Jerry R. Barrow

Do symbiotic microbes have a role in plant evolution, performance and response to stress?

Vascular plants have been considered as autonomous organisms especially when their performance has been interpreted at the genome and cellular level. In reality, vascular plants provide a unique ecological niche for diverse communities of cryptic symbiotic microbes which often contribute multiple benefits, such as enhanced photosynthetic efficiency, nutrient and water use and tolerance to abiotic and biotic stress. These benefits are similar to improvements sought by plant scientists working to develop ecologically sustainable crops for food, fiber and biofuels. Native desert plants include a community of indigenous endosymbiotic fungi that are structural components with cells, tissues, cell cultures, and regenerated plants. These fungi regulate plant growth and development and contribute genes and natural products that enable plants to adapt to changing environments. A method developed for transferring these endophytes from cell cultures to non-host plants promises to be a revolutionary approach for the development of novel plant germplasm and has application in the field of plant biotechnology.

FUNGAL ENDOPHYTES INTRINSICALLY ASSOCIATED WITH MICROPROPAGATED PLANTS REGENERATED FROM NATIVE BOUTELOUA ERIOPODA TORR. AND ATRIPLEX CANESCENS (PURSH) NUTT.

SummaryBlack grama (Bouteloua eriopoda) and fourwing saltbush (Atriplex canescens) are important grass and shrub species in arid rangelands of the northern Chihuahuan Desert. They are naturally colonized by dark septate endophytic fungi that cannot be eliminated by seed disinfestation. Plants were regenerated from both species and appeared to be fungus-free in axenic cultures. Analysis of callus and regenerated plants of both species using dual staining with light and scanning electron microscopy revealed fungal endophytes intrinsically associated with cells, roots and leaves of regenerated plants that are also associated with native plants. Fungal layers and biofilms prevent direct exposure of callus, root or leaf tissues to the external environment. Micropropagation is a valuable tool for identifying key fungal endophytes that enhance drought tolerance in native desert plants.

Proceedings: Shrubland ecosystem dynamics in a changing environment

This proceedings contains 50 papers including an overview of shrubland ecosystem dynamics in a changing environment and several papers each on vegetation dynamics, management concerns and options, and plant ecophysiology as well as an account of a Jornada Basin field trip. Contributions emphasize the impact of changing environmental conditions on vegetative composition especially in the Jornada Basin and Chihuahuan Desert but also in other parts of western North America and the world.Individual papers from this publication

REGENERATION OF BLACK GRAMA (BOUTELOUA ERIOPODA TORR. TORR) PLANTS VIA SOMATIC EMBRYOGENESIS

SummaryBlack grama (Bouteloua eriopoda) is an important forage grass in southwestern USA rangelands. Plants were regenerated by somatic embryogenesis. Surface-disinfested seeds were germinated and the embryonic shoots were excised and cultured on Murashige and Skoog (MS) medium gelled with agar. Callus was induced from apical meristems. Calluses were cultured on MS solid medium with six concentrations of 2,4-dichlorophenoxyacetic acid (2,4-D) or Dicamba (6-dichloro-o-anisic acid) for 6 wk under light or dark conditions. Somatic embryo induction was greatest on 4.52 μM Dicamba, under light, after transferring to an auxin-free medium. Embryo development progressed from globular torpedo to mature embryos phenotypically identical to those naturally produced in seed. These germinated and grew into intact plants and were established in soil and grown to maturity. To our knowledge, this is the first report of somatic embryo induction and regeneration in black grama grass.

Endosymbiotic fungi structurally integrated with leaves reveals a lichenous condition of C4 grasses

This paper addresses the assumed autonomy of vascular plants by revealing the presence of an obligate fungus structurally integrated with leaf anatomy of C4 grasses. We examined leaf surfaces of 26 species representing 14 genera of C4 grasses. In all species, we found similarities between leaf surface microhair-like structures and Uredomycete teliospores. These bicellular structures produced hyphae and spores, confirming they were fungal, rather than plant tissue. The plant-fungus structural morphology was also observed in Bouteloua eriopoda plants regenerated from embryonic meristem cells. The conserved symbiosis between fungi and C4 grasses suggests a lichenous association with evolutionary significance. The structural integration of endosymbiotic fungi with cells and tissues offers novel and unexplored approaches to developing physiological, ecological, and systematic models of C4 grasses.

The conditions required to isolate and maintain viable cotton (Gossypium hirsutum L.) microspores

Cultural systems developed for the successful production of haploid plants from anther and microspore culture of a number of species are lethal to cotton microspores. Components of these systems were examined individually and in simple combinations to determine their specific effect on cotton microspore viability during isolation and culture. An organically buffered pH of 7.0 was critical for survival. The addition of potassium salts, near standard concentrations used for other species, enhanced survival and the cytoplasmic appearance of isolated microspores. Severe toxicity resulted from ammonium, calcium and magnesium salts, and these ions were tolerated only at very low concentrations. Iron, glutamine, serine, inositol, vitamins, and trace minerals were generally not detrimental to microspores at standard concentrations. An isolation and cultural maintenance system was developed that yields large quantities of healthy, viable cotton microspores. This initial step allows for further research in inducing cotton microspores to divide and undergo embryogenesis.

Short-term storage of cotton pollen.

Several methods of storing cotton pollen (Gossypium hirsutum L.) were evaluated. A successful pollen storage method that maintains fertility would enhance the crossing of breeding materials. Storing pollen at ultra-low temperatures in liquid nitrogen or at 5°C was not successful. No storage method maintained pollen fertility for more than 72 h. Cotton pollen did maintain adequate fertility up to 24 h at 10 and 15°C, at both low and high humidity when the pollen was stored in the detached flowers. Minimally acceptable pollen fertility was maintained in flowers stored at 15°C at 100% R.H. for 72 h. Use of these methods will allow for better utilization of parental plants when both parents do not flower on the same days.