Spirulina ferredoxin-NADP+ reductase. Further characterization with an improved preparation

The preparation procedure for Spirulina ferredoxin-NADP+ reductase (ferredoxin: NADP+ oxidoreductase, EC 1.18.1.2, FNR) was improved by adding protease inhibitors, phenylmethylsulfonylfluoride (PMSF) and EDTA, through the whole process of preparation and by introducing an affinity chromatography step on Blue Sepharose CL-6B. The addition of the inhibitors largely prevented the formation of the minor component (FNR I), and the affinity gel chromatography simplified the preparation process, shortening the exposure period of FNR to proteolysis. However, complete removal of the heterogeneity of FNR found at the amino (N)-terminal region was not achieved even by applying the new method. The affinity chromatography on the Blue Sepharose gel was also effective in purifying spinach FNR. The affinity of this gel for Spirulina FNR was compared with that for the enzyme derived from spinach leaves. The spinach enzyme had a higher affinity than the Spirulina one. Both enzymes showed the highest affinities to Blue Sepharose at 20--30 mM NaCl concentration. The N-terminal sequence analysis revealed that there was 4 forms, which were probably modifications produced by exopeptidase action during the preparation, or even in the living cells. The longest component gave the N-terminal sequence Ala-Lys-Thr-Asp-Ile-Pro-Val-Asn-Ile-Tyr-. The others lacked amino acids successively one by one from the N-terminus. In contrast, the carboxyl(C)-terminal residues of all 4 FNR forms were tyrosine. The probable C-terminal sequence was predicted to be -Trp-His-Val-Gln-Thr-Tyr based on a study of a cyanogen bromide peptide.     

Sex difference in the paradoxical response of serum GH to thyrotrophin releasing hormone in cancer patients

It was demonstrated that thyrotropin-releasing hormone (TRH) elicited a paradoxical increase in basal GH levels in cancer patients. Out of 94 cancer patients, 50 were found to be GH responders and this phenomenon was more frequently recognized in female than in male cancer patients. In cancer patients under 59 years of age, the GH response to TRH was significantly greater in females than in males, although there was no sex difference in the GH response in patients above 60 years of age. In female cancer patients, the GH response to TRH was significantly greater in patients under 59 years of age than in patients above 60 years of age, while there was no age difference in the GH response in male cancer patients. It was concluded that paradoxical responses of serum GH to TRH were recognized in 53 per cent of cancer patients and were more frequently observed in female than in male cancer patients.     

Characterization of a new fetal hemoglobin variant, Hb F Izumi A gamma 6Glu replaced by Gly, by molecular secondary ion mass spectrometry

Molecular secondary ion mass spectrometry has characterized the structure of a new fetal hemoglobin variant, Hb F Izumi, without separation of peptides or amino acid analysis. First, the mass spectrum of a tryptic digest of the abnormal gamma globin revealed a decreased by 72 mass units in the molecular mass of peptide T-1,2, indicating the presence of a Glu leads to Gly substitution. Next, the analysis of the digest produced by the addition of staphylococcal protease, which specifically cleaves glutamyl peptide bonds, determined the site of substitution at 6th glutamic acid residue in peptide T-1,2 which contains two glutamic acid residues. Since this mass spectrometric approach provides digitalized data on peptide analysis, we call it 'digit printing'. The high sensitivity of this technique is especially promising for the analysis of molecular abnormality in various genetic disorders.     

Ferredoxins in Developing Spinach Cotyledons: The Presence of Two Molecular Species

An antibody for ferredoxin was used to investigate the developmentof ferredoxin during the greening of spinach cotyledons. Ferredoxinwas present in 8-day-old etiolated cotyledons and increasedwith illumination, which means that the synthesis of ferredoxinwas both light dependent and independent. The ferredoxin purified from etiolated cotyledons, greeningcotyledons, and mature leaves was a mixture of two chemicallydistinct molecular species; ferredoxin I and II. The relativecontents of these two species varied with the stage of developmentand the conditions used. Ferredoxin I was identical with that isolated previously asvalidated by its amino acid sequence [Matsubara and Sasaki (1968)J. Biol. Chem. 243: 1732]. The complete amino acid sequenceof the second component, ferredoxin II, was determined as well.It was composed of 97 amino acid residues and differed fromferredoxin I by 25 residues. (Received October 16, 1982; Accepted December 14, 1982)     

Reconstitution mechanism of nucleosome core particles mediated by poly(l-glutamic acid)

Poly(l-glutamic acid) has been reported to mediate in vitro nucleosome assembly (Stein, A., Whitlock, J.P., Jr. and Bina, M. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 5000–5004). To study the reaction mechanism, we have reconstituted nucleosome core particles from chicken erythrocyte core DNA and core histones in the presence of poly(l-glutamic acid) and analyzed the assembly products by polyacrylamide gel electrophoresis. Poly(l-glutamic acid), which binds and forms a large complex with core histones, is replaced with core DNA in the reconstitution process. When histone-poly(l-glutamic acid) complex and core DNA are mixed with a histone:DNA ratio of 1.0, the yield of core particles increases by prolonged reconstitution time. Two phases with a distinct time range appear in the process. In the fast phase within 30 min, 60% of the DNA is involved in products containing histones: reconstituted core particles, a larger nucleoprotein complex and aggregation. In the second phase, the remaining DNA and the DNA in the aggregation decrease, and the core particles increase slowly. The yield of core particles is approx. 60% after 24 h. The slow phase is not observed by reconstitution with a histone:DNA ratio of 2.0 in the initial mixture. The reaction scheme of the assembly process derived from these data is given. Based on the in vitro reaction scheme, the possible role of in vivo ‘nucleosome assembly factors’ is also discussed.     

Phenethyl Alcohol Resistance in ESCHERICHIA COLI. III. a Temperature-Sensitive Mutation (dnaP) Affecting DNA Replication

A temperature-sensitive DNA replication mutant of E. coli K-12 was isolated among the mutants selected for phenethyl alcohol resistance at low temperatures. This mutation, designated as dnaP18, affects sensitivity of the cell to phenethyl alcohol, sodium deoxycholate and rifampicin, presumably due to an alteration in the membrane structure. At high temperatures (e.g., 42 degrees ), synthesis of DNA, but not RNA or protein, is arrested, leading to the formation of "filaments" in which no septum formation is apparent. Nucleoids observed under electron microscope seem to become dispersed and DNA fibrils less condensed, which may explain the loss of viability under these conditions. Genetic analyses, including reversion studies, indicate that a recessive dnaP mutation located between cya and metE on the chromosome is responsible for both alterations of the membrane properties and temperature sensitivity. The dnaP18 mutation does not affect growth of phage T4 or lambda under conditions where host DNA replication is completely inhibited. Kinetic studies of DNA replication and cell division in this mutant after the temperature shift from 30 to 42 degrees , and during the subsequent recovery at 30 degrees , accumulated evidence suggesting that DNA replication comes to a halt at 42 degrees upon completion of a cycle already initiated before the temperature shift. Since the recovery of DNA synthesis after exposure to 42 degrees does not depend on protein or RNA synthesis or other energy-requiring processes, the product of the mutant dnaP gene appears to be reversibly inactivated at 42 degrees . Taken together with the recessive nature of the present mutation, it was suggested that one of the membrane proteins involved in initiation of DNA replication is affected in this mutant.