The reaction of the mutagen 1,1′-hexamethylene-bis[(5-p-chlorophenyl)-biguanide] with guanosine and cysteine

The mutagen 1,1′-hexamethylene-bis[(5-p-chlorophenyl)-biguanide] reacts at 37°C with guanosine and guanine to yield xanthosine or xanthine and oxidizes cysteine to cystine. After treatment of a guanosine-labelled DNA sample from Escherichia coli with the mutagen xanthine could be detected as a reaction product. At a slow rate the mutagen is hydrolysed spontaneously yielding urea, 1,6-hexanediol and 4-chloroaniline. The reaction mechanisms both of the hydrolysis and of the reaction with cysteine and guanosine are discussed.     

Biochemical studies of the excitable membrane of Paramecium tetraurelia. V. effects of proteases on the ciliary membrane

The swimming behavior of Paramecium is regulated by an excitable membrane that covers the body and cilia of the protozoan. In order to obtain information on the topology and function of ciliary membrane proteins, Paramecia were treated with trypsin, chymotrypsin or pronase and the effects of these proteases were analyzed using electron microscopy, gel electrophoresis of ciliary fractions and behavioral tests. At the concentrations used, trypsin and chymotrypsin had little or no effect on the cells while pronase removed the cell surface coat, visible as fuzzy material covering the cell membrane. The same pronase treatment caused the specific removal of a high molecular weight protein (250 000), as judged by sodium dodecyl sulfate polyacrylamide gel electrophoresis. This protein, the ‘immobilization antigen’, constitutes the major protein of the ciliary membrane. Although the immobilization antigen was removed (or markedly decreased), no marked and reproducible difference was observed in the swimming behavior of the treated cells. We also determined the effects of proteases on isolated ciliary fractions to explore the sidedness of ciliary membrane proteins. A set of proteins relatively resistant to protease digestion was identified; they may be intrinsic membrane proteins.     

Current-voltage studies on the thylakoid membrane in the presence of ionophores

The reversibility of the binding of ionophores to the thylakoid membrane is studied. While gramicidin binds practically irreversibly, valinomycin and nonactin bind reversibly, however, only a small fraction (about 1 %) of the membrane-bound valinomycin or nonactin is active in ion transport. The current-voltage relationship is evaluated under these circumstances. We have found that it is practically linear. This together with the relationship between current and ion concentration agrees qualitatively with the results reported for bimolecular lipid membranes, which contain a large fraction of negatively charged lipids. For the ionophores, valinomycin and nonactin, the binding equilibria (K ≈ 10⁴) and the turnover numbers (≈ 3 · 10⁴/s) are evaluated for their action on the thylakoid membrane. Possible reasons for the inactivity of the majority of membrane-bound ionophore molecules are discussed.     

Relationships between platelet and plasma monoamine oxidase,plasma dopamine-B-hydroxylase,and urinary 3-methoxy-4-hydroxy phenylglycol

The activity of dopamine-B-hydroxylase in blood has recently been demonstrated to be under genetic control and to correlate closely with urinary catecholamine excretion. The results of the present study did not demonstrate any relationship between a major catecholamine metabolite in urine, 3-methoxy-4-hydroxy phenylglycol, and dopamine-B-hydroxylase activity in plasma, monoamine oxidase activity in platelets, or monoamine oxidase activity in plasma. Differences in the origin of urinary catecholamines and urinary 3-methoxy-4-hydroxy phenyglycol may be responsible for these divergent results.     

Changes in lectin-induced deoxyribonucleic acid synthesis in cultures of chick-embryo fibroblasts at various stages of development

Concanavalin A and Robinia pseudoacacia lectin decreased [(3)H]thymidine incorporation into acid-insoluble material of fibroblasts cultured from 6-10-day chick embryos. In contrast, these lectins stimulated [(3)H]thymidine incorporation in cells from 16-day embryos. These effects are due to neither [(3)H]thymidine permeability modification nor toxicity of the lectins. The specificity of lectin action was proved by blocking experiments with alpha-methyl mannopyranoside and with anti-(Robinia lectin) serum.     

Neurophysiology of the vibration sense in locusts and bushcrickets: The responses of ventral-cord neurones

In the locustid Locusta migratoria and the tettigoniids Decticus verrucivorus and Tettigonia cantans, comparative aspects of physiological properties of vibratory/auditory ventral-cord neurones were studied by single cell recordings.These neurones all receive inputs from both vibratory and auditory receptors. Nevertheless, they can be classified into “V neurones” responding preferentially to vibration stimuli, “VS neurones” responding to vibration and airborne sound, and “S neurones” responding preferentially to airborne sound. In every group, there are several types with different physiological properties, normally represented by one neurone on each body side.In Locusta and in the tettigoniid species, the same physiological types of vibratory/auditory neurones were found, although there are differences in the synaptic connectivity of the vibration receptors of the different legs. In Locusta, the middle leg receptors have the strongest influence on the generation of suprathreshold responses of the central neurones, whereas in the tettigoniids the receptors of the ipsilateral fore leg are the most influential.Two of the V neurones receive inputs mainly from campaniform sensilla and other low-frequency vibration receptors, the other V and VS neurones are mainly influenced by the subgenual receptors. Central information processing results in preferential responses to different frequency/intensity ranges in different neurones.Most VS neurone types show the same response characteristics (e.g. time pattern of response, habituation) either to vibration or to airborne-sound stimuli. Simultaneous presentation of both stimuli leads to qualitative changes in the response characteristics. Therefore, the co-processing of auditory and vibratory signals seems to be very important in the acoustic behaviour of grasshoppers.     

Processing of vibratory and acoustic signals by ventral cord neurones in the cricket Gryllus campestris

The responses of single vibratory receptors and ascending ventral cord interneurones were studied extracellularly in Gryllus campestris L. The physiology of the vibration receptors resembled those found in tettigoniids and locusts. The frequency responses of the subgenual receptors provide two possible cues for central frequency discrimination: differences in mean tuning between groups of receptors in the different leg pairs and a range of receptors tuned to different frequencies within one subgenual organ.Most of the ascending vibratory interneurones were highly sensitive in either the low or high frequency range. Broadbanded neurones were less sensitive. The characteristic sensitivity peaks of these units are due mainly to receptor inputs from a particular leg pair, although most central neurones receive inputs from all 6 legs. Only one neurone type, TN1 received excitatory inputs from both auditory and vibratory receptors; its responses were greatly enhanced by the simultaneous presentation of both stimulus modes. The responses to sound stimuli of AN2, on the other hand, were inhibited by vibration. No other auditory interneurones investigated were influenced by inputs from vibration receptors. Central processing of vibratory information in the cricket is compared with that of tettigoniids and locusts.