Isolation and1H-NMR spectroscopic identification of the glucose-containing lipid-linked precursor oligosaccharide ofN-linked carbohydrate chains

The lipid-linked precursor ofN-type glycoprotein oligosaccharides was isolated from porcine thyroid microsomes after in cubation with UDP[³H] Glucose. The carbohydrate was released from dolichol pyrophosphate by mild acid hydrolysis, purified by gel filtration and characterized by 500-MHz¹H-NMR spectroscopy in combination with enzymatic degradation. The parent oligosaccharide was found to be Glc₃Man₉Glc-NAc₂. The three glucose residues are present in the linear sequence Glcα1-2Glα1-3 Glc, the latter being α(1-3)-linked to one of the mannose residues. In order to establish the branch location of the triglucosyl unit, the parent compound was digested with jack-bean α-mannosidase. The oligosaccharide product was purified by gel filtration, and identified by¹H-NMR as Glc₃Man₅GlcNAc₂ lacking the mannose residues A, D₂, B and D₃. Therefore, the structure of the precursor oligosaccharide is as follows: $$\begin{gathered} c b a D_1 C 4 \hfill \\ Glc\alpha 1 - 2Glc\alpha 1 - 3Glc\alpha 1 - 3Man\alpha 1 - 2Man\alpha 1 - 2Man\alpha 1 \hfill \\ 3 \swarrow 3 2 1 \hfill \\ Man\alpha 1 - 2Man\alpha 1 Man\beta 1 - 4GlcNAc\beta 1 - 4GlcNAc \hfill \\ D_{2 } A 3 6 \hfill \\ Man\alpha 1 \hfill \\ 6 \hfill \\ Man\alpha 1 - 2Man\alpha 1 \nwarrow 4 \hfill \\ D_3 B \hfill \\ \end{gathered} $$      

Amplified expression of streptomyces endo-beta-N-acetylglucosaminidase H in Escherichia coli and characterization of the enzyme product

The endo-beta-N-acetylglucosaminidase H (Endo H) gene from Streptomyces plicatus has been cloned into the Escherichia coli plasmid pKC30 (Shimatake, H., and Rosenberg, M. (1981) Nature 272, 128-132), thus placing expression of this gene under control of the strong lambda promoter pL. The construction, pKCE3, which includes a properly positioned E. coli ribosome binding site from the lac operon (Robbins, P.W., Trimble, R. B., Wirth, D.F., Hering, C., Maley, F. Maley, G. F., Das, R., Gibson, B.W., and Biemann, K. (1984) J. Biol. Chem. 259, 7577-7583), was used to transform an E. coli strain lysogenic for a lambda prophage containing a temperature-sensitive repressor. By shifting cultures of pKCE3 lysogens to 42 degrees C, the production of Endo H commenced and was linear for about 1 h. Enzyme yields were amplified 150-fold above those obtained from comparable cultures of S. plicatus and represented 3 to 4% of total cellular protein, which enabled purification of Endo H to homogeneity by a rapid fourstep procedure. Although most of the cloned Endo H was secreted into the periplasmic space by E. coli, its 4 kDa leader sequence peptide (Robbins et al. (1984] was only partially removed during processing. As a result the purified pKCE3 Endo H was a heterogeneous population of molecules with an average molecular mass of 31 kDa compared to the 28.9 kDa fully processed product normally secreted by S. plicatus. Despite the residual approximately 2 kDa of leader sequence on the cloned pKCE3 product, there were no detectable differences in either the substrate specificity or the stability characteristics of the enzyme purified from E. coli or from S. plicatus. Of particular value for studies on glycoproteins was the finding that the genetically engineered Endo H was completely free of proteolytic contaminants.     

Manipulation of heterogeneous hybridoma cultures for overproduction of monoclonal antibodies.

In searching for ways to manipulate heterogeneous hybridoma cell cultures (ATCC HB124) to obtain increased production of monoclonal antibodies (IgG2a), we have selected for a higher secreting but slower growing subpopulation using the level of fluorescent surface-associated antibodies and a fluorescence-activated cell sorter. Cell surface fluorescence was found to be correlated with specific antibody secretion rate over the short term but not with intracellular antibody content. Also, the specific secretion rate of a heterogeneous population of hybridoma cells grown in batch culture has been shown to be inversely correlated with an increase in either the initial cell concentration or the medium antibody concentration. Several experiments suggest that an upper limit exists for medium antibody concentration, above which antibody is degraded at the same rate at which it is produced. Should other cell lines behave similarly, strategies for overproduction of monoclonal antibodies suggested herein could be profitably used in industry.     

Escherichia coli protein StpA stimulates self-splicing by promoting RNA assembly in vitro.

An Escherichia coli gene, stpA, has been identified and cloned based on its ability to suppress the Td- phenotype of a resident, splicing-defective phage T4 td (thymidylate synthase) gene. The stpA gene, which was localized to 60.24 min on the E. coli chromosome, encodes a 15.3-kDa protein. Overproduction of StpA in vivo led to an increase in td pre-mRNA levels and modest enhancement of td mRNA:pre-mRNA ratios. Consistent with its in vivo effect, purified StpA promoted RNA splicing in vitro, and facilitated RNA annealing and strand exchange with model substrates. These results suggest that StpA promotes splicing of the intron by binding RNA nonspecifically, resolving misfolded precursor molecules and facilitating association of critical base pair elements. Furthermore, proteinase K treatment of StpA-assembled precursors prior to the initiation of the splicing reaction still resulted in splicing enhancement, indicating that StpA is not required for the catalytic step, unlike the Neurospora splicing effector CYT-18, whose presence was necessary for catalysis to proceed. Together these results suggest that StpA has chaperone activity in vitro, with the property of promoting assembly of the precursors into an active conformation, in contrast to splicing effectors that stabilize the catalytically active intron structure.     

Construction and evaluation of a metal ion biosensor

Escherichia coli, genetically engineered with a mercury(II)-sensitive promoter and the lux genes from Vibrio fischeri, were used as microbial bioluminescent sensors for the detection of mercury. Evaluation of this genetic construction was carried out by determining the effects of various parameters on cell suspensions maintained at constant conditions in a small 100-mL vessel. The strongest light intensities and quickest induction times occurred with cells in the midexponential growth phase maintained at 28 degrees C, concentrated to 1 x 10(9) cells/mL, mixed at very fast speeds, and aerated at 2 vvm (volume of air per volume of culture per minute) during light measurement in the small vessel. The cells were sensitive to the mercuric ion in the range of 20 nM to 4 muM (4 to 800 ppb), and the total response time was on the order of 1 hour, depending on the above parameters. The cells exhibited great specificity for mercury. The cells had almost equal specificity for organic and inorganic forms of the mercuric ion and responded more weakly to the mercurous ion. A simple, inexpensive, durable miniature probe (3 mL) was constructed and operated using the optimum parameters found in the small vessel as a guide. The range of sensitivity to the mercuric ion detected in the probe was 10 nM to 4 muM when aeration was provided. (c) 1993 John Wiley & Sons, Inc.     

Microfiltration of yeast suspensions with self-cleaning spiral vortices: possibilities for a new membrane module design

A novel method of producing controlled vortices was used to reduce both concentration polarization and membrane fouling during microfiltration of Saccharomyces cerevisiae broth suspensions. The method involves flow around a curved channel at a sufficient rate so as to produce centrifugal instabilities (called Dean vortices). These vortices depolarize the build-up of suspended particles such as yeast cells at the membrane-solution interface and allow for increased membrane permeation rates. Various operating conditions under which such vortices effectively reduced cake build-up of suspended particles such as yeast cells at the membrane-solution interface and allow for increased membrane permeation rates. Various operating conditions under which such vortices effectively reduced cake build-up during microfiltration of 0 to 0.55 dry wt% yeast broth were investigated. Flux improvements of over 60% for 0.25 dry wt% yeast broth for flow with over that without Dean vortices were observed. This beneficial effect increased with increasing retentate flow rate and increasing transmembrane pressure and decreased with increasing concentration of suspended matter. Similar behavior was observed whether the cells were viable of killed. the improvement in flux in the presence over that in the absence of vortices correlated well with centrifugal force or azimuthal velocity squared. The relative cake resistances increased with reservoir yeast concentration. These values with vortices increased from 62% to 75% of that without vortices with increasing yeast concentration. The ratio of the cake thicknesses in the limiting case (at high feed concentration) was 3.25. These results suggest that self-cleaning spiral vortices could be effective in maintaining good and steady microfiltration performance with cell suspensions other than those tested. (c) 1995 John Wiley & Sons, Inc.     

Repressor and int synthesis of bacteriophage lambda in the E. coli host mutant ER437.

Summary Analysis of phage infection of the host mutant ER437 by SDS polyacrylamide gel electrophoresis and autoradiography has revealed altered expression of repressor and integration function (Int). We show that in this host Int as well as repressor synthesis is not dependent upon the cIII gene product in the usual manner, nor is their synthesis turned off in the normal way.     

The inconsistent distribution of introns in the T-even phages indicates recent genetic exchanges.

Group I self-splicing introns are present in the td, nrdB and sunY genes of bacteriophage T4. We previously reported that whereas the td intron is present in T2, T4 and T6, the nrdB intron is present in T4 only. These studies, which argue in favor of introns as mobile genetic elements, have been extended by defining the distribution of all three T4 introns in a more comprehensive collection of T2, T4 and T6 isolates. The three major findings are as follows: First, all three introns are inconsistently distributed throughout the T-even phage family. Second, different T2 isolates have different intron complements, with T2H and T2L having no detectable introns. Third, the intron open reading frames are inherited or lost as a unit with their respective flanking intron core elements. Furthermore, exon sequences flanking sites where introns are inserted in the T4 td, sunY and nrdB genes were determined for all the different T-even isolates studied. Six of eighteen residues surrounding the junction sequences are identical. In contrast, a comprehensive comparison of exon sequences in intron plus and intron minus variants of the sunY gene indicate that sequence changes are concentrated around the site of intron occurrence. This apparent paradox may be resolved by hypothesizing that the recombination events responsible for intron acquisition or loss require a consensus sequence, while these same events result in sequence heterogeneity around the site.     

A redox trap to augment the intein toolbox

The unregulated activity of inteins during expression and consequent side reactions during work‐up limits their widespread use in biotechnology and chemical biology. Therefore, we exploited a mechanism‐based approach to regulate intein autocatalysis for biotechnological application. The system, inspired by our previous structural studies, is based on reversible trapping of the intein's catalytic cysteine residue through a disulfide bond. Using standard mutagenesis, the disulfide trap can be implemented to impart redox control over different inteins and for a variety of applications both in vitro and in Escherichia coli. Thereby, we first enhanced the output for bioconjugation in intein‐mediated protein ligation, also referred to as expressed protein ligation, where precursor recovery and product yield were augmented fourfold to sixfold. Second, in bioseparation experiments, the redox trap boosted precursor recovery and product yield twofold. Finally, the disulfide‐trap intein technology stimulated development of a novel bacterial redox sensor. This sensor reliably identified hyperoxic E. coli harboring mutations that disrupt the reductive pathways for thioredoxin and glutathione, against a background of wild‐type cells. Biotechnol. Bioeng. 2013; 110: 1565–1573. © 2012 Wiley Periodicals, Inc.