A comparative study across the parasitic plants of Cuscuta subgenus Grammica (Convolvulaceae) reveals a possible loss of the plastid genome in its section Subulatae

Taken to extremes: Loss of plastid rpl32 in Streptophyta and Cuscuta's unconventional solution for its replacement

The evolution of plant genomes is riddled with exchanges of genetic material within one plant (endosymbiotic gene transfer/EGT) and between unrelated plants (horizontal gene transfer/HGT). These exchanges have left their marks on plant genomes. Parasitic plants with their special evolutionary niche provide ample examples for these processes because they are under a reduced evolutionary pressure to maintain autotrophy and thus to conserve their plastid genomes. On the other hand, the close physical connections with different hosts enabled them to acquire genetic material from other plants. Based on an analysis of an extensive dataset including the parasite Cuscuta campestris and other parasitic plant species, we identified a unique evolutionary history of rpl32 genes coding for an essential plastid ribosomal subunit in Cuscuta. Our analysis suggests that the gene was most likely sequestered by HGT from a member of the Oxalidales order serving as host to an ancestor of the Cuscuta subgenus Grammica. Oxalidales had suffered an ancestral EGT of rpl32 predating the evolution of the genus Cuscuta. The HGT subsequently relieved the plastid rpl32 from its evolutionary constraint and led to its loss from the plastid genome. The HGT-based acquisition in Cuscuta is supported by a high sequence similarity of the mature L32 protein between species of the subgenus Grammica and representatives of the Oxalidales, and by a surprisingly conserved transit peptide, whose functionality in Cuscuta was experimentally verified. The findings are discussed in view of an overall pattern of EGT events for plastid ribosomal subunits in Streptophyta.

Elucidating the evolutionary dynamics of parasitism in Cuscuta: in-depth phylogenetic reconstruction and extensive plastomes reduction

BACKGROUND

The genus Cuscuta L. (Convolvulaceae), commonly known as dodder, is a holoparasite plant that relies on host plants for nutrition, leading to significant genomic changes, particularly in plastomes. This dependency has led to significant reductions and modifications in their plastomes compared to autotrophic plants. In contrast to the well-conserved plastomes of photosynthetic plants, Cuscuta exhibits substantial genomic reductions reflecting the loss of photosynthetic functions and associated genes.

RESULT

This study examines eight plastomes within Cuscuta and reconstructs the phylogenetic relationships among 40 Cuscuta taxa using five other genera as an outgroup. The size of plastid genome varies significantly, with the smallest being 60 kb and the largest 121 kb, highlighting extensive genomic reduction. In special cases, the subgenera Cuscuta exhibit the loss of inverted repeats, distinguishing from them other subge within the Cuscuta genus. This reduction is most pronounced in genes related to photosynthesis, such as atp, pet, psa, psb, and ycf genes, particularly in the subg. Grammica (Lour.) Peter. The study also notes the frequent and independent loss of the plastid genes infA, rpl23, rpl32, rps15, and rps16 across various angiosperm lineages, often involving transfer to the nuclear genome. In parasitic plants like Cuscuta, the ndh genes, crucial for photosynthesis, are often lost. The study also highlights that in the subg. Grammica, the matK and rpo genes, along with trnR-ACG genes, are lost in parallel, indicating that these parasitic plants do not need matK and rpo genes after the loss of ndh genes for survival. Analysis of selective relaxation pressure on plastid genes shows a reductive trend, with genes such as atp, pet, psa, psb, rpo, and ycf progressively becoming pseudogenes over time, with housekeeping genes like rpl and rps expected to follow. However, the pseudogenization process is specific to the subg. Grammica, Pachystigma (Engelm.) Baker & C.H.Wright, and Cuscuta, rather than in the subg. Monogynella (Des Moul.) Peter, Engl. & Prantl (ancient clade species).

CONCLUSION

The study of Cuscuta plastomes reveals the profound impact of parasitism on genome evolution, highlighting the complex interplay of gene retention and loss through phylogenomic approaches. This research enriches our understanding of plant genome evolution and the intricate host-parasite relationships. It also sheds light on the evolutionary history and genomic adaptations of Cuscuta, illustrating the diverse strategies enabling subg. Grammica, Pachystigma, Cuscuta, and Monogynella thrive as parasitic species. These findings provide valuable insights into the molecular mechanisms underlying parasitism and its impact on plastid genome organization.

What we know so far and what we can expect next: A molecular investigation of plant parasitism

The review explores parasitic plants' evolutionary success and adaptability, highlighting their widespread occurrence and emphasizing the role of an invasive organ called haustorium in nutrient acquisition from hosts. It discusses the genetic and physiological adaptations that facilitate parasitism, including horizontal gene transfer, and the impact of environmental factors like climate change on these relationships. It addresses the need for further research into parasitic plants' genomes and interactions with their hosts to better predict environmental changes' impacts.

Variations and reduction of plastome are associated with the evolution of parasitism in Convolvulaceae

Parasitic lifestyle can often relax the constraint on the plastome, leading to gene pseudogenization and loss, and resulting in diverse genomic structures and rampant genome degradation. Although several plastomes of parasitic Cuscuta have  been reported, the evolution of parasitism in the family Convolvulaceae which is linked to structural variations and reduction of plastome has not been well investigated. In this study, we assembled and collected 40 plastid genomes belonging to 23 species representing four subgenera of Cuscuta and ten species of autotrophic Convolvulaceae. Our findings revealed nine types of structural variations and six types of inverted repeat (IR) boundary variations in the plastome of Convolvulaceae spp. These structural variations were associated with the shift of parasitic lifestyle, and IR boundary shift, as well as the abundance of long repeats. Overall, the degradation of Cuscuta plastome proceeded gradually, with one clade exhibiting an accelerated degradation rate. We observed five stages of gene loss in Cuscuta, including NAD(P)H complex → PEP complex → Photosynthesis-related → Ribosomal protein subunits → ATP synthase complex. Based on our results, we speculated that the shift of parasitic lifestyle in early divergent time promoted relaxed selection on plastomes, leading to the accumulation of microvariations, which ultimately resulted in the plastome reduction. This study provides new evidence towards a better understanding of plastomic evolution, variation, and reduction in the genus Cuscuta.

Invited Review Beyond parasitic convergence: unravelling the evolution of the organellar genomes in holoparasites

BACKGROUND

The molecular evolution of organellar genomes in angiosperms has been studied extensively, with some lineages, such as parasitic ones, displaying unique characteristics. Parasitism has emerged 12 times independently in angiosperm evolution. Holoparasitism is the most severe form of parasitism, and is found in ~10 % of parasitic angiosperms. Although a few holoparasitic species have been examined at the molecular level, most reports involve plastomes instead of mitogenomes. Parasitic plants establish vascular connections with their hosts through haustoria to obtain water and nutrients, which facilitates the exchange of genetic information, making them more susceptible to horizontal gene transfer (HGT). HGT is more prevalent in the mitochondria than in the chloroplast or nuclear compartments.

SCOPE

This review summarizes current knowledge on the plastid and mitochondrial genomes of holoparasitic angiosperms, compares the genomic features across the different lineages, and discusses their convergent evolutionary trajectories and distinctive features. We focused on Balanophoraceae (Santalales), which exhibits extraordinary traits in both their organelles.

CONCLUSIONS

Apart from morphological similarities, plastid genomes of holoparasitic plants also display other convergent features, such as rampant gene loss, biased nucleotide composition and accelerated evolutionary rates. In addition, the plastomes of Balanophoraceae have extremely low GC and gene content, and two unexpected changes in the genetic code. Limited data on the mitochondrial genomes of holoparasitic plants preclude thorough comparisons. Nonetheless, no obvious genomic features distinguish them from the mitochondria of free-living angiosperms, except for a higher incidence of HGT. HGT appears to be predominant in holoparasitic angiosperms with a long-lasting endophytic stage. Among the Balanophoraceae, mitochondrial genomes exhibit disparate evolutionary paths with notable levels of heteroplasmy in Rhopalocnemis and unprecedented levels of HGT in Lophophytum. Despite their differences, these Balanophoraceae share a multichromosomal mitogenome, a feature also found in a few free-living angiosperms.