激素对不同发育阶段小麦旗叶光合速率调控研究

选择小麦旗叶叶绿素含量的相对稳定期、稳定期末期和速降期3个发育阶段,采用酶联免疫法测定旗叶中ABA／ZRs比值;将ABA、ZRs和二者的混合液引入3个发育阶段植株的蒸腾流,测定激素对不同发育阶段叶片光合速率的影响．结果表明,3个发育阶段植株旗叶中ABA／ZRs比值分别为4．20、41．83和14．40．ABA降低3个阶段叶片光合速率达到零值的时间,分别为49．5、39．1和38．0min;ZRs处理3个发育阶段小麦旗叶的光合速率值降至试验开始零分钟时测得的光合速率值一半的时间,分别为65、49和31min．小麦旗叶的前2个发育阶段为可调和可逆阶段,后1个阶段为不可调和不可逆阶段．     

Changes in the muscle fibre extracellular action potentials in long-lasting (fatiguing) activity

The dependence of extracellular action potentials (ECAPs) of single frog muscle fibres on intracellular action potentials (ICAPs) was studied during long-lasting (fatiguing) activity. The conduction velocity, peak-to-peak amplitude and amplitudes of the separate phases of the first and second ICAP time derivatives decreased during long-lasting activity. The phases of the first and second ICAP space derivatives also decreased in amplitude and lengthened. ECAPs near the membrane were similar in shape and proportional in amplitude to (formula; see text) when recording at a distance from both the end of the fibre and the point of stimulation. At long radial distances, the amplitudes of the separate ECAP phases depended on the amplitude and length of the corresponding phases of (formula; see text). Thus the decrease in ECAP amplitude during long-lasting activity at long radial distances was less than at points close to the muscle fibre membrane. The consequences of these findings for the changes in electromyograms recorded by needle or superficial electrodes during long-lasting (fatiguing) activity are discussed.     

Proliferative activity of the epithelium of the rat large intestine during carcinogenesis]

Labelling index and mitotic regimen in the epithelium of the rat descending colon and the ileum was studied during the tumour induction with 1,2-dimethylhydrazine. One month after the beginning of the experiments there was a marked increase of abnormal mitoses (up to 51%) and a change in the proportion of the mitotic phases with the metaphase prevalence (up to 73%). Later, these parameters were unchanged. Beginning from the 3rd month of the experiment there was found an increase in the labelling index (especially, in the carcinoma in situ) and of the mitotic index. In the mucosa of the ileum (where the tumours never developed) no changes of the proliferative activity and of mitotic regimen were found.     

Experimental morphological study of endings of propriospinal fibers of the lateral funiculus in the cat cervical spinal cord

The distribution and ultrastructure of terminals of the propriospinal fibers of the lateral funiculus in the cervical segments of the cat spinal cord were studied by the experimental degeneration method. A preliminary lateral hemisection of the spinal cord was carried out 5–6 months earlier at the level of segments C2 or C3 to destroy all the long descending pathways; the lateral funiculus was then divided at the level of C4 or C5. It was shown by the method of Fink and Heimer that terminals of descending and ascending propriospinal pathways damaged by the second division are distributed in the gray matter ipsilaterally in the lateral zones of Rexed's laminase V–VII and also in the dorsolateral motor nuclei. An electron-microscopic study showed that the synapses of the degenerating terminals are mainly axo-dendritic in type and account for 14.5% of the total number of terminals counted. Residual synaptic vesicles in these terminals were spherical in shape. The mean diameter of the degenerating myelinated propriospinal fibers in the lateral funiculus was 10±3 µ. The results of this investigation were compared with those of electrophysiological investigations of the function of propriospinal neurons.     

Effect of the menstrual cycle on gastric emptying

Gastric emptying of a radiolabelled solid meal was studied in 19 women. The gastric emptying curves were analyzed with the use of a power-exponential fitting, and the results were related to the phases of the menstrual cycle. No significant differences between the phases of the menstrual cycle were found when the rates of gastric emptying were compared. However, different emptying patterns in each phase of menstrual cycle were revealed by the analysis of the curve shape parameter, S. The physiological and clinical relevance of the findings is discussed.     

Ontogenetic Shape Change in the Chicken Brain: Implications for Paleontology

Paleontologists have investigated brain morphology of extinct birds with little information on post-hatching changes in avian brain morphology. Without the knowledge of ontogenesis, assessing brain morphology in fossil taxa could lead to misinterpretation of the phylogeny or neurosensory development of extinct species. Hence, it is imperative to determine how avian brain morphology changes during post-hatching growth. In this study, chicken brain shape was compared at various developmental stages using three-dimensional (3D) geometric morphometric analysis and the growth rate of brain regions was evaluated to explore post-hatching morphological changes. Microscopic MRI (μMRI) was used to acquire in vivo data from living and post-mortem chicken brains. The telencephalon rotates caudoventrally during growth. This change in shape leads to a relative caudodorsal rotation of the cerebellum and myelencephalon. In addition, all brain regions elongate rostrocaudally and this leads to a more slender brain shape. The growth rates of each brain region were constant and the slopes from the growth formula were parallel. The dominant pattern of ontogenetic shape change corresponded with interspecific shape changes due to increasing brain size. That is, the interspecific and ontogenetic changes in brain shape due to increased size have similar patterns. Although the shape of the brain and each brain region changed considerably, the volume ratio of each brain region did not change. This suggests that the brain can change its shape after completing functional differentiation of the brain regions. Moreover, these results show that consideration of ontogenetic changes in brain shape is necessary for an accurate assessment of brain morphology in paleontological studies.     

Examination of stimulation mechanism and strength-interval curve in cardiac tissue

Understanding the basic mechanisms of excitability through the cardiac cycle is critical to both the development of new implantable cardiac stimulators and improvement of the pacing protocol. Although numerous works have examined excitability in different phases of the cardiac cycle, no systematic experimental research has been conducted to elucidate the correlation among the virtual electrode polarization pattern, stimulation mechanism, and excitability under unipolar cathodal and anodal stimulation. We used a high-resolution imaging system to study the spatial and temporal stimulation patterns in 20 Langendorff-perfused rabbit hearts. The potential-sensitive dye di-4-ANEPPS was utilized to record the electrical activity using epifluorescence. We delivered S1-S2 unipolar point stimuli with durations of 2-20 ms. The anodal S-I curves displayed a more complex shape in comparison with the cathodal curves. The descent from refractoriness for anodal stimulation was extremely steep, and a local minimum was clearly observed. The subsequent ascending limb had either a dome-shaped maximum or was flattened, appearing as a plateau. The cathodal S-I curves were smoother, closer to a hyperbolic shape. The transition of the stimulation mechanism from break to make always coincided with the final descending phase of both anodal and cathodal S-I curves. The transition is attributed to the bidomain properties of cardiac tissue. The effective refractory period was longer when negative stimuli were delivered than for positive stimulation. Our spatial and temporal analyses of the stimulation patterns near refractoriness show always an excitation mechanism mediated by damped wave propagation after S2 termination.     

Discontinuous Patterns of Brain Activation in the Psychotherapy Process of Obsessive-Compulsive Disorder: Converging Results from Repeated fMRI and Daily Self-Reports

This study investigates neuronal activation patterns during the psychotherapeutic process, assuming that change dynamics undergo critical instabilities and discontinuous transitions. An internet-based system was used to collect daily self-assessments during inpatient therapies. A dynamic complexity measure was applied to the resulting time series. Critical phases of the change process were indicated by the maxima of the varying complexity. Repeated functional magnetic resonance imaging (fMRI) measurements were conducted over the course of the therapy. The study was realized with 9 patients suffering from obsessive-compulsive disorder (subtype: washing/contamination fear) and 9 matched healthy controls. For symptom-provocative stimulation individualized pictures from patients’ personal environments were used. The neuronal responses to these disease-specific pictures were compared to the responses during standardized disgust-provoking and neutral pictures. Considerably larger neuronal changes in therapy-relevant brain areas (cingulate cortex/supplementary motor cortex, bilateral dorsolateral prefrontal cortex, bilateral insula, bilateral parietal cortex, cuneus) were observed during critical phases (order transitions), as compared to non-critical phases, and also compared to healthy controls. The data indicate that non-stationary changes play a crucial role in the psychotherapeutic process supporting self-organization and complexity models of therapeutic change.     

Neuromuscular alterations during walking in persons with moderate knee osteoarthritis.

This paper compared the neuromuscular responses during walking between those with early-stage knee osteoarthritis (OA) to asymptomatic controls. The rationale for studying those with mild to moderate knee OA was to determine the alterations in response to dynamic loading that might be expected before severe pain, joint space narrowing and joint surface changes occur. We used pattern recognition techniques to explore both amplitude and shape changes of the surface electromyograms recorded from seven muscles crossing the knee joint of 40 subjects with knee OA and 38 asymptomatic controls during a walking task. The principal patterns for each muscle grouping explained over 83% of the variance in the waveforms. This result supported the notion that the main neuromuscular patterns were similar between asymptomatic controls and those with OA, reflecting the specific roles of the major muscles during walking. ANOVA revealed significant (p<0.05) differences in the principal pattern scores reflecting both amplitude and shape alterations in the OA group and among muscles. These differences captured subtle changes in the neuromuscular responses of the subjects with OA throughout different phases of the gait cycle and most likely reflected changes in the mechanical environment (joint loading, instability) and pain. The subjects with OA attempted to increase activity of the lateral sites and reduce activity in the medial sites, having minimal but prolonged activity during late stance. Therefore, alterations in neuromuscular responses were found even in this high functioning group with moderate knee OA.     

Shape and orientation of articular facets of cervical vertebrae (C3-C7) in dogs denoting axial rotational ability: an osteological study

Macerated cervical vertebrae of 139 adult and 39 juvenile dogs were assessed for morphological evidence of axial rotation, which is denoted by the shape and orientation of the articular facets. The potential effect of the presence of caudal costal foveae at C7 on facet geometry was also investigated. Four variations of caudal facet shape were evident, namely, plane, concave, convex and sigmoid. The earliest onset of change in shape from plane to curved was noticed in juvenile dogs who were older than 8 weeks. The incidence of curved facets denoting axial rotation ability was observed to increase on descending down the cervical spine. Concave caudal facets were more frequently present in males and in large dogs (P < 0.001), compared to Dachshunds and small breeds. The degree of concavity was not related to age but was associated with the transverse distance between the most medial aspects of the caudal and corresponding cranial facets (P < 0.05). In large breeds, the presence of concave caudal facets at C7 was inversely related to the presence of caudal costal foveae (P < 0.01). The effect of axial rotation is discussed in context with clinical literature suggesting that axial rotation might attribute to the development of the wobbler syndrome.     

Effects of neck and circumoesophageal connective lesions on posture and locomotion in the cockroach

Few studies in arthropods have documented to what extent local control centers in the thorax can support locomotion in absence of inputs from head ganglia. Posture, walking, and leg motor activity was examined in cockroaches with lesions of neck or circumoesophageal connectives. Early in recovery, cockroaches with neck lesions had hyper-extended postures and did not walk. After recovery, posture was less hyper-extended and animals initiated slow leg movements for multiple cycles. Neck lesioned individuals showed an increase in walking after injection of either octopamine or pilocarpine. The phase of leg movement between segments was reduced in neck lesioned cockroaches from that seen in intact animals, while phases in the same segment remained constant. Neither octopamine nor pilocarpine initiated changes in coordination between segments in neck lesioned individuals. Animals with lesions of the circumoesophageal connectives had postures similar to intact individuals but walked in a tripod gait for extended periods of time. Changes in activity of slow tibial extensor and coxal depressor motor neurons and concomitant changes in leg joint angles were present after the lesions. This suggests that thoracic circuits are sufficient to produce leg movements but coordinated walking with normal motor patterns requires descending input from head ganglia.Electronic Supplementary Material Supplementary material is available for this article at     

Extracellular potential field of excited isolated frog muscle fibres immersed in a volume conductor

The extracellular potential field of isolated frog muscle fibres immersed in a volume conductor was studied at radial distances up to 3 mm during excitation. The shape of the field distant from both the point of the origin of the excitation and the end of the fibre as well as changes in the field when depolarization wave approached the fibre end were described. Different amplitude decrease rates in individual phases of the extracellular potential and the peak-to-peak amplitude at different temperatures were found. Extracellular potentials at long radial distances were recorded using an averaging technique. The shape of the extracellular potentials at long radial distances over the fibre and beyond its end were very similar to the shape of extraterritorial potentials of a single motor unit.     

The fate of persisting thoracic neurons during metamorphosis of the meal beetle Tenebrio molitor (Insecta: Coleoptera)

Summary A set of motor neurons and interneurons in the thoracic nervous system of the meal beetle Tenebrio molitor L. is described that persist during metamorphosis. The motor neurons under discussion innervate the thoracic ventral longitudinal muscles and were identified by retrograde transport of intramuscularly injected horseradish peroxidase. Persisting motor neurons exhibit a complex repetitive pattern that changes only slightly during development. Additionally, the characterization of serotonin-immunoreactive neurons defines a complex set of interneurons that also persist throughout development. The fate of these identified neurons is outlined in detail with special reference to variations in their dendritic arborizations. All motor and interneurons are affected by a similar change in their shape during development. The larval neurons lack the contralateral arborization that is found in the adult beetle and is already distinguishable in the prepupa. Essentially only quantitative changes of the neuronal shape were observed during the pupal instar. No pupa-specific degeneration of certain axo-dendritic structures of these neurons was found. Removal of descending interneurons by sectioning the promesothoracic connectives causes specific degeneration of the dendritic tree of an identified serotonin-immunoreactive interneuron.     

Correlation of adenosine phosphate levels with cellular morphology in Dictyostelium discoideum amoebae

Prior to completion of aggregation and the beginning of multicellular differentiation, the amoebae of Dictyostelium discoideum assume two distinct phases with characteristic changes in cellular movement, shape and adhesiveness. These two phases of amoeboid behaviour have been studied with respect to the quantitative analysis of the intracellular adenosine phosphates, using both enzymatic and chromatographic techniques. A higher intracellular ATP level and energy-charge has been found for the actively moving, non-adhesive amoebae as compared to the flattened, mutually adhesive cells. The importance and possible role of ATP in regulating amoeboid form, movement and cell adhesion is discussed.     

Mesenteric microvessel reactivity in rats in mesenteric shock

Reactivity of rat mesenterial microvessels was studied during mesenterial shock. The development of the shock was discovered to involve two phases in the changes of microvascular reactivity. The sensitivity of microvessels to adrenaline was increased at the beginning of the shock whereupon it started descending. This phenomenon evidences that vasodilatation occurring at the late stages of the shock development is determined not only by a reduction in the concentration of endogenous adrenaline and noradrenaline but also by a decrease in the sensitivity of microvessels to these agents. The data obtained make it possible to explain the mechanism of steady vasodilatation in response to injection of exogenous adrenaline and noradrenaline, which is seen at the late stages of mesenterial shock.     

Time-dependent changes in the structure of the synapses of hippocampal field CA3 after their potentiation

The time-dependent quantitative ultrastructure of synapses in the stratum lucidum of the hippocampal CA3 area was investigated after the in vitro modulation of the synaptic efficacy by short tetanus applied to the fascia dentate (a so called long-term potentiation-LTP). Two distinct phases were shown in the structural alterations accompanying LTP. Firstly, significant reactive changes in the spine geometry and the active zone shape were observed. These changes reversibly disappeared during 2-3 hours of the subsequent incubation, whereas LTP became well pronounced at this time. Secondly, a substantial increase in the postsynaptic thickness was revealed. This morphological feature was matching more closely the time course of LTP, up to the disappearance of both structure and function within 5 hours or longer as a result of destructive changes during a prolonged in vitro incubation. We conclude that the increased postsynaptic thickness may structurally correspond to LTP.     

On the rate of evolutionary processes in solitary population waves: Phase transitions in microevolution

It is shown that, like physical systems, populations of species can be in different phases, depending on environmental conditions. These phases, like phases of physical systems, are described by specific state equations. The physical phenomenon of solitary population waves is revealed for the phase of invasion of organisms into their secondary range. The mathematical model has a solution in the form of a solitary wave propagating with a constant speed without changes in shape. The self-organization in solitary waves differs sharply from population processes in the primary species range and is close to the physical foundation of the theory of autosolitons. Solitary waves are impossible within the primary species range. A capacity for the formation of solitary waves is only revealed in phylogenetically young “juvenile taxa.” These coenophobes show the highest rates of adaptive changes, are provoked to expand into new areas. Their phase transitions are distinguished not only by an exclusively wide range of fluctuations of population density, but also high phenotypic variability. The macroevolutionary processes can be provided by juvenile taxa in solitary population waves formed as a result of disruption of ecosystems and invasions. Macrotaxa cannot appear in stable successional systems.     

Effect of chemical ablation of myenteric neurones on intestinal cell proliferation

The duodenum or descending colon of male Wistar rats (average weight 60 g) was treated by a serosal application of a 0.2% solution of benzalkonium chloride (BAC) for 30 min. Control animals were treated with 0.9% (physiological) saline. The rats were allocated to four groups: Group DC (N = 8) in which the duodenum was treated with physiological saline; Group DB (N = 8) in which the duodenum was treated with BAC; Group CC (N = 7) in which the descending colon was treated with physiological saline and Group CB (N = 7) in which the descending colon was treated with BAC. After treatment, the animals were followed up for 5 months. At the end of the experiment, the animals were injected intraperitoneally with vincristine sulphate before sacrifice. Three segments were removed from the duodenum and descending colon for neuronal counting, catecholamine and serotonin measurements and morphokinetic studies of the epithelium. The following results were obtained: (1) there was a significant reduction in neurone number in the myenteric plexus of segments treated with BAC; (2) in the denervated intestinal segments, catecholamine levels were unchanged whereas serotonin levels were increased; (3) epithelial hyperplasia was observed in the denervated duodenum and descending colon; and (4) crypt cell production rate in the duodenum was similar in groups DC and DB but was significantly increased in the descending colon in group CB as compared with controls (CC). The present findings indicate that selective myenteric neuronal denervation caused by benzalkonium chloride plays a causative role in the hyperplasia and crypt cell production rate of the intestinal epithelium (duodenum and descending colon). These changes are probably induced by functional imbalance by the surviving neuronal elements in the gut, implicating neurotransmitters such as acetylcholine, noradrenaline, serotonin, somatostatin and vasoactive intestinal peptide.     

Gain control in the electrosensory system: a role for the descending projections to the electrosensory lateral line lobe

The responses of E-cells, basilar pyramidal cells, of the electrosensory lateral line lobe (ELLL) were studied in normal animals (Apteronotus leptorhynchus) and in fish in which a component of the descending input from the midbrain n. praeeminentialis to the ELLL was interrupted by lesions or by application of local anesthetics. This treatment increased the responsiveness of these neurons by 100 to 300%. A method is described by which the animal's electric organ discharge (EOD) can be increased or decreased in amplitude. Responses of E-cells to a brief stationary electrosensory stimulus and to moving electrolocation targets were studied in normal and in lesioned animals with normal and altered EOD amplitudes. Large reductions in EOD amplitude, approximately 50%, result in no significant changes in the average size of E-cells' responses to either type of electrosensory stimulus in normal animals. Interruption of the descending input, however, results in a loss of the E-cells' ability to maintain constant response size when the EOD amplitude is reduced. Increases in EOD amplitude cause reductions in the size of E-cell responses to the moving electrolocation targets and to the stationary stimulus. The effects of increased EOD amplitude are present in normal animals and in animals in which the descending input is interrupted. The descending input to the ELLL seems to function as a gain control mechanism that is capable of compensating for losses in stimulus strength resulting from reduced EOD amplitude. The component of the descending input studied here does not seem to play a role in the response of the system to increases in EOD amplitude. These results are discussed in conjunction with the known details of the ELLL circuitry and its connections with other brain areas.