Biological implications of the phenotypic plasticity in the Schistosoma mansoni - Nectomys squamipes model

The water-rat Nectomys squamipes is mostly important non-human host in schistosomiasis mansoni transmission in Brazil, due to its susceptibility, high abundance and water-contact pattern. During experimental infection of N. squamipes with Schistosoma mansoni, adult worms show phenotypic plasticity. This finding led us to investigate whether biological behavior is also affected. This was assessed comparing the biological characteristics of four S. mansoni strains: BE (State of Belém do Pará), CE (State of Pernambuco), CMO (State of Rio Grande do Norte) and SJ (State of São Paulo) using laboratory-bred N. squamipes. The infection was monitored by determination of the pre-patent period, fecal egg output, egg viability, intestinal egg count and, infectivity rate. No biological modification was observed in these parameters. Overall results highlight that N. squamipes was susceptible to several S. mansoni strains, suggesting that it might contribute to the maintenance of schistosomiasis mansoni in Brazil.

Epigenetics and behavioural plasticity: drosophila euchromatin histone metiltransferase and foraging

A thesis submitted in fulfillment of the requirements for the degree of Masters in Molecular Genetics and Biomedicine

Nutritional plasticity and evolutionary divergence in the Drosophila ovary

The environment can modify developmental trajectories and generate a range of distinct phenotypes without altering an organism’s genome, a widespread phenomenon called developmental plasticity. The past decades have seen a resurgent interest in understanding how developmental plasticity contributes to evolutionary processes, as it can produce phenotypic variation among individuals and facilitate diversification among populations that inhabit distinct ecological niches. To better understand the importance of plastic responses for evolutionary change, we need to explore how the environment alters development to produce phenotypic variation and then compare this to how genetic variation influences these same developmental processes.(...)

Density-dependent morphological plasticity and trade-offs among vegetative traits in Eichhornia crassipes (Pontederiaceae)

Density-dependent responses are an important component of the organism life-history, and the resource allocation theory is a central concept to the life-history theory. When resource allocation varies due to environmental changes, a plant may change its morphology or physiology to cope with the new conditions, a process known as phenotypic plasticity. Our study aimed to evaluate how plant density affects Eichhornia crassipes allocation patterns. A total of 214 individuals in high and low density were collected. The density effect was observed in all plant traits examined including biomass accumulation. All traits of E. crassipes demonstrated higher values in high density conditions, except for biomass of leaves. Density exhibited a high influence on vegetative traits of E. crassipes, but did not influence allocation pattern, since a trade-off among the vegetative traits was not found. The morphological plasticity and the absence of trade-offs were discussed as strategies to overcome neighbor plants in competition situations. In high density conditions, there were clear changes in the morphology of the plants which probably allows for their survival in a highly competitive environment.

Procesos de plasticidad sináptica en gyrus dentado hipocampal durante la administración crónica y el síndrome de abstinencia a cocaína. Synaptic plasticity in hippocampal dentate gyrus during chronic administration and withdrawal from cocaine.

Los procesos neuronales adaptativos que se observan como consecuencia de la administración crónica de drogas de abuso, son similares a los procesos plásticos que subyacen al aprendizaje y la memoria. Por otra parte, el hipocampo forma parte del circuito neuronal responsable de los cambios conductuales observados como consecuencia de la administración crónica de diferentes drogas de abuso. De acuerdo con esto, resultados previos de nuestro laboratorio demostraron que la plasticidad sináptica en el hipocampo y las claves contextuales relacionadas con la administración de la droga, son relevantes para el incremento de la plasticidad hipocampal por la administración crónica de diazepam. Específicamente en el gyrus dentado hipocampal se han descripto fenómenos plásticos relacionados con la exposición crónica a psicofármacos, tales como facilitación en la transmisión sináptica, disminución de la proliferación celular y el aumento del factor de transcripción ?Fos B. Debido a la correlación existente entre los mecanismos de plasticidad neuronal, los aprendizaje asociativos y formación de memorias y aquellos responsables de la adicción, el objetivo general de este trabajo es caracterizar los cambios inducidos por la exposición repetida de cocaína y durante el periodo de abstinencia, en la excitabilidad neuronal de las células del gyrus dentado hipocampal, los canales iónicos afectados y los posibles mecanismos bioquímicos involucrados en dichos cambios, que podrían explicar las alteraciones conductuales observadas después de dicho tratamiento. Con este propósito, se estudiará: 1) la plasticidad sináptica (potenciación a largo plazo, LTP y depotenciación a largo plazo, LTD) en el gyrus dentado, mediante registros electrofisiológios multiunitarios; 2)la excitabilidad de las células granulares del gyrus dentado y la actividad de los canales iónicos, utilizando la técnica de patch clamp; 3) las alteraciones en la neurotransmisión glutamatergica, midiendo los niveles del neurotransmisor in vivo, utilizando la técnica de microdiálisis; el tráfico de receptores glutamatérgicos, utilizando la técnica de western-blott, 4) la participación del óxido nítrico en los cambios adaptativos observados como consecuencia de la sensibilización a cocaína. Además, mediante la utilización de técnicas comportamentales (avoidance inhibitorio), se estudiarán las posibles alteraciones de conductas que se sabe dependen de la integridad funcional del hipocampo.En relación a los resultados del presente proyecto se espera obtener un incremento en la plasticidad sináptica, en la excitabilidad neuronal de las células granulares del gyrus dentado de la formación hipocámpica, en la liberación extracelular de glutamato in vivo, como así también en el tráfico de receptores glutamatérgicos. Además se espera obtener un aumento de las vías de señalización activadas por la acción de glutamato, como la de óxido nítrico/GMPc, como consecuencia de la administración crónica de cocaína. Con este aumento global de la plasticidad sináptica hipocampal, las conductas dependientes de esta estructura debieran estar facilitadas, demostrando así una participación activa del hipocampo en los procesos de sensibilización y posiblemente en la adicción a psicoestimulantes. La caracterización del impacto del desarrollo de sensibilización a cocaína en la excitabilidad neuronal en el hipocampo, sobre los sistemas de neurotransmisión y las vías de señalización involucradas contribuirían a dilucidar los mecanismos que contribuyen al desarrollo de sensibilización a cocaína, los cuales podrían representar potenciales blancos terapéuticos para el tratamiento de la adicción, considerando principalmente aspectos específicos de la actividad eléctrica neuronal y la plasticidad sináptica asociada con las diferentes fases del ciclo de la adicción.

Synaptic plasticity in mature cultured hippocampal-entorhinal cortex slices : activity-dependent regulation of cAMP response-element binding protein

LTP, synaptic plasticity, hippocampus, organotypic cultures, CREB

Functional neuronal plasticity in the dentate gyrus of freely moving rats

Magdeburg, Univ., Fak. für Naturwiss., Diss., 2011

Functional plasticity in the hippocampal slices in vitro

Synaptic plasticity, long-term potentiation, long-term depression, depotentiation, PKM zeta

Early life stress-induced histone acetylations correlate with activation of the synaptic plasticity genes Arc and Egr1 in the mouse brain

Magdeburg, Univ., Fak. für Naturwiss., Diss., 2013

Ultra-high resolution imaging of the functional anatomy and plasticity of the human hippocampal-entorhinal circuitry

Magdeburg, Univ., Fak. für Naturwiss., Diss., 2015

Why are offspring born larger when it is colder? Phenotypic plasticity for offspring size in the cladoceran Simocephalus vetulus (Müller)

It has been predicted on theorerical grounds (Sibly & Calow, 1983; Taylor & Williams, 1984) that optimal offspring size should be highly sensitive to juvenile growth and survival rates. To test such models, genetically-identical individuals of Simicephalus vetulus were reared at different temperatures and monitored for offspring size and juvenile growth rate. As adult size correlates negatively with temperature, an analysis of covariance was performed to separate the effects of temperature and maternal size. The result is that offspring size indeed correlates negatively with juvenile growth rate. Comparisons are made with field observation of several authors on seasonal variation of offspring size and alternative explanations are discussed. It is concluded that present experiments support the prediction of the theoretical models.

Learning-induced plasticity in human audition: Objects, time, and space.

The human auditory system is comprised of specialized but interacting anatomic and functional pathways encoding object, spatial, and temporal information. We review how learning-induced plasticity manifests along these pathways and to what extent there are common mechanisms subserving such plasticity. A first series of experiments establishes a temporal hierarchy along which sounds of objects are discriminated along basic to fine-grained categorical boundaries and learned representations. A widespread network of temporal and (pre)frontal brain regions contributes to object discrimination via recursive processing. Learning-induced plasticity typically manifested as repetition suppression within a common set of brain regions. A second series considered how the temporal sequence of sound sources is represented. We show that lateralized responsiveness during the initial encoding phase of pairs of auditory spatial stimuli is critical for their accurate ordered perception. Finally, we consider how spatial representations are formed and modified through training-induced learning. A population-based model of spatial processing is supported wherein temporal and parietal structures interact in the encoding of relative and absolute spatial information over the initial ∼300ms post-stimulus onset. Collectively, these data provide insights into the functional organization of human audition and open directions for new developments in targeted diagnostic and neurorehabilitation strategies.

Altered ligands reveal limited plasticity in the T cell response to a pathogenic epitope.

Experimental leishmaniasis offers a well characterized model of T helper type 1 cell (Th1)-mediated control of infection by an intracellular organism. Susceptible BALB/c mice aberrantly develop Th2 cells in response to infection and are unable to control parasite dissemination. The early CD4(+) T cell response in these mice is oligoclonal and reflects the expansion of Vbeta4/ Valpha8-bearing T cells in response to a single epitope from the parasite Leishmania homologue of mammalian RACK1 (LACK) antigen. Interleukin 4 (IL-4) generated by these cells is believed to direct the subsequent Th2 response. We used T cells from T cell receptor-transgenic mice expressing such a Vbeta4/Valpha8 receptor to characterize altered peptide ligands with similar affinity for I-Ad. Such altered ligands failed to activate IL-4 production from transgenic LACK-specific T cells or following injection into BALB/c mice. Pretreatment of susceptible mice with altered peptide ligands substantially altered the course of subsequent infection. The ability to confer a healer phenotype on otherwise susceptible mice using altered peptides that differed by a single amino acid suggests limited diversity in the endogenous T cell repertoire recognizing this antigen.

Increased plasticity of the stiffness of melanoma cells correlates with their acquisition of metastatic properties.

The stiffness of tumor cells varies during cancer progression. In particular, metastatic carcinoma cells analyzed by Atomic Force Microscopy (AFM) appear softer than non-invasive and normal cells. Here we examined by AFM how the stiffness of melanoma cells varies during progression from non-invasive Radial Growth Phase (RGP) to invasive Vertical Growth Phase (VGP) and to metastatic tumors. We show that transformation of melanocytes to RGP and to VGP cells is characterized by decreased cell stiffness. However, further progression to metastatic melanoma is accompanied by increased cell stiffness and the acquisition of higher plasticity by tumor cells, which is manifested by their ability to greatly augment or reduce their stiffness in response to diverse adhesion conditions. We conclude that increased plasticity, rather than decreased stiffness as suggested for other tumor types, is a marker of melanoma malignancy. These findings advise caution about the potential use of AFM for melanoma diagnosis. FROM THE CLINICAL EDITOR: This study investigates the changes to cellular stiffness in metastatic melanoma cells examined via atomic force microscopy. The results demonstrate that increased plasticity is a marker of melanoma malignancy, as opposed to decreased stiffness.

Imaging of experience-dependent structural plasticity in the mouse neocortex in vivo

The functionality of adult neocortical circuits can be altered by novel experiences or learning. This functional plasticity appears to rely on changes in the strength of neuronal connections that were established during development. Here we will describe some of our studies in which we have addressed whether structural changes, including the remodeling of axons and dendrites with synapse formation and elimination, could underlie experience-dependent plasticity in the adult neocortex. Using 2-photon laser-scanning microscopes and transgenic mice expressing GFP in a subset of pyramidal cells, we have observed that a small subset of dendritic spines continuously appear and disappear on a daily basis, whereas the majority of spines persists for months. Axonal boutons from different neuronal classes displayed similar behavior, although the extent of remodeling varied. Under baseline conditions, new spines in the barrel cortex were mostly transient and rarely survived for more than a week. However, when every other whisker was trimmed, the generation and loss of persistent spines was enhanced. Ultrastructural reconstruction of previously imaged spines and boutons showed that new spines slowly form synapses. New spines persisting for a few days always had synapses, whereas very young spines often lacked synapses. New synapses were predominantly found on large, multi-synapse boutons, suggesting that spine growth is followed by synapse formation, preferentially on existing boutons. Altogether our data indicate that novel sensory experience drives the stabilization of new spines on subclasses of cortical neurons and promotes the formation of new synapses. These synaptic changes likely underlie experience-dependent functional remodeling of specific neocortical circuits.