Protein-tyrosine phosphatase 1B (PTP1B) has recently received much attention as a potential drug target in type 2 diabetes. This has in particular been spurred by the finding that PTP1B knockout mice show increased insulin sensitivity and resistance to diet-induced obesity. Surprisingly, the highly homologous T cell protein-tyrosine phosphatase (TC-PTP) has received much less attention, and no x-ray structure has been provided. We have previously co-crystallized PTP1B with a number of low molecular weight inhibitors that inhibit TC-PTP with similar efficiency. Unexpectedly, we were not able to co-crystallize TC-PTP with the same set of inhibitors. This seems to be due to a multimerization process where residues 130 -132, the DDQ loop, from one molecule is inserted into the active site of the neighboring molecule, resulting in a continuous string of interacting TC-PTP molecules. Importantly, despite the high degree of functional and structural similarity between TC-PTP and PTP1B, we have been able to identify areas close to the active site that might be addressed to develop selective inhibitors of each enzyme.Protein-tyrosine phosphatases (PTPs) 1 are key regulators of signal transduction processes (1, 2). The family of classical PTPs can be divided into two broad categories as intracellular and receptor-like PTPs covering a total of 17 subtypes (3). Receptor-like PTPs contain an extracellular domain, a single transmembrane domain, and one or two cytoplasmic PTP domains. Intracellular PTPs generally contain one PTP domain and an N-or C-terminal domain that targets the enzymes to specific subcellular localizations, as exemplified by the targeting of PTP1B to the endoplasmic reticulum (4).PTP1B and TC-PTP are two closely related intracellular enzymes. PTP1B was the first protein-tyrosine phosphatase to be identified and characterized (5, 6). Shortly after this landmark event, PTP1B was cloned from a placenta cDNA library (7), and TC-PTP was cloned from a peripheral human T cell cDNA library (8). Despite its name, TC-PTP is ubiquitously expressed (9). Alternative splicing gives rise to two forms of TC-PTP that differ in the C termini, a 45-kDa form that is targeted to the nucleus and a 48-kDa form that localizes to the endoplasmic reticulum via a hydrophobic C-terminal region (10). TC-PTP is tightly regulated during the cell cycle and seems to play an important role in mitogenesis (9). In a recent study, it was shown that cellular stress causes reversible cytoplasmic accumulation of the 45-kDa form of TC-PTP (i.e. the nuclear form) (11).Although they have a sequence identity of about 74% in the catalytic domains (see Fig. 1), TC-PTP and PTP1B clearly fulfill different biological functions, as has been demonstrated in knock-out mice. Thus, although PTP1B knock-out mice show increased insulin sensitivity and resistance to diet-induced obesity and are viable with a normal life span (12, 13), TC-PTP knock-out mice die at 3-5 weeks of age (14).In accordance with these in vivo observations, substrate trapping experiment...
The serotonin transporter (SERT) is one of the neurotransmitter transporters that plays a critical role in the regulation of endogenous amine concentrations and therefore is an important target for therapeutic agents affecting the central nervous system. The recently published, high resolution X-ray structure of the closely related amino acid transporter, Aquifex aeolicus leucine transporter (LeuT), provides an opportunity to develop a three-dimensional model of the structure of SERT. We present herein a homology model of SERT using LeuT as the template and containing escitalopram as a bound ligand. Our model explains selectivities known from mutational studies and varying ligand data, which are discussed and illustrated in the paper.
We have performed molecular dynamics simulations of a homology model of the human serotonin transporter (hSERT) in a membrane environment and in complex with either the natural substrate 5-HT or the selective serotonin reuptake inhibitor escitalopram. We have also included a transporter homologue, the Aquifex aeolicus leucine transporter (LeuT), in our study to evaluate the applicability of a simple and computationally attractive membrane system. Fluctuations in LeuT extracted from simulations are in good agreement with crystallographic B factors. Furthermore, key interactions identified in the X-ray structure of LeuT are maintained throughout the simulations indicating that our simple membrane system is suitable for studying the transmembrane protein hSERT in complex with 5-HT or escitalopram. For these transporter complexes, only relatively small fluctuations are observed in the ligand-binding cleft. Specific interactions responsible for ligand recognition, are identified in the hSERT-5HT and hSERT-escitalopram complexes. Our findings are in good agreement with predictions from mutagenesis studies.
IA-2 is a major target of autoimmunity in type 1 diabetes. IA-2 responsive T cells recognize determinants within regions represented by amino acids 787-817 and 841-869 of the molecule. Epitopes for IA-2 autoantibodies are largely conformational and not well defined. In this study, we used peptide phage display and homology modeling to characterize the epitope of a monoclonal IA-2 Ab (96/3) from a human type 1 diabetic patient. This Ab competes for IA-2 binding with Abs from the majority of patients with type 1 diabetes and therefore binds a region close to common autoantibody epitopes. Alignment of peptides obtained after screening phage-displayed peptide libraries with purified 96/3 identified a consensus binding sequence of Asn-x-Glu-x-x-(aromatic)-x-x-Gly. The predicted surface on a three-dimensional homology model of the tyrosine phosphatase domain of IA-2 was analyzed for clusters of Asn, Glu, and aromatic residues and amino acids contributing to the epitope investigated using site-directed mutagenesis. Mutation of each of amino acids Asn(858), Glu(836), and Trp(799) reduced 96/3 Ab binding by >45%. Mutations of these residues also inhibited binding of serum autoantibodies from IA-2 Ab-positive type 1 diabetic patients. This study identifies a region commonly recognized by autoantibodies in type 1 diabetes that overlaps with dominant T cell determinants.
Liposomale Wirkstofftransportsysteme, in denen Vorstufen durch krankheitsspezifische Enzyme aktiviert werden, haben ein großes Potenzial für die Therapie von Erkrankungen wie Krebs. Eine neuartige Wirkstoffvorstufe auf Phospholipidbasis kann stabile kleine unilamellare Vesikel aufbauen (siehe Bild). Die Aktivierung dieser Vesikel durch das Enzym sPLA2 löst eine Cyclisierungsreaktion aus, die zur Freisetzung des Wirkstoffs führt.
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