Exploring the patterns of evolution: Core thoughts and focus on the saltational model.

The Modern Synthesis, a pillar in biological thought, united Darwin's species origin concepts with Mendel's laws of character heredity, providing a comprehensive understanding of evolution within species. Highlighting phenotypic variation and natural selection, it elucidated the environment's role as a selective force, shaping populations over time. This framework integrated additional mechanisms, including genetic drift, random mutations, and gene flow, predicting their cumulative effects on microevolution and the emergence of new species. Beyond the Modern Synthesis, the Extended Evolutionary Synthesis expands perspectives by recognizing the role of developmental plasticity, non-genetic inheritance, and epigenetics. We suggest that these aspects coexist in the plant evolutionary process; in this context, we focus on the saltational model, emphasizing how saltation events, such as dichotomous saltation, chromosomal mutations, epigenetic phenomena, and polyploidy, contribute to rapid evolutionary changes. The saltational model proposes that certain evolutionary changes, such as the rise of new species, may result suddenly from single macromutations rather than from gradual changes in DNA sequences and allele frequencies within a species over time. These events, observed in domesticated and wild higher plants, provide well-defined mechanistic bases, revealing their profound impact on plant diversity and rapid evolutionary events. Notably, next-generation sequencing exposes the likely crucial role of allopolyploidy and autopolyploidy (saltational events) in generating new plant species, each characterized by distinct chromosomal complements. In conclusion, through this review, we offer a thorough exploration of the ongoing dissertation on the saltational model, elucidating its implications for our understanding of plant evolutionary processes and paving the way for continued research in this intriguing field.

The plastic genome: The impact of transposable elements on gene functionality and genomic structural variations.

Transposable elements (TEs) are DNA sequences that can change their position within genomes. TEs are present in most organisms and can be an important genomic component. Their activities are manifold: restructuring of genome size, chromosomal rearrangements, induction of gene mutations, and alteration of gene activity by insertion near or within promoters, intronic regions, or enhancer. There are several examples of mutations and other genetic variations determined by the activity of TEs, associated with the evolution of prokaryotic and eukaryotic organisms and the domestication of plants. Generally, TE mobilization occurs when the organism is subjected to stress, which can include both biotic and abiotic stresses, polyploidy conditions, and interspecific hybridizations, very common events in plants. TEs are widely distributed among organisms. TEs also play essential roles in evolution, but most of them are either dormant or inactive. This is mainly determined by epigenetic silencing mechanisms, regulatory systems, and control systems that aim to limit its proliferation. Furthermore, the host has recruited many genes originated from TEs as transcriptional regulators, especially in defense against pathogens and invasive genetic elements; this phenomenon is called molecular domestication. Therefore, TEs are responsible for horizontal gene transfer and the movement of genetic material between organisms, even phylogenetically distant, with a consequent remixing of their gene pools.

A deficiency at the gene coding for zeta-carotene desaturase characterizes the sunflower non dormant-1 mutant.

The non dormant-1 (nd-1) mutant of sunflower (Helianthus annuus L.) is characterized by an albino and viviparous phenotype. Pigment analysis by spectrophotometer and HPLC demonstrated in nd-1 cotyledons the absence of beta-carotene, lutein and violaxanthin. Additionally, we found a strong accumulation of zeta-carotene and, to a lesser extent, of phytofluene and cis-phytoene in nd-1 seedlings grown in very dim light (1 micro mol m(-2) s(-1)). These results suggested that zeta-carotene desaturation was impaired in the mutant plants. To understand the molecular basis of the nd-1 mutation, we cloned and characterized the zeta-carotene desaturase (Zds) gene from sunflower. A reconstructed full-length sequence (1,916 bp) of the Zds cDNA was obtained from homozygous Nd-1/Nd-1 wild-type plants. It contains a 1,761-bp CDS, 62 nucleotides of 5'-untranslated region (UTR), and 77 nucleotides of 3'-UTR. The predicted protein (64.9 kDa) consists of 587 amino acid residues with a putative transit sequence for plastid targeting in the N-terminal region and a typical amino oxidase domain that includes the flavin adenosine dinucleotide (FAD) binding motif. The phylogenetic analysis demonstrated that the sunflower Zds was clustered to marigold (Tagetes) Zds gene, for which it showed an overall aminoacidic identity of 96.6% and resulted strictly correlated with other Zds sequences of higher plants. Interestingly, RT-PCR analyses showed that nd-1 plants were unable to accumulate Zds transcripts. Sequence information from the Zds cDNA was used to design specific primers and to isolate the full-length exons/introns region of the gene. The sunflower Zds gene (HaZds) comprises 14 exons and 13 introns scattered in a ca. 5.0-kb region. Also, HaZds showed a high conservation of the distribution and size of the exons with rice Zds gene. Based on genomic Southern analysis, the nd-1 genome disclosed a large deficiency at the Zds locus.