Tumor necrosis factor-␣ (TNF) is initially expressed as a 26-kDa membrane-bound precusor protein (pro-TNF) that is shed proteolytically from the cell surface, releasing soluble 17-kDa TNF. We have identified human ADAM 10 (HuAD10) from THP-1 membrane extracts as a metalloprotease that specifically clips a peptide substrate spanning the authentic cleavage site between Ala 76 and Val 77 in pro-TNF. To confirm that HuAD10 has TNF processing activity, we cloned, expressed, and purified an active, truncated form of HuAD10. Characterization of recombinant HuAD10 (rHuAD10) suggests that this enzyme has many of the properties (i.e. substrate specificity, metalloprotease activity, cellular location) expected for a physiologically relevant TNF-processing enzyme. Tumor necrosis factor-␣ (TNF)1 is a cytokine that is produced primarily by activated monocytes and macrophages in response to a variety of physiological stresses such as infection or injury (1). Clinical and experimental evidence has also identified TNF as a mediator of chronic autoimmune diseases such as rheumatoid arthritis (2) and Crohn's disease (3), as well as being involved in the pathology associated with sepsis (1). Accordingly, TNF has become a primary target for therapeutic intervention of several inflammatory diseases.TNF is initially synthesized as a 26-kDa membrane-bound protein (pro-TNF) that is subsequently cleaved to release soluble 17-kDa TNF with an NH 2 terminus of Val 77 (4). The identity of the protease(s) responsible for TNF processing remains controversial. Robache-Gallea et al. (5) detected a serine protease activity (PR3) in monocyte membrane preparations which was able to generate a 17-kDa active TNF with an NH 2 terminus of Arg 78 . In 1994, the partial isolation and characterization of a membrane-bound activity capable of generating the 17-kDa form of TNF were reported (6). The TNF-processing enzyme was thought to be a non-matrix metalloprotease since it was not inhibited by TIMP-1,2 or phosphoramidon, and no calcium requirement was detected. More recently, two members of the ADAM family (TNF-␣ converting enzyme (TACE) and bovine ADAM 10 (BoAD10)) have been shown to possess pro-TNF processing activity (7-9).In this report we describe the isolation, cloning, and characterization of a TNF-processing enzyme from the human monocytic cell line THP-1. The purified recombinant enzyme, rHuAD10, specifically recognizes the authentic cleavage site in pro-TNF and is sensitive to metalloprotease inhibitors that block soluble TNF production (6). MATERIALS AND METHODSReagents-Dinitrophenol-labeled polypeptides were synthesized by the Fmoc (N-(9-fluorenyl)methoxycarbonyl)/t-butyl-based solid phase peptide chemistry method using an Applied Biosystems, Inc. 431A peptide synthesizer (10). All peptides were purified by reversed phase HPLC, and molecular weights were verified by mass spectrometry.HPLC Peptide Assay-TNF processing activity was measured as the ability to cleave a 12-residue peptide spanning the Ala 76 -Val 77 site in pro-TNF. The chromatopho...
We determined the dissociation constant (Kd) of a series of nucleotides for the bovine skeletal muscle type II catalytic subunit by displacing lin-benzoadenosine 5'-diphosphate (lin-benzo-ADP) with increasing concentrations of competing nucleotide. The Kd of each nucleotide was calculated from the decreases in the fluorescence polarization of lin-benzo-ADP that accompany its displacement from the catalytic subunit. We found that modifications of the adenine moiety reduce nucleotide affinity for the enzyme. The effect was most pronounced with modifications at position 6 of the base. Replacement of the 3'-hydroxyl group of ribose with a hydrogen increased the affinity of the nucleotide; addition of phosphate to the 2'- or 3'-hydroxyl groups, on the other hand, decreased nucleotide affinity. MgATP and MgADP exhibited Kd's of about 10 microM. AMP, which contains a negatively charged alpha-phosphate, bound with reduced affinity (643 microM). Adenosine, which lacks a charged alpha-phosphate, bound with a higher affinity (32 microM). To learn more about the nature of the alpha-phosphate binding site, a series of uncharged and positively charged derivatives of the 5'-position on the ribose moiety was prepared. The uncharged derivatives bound with much greater affinity than the negatively charged AMP. The Kd's for 5'-tosyladenosine and 5'-iodo-5'-deoxyadenosine were 30 and 32 microM, respectively. Like the negatively charged AMP, positively charged derivatives also bound less tenaciously than the neutral species. The positively charged 5'-amino-5'deoxyadenosine, for example, exhibited a 15-fold higher Kd (506 microM) than the neutral congenors.(ABSTRACT TRUNCATED AT 250 WORDS)
Recombinant interferon alpha-2 (IFN-alpha2) is used clinically to treat a variety of viral diseases and cancers. IFN-alpha2 has a short circulating half-life, which necessitates frequent administration to patients. Previous studies showed that it is possible to extend the circulating half-life of IFN-alpha2 by modifying lysine residues of the protein with amine-reactive poly(ethylene glycol) (PEG) reagents. However, amine-PEGylated IFN-alpha2 comprises a heterogeneous product mixture with low specific activity due to the large number and critical locations of lysine residues in IFN-alpha2. In an effort to overcome these problems we determined the feasibility of creating site-specific, mono-PEGylated IFN-alpha2 analogues by introducing a free (unpaired) cysteine residue into the protein, followed by modification of the added cysteine residue with a maleimide-PEG reagent. IFN-alpha2 cysteine analogues were expressed in Escherichia coli and purified, and their in vitro bioactivities were measured in the human Daudi cell line growth inhibition assay. Several cysteine analogues were identified that do not significantly affect in vitro biological activity of IFN-alpha2. Certain of the cysteine analogues, but not wild-type IFN-alpha2, reacted with maleimide-PEG to produce mono-PEGylated proteins. The PEG-Q5C analogue retained high in vitro bioactivity (within 3- to 4-fold of wild-type IFN-alpha2) even when modified with 20- and 40-kDa PEGs. Pharmacokinetic experiments indicated that the 20-kDa PEG-Q5C and 40-kDa PEG-Q5C proteins have 20-fold and 40-fold longer half-lives, respectively, than IFN-alpha2 following subcutaneous administration to rats. These studies demonstrate the feasibility of using site-specific PEGylation technology to create a long-acting, mono-PEGylated IFN-alpha2 protein with high specific activity.
Infection of monocytes with human immunodeficiency virus type 1Ba-L (HIV-1Ba-L ) is significantly inhibited by treatment with the serine protease inhibitor, secretory leukocyte protease inhibitor (SLPI). SLPI does not appear to act on virus directly, but rather the inhibitory activity is most likely due to interaction with the host cell. The current study was initiated to investigate how SLPI interacts with monocytes to inhibit infection. SLPI was found to bind to monocytes with high affinity to a single class of receptor sites (∼7,000 receptors per monocyte, KD = 3.6 nmol/L). The putative SLPI receptor was identified as a surface protein with a molecular weight of 55 ± 5 kD. A well-characterized function of SLPI is inhibition of neutrophil elastase and cathepsin G. However, two SLPI mutants (or muteins) that contain single amino acid substitutions and exhibit greatly reduced protease inhibitory activity still bound to monocytes and retained anti–HIV-1 activity. SLPI consists of two domains, of which the C-terminal domain contains the protease inhibiting region. However, when tested independently, neither domain had potent anti–HIV-1 activity. SLPI binding neither prevented virus binding to monocytes nor attenuated the infectivity of any virus progeny that escaped inhibition by SLPI. A polymerase chain reaction (PCR)-based assay for newly generated viral DNA demonstrated that SLPI blocks at or before viral DNA synthesis. Therefore, it most likely inhibits a step of viral infection that occurs after virus binding but before reverse transcription. Taken together, the unique antiviral activity of SLPI, which may be independent of its previously characterized antiprotease activity, appears to reside in disruption of the viral infection process soon after virus binding.
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