Efficient production of thermostable Thermus thermophilus xylose isomerase in Escherichia coli and Bacillus brevis

Summary The xylose (glucose) isomerase from the thermophile Thermus thermophilus seems to have potential for the development of new isomerization processes using high temperatures and slightly acidic pH. The isomerase has an optimum temperature at 95° C, and is also very stable at high temperatures. The optimum pH is around 7.0, close to where by-product formation is minimal. Since Thermus produces only a little of this useful isomerase, the production of the cloned gene in Escherichia coli and Bacillus brevis were compared. Especially B. brevis was able to produce the isomerase effeciently, more than 1 g/l, in spite of the high G + content (67%) of the Thermus gene, and the presence of codons not frequently used in E. coli or B. brevis.Offprint requests to: S. Udaka     

One-step affinity purification of the G protein betagamma subunits from bovine brain using a histidine-tagged G protein alpha subunit

An efficient one-step affinity purification of bovine brain G protein betagamma subunits (betagamma's) is described. The betagamma's, in a detergent extract of brain membranes, are first dissociated from the alpha subunits (alpha's), reassociated with decahistidine-tagged alphail produced in bacteria, and then adsorbed onto Ni2+-nitrilotriacetic acid-agarose via the histidine tag. This mild adsorption retained the high activity of the ligand alpha's, in contrast to the commonly used chemical crosslinking methods. A wash step with a buffer containing chaotropic ions (SCN-) completely removed contaminating proteins that were refractory to washes with high concentrations of detergents, after which the highly purified betagamma's were eluted with a buffer containing Al3+, Mg2+, and F- ions. The obtained betagamma's were found to be fully functional, as assessed by their ability to support pertussis toxin-catalyzed ADP-ribosylation of alphail. Since the combination of the mild adsorption via the histidine tag and the wash with chaotropic ions can be easily applied to purifying betagamma's from various animal tissues, this new chromatographic method is expected to facilitate the purification of other membrane proteins that bind to Galpha and/or Galphabetagamma.     

High-level expression of Rhizopus niveus lipase in the yeast Saccharomyces cerevisiae and structural properties of the expressed enzyme

Rhizopus niveus lipase (RNL) has a unique structure consisting of two noncovalently bound polypeptides (A-chain and B-chain). To improve this enzyme's properties by protein engineering, we have developed a new expression system for the production of recombinant lipase in the yeast Saccharomyces cerevisiae. For the present study, we developed a more efficient expression system using the strain ND-12B and the multicopy-type plasmid pJDB219. We purified two types of recombinant lipases, each to a single peak by gel-filtration HPLC, although they were found to be heterogeneous by SDS-PAGE. Analysis of reversed-phase HPLC, N-terminal amino acid sequence, and sugar content showed that the difference between the two types of lipases was due mainly to their sugar content (high or low mannose type). Moreover, there were two species within each type of lipase. One kind was processed to the A-chain and B-chain as in the native lipase, while the other remained unprocessed. Although these yeast-purified lipases contained several posttranslational modifications and different glycosylations, their secondary structures were the same as those of the native lipase as measured by circular dichroism spectra and determination of disulfide bonding. This suggests that protein folding of the recombinant lipase occurred correctly in yeast.     

T3-hydrocortisone synergism on adult-type erythroblast proliferation and T3-mediated apoptosis of larval-type erythroblasts during erythropoietic conversion in Xenopus laevis

 The conversion of an erythropoietic system from larval to adult type in anuran amphibia may possibly come about through cell replacement. The hormonal regulation of apoptosis of larval-type precursor cells and adult-type cell proliferation has yet to be examined in detail. In amphibians, corticoids synergize T₃ action during metamorphosis. In the present study, examination was made of the process of larval-to-adult conversion in the liver erythropoietic site of Xenopus laevis, with special attention to how these metamorphic hormones, T₃ and corticoid, regulate programmed cell death specific for larval erythroblasts and the proliferation of adult cells. Immunohistochemical analysis of liver sections indicates that the number of larval erythroblasts decreased to less than 50% at the early climax stage (stages 59–60) of metamorphosis. Overall liver morphology greatly changed subsequent to the climax stage from the three-lobe to the two-lobe shape. The addition of T₃ (10^-8 M) to premetamorphic tadpoles induced considerable liver morphological change and a 50% decrease in larval-type erythroblasts. These erythroblast decreases seem to take place through the apoptotic process, since double-staining experiments with in situ DNA nick-end labeling (TUNEL) and hemoglobin immunostaining revealed that DNA breakage of nuclei, a well-known feature of apoptosis, occured specifically in larval erythroblasts during prometamorphosis. Hydrocortisone (HC), which modulates T₃ action during metamorphosis, was found not to be a factor in larval cell decrease. But adult erythroblasts increased by 8 times as much through the action of T₃ and 32 times as much by the action of T₃ plus HC, indicating the important action of T₃–HC synergism. It thus follows that the erythropoietic system is converted during metamorphosis effectively by two distinct hormonal mechanisms, T₃–HC synergism on adult erythroblast proliferation and T₃-mediated programmed death of larval precursor cells. Accepted: 14 January 1999     

Development of CD8+ effector T cells is differentially regulated by IL-18 and IL-12

We investigated the effects of IL-18 on the development of CD8+ effector T cells in DBA/2 anti-BDF1 whole spleen cell MLC and compared the results with those of IL-12. Addition of IL-18 to the MLC resulted in a twofold increase in CD8/CD4 ratios compared with the control cultures when cells were expanded in IL-2-containing medium following MLC. Purified CD8+ T cells recovered from the IL-18-stimulated MLC produced 20- to 30-fold more IFN-gamma after secondary stimulation with C57BL/6 spleen cells or anti-CD3 mAb, and exhibited strong allospecific CTL activity. Neither IL-18 nor IL-18-supplemented culture supernatants from DBA/2 anti-BDF1 MLC induced type I CD8+ effector T cells when purified CD8+ T cells were used as responder cells in primary MLC. Furthermore, CD4+ T cell depletion from the responder cells abrogated the IL-18-induced increase in secondary IFN-gamma production by CD8+ T cells, suggesting that IL-18-induced type I effector CD8+ T cell development was CD4+ T cell dependent. In marked contrast, adding IL-12 to primary MLC decreased CD8/CD4 ratios by 50% and suppressed secondary IFN-gamma production and CTL activity by CD8+ T cells regardless of concentration, whereas Th1 development was promoted by IL-12. Moreover, both IL-12 and IL-18 efficiently induced type I CD8+ effector T cells in C57BL/6 anti-BDF1 MLC. These findings show that IL-18 plays an important role in the generation of type I CD8+ effector T cells, and further suggest that functional maturation of CD8+ T cells is differentially regulated by IL-18 and IL-12.     

Development of a novel neodymium compound for in vivo fluorescence imaging.

We developed a novel fluorescent probe that contains the neodymium(III) complex moiety and fluorescein moiety. This probe can emit long-lived near-infrared luminescence derived from a Nd ion through excitation of the fluorescein moiety with visible light (lambda(ex) = 488 nm, lambda(em) = 880 nm, lifetime = 2.3 micros). These results indicate the possibility of the probe as a candidate for in vivo fluorescence molecular imaging.     

The budding yeast mei5 and sae3 proteins act together with dmc1 during meiotic recombination

Here we provide evidence that the Mei5 and Sae3 proteins of budding yeast act together with Dmc1, a meiosis-specific, RecA-like recombinase. The mei5 and sae3 mutations reduce sporulation, spore viability, and crossing over to the same extent as dmc1. In all three mutants, these defects are largely suppressed by overproduction of Rad51. In addition, mei5 and sae3, like dmc1, suppress the cell-cycle arrest phenotype of the hop2 mutant. The Mei5, Sae3, and Dmc1 proteins colocalize to foci on meiotic chromosomes, and their localization is mutually dependent. The localization of Rad51 to chromosomes is not affected in either mei5 or sae3. Taken together, these observations suggest that the Mei5 and Sae3 proteins are accessory factors specific to Dmc1. We speculate that Mei5 and Sae3 are necessary for efficient formation of Dmc1-containing nucleoprotein filaments in vivo.