Functional analysis of Arabidopsis thaliana lesion mimic mutant cfs1 in ESCRT complex-related protein trafficking

The Endosomal Sorting Complex Required for Transport (ESCRT)-complex is composed of four complexes, ESCRT-0-III. They sequentially act on a late endosome to sort mono-ubiquitinated transmembrane proteins into the intralumenal vesicle, forming of a multivesicular body(MVB) that is delivered to vacuole for degradation. In Arabidopsis thaliana, the loss of an ESCRT-I component, elch displays a cytokinesis defect; while a dominant negative expression of an ESCRT-III component results in cell death due to vacuolar loss. In this work, the function of a plant-specific ELCH-interactor, CELL DEATH RELATED FYVE/SYLF DOMAIN CONTAINING 1 (CFS1) and its influences on the ESCRT-complex function are investigated. CFS1 is a phosphatidylinositol-3-phosphate- and actin-binding protein. The cfs1 mutants mimic lesions in the first eldest leaf that propagate to the next eldest one. Genetic analyses have demonstrated that cell death in cfs1 does not require a functional ESCRT-I component; nevertheless, the loss of CFS1 alleviates elchcytokinesis defect, suggesting its influence on the ESCRT-I function. Further analyses reveal that cfs1 accumulates autophagosomes throughout its lifespan due to a decrease in autophagosome degradation, suggesting that as the plant ages, the cumulated autophagosomes falsely trigger effectors-triggered immunity that executes cell death in cfs1. As the ESCRT-complex has been demonstrated to be involved in the delivery of autophagosomes to vacuole and CFS1 homolog, CFS2 reportedly interacts with ATG8, it can be postulated from the results of this work that CFS1 alone or together with CFS2 function in sequestering mature autophagosomes onto MVBs. At the MVBs, the ESCRT-complex then mediates the fusion of autophagosome and MVB for subsequent delivery to vacuole.

The role of FMT and FIS1A in mitochondrial morphology and salt stress in Arabidopsis thaliana

Salt stress is known to have severe effects on plant health and fecundity, and mitochondria are known to be an essential part of the plant salt stress response. Arabidopsis thaliana serves as an excellent model to study the effects of salt stress as well as mitochondrial morphology. Arabidopsis contains several homologues to known mitochondrial proteins, including the fission protein FIS1A, and FMT, a homologue of the CLU subfamily. We sought to examine the effects of salt stress on knockout lines of FIS1A and FMT, as well as a transgenic line overexpressing FMT (FMT-OE) in columella cells in the root cap of Arabidopsis. fmt mutants displayed defects in both root and leaf growth, as well as a delay in flowering time. These mutants also showed a pronounced increase in mitochondrial clustering and number. FMT-OE mutants displayed severe defects in germination, including a decrease in total germination, and an increase in the number of days to germination. fis1A mutants exhibited shorter roots and slightly shorter leaves, as well as a tendency towards random mitochondrial clustering in root cells. Salt stress was shown to affect various mitochondrial parameters, including an increase in mitochondrial number and clustering, as well as a decrease in mitochondrial area. These results reveal a previously unknown role for FMT in germination and flowering in Arabidopsis, as well as insight into the effects of salt stress on mitochondrial morphology. FMT, along with FIS1A, may also help to regulate mitochondrial number and clustering, as well as root and leaf growth, under both control and salt-stressed conditions. This has implications for both FMT and FIS1A in whole-plant morphology as well as the plant salt stress response.