Eragrostis curvula, a Model Species for Diplosporous Apomixis

Eragrostis curvula (Schrad.) Ness is a grass with a particular apomictic embryo sac development called Eragrostis type. Apomixis is a type of asexual reproduction that produces seeds without fertilization in which the resulting progeny is genetically identical to the mother plant and with the potential to fix the hybrid vigour from more than one generation, among other advantages. The absence of meiosis and the occurrence of only two rounds of mitosis instead of three during embryo sac development make this model unique and suitable to be transferred to economically important crops. Throughout this review, we highlight the advances in the knowledge of apomixis in E. curvula using different techniques such as cytoembryology, DNA methylation analyses, small-RNA-seq, RNA-seq, genome assembly, and genotyping by sequencing. The main bulk of evidence points out that apomixis is inherited as a single Mendelian factor, and it is regulated by genetic and epigenetic mechanisms controlled by a complex network. With all this information, we propose a model of the mechanisms involved in diplosporous apomixis in this grass. All the genetic and epigenetic resources generated in E. curvula to study the reproductive mode changed its status from an orphan to a well-characterised species.

Genetic and Environmental Factors Affecting the de novo Appearance of the [PSI + ] Prion in Saccharomyces cerevisiae

It has previously been shown that yeast prion [PSI + ] is cured by GuHCl, although reports on reversibility of curing were contradictory. Here we show that GuHCl treatment of both [PSI + ] and [psi – ] yeast strains results in two classes of [psi – ] derivatives: Pin+, in which [PSI + ] can be reinduced by Sup35p overproduction, and Pin–, in which overexpression of the complete SUP35 gene does not lead to the [PSI + ] appearance. However, in both Pin+ and Pin– derivatives [PSI + ] is reinduced by overproduction of a short Sup35p N-terminal fragment, thus, in principle, [PSI + ] curing remains reversible in both cases. Neither suppression nor growth inhibition caused by SUP35 overexpression in Pin+ [psi – ] derivatives are observed in Pin– [psi – ] derivatives. Genetic analyses show that the Pin+ phenotype is determined by a non-Mendelian factor, which, unlike the [PSI + ] prion, is independent of the Sup35p N-terminal domain. A Pin– [psi – ] derivative was also generated by transient inactivation of the heat shock protein, Hsp104, while [PSI + ] curing by Hsp104 overproduction resulted exclusively in Pin+ [psi – ] derivatives. We hypothesize that in addition to the [PSI + ] prion-determining domain in the Sup35p N-terminus, there is another self-propagating conformational determinant in the C-proximal part of Sup35p and that this second prion is responsible for the Pin+ phenotype.

Genesis and Variability of [PSI] Prion Factors in Saccharomyces cerevisiae

We have previously shown that multicopy plasmids containing the complete SUP35 gene are able to induce the appearance of the non-Mendelian factor [PSI]. This result was later interpreted by others as a crucial piece of evidence for a model postulating that [PSI] is a self-modified, prion-like conformational derivative of the Sup35 protein. Here we support this interpretation by proving that it is the overproduction of Sup35 protein, and not the excess of SUP35 DNA or mRNA that causes the appearance of [PSI]. We also show that the “prion-inducing domain” of Sup35p is in the N-terminal region, which, like the “prion-inducing domain” of another yeast prion, Ure2p, was previously shown to be distinct from the functional domain of the protein. This suggests that such a chimeric organization may be a common pattern of some prion elements. Finally, we find that [PSI] factors of different efficiencies and different mitotic stabilities are induced in the same yeast strain by overproduction of the identical Sup35 protein. We suggest that the different [PSI]-containing derivatives are analogous to the mysterious mammalian prion strains and result from different conformational variants of Sup35p.

Isolation of omnipotent suppressors in an [eta+] yeast strain.

Omnipotent suppressors decrease translational fidelity and cause misreading of nonsense codons. In the presence of the non-Mendelian factor [eta+], some alleles of previously isolated omnipotent suppressors are lethal. Thus the current search was conducted in an [eta+] strain in an effort to identify new suppressor loci. A new omnipotent suppressor, SUP39, and alleles of sup35, sup45, SUP44 and SUP46 were identified. Efficiencies of the dominant suppressors were dramatically reduced in strains that were cured of non-Mendelian factors by growth on guanidine hydrochloride. Wild-type alleles of SUP44 and SUP46 were cloned and these clones were used to facilitate the genetic analyses. SUP44 was shown to be on chromosome VII linked to cyh2, and SUP46 was clearly identified as distinct from the linked sup45.

The Mutator-Related Cy Transposable Element of Zea Mays L. Behaves as a near-Mendelian Factor.

The bz-rcy allele arose in a single gamete of the TEL (transposable-element laden) population, when the rcy receptor element inserted into the Bronze1 locus. This newly arisen receptor allele conditions a stable bronze kernel phenotype in the absence of the independently segregating regulatory element, Cy. In the presence of Cy, bz-rcy conditions fully colored spots on a bronze background. The spots represent clonal sectors arising from mutations of bz-rcy to Bz'. Although Cy exhibits genetic interactions with the Mutator system it differs from Mu-homologous elements in its near-Mendelian behavior which is in contrast to the non-Mendelian inheritance of Mutator and Mu-homologous elements. Evidence is presented which suggests that the timing and mode of Cy transposition differ from those of Mu1.