Isolation and characterization of the membrane envelope enclosing the bacteroids in soybean root nodules

The membrane envelope enclosing the bacteroids in soybean root nodules is shown by ultrastructural and biochemical studies to be derived from, and to retain the characteristics of, the host cell plasma membrane. During the early stages of the infection process, which occurs through an invagination, Rhizobium becomes surrounded by the host cell wall and plasma membrane, forming the infection thread. The cell wall of the infection thread is degraded by cellulolytic enzyme(s), leaving behind the enclosed plasma membrane, the membrane envelope. Cellulase activity in young nodules increases two- to threefold as compared to uninfected roots, and this activity is localized in the cell wall matrix of the infection threads. Membrane envelopes were isolated by first preparing bacteroids enclosed in the envelopes on a discontinuous sucrose gradient followed by passage through a hypodermic needle, which released the bacteroids from the membranes. This membrane then sedimented at the interface of 34--45% sucrose (mean density of 1.14 g/cm3). Membranes were characterized by phosphotungstic acid (PTA)-chromic acid staining. ATPase activity, and localization, sensitivity to nonionic detergent Nonidet P-40 (NP-40) and sodium dodecyl sulfate (SDS) gel electrophoresis. These analyses revealed a close similarity between plasma membrane and the membrane envelope. Incorporation of radioactive amino acids into the membrane envelope proteins was sensitive to cycloheximide, suggesting that the biosynthesis of these proteins is primarily under host-cell control. No immunoreactive material to leghemoglobin antibodies was found inside or associated with the isolated bacteroids enclosed in the membrane envelope, and its location is confined to the host cell cytoplasmic matrix.     

Ultrastructure of infection-thread development during the infection of soybean by Rhizobium japonicum

The location and topography of infection sites in soybean (Glycine max (L.) Merr.) root hairs spot-inoculated with Rhizobium japonicum have been studied at the ultrastructural level. Infections commonly developed at sites created when the induced deformation of an emerging root hair caused a portion of the root-hair cell wall to press against an adjacent epidermal cell, entrapping rhizobia within the pocket between the two host cells. Infections were initiated by bacteria which became embedded in the mucigel in the enclosed groove. Infection-thread formation in soybean appears to involve degradation of mucigel material and localized disruption of the outer layer of the folded hair cell wall by one or more entrapped rhizobia. Rhizobia at the site of penetration are separated from the host cytoplasm by the host plasmalemma and by a layer of wall material that appears similar or identical to the normal inner layer of the hair cell wall. Proliferation of the bacteria results in an irregular, wall-bound sac near the site of penetration. Tubular infection threads, bounded by wall material of the same appearance as that surrounding the sac, emerge from the sac to carry rhizobia roughly single-file into the hair cell. Growing regions of the infection sac or thread are surrounded by host cytoplasm with high concentrations of organelles associated with synthesis and deposition of membrane and cell-wall material. The threads follow a highly irregular path toward the base of the hair cell. Threads commonly run along the base of the hair cell for some distance, and may branch and penetrate into subjacent cortical cells at several points in a manner analagous to the initial penetration of the root hair.     

拟菌体包囊膜的动态变化和宿主细胞与细菌的相互关系

本文初次报道紫云英根瘤的超微结构。用根瘤中段的中心组织作实验材料,以显示受根瘤菌侵染的宿主细胞的一般结构。细菌借助于侵入线进入宿主细胞,发育成拟菌体,为包囊膜所裹。一个包囊膜内一般只有一个拟菌体。包囊膜可以与细胞质内的囊泡和小液泡融合而扩增,导致膜对拟菌体的包裹由紧密到疏松的变化。包囊膜和拟菌体表面都有突起,两者的突起相对接触和融合。对拟菌体包囊膜的动态变化与衰老的关系以及宿主细胞和拟菌体之间物质交换的关系进行了讨论。作者指出包囊膜的扩增和电子透明区域的存在,是拟菌体发育成熟的一个阶段,包囊膜和拟菌体通过互相突起、融合沟通的结构,可能是宿主细胞和细菌之间物质交换功能的一种表现。     

Development of the bacteroid in the root nodule of barrel medic (Medicago tribuloides Desr.) and subterraneum clover (Trifolium subterraneum L.)

Summary The development of the bacteriod is traced from thin sections of slices of nodules fixed in KMnO₄ and OsO₄. While in the infection thread the Rhizobium cell has the ultrastructure characteristic of gram-negative bacteria, with two unit membranes bounding a granular cytoplasm containing dense bodies, a nucleoid area and inclusion granules. A 10–12 fold increase in size, a loss of inclusion granules and the formation of a membrane envelope around each Rhizobium cell follows the dispersal of the rhizobia through the host cytoplasm. As the bacteriods develop there is a loss of fibrillar material from the nucleoid region and changes occur in the distribution of ribosome-like particles in both host and bacterial cells. When fully differentiated and presumably fixing nitrogen the bacteroids from the red zone of subterraneum clover nodules but not barrel medic have a well developed intra-cytoplasmic membrane system.     

The Ultrastructural Analysis on the Relationship between Rhizobia and Host Cells

By means of electron microscopy, the ultra-thin sections of the effective nodules of Glycine max, Pisum sativum, Phaseolus vulgaris and Sesbania cannabia were investigated. In this paper the multiple forms of the infection thread, the various structual changes in capsule and cell wall of rhizobia before and after their releasing into the cytoplasm of the host cell, the rhizobia entering into the vacuoles of the host cells and the bacteriod formation in the vacuoles were observed. Accordingly, the possibility of two different ways of the enclosing membrane formation of rhizobia was observed. The relationship between the structure and function of the rhizobia and host cells during nodulation is also discussed.     

The structure of infection threads,bacteria and bacteroids in pea and clover root nodules

Summary The bacteria and infection threads of the pea root nodule were examined by light and electron microscopy. The bacteria in the infection thread are enclosed in a microcapsule. This capsule disappears when the bacterium is released into the host cytoplasm. The membrane envelope which surrounds the bacteria in the host cell is shown to be derived from the plant cell membrane. The infection of the host cell is by means of a process akin to pinocytosis and the bacteria are confined to vacuoles in the host cytoplasm. As each membrane envelope contains only one bacterium, the envelopes must divide with the bacteria. The bacteria increase 40fold in volume from the infection thread to the stage of the mature bacteroid. The mature infected host cell contains few organelles. The mitochondria become confined to the periphery of the cell. Differences of membrane structure in gram negative bacteria found by other workers have been attributed to fixation artifacts.     

Early development ofRhizobium-induced root nodules ofParasponia rigida. I. Infection and early nodule initiation

Summary The first of two major steps in the infection process in roots ofParasponia rigida (Ulmaceae) following inoculation byRhizobium strain RP501 involves the invasion ofRhizobium into the intercellular space system of the root cortex. The earliest sign of root nodule initiation is the presence of clumps of multicellular root hairs (MCRH), a response apparently unique amongRhizobium-root associations. At the same time or shortly after MCRH are first visible, cell divisions are initiated in the outer root cortex of the host plant, always subjacent to the MCRH. No infection threads were observed in root hairs or cortical cells in early stages. Rhizobial entry through the epidermis and into the root cortex was shown to occur via intercellular invasion at the bases of MCRH. The second major step in the infection process is the actual infectionper se of host cells by the rhizobia and formation of typical intracellular infection threads with host cell accommodation. This infection step is probably the beginning of the truly symbiotic relationship in these nodules. Rhizobial invasion and infection are accompanied by host cortical cell divisions which result in a callus-like mass of cortical cells. In addition to infection thread formation in some of these host cortical cells, another type of rhizobial proliferation was observed in which large accumulations of rhizobia in intercellular spaces are associated with host cell wall distortion, deposition of electron-dense material in the walls, and occasional deleterious effects on host cell cytoplasm.     

Structure of nitrogen-fixing nodules formed by Rhizobium on roots of Parasponia andersonii Planch.

The structure of nitrogen-fixing nodules produced by Rhizobium infection of the non-legume Parasponia andersonii was examined by light and electron (both SEM and TEM) microscopy. Comparisons were made with the nodules previously described on P. rugosa. Like the nodules on different non-legumes formed by other types of endophytes, the Rhizobium nodules on Parasponia resembled modified roots by having a central vascular bundle surrounded by an endophyte-infected zone. The intimate association between the Rhizobium and the host nodule cell was compared with the Rhizobium association found in legumes. The rhizobia were not released from the infection thread as happens in the legume. The infection thread, which propagates the Rhizobium infection to new cells, was transformed within a nodule cell from a darkly stained (light microscopy) or very electron-dense (TEM) structure to a number of thread types. The walls of the threads varied greatly in thickness and often the thread structures were without rigid walls and were only enclosed by a plasma membrane. If the rhizobia are transformed into bacteroids, as in the legumes, it would have to occur when the threads had reached their mature size, when bacterial division had ceased. Nitrogen fixation was considered to occur in all thread types.     

Structure and growth of infection threads in the legume symbiosis with Rhizobium leguminosarum

Specific antibodies and enzyme–gold probes were used to study the structure and development of infection threads in nodules induced by Rhizobium leguminosarum on the roots of Vicia, Pisum and Phaseolus. In Pisum nodules, the tubular infection thread wall contains polysaccharides antigenically similar to those of the cell wall, including cellulose, xyloglucan, methyl-esterified pectin and non-esterified pectin, but none of these wall components is present around the infection droplet structures from which bacteria are internalized by plant plasma membrane. As reported previously for pea nodules, the luminal matrix of infection threads and infection droplets contains a plant glycoprotein; this glycoprotein is also secreted by infected and uninfected cortical cells of a Vicia root at the earliest stages of nodule initiation. Synthesis of a transcellular infection thread apparently involves reorganized deposition of components normally targeted to the cell wall, and infection thread growth is orientated anticlinally through the outer cortex in the same plane observed for the deposition of new cell walls following mitosis. Both the development of infection threads in the outer cortex and the initiation of cell division in the inner cortex are preceded by a similar process of cell reactivation involving centralization of nuclei and the development of anticlinal transvacuolar strands. It is therefore suggested that the two Rhizobium-induced processes of infection thread growth and cortical cell division may both be consequences of a similar plant cell response in the inner and outer root cortex, respectively. Phaseolus nodules contained only short intracellular infection structures which terminated within individual cells and contained no luminal matrix material. The differences in infection thread structure between Pisum and Phaseolus nodules may reflect differences in ontogeny between “indeterminate” and “determinate” nodule meristems.     

Fine structure of nitrogen-fixing leguminous root nodules from the Canadian Arctic

Effective (nitrogen-fixing) root nodules of Oxytropis maydelliana Trautv., O. arctobia Bunge and Astragulus alpinus L. were collected in the high Arctic tundra and subsequently processed for structural studies. The cylindrically-shaped perennial nodules consisted of the following tissues: nodule cortex, nodule meristem, nodular vascular bundles, an active central region with uninfected and infected cells at various stages of development, and a proximal region of senescent cells. The active central region was dark red-coloured due to the presence of the pigment leghemoglobin. The host cells became infected by the growth of infection threads into cells recently derived from the nodule meristem and the subsequent endocytotic release of rhizobia from unwalled membrane-bound regions of the infection thread. The host plasma membrane adjacent to the unwalled regions of infection thread gave rise to the peribacteroid membrane which surrounded the released bacteria. Thus, nodule development and the basic tissue arrangement of the arctic nodules was similar to that of cylindrically-shaped nodules formed on temperate species of legumes.
The arctic legume nodules are unique in having large numbers of lipid droplets present in the cytoplasm of the nodule cortex and uninfected cells of the central active region. Newly infected cells also have lipid droplets. More developed infected cells lack lipid droplets but often contain amyloplasts. Mature differentiated bacteria were spherically-shaped and contained electron-dense inclusions. Electron-dense material was also present in vesicles formed from dilated endoplasmic reticulum and in the peribacteroid space. The lipid droplets present in the host cytoplasm of the nodule cortex and uninfected cells of the central tissue may be storage products which are used to support nitrogen-fixation in nodules growing under cool temperatures of this harsh environment.     

Plant Cell Wall Remodelling in the Rhizobium–Legume Symbiosis

Colonization of host cells by rhizobium bacteria involves the progressive remodelling of the plant–microbial interface. Following induction of nodulation genes by legume-derived flavonoid signals, rhizobium secretes Nod-factors (lipochitin oligosaccharides) that cause root hair deformations by perturbing the growth of the plant cell wall. The infection thread arises as a tubular ingrowth bounded by plant cell wall. This serves as a conduit for colonizing bacterial cells that grow and divide in its lumen. The transcellular orientation of thread growth is controlled by the cytoskeleton and is coupled to cell cycle reactivation and cell division processes. In response to rhizobium infection, host cells synthesize several new components (early nodulins) that modify the properties of the cell wall and extracellular matrix. Root nodule extensins are a legume-specific family of hydroxyproline-rich glycoproteins targeted into the lumen of the infection thread. They have alternating extensin and arabinogalactan (AGP) glycosylation motifs. The structural characteristics of these glycoproteins suggest that they may serve to regulate fluid-to-solid transitions in the extracellular matrix. Extensibility of the infection thread is apparently controlled by peroxide-driven protein cross-linking and perhaps also by modification of the pectic matrix. Endocytosis of rhizobia from unwalled infection droplets into the host cell cytoplasm depends on physical contact between glycocalyx components of the plant and bacterial membrane surfaces. As endosymbionts, bacteroids remain enclosed within a plant-derived membrane that is topologically equivalent to the plasma membrane. This membrane acquires specialist functions that regulate metabolite exchanges between bacterial cells and the host cytoplasm. Ultimately, however, the fate of the symbiosome is to become a lysosome, causing the eventual senescence of the symbiotic interaction.     

Effects of Boron on Rhizobium-Legume Cell-Surface Interactions and Nodule Development

Boron (B) is an essential micronutrient for the development of nitrogen-fixing root nodules in pea (Pisum sativum). By using monoclonal antibodies that recognize specific glycoconjugate components implicated in legume root-nodule development, we investigated the effects of low B on the formation of infection threads and the colonization of pea nodules by Rhizobium leguminosarum bv viciae. In B-deficient nodules the proportion of infected host cells was much lower than in nodules from plants supplied with normal quantities of B. Moreover, the host cells often developed enlarged and abnormally shaped infection threads that frequently burst, releasing bacteria into damaged host cells. There was also an over-production of plant matrix material in which the rhizobial cells were embedded during their progression through the infection thread. Furthermore, in a series of in vitro binding studies, we demonstrated that the presence of B can change the affinity with which the bacterial cell surface interacts with the peribacteroid membrane glycocalyx relative to its interaction with intercellular plant matrix glycoprotein. From these observations we suggest that B plays an important role in mediating cell-surface interactions that lead to endocytosis of rhizobia by host cells and hence to the correct establishment of the symbiosis between pea and Rhizobium.     

Infection and invasion of roots by symbiotic, nitrogen-fixing rhizobia during nodulation of temperate legumes.

Bacteria belonging to the genera Rhizobium, Mesorhizobium, Sinorhizobium, Bradyrhizobium, and Azorhizobium (collectively referred to as rhizobia) grow in the soil as free-living organisms but can also live as nitrogen-fixing symbionts inside root nodule cells of legume plants. The interactions between several rhizobial species and their host plants have become models for this type of nitrogen-fixing symbiosis. Temperate legumes such as alfalfa, pea, and vetch form indeterminate nodules that arise from root inner and middle cortical cells and grow out from the root via a persistent meristem. During the formation of functional indeterminate nodules, symbiotic bacteria must gain access to the interior of the host root. To get from the outside to the inside, rhizobia grow and divide in tubules called infection threads, which are composite structures derived from the two symbiotic partners. This review focuses on symbiotic infection and invasion during the formation of indeterminate nodules. It summarizes root hair growth, how root hair growth is influenced by rhizobial signaling molecules, infection of root hairs, infection thread extension down root hairs, infection thread growth into root tissue, and the plant and bacterial contributions necessary for infection thread formation and growth. The review also summarizes recent advances concerning the growth dynamics of rhizobial populations in infection threads.     

银合欢根瘤细胞的光学显微镜和电子显微镜研究

银合欢接种根瘤菌形成根瘤后,应用光镜和电镜技术观察。银合欢根瘤由分生组织细胞、皮层组织细胞、维管束系统和侵染细胞区域四个不同部分组成。根瘤菌借助于侵染线侵染细胞,释放进入宿主细胞质中,转变成固氮类菌体。最初每个包被膜内只含单独的类菌体,随后较老的侵染细胞中,每个包被膜内含有一个以上的类菌体。因此,成熟根瘤的侵染细胞可见有2~5个类菌体群集包被膜里,并且明显地累积PHB物质,显示电子染色透明颗粒。本文还讨论了上述变化的意义与银合欢根瘤细胞结构和功能的关系。     

Ricerche al Microscopio Elettronico sui Tubercoli Radicali di Alcune Leguminose

Abstract

Electron microscope studies on root nodules of some leguminous plants. — From this study of ultrathin sections of root nodules of Pea, Bean and Kidney-bean plants, it has been possible to recognize the infrastructural changes which occur during the development of the root nodules, both in the special cells (containing Rhizobia) and in the intermediary cells (free of Rhizobia). With regard to the symbiotic bacteria it has been possible to ascertain that their penetration into root nodules occurs by means of an infection's thread (delimited by its own wall), which contains numerous Rhizobia dipped in an abundant mucilage, with which they, at the beginning, are released into the host plant's cells. The Rhizobia appear enveloped by three membranes, namely a thin citoplasmic membrane, a cell wall, and a « membrane envelope », this last looking at the beginning rather detached from bacterial cell, by the presence of mucillaginous substances which afterward become less and less reduced. The membrane envelope, which is common for several bacteria in the kidney-bean plants, surrounds instead a single bacterium in the pea and in the bean plants. The importance of this membrane seems to rely on the fact that, according to some Authors, it would be formed around the bactetia which are active in nitrogen fixation. Moreover, it has been possible to find out that, among the varous Leguminous plants studied, there are remarkable differences in the morphology of the bacteria as well as in their modifications during the evolution to bacteroid stage.     

The origin of the membrane envelope surrounding the bacteria and bacteroids and the presence of glycogen in clover root nodules

Summary Thin sections of clover nodules were examined by electron microscopy. The emergence of the bacteria from the infection thread was found to occur by a process of phagocytosis. No evidence was found, using glutar-aldehyde-osmium as a fixative, that there is any connection between the membrane envelope and the endoplasmic reticulum.Electron dense granules, previously observed in clover nodule bacteria, were identified as glycogen granules. These glycogen granules accumulated in bacteria and bacteroids in some ineffective nodules.     

Infection and Invasion of Roots by Symbiotic, Nitrogen-Fixing Rhizobia during Nodulation of Temperate Legumes

Bacteria belonging to the genera Rhizobium, Mesorhizobium, Sinorhizobium, Bradyrhizobium, and Azorhizobium (collectively referred to as rhizobia) grow in the soil as free-living organisms but can also live as nitrogen-fixing symbionts inside root nodule cells of legume plants. The interactions between several rhizobial species and their host plants have become models for this type of nitrogen-fixing symbiosis. Temperate legumes such as alfalfa, pea, and vetch form indeterminate nodules that arise from root inner and middle cortical cells and grow out from the root via a persistent meristem. During the formation of functional indeterminate nodules, symbiotic bacteria must gain access to the interior of the host root. To get from the outside to the inside, rhizobia grow and divide in tubules called infection threads, which are composite structures derived from the two symbiotic partners. This review focuses on symbiotic infection and invasion during the formation of indeterminate nodules. It summarizes root hair growth, how root hair growth is influenced by rhizobial signaling molecules, infection of root hairs, infection thread extension down root hairs, infection thread growth into root tissue, and the plant and bacterial contributions necessary for infection thread formation and growth. The review also summarizes recent advances concerning the growth dynamics of rhizobial populations in infection threads.     

Sequential Analysis of the Organogenesis of Lucerne (Medicago sativa) Root Nodules Using Symbiotically-Defective Mutants of Rhizobium meliloti

Legume root-nodules are differentiated organs composed of peripheral tissue containing vascular bundles, and a central tissue in which are located the nitrogen-fixing bacteroids. The morphogenesis of these eukaryotic organs is induced by a prokaryotic organism, Rhizobium , which is amenable to genetic analysis. Inoculation of lucerne seedlings with leucine-requiring (Leu⁻) mutants of R. meliloti resulted in the formation of ineffective nodules. In these nodules, bacteria were not released from the infection threads into the host cytoplasm. When urea was provided as a nitrogen source to compensate for the defect in nitrogen fixation, the nodules became anatomically similar to those of effective nodules induced by the wild-type strain. The fact that these nodules were induced by bacteria which remained sequestered in infection threads indicates that nodule morphogenesis can be triggered from a distance. We hypothesize the existence of a bacterial nodule organogenesis-inducing principle (NOIP) which can cross the plant cell wall and plasmalemma.
In nitrogen-fixing nodules the central tissue exhibited a ploidy gradient, while in ineffective Leu⁻ nodules it was found to be monosomatic. The initiation of nodule formation is therefore independent of polyploidy. Supplying the defective plant-bacterial system with l -leucine or one of its precursors, α-ketoisovalerate or α-ketoisocaproate, caused the release of rhizobia into the plant cytoplasm and a restoration of nitrogen fixation. In the central tissue infected cells were polyploid and enlarged, and uninfected cells remained small and contained small nuclei. Therefore induction of differentiation of the central tissue requires the presence of bacteria in the cytoplasm. We hypothesize the role of a bacterial central tissue differentiation inducing principle (CTDIP) which cannot pass from cell to cell.     

The development and structure of root nodules on bambara groundnut [Voandzeia (Vigna)subterranea]

The infection of Vigna subterranea (formerly Voandzeia subterranea) by Bradyrhizobium strain MAO 113 (isolated from V. subterranea) was examined by light and transmission electron microscopy. Bacteria accumulated on the epidermis close to root hairs, and subsequently entered the latter via infection threads. Most of the steps involved in nodule formation were generally characteristic of determinate nodules, such as those which form on the closely related V. radiata. For example, nodule meristems were induced beneath the root epidermis adjacent to infected root hairs, but prior to infection of the meristem by rhizobia. Moreover, after the infection of some of the meristematic cells by the infection threads, and the release of the rhizobia into membrane-bound vesicles, the infection process ceased and dissemination of the rhizobia was by division of already-infected host cells. However, there were some aspects of this process in V. subterranea which have been more commonly described in indeterminate nodules. These include long infection threads entering a number of cells within the meristems simultaneously and a matrix within infection threads which was strongly labelled with immunogold monoclonal antibodies, MAC236 and MAC265, which recognize epitopes on an intercellular glycoprotein. The MAC236 and MAC265 antibodies also recognized material in the unwalled infection droplets surrounding bacteria which were newly-released from the infection threads. The amount of labelling shown was more characteristic of the long infection threads seen in indeterminate nodules such as pea (Pisum sativum) and Neptunia plena. The structure of mature V. subterranea nodules was similar to that described for other determinate nodules such as Glycine max, Vigna unguiculata and V.radiata, i.e. they were spherical and the infected zone consisted of both infected and uninfected cells. Surrounding the infected tissue was an inner cortex of uninfected cell layers containing the putative components of an oxygen diffusion barrier (including glycoprotein-occluded intercellular spaces), and an outer cortex with cells containing calcium oxalate crystals.     

The development and structure of root nodules on bambara groundnut [Voandzeia (Vigna)subterranea]

The infection of Vigna subterranea (formerly Voandzeia subterranea) by Bradyrhizobium strain MAO 113 (isolated from V. subterranea) was examined by light and transmission electron microscopy. Bacteria accumulated on the epidermis close to root hairs, and subsequently entered the latter via infection threads. Most of the steps involved in nodule formation were generally characteristic of determinate nodules, such as those which form on the closely related V. radiata. For example, nodule meristems were induced beneath the root epidermis adjacent to infected root hairs, but prior to infection of the meristem by rhizobia. Moreover, after the infection of some of the meristematic cells by the infection threads, and the release of the rhizobia into membrane-bound vesicles, the infection process ceased and dissemination of the rhizobia was by division of already-infected host cells. However, there were some aspects of this process in V. subterranea which have been more commonly described in indeterminate nodules. These include long infection threads entering a number of cells within the meristems simultaneously and a matrix within infection threads which was strongly labelled with immunogold monoclonal antibodies, MAC236 and MAC265, which recognize epitopes on an intercellular glycoprotein. The MAC236 and MAC265 antibodies also recognized material in the unwalled infection droplets surrounding bacteria which were newly-released from the infection threads. The amount of labelling shown was more characteristic of the long infection threads seen in indeterminate nodules such as pea (Pisum sativum) and Neptunia plena. The structure of mature V. subterranea nodules was similar to that described for other determinate nodules such as Glycine max, Vigna unguiculata and V.radiata, i.e. they were spherical and the infected zone consisted of both infected and uninfected cells. Surrounding the infected tissue was an inner cortex of uninfected cell layers containing the putative components of an oxygen diffusion barrier (including glycoprotein-occluded intercellular spaces), and an outer cortex with cells containing calcium oxalate crystals.