Physiological responses of Triplaris gardneriana Wedd. seedlings (Polygonaceae) under intermittent drought

Triplaris gardneriana Wedd is a deciduous riparian tree occurring in areas with different climatic conditions in Brazil, from the rainforest to the tropical dry forest. An increase in global temperature and drought events can change the growth pattern and establishment of the species. To evaluate the effects of intermittent drought on the growth of T. gardneriana seedlings, an experiment was performed using seedlings with one month old subjected to three water treatments (daily irrigation as control, and intermittent drought through cycles of water suppression of seven (S7) and 14 days-intervals (S14) between watering. Growth, biomass production and partitioning, relative water content (RWC), the accumulation of organic solutes, protoplasmic integrity and phenotypic plasticity index (PPI) were evaluated for a better understanding about its drought tolerance level. Intermittent drought severely affected plants growth in S14 plants, showing lower plant height, number of leaves, leaf area, and dry biomass. RWC was reduced, while carbohydrates and proline contents increased in response to drought stress. Protoplasmic damage increased electrolyte leakage in plants subjected to severe stress. However, T. garderiana demonstrated moderate tolerance to water deficit. The plastic changes observed were more physiological than morphological. Therefore, T. gardneriana seems to be a moderately tolerant species to intermittent drought.

Geoplastics of relief as a means of forming the perception of landscape compositions on the example of the Pechersk landscape park in Kyiv

Geoplastics, as a method of vertical planning, is gaining more and more popularity among landscape architects, because this method gives the landscape an aesthetic unity, expressiveness, and a peculiar feature. The paper considers the influence of geo-plastic changes in the relief on a person, the viewer's perception of the environment. These factors are extremely important in the creation and design of the park, they allow the key elements to be presented, while creating harmonious combinations in the space, it is admirable and it is this that encourages you to visit the landscape object. Pechersk Landscape Park is located on the picturesque slopes of the Dnieper in Kiev, has a landscape type of planning, which is characterized by large areas of lawns with groups of shrubs and trees, the lack of symmetry in the placement of alleys and other elements of free planning. The park zone itself covers an area of 32,92 hectares. Location in difficult terrain contributes to the use of geo-plastic tools, which can be used to improve and develop park space. The illuminated research is based on the analogy method, by means of which the analog elements of geoplastics are transferred to the results obtained during the field survey of the park territory on difficult terrain. Graphic materials were developed using the ArchiCad 21 software package based on the original cartographic data. A detailed analysis of the problematic aspects of the Pechersky Landscape Park identified the main tasks: adaptability to the needs of society, increasing the comfort of stay, improving the natural landscape, arranging natural zones of park relief. Techniques and methods for improving the territory were applied, such as terracing slopes, creating eco-chairs, using artificial relief in playgrounds. The impact of these changes on the stay of visitors and on the environment as a whole is summarized and predicted. The use of geoplastics in the context of the perception of landscape compositions will contribute to solving problematic relief and exposition aspects of the Pechersk Landscape Park, which will increase its recreational potential.

Neural Correlates of Music Listening: Does the Music Matter?

The last decades have seen a proliferation of music and brain studies, with a major focus on plastic changes as the outcome of continuous and prolonged engagement with music. Thanks to the advent of neuroaesthetics, research on music cognition has broadened its scope by considering the multifarious phenomenon of listening in all its forms, including incidental listening up to the skillful attentive listening of experts, and all its possible effects. These latter range from objective and sensorial effects directly linked to the acoustic features of the music to the subjectively affective and even transformational effects for the listener. Of special importance is the finding that neural activity in the reward circuit of the brain is a key component of a conscious listening experience. We propose that the connection between music and the reward system makes music listening a gate towards not only hedonia but also eudaimonia, namely a life well lived, full of meaning that aims at realizing one’s own “daimon” or true nature. It is argued, further, that music listening, even when conceptualized in this aesthetic and eudaimonic framework, remains a learnable skill that changes the way brain structures respond to sounds and how they interact with each other.

A Critical Period for Learning and Plastic Changes at Hippocampal CA1 Synapses

Postnatal development of hippocampal function has been reported in numerous mammalian species, including humans. To obtain a synaptic evidence, we analyzed developmental changes in plasticity after an inhibitory avoidance task in rats. Learning performance was low in infants (postnatal 2 weeks) but clearly improved from the juvenile period (3–4 weeks) to adulthood (8 weeks). One hour after the training, we prepared brain slices and sequentially recorded miniature excitatory postsynaptic currents (mEPSCs) and inhibitory postsynaptic currents (mIPSCs) from the same hippocampal CA1 neuron. Although the training failed to affect the amplitude of either mEPSCs or mIPSCs at 2 weeks, it increased mEPSC, but not mIPSC, amplitude at 3 weeks. At 4 weeks, the training had increased the amplitude of both mEPSCs and mIPSCs, whereas mIPSC, but not mEPSC, amplitude was increased at 8 weeks. Because early-life physiological functions can affect performance, we also evaluated sensory–motor functions together with emotional state and found adequate sensory/motor functions from infancy to adulthood. Moreover, by analyzing performance of rats in multiple hippocampal-dependent tasks, we found that the developmental changes in the performance are task dependent. Taken together, these findings delineate a critical period for learning and plastic changes at hippocampal CA1 synapses.

Shift-inducible [transgenerational] increase in recombination rate as an evolving strategy in a periodic environment: a numerical model

Numerous empirical studies have witnessed a plastic increase in meiotic recombination rate in organisms experiencing physiological stress due to unfavourable environmental conditions. Yet, it is not clear enough which characteristics of an ecological factor (intensity, duration, variability, etc.) make it stressogenic and therefore recombinogenic for an organism. Several previous theoretical models proceeded from the assumption that organisms increase their recombination rate when the environment becomes more severe, and demonstrated the evolutionary advantage of such recombination strategy. Here we explore another stress-associated recombination strategy, implying a reversible increase in recombination rate each time when the environment alternates. We allow such plastic changes in the organisms, grown in an environment different from that of their parents, and, optionally, also in their offspring. We show that such shift-inducible recombination is always favoured over intermediate constant optimal recombination. Besides, it sometimes outcompetes also zero and free optimal constant recombination, therefore making selection on recombination less polarized. Shift-inducible strategies with a longer, transgenerational plastic effect, are favoured under slightly stronger selection and longer period. These results hold for both panmixia and partial selfing, although selfing makes the dynamics of recombination modifier alleles faster. Our results suggest that epigenetic factors, presumably underlying the environmental plasticity of recombination, may play an important evolutionary role.

Spared perilesional V1 activity underlies training-induced recovery of luminance detection sensitivity in cortically-blind patients

Damage to the primary visual cortex (V1) causes homonymous visual-field loss long considered intractable. Multiple studies now show that perceptual training can restore visual functions in chronic cortically-induced blindness (CB). A popular hypothesis is that training can harness residual visual functions by recruiting intact extrageniculostriate pathways. Training may also induce plastic changes within spared regions of the damaged V1. Here, we link changes in luminance detection sensitivity with retinotopic fMRI activity before and after visual discrimination training in eleven patients with chronic, stroke-induced CB. We show that spared V1 activity representing perimetrically-blind locations prior to training predicts the amount of training-induced recovery of luminance detection sensitivity. Additionally, training results in an enlargement of population receptive fields in perilesional V1, which increases blind-field coverage and may support further recovery with subsequent training. These findings uncover fundamental changes in perilesional V1 cortex underlying training-induced restoration of conscious luminance detection sensitivity in CB.

Combining transcranial brain stimulation and PET/SPECT molecular imaging

Transcranial brain stimulation (TMS) was introduced in 1985 by Barker and his colleagues. Since then, further improvements in technology have allowed additional applications and new stimulation protocols. In the last decade, while the use of TMS has expanded enormously in basic science as well as in the clinical scenario, the underlying neurophysiological or neurochemical mechanisms are still not fully understood. Positron emission tomography (PET) and single-photon emission computerized tomography (SPECT) are neuroimaging modalities utilized to investigate brain functions. In spite of their lower spatial and time resolution compared with functional magnetic resonance imaging (fMRI) and electroencephalography (EEG), PET/SPECT have helped to elucidate some of the neurochemical mechanisms and neural plastic changes associated with TMS. In this chapter, we will provide an overview of these techniques, describing methodological details and application of TMS-PET/SPECT imaging in basic and clinical studies.

Impaired selection of a previously ignored singleton: Evidence for salience map plastic changes

Spatial suppression of a salient colour distractor is achievable via statistical learning. Distractor suppression attenuates unwanted capture, but at the same time target selection at the most likely distractor location is impaired. This result corroborates the idea that the distractor salience is attenuated via inhibitory signals applied to the corresponding location in the priority map. What is less clear, however, is whether lingering impairment in target selection when the distractor is removed are due to the proactive strategic maintenance of the suppressive signal at the previous most likely distractor location or result from the fact that suppression has induced plastic changes in the priority map, probably changing input weights. Here, we provide evidence that supports the latter possibility, as we found that impairment in target selection persisted even when the singleton distractor in the training phase became the target of search in a subsequent test phase. This manipulation rules out the possibility that the observed impairments at the previous most likely distractor location were caused by a signal suppression maintained at this location. Rather, the results reveal that the inhibitory signals cause long-lasting changes in the priority map, which affect future computation of the target salience at the same location, and therefore the efficiency of attentional selection.