Thomas E. Dolan scite author profile

Thomas E. Dolan

5Publications

86Citation Statements Received

74Citation Statements Given

How they've been cited

150

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Affiliations

Butler University, State University of New York, University of California, Riverside

Publications

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Potential versus actual contribution of vertical transmission to pathogen fitness

Kover

Dolan

Clay

1997

Proc. R. Soc. Lond. B

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Theory predicts that virulent parasites cannot be maintained at high prevalence if they are only vertically transmitted. However, parasites with high rates of vertical transmission that cause severe reduction in host fitness have been reported. Atkinsonella h pox lon is a fungal pathogen capable of both vertical and horizontal transmission that drastically reduces its host's fitness. In contrast with theoretical predictions, field and laboratory observations suggested that the primary mechanism of transmission was vertical. Using randomly amplified polymorphic DNA markers, we investigated the effective contribution of vertical and horizontal transmission to the genetic structure of three natural populations of A. h pox lon. We found high genotypic diversity and low linkage disequilibrium, indicating that most established genotypes are derived from horizontally transmitted, sexual spores. The low contribution of vertical transmission to the parasite's fitness despite its high potential might be due to lower establishment of cleistogamous seeds (through which vertical transmission occurs) or lower vigour of vertically transmitted fungal genotypes. Low establishment of vertically infected hosts might explain the persistence of virulent parasites with high apparent vertical transmission. Our results suggest that caution must be taken when using the potential for vertical transmission to make predictions about the evolution of parasite virulence.

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Correlative in Vitro and in Vivo Behavior of Mutant Strains ofPhytophthora palmivoraExpressing Different Resistances to Phosphorous Acid and Fosetyl-Na

Dolan¹,

Coffey²

1988

Phytopathology

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Sodium Chloride Effect on Dark Fixation of CO₂ by Marine & Terrestrial Plants

et al. 1962

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Systemic Acquired Resistance in Moss: Further Evidence for Conserved Defense Mechanisms in Plants

et al. 2014

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Vascular plants possess multiple mechanisms for defending themselves against pathogens. One well-characterized defense mechanism is systemic acquired resistance (SAR). In SAR, a plant detects the presence of a pathogen and transmits a signal throughout the plant, inducing changes in the expression of various pathogenesis-related (PR) genes. Once SAR is established, the plant is capable of mounting rapid responses to subsequent pathogen attacks. SAR has been characterized in numerous angiosperm and gymnosperm species; however, despite several pieces of evidence suggesting SAR may also exist in non-vascular plants6–8, its presence in non-vascular plants has not been conclusively demonstrated, in part due to the lack of an appropriate culture system. Here, we describe and use a novel culture system to demonstrate that the moss species Amblystegium serpens does initiate a SAR-like reaction upon inoculation with Pythium irregulare, a common soil-borne oomycete. Infection of A. serpens gametophores by P. irregulare is characterized by localized cytoplasmic shrinkage within 34 h and chlorosis and necrosis within 7 d of inoculation. Within 24 h of a primary inoculation (induction), moss gametophores grown in culture became highly resistant to infection following subsequent inoculation (challenge) by the same pathogen. This increased resistance was a response to the pathogen itself and not to physical wounding. Treatment with β-1,3 glucan, a structural component of oomycete cell walls, was equally effective at triggering SAR. Our results demonstrate, for the first time, that this important defense mechanism exists in a non-vascular plant, and, together with previous studies, suggest that SAR arose prior to the divergence of vascular and non-vascular plants. In addition, this novel moss – pathogen culture system will be valuable for future characterization of the mechanism of SAR in moss, which is necessary for a better understanding of the evolutionary history of SAR in plants.

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The Ultrastructure of Nuclear Division in Monoblepharella sp.

Dolan

Fuller

1985

Mycologia

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Thomas E. Dolan

Potential versus actual contribution of vertical transmission to pathogen fitness

Correlative in Vitro and in Vivo Behavior of Mutant Strains ofPhytophthora palmivoraExpressing Different Resistances to Phosphorous Acid and Fosetyl-Na

Sodium Chloride Effect on Dark Fixation of CO₂ by Marine & Terrestrial Plants

Systemic Acquired Resistance in Moss: Further Evidence for Conserved Defense Mechanisms in Plants

The Ultrastructure of Nuclear Division in Monoblepharella sp.

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Thomas E. Dolan

Potential versus actual contribution of vertical transmission to pathogen fitness

Correlative in Vitro and in Vivo Behavior of Mutant Strains ofPhytophthora palmivoraExpressing Different Resistances to Phosphorous Acid and Fosetyl-Na

Sodium Chloride Effect on Dark Fixation of CO2 by Marine & Terrestrial Plants

Systemic Acquired Resistance in Moss: Further Evidence for Conserved Defense Mechanisms in Plants

The Ultrastructure of Nuclear Division in Monoblepharella sp.

Contact Info

Product

Resources

About

Sodium Chloride Effect on Dark Fixation of CO₂ by Marine & Terrestrial Plants