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Target Concepts:
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Query: EC:1.9.3.1 (
cytochrome oxidase
)
8,822
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The effects of sublethal heat pulses on cell division have provided insights into possible molecular mechanisms. Thus Zeuthen's findings of 'set-backs' up to a transition point provides the basis for the idea that the continuous accumulation of a compound needed for cell division spans a major portion of the cell cycle. The accumulating substance is a 'division protein' which forms part of a structure which is unstable until completely assembled at the transition point. Experiments showing phase resetting of mammalian cells by temperature perturbation indicate limit-cycle oscillator control of the cell cycle with a phase-response curve with a repeat interval equal to the period of the clock. As well as providing a method for establishing synchronized cultures these observations have found application in the selective effects of hyperthermia as an antitumour agent. Circadian rhythms display several unique features distinguishing them from other periodic processes. Only recently has it been recognized that some of these characteristics may be properties of ultradian rhythms as well. The probably most striking feature of circadian timekeeping, i.e. independence of ambient temperature, was found for ultradian rhythmicity even at the level of the unicellular organization. Synchronous cultures of some lower eukaryotes were prepared by centrifugal size selection methods. Experiments with asynchronous control cultures substantiated the view that the conditions employed were such as to minimize any perturbative effects: most importantly the organisms were never removed from their culture medium. Whereas the control cultures showed smoothly increasing respiration rates, total RNA, total protein, enzyme activities and enzyme protein (e.g. for
cytochrome aa3
, ATPase, catalase), in synchronous cultures all these parameters showed oscillatory behaviour. Different periods were observed in different organisms: thus in Acanthamoeba castellanii the period was about 70 min, in Tetrahymena pyriformis strain ST it was about 50 min, in T. pyriformis
AII
it was 30 min, and in Candida utilis it was about 30 min (all measurements at 30 degrees C). In A. castellanii the periods of both the oscillations in rate of respiration and the total cell protein were hardly affected by the temperature of growth over the range 20 to 30 degrees C. The oscillations show no damping during experiments lasting 12 h: these properties suggest that we are observing temperature-compensated endogenous rhythms which presumably serve a timekeeping function in cells undergoing growth and division.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:A temperature-compensated ultradian clock explains temperature-dependent quantal cell cycle times. 333 82
1. Two 8 x 8-channel microelectrode arrays were used to map epicortical field potentials from a 3.5 x 3.5-mm2 area in homologous regions of right and left parietotemporal cortex of four rats. Potentials were evoked with bilaterally presented click stimuli and with bilateral tactile stimulation of the 25 major vibrissae. The spatial distribution of temporal components of the somatosensory evoked potential (SEP) and auditory evoked potential (AEP) complex were compared directly with
cytochrome oxidase
-stained sections of the recorded region. 2. Epicortical responses in both hemispheres to bilateral vibrissal stimuli consisted of a biphasic sharp wave (P1a-N1) constrained to the vibrissa/barrel granular region of primary somatosensory cortex (SmI). A slightly later sharp positive wave (P1b) was localized to secondary somatosensory cortex (SmII) and to perigranular cortex medial to the vibrissa/barrel field. The SEP complex ended with a biphasic slow wave (P2-N2). The P2 was centered on SmI and spread to dysgranular lateral cortex, caudal to but excluding SmII. The N2 was centered on SmII and spread to dysgranular cortex caudal to but excluding SmI. 3. The anatomic organization of the AEP in many ways approximated that of the SEP in the same animals. The timing and morphology of the AEP were nearly identical to the SEP. The AEP consisted of a P1a-N1 sharp wave constrained to the estimated region of primary auditory cortex (AI) in the lateral parietotemporal region, a later P1b localized to secondary auditory cortex (
AII
), and subsequent slow waves (P2 and N2) that were centered on AI and
AII
, respectively, and spread to dysgranular regions overlapping the distributions of the P2 and N2 of the SEP complex. 4. These data suggest that the basic neural generators for the SEP and AEP in parietotemporal cortex are quite similar, and provide evidence for the functional anatomy of each temporal component of the sensory evoked potential complex. It is concluded that the early fast waves of the SEP and AEP are modality specific and may represent the parallel activation of primary and secondary sensory cortex through established parallel afferent projections from lateral and medial thalamic nuclei. The later slow waves of the SEP and AEP appear to selectively involve primary and secondary sensory cortex but are more widely distributed, possibly reflecting a less modality-specific level of information processing in dysgranular cortex.
...
PMID:Anatomic organization of evoked potentials in rat parietotemporal cortex: somatosensory and auditory responses. 839 9
