The landscape complexity relevance to farming effect assessment on small mammal occupancy in Argentinian farmlands.

The responses of organisms to organic farming depend on the taxonomic group and landscape complexity. Following the intermediate landscape complexity hypothesis, organic farming can compensate for the lack of complexity in simple landscapes. Argentinian farmlands are simple with large fields and scarce linear habitat array, and conventional agriculture is almost the only agriculture practice. We hypothesize that there is an interaction effect of landscape complexity and farming practices on occupancy and species richness of small mammals in farmland of central Argentina. We selected circular landscapes under organic farming and low- and high-intensity conventional farming and quantified heterogeneity in each landscape considering different cover types (crops, resting plots, fallow land, border habitats, grasslands and man-made structures). We used multi-species occupancy models accounting for multiple seasons with a Bayesian approach to make the estimates. Landscapes under organic farms had the highest level of landscape heterogeneity. In simple Argentinian farmlands, organic farming benefited species richness and occupancy of all small mammal species. Some management strategies used in organic farming (wide and vegetated border habitats, diversity in types of production, winter cover crops, natural or semi-natural patches) should be taken into account to increase landscape complexity in conventional farming.

[Hepatic fibrosis: role of matrix metalloproteases and TGFbeta]. / Fibrosis hepática. El papel de las metaloproteinasas y de TGF-beta.

Liver fibrosis and cirrhosis involve multiple cellular and molecular events that lead to deposition of an excess of extracellular matrix proteins and increase the distortion of normal liver architecture. Etiologies include chronic viral hepatitis, alcohol abuse and drug toxicity. Degradation of these matrix proteins occurs predominantly as a result of a family of enzymes called metalloproteases (MMPs) that specifically degrade collagenous and non-collagenous substrates. Matrix degradation in the liver is due to the action of at least four of these enzymes: MMP-1, MMP-2, MMP-3 and MMP-9. In the fibrinolytic system, MMPs can be activated through proteolytic cleavage by the action of urokinase plasminogen activator; a second mechanism includes the same metalloproteases. This activity is regulated at many levels in the fibrinolytic system. The main regulator is the PAI-1. This molecule blocks the conversion of plasminogen into plasmin, and the MMP cannot be activated. At a second level, the inhibition is possible by binding to inhibitors called TIMP that can inhibit the proteolitic activity even when the MMPs had been previously activated by plasmin. During abnormal conditions, overexpression of these inhibitors is directed by the transforming growth factor-beta that in a fibrotic disease acts as an extremely important adverse factor.

Fibrosis Hepática: El papel de las metaloproteinasas y de TGF-β / Hepatic fibrosis: Role of matrix Metallopoteases and TGF-β

La fibrosis hepática involucra múltiples eventos celulares y moleculares que inducen un excesivo depósito de proteínas de matriz extracelular que distorsionan la arquitectura del parénquima hepático, cuya etapa final es conocida como cirrosis. El daño proviene de una variedad de causas como abuso de drogas y enfermedades virales, autoinmunes, metabólicas y colestásicas. La degradación de estas proteínas de matriz ocurre predominantemente como una consecuencia de la acción de metalopro teinasas (MMPs) que degradan sustratos colágenos y no colágenos. La degradación de la matriz en el hígado se lleva a cabo principalmente por la acción de cuatro de estas enzimas: MMP-1, MMP-2, MMP-3 y MMP-9. En el sistema fibrinolítico, las MMPs pueden ser activadas a través de un corte proteolítico por acción del activador de plasminógeno tipo urocinasa y un segundo mecanismo de activación es realizado por las mismas MMPs. La regulación para restringir la actividad puede ser a diferentes niveles; en el sistema fibrinolítico el principal regulador es el PAI- 1, molécula que bloquea la conversión de plasminógeno a plasmina y la MMP no puede ser activada. Un segundo nivel de inhibición es posible a través del TIMP, que inhibe la actividad proteolítica aun cuando las MMPs hayan sido activadas vía plasmina. Durante condiciones patológicas la sobreexpresión de estos inhibidores es dirigida por el factor de crecimiento transformante β, el cual en un padecimiento fibrótico actúa como el más importante factor adverso.

Liver fibrosis and cirrhosis involve multiple cellular and molecular events that lead to deposition of an excess of extracellular matrix proteins and increase the distortion of normal liver architecture. Etiologies include chronic viral hepatitis, alcohol abuse and drug toxicity. Degradation of these matrix proteins occurs predominantly as a result of a family of enzymes called metalloproteinases (MMPs) that specifically degrade collagenous and non collagenous substrates. Matrix degradation in the liver is due to the action of at least four of these enzymes: MMP-1, MMP-2, MMP 3 and MMP 9. In the fibrinolytic system, MMPs can be activated through proteolytic cleavage by the action of urokinase plasminogen activator; a second mechanism includes the same metalloproteinases. This activity is regulated at many levels in the fibrinolytic system. The main regulator is the PAI- 1. This molecule blocks the conversion of plasminogen into plasmin, and the MMP cannot be activated. At a second level, the inhibition is possible by binding to inhibitors called TIMP that can inhibit the proteolytic activity even when the MMPs had been previously activated by plasmin. During abnormal conditions, overexpression of these inhibitors is directed by the transforming growth factor-β that in a fibrotic disease acts as an extremely important adverse factor.