Novel symbiotic protoplasts formed by endophytic fungi explain their hidden existence, lifestyle switching, and diversity within the plant kingdom.

Diverse fungi live all or part of their life cycle inside plants as asymptomatic endophytes. While endophytic fungi are increasingly recognized as significant components of plant fitness, it is unclear how they interact with plant cells; why they occur throughout the fungal kingdom; and why they are associated with most fungal lifestyles. Here we evaluate the diversity of endophytic fungi that are able to form novel protoplasts called mycosomes. We found that mycosomes cultured from plants and phylogenetically diverse endophytic fungi have common morphological characteristics, express similar developmental patterns, and can revert back to the free-living walled state. Observed with electron microscopy, mycosome ontogeny within Aureobasidium pullulans may involve two organelles: double membrane-bounded promycosome organelles (PMOs) that form mycosomes, and multivesicular bodies that may form plastid-infecting vesicles. Cultured mycosomes also contain a double membrane-bounded organelle, which may be homologous to the A. pullulans PMO. The mycosome PMO is often expressed as a vacuole-like organelle, which alternatively may contain a lipoid body or a starch grain. Mycosome reversion to walled cells occurs within the PMO, and by budding from lipid or starch-containing mycosomes. Mycosomes discovered in chicken egg yolk provided a plant-independent source for analysis: they formed typical protoplast stages, contained fungal ITS sequences and reverted to walled cells, suggesting mycosome symbiosis with animals as well as plants. Our results suggest that diverse endophytic fungi express a novel protoplast phase that can explain their hidden existence, lifestyle switching, and diversity within the plant kingdom. Importantly, our findings outline "what, where, when and how", opening the way for cell and organelle-specific tests using in situ DNA hybridization and fluorescent labels. We discuss developmental, ecological and evolutionary contexts that provide a robust framework for continued tests of the mycosome phase hypothesis.

The brighter side of soils: quantum dots track organic nitrogen through fungi and plants.

Soil microorganisms mediate many nutrient transformations that are central in terrestrial cycling of carbon and nitrogen. However, uptake of organic nutrients by microorganisms is difficult to study in natural systems. We assessed quantum dots (fluorescent nanoscale semiconductors) as a new tool to observe uptake and translocation of organic nitrogen by fungi and plants. We conjugated quantum dots to the amino groups of glycine, arginine, and chitosan and incubated them with Penicillium fungi (a saprotroph) and annual bluegrass (Poa annua) inoculated with arbuscular mycorrhizal fungi. As experimental controls, we incubated fungi and bluegrass samples with substrate-free quantum dots as well as unbound quantum dot substrate mixtures. Penicillium fungi, annual bluegrass, and arbuscular mycorrhizal fungi all showed uptake and translocation of quantum dot-labeled organic nitrogen, but no uptake of quantum dot controls. Additionally, we observed quantum dot-labeled organic nitrogen within soil hyphae, plant roots, and plant shoots using field imaging techniques. This experiment is one of the first to demonstrate direct uptake of organic nitrogen by arbuscular mycorrhizal fungi.

Fungus propagules in plastids: the mycosome hypothesis.

A stress-induced "mycosome" phase of Aureobasidium pullulans consisting of minute reproductive propagules that may revert directly to walled yeast cells is described. Mycosomes detected by light- and electron-microscopy reproduce within senescent plant plastids, and display three developmental pathways: wall-less cells (protoplasts), yeast cells, or membrane-bounded spherules that harbor plastids. Widespread in plant and algal cells, mycosomes are produced by both ascomycete and basidiomycete fungi.

Fungus propagules in plastids: the mycosome hypothesis / Propágulos fúngicos en plástidos: la hipótesis micosómica

A stress-induced «mycosome» phase of Aureobasidium pullulans consisting of minute reproductive propagules that may revert directly to walled yeast cells is described. Mycosomes detected by light- and electron-microscopy reproduce within senescent plant plastids, and display three developmental pathways: wall-less cells (protoplasts), yeast cells, or membrane-bounded spherules that harbor plastids. Widespread in plant and algal cells, mycosomes are produced by both ascomycete and basidiomycete fungi (AU)

En este artículo se describe una fase «micosómica» inducida por estrés en Aureobasidium pullulans, consistente en minúsculos propágulos reproductivos que pueden revertir directamente a células de levadura con pared. Los micosomas, detectados por microscopía óptica y electrónica, se reproducen en el interior de plástidos senescentes en plantas, y muestran tres tipos de desarrollo diferentes: células sin pared (protoplastos), células de levadura, y esférulas rodeadas por membrana que contienen plástidos. Muy extendidos en células de plantas o algas, los micosomas son producidos por hongos ascomicetes o basidiomicetes (AU)

Local distribution of the lycaenid butterfly, Jalmenus evagoras, in response to host ants and plants.

The caterpillars of Jalmenus evagoras are tended by ants as they feed upon Acacia trees. In the area of Brisbane, Australia, J. evagoras require ants of the Iridomyrmex anceps species group; predation and parasitism are so intense that larvae and pupae deprived of attendant ants cannot survive (Pierce 1983). We investigated the efficiency with which J. evagoras locate and exploit the "host ant" resource by sampling 737 quadrats in 30 sampling grids and six study sites containing appropriate host plants; ants were collected at baits located in the center of each quadrat. J. evagoras was found in all habitats where I. anceps cooccurred with host Acacia. Nine of the ten sampling grids which had three or more I. anceps/Acacia "host" quadrats also had colonies of J. evagoras present (or immediately adjacent), including sites as far as 35 km apart. Of 19 sampling grids on which "host" quadrats were rare (i.e., less than three quadrats), none had J. evagoras (P<0.001). Within sample grids, I. anceps was distributed indepedently from Acacia trees, suggesting that they are not dependent for their survival on either Acacia or on J. evagoras. Within montane pasture habitats, I. anceps and at least one other ground-dwelling Iridomyrmex species were distributed in mutually exclusive "ant mosaic" territories which were stable during a one month period. I. anceps did not colonize or tend pupae of J. evagoras experimentally placed in adjacent territories of a different, nontending species of Iridomyrmex, demonstrating the integrity of territory boundaries. Sampling of ants in Acacia trees revealed that, in the absence of J. evagoras, Iridomyrmex workers are not common above ground level, and that their numbers decline in larger trees (P=0.02). In I. anceps territories, eight of nine J. evagoras pupae placed in trees over 3.0 m tall were not found after 24 h whereas all ten controls placed in low trees were found and tended (P=0.00012). This may explain why J. evagoras tends to oviposit in trees less than 2.0 m tall. An alternative hypothesis, that smaller trees have higher content of total nitrogen, and are threfore more nutritious, was not supported. We conclude that the local distribution and host tree selection by J. evagoras is dependent upon the distribution, patchiness, and foraging behavior of the host ant, I. anceps, and its spatial overlap with a number of species of host Acacia.

Adaptation to oak and other fibrous, phenolic-rich foliage by a small mammal, Neotoma fuscipes.

Neotoma fuscipes, a small mammalian herbivore with apparently generalized food habits, was laboratory tested to determine its degree of dietary specialization. Woodrats from both oak woodland and coastal sage communities preferred Quercus agrifolia leaves (containing 40% phenolics and about 16% condensed tannin) over foliage from other dominant species. Approximately one-third of the oak phenolics and less than 10% of the oak condensed tannin remained in the feces. Their performance on pure oak leaves was comparable to that on a mixed diet of Quercus, Salvia, Eriogonum, and Rhus, with respect to weight maintenance, digestive efficiency and total amount ingested. Digestive efficiency was low on the oak diet (55%) relative to Salvia (77%), and to achieve similar weight levels, approximately twice as much oak as Salvia was ingested. Woodrats retained more nitrogen as oak consumption increased. Intake of oak and other foods increased with each experimental day. A sympatric species, N. lepida, was unable to maintain weight on oak leaves, although its digestive and polyphenolic-degrading capabilities, and nitrogen retention efficiency were equivalent to those of N. fuscipes. On a weight-adjusted basis, N. lepida ate about half as much oak per day as N. fuscipes. Oak intake may have been reduced by an inability to rapidly degrade fiber, which constitutes about 30% of the oak diet. In natural populations, N. fuscipes selectively feeds on evergreen sclerophyll vegetation high in fiber, tannins and related polyphenolics. Individuals ingest 2-3 plant types at a time, with a single species (oak when available) constituting most of the material consumed. Neotoma lepida diets are also dominated by a single species. The diversity of plant types eaten by different populations of N. lepida suggests that local dietary specializations may be developmentally acquired.

Ant-dependent food plant selection by the mistletoe butterfly Ogyris amaryllis (Lycaenidae).

A quantitative study of the relationship between antoccupied mistletoes and oviposition by Ogyris amaryllis (Lycaenidae) revealed diet selection to be ant-dependent. Chemical toxins apparently prohibit the use of ant-occupied Lysiana plants. Nearly all of the 5106 censused eggs were laid on Amyema individuals with ants, independent of plant abundance or relative quality. On the average, only 32% of these nutritionally acceptable individuals were actually suitable for oviposition. The selection of Amyema maidenii with ants over nutritionally superior A. preissii without ants clearly identifies the secondary importance of food quality to O. amaryllis. Oviposition normally occurs after tactile stimulation by ants. Under experimental conditions without ants, females often laid clutches of 1-3 eggs, but significantly increased clutch size after contact with ants. Eggs laid in the presence of ants had lower parasitism rates than eggs laid away from ants.