Imunopatogenia da interação entre acrófagos e/ou células de Langerhans e Lacazia loboi

A lobomicose é uma infecção subcutânea crônica, granulomatosa, causada pela implantação traumática do fungo Lacazia loboi nos tecidos cutâneo e subcutâneo. Ocorre predominantemente na região Amazônica e atinge qualquer grupo populacional. Histologicamente, observa-se reação inflamatória crônica caracterizada por intensa histiocitose e fibroplasia, abundante número de macrófagos, células gigantes multinucleadas do tipo corpo estranho e presença de considerável número de células leveduriformes. Os macrófagos são células fagocíticas que participam do reconhecimento e da resposta a patógenos através da fagocitose, da apresentação de antígenos aos linfócitos T e da produção de citocinas. As células de Langerhans (LC) são um grupo de Células dendríticas (CD) derivadas da medula óssea situadas principalmente em uma camada suprabasal da epiderme. Estudos envolvendo a interação fungo-hospedeiro na doença de Jorge Lobo são escassos. Assim, Este estudo é um passo importante para o melhor entendimento da biologia e patogenia do L. loboi, e para o estudo da imunopatologia da interação patógeno versus hospedeiro desta doença emergente e pouco conhecida. O objetivo do presente trabalho foi analisar a interação in vitro entre macrófagos peritoneais não ativados e/ou LC, isolados de camundongos BALB/c, com L. loboi recém-isolado de pacientes com doença de Jorge Lobo, bem como determinar os índices de infecção, fagocitose e fusão, e medir a produção das citocinas TNF-α, IL-4, IL-6, IL-10 e IL-12. Os resultados demonstraram que L. loboi é fagocitado por macrófagos, mas não por LC. O índice de infecção na interação entre macrófagos e L. loboi foi semelhante à interação entre macrófagos, LC e L. loboi em todos os tempos analisados. A média do número de fungos por macrófago também foi praticamente igual entre as interações e ao longo do tempo, variando de 1,2 a 1,6 fungos/macrófagos. Não houve a formação de células gigantes em macrófagos cultivados ou LC cultivadas isoladamente e em nenhum dos co-cultivos. Não houve diferença significante na produção de IL-4, IL-2 e IL-10 nas interações estudadas. Os níveis de TNF-α diminuem ao longo do tempo na interação entre macrófagos e L. loboi, enquanto a adição de LC induz aumento da produção de TNF-α, principalmente após 48 horas. LC modulam negativamente a produção de IL-6 por macrófagos e L. loboi também inibem essa produção por macrófagos isoladamente ou em co-cultivo com LC. L. loboi estimulam significativamente a produção de IL-12 por macrófagos co-cultivados com LC, mas não em LC ou macrófagos isoladamente.

Density, proportion, and dendritic coverage of retinal ganglion cells of the common marmoset (Callithrix jacchus jacchus)

We performed a quantitative analysis of M and P cell mosaics of the common-marmoset retina. Ganglion cells were labeled retrogradely from optic nerve deposits of Biocytin. The labeling was visualized using horseradish peroxidase (HRP) histochemistry and 3-3'diaminobenzidine as chromogen. M and P cells were morphologically similar to those found in Old- and New-World primates. Measurements were performed on well-stained cells from 4 retinas of different animals. We analyzed separate mosaics for inner and outer M and P cells at increasing distances from the fovea (2.5-9 mm of eccentricity) to estimate cell density, proportion, and dendritic coverage. M cell density decreased towards the retinal periphery in all quadrants. M cell density was higher in the nasal quadrant than in other retinal regions at similar eccentricities, reaching about 740 cells/mm2 at 2.5 mm of temporal eccentricity, and representing 8-14% of all ganglion cells. P cell density increased from peripheral to more central regions, reaching about 5540 cells/mm2 at 2.5 mm of temporal eccentricity. P cells represented a smaller proportion of all ganglion cells in the nasal quadrant than in other quadrants, and their numbers increased towards central retinal regions. The M cell coverage factor ranged from 5 to 12 and the P cell coverage factor ranged from 1 to 3 in the nasal quadrant and from 5 to 12 in the other quadrants. These results show that central and peripheral retinal regions differ in terms of cell class proportions and dendritic coverage, and their properties do not result from simply scaling down cell density. Therefore, differences in functional properties between central and peripheral vision should take these distinct regional retinal characteristics into account.

Dendritic thickness: a morphometric parameter to classify mouse retinal ganglion cells

To study the dendritic morphology of retinal ganglion cells in wild-type mice we intracellularly injected these cells with Lucifer yellow in an in vitro preparation of the retina. Subsequently, quantified values of dendritic thickness, number of branching points and level of stratification of 73 Lucifer yellow-filled ganglion cells were analyzed by statistical methods, resulting in a classification into 9 groups. The variables dendritic thickness, number of branching points per cell and level of stratification were independent of each other. Number of branching points and level of stratification were independent of eccentricity, whereas dendritic thickness was positively dependent (r = 0.37) on it. The frequency distribution of dendritic thickness tended to be multimodal, indicating the presence of at least two cell populations composed of neurons with dendritic diameters either smaller or larger than 1.8 µm ("thin" or "thick" dendrites, respectively). Three cells (4.5%) were bistratified, having thick dendrites, and the others (95.5%) were monostratified. Using k-means cluster analysis, monostratified cells with either thin or thick dendrites were further subdivided according to level of stratification and number of branching points: cells with thin dendrites were divided into 2 groups with outer stratification (0-40%) and 2 groups with inner (50-100%) stratification, whereas cells with thick dendrites were divided into one group with outer and 3 groups with inner stratification. We postulate, that one group of cells with thin dendrites resembles cat ß-cells, whereas one group of cells with thick dendrites includes cells that resemble cat a-cells.

Relationships between dendritic morphology, spatial distribution and firing patterns in rat layer 1 neurons

The cortical layer 1 contains mainly small interneurons, which have traditionally been classified according to their axonal morphology. The dendritic morphology of these cells, however, has received little attention and remains ill defined. Very little is known about how the dendritic morphology and spatial distribution of these cells may relate to functional neuronal properties. We used biocytin labeling and whole cell patch clamp recordings, associated with digital reconstruction and quantitative morphological analysis, to assess correlations between dendritic morphology, spatial distribution and membrane properties of rat layer 1 neurons. A total of 106 cells were recorded, labeled and subjected to morphological analysis. Based on the quantitative patterns of their dendritic arbor, cells were divided into four major morphotypes: horizontal, radial, ascendant, and descendant cells. Descendant cells exhibited a highly distinct spatial distribution in relation to other morphotypes, suggesting that they may have a distinct function in these cortical circuits. A significant difference was also found in the distribution of firing patterns between each morphotype and between the neuronal populations of each sublayer. Passive membrane properties were, however, statistically homogeneous among all subgroups. We speculate that the differences observed in active membrane properties might be related to differences in the synaptic input of specific types of afferent fibers and to differences in the computational roles of each morphotype in layer 1 circuits. Our findings provide new insights into dendritic morphology and neuronal spatial distribution in layer 1 circuits, indicating that variations in these properties may be correlated with distinct physiological functions.