Phenylboronic acid-salicylhydroxamic acid bioconjugates. 1. A novel boronic acid complex for protein immobilization.

A chemical affinity system exhibiting antibody-like properties is described. The system exploits bioconjugates with appended phenylboronic acid (PBA) moieties and a support-bound phenylboronic acid complexing reagent derived from salicylhydroxamic acid (SHA) for protein immobilization on a chromatographic support. The structure of the PBA.SHA complex was characterized by 11B NMR and mass spectrometry and compared with complexes derived from model compounds. Protein modification reagents were synthesized from 3-aminophenylboronic acid and utilized to prepare bioconjugates from alkaline phosphatase (AP) and horseradish peroxidase (HRP). AP obtained from one source afforded PBA bioconjugates exhibiting significant loss of enzymatic activity, whereas AP obtained from a second source afforded PBA bioconjugates exhibiting only a modest loss of enzymatic activity. Conversely, HRP afforded PBA bioconjugates exhibiting no loss of enzymatic activity. SHA-modified Sepharose was prepared by reaction of methyl 4-[(6-aminohexanoylamino)methyl]salicylate with CNBr-activated Sepharose 4B, followed by treatment with aqueous alkaline hydroxylamine. PBA-AP and PBA-HRP conjugates were efficiently immobilized on SHA-Sepharose at pH 8.3. PBA-AP conjugates were retained after washing with acidic buffers at pH 6.7, 4.2, and 2.5, whereas PBA-HRP conjugates were retained after washing with buffer at pH 6.7, but were eluted to some extent at and below pH 4.2. The results are interpreted in terms of multivalent interactions involving boronic acid complex formation between the enzyme bioconjugates and immobilized complexing reagent.

Phenylboronic acid-salicylhydroxamic acid bioconjugates. 2. Polyvalent immobilization of protein ligands for affinity chromatography.

Phenylboronic acid bioconjugates prepared from alkaline phosphatase by reaction with either 2,5-dioxopyrrolidinyl 3-[N-[3-(1,3,2-dioxaboran-2-yl)phenyl]carbamoyl]propanoate (PBA-XX-NHS) or 2,5-dioxopyrrolidinyl 6-[[3,5-di-(1,3,2-dioxaboran-2-yl)phenyl]carbonylamino]hexanoate (PDBA-X-NHS) were compared with respect to the efficiency with which they were immobilized on salicylhydroxamic acid-modified Sepharose (SHA-X-Sepharose) by boronic acid complex formation. When immobilized on moderate capacity SHA-X-Sepharose (5.4 micromol of SHA/mL of gel), PDBA-alkaline phosphatase conjugates were shown to be stable with respect to both the alkaline (pH 11.0) and acidic (pH 2.5) buffers utilized to recover anti-alkaline phosphatase during affinity chromatography. Boronic acid complex formation was compared to covalent immobilization of alkaline phosphatase on Affi-Gel 10 and Affi-Gel 15. PDBA-AP.SHA-X-Sepharose was shown to afford superior performance to both Affi-Gel 10 and Affi-Gel 15 with respect to immobilization of alkaline phosphatase, retention of anti-alkaline phosphatase and recovery of anti-alkaline phosphatase under alkaline conditions. High capacity SHA-X-Sepharose (> or = 7 micromol of SHA/mL of gel) was shown to afford superior performance to moderate capacity SHA-X-Sepharose (4.5 micromol of SHA/mL of gel) with respect to stability at pH 11.0 and pH 2.5 when a PDBA-alphaHuman IgG conjugate with a low incorporation ratio of only 1.5:1 was immobilized on SHA-X-Sepharose and subsequently utilized for affinity chromatography of Human IgG. The results are interpreted in terms of either a bivalent or trivalent interaction involving boronic acid complex formation.

Large-scale and automated DNA sequence determination.

DNA sequence analysis is a multistage process that includes the preparation of DNA, its fragmentation and base analysis, and the interpretation of the resulting sequence information. New technological advances have led to the automation of certain steps in this process and have raised the possibility of large-scale DNA sequencing efforts in the near future [for example, 1 million base pairs (Mb) per year]. New sequencing methodologies, fully automated instrumentation, and improvements in sequencing-related computational resources may render genome-size sequencing projects (100 Mb or larger) feasible during the next 5 to 10 years.

Specific-primer-directed DNA sequencing using automated fluorescence detection.

Automated fluorescence-based DNA sequence analysis offers the possibility to undertake very large scale sequencing projects. Directed strategies, such as the specific-primer-directed sequencing approach ('gene walking'), should prove useful in such projects. Described herein is a study involving the use of this approach in conjunction with automated fluorescence detection on a commercial instrument (ABI 370A DNA sequencer). This includes procedures for the rapid chemical synthesis and purification of labeled primers, the design of primer sequences that are compatible with the commercial analysis software, and automated DNA sequence analysis using such primers. A set of four fluorophore-labeled primers can be reliably synthesized in a twenty-four hour period, and greater than 300 nucleotides of analyzed new sequence obtained using this set in an additional twenty-four hours. Scale-up of these procedures to take advantage of the full capabilities of the sequencer is, at present, too slow and costly to be suitable for routine sequencing, and therefore the use of specific-primers is best suited to the closure of gaps in extended sequence produced using random cloning and sequencing strategies.

Fluorescence detection in automated DNA sequence analysis.

We have developed a method for the partial automation of DNA sequence analysis. Fluorescence detection of the DNA fragments is accomplished by means of a fluorophore covalently attached to the oligonucleotide primer used in enzymatic DNA sequence analysis. A different coloured fluorophore is used for each of the reactions specific for the bases A, C, G and T. The reaction mixtures are combined and co-electrophoresed down a single polyacrylamide gel tube, the separated fluorescent bands of DNA are detected near the bottom of the tube, and the sequence information is acquired directly by computer.