Tea Tree Oil Induces Systemic Resistance against Fusarium wilt in Banana and Xanthomonas Infection in Tomato Plants.

The essential tea tree oil (TTO) derived from Melaleuca alternifolia plant is widely used as a biopesticide to protect crops from several plant-pathogens. Its activity raised queries regarding its ability to, not only act as a bio-fungicide or bio-bactericide, but also systemically inducing resistance in plants. This was examined by TTO application to banana plants challenged by Fusarium oxysporum f. sp. cubense (Foc, Race 1) causing Fusarium wilt and to tomato plants challenged by Xanthomonas campestris. Parameters to assess resistance induction included: disease development, enzymatic activity, defense genes expression correlated to systemic acquired resistance (SAR) and induced systemic resistance (ISR) and priming effect. Spraying TTO on field-grown banana plants infected with Foc and greenhouse tomato plants infected with Xanthomonas campestris led to resistance induction in both hosts. Several marker genes of salicylic acid, jasmonic acid and ethylene pathways were significantly up-regulated in parallel with symptoms reduction. For tomato plants, we have also recorded a priming effect following TTO treatment. In addition to fungicidal and bactericidal effect, TTO can be applied in more sustainable strategies to control diseases by enhancing the plants ability to defend themselves against pathogens and ultimately diminish chemical pesticides applications.

Mechanisms and significance of fungicide resistance / Mecanismos e significância da resistência a fungicidas

In this review article, we show that occurrence of fungicide resistance is one of the most important issues in modern agriculture. Fungicide resistance may be due to mutations of genes encoding fungicide targets (qualitative fungicide resistance) or to different mechanisms that are induced by sub-lethal fungicide stress. These mechanisms result in different and varying levels of resistance (quantitative fungicide resistance). We discuss whether or not extensive use of fungicides in agricultural environments is related to the occurrence of fungicide resistance in clinical environments. Furthermore, we provide recommendations of how development of fungicide resistant pathogen populations may be prevented or delayed.

A ocorrência de resistência a fungicidas é uma das mais importantes conseqüências da agricultura moderna. Este fato pode ser resultado de mutações em genes codificadores de resistência a fungicidas (resistência quantitativa) ou a diferentes mecanismos que são induzidos por stresse devido a doses subletais dos produtos utilizados. Estes mecanismos produzem diferentes e variados níveis de resistência (resistência quantitativa). Também é discutido se o uso extensivo de fungicidas em ambientes agricultáveis é relacionado ou não com a ocorrência de resistência em ambientes clínicos. Além disso, também são fornecidas recomendações de como prevenir ou mesmo retardar o desenvolvimento de resistência a fungicidas em patógenos.

Retention sites for Xylella fastidiosa in four sharpshooter vectors (Hemiptera: Cicadellidae) analyzed by scanning electron microscopy.

Xylella fastidiosa is a xylem-limited bacterium that causes citrus variegated chlorosis (CVC), Pierce's disease of grapevine, and leaf scald of coffee and plum and many other plant species. This pathogen is vectored by sharpshooter leafhoppers (Hemiptera: Cicadellidae: Cicadellinae) and resides in the insect foregut. Scanning electron microscopy was used to determine the retention sites of X. fastidiosa for the most common vector species in Brazilian citrus groves, Acrogonia citrina, Bucephalogonia xanthophis, Dilobopterus costalimai, and Oncometopia facialis. After a 48-h acquisition access period on infected citrus or plum, adult sharpshooters were kept on healthy citrus seedlings for an incubation period of 2 weeks to allow for bacterial multiplication. Then the vector heads were incubated for 24 h in a fixative and transferred into a cryoprotector liquid. Bacterial rod cells exhibiting similar X. fastidiosa morphology were found laterally attached to different regions inside the cibarial pump chamber (longitudinal groove, lateral surface, cibarial diaphragm and apodemal groove) of A. citrina, O. facialis, and D. costalimai, and polarly attached to the precibarium channel of O. facialis. Polymerase chain reactions of vector's heads were positive for the presence of X. fastidiosa. No X. fastidiosa-like cells were detected in B. xanthophis. A different type of rod-shaped bacterium was found on B. xanthophis cibarium chamber and images suggest that the cibarium wall was degraded/digested by these bacteria. Colonization patterns of X. fastidiosa in their vectors are fundamental aspects to be explored toward understanding acquisition, adhesion, and transmission mechanisms for development of X. fastidiosa control strategies.

Mechanisms and significance of fungicide resistance.

In this review article, we show that occurrence of fungicide resistance is one of the most important issues in modern agriculture. Fungicide resistance may be due to mutations of genes encoding fungicide targets (qualitative fungicide resistance) or to different mechanisms that are induced by sub-lethal fungicide stress. These mechanisms result in different and varying levels of resistance (quantitative fungicide resistance). We discuss whether or not extensive use of fungicides in agricultural environments is related to the occurrence of fungicide resistance in clinical environments. Furthermore, we provide recommendations of how development of fungicide resistant pathogen populations may be prevented or delayed.

Partial purification of elicitors from Lentinula edodes basidiocarps protecting cucumber seedlings against Colletotrichum lagenarium

O cogumelo shiitake (Lentinula edodes) vem sendo utilizado com objetivos de prevenir e controlar doenças em humanos e em vegetais. O tratamento com o extrato aquoso de basidiocarpos do cogumelo propiciou uma redução significativa na severidade da antracnose em plantas de pepino, provocada por Colletotrichum lagenarium, e um aumento na atividade de peroxidases nos tecidos foliares. Desse modo, com o objetivo de obter moléculas de interesse agronômico destinadas à proteção de plantas, o extrato aquoso bruto de basidiocarpos de L. edodes foi fracionado inicialmente com sulfato de amônio. A fração correspondente a 40-80 por cento de saturação (p40-80) foi a mais efetiva em reduzir a antracnose em cotilédones de pepino, sendo então submetida à cromatografia de troca aniônica (CTA). Após a CTA, seis picos protéicos foram obtidos, e o pico V, contendo em média 34 por cento das proteínas presentes em p40-80, provocou o acúmulo de peroxidases nos cotilédones de pepino, bem como reduziu a antracnose. A separação eletroforética das proteínas do pico V revelou a presença de mais de uma banda no gel de poliacrilamida. Portanto, estes procedimentos resultaram na purificação parcial de elicitores presentes no basidiocarpo de L. edodes.

Transmissão do Passion fruit woodiness Virus por Aphis gossypii ( Glover ) ( Hemiptera: Aphididae ) e colonização de maracujazeiro pelo vetor / Transmission of Passion fruit woodiness virus by Aphis gossypii ( Glover ) ( Hemiptera: Aphididae ) and colonization of Passion flower by the vector

Avaliou-se a transmissão de Passion fruit woodiness virus (PWV) por Aphis gossypii (Glover). Em dois experimentos independentes, o afídeo transmitiu o PWV para maracujazeiros com taxas de 75 por cento e 100 por cento, ao se depositarem oito e doze afídeos virulíferos por planta, respectivamente. No final dos testes, observaram-se, em algumas plantas de maracujá, formas ápteras e ninfas de A. gossypii, sugerindo a colonização dessas plantas pelo afídeo. Esse parece ser o primeiro relato da colonização de Passiflora edulis f. flavicarpa (Deneger) por uma espécie de afídeo.

[Transmission of Passion fruit woodiness virus by Aphis gossypii (Glover) (Hemiptera: Aphididae) and colonization of passion flower by the vector]. / Transmissão do Passion fruit woodiness virus por Aphis gossypii (Glover) (Hemiptera: Aphididae) e colonização de maracujazeiro pelo vetor.

The transmission of Passion fruit woodiness virus (PWV) by Aphis gossypii (Glover) was evaluated. In two independent experiments, A. gossypii transmitted PWV to passion fruit plants at the rates of 75% and 100%, when eight and twelve viruliferous aphids were deposited by plant, respectively. At the end of the tests, nymphs of A. gossypii were observed in some of the passion fruit plants, suggesting that the aphid species was colonizing the plants. This seems to be the first report of Passiflora edulis f. flavicarpa (Deneger) colonization by a species of aphid.