# Protoplast‐Based Functional Genomics and Genome Editing: Progress, Challenges and Applications

**Authors:** Jo‐Wei Allison Hsieh, Fu‐Hui Wu, Dian‐Xuan Yang, Ai‐En Wu, Ching‐Ann Liu, Chang‐Hung Chen, Shinn‐Zong Lin, Ying‐Chung Jimmy Lin, Choun‐Sea Lin

PMC · DOI: 10.1111/pce.70375 · 2026-01-11

## TL;DR

This review explores how protoplast-based systems are used to study plant responses to stress and improve crops through techniques like CRISPR and single-cell transcriptomics.

## Contribution

The paper provides a comprehensive analysis of 1050 studies to highlight recent advances in protoplast-based functional genomics and genome editing for crop improvement.

## Key findings

- Protoplast-based systems enable precise molecular studies of plant stress responses and gene regulation.
- CRISPR/Cas RNP editing via protoplasts offers a regulation-compliant strategy for crop improvement.
- Protoplast fusion and single-cell transcriptomics are advancing stress resilience in crops.

## Abstract

Protoplast‐based systems provide a powerful and versatile platform for exploring how plants sense and respond to their environment. By enabling the direct delivery of proteins, DNA, and RNA into plant cells after cell wall removal, this approach facilitates precise molecular dissection of signaling, stress adaptation, and gene regulation across both model species and economically important crops. In this review, we analyzed 1050 published articles and categorizing them by delivery methods, research focus, plant species, and tissue types. We further highlight recent advances, including the application of single‐cell transcriptomics, which provides unprecedented resolution for dissecting cellular responses and offers deeper insights into the mechanisms underlying stress resilience. Importantly, protoplast regeneration is gaining renewed attention not only as a model system for studying cellular reprogramming but also as a practical platform for crop improvement. Applications of protoplast regeneration include protoplast fusion, which integrates nuclear and organellar DNA/genomes from divergent parents to accelerate breeding and enhance tolerance to both biotic and abiotic stresses. Another important application is CRISPR/Cas ribonucleoprotein (RNP)‐based editing targeting stress‐resilience‐related genes. In asexually propagated or highly heterozygous perennial crops with limited sexual reproduction, protoplast‐based RNP delivery offers a viable and regulation‐compliant strategy. This approach may help address public concerns over transgenic technologies while enabling the rapid development of stress‐tolerant cultivars.

Based on an analysis of 1050 studies, this review shows that protoplast‐based systems have evolved into a powerful platform for both mechanistic studies and crop improvement, integrating advances such as single‐cell transcriptomics, protoplast fusion, and CRISPR/Cas RNP editing to enable precise and regulation‐compliant development of stress‐resilient crops.

Based on an analysis of 1050 studies, this review shows that protoplast‐based systems have evolved into a powerful platform for both mechanistic studies and crop improvement, integrating advances such as single‐cell transcriptomics, protoplast fusion, and CRISPR/Cas RNP editing to enable precise and regulation‐compliant development of stress‐resilient crops.

## Full-text entities

- **Genes:** LYK5 (Protein kinase superfamily protein) [NCBI Gene 817923] {aka AtLYK5, F4P9.35, F4P9_35, LysM-containing receptor-like kinase 5}, CERK1 (chitin elicitor receptor kinase 1) [NCBI Gene 821717] {aka AtCERK1, AtLYK1, LYK1, LYSM DOMAIN RECEPTOR-LIKE KINASE 1, LYSM RLK1, LysM-containing receptor-like kinase 1}, ERF104 (ethylene response factor 104) [NCBI Gene 836281] {aka K11J9.13, K11J9_13, ethylene response factor 104}, MPK6 (MAP kinase 6) [NCBI Gene 818982] {aka ATMAPK6, ATMPK6, F18O19.10, MAP KINASE 6, MAP kinase 6, MAPK6}, PIP5K6 (Phosphatidylinositol-4-phosphate 5-kinase family protein) [NCBI Gene 819987] {aka phosphatidylinositol-4-phosphate 5-kinase 6}
- **Diseases:** male sterility (MESH:D007248), nodulation (MESH:D016606), infection (MESH:D007239)
- **Chemicals:** tunicamycin (MESH:D014415), dithiothreitol (MESH:D004229), salt (MESH:D012492), phosphoinositide (MESH:D010716), salicylic acid (MESH:D020156), NaCl (MESH:D012965), ABA (MESH:D000040), Chitin (MESH:D002686), PEG (MESH:D011092), lipid (MESH:D008055), cytokinin (MESH:D003583), ROS (MESH:D017382), Calcium (MESH:D002118), auxin (MESH:D007210), BBDD (-)
- **Species:** Brassica oleracea (wild cabbage, species) [taxon 3712], Citrus (genus) [taxon 2706], Musa (genus) [taxon 4640], Nicotiana tabacum (American tobacco, species) [taxon 4097], Isatis tinctoria (woad, species) [taxon 161756], Vitis vinifera (wine grape, species) [taxon 29760], Glycine max (soybean, species) [taxon 3847], Medicago sativa (alfalfa, species) [taxon 3879], Musa acuminata (banana, species) [taxon 4641], Gossypium hirsutum (American cotton, species) [taxon 3635], Nalata (genus) [taxon 1239038], Solanum peruvianum (Peruvian tomato, species) [taxon 4082], Physcomitrium patens (species) [taxon 3218], Solanum (genus) [taxon 4107], Nicotiana benthamiana (species) [taxon 4100], Thinopyrum elongatum (tall wheatgrass, species) [taxon 4588], Nicotiana attenuata (species) [taxon 49451], Oryza sativa (Asian cultivated rice, species) [taxon 4530], Solanum tuberosum (potatoes, species) [taxon 4113], Triticum aestivum (bread wheat, species) [taxon 4565], Salvia miltiorrhiza (Chinese salvia, species) [taxon 226208], Citrus maxima (buntan, species) [taxon 37334], Lathyrus oleraceus (garden pea, species) [taxon 3888], Arabidopsis thaliana (mouse-ear cress, species) [taxon 3702], Daucus carota (carrot, species) [taxon 4039], Solanum lycopersicum (tomato, species) [taxon 4081], Brassica napus (oilseed rape, species) [taxon 3708], Zea mays (maize, species) [taxon 4577], Tomato yellow leaf curl virus (no rank) [taxon 10832]
- **Cell lines:** S2 — Drosophila melanogaster (Fruit fly), Spontaneously immortalized cell line (CVCL_Z232)

## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12976588/full.md

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Source: https://tomesphere.com/paper/PMC12976588