Project description:Inteins are prevalent among extremophiles. Mini-inteins with robust splicing properties are of particular interest for biotechnological applications due to their small size. However, biochemical and structural characterization has still been limited to a small number of inteins, and only a few serve as widely used tools in protein engineering. We determined the crystal structure of a naturally occurring Pol-II mini-intein from Pyrococcus horikoshii and compared all three mini-inteins found in the genome of P. horikoshii. Despite their similar sizes, the comparison revealed distinct differences in the insertions and deletions, implying specific evolutionary pathways from distinct ancestral origins. Our studies suggest that sporadically distributed mini-inteins might be more promising for further protein engineering applications than highly conserved mini-inteins. Structural investigations of additional inteins could guide the shortest path to finding novel robust mini-inteins suitable for various protein engineering purposes.

Project description:Zinc has been found in the crystal structures of inteins and the zinc ion can inhibit intein splicing both in vitro and in vivo. The interactions between metal ions and three minimized recA inteins have been studied in this work. Isothermal titration calorimetry (ITC) results show that the zinc binding affinity to three inteins is in the order of DeltaI-SM > DeltaDeltaI(hh)-SM approximately DeltaDeltaI(hh)-CM, but is much weaker than to EDTA. These data explain the reversible inhibition and the presence of zinc only in the crystal structure of DeltaI-SM of recA intein. A positive correlation between binding constants and inhibition efficiency was observed upon the titration of different metal ions. Single-site binding modes were detected in all interactions, except DeltaDeltaI(hh)-CM which has two Zn sites. Zinc binding sites on DeltaDeltaI(hh)-CM were analyzed by NMR spectroscopy and ITC titration on inteins with chemical modifications. Results indicate that the Cys1 and His73 are the second zinc binding sites in DeltaDeltaI(hh)-CM. CD studies show the metal coordinations have negligible influence on protein structure. This work suggests that the mobility restriction of key residues from metal coordination is likely the key cause of metal inhibition of intein splicing.

Project description:Inteins (protein introns) are internal portions of protein sequences that are posttranslationally excised while the flanking regions are spliced together, making an additional protein product. Inteins have been found in a number of homologous genes in yeast, mycobacteria, and extreme thermophile archaebacteria. The inteins are probably multifunctional, autocatalyzing their own splicing, and some were also shown to be DNA endonucleases. The splice junction regions and two regions similar to homing endonucleases were thought to be the only common sequence features of inteins. This work analyzed all published intein sequences with recently developed methods for detecting weak, conserved sequence features. The methods complemented each other in the identification and assessment of several patterns characterizing the intein sequences. New intein conserved features are discovered and the known ones are quantitatively described and localized. The general sequence description of all the known inteins is derived from the motifs and their relative positions. The intein sequence description is used to search the sequence databases for intein-like proteins. A sequence region in a mycobacterial open reading frame possessing all of the intein motifs and absent from sequences homologous to both of its flanking sequences is identified as an intein. A newly discovered putative intein in red algae chloroplasts is found not to contain the endonuclease motifs present in all other inteins. The yeast HO endonuclease is found to have an overall intein-like structure and a few viral polyprotein cleavage sites are found to be significantly similar to the inteins amino-end splice junction motif. The intein features described may serve for detection of intein sequences.

Project description:Inteins mediate protein splicing, which has found many applications in biotechnology and protein engineering. A single valine-to-leucine mutation (V67L) can globally enhance splicing and related cleavage reactions in minimized Mycobacterium tuberculosis RecA inteins. However, V67L mutation causes little change in crystal structures. To test whether protein dynamics contribute to activity enhancement in the V67L mutation, we have studied the conformations and dynamics of the minimized and engineered intein DeltaDeltaIhh-V67CM and a single V67L mutant, DeltaDeltaIhh-L67CM, by solution NMR. Chemical shift perturbations established that the V67L mutation causes global changes, including changes at the N-terminus and C-terminus of the intein, which are active sites for protein splicing. The single V67L mutation significantly slows hydrogen-exchange rates globally, indicating a shift to more stable conformations and reduction in ensemble distribution. Whereas the V67L mutation causes little change for motions on the picosecond-to-nanosecond timescale, motions on the microsecond-to-millisecond timescale affect a region involving the conserved F-block histidine and C-terminal asparagine, which are residues important for C-terminal cleavage. The V67L mutation is proposed to activate splicing by reducing the ensemble distribution of the intein structure and by modifying the active sites.

Project description:BackgroundThe piggyBac mobile element is quickly gaining popularity as a tool for the transgenesis of many eukaryotic organisms. By studying the transposase which catalyzes the movement of piggyBac, we may be able to modify this vector system to make it a more effective transgenesis tool. In a previous publication, Sarkar A, Sim C, Hong YS, Hogan JR, Fraser MJ, Robertson HM, and Collins FH have proposed the presence of the widespread 'DDE/DDD' motif for piggyBac at amino acid positions D268, D346, and D447.ResultsThis study utilizes directed mutagenesis and plasmid-based mobility assays to assess the importance of these residues as the catalytic core of the piggyBac transposase. We have functionally analyzed individual point-mutations with respect to charge and physical size in all three proposed residues of the 'DDD' motif as well as another nearby, highly conserved aspartate at D450. All of our mutations had a significant effect on excision frequency in S2 cell cultures. We have also aligned the piggyBac transposase to other close family members, both functional and non-functional, in an attempt to identify the most highly conserved regions and position a number of interesting features.ConclusionWe found all the designated DDD aspartates reside in clusters of amino acids that conserved among piggyBac family transposase members. Our results indicate that all four aspartates are necessary, to one degree or another, for excision to occur in a cellular environment, but D450 seems to have a tolerance for a glutamate substitution. All mutants tested significantly decreased excision frequency in cell cultures when compared with the wild-type transposase.

Project description:Members of the Cys-loop superfamily of ligand-gated ion channels, which mediate fast synaptic transmission in the nervous system, are assembled as heteropentamers from a large repertoire of neuronal subunits. Although several motifs in subunit N-terminal domains are known to be important for subunit assembly, increasing evidence points toward a role for C-terminal domains. Using a combination of flow cytometry, patch clamp recording, endoglycosidase H digestion, brefeldin A treatment, and analytic centrifugation, we identified a highly conserved aspartate residue at the boundary of the M3-M4 loop and the M4 domain that was required for binary and ternary gamma-aminobutyric acid type A receptor surface expression. Mutation of this residue caused mutant and partnering subunits to be retained in the endoplasmic reticulum, reflecting impaired forward trafficking. Interestingly although mutant and partnering wild type subunits could be coimmunoprecipitated, analytic centrifugation studies demonstrated decreased formation of pentameric receptors, suggesting that this residue played an important role in later steps of subunit oligomerization. We thus conclude that C-terminal motifs are also important determinants of Cys-loop receptor assembly.

Project description:The ligand-binding ?I and ?I domains of integrin are the best-studied von Willebrand factor A domains undergoing significant conformational changes for affinity regulation. In both ?I and ?I domains, the ?1- and ?7-helixes work in concert to shift the metal-ion-dependent adhesion site between the resting and active states. An absolutely conserved Gly in the middle of the ?1-helix of ?I helps maintain the resting ?I conformation, whereas the homologous position in the ?I ?1-helix contains a conserved Phe. A functional role of this Phe is structurally unpredictable. Using ?L?2 integrin as a model, we found that the residue volume at the Phe position in the ?1-helix is critical for ?L?2 activation because trimming the Phe by small amino acid substitutions abolished ?L?2 binding with soluble and immobilized intercellular cell adhesion molecule 1. Similar results were obtained for ?M?2 integrin. Our experimental and molecular dynamics simulation data suggested that the bulky Phe acts as a pawl that stabilizes the downward ratchet-like movement of ?6-?7 loop and ?7-helix, required for high-affinity ligand binding. This mechanism may apply to other von Willebrand factor A domains undergoing large conformational changes. We further demonstrated that the conformational cross-talk between ?L ?I and ?2 ?I could be uncoupled because the ?2 extension and headpiece opening could occur independently of the ?I activation. Reciprocally, the ?I activation does not inevitably lead to the conformational changes of the ?2 subunit. Such loose linkage between the ?I and ?I is attributed to the ?I flexibility and could accommodate the ?L?2-mediated rolling adhesion of leukocytes.

Project description:In the brain, transporters of the major excitatory neurotransmitter glutamate remove their substrate from the synaptic cleft to allow optimal glutamatergic neurotransmission. Their transport cycle consists of two sequential translocation steps, namely cotransport of glutamic acid with three Na(+) ions, followed by countertransport of K(+). Recent studies, based on several crystal structures of the archeal homologue Glt(Ph), indicate that glutamate translocation occurs by an elevator-like mechanism. The resolution of these structures was not sufficiently high to unambiguously identify the sites of Na(+) binding, but functional and computational studies suggest some candidate sites. In the Glt(Ph) structure, a conserved aspartate residue (Asp-390) is located adjacent to a conserved tyrosine residue, previously shown to be a molecular determinant of ion selectivity in the brain glutamate transporter GLT-1. In this study, we characterize mutants of Asp-440 of the neuronal transporter EAAC1, which is the counterpart of Asp-390 of Glt(Ph). Except for substitution by glutamate, this residue is functionally irreplaceable. Using biochemical and electrophysiological approaches, we conclude that although D440E is intrinsically capable of net flux, this mutant behaves as an exchanger under physiological conditions, due to increased and decreased apparent affinities for Na(+) and K(+), respectively. Our present and previous data are compatible with the idea that the conserved tyrosine and aspartate residues, located at the external end of the binding pocket, may serve as a transient or stable cation binding site in the glutamate transporters.

Project description:The present study characterized conserved residues in a GST (glutathione transferase) in the active-site region that interacts with glutathione. This region of the active site is near the glycine moiety of glutathione and consists of a hydrogen bond network. In the GSTD (Delta class GST) studied, adGSTD4-4, the network consisted of His(38), Met(39), Asn(47), Gln(49), His(50) and Cys(51). In addition to contributing to glutathione binding, this region also had major effects on enzyme catalysis, as shown by changes in kinetic parameters and substrate-specific activity. The results also suggest that the electron distribution of this network plays a role in stabilization of the ionized thiol of glutathione as well as impacting on the catalytic rate-limiting step. This area constitutes a second glutathione active-site network involved in glutathione ionization distinct from a network previously observed interacting with the glutamyl end of glutathione. This second network also appears to be functionally conserved in GSTs. In the present study, His(50) is the key basic residue stabilized by this network, as shown by up to a 300-fold decrease in k(cat) and 5200-fold decrease in k(cat)/K(m) for glutathione. Although these network residues have a minor role in structural integrity, the replaced residues induced changes in active-site topography as well as generating positive co-operativity towards glutathione. Moreover, this network at the glycine moiety of GSH (glutathione) also contributed to the 'base-assisted deprotonation model' for GSH ionization. Taken together, the results indicate a critical role for the functionally conserved basic residue His(50) and this hydrogen bond network in the active site.

Project description:A single nucleotide polymorphism (SNP) in codon 129 of the human prion gene, leading to a change from methionine to valine at residue 129 of prion protein (PrP), has been shown to be a determinant in the susceptibility to prion disease. However, the molecular basis of this effect remains unexplained. In the current study, we determined crystal structures of prion segments having either Met or Val at residue 129. These 6-residue segments of PrP centered on residue 129 are "steric zippers," pairs of interacting ?-sheets. Both structures of these "homozygous steric zippers" reveal direct intermolecular interactions between Met or Val in one sheet and the identical residue in the mating sheet. These two structures, plus a structure-based model of the heterozygous Met-Val steric zipper, suggest an explanation for the previously observed effects of this locus on prion disease susceptibility and progression.