Mechanism of cleavage and ligation by FLP recombinase: classification of mutations in FLP protein by in vitro complementation analysis.

The FLP recombinase of the 2 microns plasmid of Saccharomyces cerevisiae is a member of the integrase family of site-specific recombinases. Recombination catalyzed by members of this family proceeds via the ordered cleavage and religation of four strands of DNA. Although the amino acid sequences of integrase family members are quite different, each recombinase maintains an absolutely conserved tetrad of amino acids (R-191, H-305, R-308, Y-343; numbers are those of the FLP protein). This tetrad is presumed to reflect a common chemical mechanism for cleavage and ligation that has evolved among all family members. The tyrosine is the nucleophile that causes phosphodiester bond cleavage and covalently attaches to the 3'-PO4 terminus, whereas the other three residues have been implicated in ligation of strands. It has recently been shown that cleavage by FLP takes place in trans; that is, a FLP molecule binds adjacent to the site of cleavage but receives the nucleophilic tyrosine from a molecule of FLP that is bound to another FLP-binding element (J.-W. Chen, J. Lee, and M. Jayaram, Cell 69:647-658, 1992). These studies led us to examine whether the ligation step of the FLP reaction is performed by the FLP molecule bound adjacent to the cleavage site (ligation in cis). We have found that FLP promotes ligation in cis. Furthermore, using in vitro complementation analysis, we have classified several mutant FLP proteins into one of two groups: those proteins that are cleavage competent but ligation deficient (group I) and those that are ligation competent but cleavage defective (group II). This observation suggests that the active site of FLP is composed of several amino acid residues from each of two FLP molecules.     

Sequence-structure-function relation characterized in silico

Methods for biological function recognition in silico appeared to be useful also for identifying characteristics of structure-to-function relations. The introduction of a three-dimensional Gauss function was assumed to represent the hydrophobic core in a protein molecule. The discrepancy between idealized "fuzzy oil-drop" and the observed one in real proteins appeared to be localized in the ligation site or in the area of biological function related part of protein molecule. The examples of proteins presented in this paper reveal that the structure-function relation can be evaluated and characterized also using the profile of the difference in value between idealized and real hydrophobicity distribution along the polypeptide chain. The specificity of particular polypeptide chain fragments in respect to their biological function and their specific participation in active site creation is discussed in this paper. The scale allowing comparison of different proteins in respect to their ligand-binding sites characteristics is introduced.     

Ligation of expressed protein α-hydrazides via genetic incorporation of an α-hydroxy acid

Expressed protein ligation bridges the gap between synthetic peptides and recombinant proteins and thereby significantly increases the size and complexity of chemically synthesized proteins. Although the intein-based expressed protein ligation method has been extensively used in this regard, the development of new expressed protein ligation methods may improve the flexibility and power of protein semisynthesis. In this study a new alternative version of expressed protein ligation is developed by combining the recently developed technologies of hydrazide-based peptide ligation and genetic code expansion. Compared to the previous intein-based expressed protein ligation method, the new method does not require the use of protein splicing technology and generates recombinant protein α-hydrazides as ligation intermediates that are more chemically stable than protein α-thioesters. Furthermore, the use of an evolved mutant pyrrolysyl-tRNA synthetase(PylRS), ACPK-RS, from M. barkeri shows an improved performance for the expression of recombinant protein backbone oxoesters. By using HdeA as a model protein we demonstrate that the hydrazide-based method can be used to synthesize proteins with correctly folded structures and full biological activity. Because the PylRS-tRNACUAPyl system is compatible with both prokaryotic and eukaryotic cells,the strategy presented here may be readily expanded to manipulate proteins produced in mammalian cells. The new hydrazide-based method may also supplement the intein-based expressed protein ligation method by allowing for a more flexible selection of ligation site.     

Scanning mutagenesis using T4 DNA ligase and short degenerate DNA oligonucleotides containing tri-nucleotide mismatches

Scanning mutagenesis is an attractive tool for protein structure-function correlation analysis. With one round of this method it is possible to obtain a library containing all possible single-residue mutants of the protein of interest. The practical application of this approach is currently limited by the large number and cost of the required 30-35mer oligonucleotides. As an alternative, we studied the ligation of shorter DNA oligonucleotides (6-11mer) containing a degenerate binding site and a desired mutation mismatch to a nested set of megaprimers annealed to the gene of interest. T4 DNA ligase was able to perform this task, and the obtained ligation products were elongated by DNA polymerase. The effectiveness of ligation depends on the length of the random binding site of the mutagenic oligonucleotide, on its molar excess over the template-primer complex and on the position of the mismatching tri-nucleotide insert with respect to the joining site. The secondary structure of the DNA template close to the joining site also influences the ligation yield. Mismatching oligonucleotides, protected by a 3'-phosphate group, were joined to a nested set of megaprimers, the latter being obtained by a novel procedure called reversible chain termination, i.e., termination of the dsDNA synthesis with ddNTP followed by the subsequent removal of the incorporated ddNMP with exonuclease III. T7 sequenase 2.0 DNA polymerase elongated the ligation products after the 3'-phosphate protection group was removed with T4 polynucleotide kinase, resulting in the incorporation of a specific tri-nucleotide mismatch into dsDNA. This sequence of reactions serves as the basis for a novel scanning mutagenesis procedure.     

Expressed protein ligation. Method and applications.

The introduction of noncanonical amino acids and biophysical probes into peptides and proteins, and total or segmental isotopic labelling has the potential to greatly aid the determination of protein structure, function and protein-protein interactions. To obtain a peptide as large as possible by solid-phase peptide synthesis, native chemical ligation was introduced to enable synthesis of proteins of up to 120 amino acids in length. After the discovery of inteins, with their self-splicing properties and their application in protein synthesis, the semisynthetic methodology, expressed protein ligation, was developed to circumvent size limitation problems. Today, diverse expression vectors are available that allow the production of N- and C-terminal fragments that are needed for ligation to produce large amounts and high purity protein(s) (protein alpha-thioesters and peptides or proteins with N-terminal Cys). Unfortunately, expressed protein ligation is still limited mainly by the requirement of a Cys residue. Of course, additional Cys residues can be introduced into the sequence by site directed mutagenesis or synthesis, however, those mutations may disturb protein structure and function. Recently, alternative ligation approaches have been developed that do not require Cys residues. Accordingly, it is theoretically possible to obtain each modified protein using ligation strategies.     

Mutational analysis of Escherichia coli MoeA: two functional activities map to the active site cleft

The molybdenum cofactor is ubiquitous in nature, and the pathway for Moco biosynthesis is conserved in all three domains of life. Recent work has helped to illuminate one of the most enigmatic steps in Moco biosynthesis, ligation of metal to molybdopterin (the organic component of the cofactor) to form the active cofactor. In Escherichia coli, the MoeA protein mediates ligation of Mo to molybdopterin while the MogA protein enhances this process in an ATP-dependent manner. The X-ray crystal structures for both proteins have been previously described as well as two essential MogA residues, Asp49 and Asp82. Here we describe a detailed mutational analysis of the MoeA protein. Variants of conserved residues at the putative active site of MoeA were analyzed for a loss of function in two different, previously described assays, one employing moeA- crude extracts and the other utilizing a defined system. Oddly, no correlation was observed between the activity in the two assays. In fact, our results showed a general trend toward an inverse relationship between the activity in each assay. Moco binding studies indicated a strong correlation between a variant's ability to bind Moco and its activity in the purified component assay. Crystal structures of the functionally characterized MoeA variants revealed no major structural changes, indicating that the functional differences observed are not due to disruption of the protein structure. On the basis of these results, two different functional areas were assigned to regions at or near the MoeA active site cleft.     

An amalgamation of solid phase peptide synthesis and ribosomal peptide synthesis

Expressed protein ligation (EPL) is a protein semisynthesis technique that allows the site-specific introduction of unnatural amino acids and biophysical probes into proteins. In the present study, we illustrate the utility of the approach through the generation of two semisynthetic proteins bearing spectroscopic probes. Dihydrofolate reductase containing a single (13)C probe in an active site loop was generated through the ligation of a synthetic peptide-alpha-thioester to a recombinantly generated fragment containing an N-terminal Cys. Similarly, c-Crk-II was assembled by the sequential ligation of three recombinant polypeptide building blocks, allowing the incorporation of (15)N isotopes in the central domain of the protein. These examples showcase the scope of the protein ligation strategy for selective introduction of isotopic labels into proteins, and the protocols described will be of value to those interested in using EPL on other systems.     

Western blot analysis of Src kinase assays using peptide substrates ligated to a carrier protein

We have applied intein-mediated peptide ligation (IPL) to the use of peptide substrates for kinase assays and subsequent Western blot analysis. IPL allows for the efficient ligation of a synthetic peptide with an N-terminal cysteine residue to an intein-generated carrier protein containing a cysteine reactive C-terminal thioester through a native peptide bond. A distinct advantage of this procedure is that each carrier protein molecule ligates only one peptide, ensuring that the ligation product forms a sharp band on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). We demonstrate the effectiveness of this approach by mutational analysis of peptide substrates derived from human cyclin-dependent kinase, Cdc2, which contains a phosphorylation site of human c-Src protein tyrosine kinase.     

Biosynthesis of lipoteichoic acid in Lactobacillus rhamnosus: role of DltD in D-alanylation

The dlt operon (dltA to dltD) of Lactobacillus rhamnosus 7469 encodes four proteins responsible for the esterification of lipoteichoic acid (LTA) by D-alanine. These esters play an important role in controlling the net anionic charge of the poly (GroP) moiety of LTA. dltA and dltC encode the D-alanine-D-alanyl carrier protein ligase (Dcl) and D-alanyl carrier protein (Dcp), respectively. Whereas the functions of DltA and DltC are defined, the functions of DltB and DltD are unknown. To define the role of DltD, the gene was cloned and sequenced and a mutant was constructed by insertional mutagenesis of dltD from Lactobacillus casei 102S. Permeabilized cells of a dltD::erm mutant lacked the ability to incorporate D-alanine into LTA. This defect was complemented by the expression of DltD from pNZ123/dlt. In in vitro assays, DltD bound Dcp for ligation with D-alanine by Dcl in the presence of ATP. In contrast, the homologue of Dcp, the Escherichia coli acyl carrier protein (ACP), involved in fatty acid biosynthesis, was not bound to DltD and thus was not ligated with D-alanine. DltD also catalyzed the hydrolysis of the mischarged D-alanyl-ACP. The hydrophobic N-terminal sequence of DltD was required for anchoring the protein in the membrane. It is hypothesized that this membrane-associated DltD facilitates the binding of Dcp and Dcl for ligation of Dcp with D-alanine and that the resulting D-alanyl-Dcp is translocated to the primary site of D-alanylation.     

Protein ligation in living cells using sortase

Sortagging is a versatile method for site‐specific modification of proteins as applied to a variety of in vitro reactions. Here, we explore possibilities of adapting the sortase method for use in living cells. For intracellular sortagging, we employ the Ca²⁺‐independent sortase A transpeptidase (SrtA) from Streptococcus pyogenes. Substrate proteins were equipped with the C‐terminal sortase‐recognition motif (LPXTG); we used proteins with an N‐terminal (oligo)glycine as nucleophiles. We show that sortase‐dependent protein ligation can be achieved in Saccharomyces cerevisiae and in mammalian HEK293T cells, both in the cytosol and in the lumen of the endoplasmic reticulum (ER). ER luminal sortagging enables secretion of the reaction products, among which circular polypeptides. Protein ligation of substrate and nucleophile occurs within 30 min of translation. The versatility of the method is shown by protein ligation of multiple substrates with green fluorescent protein‐based nucleophiles in different intracellular compartments.     

Localization of ligand binding site in proteins identified in silico

Knowledge-based models for protein folding assume that the early-stage structural form of a polypeptide is determined by the backbone conformation, followed by hydrophobic collapse. Side chain–side chain interactions, mostly of hydrophobic character, lead to the formation of the hydrophobic core, which seems to stabilize the structure of the protein in its natural environment. The fuzzy-oil-drop model is employed to represent the idealized hydrophobicity distribution in the protein molecule. Comparing it with the one empirically observed in the protein molecule reveals that they are not in agreement. It is shown in this study that the irregularity of hydrophobic distributions is aim-oriented. The character and strength of these irregularities in the organization of the hydrophobic core point to the specificity of a particular protein’s structure/function. When the location of these irregularities is determined versus the idealized fuzzy-oil-drop, function-related areas in the protein molecule can be identified. The presented model can also be used to identify ways in which protein–protein complexes can possibly be created. Active sites can be predicted for any protein structure according to the presented model with the free prediction server at . The implication based on the model presented in this work suggests the necessity of active presence of ligand during the protein folding process simulation. Figure Fuzzy-oil-drop model applied to identify the ligation site in lysozyme complexed with N-acetylglucosamine (PDB ID:1LMQ) in form of hydrophobicity deficiency (ΔH) profile and three-dimensional distribution of on protein surface     

Thermodynamic and spectroscopic study of Cu(II) and Ni(II) binding to bovine serum albumin

The thermodynamics of Cu(II) and Ni(II) binding to bovine serum albumin (BSA) have been studied by isothermal titration calorimetry (ITC). The Cu(II) binding affinity of the N-terminal protein site is quantitatively higher when the single free thiol, Cys-34, is reduced (mercaptalbumin), compared to when it is oxidized or derivatized with N-ethylmaleimide. This increased affinity is due predominantly to entropic factors. At higher pH (approximately 9), when the protein is in the basic (B) form, a second Cu(II) binds with high affinity to albumin with reduced Cys-34. The Cu(II) coordination has been characterized by UV-vis absorption, CD, and EPR spectroscopy, and the spectral data are consistent with thiolate coordination to a tetragonal Cu(II), indicating this is a type 2 copper site with thiolate ligation. Nickel(II) binding to the N-terminal site of BSA is also modulated by the redox/ligation state of Cys-34, with higher Ni(II) affinity for mercaptalbumin, the predominant circulating form of the protein.     

GPI-anchored GFP signals Ca2+ but is homogeneously distributed on the cell surface

Glycosyl-phosphatidylinositol (GPI)-anchored proteins are unique in that they penetrate only the outer leaflet of the plasma membrane but are still able to mediate intracellular signalling events following antibody-induced ligation. Detergent solubilisation studies suggest that microdomains exist at the cell surface within which are sequestered GPI-linked proteins. Here we report the construction and expression of a fluorescent GPI anchor on the surface of CHO, EL4, and U937 cells by fusing green fluorescent protein (GFP) to the GPI-attachment site of CD59. The resultant GFP-GPI has properties comparable to that of endogenously expressed GPI-anchored molecules as shown by Triton X-114 partitioning. However, sucrose gradient floatation showed that GFP-GPI was only partially resistant to detergent solubilisation. Furthermore confocal scanning laser microscopy revealed a homogeneous distribution of GFP-GPI at the cell surface, which only became clustered following cross-linking of the GPI anchor via an anti-GFP antibody. Surprisingly, GFP-GPI signalled Ca2+ change upon cross-linking demonstrating its signalling competence. Our results suggest that the GPI-anchor itself does not confer a clustered distribution to molecules but that clustering occurs following ligation with antibody, which allows the protein to become Ca2+ signalling competent.     

Cu(I) recognition via cation-pi and methionine interactions in CusF

Methionine-rich motifs have an important role in copper trafficking factors, including the CusF protein. Here we show that CusF uses a new metal recognition site wherein Cu(I) is tetragonally displaced from a Met2His ligand plane toward a conserved tryptophan. Spectroscopic studies demonstrate that both thioether ligation and strong cation-pi interactions with tryptophan stabilize metal binding. This novel active site chemistry affords mechanisms for control of adventitious metal redox and substitution chemistry.     

猪冠状动脉前降支结扎位点和左室功能的线性回归

目的探讨猪冠状动脉前降支(LAD)结扎百分位点和心梗体积、左室射血分数的关系,以期指导研究者能够根据急性心肌梗死模型的心功能要求选择合适的LAD结扎百分位点。方法将47只小型猪开胸结扎心脏LAD中远段约30%~75%的不同百分位点,分别于术前、术后1 h心脏超声检查左室射血分数(LVEF),术后3 d进行常规冠状动脉造影,4周处死测量前降支结扎位点和梗死体积,最后用简单直线回归模型分析LAD结扎百分位点和心梗体积、左室射血分数回归方程和相关系数。结果47例动物手术过程中死亡8只,剩余39只存活动物冠状动脉造影均显示LAD中远段结扎部位处完全闭塞,表明手术成功。LAD结扎百分位点和术后1 h LVEF、术后1 hLVEF下降值、梗死心肌体积均明显相关(相关系数r分别为0.87、0.78和0.90,P均<0.001),其回归方程分别为:术后LVEF(%)=65.88-0.55x结扎百分位点;术后LVEF下降值(%)=0.12 0.59x结扎百分位点;心肌梗死体积(%)=0.53x结扎百分位点-5.43。结论猪LAD结扎百分位点和术后左室功能、梗死心肌体积均存在显著的相关性,可根据实验目的和对心功能的要求选择合适的结扎百分位点。     

Studies of ion channels using expressed protein ligation

Expressed protein ligation (EPL) is a semisynthetic technique for the chemoselective ligation of a synthetic peptide to a recombinant peptide that results in a native peptide bond at the ligation site. EPL therefore allows us to engineer proteins with chemically defined, site-specific modifications. While EPL has been used mainly in investigations of soluble proteins, in recent years it has been increasingly used in investigations of integral membrane proteins. These include studies on the KcsA K(+) channel, the non-selective cation channel NaK, and the porin OmpF. These studies are discussed in this review.     

The efficiency of mispaired ligations by lambda integrase is extremely sensitive to context

The integrase protein (Int) of phage lambda is a well-studied representative of the tyrosine recombinase family, whose defining features are two sequential pairs of DNA cleavage/ligation reactions that proceed via a 3' phosphotyrosine covalent intermediate to first form and then resolve a Holliday junction recombination intermediate. We devised an assay that takes advantage of DNA hairpin formation at one Int target site to trap Int cleavages at a different target site, and thereby reveal iterative cycles of cleavage and ligation that would otherwise be undetected. Using this assay and others to compare wild-type Int and a mutant (R169D) defective in forming proper dimer/tetramer interfaces, we found that the efficiency of "bottom-strand" DNA cleavage by wild-type Int, but not R169D, is very sensitive to the base-pair at the "top-strand" cleavage site, seven base-pairs away. We show that this is related to the finding that hairpin formation involving ligation of a mispaired base is much faster for R169D than for wild-type Int, but only in the context of a multimeric complex. During resolution of Holliday junction recombination intermediates, wild-type Int, but not R169D, is very sensitive to homology at the sites of ligation. A long-sought insight from these results is that during Holliday junction resolution the tetrameric Int complex remains intact until after ligation of the product helices has been completed. This contrasts with models in which the second pair of DNA cleavages is a trigger for dissolution of the recombination complex.     

Structural flexibility in Trypanosoma brucei enolase revealed by X-ray crystallography and molecular dynamics

Enolase is a validated drug target in Trypanosoma brucei. To better characterize its properties and guide drug design efforts, we have determined six new crystal structures of the enzyme, in various ligation states and conformations, and have carried out complementary molecular dynamics simulations. The results show a striking structural diversity of loops near the catalytic site, for which variation can be interpreted as distinct modes of conformational variability that are explored during the molecular dynamics simulations. Our results show that sulfate may, unexpectedly, induce full closure of catalytic site loops whereas, conversely, binding of inhibitor phosphonoacetohydroxamate may leave open a tunnel from the catalytic site to protein surface offering possibilities for drug development. We also present the first complex of enolase with a novel inhibitor 2-fluoro-2-phosphonoacetohydroxamate. The molecular dynamics results further encourage efforts to design irreversible species-specific inhibitors: they reveal that a parasite enzyme-specific lysine may approach the catalytic site more closely than crystal structures suggest and also cast light on the issue of accessibility of parasite enzyme-specific cysteines to chemically modifying reagents. One of the new sulfate structures contains a novel metal-binding site IV within the catalytic site cleft.     

Rearrangement of substrate secondary structure facilitates binding to the Neurospora VS ribozyme

The Neurospora VS ribozyme differs from other small, naturally occurring ribozymes in that it recognizes for trans cleavage or ligation a substrate that consists largely of a stem-loop structure. We have previously found that cleavage or ligation by the VS ribozyme requires substantial rearrangement of the secondary structure of stem-loop I, which contains the cleavage/ligation site. This rearrangement includes breaking the top base-pair of stem-loop I, allowing formation of a kissing interaction with loop V, and changing the partners of at least three other base-pairs within stem-loop I to adopt a conformation termed shifted. In the work presented, we have designed a binding assay and used mutational analysis to investigate the contribution of each of these structural changes to binding and ligation. We find that the loop I-V kissing interaction is necessary but not sufficient for binding and ligation. Constitutive opening of the top base-pair of stem-loop I has little, if any, effect on either activity. In contrast, the ability to adopt the shifted conformation of stem-loop I is a major determinant of binding: mutants that cannot adopt this conformation bind much more weakly than wild-type and mutants with a constitutively shifted stem-loop I bind much more strongly. These results implicate the adoption of the shifted structure of stem-loop I as an important process at the binding step in the VS ribozyme reaction pathway. Further investigation of features near the cleavage/ligation site revealed that sulphur substitution of the non-bridging phosphate oxygen atoms immediately downstream of the cleavage/ligation site, implicated in a putative metal ion binding site, significantly altered the cleavage/ligation equilibrium but did not perturb substrate binding significantly. This indicates that the substituted oxygen atoms, or an associated metal ion, affect a step that occurs after binding and that they influence the rates of cleavage and ligation differently.