Trehalose-6-phosphate synthetase activity in extracts of Dictyostelium discoideum.

Trehalose-6-phosphate (T-6-P) synthetase activity in extracts of Dictyostelium discoideum has been reexamined in an effort to resolve discrepancies between the results of previous studies (R. Roth and M. Sussman (1966). Biochim. Biophys. Acta, 122, 225; K. A. Killick and B. E. Wright (1972). J. Biol. Chem., 247, 2967). We find that T-6-P synthetase is not cold sensitive as reported by Killick and Wright (1972), is not present in bacterial-grown vegetative cells (though subject to some modulation by other nutritional conditions), and is not in our hands unmasked or activated by ammonium sulfate fractionation. We conclude that the pattern of T-6-P synthetase accumulation and disappearance during fruiting body construction in D. discoideum is as originally described by R. Roth and M. Sussman (1968). J. Biol. Chem., 243, 5081) and confirmed elsewhere (P. C. Newell et al. (1972). J. Mol. Biol., 63, 373; R. W. Brackenbury et al. (1974). J. Mol. Biol., 90, 529; B. D. Hames and J. M. Ashworth (1974). Biochem. J., 142, 301).     

A note on the sampling theory for infinite alleles and infinite sites models

This note considers sampling theory for a selectively neutral locus where it is supposed that the data provide nucleotide sequences for the genes sampled. It thus anticipates that technical advances will soon provide data of this form in volume approaching that currently obtained from electrophoresis. The assumption made on the nature of the data will require us to use, in the terminology ofKimura (Theor. Pop. Biol.2, 174–208 (1971)), the “infinite sites” model of Karlin and McGregor (Proc. Fifth Berkeley Symp. Math. Statist. Prob.4, 415–438 (1967)) rather that the “infinite alleles” model of Kimura and Crow (Genetics49, 174–738 (1964)). We emphasize that these two models refer not to two different real-world circumstances, but rather to two different assumptions concerning our capacity to investigate the real world. We compare our results where appropriate with corresponding sampling theory of Ewens (Theor. Pop. Biol.3, 87–112 (1972)) for the “infinite alleles” model. Note finally that some of our results depend on an assumption of independence of behavior at individual sites; a parallel paper byWatterson (submitted for publication (1974)) assumes no recombination between sites. Real-world behavior will lie between these two assumptions, closer to the situation assumed by Watterson than in this note. Our analysis provides upper bounds for increased efficiency in using complete nucleotide sequences.     

Cell surface glycosyltransferase activities during normal and mutant (TT) mesenchyme migration

Migrating cells possess surface glycosyltransferase activity toward extracellular substrates, and the appearance of enzyme activity coincides with the onset of cellular migration (Shur, 1977a, Shur, 1977b, Develop. Biol.58, 23–39, 40–55; E. A. Turley and S. Roth, 1979, Cell17, 109–115). In this paper, surface glycosyltransferases were examined during normal and $\text{T}\text{T}$ mutant mesenchyme migration. Of six glycosyltransferases that were assayed, only galactosyltransferase was present at significant levels on the cell surface, despite the presence of a variety of intracellular glycosyltransferases. All controls have been performed to show clearly the enzyme activity was cell surface localized. In both normal and $\text{T}\text{T}$ embryos, surface galactosyltransferase activity was localized, by autoradiography, primarily to migrating mesenchymal cells, and to a lesser degree, to presumptive neural epithelium. During primitive streak formation, putative $\text{T}\text{T}$ embryos were devoid of surface galactosyltransferase activity. However, as development progressed, the $\text{T}\text{T}$ level of activity eventually exceeded wild-type levels by two- to sixfold and was evident in $\text{T}\text{T}$ tissues prior to the onset of microscopic pathology. Other surface enzymes assayed did not show any $\text{T}\text{T}\text{-}\text{dependent}$ increase in activity. The extracellular galactosyl acceptors were not chloroform:methanol soluble, and glycopeptides prepared by exhaustive Pronase digestion were excluded from Sephadex G-50. This large galactosylated glycoconjugate was readily digestable with endo-β-galactosidase, and, therefore, is similar to the poly-N-acetyllactosamine chains previously identified on early embryonic tissues (A. Kapadia, T. Feizi, and M. J. Evans, 1981, Exp. Cell. Res.131, 185–195; T. Muramatsu, G. Gachelin, M. Damonneville, C. Delarbre, and F. Jacob, 1979, Cell18, 183–191; A. Heifetz, W. J. Lennarz, B. Libbus, and Y. -C. Hsu, 1980, Develop. Biol.80, 398–408). These results support an involvement of surface galactosyltransferases in mesenchyme formation and during migration on poly-N-acetyllactosamine substrates.     

Cotranslational cleavage of immunoglobulin light chain precursors by plasmacytoma microsomes.

Murine plasmacytoma endoplasmic reticulum which has been freed of ribosomes by EDTA treatment is capable of the cotranslational proteolytic processing of representative λ₁,λ₂, and k immunoglobulin light chain precursors. Messenger RNA fractions from the MOPC-104E, MOPC-315, and MOPC-46B tumor lines were used to direct the synthesis of the light chain precursors in a cell-free system derived from Krebs II ascites cells. The precursor cleavage activity of the plasmacytoma membranes is comparable in activity and in characteristics to that of two well-defined membrane preparations: Krebs II ascites intracellular membranes (E. Szczesna and I. Boime, 1976, Proc. Nat. Acad. Sci. USA73, 1179–1183) and EDTA-treated rough endoplasmic reticulum from canine pancreas (34., 35., J. Cell Biol.67, 852–862). The efficiency of the cleavage reaction appears to be dependent upon the precursor being utilized as a substrate. An assay suitable for a preliminary characterization of the plasmacytoma membrane preparations is described.     

Is the most frequent allele the oldest?

Exact and approximate expressions are obtained for the probability that the most frequent allele is oldest, in neutral allele models in which all mutations produce new alleles. The higher the mutation rate, the less likely is it that the most frequent allele would be oldest. The results are in agreement with simulation studies by Ewens and Gillespie (1974) (Theor. Popul. Biol.6, 35–57), and limit the range of validity of a suggestion made by Crow (1972) (J. Hered.63, 306–316) with respect to the statistical testing of the neutral allele hypothesis.     

Large scale isolation and storage of Neurospora plasma membranes.

Functionally inverted plasma membrane vesieles isolated from the eukaryotic microorganism Neurospora crassa generate and maintain a transmembrane electrical potential via ATP hydrolysis catalyzed by a plasma membrane ATPase (G. A. Scarborough, 1976, Proc. Nat. Acad. Sci. USA73, 1485–1488). In order to facilitate investigation of the molecular mechanism of the electrogenic ATPase, and other transport systems, we have developed a method for the large scale isolation and storage of Neurospora plasma membranes in a stable form. Large quantities of open plasma membrane sheets (ghosts) are isolated by a scaled-up modification of the original method (G. A. Scarborough, 1975, J. Biol. Chem.250, 1106–1111) and stored at ?26°C in 60% glycerol ($\text{v}\text{v}$). As needed, the ghosts are washed free of glycerol and then converted to closed vesicles by a modification of the original method. With this technique, plasma membrane vesicles with normal electrogenic pump activity can be prepared daily in approximately 2.5 h.     

Proteolysis in eucaryotic cells: Aminopeptidases and dipeptidyl aminopeptidases of yeast revisited

Using nine different l-aminoacyl-4-nitroanilides and four different dipeptidyl-4-nitroanilides, aminopeptidases and dipeptidyl aminopeptidases active at pH 7.5 and (or) pH 5.5 in logarithmically growing and stationary-phase cells of Saccharomyces cerevisiae were searched for. Ion-exchange chromatography was used to separate the proteins of the soluble cell extract. Besides the three already-characterized aminopeptidases—aminopeptidase I (P. Matile, A. Wiemken, and W. Guyer (1971) Planta (Berlin)96, 43–53; J. Frey and K. H. Röhm (1978) Biochim. Biophys. Acta527, 31–41), aminopeptidase II (J. Frey and K. H. Röhm (1978) Biochim. Biophys. Acta527, 31–41; J. Knüver (1982) Thesis, Fachbereich Chemie, Marburg, FRG), and aminopeptidase Co (T. Achstetter, C. Ehmann, and D. H. Wolf (1982) Biochem. Biophys. Res. Commun.109, 341–347)—12 additional aminopeptidase activities are found in soluble cell extracts eluting from the ion-exchange column. These activities differ from the characterized aminopeptidases in one or more of the parameters such as charge, size, substrate specificity, inhibition pattern, pH optimum for activity and regulation. Also, a particulate aminopeptidase, called aminopeptidase P, is found in the nonsoluble fraction of disintegrated cells. Besides the described particulate X-prolyl-dipeptidyl aminopeptidase (M. P. Suarez Rendueles, J. Schwencke, N. Garcia-Alvarez and S. Gascon (1981) FEBS Lett.131, 296–300), three additional dipeptidyl aminopeptidase activities of different substrate specificities are found in the soluble extract.     

Quantitative dependence of mitochondrial oxidative phosphorylation on oxygen concentration: a mathematical model.

The model of Wilson and co-workers (2., 3., Arch. Biochem. Biophys. 182, 749–762) for the regulation of mitochondrial oxidative phosphorylation has been extended to include the dependence on oxygen tension. The derived rate expression correctly describes the observed dependence of cellular energy metabolism on oxygen tension, including the oxygen dependence at “normoxic” physiological values. Experimental evidence is presented that oxidative phosphorylation by suspensions of isolated rat liver mitochondria is also dependent on oxygen concentration up to values of at least 100 μM.     

Further characterization and thiophosphorylation of smooth muscle myosin

(i) Myosin from chicken gizzards was purified by a modification of an earlier procedure (M. N. Malik, 1978,Biochemistry17, 27–32). When this myosin, as well as that prepared by the method of A. Sobieszek and R. D. Bremel (1975,Eur. J. Biochem.55, 49–60), was analyzed by gradient slab gel using the discontinuous buffer system of Neville (1971,J. Biol. Chem.246, 6328–6334), a closely spaced doublet in the heavy chain and four light chains were observed as opposed to one heavy chain and two light chains with the method of Weber and Osborn (1969, J. Biol. Chem.244, 4406–4412). These findings raise the possibility of the existence of myosin isoenzymes in smooth muscle. (ii) The purified gizzard myosin was found to be free of kinase and phosphatase. Phosphorylation or thiophosphorylation of myosin was observed only by exogenously adding kinase. A maximum of 1.2 mol of ³²P/mol of myosin and 2.3 mol of ³⁵S/mol of myosin were obtained. The actin-activated ATPase activity depended upon the extent of thiophosphorylation of myosin; a four- to fivefold increase in the activity was observed when myosin was fully thiophosphorylated. Thiophosphorylated myosin was found to be more stable than phosphorylated myosin.     

Design principles for active transport systems

We have previously described simple models for active transport and have derived steady state equations for the unidirectional flux of substrate in terms of a minimal set of kinetic parameters. Here we consider how to maximize the pumping rate of a carrier-enzyme through the optimal utilization of the ATP hydrolysis reaction. The equations for net flux contain rate constants and dissociation constants and these determine the maximum velocities and affinities measured in transport kinetic analysis. It is assumed that the rate constants can evolve to the diffusion limited rate of substrate binding as has apparently occurred in the enzyme triosephosphate isomerase (Knowles & Albery, 1977). The dissociation constants of the rate limiting intermediates fit the affinities for substrates on different sides of the membrane and are dependent on the basic free energy levels (Hill, 1976) of the carrier substrate system. From our analysis it is clear that there are three ways to design a system with optimal affinities and that the choice is linked to the sequence of substrate binding. It is possible to use free energy differences of isomerization (Boyer, 1975) or ligand-ligand interactions (Weber, 1975) both of which have been described previously, but which are incorporated here into a unified treatment. A third possibility is to couple the binding step of a transported ligand to the progress of a chemical reaction as might occur, for example, if Na⁺ must be bound before the carrier can be phosphorylated. In this way the free energy of hydrolysis can be used not only to drive the overall pumping reaction, but also to fix differentially the affinity for substrate on either side of the membrane, as required for rapid pumping.     

Liberation of labile sulfur from ferredoxins by alkaline zinc reagent: an appraisal of the methylene blue method.

In disagreement with reported observation by Suhara and her colleagues (K. Suhara, S. Takemori, M. Katagiri, K. Wada, H. Kobayashi, and H. Matsubara, 1975, Anal. Biochem.68, 632–636) we found that more than 90% of labile sulfur was liberated from adrenodoxin within 5 min at 22°C. This rate was faster than those of spinach and clostridial ferredoxins, a result also at variance with Suhara's observation. At low temperature, the reaction was clearly biphasic, and spinach ferredoxin showed a similar profile. In the absence of zinc acetate, activation energies of the decomposition reaction of iron-sulfur center of OH^? were obtained as 39, 26, and 11 kcal/mol for adrenal, spinach, and clostridial ferredoxins, respectively. The adrenal reaction became faster as the dipole moment of the solvent increased. In the presence of 4 m urea and 1 m KCl, the rate was enhanced by approximately 26-fold, relative to the reaction without the addition of urea. In conclusion, the liberation reaction of adrenal labile sulfur with alkaline zinc reagent is fast at 22°C, indicating no need for modification of the original method (T. Kimura and K. Suzuki, 1967, J. Biol. Chem.242, 485–491; P. E. Brumly, R. W. Miller, and V. Massey, 1965, J. Biol. Chem.240, 2222–2228).     

Transport and metabolism of N-δ-chloroacetyl-l-ornithine by Saccharomyces cerevisiae

The general amino acid transport system of Saccharomyces cerevisiae functions in the uptake of neutral, basic, and acidic amino acids (M. Grenson, C. Hou, and M. Crabeel, 1970,J. Bacteriol. 103, 770–777; J. Rytka, 1975,J. Bacteriol.121, 562–570; C. Darte and M. Grenson, 1975,Biochem. Biophys. Res. Commun.67, 1028–1033). We have previously demonstrated that this transport system can be inhibited by the amino acid, N-δ-chloroacetyl-l-ornithine (NCAO) (F. S., Larimore and R.J. Roon, 1978,Biochemistry17, 431–436). In the present study radiolabeled NCAO was synthesized and its transport and metabolism studied. Under initial rate conditions: (a) NCAO was transported by the general amino acid transport system with a K_m of 52 μm, a V of 32 nmol/min/mg cells, and a pH optimum of 5.0; (b) the V for NCAO transport in gap mutants, which lack the general amino acid transport system, was approximately 1% of that observed with wild-type cells; (c) the V for NCAO in cells deprived of glucose was less than 5% of that observed when glucose was present. NCAO was transiently concentrated more than 1000-fold by yeast cells when glucose served as an energy source. The internal pool of NCAO was metabolized by the yeast cells and the products were excreted. When 100 μm [¹⁴C]NCAO was incubated with a yeast cell suspension for 8 h, more than 95% of the compound was converted into two ninhydrin-negative excretory products. The effect of NCAO on the growth of yeast cells was determined. Wild-type strains did not grow when 1 mm NCAO was present in the medium. The growth of gap mutants was not inhibited by 1 mm NCAO.     

Mitochondrial RNAs are abundant in the poly(A)+RNA population of early frog embryos

Mitochondrial sequences have been identified within a set of cloned complementary DNAs that had been copied from poly(A)⁺RNA of two embryonic stages of Xenopus laevis (Dworkin and Dawid, 1980, Dworkin and Dawid, 1980, Develop. Biol.76, 435–448 and 449–464). Mitochondrial sequences were found to be highly abundant in gastrula stage poly(A)⁺RNA sequences; in tadpole RNA their relative abundance is reduced severalfold. Mitochondrial sequences account for the most abundant poly(A)⁺RNA molecules in the gastrula population. The high abundance of mitochondrial RNA in early stages may be the consequence of the accumulation of large numbers of mitochondria in the egg.     

Perturbation of membrane phospholipids alters the interaction between epidermal growth factor and its membrane receptors

This report presents electron microscopic evidence of statistically significant changes in the microtubule number concentration and length distribution after the attainment of monomer-polymer equilibrium (“steady state”). We also extend previous theoretical work on polymer redistribution (F. Oosawa, 1970, J. Theor. Biol.27, 69–86).     

Fusion of chick embryo skeletal myoblasts: interactions of prostaglandin E1, adenosine 3':5' monophosphate, and calcium influx

In the accompanying paper (J. D. David, W. M. See, and C.-A. Higginbotham, 1981, Develop. Biol.82, 297–307) we demonstrated that a net calcium influx into fusion-competent myoblasts is a requisite step in membrane fusion. Zalin and Montague, 1974, Zalin, 1977 has shown that a prostaglandin E₁ (PGE₁)-dependent transient rise in cAMP occurs 5–6 hr prior to myoblast fusion. In this communication we show that (1) the increase in intracellular cAMP precedes, and/or is independent of, the calcium influx; (2) the calcium influx is either directly or indirectly dependent on PGE₁ activity as well as PGE₁ synthesis; and (3) although the cAMP increase may be essential for fusion, it is not sufficient in the absence of calcium influx. Our experiments define fusion competency, at a minimum, as (1) the accumulation of extracellular PGE₁ receptors; (2) the accumulation of intracellular cAMP receptors; and (3) the ability to respond to a calcium influx.     

Investigation of the pH dependence of proton uptake by porcine heart mitochondrial malate dehydrogenase upon binding of NADH

The pH dependence of proton uptake upon binding of NADH to porcine heart mitochondrial malate dehydrogenase (l-malate: NAD⁺ oxidoreductase, EC 1.1.1.37) has been investigated. The enzyme has been shown to exhibit a pH-dependent uptake of protons upon binding NADH at pH values from 6.0 to 8.5. Enzyme in which one histidine residue has been modified per subunit by the reagent iodoacetamide (E. M. Gregory, M. S. Rohrbach, and J. H. Harrison, 1971, Biochim. Biophys. Acta253, 489–497) was used to establish that this specific histidine residue was responsible for the uptake of a proton upon binding of NADH to the native enzyme. It has also been established that while there is no enhancement of the nucleotide fluorescence upon addition of NADH to the iodoacetamide-modified enzyme, NADH is nevertheless binding to the modified enzyme with the same stoichiometry as with native enzyme. The data are discussed in relation to the involvement of the essential histidine residue in the catalytic mechanism of “histidine dehydrogenases” recently proposed by Lodola et al. (A. Lodola, D. M. Parker, R. Jeck, and J. J. Holbrook, 1978, Biochem. J.173, 597–605) and the catalytic mechanism of “malate dehydrogenases” recently proposed by L. H. Bernstein and J. Everse (1978, J. Biol. Chem.253, 8702–8707).     

Does a functional relationship exist between the polymerization and catalytic activity of beef liver glutamate dehydrogenase?

The recent work of Cohen &; Benedek (1976) and Cohen et al. (1975, 1976) on the apparent interdependence of beef liver glutamate dohydrogenase catalytic activity and degree of polymerization is examined in the light of previously published equilibrium and kinetic results. It is shown that some of the hypotheses central to the Cohen &; Benedek (1976) model are in contradiction with existent data. Consideration of all available information leads to the conclusion that effector-induced depolymerization may simply be an incidental side reaction in the events leading to inhibition.     

The role of migration in the genetic structure of populations in temporally and spatially varying environments II. Island Models

The Island Model introduced by Sewall Wright (1951) has proven to be a useful construction for studying the interaction of genetic drift, population subdivision, and mutation. Interest in the model has recently increased because of its relevance to certain questions involving the rate of differentiation of sub-populations under the neutral allele hypothesis (e.g., Smith, 1970; Latter, 1973). It is perhaps the only realistic population structure in which the test for neutrality proposed by Lewontin and Krakauer (1973) is valid (Lewontin and Krakauer, 1975). If data from natural populations is to be compared to the predictions of the Island Model, it is desirable to have an alternative model with the same migration pattern but with natural selection operating. In this paper one such model will be introduced where the stochastic element comes from random fluctuations in the environment rather than from genetic drift. The model is a direct extension of the one in the previous paper in this series (Gillespie, 1975) which dealt with a population which is subdivided into two patches with restricted migration between them.     

The Plasmodium vaughani--Complex

Plasmodium vaughaniNovy and MacNeal, 1904, Plasmodium tenueLaveran and Marullaz, 1914, and Plasmodium merulaeCorradetti and Scanga, 1972 are shown to differ. It is suggested that P. tenue and P. merulae should be considered as subspecies belonging to Plasmodium vaughani-complex.More investigations are needed for a sufficient knowledge of the complex, particularly because at least 36 species of birds harbor P. vaughani-like parasites and cover an immense geographical area in all the parts of the world.     

Replication of polyoma DNA in isolated nuclei. VII. Initiator RNA synthesis during nucleotide depletion.

Earlier experiments demonstrated that the Okazaki fragments synthesized during discontinuous polyoma DNA synthesis in isolated nuclei at their 5′ ends contained structural elements consisting of polyribonucleotides starting with ATP or GTP (Reichard et al., 1974). These structures could be released by digestion with pancreatic DNAase and were named initiator RNA. They consist of a large family of polyribonucleotides differing in base sequence but having a common size of about a decanucleotide. We now demonstrate that limitation of DNA synthesis by low concentrations of deoxyribonucleoside triphosphates in parallel limits the synthesis of initiator RNA. This is additional evidence for the primer function of initiator RNA. When ribonucleoside triphosphates other than ATP were deleted from the incubation medium only a small decrease of DNA and initiator RNA synthesis occurred. Under those conditions deoxyribonucleotides substituted for ribonucleotides and were incorporated internally into the primer. From this result as well as the insensitivity of initiator RNA synthesis to α-amanitin (Reichard &; Eliasson, 1979) we suggest that a mammalian counterpart to primase, the dnaG gene product of Escherichia coli(Rowen &; Kornberg, 1978a), catalyzes the synthesis of initiator RNA.