Stress sensitive glucose oxidase-nylon membrane

Summary Glucose oxidase (GOD) was immobilized on a nylon membrane. No activity of the GOD-nylon membrane was observed under normal conditions but it appeared when the membrane was mechanically stretched. A linear relationship was observed between the stress strength and the GOD activity of the membrane. The appearance of the GOD activity of the membrane with stress was reproducible and the membrane could be stored for at least 2 months. Therefore, the GOD-nylon membrane can be called a stress sensitive membrane.     

A photochemical fuel cell system using Anabaena N-7363

Summary A blue-green algae, Anabaena N-7363, was immobilized in 2% agar gel. The hydrogen productivity of the immobilized algae was three times higher than that of free algae. The maximum hydrogen production rate by the immobilized blue-green algae was 0.52 moles h^–1 g^–1 (of wet gel) in the medium without nitrogen sources under illumination (10,000 lux). The oxygen evolved was then removed by a reactor containing aerobic bacteria. A photo-current of 15–20 mA was continuously produced for 7 days by the photochemical fuel cell system consisting of the immobilized Anabaena reactor, the oxygen-removing reactor and the hydrogen-oxygen fuel cell. The conversion ratio of hydrogen to current was from 80% to 100%.     

Proton magnetic resonance spectra of tRNA-Met-f from Thermus thermophilus.

220 MHz proton magnetic resonance spectra of tRNAs in bulk and tRNA-Met-f from Thermus thermophilus have been measured and compared with those of tRNAs from E. coli. Temperature dependences and chemical shift positions of the bulk tRNAs are well explained by the difference in their GC contents. It is known that the base sequence of the double helical regions in the cloverleaf structure of T. thermophilus tRNA-Met-f is different from that of E. coli tRNA-Met-f only at two positions in TpsiCarm; one more C:G pair is contained instead of a U:G pair of E. coli tRNA-Met-f and a C:G pair of E. coli is replaced by a G:C pair. In spite of the resembrance in the base sequences, nmr patterns around 13 ppm are fairly different from each other. The difference is discussed in relation with their tertiary structures and with the origin of chemical shift displacements.     

Synthesis of desmosterol and epidesmosterol from hyodeoxycholic acid

A new synthesis of desmosterol was described using hyodeoxycholic acid (3,6-dihydroxy-5β-cholanic acid) as a starting material. Epidesmosterol (3-hydroxycholesta-5,24-diene) was also synthesized for the first time from the same starting material.     

Adenylate cyclase in silkworm. Properties of the enzyme in pupal fat body.

Adenylate cyclase was assayed in a sonicated preparation of silkworm pupal fat body. The adenylate cyclase was found mostly in the particulate fraction. The activity depended upon either Mg2+ or Mn2+, and the degree of stimulation by Mn2+ was 2 times greater than that by Mg2+ compared at the saturating concentrations. In the presence of Mg2+, the enzyme was inhibited by both EGTA and high concentrations of Ca2+, showing biphasical response to Ca2+. The enzyme was stimulated several-fold by NaF. The enzyme exhibited typical Michaelis-Menten kinetics and Km values were 0.13 mM for MgATP and 0.086 mM for MnATP.     

Electric field control of lipase membrane activity

Lipase (EC 3.1.1.3., from Pseudomonas sp.) was entrapped in collagen membrane containing liquid crystal (4-methoxybenzilidene-4′-n-butylaniline). The activity of the lipase–liquid crystal membrane at an applied voltage of 4 V was 3.4 compared to a membrane tested without imposition of an external electric field. A linear relationship was observed between the activity of the lipase–liquid crystal membrane and the current. The apparent Michaelis constant (K′_m) of the lipase–liquid crystal membrane under electric field was identical to that of the membrane under ordinary condition. Activation of the lipase–liquid crystal membrane was observed repeatedly, i.e., activation in the presence of an electric field and reversion to a basal level upon removal of the field occurred cyclically. Activity control of immobilized enzymes is desirable for switching devices of a bioreactor. Possible mechanisms of the lipase activation by electric field are discussed.     

Occurrence and induction of spermidine-N1-acetyltransferase in Escherichia coli

Spermidine acetylase activity was detected in extracts prepared from $\text{Escherichia coli}$ and there was a marked increase in activity over the early period of growth. This increase reached a maximum 3 h after inoculation and was followed by an increase in ornithine decarboxylase activity. The acetylase was also able to use spermine as a substrate, but not putrescine. With spermidine and acetyl-CoA as substrate, the product formed was exclusively N¹-acetyl-spermidine. This is the first evidence for the occurrence in bacteria of spermidine-N¹-acetyltransferase, an enzyme which has previously been described in mammalian cells. These results suggest that acetylation of spermidine may be involved in the growth of $\text{Escherichia coli}$ and in the regulation of its polyamine content.     

A subunit of yeast site-specific endonuclease SceI is a mitochondrial version of the 70-kDa heat shock protein

Endo.SceI of Saccharomyces cerevisiae is a heterodimeric site-specific endonuclease, which is distinguishable from prokaryotic restriction endonucleases in the mode of recognition of its cleavage site. We have used monoclonal antibodies specific to the larger subunit (75 kDa) of Endo.SceI to isolate the gene for the subunit (ENS1) from S. cerevisiae. Unexpectedly, ENS1 was found to encode a 70-kDa heat shock protein-related polypeptide and to be identical to recently cloned SSC1. Subcellular fractionation experiments on yeast cells revealed that the primary target site of the larger subunit is mitochondria, where almost all the Endo.SceI activity is localized. Molecular genetic analysis of ENS1 demonstrated its indispensability for growth and the requirement of a high level of its expression at the sporulation and germination stages. The data suggest that ENS1 plays an important role, especially at these differentiation stages.