Requirement of ADP-ribosylation for the pertussis toxin-induced alteration in electrophoretic mobility of G-proteins.

Pertussis toxin (PTX) catalyzes the ADP-ribosylation of the alpha-subunit of GTP-binding proteins (G-proteins) in the presence of NAD+. Pertussis toxin also decreases the electrophoretic mobility of the alpha-subunit on urea SDS PAGE. This effect of PTX has been suggested to be a property of the toxin different from its ability to catalyze ADP-ribosylation. However, the present report provides evidence to the contrary; ie, this mobility shift required the ADP-ribosylation of alpha-subunits. This conclusion was based on: (1) in the presence of increasing concentrations of NAD+ (0.026-1.3 microM), there was a linear increase in the formation of the slower migrating alpha-subunit as measured by immunoblotting with selective antisera, (2) addition of NADase to the incubation mixture completely eliminated the formation of this protein, and (3) increasing concentrations of nicotinamide (50-250 mM), which inhibits ADP-ribosylation, decreased the amount of the slower migrating alpha-subunit. Thus, in addition to PTX, NAD+ was required for the mobility shift and the slower migrating alpha-subunit is likely the ADP-ribosylated form.     

Isolation and molecular cloning of transferrin from the tobacco hornworm, Manduca sexta. Sequence similarity to the vertebrate transferrins

An iron-binding glycoprotein of Mr = 77,000 has been isolated from hemolymph of the adult sphinx moth Manduca sexta. Since this protein binds ferric ion both in vivo and in vitro and has a secondary structure similar to that of human serum transferrin and human lactoferrin as judged by CD spectra, we decided to clone its cDNA in order to determine its relationship to the vertebrate transferrins. Antiserum generated against this protein was used to screen a larval fat body cDNA library. A 2.0 kilobase clone was isolated that selects an mRNA which, when translated in vitro, produces an immunoprecipitable 77-kDa protein. When the library was rescreened using the 2.0-kilobase clone as a probe, three full-length clones were isolated, and the complete nucleotide sequence of one 2,183-base pair insert was determined. The deduced protein sequence contains an 18-amino acid signal sequence and a mature protein sequence of 663 amino acids with a calculated Mr of 73,436. The sequence was used to search the National Biomedical Research Foundation (NBRF) protein database, revealing significant similarity to the vertebrate transferrins, a family of 80-kDa glycoproteins which transport and sequester iron in the blood and other body fluids. A multiple sequence alignament shows the greatest areas of similarity to be around the two iron binding sites, although the insect protein seems to contain only one such functional site. Moreover, 23 of the 24 cysteine residues in the insect protein occupy identical positions as compared with the other transferrins, indicating a similar overall tertiary structure. Comparison of the two halves of the insect sequence indicates that the protein may have arisen as a result of gene duplication. The similarity of the M. sexta sequence to the vertebrate transferrins may provide important clues to transferrin evolution.     

Structural and genetical studies on the high-molecular-weight subunits of wheat glutenin

Summary The high-molecular-weight (HMW) subunits of glutenin from about 185 varieties were fractionated by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE). About 20 different, major subunits were distinguished by this technique although each variety contained, with only a few exceptions, between 3 and 5 subunits. Further inter-varietal substitution lines to those already described (Payne et al. 1980) were analysed and the results indicate that all the HMW subunits are controlled by the homoeologous group 1 chromosomes. All hexaploid varieties studied except ‘NapHal’ contained two major subunits controlled by chromosome 1D. Their genes were shown to be tightly linked genetically for only four different types of banding patterns were observed. The nominal molecular weights determined after fractionation in 10% polyacrylamide gels were between 110,000 and 115,000 for the larger of the two subunits and between 82,000 and 84,000 for the smaller. One quarter of the varieties contained only one major HMW subunit controlled by chromosome 1B whereas the rest had two. The chromosome 1B subunits were the most varied and nine different banding patterns were detected. All the subunits had mobilities which were intermediate between those of the two chromosome 1D-controlled subunits. Only two types of HMW subunit controlled by chromosome 1A were detected in all the varieties examined; a single variety never contained both of these subunits and 40% of varieties contained neither. The chromosome 1A-controlled subunits had slightly slower mobilities in 10% gels than the largest HMW subunit controlled by chromosome 1D. About 100 single grains were analysed from each of five different crosses of the type (F₁ of variety A × variety B) × variety C. The results indicate that the genes on chromosome 1B which control the synthesis of subunits 6, 7, 13, 14 and 17 are allelic, as are the genes of the chromosome 1A-controlled subunits, 1 and 2.     

The effect of 4-isothiocyanatobenzene sulfonic acid on the oxygen affinity of human hemoglobin

Human hemoglobin reacts with 4-Isothiocyanatobenzene sulfonic acid at the four amino groups of the N-terminal valines. The modified protein shows a decreased oxygen affinity over a wide pH range, a reduced alkaline Bohr effect, decreased co-operativity, and a reduced effect of inositol hexasulfate on the oxygen affinity.     

Control of Endosperm Proteins in TRITICUM AESTIVUM (Var. Chinese Spring) and AEGILOPS UMBELLULATA by Homoeologous Group 1 Chromosomes

The genetic control of major wheat endosperm proteins by homoeologous group 1 chromosomes has been studied by two-dimensional polyacrylamide gel electrophoresis. The control of at least 15 distinct protein subunits or groups of protein subunits has been allocated to chromosomes 1A, 1B and 1D of Chinese Spring wheat from the analysis of grains of aneuploid genotypes. In addition, six protein subunits have been shown to be controlled by chromosome 1C^u of the related species, Aegilops umbellulata, from studies of wheat lines carrying disomic substitutions of 1C^u chromosomes. On the basis of protein subunit patterns, chromosome 1C^u is more closely related to chromosome 1D of wheat than to chromosomes 1A or 1B.     

Possible involvement of cerebroside sulfate in opiate receptor binding.

Cerebroside sulfate (CS) appears to fulfill most of the structural requirements of a hypothetical opiate receptor. It possesses many of the properties that are thought to be necessary for the identification of an "opiate receptor," exhibiting high affinity and stereoselective binding to a number of narcotic drugs. Although these properties are insufficient to establish identity of the receptor, it is highly significant that the affinity of this binding can be correlated with the analgetic potency of these drugs in both man and rodents. CS is an endogenous component of brain tissue, and a partially purified opiate receptor from mouse brain has been found to be CS. Other experiments indicate that reduced availability of brain CS decreases the analgetic effects of morphine and this is accompanied by a reduction in number of binding sites, suggesting that the interaction of opiates with CS observed in vitro may also have importance in vivo. CS was also found to be a component of the opiate receptor after marking with 125I-labeled diazosulfanilic acid. The possibility that CS or the SO4-2 group of this lipid may be the "anionic site" of the opiate receptor should be considered.     

On describing microbial growth kinetics from continuous culture data: Some general considerations,observations, and concepts

Analysis of continuous culture methodology suggests that this potentially powerful tool for kinetic analysis can be improved by minimizing several inherent shortcomings. Medium background substrates — organic carbon, phosphate, and manganese — were shown to dominate kinetic observations at concentrations below chemical detection methods. Reactor wall growth, culture size distribution changes, sample removal-induced steady state perturbations, and limiting substrate leakage from organisms are treated in terms of kinetic measurement errors. Large variations in maximal growth rates and substrate uptake rates found are attributed to experimental protocol-induced transient states. Relationships are presented for correcting limiting substrate concentrations for lability during sampling, contamination with unreacted medium, and background substrate effects. Analytical procedures are discussed for improved measurement of limiting substrate kinetics involving enzymes, isotopes, and material balance manipulation. Relaxation methods as applied to continuous culture are introduced as a means for isolating separate rate constants describing net substrate transport and for evaluating cellular metabolite leakage. Low velocity growth, multiple substrate metabolism, and endogenous metabolism are discussed along with measurements showing that 1-month generation times for aquatic microorganisms can be quite normal and that the kinetics are compatible withμg/liter limiting substrate concentrations. The concept of regarding growth kinetics as the sum of several net accumulation processes is suggested.