Formation of α- and β-conidia by Phaeocytostroma ambiguum

The formation of conidia in Phaeocytostroma ambiguum on different media and conditions was investigated in this study. Carnation leaf agar (CLA) and a 12 h photoperiod (24/18 °C) provided excellent conditions for the promotion of rapid formation of both alpha (α) and beta (β) conidia in a number of P. ambiguum isolates. The dimensions of α- and β-conidia amounted to 6.0–19.6 × 3.8–7.5 μm and 6.0–24.9 × 1.1–2.6 μm, respectively. They were produced on short or elongate, simple and branched conidiophores. β-conidia have not been described before in P. ambiguum. Intermediate conidia were rarely found. This revised version was published online in August 2006 with corrections to the Cover Date.     

Development of a fertile genetic bridge between Trifolium ambiguum M. Bieb. and T. repens L.

  Trifolium ambiguum M. Bieb and T. repens L. are taxonomically related but very difficult to cross. The rare hybrids so far reported between these two species were obtained only by embryo culture. This difficulty has been overcome in the present research by the creation of a “fertile bridge” between T. ambiguum and T. repens. Characters of interest can now be transferred from T. ambiguum to T. repens by using this “fertile bridge” without the use of sophisticated techniques. An array of backcross progenies was generated from crosses between a T. ambiguum×T. repens F₁ hybrid (8x H-435) and its parental species. The 8x hybrid was cross-fertile only with T. repens and resulted in 145 seeds from 1578 reciprocal crosses. Eleven of nineteen initially grown BC₁F₁ plants were all hexaploid with an average pollen stainability of 41.6%. A high frequency of multivalents at metaphase-I indicated that both autosyndetic and allosyndetic pairing occurred. Backcrosses of 6x BC₁F₁ plants to T. repens resulted in 5x BC₂F₁ plants with an average pollen stainability of 59.3%. On the other hand, 6x BC₁F₁×6x T. ambiguum crosses did not produce any seed and only two pentaploid plants were obtained from 6x BC₁F₁×4x T. ambiguum crosses. The difficulty encountered in generating 6x backcross progeny with 6x T. ambiguum was overcome by intercrossing the 6x BC₁F₁ plants and producing 6x BC₁F₂ plants with an average pollen stainability of 65.8%. One of these 6x BC₁F₂ plants was cross-compatible as a female with 6x T. ambiguum and resulted in CBC₂ plants that were all cross-compatible with 6x T. ambiguum. The 6x BC₁F₂ plants are likely to be superior to 6x BC₁F₁ progeny, as they have exhibited better expression of the combined rhizomatous and stoloniferous growth habit, improved fertility, more frequent nodal rooting and heavier nodulation. Consequently, the 6x BC₁F₂ plants can either be used directly in the selection programme or as a “fertile bridge” between the two parental species. The present work has resulted in the development of a series of fertile hybrids by the manipulation of chromosome numbers, combining the agronomic characteristics of the parent species in varying genome balances and at a range of ploidy levels. It is concluded that the initial sterility of the primary interspecific hybrids need not be a barrier to successful inter-breeding. Received: 2 August 1996 / Accepted: 4 April 1997     

Variations in seed germination behavior of Phleum hirsutum subsp. ambiguum and possible applications in semi-natural grassland restoration

Phleum hirsutum Honck. subsp. ambiguum (Ten.) Tzvelev is an important component of the vegetation of some semi-natural grassland habitats of central and southern Italy and especially of those referring to the 6210^* habitat (Directive 92/43/EEC). Seeds of this species are required for the execution of restoration works concerning this habitat. Therefore, the recovery and the study of autochthonous germplasm are needed. This study focused on the intra-specific variations in seed mass and size and in seed germination behavior in this species since the knowledge of these aspects can be very useful in the planning of restoration projects. The present research evidenced significant differences in mean seed mass and size in the populations studied that were correlated to the precipitation values of their collection sites. Studied seeds are able to germinate under a wide range of temperatures. They reached their maximum germination between 5 and 25°C and are capable of germination even at 30°C but with a remarkable reduction in germination percentage. Temperature was found to strongly influence germination, especially in terms of the speed. Light was found to enhance germination in almost all the populations studied while the removal of outer covering structures was found to be of no effect.