Establishment of a Single Temperature Incubation Approach for Environmental Monitoring Samples with Focus on Mold Recoveries.

A robust environmental monitoring program is essential to properly estimate and identify microorganisms in cleanrooms, ensuring that microbial contamination remains acceptably low, and a good state of control is maintained in the manufacturing areas. The incubation conditions are important to support optimal microbial recoveries, considering that there is no single culture medium, temperature and incubation time that can recover all microorganisms. Particularly molds are quite sensitive microorganisms, and some species may have very specific nutritional and environmental needs. In this study, a two-phase approach was used to identify a single incubation-temperature approach that could recover most of the cleanroom microbial flora with focus on molds. Phase 1 included a growth promotion study performed in the laboratory using pharmacopeial and in-house strains, comparing different media (SDA and TSA) at single or dual incubation-temperature approaches for 5 or 6 days. Phase 2 was based on an in situ study where sampling was performed in different areas of a pharmaceutical facility, comparing the recoveries at different incubation conditions. In addition, extension studies of phase 1 and phase 2 were performed to get a better understanding of growth requirements for in-house molds. The results show that an incubation on Tryptone Soy Agar (TSA) at 25-30° for 3-4 days was able to recover most tested microorganisms in phase 1 and a large variety of microorganisms in phase 2, indicating that the single incubation-temperature is an optimal approach for the recovery of microorganisms in cleanrooms. Exceptions were noted for one strain of the species Cutibacterium acnes, a microaerophilic bacterium for which anaerobiosis and higher temperatures were needed, and two mold strains (Sistotrema brinkmannii and Stereum hirsutum), indicating that those molds required a specific media (Sabouraud Dextrose Agar, SDA) for their proliferation. The results showed that TSA incubated at single or dual incubation-temperature approach cannot compensate for the absence of SDA for some environmental molds that may be atypical in cleanrooms. Therefore, in addition to TSA, certain monitoring with SDA at e.g., cleanroom entrance points may be beneficial to recover molds with very specific nutritional requirements.

Transcriptome Analysis Reveals Contrasting Plant Responses of Sorghum bicolor upon Colonization by Two Formae Speciales of Sporisorium reilianum.

The biotrophic fungus Sporisorium reilianum exists in two host-adapted formae speciales that cause head smut in maize (S. reilianum f. sp. zeae; SRZ) and sorghum (S. reilianum f. sp. reilianum; SRS). In sorghum, the spread of SRZ is limited to the leaves. To understand the plant responses to each forma specialis, we determined the transcriptome of sorghum leaves inoculated either with SRS or SRZ. Fungal inoculation led to gene expression rather than suppression in sorghum. SRZ induced a much greater number of genes than SRS. Each forma specialis induced a distinct set of plant genes. The SRZ-induced genes were involved in plant defense mainly at the plasma membrane and were associated with the Molecular Function Gene Ontology terms chitin binding, abscisic acid binding, protein phosphatase inhibitor activity, terpene synthase activity, chitinase activity, transmembrane transporter activity and signaling receptor activity. Specifically, we found an upregulation of the genes involved in phospholipid degradation and sphingolipid biosynthesis, suggesting that the lipid content of the plant plasma membrane may contribute to preventing the systemic spread of SRZ. In contrast, the colonization of sorghum with SRS increased the expression of the genes involved in the detoxification of cellular oxidants and in the unfolded protein response at the endoplasmic reticulum, as well as of the genes modifying the cuticle wax and lipid composition through the generation of alkanes and phytosterols. These results identified plant compartments that may have a function in resistance against SRZ (plasma membrane) and susceptibility towards SRS (endoplasmic reticulum) that need more attention in the future.

Host specificity in Sporisorium reilianum is determined by distinct mechanisms in maize and sorghum.

Smut fungi are biotrophic plant pathogens that exhibit a very narrow host range. The smut fungus Sporisorium reilianum exists in two host-adapted formae speciales: S. reilianum f. sp. reilianum (SRS), which causes head smut of sorghum, and S. reilianum f. sp. zeae (SRZ), which induces disease on maize. It is unknown why the two formae speciales cannot form spores on their respective non-favoured hosts. By fungal DNA quantification and fluorescence microscopy of stained plant samples, we followed the colonization behaviour of both SRS and SRZ on sorghum and maize. Both formae speciales were able to penetrate and multiply in the leaves of both hosts. In sorghum, the hyphae of SRS reached the apical meristems, whereas the hyphae of SRZ did not. SRZ strongly induced several defence responses in sorghum, such as the generation of H2 O2 , callose and phytoalexins, whereas the hyphae of SRS did not. In maize, both SRS and SRZ were able to spread through the plant to the apical meristem. Transcriptome analysis of colonized maize leaves revealed more genes induced by SRZ than by SRS, with many of them being involved in defence responses. Amongst the maize genes specifically induced by SRS were 11 pentatricopeptide repeat proteins. Together with the microscopic analysis, these data indicate that SRZ succumbs to plant defence after sorghum penetration, whereas SRS proliferates in a relatively undisturbed manner, but non-efficiently, on maize. This shows that host specificity is determined by distinct mechanisms in sorghum and maize.

Red card for pathogens: phytoalexins in sorghum and maize.

Cereal crop plants such as maize and sorghum are constantly being attacked by a great variety of pathogens that cause large economic losses. Plants protect themselves against pathogens by synthesizing antimicrobial compounds, which include phytoalexins. In this review we summarize the current knowledge on phytoalexins produced by sorghum (luteolinidin, apigeninidin) and maize (zealexin, kauralexin, DIMBOA and HDMBOA). For these molecules, we highlight biosynthetic pathways, known intermediates, proposed enzymes, and mechanisms of elicitation. Finally, we discuss the involvement of phytoalexins in plant resistance and their possible application in technology, medicine and agriculture. For those whose world is round we tried to set the scene in the context of a hypothetical football game in which pathogens fight with phytoalexins on the different playing fields provided by maize and sorghum.

O G-CSF na terapia do acidente vascular cerebral / The potential role of G-CSF in stroke

O fator estimulador de colônias granulocitárias (G-CSF) é uma glicoproteína descrita há mais de vinte anos, e é largamente utilizada para tratamento de estados neutropênicos e no transplante de medula óssea. O G-CSF estimula células-tronco hematopoéticas e regula crucialmente a sobrevivência de neutrófilos maduros, pós-mitóticos, através da inibição da apoptose. Além do efeito sistêmico, mais recentemente tem-se demonstrado uma surpreendente atividade do G-CSF no sistema nervoso central. A administração de G-CSF mobiliza células-tronco e progenitoras da medula óssea para o sangue periférico, que, por sua vez, atravessa a barreira hemato-encefálica (BHE) e se dirige à área acometida do cérebro. A atividade do G-CSF no sistema nervoso central tem sido caracterizada como multimodal, pois, além do efeito mobilizador de células da medula óssea, demonstrou uma ação direta neuroprotetora através de diferentes mecanismos, tais como a atividade antiapoptótica em neurônios, regeneração da vascularização, efeito anti-inflamatório e estimulação da neurogênese endógena. Este relato sumariza a ação do G-CSF no sistema nervoso central e aborda seu potencial para o emprego no acidente vascular cerebral.

The granulocyte colony-stimulating-factor (G-CSF) is a glycoproteina which has been described for decades, and it is commonly utilized in the treatment of neutropenic states and bone marrow transplants. G-CSF stimulates hematopoietic stem-cels e crucially regulates the survival of mature neutrophils through a mechanism of apoptosis inhibition. Beyond its systemic effect, recently it has been shown its surprising activity in the central nervous system (CNS). G-CSF administration mobilizes bone marrow stem cells para systemic blood, and those cells cross the blood-brain-barrier e target brain's damaged area. G-CSF's activity in the CNS has been defined as multimodal, because additionally it has been demonstrated a direct neuroprotective action through different mechanisms such as antiapoptotic activity, angiogenesis, anti-inflamatory effect, and stimulation of endogenous neurogenesis. This paper sumarizes G-CSF action in the CNS and approaches its potential para use in stroke.

Insuficiência cardíaca: do tratamento farmacológico à terapia-celular / Heart failure: from the pharmacological treatment to cellular therapy

Nos últimos quinze anos, o tratamento da insuficiência cardíaca (IC) adquiriu especial relevância não apenas na cardiologia, mas na medicina interna. Um grande número de novos medicamentos, baseados em uma farmacocinética e apoiados por grandes estudos multicêntricos, tem permitido melhorar a sobrevida e a qualidade de vida de inúmeros pacientes espalhados pelo globo. Quando se achou que os fármacos recém-introduzidos no cotidiano tinham controlado sinais e sintomas da IC, surgiram novas alternativas terapêuticas, com destaque para a ressincronização cardíaca. Mais recentemente, outras opções de tratamento vêm surgindo, culminando na terapia celular. Este artigo realiza uma revisão da literatura já que este tema se torna de vital importância no dia-a-dia da cardiologia clínica.