowed the isolation of each NAGS domain. The AAK domain was hexameric and inactive, whereas the GNAT domain was monomeric/dimeric and catalytically active although with ～50-fold-increased and ～3-fold-decreased K(m)(glutamate) and k(cat) values, respectively, with arginine not influencing its activity. The deletion of N-terminal residues 1 to 12 dissociated NAGS into active dimers, catalyzing the reaction with substrate kinetics and arginine insensitivity identical to those for the GNAT domain. Therefore, the interaction between the AAK and GNAT domains from different dimers modulates GNAT domain activity, whereas the hexameric architecture appears to be essential for arginine inhibition. We proved the closeness of the AAK domains of NAGS and N-acetylglutamate kinase (NAGK), the enzyme that catalyzes the next arginine biosynthesis step, shedding light on the origin of classical NAGS, by showing that a double mutation (M26K L240K) in the isolated NAGS AAK domain elicited NAGK activity.     

Sequence Determinants for Amyloid Fibrillogenesis of Human alpha-Synuclein

Parkinson's disease (PD) and dementia with Lewy bodies (DLB) are characterized by the presence of filamentous inclusions in nerve cells. These filaments are amyloid fibrils that are made of the protein α-synuclein, which is genetically linked to rare cases of PD and DLB. β-Synuclein, which shares 60% identity with α-synuclein, is not found in the inclusions. Furthermore, while recombinant α-synuclein readily assembles into amyloid fibrils, β-synuclein fails to do so. It has been suggested that this may be due to the lack in β-synuclein of a hydrophobic region that spans residues 73-83 of α-synuclein. Here, fibril assembly of recombinant human α-synuclein, α-synuclein deletion mutants, β-synuclein and β/α-synuclein chimeras was assayed quantitatively by thioflavin T fluorescence and semi-quantitatively by transmission electron microscopy. Deletion of residues 73-83 from α-synuclein did not abolish filament formation. Furthermore, a chimera of β-synuclein with α-synuclein(73-83) inserted was significantly less fibrillogenic than wild-type α-synuclein. These findings, together with results obtained using a number of recombinant synucleins, showed a correlation between fibrillogenesis and mean β-strand propensity, hydrophilicity and charge of the amino acid sequences. The combination of these simple physicochemical properties with a previously described calculation of β-strand contiguity allowed us to design mutations that changed the fibrillogenic propensity of α-synuclein in predictable ways.     

GrpE N-terminal domain contributes to the interaction with Dnak and modulates the dynamics of the chaperone substrate binding domain

GrpE acts as a nucleotide exchange factor for DnaK, the main Hsp70 protein in bacteria, accelerating ADP/ATP exchange by several orders of magnitude. GrpE is a homodimer, each subunit containing three structural domains: a N-terminal unordered segment, two long coils and a C-terminal globular domain formed by a four-helix bundle, and a β-subdomain. GrpE association to DnaK nucleotide-binding domain involves side-chain and backbone interactions located within the “headpiece” of the cochaperone, which consists of the C-terminal half of the coils, the four-helix bundle and the β-subdomain. However, the role of the GrpE N-terminal region in the interaction with DnaK and the activity of the cochaperone remain controversial. In this study we explore the contribution of this domain to the binding reaction, using the wild-type proteins, two deletion mutants of GrpE (GrpE_34-197 and GrpE_69-197) and the isolated DnaK nucleotide-binding domain. Analysis of the thermodynamic binding parameters obtained by isothermal titration calorimetry shows that both GrpE N-terminal segments, 1-33 and 34-68, contribute to the binding reaction. Partial proteolysis and substrate dissociation kinetics also suggest that the N-terminal half of GrpE coils (residues 34-68) interacts with DnaK interdomain linker, regulates the nucleotide exchange activity of the cochaperone and is required to stabilize DnaK-substrate complexes in the ADP-bound conformation.