A Pectinase-deficient Ralstonia solanacearum Strain Induces Reduced and Delayed Structural Defences in Tomato Xylem

It has been suggested that oligogalacturonides (OGAs) released by bacterial pectinases can induce plant defence responses. To test this hypothesis, resistant tomato cultivar LS-89 and susceptible cultivar Ponderosa were inoculated with either wild-type Ralstonia solanacearum strain K60 or a pectinase-deficient triple mutant K60-509, which lacks endo-polygalacturonase PehA, exo-poly-alpha- d -galacturonosidase PehB, and pectin methylesterase Pme. K60 induced structural defence responses, including electron-dense materials (EDMs) in vessels and apposition layers (ALs) in parenchyma cells adjacent to xylem vessels colonized by bacteria in LS-89 stems. In contrast, LS-89 infected with K60-509 did not have any EDMs in vessels at 4 days after inoculation (DAI), and had them only rarely at 7 DAI. In LS-89 infected with K60-509, ALs were rarely observed in parenchyma cells adjacent to vessels at 4 DAI, and while they were present at 7 DAI, they were thinner than ALs induced by K60. The bacterial density in LS-89 stems infected with K60-509 was lower than in stems infected with K60 at 4 DAI, but the strains reached similar population sizes by 7 DAI, showing the pectinase-deficient mutant colonized resistant stems more slowly than did the wild-type strain. Vessels infected with K60-509 contained fewer EDMs at 7 DAI than were observed at either 4 or 7 DAI in vessels colonized by K60, although bacterial density in the xylem tissues containing K60-509 at 7 DAI was about the same as in the xylem tissues containing K60 at 4 DAI. Neither the wild-type strain nor the pectinase-deficient mutant induced these histopathological changes on susceptible cultivar Ponderosa. These results indicate that R. solanacearum pectinases play some role in eliciting histopathological changes in LS-89, likely by releasing OGAs that trigger plant structural defences.     

Deciphering the route of Ralstonia solanacearum colonization in Arabidopsis thaliana roots during a compatible interaction: focus at the plant cell wall

The compatible interaction between the model plant, Arabidopsis thaliana, and the GMI1000 strain of the phytopathogenic bacterium, Ralstonia solanacearum, was investigated in an in vitro pathosystem. We describe the progression of the bacteria in the root from penetration at the root surface to the xylem vessels and the cell type-specific, cell wall-associated modifications that accompanies bacterial colonization. Within 6?days post inoculation, R. solanacearum provoked a rapid plasmolysis of the epidermal, cortical, and endodermal cells, including those not directly in contact with the bacteria. Plasmolysis was accompanied by a global degradation of pectic homogalacturonanes as shown by the loss of JIM7 and JIM5 antibody signal in the cell wall of these cell types. As indicated by immunolabeling with Rsol-I antibodies that specifically recognize R. solanacearum, the bacteria progresses through the root in a highly directed, centripetal manner to the xylem poles, without extensive multiplication in the intercellular spaces along its path. Entry into the vascular cylinder was facilitated by cell collapse of the two pericycle cells located at the xylem poles. Once the bacteria reached the xylem vessels, they multiplied abundantly and moved from vessel to vessel by digesting the pit membrane between adjacent vessels. The degradation of the secondary walls of xylem vessels was not a prerequisite for vessel colonization as LM10 antibodies strongly labeled xylem cell walls, even at very late stages in disease development. Finally, the capacity of R. solanacearum to specifically degrade certain cell wall components and not others could be correlated with the arsenal of cell wall hydrolytic enzymes identified in the bacterial genome.     

A xylem sap retrieval pathway in rice leaf blades: evidence of a role for endocytosis?

The structure and transport properties of pit membranes at the interface between the metaxylem and xylem parenchyma cells and the possible role of these pit membranes in solute transfer to the phloem were investigated. Electron microscopy revealed a fibrillar, almost tubular matrix within the pit membrane structure between the xylem vessels and xylem parenchyma of leaf blade bundles in rice (Oryza sativa). These pits are involved primarily with regulating water flux to the surrounding xylem parenchyma cells. Vascular parenchyma cells contain large mitochondrial populations, numerous dictyosomes, endomembrane complexes, and vesicles in close proximity to the pit membrane. Taken collectively, this suggests that endocytosis may occur at this interface. A weak solution of 5,6-carboxyfluorescein diacetate (5,6-CFDA) was applied to cut ends of leaves and, after a minimum of 30 min, the distribution of the fluorescent cleavage product, 5,6-carboxyfluorescein (5,6-CF), was observed using confocal microscopy. Cleavage of 5,6-CFDA occurred within the xylem parenchyma cells, and the non-polar 5,6-CF was then symplasmically transported to other parenchyma elements and ultimately, via numerous pore plasmodesmata, to adjacent thick-walled sieve tubes. Application of Lucifer Yellow, and, separately, Texas Red-labelled dextran (10 kDa) to the transpiration stream, confirmed that these membrane-impermeant probes could only have been offloaded from the xylem via the xylem vessel-xylem parenchyma pit membranes, suggesting endocytotic transmembrane transfer of these membrane-impermeant fluorophores. Accumulation within the thick-walled sieve tubes, but not in thin-walled sieve tubes, confirms the presence of a symplasmic phloem loading pathway, via pore plasmodesmata between xylem parenchyma and thick-walled sieve tubes, but not thin-walled sieve tubes.     

Histopathology of Susceptible and Resistant Capsicum annuum Cultivars Infected with Ralstonia solanacearum

The vascular colonisation of resistant and susceptible hot chilli (Capsicum annuum) cultivars by Ralstonia solanacearum was examined using transmission electron microscopy. Tap roots of artificially-inoculated plants, grown in sterilised soil were investigated to observe the morphological barriers involved in the restriction of bacterial spread. In the resistant cultivar, several responses induced in response to bacterial infection, were observed. First, a cell wall coating material developed together with swelling of the primary wall of the xylem vessels, limiting the bacterial spread. Second, formation of various types of vesicles in the vascular parenchyma cells, which enveloped the bacterial mass and also partly restricted the pathogen spread. Third, induction of hypersensitive reaction in the xylem vessels resulted in the distortion and lysis of the bacteria. In the susceptible cultivar, vascular coating, production of vesicle and induction of hypersensitive reaction were not observed and bacterial spread was not limited. Rapid vascular colonisation of the susceptible cultivar seemed to be generalised which resulted in the rapid wilting of affected plants. Other reactions involved in both resistant and susceptible cultivars include disorganisation of cytoplasm of parenchyma cells, disintegration of nuclei, and rupturing of xylem vessel walls. The restriction of pathogen spread associated with the resistance in C. annuum to bacterial wilt was mainly attributed to some induced, morphological and physical barriers.     

Infiltration of Pseudomonas putida cells, strain 48, into xylem vessels of cut Rosa cv. 'Sonia'

Pseudomonas putida cells were unable to pass the inter-vessel pit membranes of the xylem system of cut roses ( Rosa hybrida cv. 'Sonia'). It was further shown that (1) the number of bacteria which infiltrated into the xylem vessels decreased with increased distance between the cutting point and sampling point; (2) the number of bacteria which infiltrated into the open xylem vessels increased with time and with increasing numbers of pseudomonas cells; (3) only a minor part of the pseudomonas cells homogeneously suspended in the vase solution was able to infiltrate into the xylem vessels of the cut roses up to a distance from the cutting point of > 1 cm; and (4) even low levels of infiltrated pseudomonas cells could be demonstrated by measurements of the water conductivity of stem segments. More research is needed to reveal which mechanisms (e.g. gumnosis) might have contributed, directly or indirectly, to the prevention of further infiltration of bacterial particles into the cut open vascular system of the Rosa cultivar.     

Secretion of vascular coating components by xylem parenchyma cells of tomatoes infected withVerticillium albo-atrum

Summary Massive infusion of conidia ofVerticillium albo-atrum into the xylem of tomato induces a cell wall coating response in resistant and susceptible near-isolines. In the early stages two types of coating material develop in the xylem vessels. The first, designated type A, is formed in association with xylem parenchyma cells that lack secondary walls; the localized accumulation of type A coating in the in the adjacent intercellular spaces, primary walls (i.e., pit membranes) and vessels occurs in conjunction with localized development of apposition wall layers within the parenchyma cells. Type B coating is initially formed in association with xylem parenchyma cells with secondary walls; the localized accumulation of typeB coating in the adjacent intercellular spaces, primary walls (i.e., pit membranes) and vessels occurs in conjunction with development of protective layers within the parenchyma cells. Most vessels are surrounded by a number of parenchyma cells including both cell types; therefore, in most vessels the coatings are mixed in later stages of development (i.e.,> 48 hours). The formation of both types of coating is stopped by the application of L--aminooxy--phenylpropionate, a specific inhibitor of phenylpropanoid synthesis. Histochemically, type A coating resembles lignin and type B, suberin. The data suggest that the coating response is due, wholly or in part to hypersecretion and/or chemical modification of normal cell wall components, induced by the pathogen.     

Vascular defense responses in rice: peroxidase accumulation in xylem parenchyma cells and xylem wall thickening.

The rice bacterial blight pathogen Xanthomonas oryzae pv. oryzae is a vascular pathogen that elicits a defensive response through interaction with metabolically active rice cells. In leaves of 12-day-old rice seedlings, the exposed pit membrane separating the xylem lumen from the associated parenchyma cells allows contact with bacterial cells. During resistant responses, the xylem secondary walls thicken within 48 h and the pit diameter decreases, effectively reducing the area of pit membrane exposed for access by bacteria. In susceptible interactions and mock-inoculated controls, the xylem walls do not thicken within 48 h. Xylem secondary wall thickening is developmental and, in untreated 65-day-old rice plants, the size of the pit also is reduced. Activity and accumulation of a secreted cationic peroxidase, PO-C1, were previously shown to increase in xylem vessel walls and lumen. Peptide-specific antibodies and immunogold-labeling were used to demonstrate that PO-C1 is produced in the xylem parenchyma and secreted to the xylem lumen and walls. The timing of the accumulation is consistent with vessel secondary wall thickening. The PO-C1 gene is distinct but shares a high level of similarity with previously cloned pathogen-induced peroxidases in rice. PO-C1 gene expression was induced as early as 12 h during resistant interactions and peaked between 18 and 24 h after inoculation. Expression during susceptible interactions was lower than that observed in resistant interactions and was undetectable after infiltration with water, after mechanical wounding, or in mature leaves. These data are consistent with a role for vessel secondary wall thickening and peroxidase PO-C1 accumulation in the defense response in rice to X. oryzae pv. oryzae.     

Xylem structure and connectivity in grapevine (Vitis vinifera) shoots provides a passive mechanism for the spread of bacteria in grape plants

BACKGROUND AND AIMS: Bacterial leaf scorch occurring in a number of economically important plants is caused by the xylem-limited bacterium Xylella fastidiosa (Xf). In grapevine, Xf systemic infection causes Pierce's disease and is lethal. Traditional dogma is that Xf movement between vessels requires the digestion of inter-vessel pit membranes. However, Yersinia enterocolitica (Ye) (a bacterium found in animals) and fluorescent beads moved rapidly within grapevine xylem from stem into leaf lamina, suggesting open conduits consisting of long, branched xylem vessels for passive movement. This study builds on and expands previous observations on the nature of these conduits and how they affect Xf movement. METHODS: Air, latex paint and green fluorescence protein (GFP)-Xf were loaded into leaves and followed to confirm and identify these conduits. Leaf xylem anatomy was studied to determine the basis for the free and sometimes restricted movement of Ye, beads, air, paint and GFP-Xf into the lamina. KEY RESULTS: Reverse loading experiments demonstrated that long, branched xylem vessels occurred exclusively in primary xylem. They were observed in the stem for three internodes before diverging into mature leaves. However, this stem-leaf connection was an age-dependent character and was absent for the first 10-12 leaves basal to the apical meristem. Free movement in leaf blade xylem was cell-type specific with vessels facilitating movement in the body of the blade and tracheids near the leaf margin. Air, latex paint and GFP-Xf all moved about 50-60% of the leaf length. GFP-Xf was never observed close to the leaf margin. CONCLUSIONS: The open vessels of the primary xylem offered unimpeded long distance pathways bridging stem to leaves, possibly facilitating the spread of bacterial pathogens in planta. GFP-Xf never reached the leaf margins where scorching appeared, suggesting a signal targeting specific cells or a toxic build-up at hydathodes.     

Use of a green fluorescent strain for analysis of Xylella fastidiosa colonization of Vitis vinifera

Xylella fastidiosa causes Pierce's disease of grapevine as well as several other major agricultural diseases but is a benign endophyte in most host plants. X. fastidiosa colonizes the xylem vessels of host plants and is transmitted by xylem sap-feeding insect vectors. To understand better the pattern of host colonization and its relationship to disease, we engineered X. fastidiosa to express a green fluorescent protein (Gfp) constitutively and performed confocal laser-scanning microscopic analysis of colonization in a susceptible host, Vitis vinifera. In symptomatic leaves, the fraction of vessels colonized by X. fastidiosa was fivefold higher than in nearby asymptomatic leaves. The fraction of vessels completely blocked by X. fastidiosa colonies increased 40-fold in symptomatic leaves and was the feature of colonization most dramatically linked to symptoms. Therefore, the extent of vessel blockage by bacterial colonization is highly likely to be a crucial variable in symptom expression. Intriguingly, a high proportion (>80%) of colonized vessels were not blocked in infected leaves and instead had small colonies or solitary cells, suggesting that vessel blockage is not a colonization strategy employed by the pathogen but, rather, a by-product of endophytic colonization. We present evidence for X. fastidiosa movement through bordered pits to neighboring vessels and propose that vessel-to-vessel movement is a key colonization strategy whose failure results in vessel plugging and disease.     

Unravelling physiological signatures of tomato bacterial wilt and xylem metabolites exploited by Ralstonia solanacearum

The plant pathogen Ralstonia solanacearum uses plant resources to intensely proliferate in xylem vessels and provoke plant wilting. We combined automatic phenotyping and tissue/xylem quantitative metabolomics of infected tomato plants to decipher the dynamics of bacterial wilt. Daily acquisition of physiological parameters such as transpiration and growth were performed. Measurements allowed us to identify a tipping point in bacterial wilt dynamics. At this tipping point, the reached bacterial density brutally disrupts plant physiology and rapidly induces its death. We compared the metabolic and physiological signatures of the infection with drought stress, and found that similar changes occur. Quantitative dynamics of xylem content enabled us to identify glutamine (and asparagine) as primary resources R. solanacearum consumed during its colonization phase. An abundant production of putrescine was also observed during the infection process and was strongly correlated with in planta bacterial growth. Dynamic profiling of xylem metabolites confirmed that glutamine is the favoured substrate of R. solanacearum. On the other hand, a triple mutant strain unable to metabolize glucose, sucrose and fructose appears to be only weakly reduced for in planta growth and pathogenicity.     

DoesAcetobacter diazotrophicusLive and Move in the Xylem of Sugarcane Stems? Anatomical and Physiological Data

We have previously shown that the nitrogen-fixing endophyteof sugarcane,Acetobacter diazotrophicuslives in the sugar solutionin the intercellular-space apoplast of the stem cortex. Variousauthors have claimed that it inhabits the xylem apoplast. Thispossibility has been investigated in the clone Ja 60-5 and shownto be most unlikely for the following reasons: (1) an adequatecarbon source is lacking in the xylem sap, and cannot be suppliedfrom the intercellular-space apoplast of the cortex. Diffusionof solutes into and out of the vascular bundles is preventedby complete lignification and suberization of the bundle sheathcell walls except at the nodes. (2) Longitudinal movement ofparticles as large as bacteria is severely limited at the nodes.Vessel end walls were found in 90% of vessels at each node,and only 1% of open vessels extended through two nodes. Noneextended as far as three nodes. In addition to vessel end walls,vessel continuity at nodes was interrupted by living cells.Dye solution in the transpiration stream in metaxylem vesselsdid not pass through these living cells, but accumulated incrystals (sump formation) in the vessels below the node. Onlyin some protoxylem vessels and cavities did dye solution movethrough many nodes. It is likely that selection of sugarcaneclones such as Ja 60-5 for resistance to bacterial wilt diseaseshave selected for clones that have limited vessel continuity.(3) When culturedA. diazotrophicuswas introduced into the transpirationstream, the xylem parenchyma reacted by secreting a bright redpolymer which killed the bacteria and blocked the movement ofwater. We conclude that the xylem flow-apoplast of this cloneof sugarcane is an unsuitable habitat forA. diazotrophicusandthat additional habitats to those of the intercellular-spaceapoplast should be sought elsewhere. Acetobacter diazotrophicus; endophytic bacteria; nitrogen fixation; sugarcane; vessel end walls; xylem apoplast; xylem bacteria; xylem segmentation     

Plasmodesmata and pit development in secondary xylem elements

Developing pit membranes of secondary xylem elements in Drimys winteri, Fagus sylvatica, Quercus robur, Sorbus aucuparia, Tilia vulgaris and Trochodendron aralioides have been examined by transmission electron microscopy. Absence of plasmodesmata from the membranes of vessel elements and tracheids indicates that their pits develop independently of these structures. On the other hand, plasmodesmata are abundant in pit membranes between fibres, parenchyma cells, and combinations of these cell types in Fagus, Quercus and Tilia. In each case the plasmodesmata pass right through the developing pit membrane. In the case of Sorbus fibres, however, plasmodesmata were absent from the majority of pit membrane profiles seen in sections. Occasionally they were observed in large numbers associated with a swollen region on one side of the pit membrane between fibres and between fibres and parenchyma, radiating from a small area of the middle lamella. In the case of fibre to parenchyma pitting, this swelling was always found on the fibre side of the membrane, while on the other side a small number of plasmodesmata were present completing communication with the parenchyma cytoplasm. These observations are discussed with regard to the role of plasmodesmata in pit formation, and in the differentiation of the various cell types in secondary xylem. The significance their distribution may have for our understanding of xylem evolution is also discussed.     

The structure of xylem vessels in grapevine (Vitaceae) and a possible passive mechanism for the systemic spread of bacterial disease

Xylem-dwelling pathogens become systemic, suggesting that microorganisms move efficiently in the xylem. To better understand xylem pathways and how bacteria move within the xylem, vessel connectivity between stems and leaves of Vitis vinifera cv. Chardonnay and Muscadinia rotundifolia cv. Cowart was studied. Three methods were used: (1) the light-producing bacterium, Yersinia enterocolitica, (Ye) strain GY5232 was loaded into petioles and followed using X-ray film, (2) fluorescent beads were loaded and followed by microscopy, and (3) low-pressure air was pumped into leaves and extruded bubbles from cuts in submerged leaves were followed. Bacteria, beads, and air moved through long and branched xylem vessels from the petiole into the veins in leaves of both varieties. From the stem, bacteria and air traveled into primary and secondary veins of leaves one, two, and three nodes above the loading point of the bacteria or air. Particles and air could move unimpeded through single xylem vessels or multiple vessels (conduits) connected possibly through broken pit membranes from within the stem axis into leaf blades. Bacteria were also able to move long distances within minutes from stem to leaf passively without having to cross pit membranes. Such complex, open xylem conduits have not been well documented before; these findings will help elucidate mechanisms involved in the systemic spread of pathogens.     

The cytoskeleton facilitates a three-dimensional symplasmic continuum in the long-lived ray and axial parenchyma cells of angiosperm trees

The microtubule (MT), microfilament (MF) and myosin components of the cytoskeleton were studied in the long-lived ray and axial parenchyma cells of the secondary xylem (wood) and secondary phloem of two angiosperm trees, Aesculus hippocastanum L. (horse-chestnut) and Populus tremula L. x P. tremuloides Michx. (hybrid aspen), using indirect immunofluorescence localisation and transmission electron microscopy. MTs and MFs were bundled and oriented axially (parallel to the cell's long axis) within all parenchyma cell types after they had fully differentiated. Additionally, actin and myosin were immunolocalised at the thin-walled membranes of the pits, which linked cells in neighbouring files of both ray and axial parenchyma, and at the pits between axial and ray parenchyma cells themselves. Anti-callose antibody immunolocated the plasmodesmata at the pit membranes, and in the same pattern as that of anti-myosin. Ray cells are important symplasmic pathways between the xylem and the phloem throughout the life of trees. We hypothesise that the MT and MF components of the cytoskeleton in the ray and axial parenchyma cells are involved in the transport of materials within those cells, and, in association with the acto-myosin of plasmodesmata at pit fields, are also important in intercellular transport. Thus, the symplasmic coupling between ray cells, between axial parenchyma cells, and between axial parenchyma and ray cells represents an extensive three-dimensional communication pathway permeating the tree from the phloem through the cambium into the wood. We suggest that this cytoskeletal pathway has an important role in delivery of photosynthate, and mobilised reserves, to the actively dividing cambium, and in the movement of materials to sites of reserve deposition, principally within the wood. This pathway could also have an important role in co-ordinating developmental processes throughout the tree.     

Colonization of Maize and Rice Plants by Strain Bacillus megaterium C4

Bacillus megaterium C4, a nitrogen-fixing bacterium, was marked with the gfp gene. Maize and rice seedlings were inoculated with the, GFP-labeled B. megaterium C4 and then grown in gnotobiotic condition. Observation by confocal laser scanning microscope showed that the GFP-labeled bacterial cells infected the maize roots through the cracks formed at the lateral root junctions and then penetrated into cortex, xylem, and pith, and that the bacteria migrated slowly from roots to stems and leaves. The bacteria were mainly located in the intercellular spaces, although a few bacterial cells were also present within the xylem vessels, root hair cells, epidermis, cortical parenchyma, and pith cells. In addition, microscopic observation also revealed clearly that the root tip in the zone of elongation and differentiation and the junction between the primary and the lateral roots were the two sites for the bacteria entry into rice root. Therefore, we conclude that this Gram-positive nitrogen-fixer has a colonization pattern similar to those of many Gram-negative diazotrophs, such as Azospirillun brasilense Yu62 and Azoarcus sp. As far as we know, this is the first detailed report of the colonization pattern for Gram-positive diazotrophic Bacillus.     

Comparison of structural damage caused by Russian wheat aphid (Diuraphis noxia) and Bird cherry-oat aphid (Rhopalosiphum padi) in a susceptible barley cultivar, Hordeum vulgare cv. Clipper

The Russian wheat aphid (RWA, ( Diuraphis noxia ) and the Bird cherry-oat aphid (BCA, ( Rhopalosiphum padi L.) cause severe damage to grain crops, including barley. An investigation of the effects of these aphids on a susceptible cultivar revealed that BCA-infested barley plants remained healthy looking for 2 weeks after feeding commenced. In contrast, signs of stress and damage, including chlorosis and leaf necrosis were evident in RWA-infested plants. Our study suggests that damage to the vascular tissue because of sustained feeding by BCA was not as extensive as that caused by RWA. In addition, there is a marked difference in the salivary secretion pattern within xylem elements punctured by aphids tapping the xylem for water. RWA deposit electron-dense, amorphous to smooth saliva, which completely encases the inner walls of affected elements, and saliva encases pit membranes between xylem elements, and between xylem vessels and xylem parenchyma. Xylem tapped by BCA contained more granular saliva, which apparently does not occlude vessel wall apertures or the pit membranes to the same extent, as was observed with RWA. Damage to phloem tissue, including phloem parenchyma elements, sieve tube–companion cell (CC–ST) complexes as well as thick-walled ST, was extensive. Plasmodesmata between phloem parenchyma elements as well as pore plasmodesmata between the CC and ST were occluded by callose. We conclude that severe, perhaps permanent damage to conducting elements in RWA-infested leaves may be responsible for the detrimental chlorosis and necrosis symptoms. These symptoms are absent in BCA-infested plants.     

Agrobacterium tumehciens After in vivo Inoculation of Potato (Sohnum tuberosum L.) (Scanning Electron Microscopy)

Five weeks after the in vivo inoculation of potatoes ( Solanum tuberosum L.) with Agrobacterium. tumefaciens strain B6S3, bacteria were found in the non-differentiated cells of tumors (formed from xylem parenchyma or other living cells), in xylem cells at the site of inoculation, as well as in xylem cells of the adjacent stem.
Bacteria were attached by fibrillar aggregates to the tumor cell walls. They were also attached to a fibrillar mass which arose from agrobacteria connected to this mass in the tumor. Agrobacteria, singly or in pairs, were attached to an electron dense formation (possibly bacterial extracellular polysaccharides) found both inside the xylem cells of the stem adjacent to the tumor and at the site of inoculation. Some A. tumefaciens cells were attached by means of a pedestal-like structure at the inoculation site.
A possible function of the different means of attachment of A. tumefaciens in both nontransformed plant cells and tumors is discussed.     

Real Time Live Imaging of Phytopathogenic Bacteria Xanthomonas campestris pv. campestris MAFF106712 in ‘Plant Sweet Home’

Xanthomonas is one of the most widespread phytobacteria, causing diseases on a variety of agricultural plants. To develop novel control techniques, knowledge of bacterial behavior inside plant cells is essential. Xanthomonas campestris pv. campestris, a vascular pathogen, is the causal agent of black rot on leaves of Brassicaceae, including Arabidopsis thaliana. Among the X. campestris pv. campestris stocks in the MAFF collection, we selected XccMAFF106712 as a model compatible pathogen for the A. thaliana reference ecotype Columbia (Col-0). Using modified green fluorescent protein (AcGFP) as a reporter, we observed real time XccMAFF106712 colonization in planta with confocal microscopy. AcGFP-expressing bacteria colonized the inside of epidermal cells and the apoplast, as well as the xylem vessels of the vasculature. In the case of the type III mutant, bacteria colonization was never detected in the xylem vessel or apoplast, though they freely enter the xylem vessel through the wound. After 9 days post inoculation with XccMAFF106712, the xylem vessel became filled with bacterial aggregates. This suggests that Xcc colonization can be divided into main four steps, (1) movement in the xylem vessel, (2) movement to the next cell, (3) adhesion to the host plant cells, and (4) formation of bacterial aggregates. The type III mutant abolished at least steps (1) and (2). Better understanding of Xcc colonization is essential for development of novel control techniques for black rot.