Mapping the binding site of full length HIV-1 Nef on human Lck SH3 by NMR spectroscopy

The Nef protein of human immunodeficiency virus type 1 (HIV-1) is known to directly bind to the SH3 domain of human lymphocyte specific kinase (Lck) via a proline-rich region located in the amino terminal part of Nef. To address the question whether Nef binding to Lck SH3 involves residues outside the typical poly-proline peptide binding site and whether the Lck unique domain is involved in Nef-Lck interaction, we studied the direct interaction between both molecules using recombinant full-length HIV-1 Nef protein on one side and recombinantly expressed and uniformly 15N-isotope labeled Lck protein comprising unique and SH3 domains on the other side. Applying nuclear magnetic resonance spectroscopy we could show that only residues of Lck SH3, that are typically involved in binding poly-proline peptides, are affected by Nef binding. Further, for the first time we could rule out that residues of Lck unique domain are involved in binding to full length Nef protein. Thus, interactions of Lck unique domain to cellular partners e.g. CD4 or CD8, are not necessarily competitive with Lck binding to HIV-1 Nef

Nef protein of human immunodeficiency virus type 1 binds its own myristoylated N-terminus

HIV-1 Nef is a small protein (approx. 25 kDa) that is posttranslationally modified by myristoylation. To explain its complex activities, a 'Nef-cycle' is discussed, which postulates different molecular conformations of Nef. Using recombinant full-length non-myristoylated Nef and synthetic peptides, we demonstrate by fluorescence titration experiments that a peptide representing the myristoylated N-terminus of Nef is specifically bound by Nef. A non-myristoylated N-terminal fragment of Nef or a myristoylated control peptide does not bind to Nef. These results are the first direct experimental evidence of the existence of a myristate-binding pocket in Nef, a prerequisite of the postulated 'closed' Nef conformation

Expression, localization, structural, and functional characterization of pFGE, the paralog of the C alpha-formylglycine-generating enzyme

Mariappan M, Preusser-Kunze A, Balleininger M, et al. Expression, localization, structural, and functional characterization of pFGE, the paralog of the C alpha-formylglycine-generating enzyme. JOURNAL OF BIOLOGICAL CHEMISTRY. 2005;280(15):15173-15179.pFGE is the paralog of the formylglycine-generating enzyme (FGE), which catalyzes the oxidation of a specific cysteine to C alpha-formylglycine, the catalytic residue in the active site of sulfatases. The enzymatic activity of sulfatases depends on this posttranslational modification, and the genetic defect of FGE causes multiple sulfatase deficiency. The structural and functional properties of pFGE were analyzed. The comparison with FGE demonstrates that both share a tissue-specific expression pattern and the localization in the lumen of the endoplasmic reticulum. Both are retained in the endoplasmic reticulum by a saturable mechanism. Limited proteolytic cleavage at similar sites indicates that both also share a similar three-dimensional structure. pFGE, however, is lacking the formylglycine-generating activity of FGE. Although overexpression of FGE stimulates the generation of catalytically active sulfatases, overexpression of pFGE has an inhibitory effect. In vitro pFGE interacts with sulfatase-derived peptides but not with FGE. The inhibitory effect of pFGE on the generation of active sulfatases may therefore be caused by a competition of pFGE and FGE for newly synthesized sulfatase polypeptides

Eukaryotic formylglycine-generating enzyme catalyses a monooxygenase type of reaction

Peng J, Alam S, Radhakrishnan K, et al. Eukaryotic formylglycine-generating enzyme catalyses a monooxygenase type of reaction. FEBS Journal. 2015;282(17):3262-3274.C alpha-formylglycine (FGly) is the catalytic residue of sulfatases in eukaryotes. It is generated by a unique post-translational modification catalysed by the FGly-generating enzyme (FGE) in the endoplasmic reticulum. FGE oxidizes a cysteine residue within the conserved CxPxR sequence motif of nascent sulfatase polypeptides to FGly. Here we show that this oxidation is strictly dependent on molecular oxygen (O-2) and consumes 1 mol O-2 per mol FGly formed. For maximal activity FGE requires an O-2 concentration of 9% (105 mu M). Sustained FGE activity further requires the presence of a thiol-based reductant such as DTT. FGly is also formed in the absence of DTT, but its formation ceases rapidly. Thus inactivated FGE accumulates in which the cysteine pair Cys336/Cys341 in the catalytic site is oxidized to form disulfide bridges between either Cys336 and Cys341 or Cys341 and the CxPxR cysteine of the sulfatase. These results strongly suggest that the Cys336/Cys341 pair is directly involved in the O-2-dependent conversion of the CxPxR cysteine to FGly. The available data characterize eukaryotic FGE as a monooxygenase, in which Cys336/Cys341 disulfide bridge formation donates the electrons required to reduce one oxygen atom of O-2 to water while the other oxygen atom oxidizes the CxPxR cysteine to FGly. Regeneration of a reduced Cys336/Cys341 pair is accomplished in vivo by a yet unknown reductant of the endoplasmic reticulum or in vitro by DTT. Remarkably, this monooxygenase reaction utilizes O-2 without involvement of any activating cofactor

Molecular basis for multiple sulfatase deficiency and mechanism for formylglycine generation of the human formylglycine-generating enzyme

Dierks T, Dickmanns A, Preusser-Kunze A, et al. Molecular basis for multiple sulfatase deficiency and mechanism for formylglycine generation of the human formylglycine-generating enzyme. CELL. 2005;121(4):541-552.Sulfatases are enzymes essential for degradation and remodeling of sulfate esters. Formylglycine (FGly), the key catalytic residue in the active site, is unique to sulfatases. In higher eukaryotes, FGly is generated from a cysteine precursor by the FGly-generating enzyme (FGE). Inactivity of FGE results in multiple sulfatase deficiency (MSD), a fatal autosomal recessive syndrome. Based on the crystal structure, we report that FGE is a single-domain monomer with a surprising paucity of secondary structure and adopts a unique fold. The effect of all 18 missense mutations found in MSD patients is explained by the FGE structure, providing a molecular basis of MSD. The catalytic mechanism of FGly generation was elucidated by six high-resolution structures of FGE in different redox environments. The structures allow formulation of a novel oxygenase mechanism whereby FGE utilizes molecular oxygen to generate FGly via a cysteine sulfenic acid intermediate

The non-catalytic N-terminal extension of formylglycine-generating enzyme is required for its biological activity and retention in the endoplasmic reticulum

Mariappan M, Gande SL, Radhakrishnan K, Schmidt B, Dierks T, von Figura K. The non-catalytic N-terminal extension of formylglycine-generating enzyme is required for its biological activity and retention in the endoplasmic reticulum. JOURNAL OF BIOLOGICAL CHEMISTRY. 2008;283(17):11556-11564.Formylglycine-generating enzyme (FGE) catalyzes the oxidation of a specific cysteine residue in nascent sulfatase polypeptides to formylglycine (FGly). This FGly is part of the active site of all sulfatases and is required for their catalytic activity. Here we demonstrate that residues 34-68 constitute an N-terminal extension of the FGE catalytic core that is dispensable for in vitro enzymatic activity of FGE but is required for its in vivo activity in the endoplasmic reticulum (ER), i.e. for generation of FGly residues in nascent sulfatases. In addition, this extension is needed for the retention of FGE in the ER. Fusing a KDEL retention signal to the C terminus of FGE is sufficient to mediate retention of an N-terminally truncated FGE but not sufficient to restore its biological activity. Fusion of FGE residues 1-88 to secretory proteins resulted in ER retention of the fusion protein. Moreover, when fused to the paralog of FGE (pFGE), which itself lacks FGly-generating activity, the FGE extension ( residues 34-88) of this hybrid construct led to partial restoration of the biological activity of co-expressed N-terminally truncated FGE. Within the FGE N-terminal extension cysteine 52 is critical for the biological activity. We postulate that this N-terminal region of FGE mediates the interaction with an ER component to be identified and that this interaction is required for both the generation of FGly residues in nascent sulfatase polypeptides and for retention of FGE in the ER

Crystal structure of human pFGE, the paralog of the C alpha-formylglycine-generating enzyme

Dickmanns A, Schmidt B, Rudolph MG, et al. Crystal structure of human pFGE, the paralog of the C alpha-formylglycine-generating enzyme. JOURNAL OF BIOLOGICAL CHEMISTRY. 2005;280(15):15180-15187.In eukaryotes, sulfate esters are degraded by sulfatases, which possess a unique C alpha-formylglycine residue in their active site. The defect in post-translational formation of the C alpha-formylglycine residue causes a severe lysosomal storage disorder in humans. Recently, FGE (formylglycine-generating enzyme) has been identified as the protein required for this specific modification. Using sequence comparisons, a protein homologous to FGE was found and denoted pFGE (paralog of FGE). pFGE binds a sulfatase-derived peptide bearing the FGE recognition motif, but it lacks formylglycine-generating activity. Both proteins belong to a large family of pro- and eukaryotic proteins containing the DUF323 domain, a formylglycine-generating enzyme domain of unknown three-dimensional structure. We have crystallized the glycosylated human pFGE and determined its crystal structure at a resolution of 1.86 angstrom. The structure reveals a novel fold, which we denote the FGE fold and which therefore serves as a paradigm for the DUF323 domain. It is characterized by an asymmetric partitioning of secondary structure elements and is stabilized by two calcium cations. A deep cleft on the surface of pFGE most likely represents the sulfatase polypeptide binding site. The asymmetric unit of the pFGE crystal contains a homodimer. The putative peptide binding site is buried between the monomers, indicating a biological significance of the dimer. The structure suggests the capability of pFGE to form a heterodimer with FGE

Arylsulfatase K, a Novel Lysosomal Sulfatase

Wiegmann E, Westendorf E, Kalus I, Pringle TH, Lübke T, Dierks T. Arylsulfatase K, a Novel Lysosomal Sulfatase. Journal of Biological Chemistry. 2013;288(42):30019-30028.The human sulfatase family has 17 members, 13 of which have been characterized biochemically. These enzymes specifically hydrolyze sulfate esters in glycosaminoglycans, sulfolipids, or steroid sulfates, thereby playing key roles in cellular degradation, cell signaling, and hormone regulation. The loss of sulfatase activity has been linked to severe pathophysiological conditions such as lysosomal storage disorders, developmental abnormalities, or cancer. A novel member of this family, arylsulfatase K (ARSK), was identified bioinformatically through its conserved sulfatase signature sequence directing posttranslational generation of the catalytic formylglycine residue in sulfatases. However, overall sequence identity of ARSK with other human sulfatases is low (18-22%). Here we demonstrate that ARSK indeed shows desulfation activity toward arylsulfate pseudosubstrates. When expressed in human cells, ARSK was detected as a 68-kDa glycoprotein carrying at least four N-glycans of both the complex and high-mannose type. Purified ARSK turned over p-nitrocatechol and p-nitrophenyl sulfate. This activity was dependent on cysteine 80, which was verified to undergo conversion to formylglycine. Kinetic parameters were similar to those of several lysosomal sulfatases involved in degradation of sulfated glycosaminoglycans. An acidic pH optimum (4.6) and colocalization with LAMP1 verified lysosomal functioning of ARSK. Further, it carries mannose 6-phosphate, indicating lysosomal sorting via mannose 6-phosphate receptors. ARSK mRNA expression was found in all tissues tested, suggesting a ubiquitous physiological substrate and a so far non-classified lysosomal storage disorder in the case of ARSK deficiency, as shown before for all other lysosomal sulfatases