The three-dimensional structure of the lipase-procolipase complex, co-crystallized with mixed micelles of phosphatidylcholine and bile salt, has been determined at 3 A resolution by X-ray crystallography. The lid, a surface helix covering the catalytic triad of lipase, adopts a totally different conformation which allows phospholipid to bind to the enzyme's active site. The open lid is an essential component of the active site and interacts with procolipase. Together they form the lipid-water interface binding site. This reorganization of the lid structure provokes a second drastic conformational change in an active site loop, which in its turn creates the oxyanion hole (induced fit).
Limited action of papain on the native forms of two cellobiohydrolases (CBH) from Trichoderma reesei (CBH I, 65 kDa, and CBH II,58 kDa) leads to the isolation of the respective core fragments (56 kDa and 45 kDa) which are fully active on small, soluble substrates, but have a strongly reduced activity (respectively 10% and 50% of the initial value) on microcrystalline cellulose (Avicel).By partial sequencing at the C terminus of the CBH I core and at the N terminus of the CBH I1 core the papain cleavage sites have been assigned in the primary structures (at about residue 431 and 82 respectively). This limited action of papain on the native enzymes indicates the presence of hinge regions linking the core to these terminal glycopeptides. The latter conserved sequences appear either at the C or N terminus of several cellulolytic enzymes from ~r~c~o d e r m a reesei [Teeri et al. (1987) Gene 51,43 -521. The specific activities of the intact enzymes and their cores on two forms of insoluble cellulose (crystalline, amorphous) differentiate the CBH I and CBH TI in terms of adsorption and catalytic properties, Distinct functions can be attributed to the terminal peptides: for intact CBH I1 the N-terminal region contributes in the binding onto both cellulose types; the homologous C-terminal peptide in CBH I, however, only affects the interaction with microcrystalline cellulose. It could be inferred that CBH I and its core bind preferentially to crystalline regions. This seems to be corroborated by the results of CBH I/CBH I1 synergism experiments.The filamentous fungus Trichoderma reesei presents an ideal system for the study of cellulose hydrolysis since it produces a variety of enzymes including endocellulase and exocellulase (cellobiohydrolases) and b-glucosidases (cellobiases) [l]. The primary structure of several of these proteins is presently known [2 -61 but no structure/function relationships have yet been established. The two cellobiohydrolases, CBH I and CBH I1 [7 -111, lack any apparent homology in their amino acid sequence except for a conserved region present at their C and N termini respectively [4].Their action is similar both with regard to their strong adsorption onto insoluble substrates and lack of carboxymethylcellulase activity. However, studies both with microcrystalline cellulose [9] and small, soluble substrates [I 21 reveal some differences in specificity. In addition, the two cellobiohydrolases interact synergistically both with each other and with endoglucanases on microcrystalline substrates In order to differentiate these enzymes further by their function and to investigate possible domain structure, proteolysis studies were performed. Preliminary results on the limited action of papain on native CBH I have been reported by us [16]. Two fragments were isolated: first, a heavily glycosylated peptide, tentatively identified with the C terminus; secondly, a core protein containing the active (hydrolytic) site. The terminal peptide was characterised as an independent structural and functional dom...
The DEAH/RNA helicase A (RHA) helicase family comprises proteins involved in splicing, ribosome biogenesis and transcription regulation. We report the structure of yeast Prp43p, a DEAH/RHA helicase remarkable in that it functions in both splicing and ribosome biogenesis. Prp43p displays a novel structural architecture with an unforeseen homology with the Ski2-like Hel308 DNA helicase. Together with the presence of a b-hairpin in the second RecA-like domain, Prp43p contains all the structural elements of a processive helicase. Moreover, our structure reveals that the C-terminal domain contains an oligonucleotide/oligosaccharide-binding (OB)-fold placed at the entrance of the putative nucleic acid cavity. Deletion or mutations of this domain decrease the affinity of Prp43p for RNA and severely reduce Prp43p ATPase activity in the presence of RNA. We also show that this domain constitutes the binding site for the G-patch-containing domain of Pfa1p. We propose that the C-terminal domain, specific to DEAH/RHA helicases, is a central player in the regulation of helicase activity by binding both RNA and G-patch domain proteins.
Galloway-Mowat syndrome (GAMOS) is a severe autosomal-recessive disease characterized by the combination of early-onset steroid-resistant nephrotic syndrome (SRNS) and microcephaly with brain anomalies. To date, mutations of WDR73 are the only known monogenic cause of GAMOS and in most affected individuals the molecular diagnosis remains elusive. We here identify recessive mutations of OSGEP, TP53RK, TPRKB, or LAGE3, encoding the 4 subunits of the KEOPS complex in 33 individuals of 30 families with GAMOS. CRISPR/Cas9 knockout in zebrafish and mice recapitulates the human phenotype of microcephaly and results in early lethality. Knockdown of OSGEP, TP53RK, or TPRKB inhibits cell proliferation, which human mutations fail to rescue, and knockdown of either gene activates DNA damage response signaling and induces apoptosis. OSGEP and TP53RK molecularly interact and co-localize with the actin-regulating ARP2/3 complex. Furthermore, knockdown of OSGEP and TP53RK induces defects of the actin cytoskeleton and reduces migration rate of human podocytes, an established intermediate phenotype of SRNS. We thus identify 4 novel monogenic causes of GAMOS, describe the first link between KEOPS function and human disease, and delineate potential pathogenic mechanisms.
Pancreatic lipase belongs to the serine esterase family and can therefore be inhibited by classical serine reagents such as diisopropyl fluoride or E600. In an attempt to further characterize the active site and catalytic mechanism, we synthesized a C11 alkyl phosphonate compound. This compound is an effective inhibitor of pancreatic lipase. The crystal structure of the pancreatic lipase-colipase complex inhibited by this compound was determined at a resolution of 2.46 A and refined to a final R-factor of 18.3%. As was observed in the case of the structure of the ternary pancreatic lipase-colipase-phospholipid complex, the binding of the ligand induces rearrangements of two surface loops in comparison with the closed structure of the enzyme (van Tilbeurgh et al., 1993b). The inhibitor, which could be clearly observed in the active site, was covalently bound to the active site serine Ser152. A racemic mixture of the inhibitor was used in the crystallization, and there exists evidence that both enantiomers are bound at the active site. The C11 alkyl chain of the first enantiomer fits into a hydrophobic groove and is though to thus mimic the interaction between the leaving fatty acid of a triglyceride substrate and the protein. The alkyl chain of the second enantiomer also has an elongated conformation and interacts with hydrophobic patches on the surface of the open amphipathic lid. This may indicate the location of a second alkyl chain of a triglyceride substrate. Some of the detergent molecules, needed for the crystallization, were also observed in the crystal. Some of them were located at the entrance of the active site, bound to the hydrophobic part of the lid. On the basis of this crystallographic study, a hypothesis about the binding mode of real substrates and the organization of the active site is proposed.
Interfacial adsorption of pancreatic lipase is strongly dependent on the physical chemical properties of the lipid surface. These properties are affected by amphiphiles such as phospholipids and bile salts. In the presence of such amphiphiles, lipase binding to the interface requires a protein cofactor, colipase. We obtained crystals of the pancreatic lipase-procolipase complex and solved the structure at 3.04 A resolution. Here we describe the structure of procolipase, which essentially consists of three 'fingers' and is topologically comparable to snake toxins. The tips of the fingers contain most of the hydrophobic amino acids and presumably form the interfacial binding site. Lipase binding occurs at the opposite side to this site and involves polar interactions. Determination of the three-dimensional structure of pancreatic lipase has revealed the presence of two domains: an amino-terminal domain, at residues 1-336 containing the active site and a carboxy-terminal domain at residues 337-449 (ref. 6). Procolipase binds exclusively to the C-terminal domain of lipase. No conformational change in the lipase molecule is induced by the binding of procolipase.
Limited proteolysis of the cellobiohydrolase I (CBH I, 65 kDa) from Trichoderma reesei by papain yields a core protein (56 kDa) which is fully active against small, soluble substrates such as the chromophoric glycosides derived from the cellodextrins and lactose. Activity against an insoluble substrate, such as Avicel, is however completely lost and concomitantly decreased adsorption onto this microcrystalline cellulose is observed. The peptide (10 kDa), initially split off during proteolysis, is identified as the heavily glycosylated carboxy‐terminal of the native CBH I. Depending on the experimental conditions the core protein is further nicked in between disulfide bonds, but its properties and stability do not appreciably differ from those of intact CBH I. These results lead to the proposal of a bifunctional organisation of the CBH I: one domain, corresponding to the carboxyterminal, acts as a binding site for insoluble cellulose and the other, localised in the core protein, contains the active (hydrolytic) site.
Transformation promotes genome plasticity in bacteria via RecAdriven homologous recombination. In the Gram-positive human pathogen Streptococcus pneumoniae, the transformasome a multiprotein complex, internalizes, protects, and processes transforming DNA to generate chromosomal recombinants. Double-stranded DNA is internalized as single strands, onto which the transformation-dedicated DNA processing protein A (DprA) ensures the loading of RecA to form presynaptic filaments. We report that the structure of DprA consists of the association of a sterile alpha motif domain and a Rossmann fold and that DprA forms tail-totail dimers. The isolation of DprA self-interaction mutants revealed that dimerization is crucial for the formation of nucleocomplexes in vitro and for genetic transformation. Residues important for DprARecA interaction also were identified and mutated, establishing this interaction as equally important for transformation. Positioning of key interaction residues on the DprA structure revealed an overlap of DprA-DprA and DprA-RecA interaction surfaces. We propose a model in which RecA interaction promotes rearrangement or disruption of the DprA dimer, enabling the subsequent nucleation of RecA and its polymerization onto ssDNA.bacterial transformation | genetic exchange | recombinase loader | recombination mediator protein | horizontal gene transfer
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