An hermaphrodite [2]rotaxane: preparation and analysis of structure.

[structure: see text]. The pictured rotaxane is assembled in water by capping a substituted cyclodextrin composed of the wheel and axle components. The unusual dimeric structure of the rotaxane reflects the thermodynamics of the assembly process. In N,N-dimethylformamide, the corresponding monomer is the predominant product.

A new approach to gene mutation analysis using "GFP-Display".

The unique behavior of green fluorescent protein (GFP) on SDS-PAGE was applied to the detection of a single amino acid substitution in GFP-tagged polypeptides. This simple detection method using SDS/urea gels was designated GFP-display. The N-terminal 18 or 37 amino acids of K-Ras was used as a model GFP-tagged polypeptide. K-ras exon 1 was fused to a gfp cDNA at each end and expressed in Escherichia coli. Amino acid number 12 of K-Ras (wild type; Gly) was changed to Ser, Arg, Cys, Asp, Ala, or Val, and the mobility shift of the greenish fluorescent bands in the SDS/urea gel was analyzed. These mutants were easily detected by GFP-display; however, detection depended strongly on the urea concentration and electrophoresis temperature. Subsequently, GFP-display was applied to the 36 amino acids encoding human p53 exon 7. Amino acid number 248 (wild type; Arg) was changed to Gly, Trp, Gln, Pro, or Leu, and similar mobility shifts were observed. GFP-display could be coupled with an in vitro translation system. Fluorescent active GFP and GFP-Ras fusion proteins were synthesized within a few hours. GFP-display shows potential as a modern approach to gene mutation analysis at the protein level, and is a useful method for protein engineering studies.

Purification of recombinant human pepsinogens and their application as immunoassay standards.

Human pepsinogen (PG) A and C were cloned in Escherichia coli, but the levels of expression were low and unstable. When there were fused to maltose-binding protein (MBP), the fusion proteins (MBP-PGA and MBP-PGC) were expressed as the major products. Although these fused products were almost totally recovered from the insoluble fraction, the renaturation and purification procedures were easy and simple. MBP-PGA and the PGA segment obtained by factor Xa digestion (designated as r-PGA) possessed proteolytic activities equivalent to native PGA purified from gastric tissue (t-PGA). For PGCs (MBP-PGC, r-PGC and t-PGC) also, the specific activities were almost the same. However, the activities of PGCs were about 3- to 4-hold higher than those of PGAs. In PGA and PGC immunoassay systems, r-PGs (r-PGA and r-PGC) and the EIA kit standard PGs (gastric mucosal PGs) exhibited a good correlation. From these results, r-PGs would seem to be applicable as assay standards without compromising the sensitivity of the immunoassay systems.

A simple and rapid immunoassay system using green fluorescent protein tag.

A fusion protein between green fluorescent protein (GFP) and neuron-specific enolase (NSE) was expressed in Escherichia coli. The GFP-NSE fusion protein migrated at 62 kDa in SDS-PAGE and retained the fluorescence under non-heating conditions. However, heat-denatured GFP-NSE was non-fluorescent and migrated at 74 kDa corresponding to the theoretical value. This suggests that the special structure of GFP, which is not denatured by SDS, influences its mobility in SDS-PAGE under non-heating conditions. The fluorescence intensity of GFP-NSE was measurable over a wide range by spectrophotometry or densitometry. The competitive immunoassay for NSE was performed using GFP-NSE as labeled antigen. Under our assay conditions, the working range of this system was about 2 -60 ng. This simple and rapid fluorescence immunoassay (FIA) using GFP-tagged antigen may be applicable to many protein markers.

Biochemical and immunochemical properties of modified human neuron-specific enolase.

125I-Labeled recombinant human neuron-specific enolase (R-NSE) was inadequate for RIA as a labeled antigen. The binding activity of labeled R-NSE to the antibody was markedly decreased. To supplement this defect and facilitate purification, we constructed two R-NSE derivatives, Y-NSE (one tyrosine residue was added at the N-terminal of R-NSE) and Y-NSE.H6 (six histidine residues were further added at the C-terminal of Y-NSE). The biochemical and immunochemical characteristics of these R-NSE derivatives were essentially the same to those of R-NSE. These derivatives were useful not only as standards for enzyme immunoassay (EIA), but also as labeled antigens for RIA. These results clearly indicate that the reactivity of these modified NSEs to anti-NSE antibody is almost equivalent to that of human brain gammagamma-enolase (B-NSE), and that even if the modified NSEs are labeled, they retain their binding affinities to antibodies in contrast to R-NSE.

Modification of human neuron-specific enolase for application to radioimmunoassay.

A recombinant human neuron-specific enolase (R-NSE), isolated from Escherichia coli, could not be used in an RIA system because of instability upon labeling. To apply R-NSE to RIA and to simplify the purification procedure, the N- and C-terminals of R-NSE were modified by tyrosine- and histidine-tagging, respectively. SY-NSE, containing one additional tyrosine residue, was obtained from both soluble and insoluble fractions. More derivatives tagged by two or four tyrosine residues were expressed, but only in the insoluble fraction. SY-NSE and SY-NSE.H6 (containing six histidine residues at C-terminal of SY-NSE) purified from the soluble fraction were applicable to the RIA system, indicating that the addition of a tyrosine residue at the terminal is effective if the antigen is unstable during labeling.