Function of the <Emphasis Type="Italic">rel</Emphasis> Gene in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Sokawa et al. suggest that rel^- strains of Escherichia coli possess abnormal protein synthesizing machinery, which cannot carry out normal protein synthesis when the supply of amino-acids is limited.     

“Pleiotypic Response”

A hypothesis has been developed to relate stringent control in bacteria to a set of interactions involved in the regulation of growth of transformed and untransformed mammalian cells.     

Electrotonically Coupled Interneurones produce Two Types of Inhibition in <Emphasis Type="Italic">Aplysia</Emphasis> Neurones

IN the abdominal ganglion of Aplysia californica, there are two types of inhibitory post-synaptic potentials (IPSPs). There are unitary short-lasting IPSPs which occur as the result of conductance changes during the movement of Cl^? across the synaptic membrane—IPSPs which have definite equilibrium potentials and characteristics similar to those described for other neuronal systems¹—and there are IPSPs which last much longer and may be much more effective in regulating the activity of the neurone, which Taue has called “inhibitions of long duration” (ILD)^2,3. In Aplysia some of these long lasting inhibitory potentials are produced by conductance changes and have definite equilibrium potentials⁴. Long lasting inhibitions or “slow inhibitory potentials” as well as short lasting IPSPs have also been described in vertebrate sympathetic ganglia⁵, but in these, long lasting IPSPs are not accompanied by changes in membrane conductance. Some of the long lasting inhibitions (LLI) have been explained on the basis of an ATP-dependent electrogenic Na+ pump⁶. Presumably this ATP-dependent pump hyperpolarizes the membrane by causing an outflux of Na+ from the cell which is more rapid than the corresponding “active” influx of K+⁷. There is evidence now for the existence of such an electrogenic Na+ pump in some of the identified neurones of the abdominal ganglion of Aplysia californica⁸. Pinsker and Kandel⁹ have found some evidence that in these neurones the electrogenic Na+ pump is activated by the synaptic action of an identified cholinergic inhibitory interneurone, L10, producing the long lasting “late IPSP”. But Kehoe and Ascher¹⁰, although agreeing that the same interneurone (L10) produces both types of IPSPs in the follower neurones, have shown that the “late IPSP”⁹ is due to an increase in the K+ conductance and that it has an equilibrium potential around ?90 mV. I have found that in this abdominal ganglion there is another specific interneurone which is electrotonically coupled to L10 and which, when activated, produces a long lasting inhibition (LLI) in a number of follower neurones. Thus L10 produces the LLI or “late IPSP” in some follower neurones not directly, but through the mediation of another interneurone.     

Inhibition of DNA Synthesis but not of Poly-dAT Synthesis by the Arabinose Analogue of Cytidine <Emphasis Type="Italic">in vitro</Emphasis>

Kimball and Wilson¹ reported that the arabinose analogue of cytidine (ara-C) inhibited DNA polymerase in a crude extract prepared from Ehrlich ascites cells. Furth and Cohen² observed cytosine arabinoside triphosphate (ara-CTP) inhibited DNA polymerase in extracts from either calf thymus or bovine lymphosarcoma tissue, although these investigators³ had already found no effect of ara-CTP on DNA polymerase from Escherichia coli. The inhibition in both of these cases could be substantially reversed by dCTP; but incorporation of the arabinose nucleotide (ara-CMP) into DNA could not be unequivocally demonstrated. Graham and Whitmore⁴ reported the incorporation of ara-C into DNA in vivo and the inhibition of a DNA polymerase from L cells by ara-CTP. They found that ara-CMP was initially incorporated into small DNA strands but subsequently appeared in long strands. Momparler⁵ has presented evidence that, in vitro, ara-C incorporation was limited to the 3′-hydroxyl end of DNA chains. Such incorporation might be expected to block further chain elongation but this expectation was not supported by the evidence presented by Graham and Whitmore.     

Endopeptidase Activity of Phage λ-Endolysin

JACOB and Fuerst^1,2 demonstrated the presence of a bacteriolytic enzyme (λ-endolysin) in the induced cultures of lysogenic Escherichia coli K12 (λ). The enzyme was later identified as the product of gene R; of phage λ³ which is involved in bacterial lysis at the end of a latent period. The enzyme is apt to form spheroplast-like structures in E. coli² and one would therefore expect its substrate to be murein.     

Induced Bivalent Interlocking and the Course of Meiotic Chromosome Synapsis

WHEN chromosomes pair at meiosis the bivalents so formed do not normally interlock. Heat-treatments can, however, induce bivalent interlocking in the locust Locusta migratoria. Only the longest bivalents interlock and usually only two are found per cell; two “rod” bivalents, with single chiasmata, two “ring” bivalents, each with two or three chiasmata, or one “rod” and one “ring” bivalent (Fig. 1a, b and c). The nature of this interlocking and the metaphase orientational and congressional properties of interlocked bivalents are analysed in detail elsewhere¹.     

Progesterone transformations as a diagnostic feature in the generaAlternaria,Stemphylium andCladosporium

Various species of the generaAlternaria, Stemphylium andCladosporium were shown to display a specific reaction characteristic for the given genus. In theAlternaria genus this is a 1-2-dehydrogenation of the A ring of the steroid molecule, inStemphylium 14α-hydroxylation and inCladosporium 7β-hydroxylation. This chemotaxonomic feature may supplement morphological and functional criteria in the taxonomy of filamentous fungi (Hyphomycetes).     

Purification and characterization of beta-glucosidase of Alcaligenes faecalis

A cellobiose-utilizing bacterium isolated from sugar cane bagasse and identified as a strain of Alcaligenes faecalis (ATCC 21400) produced an inducible beta-glucoside-splitting enzyme. The enzyme was purified by a series of streptomycin and ammonium sulfate fractionations and by Sephadex and diethylaminoethyl column chromatography. The final preparation was purified 130-fold, with a recovery of about 10% of the initial enzyme activity. The enzyme had a wide pH range, with optimal activity at pH 6.0 to 7.0. The enzyme was stable in solution at pH 6.5 to 7.8 when kept at 30 C for 2 hr, but it was destroyed by temperatures above 55 C. At 58 and 60 C, the time required to inactivate 90% of the initial activity was 16 and 6.5 min, respectively. An activation energy of 9,500 cal/mole and a K(m) of 1.25 x 10(-4)m were obtained by using p-nitrophenyl beta-glucoside as a substrate. The K(i) value and hydrolysis of cellobiose by the enzyme indicated a high affinity of the enzyme for the cellobiose. The enzyme had its specificity on beta-glucosidic linkage and the rate of hydrolisis of glucosides depended upon the nature of the aglycon moiety. The inactivation studies showed the presence of sulfhydryl groups in the enzyme. The activity of the enzyme was easily destroyed by the Cu(++) and Hg(++) ions. The Michaelis-Menton relationship and the rate of heat inactivation indicated the presence of one type of noninteracting active site in the bacterial beta-glucosidase. Molecular weight of the enzyme was estimated by gel filtration (Sephadex G-200) and sucrose density gradient, and a value of 120,000 to 160,000 was obtained.