IDENTIFICAÇÃO POLIFÁSICA DE GONGRONELLA SP. E DE RHIZOPUS SP. DEGRADADORES DO FUNGICIDA SISTÉMICO METALAXIL

A capacidade destes fungos degradarem compostos xenobióticos e recalcitrantes é uma característica biotecnologicamente importante tornando-os potencialmente úteis para processos de biorremediação. Gongronella sp. e Rhizopus sp. foram isolados do solo de vinhas da região do Alentejo, Portugal. Estes isolados mostraram elevada capacidade de degradarem o fungicida acilalanina metalaxil. No presente estudo, para a identificação polifásica de Gongronella sp. e Rhizopus sp., presuntivamente identificado como R. stolonifer, várias linhagens de referência da ordem Mucorales (Absidia, Circinella, Gongronella e Rhizopus) foram incluídas. A abordagem polifásica combinou a análise das macro- e micromorfologias, a análise da sequência inteira da região ITS ribossomal (i.e., ITS1/5.8S rDNA/ITS2) e ainda o uso da espectrometria de massas por Matrix Assisted Laser Desorption Ionization Time-of-Flight (MALDI-TOF).

A SHORTENED RNA-FISH PROTOCOL FOR ANALYZING ARTWORKS’ MICROCOLONIZERS

Microorganisms are involved in the deterioration of Cultural Heritage. Thus, there is a need to enhance the techniques used for their detection and identification. RNA Fluorescent In Situ Hybridization (RNA-FISH) has been successfully applied for phylogenetic identification of the viable components of the microbial communities colonizing artworks both in situ and ex situ. Until recently, it was time-consuming, taking not less than 6 h for the analysis. We have developed an RNA-FISH in suspension protocol that allowed ex situ analysis of microorganisms involved in artworks’ biodeterioration in 5 h. In this work, three modified protocols, involving microwave heating, were evaluated for further shortening two of the four main critical steps in RNA-FISH: hybridization and washing. The original and modified protocols were applied in cellular suspensions of bacteria and yeast isolates. The results obtained were evaluated and compared in terms of detectability and specificity of the signals detected by epifluorescence microscopy. One of the methods tested showed good and specific FISH signals for all the microorganisms selected and did not produce signals evidencing non-specific or fixation-induced fluorescence. This 3 h protocol allows a remarkable reduction of the time usually required for performing RNA-FISH analysis in Cultural Heritage samples. Thus, a rapid alternative for analyzing yeast and bacteria cells colonizing artworks’ surfaces by RNA-FISH is presented in this work.