High-resolution separation of amyloid beta-peptides: structural variants present in Alzheimer's disease amyloid.

In Alzheimer's disease (AD), one of the cardinal neuropathological signs is deposition of amyloid, primarily consisting of the amyloid beta-peptide (Abeta). Structural variants of AD-associated Abeta peptides have been difficult to purify by high-resolution chromatographic techniques. We therefore developed a novel chromatographic protocol, enabling high-resolution reverse-phase liquid chromatography (RPLC) purification of Abeta variants displaying very small structural differences. By using a combination of size-exclusion chromatography and the novel RPLC protocol, Abeta peptides extracted from AD amyloid were purified and subsequently characterized. Structural analysis by microsequencing and electrospray-ionization mass spectrometry revealed that the RPLC system resolved a complex mixture of Abeta variants terminating at either residue 40 or 42. Abeta variants differing by as little as one amino acid residue could be purified rapidly to apparent homogeneity. The resolution of the system was further illustrated by its ability to separate the structural isomers of Abeta1-40. The present chromatography system might provide further insight into the role of N-terminally and posttranslationally modified Abeta variants, because each variant can now be studied individually.

The Alzheimer A beta peptide develops protease resistance in association with its polymerization into fibrils.

An intriguing property of the polypeptide constituents of amyloid is that they apparently can escape the proteolytic mechanisms that normally catalyze turnover and prevent abnormal tissue accumulation of polypeptides. Here, we demonstrate that the A beta peptide, the principal component of cerebrovascular amyloid deposits in Alzheimer's disease, becomes resistant to an array of proteases as a result of structural changes associated with its polymerization into amyloid fibrils. It is further demonstrated that fibril formation per se does not lead to protease resistance but probably structural changes associated with polymerization. The results suggest that higher order structural changes, regulated by the primary structure, enable amyloidogenic polypeptides to escape proteolytic degradation and accumulate in tissues.

Reactivity of cysteine residues in the protease from human immunodeficiency virus: identification of a surface-exposed region which affects enzyme function.

The protease encoded by the human immunodeficiency virus (HIV) is essential for the processing of viral polyproteins encoded by the gag and pol genes into mature viral proteins. The 99-residue protease from HIV-1 contains two cysteine residues (Cys-67 and Cys-95), both of which are usually conserved in viruses isolated from patients. Despite this conservation, neither residue is required for enzymatic activity. Certain site-specific cysteine mutants of HIV-1 protease are catalytically active, and the protease from HIV-2 lacks both cysteines. Copper is a potent inhibitor of HIV-1 protease, but not of mutants lacking cysteine (A. R. Karlström and R. L. Levine, 1991, Proc. Natl. Acad. Sci. USA 88, 5552-5556). The addition of copper to the protease at pH 5.5 induced aggregation of the protein, providing a possible basis for the inhibitory action of copper. However, addition of both copper and dithiothreitol still led to inhibition of activity but did not cause aggregation. These findings led to a study of the reactivity of the cysteine residues to 5,5'-dithiobis-(2-nitrobenzoic acid) (Ellman's reagent), a sulfhydryl compound which reacts with the ionized form of cysteine residues. At pH 6.2 in 6 M guanidine, no derivatization of cysteine residues occurred, consistent with the typical pKa of cysteine expected for the denatured protein. However, in the same buffer without guanidine, the native protease reacted rapidly with concomitant loss of proteolytic activity. Peptic mapping demonstrated that both Cys-67 and Cys-95 were derivatized. A catalytically active fusion protein of protease with protein A domains was then studied with the expectation that access to Cys-95 would be hindered. This was confirmed, with only Cys-67 reacting rapidly with Ellman's reagent. Enzymatic activity was again lost, indicating that derivatization of the surface-accessible Cys-67 was sufficient to inactivate the enzyme. The reactivity and accessibility of these residues suggest an interesting approach for the development of protease inhibitors which are not directed to the substrate-binding site.

Copper inhibits the protease from human immunodeficiency virus 1 by both cysteine-dependent and cysteine-independent mechanisms.

The protease of the human immunodeficiency virus is essential for replication of the virus, and the enzyme is therefore an attractive target for antiviral action. We have found that the viral protease is inhibited by approximately stoichiometric concentrations of copper or mercury ions. Inactivation by Cu2+ was rapid and not reversed by subsequent exposure to EDTA or dithiothreitol. Direct inhibition by Cu2+ required the presence of cysteine residue(s) in the protease. Thus, a synthetic protease lacking cysteine residues was not inhibited by exposure to copper. However, addition of dithiothreitol as an exogenous thiol rendered even the synthetic protease susceptible to inactivation by copper. Oxygen was not required for inactivation of either the wild-type or the synthetic protease. These results provide the basis for the design of novel types of protease inhibitors.

Human immunodeficiency viral protease is catalytically active as a fusion protein: characterization of the fusion and native enzymes produced in Escherichia coli.

Processing of the gag and pol gene precursor proteins of retroviruses is essential for the production of mature infectious virions. The processing is directed by a viral protease that itself is part of these precursors and is presumed to cleave itself autocatalytically. To facilitate study of this process, the protease was produced as a fusion protein in Escherichia coli. In this construct, the 10,793-Da protease was preceeded by two copies of a modified IgG binding domain derived from protein A. The IgG binding domain was linked to the protease by an Asp-Pro peptide bond which could not be cleaved by the viral protease. A dimer of the 25,400-Da fusion protein was catalytically active, specifically cleaving a substrate peptide at the correct Tyr-Pro bond. Thus, the fusion protein could serve as a model of the viral gag-pol polyprotein. The finding that the fusion protein was catalytically active supports the suggestion that a gag-pol dimer can initiate a proteolytic cascade after budding of the immature virus. The fusion protein also provided a source of authentic protease. The protease was released from the fusion construct by incubation with formic acid, cleaving the Asp-Pro linkage which had been inserted between the IgG binding domain and the protease.

Improved assays for DNA-polymerizing enzymes by the use of enzymatically synthesized 5-[125I]iodo-2'-deoxyuridine triphosphate, illustrated by direct quantitation of anti-HIV reverse transcriptase antibody and by serum DNA polymerase analyses.

A one-step procedure which uses enzymes in a crude extract of herpes simplex virus (HSV) type 1-infected cells to synthesize 5-[125I]iodo-2'-deoxyuridine triphosphate [( 125I]dUTP) from [125I]dU is described. The design of a one-step procedure for the purification of the product is also presented. The recovery of [125I]dUTP from [125I]dU varied between 50 and 75%, the radiochemical purity of the product was greater than 90%, and both synthesis and purification were completed within 8 h. The sensitivity and specificity of [125I]dUTP as a substrate for both DNA-dependent DNA polymerase (DNAp) and RNA-dependent DNA polymerase (reverse transcriptase, RT) were evaluated and compared to those of [3H]dTTP for the following specimens: purified cloned Klenow fragment, crude extracts of HeLa-, BHK-, and HSV-2-infected BHK cells, purified avian myeloblastosis virus RT, and purified cloned human immunodeficiency virus (HIV) RT. The [125I]dUTP was accepted as a substrate equally as well [3H]dTTP by all of the specimens at all of the concentrations tested. When the same amount of radiolabel was used, [125I]dUTP gave a sensitivity 10- to 25-fold higher than that of [3H]dTTP. The gain in sensitivity was due to the higher specific activity and a higher counting efficiency of the 125I-label compound. The use of [125I]dUTP also offered technical advantages over alternative substrates available, such as product separation without acid precipitation and exclusion of the need for scintillation cocktails. The half-life of the nucleic also gives a reasonable shelf-life for use in routine assays. Activity of less than 0.3 pg of HIV RT could be detected when the new substrate was used, and this made it possible to quantitate HIV RT antibodies (abs) in diluted serum samples without purifying the immunoglobulin. Analysis of 31 HIV-infected individuals showed that all of them had anti-HIV RT ab and that the amount of serum needed for 50% inhibition of the HIV RT activity corresponded to an amount of immunoglobulin 100-fold smaller (i.e., 0.02-31.4 micrograms) than has been previously reported. With the substrate it was also possible to detect DNAp activity in serum from healthy individuals, although a long-duration assay was required. In a long-duration assay the DNAp activity found in sera from healthy individuals was linear with respect to time, whereas the DNAp activity found in many sera from tumor patients was not. [125I]dUTP is judged to be an excellent substrate for detecting and quantifying the activity of various DNA-synthesizing enzymes and their blocking abs.

Molecular forms in human serum of enzymes synthesizing DNA precursors and DNA.

Both thymidine kinase (TK) and DNA polymerase (DNAp) are present in measurable amounts in human serum. Even though the use of TK as a clinical marker is rapidly increasing there has been no attempt to characterize the serum TK in a wider extent, i.e.; with respect to Mw or other biochemical parameters. Therefore sera with high TK or DNAp activities derived from patients with cytomegalovirus (CMV) infection, B12-deficiency and leukaemia were fractionated by gel exclusion chromatography. The TK activity eluted as two peaks, one major TK activity with an apparent molecular weight (Mw) or 730 kD and one minor TK activity corresponding to a Mw of 58 kD. The amount of TK activity at 58 kD varied between 7 and 23% of total activity, depending on the serum fractionated. The DNAp activity in sera from patients with malignant disease and B12 deficiency eluted as a single peak corresponding to a Mw of 240 kD. A DNAp with a different Mw (greater than 1000 kD) was recovered from 1 of 3 investigated immunosuppressed patients with CMV infection. A similar pattern of enzyme forms was observed when sera were separated by glycerol gradient centrifugation. The effect of high salt and various reaction solution components on the enzymes were studied. The only condition found that affected the molecular forms of TK was the state of reduction. Incubation of sera with high concentrations of dithioerythritol (DTE) (400 mM) prior to separation transferred all serum TK to the 58 kD form, it also converted most of the serum DNAp from the 240 kD form to a smaller form (56 kD) without affecting the total recovery of enzymatic activity. The reaction product from both TK forms was exclusively monophosphate and none of the TK forms could efficiently utilize cytidine triphosphate as phosphate donor. The substrate kinetics of the small serum TK fraction was identical with those of an enzyme with similar size purified from proliferating HeLa cells, indicating that both serum TK activities are forms of TK 1, the proliferation associated cellular isozyme.

An optimized thymidylate kinase assay, based on enzymatically synthesized 5-[125I]iododeoxyuridine monophosphate and its application to an immunological study of herpes simplex virus thymidine-thymidylate kinases.

The biological synthesis and purification of 5-[125I]iododeoxyuridine monophosphate (IdUMP) are described. The specificity of IdUMP as substrate in the thymidylate monophosphate kinase (TMPK) assay is demonstrated, and a 100-fold gain in sensitivity as compared to the conventional TMPK assay is shown. TMPK measurements of isozymes derived from herpes simplex virus (HSV)-infected cells, uninfected cells, and tumor biopsies were performed. The results showed a significant difference in dependence of phosphate donor concentration present for TMPK activity from HSV-infected cells compared to the corresponding activity from uninfected cells, while only a minor difference in pH optima was observed for these enzyme activities. The increased sensitivity made it possible to detect and quantify HSV TMPK-blocking antibodies (ab) present in human sera. Sera from HSV ab-positive individuals were found to block the two HSV TMPKs to varying degrees and with different specificities. The immunological relationship between the TMPK and thymidine kinase (TK) induced by HSV-1 and HSV-2, respectively, was studied by comparing the capacities of different sera to block the two enzymatic activities. The results showed that the capacity to block HSV-1 TK and TMPK was proportional for all of the sera studied, while sera that preferentially blocked only the HSV-2 TMPK or HSV-2 TK were found. It was concluded that the HSV-2 TMPK and TK activities are less related than the corresponding activities for HSV-1 and that the HSV-2 enzyme activities are mediated by different catalytic sites.