120 research outputs found
Plant Cyclin-Dependent Kinase Inhibitors of the KRP Family: Potent Inhibitors of Root-Knot Nematode Feeding Sites in Plant Roots
Root-knot nematodes (RKN), Meloidogyne spp., are distributed worldwide and impose severe economic damage to many agronomically important crops. The plant cell cycle machinery is considered one of the pivotal components for the formation of nematode feeding sites (NFSs) or galls. These feeding sites contain five to nine hypertrophied giant cells (GC) resulting from developmental reprogramming of host root cells by this pathogen. GC undergo synchronous waves of mitotic activity uncoupled from cytokinesis giving rise to large multinucleate cells. As development of the NFS progresses, multiple rounds of DNA synthesis occur in the nuclei of GC, coupled with nuclear and cellular expansion. These cells are highly metabolically active and provide the nematode with nutrients necessary for its development and completion of its life cycle. In Arabidopsis seven cyclin dependent kinase inhibitors (CKIs) belonging to the interactors/inhibitors of the cyclin dependent kinases (ICK) family, also referred as Kip-Related Proteins (KRPs) have been identified. Interactions of KRPs with CDK/Cyclin complexes decrease CDK activity, affecting both cell cycle progression and DNA content in a concentration-dependent manner. We performed the functional analysis of all Arabidopsis KRP gene members during RKN interaction in Arabidopsis to obtain more insight into their role during gall development. We demonstrated that three members of this family (KRP2, KRP5, and KRP6) were highly expressed in galls and were important for cell cycle regulation during NFS development as shown by their different modes of action. We also pointed out that cell cycle inhibition through overexpression of all members of the KRP family can affect NFS development and consequently compromise the nematodeās life cycle. In this review we summarized our recent understanding of the KRP family of genes, and their role in controlling cell cycle progression at the RKN feeding site
Redirection of auxin flow in Arabidopsis thaliana roots after infection by root-knot nematodes
Plant auxin efflux and influx proteins redirect the plant hormone auxin towards the feeding site upon root-knot nematode infection in Arabidopsis thaliana roots.Plant-parasitic root-knot nematodes induce the formation of giant cells within the plant root, and it has been recognized that auxin accumulates in these feeding sites. Here, we studied the role of the auxin transport system governed by AUX1/LAX3 influx proteins and different PIN efflux proteins during feeding site development in Arabidopsis thaliana roots. Data generated via promoter-reporter line and protein localization analyses evoke a model in which auxin is being imported at the basipetal side of the feeding site by the concerted action of the influx proteins AUX1 and LAX3, and the efflux protein PIN3. Mutants in auxin influx proteins AUX1 and LAX3 bear significantly fewer and smaller galls, revealing that auxin import into the feeding sites is needed for their development and expansion. The feeding site development in auxin export (PIN) mutants was only slightly hampered. Expression of some PINs appears to be suppressed in galls, probably to prevent auxin drainage. Nevertheless, a functional PIN4 gene seems to be a prerequisite for proper nematode development and gall expansion, most likely by removing excessive auxin to stabilize the hormone level in the feeding site. Our data also indicate a role of local auxin peaks in nematode attraction towards the root
The plantĀ WEE1Ā kinaseĀ isĀ involved inĀ checkpointĀ control activation inĀ nematode-induced galls
Galls induced by plantāparasitic nematodes involve a hyperactivation of the plant mitotic and endocycle machinery for their profit. Dedifferentiation of host root cells includes drastic cellular and molecular readjustments. In such background, potential DNA damage in the genome of gall cells is eminent.
We questioned if DNA damage checkpoints activation followed by DNA repair occurred, or was eventually circumvented, in nematodeāinduced galls.
Galls display transcriptional activation of the DNA damage checkpoint kinase WEE1, correlated with its protein localization in the nuclei. The promoter of the stress marker gene SMR7 was evaluated under the WEE1āknockout background. Drugs inducing DNA damage and a marker for DNA repair, PARP1 were used to understand mechanisms that might cope with DNA damage in galls.
Our functional study revealed that gall cells lacking WEE1 conceivably entered mitosis prematurely disturbing the cell cycle despite the loss of genome integrity. The disrupted nuclei phenotype in giant cells hinted to the accumulation of mitotic defects. As well, WEE1āknockout in Arabidopsis and downregulation in tomato repressed infection and reproduction of rootāknot nematodes. Together with data on DNA damaging drugs, we suggest a conserved function for WEE1 controlling a G1/S cell cycle arrest in response to replication defect in galls
Ectopic expression of Kip-related proteins restrains root-knot nematode-feeding site expansion
The development of nematode feeding sites induced by root-knot nematodes involves the
synchronized activation of cell cycle processes such as acytokinetic mitoses and DNA amplification.
A number of key cell cycle genes are reported to be critical for nematode feeding site
development. However, it remains unknown whether plant cyclin-dependent kinase (CDK)
inhibitors such as the Arabidopsis interactor/inhibitor of CDK (ICK)/Kip-related protein (KRP)
family are involved in nematode feeding site development. This study demonstrates the
involvement of Arabidopsis ICK2/KRP2 and ICK1/KRP1 in the control of mitosis to endoreduplication
in galls induced by the root-knot nematode Meloidogyne incognita.
! Using ICK/KRP promoter-GUS fusions and mRNA in situ hybridizations, we showed that
ICK2/KRP2, ICK3/KRP5 and ICK4/KRP6 are expressed in galls after nematode infection.
Loss-of-function mutants have minor effects on gall development and nematode reproduction.
Conversely, overexpression of both ICK1/KRP1 and ICK2/KRP2 impaired mitosis in giant
cells and blocked neighboring cell proliferation, resulting in a drastic reduction of gall size.
! Studying the dynamics of protein expression demonstrated that protein levels of ICK2/
KRP2 are tightly regulated during giant cell development and reliant on the presence of the
nematode.
! This work demonstrates that impeding cell cycle progression by means of ICK1/KRP1 and
ICK2/KRP2 overexpression severely restricts gall development, leading to a marked limitation
of root-knot nematode development and reduced numbers of offsprin
The plant apoplasm is an important recipient compartment for nematode secreted proteins
Similarly to microbial pathogens, plant-parasitic nematodes secrete into their host plants proteins that are essential to establish a functional interaction. Identifying the destination of nematode secreted proteins within plant cell compartment(s) will provide compelling clues on their molecular functions. Here the fine localization of five nematode secreted proteins was analysed throughout parasitism in Arabidopsis thaliana. An immunocytochemical method was developed that preserves both the host and the pathogen tissues, allowing the localization of nematode secreted proteins within both organisms. One secreted protein from the amphids and three secreted proteins from the subventral oesophageal glands involved in protein degradation and cell wall modification were secreted in the apoplasm during intercellular migration and to a lower extent by early sedentary stages during giant cell formation. Conversely, another protein produced by both subventral and dorsal oesophageal glands in parasitic stages accumulated profusely at the cell wall of young and mature giant cells. In addition, secretion of cell wall-modifying proteins by the vulva of adult females suggested a role in egg laying. The study shows that the plant apoplasm acts as an important destination compartment for proteins secreted during migration and during sedentary stages of the nematode
Cell cycle genes as markers to study the ontogeny of nematode feeding sites in plant roots
Research on the ontogeny of feeding sites induced by sedentary plant-endoparasitic nematodes has already been in focus for many decades. Nematodes induce root cells to de-differentiate into large multinucleate and cytoplasm-dense feeding cells. Arabidopsis thaliana was chosen as a model host to study cell cycle progression in nematode feeding sites induced by the root-knot nernatode, Meloidogyne incognita, and the cyst nematode Heterodera schachtii. Cell cycle markers were used to monitor how nematode feeding sites develop and what the initial signals are that trigger certain root cells to evolve into giant cells embedded in a gall, or into a syncytium. Tritiated thymidine incorporation experiments were applied to detect DNA synthesis, which was used as a marker for the S phase of the cell cycle. Extending our analysis, the expression pattern of two cyclin-dependent kinases and two mitotic cyclins were examined. The CYCB1;1 gene was used as a marker for the G2 phase and CDKB1;1 arid CYCA2;1 for the S and G2 phases, whereas the CDKA;1 gene was used as a marker for all cell cycle phases. Nematode-infected seedlings were also treated with two cell cycle inhibitors (hydroxyurea and oryzalin) to investigate the relevance of DNA synthesis and mitosis on the development of these feeding sites. A strong correlation was observed between initiation of feeding cells by both root-knot and cyst nematodes, and the induction of DNA synthesis and the expression of particular cell cycle genes. Our results show that endoreplication and mitotic cycles play a role during the root cell dedifferentiation process caused by nematode infection
Nematode-induced endoreduplication in plant host cells: why and how?
Plant-parasitic root-knot and cyst nematodes have acquired the ability to induce remarkable changes in host cells during the formation of feeding sites. Root-knot nematodes induce several multinucleate giant cells inside a gall whereas cyst nematodes provoke the formation of a multinucleate syncytium. Both strategies impinge on the deregulation of the cell cycle, involving a major role for endoreduplication. This review will first describe the current knowledge on the control of normal and aberrant cell cycles. Thereafter, we will focus on the role of both cell-cycle routes in the transformation process of root cells into large and highly differentiated feeding sites as induced by the phytoparasitic root-knot and cyst nematodes
- ā¦