Properties of rat tracheal epithelial cells separated based on expression of cell surface alpha-galactosyl end groups.

We used Griffonia (bandeiraea) simplicifolia I (GS I) lectin and flow cytometry to isolate subsets of rat tracheal epithelial cells based on the presence or absence of cell surface alpha-galactosyl end groups. These fractions were designated GS I-positive and -negative, respectively. Ninety-eight percent of the cells in the GS I-positive fraction expressed cell surface alpha-galactosyl end groups; 95% had immunocytochemically detectable keratin 14-related protein (a basal cell marker) and 98% lacked alcian blue-periodic acid-Schiff (AB-PAS)-stained cytoplasmic granules. More than 90% of the GS I-positive cells had a high nuclear-to-cytoplasm ratio, had tonofilaments, and lacked organelles characteristic of other differentiated cell types; they were thus classified as basal cells. In bioassays, the GS I-positive fraction had a colony-forming efficiency greater than or equal to that of native tracheal cell suspensions, and the cells were able to repopulate denuded tracheal grafts with ciliated, secretory, and basal cells. More than 99% of the cells in the GS I-negative fraction lacked cell surface alpha-galactosyl end groups, 98% did not stain for keratin 14-related protein, 54% had significant numbers of AB-PAS-stained cytoplasmic granules, and 16% were identified as ciliated cells. The GS I-negative fraction had a lower colony-forming efficiency than the GS I-positive fraction but, it too, was able to repopulate denuded tracheal grafts with a complete mucociliary epithelium. These results show that both GS I-positive and -negative cells had the potential to proliferate and differentiate into the major tracheal cell types

Phenotypic marker expression during fetal and neonatal differentiation of rat tracheal epithelial cells.

The expression of phenotypic markers was examined during fetal and neonatal differentiation of rat tracheal epithelial (RTE) cells. The rat counterpart of human keratin 18 was predominantly found in columnar cells in the adult trachea. It was detected in the primordial tracheal epithelium first seen on gestational day (GD) 12 (term = 21.5 days). Staining intensity gradually increased, and by GD 17 it was principally localized to the apical portion of the epithelium. The rat counterpart of human keratin 19 was barely detectable in the trachea on GD 13 but became abundant in almost all RTE cells on and after GD 19. Morphologically and immunocytochemically identifiable secretory and ciliated cells appeared on GD 18. Ciliated cell number slowly rose while secretory cells increased dramatically on GD 19 through postnatal day 1. The secretory granule antigens detected by monoclonal antibodies RTE 9 and 11 were rare in the adult trachea but were highly expressed in virtually all of the perinatal secretory cells. In contrast, the epitope detected by monoclonal antibody RTE 12, which was present in all adult tracheal surface secretory cells, did not appear until postnatal day 1 and slowly increased. These results demonstrate marked shifts in the biochemical composition of secretory cells during development and postnatal maturation. For the above-mentioned molecules, a similar expression pattern was observed during epithelial regeneration in tracheal grafts (Am. J. Respir. Cell Mol. Biol. 1992; 7:30-41). Pseudo-stratification of the epithelium and basal cells was first observed on GD 20. Keratin 14, which is confined to basal cells in the normal adult trachea, was not present in the nascent basal cells but appeared after postnatal day 1. In contrast to the present results, during epithelial regeneration in tracheal grafts keratin 14 appeared before markers of highly differentiated secretory or ciliated cells. Thus, the biochemical sequence of cellular differentiation during regeneration did not precisely recapitulate development

Estrutura e composição florística de um Cerrado sensu stricto e sua importância para propostas de restauração ecológica

Bordas são áreas de transição entre dois ecossistemas e podem ter origem natural ou antrópica. A influência de borda inclui tanto os efeitos diretos, relacionados às alterações microambientais, como os efeitos indiretos que afetam as interações entre espécies. Adicionalmente, estudos sugerem que a orientação cardinal pode modificar os efeitos microambientais da borda. O objetivo deste estudo foi avaliar a influência de borda sobre os fatores microambientais, as condições edáficas locais, a densidade e a riqueza de espécies em um Cerrado sensu stricto em Itirapina, SP, Brasil. Especificamente, nós investigamos se as características microambientais (umidade relativa do ar (%), radiação fotossinteticamente ativa (PAR), temperatura e porcentagem de abertura de dossel), as condições edáficas e a composição da vegetação diferem entre parcelas (36 parcelas de 25 × 2 m distanciadas 50 m entre si) distribuídas na borda e no interior, orientadas a leste e a sul do Cerrado estudado. Todos os indivíduos lenhosos com circunferência a 30 cm da base do caule ≥ 3 cm foram amostrados e marcados. As variáveis microambientais e as amostras de solo para análises químicas e granulométricas (0-20 cm de profundidade) foram coletadas em três pontos de cada parcela. Foi registrado um total de 120 espécies distribuídas em 40 famílias. Dentre os parâmetros estruturais da vegetação, somente a densidade absoluta foi significativamente maior no interior sul do fragmento. As variáveis microambientais diferiram significativamente entre as faces leste e sul, mas não entre borda e interior. Os parâmetros microambientais e estruturais não caracterizaram uma influência da borda. Entretanto, a orientação cardinal leste e sul e fatores microambientais associados, e a presença de determinados nutrientes no solo como o Mn, influenciaram a estrutura da vegetação de Cerrado e a sua composição em espécies. Nossos resultados ressaltam a importância de considerar a orientação cardinal, além da composição de nutrientes no solo, e dos fatores microambientais, para compreender as variações da vegetação em escala local.Edges are transition areas between two adjacent ecosystems that can be originated by natural or anthropogenic events. The edge influence includes both direct effects, related to changes on microenvironmental factors, as well as indirect effects, related to changes in species interactions. Additionally, some studies suggest that microenvironmental factors are altered by the cardinal orientation of the edge. The present study aimed to evaluate the influence of edge on microenvironmental factors, local soil conditions, woody vegetation structure, and species richness in a Cerrado sensu stricto at Itirapina, São Paulo State, Brazil. Specifically, we investigated whether microenvironmental factors (relative humidity (%), photosynthetic active radiation (PAR), temperature and percentage of canopy cover), soil conditions and vegetation composition differ among plots (36 plots of 25 × 2 m spaced 50 m apart) distributed on the edge and in the interior, facing east and south sides of the Cerrado. We sampled all woody trees and treelets with circumference ≥ 3 cm at 30 cm from its ground base within each plot. The microenvironmental variables relative humidity, PAR (photosynthetic active radiation), temperature and percent of canopy openness, and the soil samples (0-20 cm deep) for nutrients and texture analyses, were all collected at three points within each plot. We recorded a total of 120 woody species distributed among 40 plant families. Among the structural parameters of vegetation, only the absolute density was significantly higher in the interior south of the Cerrado. The microenvironmental factors were significantly different between the east and south sides, but did not differ between edge and interior. Therefore, based on the environmental and structural parameters we evaluated, there was no evidence of edge influence in the Cerrado studied. However, the east and south faces and associated microenvironmental factors, and the presence of some nutrients in the soil, such as Mn, affected the Cerrado vegetation structure and species composition. Our results highlight the importance of taking into account the cardinal orientation in addition to the soil nutrient and microenvironment parameters to better understand the factors influencing the vegetation at a local scale.Universidade Estadual Paulista Júlio de Mesquita Filho Departamento de Botânica Laboratório de FenologiaInstituto de BotânicaUniversidade Estadual Paulista Júlio de Mesquita Filho Departamento de BotânicaUniversidade Estadual Paulista Júlio de Mesquita Filho Departamento de Botânica Laboratório de FenologiaUniversidade Estadual Paulista Júlio de Mesquita Filho Departamento de Botânic

Dispersions and mixtures of particles with complex architectures in shear flow

We review the effect of shear flow on the phase behavior and structure of colloidal dispersions with increasing degree of complexity. We discuss dispersions of colloidal rods, stiff living polymers like wormlike micelles, and colloidal platelets. In addition, a review is presented on sheared binary dispersions. For all cases we discuss the interplay between thermodynamic instabilities and hydrodynamic instabilities