Chromatin organization in Entamoeba histolytica

The chromatin structure of Entamoeba histolytica was investigated. It was found that this protozoan organizes its chromatin in nucleosome-like particles 10 nm in diameter, but digestion of the chromatin with micrococcal nuclease did not render a regularly spaced DNA ladder in agarose gels. Southern blot analysis of the products of Entamoeba chromatin digestion using total amebic DNA and a non-transcribed repetitive sequence produced a banding pattern characteristic of eukaryotic chromatin with a repetitive size of approximately 130 bp. Conversely, hybridization with two active gene probes, actin and ribosomal RNA, showed that these sequences are not part of the chromatin organized in nucleosomes. It was also found that the basic nuclear proteins differ from histones of higher eukaryotes in electrophoretic mobility. Screening of an E. histolytica HM1-IMSS genomic library with Saccharomyces cerevisiae H3 and H4 genes and attempts to amplify E. histolytica sequences, homologous to these yeast histone genes, gave negative results suggesting that the Entamoeba proteins involved in chromatin organization are not typical histones.

Mapping trajectories of Pgp-1 membrane protein patches on surfaces of motile fibroblasts reveals a distinct boundary separating capping on the lamella and forward transport on the retracting tail

Patches of aggregated membrane proteins on motile fibroblasts are transported from the surfaces of the leading lamella to a site just ahead of the nucleus in the phenomenon known as capping. A major cell surface glycoprotein, Pgp-1 (GP80), was tagged with a monoclonal IgG and then aggregated with fluorescent secondary antibodies. Correlated digitized fluorescence and phase-contrast microscopy were used to map the trajectories of fluorescent Pgp-1 patches located in various regions of the cell surface. The response of patches located in lamellar and nonlamellar regions to spontaneous retraction of the trailing cell margin, or tail was examined in detail. During capping, Pgp-1 patches accumulated at a morphologically distinct site on the cell surface, the ‘null border’, corresponding to the boundary between lamelloplasm and endoplasm and the posterior edge of the dorsal cortical F-actin sheath. Posterior to this site, gradual forward movement of patches accompanied the gradual narrowing phase of the trailing edge retraction that occurs prior to abrupt detachment of the tail, but patches did not actually accumulate at the null border. The rate of forward patch movement was generally greater at positions further behind the boundary. Patch movement correlated approximately with forward organelle movement in the trailing region of the cell. The boundary was also apparent during simultaneous capping and retraction when forward patch transport on the trailing edge and rearward transport of patches across the lamellar surface appeared to converge on the null border. Forward patch transport was strictly confined to regions behind the boundary while retrograde patch transport was confined to the lamellar region ahead of the boundary. Patches are thought to be linked to the cortical cytoskeleton and their transport is discussed in terms of the very different cortical cytoskeletal dynamics occurring in the leading and trailing edges of locomoting cells.

Screening for enteropathogenic Escherichia coli in infants with diarrhea by the fluorescent-actin staining test

The attaching effacing (AE) adherence property is now recognized as an important virulence characteristic of enteropathogenic Escherichia coli (EPEC). The fluorescent-actin staining (FAS) test (S. Knutton, T. Baldwin, P. H. Williams, and A. S. McNeish, Infect. Immun. 57:1290-1298, 1989), which is diagnostic for the AE lesions produced by EPEC (and Vero cytotoxin-producing E. coli), has provided an additional tool with which to investigate this important class of enteric pathogens. In this study, we screened for the AE adherence property in two groups of E. coli isolated from infants with diarrhea by using the FAS test and compared the results with those from O:H serotyping, localized adhesion to HEp-2 cells (LA), and the EPEC adherence factor (EAF) probe. Only 16 of 41 (39%) E. coli strains previously diagnosed as EPEC by O antigen serogrouping were FAS test positive, and of these only 12 belonged to recognized EPEC O:H serotypes; 9 strains which did belong to EPEC O:H serotypes were FAS test negative. Of a second group of 297 untyped E. coli, 7 (2.3%) were FAS test positive, and of these only 2 belonged to EPEC serogroups; 5 belonged to serogroups not regarded as EPEC serogroups or were nontypeable. Of the 23 FAS-test-positive strains identified, 10 were EAF probe positive and showed good LA; 13 were EAF probe negative and showed a quantitatively distinctly poor LA. EAF-positive and EAF-negative strains, however, showed equally good adhesion to human small intestinal mucosa. None of the FAS-test-positive E. coli hybridized with probes for Vero toxins 1 or 2. We conclude that the FAS test is diagnostic not only for classical EPEC and Vero cytotoxin-producing E. coli but also for EPEC strains which are not currently being diagnosed because they belong to serotypes not generally regarded as EPEC serotypes.

Construction, expression and unexpected regulatory properties of a tropomyosin mutant with a 31-residue deletion at the C-terminus (exon 9)

The cDNA coding for human skeletal muscle beta-tropomyosin was expressed in Escherichia coli to produce an unacetylated beta-tropomyosin. This cDNA was deleted from the sequence corresponding to the exon 9 and expressed in E. coli to produce an unacetylated beta-tropomyosin mutant lacking the C-terminal residues 254-284. The main structural and functional properties of the two isolated proteins, designated tropomyosin-1 and des-(254-284)-tropomyosin, respectively, were characterized in comparison with those of the genuine rabbit skeletal muscle alpha beta-tropomyosin. The folding and thermal stability of the three tropomyosins were indistinguishable. Tropomyosin-1, but not des-(254-284)-tropomyosin, was polymerized in the presence of troponin and did bind to actin in the presence of the troponin complex. Despite its weak binding to actin, des-(254-284)-tropomyosin displayed a regulatory function in the presence of troponin with a marked activation of the actomyosin subfragment-1 ATPase in the presence of Ca2+ and low concentrations of subfragment-1. The data were interpreted in the light of the allosteric models of regulation and suggest the involvement of the sequence coded by exon 9 in the stabilization by tropomyosin of the off state of the thin filament.

Stress fibers in the mesenteric mesothelial cells of the large intestine of the bullfrog, Rana catesbeiana

Actin-containing cytoplasmic fibers were visualized in the mesenteric mesothelial cells of the large intestine of bullfrog tadpoles by rhodamine-phalloidin staining of en face preparations of mesothelial cells. These fibers were concurrently stained by immunofluorescence using antibodies to myosin or alpha-actinin. Electron microscopy showed the presence of bundles of microfilaments in the basal cytoplasm of the cells. Such fibers in the mesothelial cells may be comparable to the stress fibers present in cultured cells. The mesothelial cells initially formed axially oriented stress fibers when they changed from a rhombic to a slender spindle-like shape. On the other hand, stress fibers disappeared as cells transformed from elongated to polygonal shapes during the period of metamorphic climax. Expression of stress fibers in these cells appears to be related to the degree of tension loaded on the mesentery, which may be generated by mesenteric winding. These stress fibers in the mesothelial cells may serve to regulate cellular transformation. They may also help to maintain cellular integrity by strengthening the cellular attachment to subepithelial tissue against tensile stress exerted on the mesentery.

2,4-Dinitrophenyl [14C]cysteinyl disulfide allows selective radioactive labeling of protein thiols under spectrophotometric control

2,4-Dinitrophenyl [1-14C]cysteinyl disulfide readily introduces by disulfide exchange [14C]cysteine as a label into proteins with exposed thiols. The release of an equivalent amount of colored 2,4-dinitrothiophenolate allows the labeling reaction to be followed spectrophotometrically. In reaction with two cysteine residues of rabbit skeletal muscle actin, the thiol selectivity of the reagent corresponded to that of 5,5'-dithiobis(2-nitrobenzoic acid) (Ellman's reagent) and was superior to that of N-[14C]ethylmaleimide. Labeling of single SH groups of actin and papain proceeded faster than titration with Ellman's reagent under the same conditions. The [14C]cysteine label could be removed under mild conditions, e.g., with dithiothreitol, but proved to be stable during cyanogen bromide degradation of the protein and peptide purification. 2,4-Dinitrophenyl cysteinyl disulfide can be easily prepared within a few hours.

Liquid crystal domains and thixotropy of filamentous actin suspensions

The thixotropic properties of filamentous actin suspensions were examined by a step-function shearing protocol. Samples of purified filamentous actin were sheared at 0.2 sec-1 in a cone and plate rheometer. We noted a sharp stress overshoot upon the initiation of shear, indicative of a gel state, and a nearly instantaneous drop to zero stress upon cessation of shear. Stress-overshoot recovery was almost complete after 5 min of "rest" before samples were again sheared at 0.2 sec-1. Overshoot recovery increased linearly with the square root of rest time, suggesting that gel-state recovery is diffusion limited. Actin suspensions subjected to oscillatory shearing at frequencies from 0.003 to 30 radians/sec confirmed the existence of a 5-min time scale in the gel, similar to that for stress-overshoot recovery. Flow of filamentous actin was visualized by polarized light observations. Actin from 6 mg/ml to 20 mg/ml showed the "polycrystalline" texture of birefringence typical for liquid crystal structure. At shear rates less than 1 sec-1, flow occurred by the relative movement of irregular, roughly ellipsoidal actin domains 40-140 microns long; the appearance was similar to moving ice floes. At shear rates greater than 1 sec-1, domains decreased in size, possibly by frictional interactions among domains. Eventually domains flow in a "river" of actin aligned by the flow. Our observations confirm our previous domain-friction model for actin rheology. The similarities between the unusual flow properties of actin and cytoplasm argue that cytoplasm also may flow as domains.

A blotting method for monitoring the formation of chemically induced DNA-protein complexes

The formation and identification of DNA-protein crosslinks are usually detected by filter binding assays such as alkaline elution. We describe a modified blotting method to selectively identify DNA-protein complexes (DPCs) formed in vitro by either Cr3+ ion or formaldehyde. This protocol allows DPC formation in vitro to be assayed with various chemical agents, requires minimal usage of radioactivity, and is performed in a shorter time frame than that commonly used to resolve DPCs from free proteins and unbound DNA.

Zero-length crosslinking procedure with the use of active esters

A two-step zero-length crosslinking procedure for studying protein-protein complexes has been developed. One component of a complex is briefly incubated with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) in the presence of N-hydroxysuccinimide resulting in the conversion of some of the protein carboxyls into succinimidyl esters. The reaction is stopped by addition of beta-mercaptoethanol and other interacting proteins are then added. Crosslinking arises from substitution of lysine epsilon-amino groups of these proteins for the succinimidyl moieties during a 1- to 2-h incubation period. The advantage of this method versus one-step zero-length crosslinking is that only one component of the complex is exposed to the crosslinker, which eliminates complications arising from the formation of crosslinks among several proteins of a multicomponent complex. Furthermore, crosslinks can be formed even in the presence of reagents, such as dithiothreitol and EDTA, that would interfere with direct crosslinking with EDC.

Is a four-state model sufficient to describe actomyosin ATPase?

Four-[(1984), J. Biol. Chem. 259, 11908] and six-[(1985) Science 227, 999] state models have been proposed for actomyosin ATPase. A key experiment in deciding between these is whether or not there is a transient Pi burst at high actin. In the first, the cleavage and release of products rates are similar and the Pi burst is low; in the second, there are additional product complexes and the Pi burst is large. We reinvestigated the problem by carrying out burst experiments under the conditions in [(1985) Science 227, 999]. Since we find that the Pi burst at high actin is low, we conclude that the four-state model is sufficient to describe actomyosin ATPase.

Enthalpic and entropic contributions to actin stability: calorimetry, circular dichroism, and fluorescence study and effects of calcium

The delta H associated with the thermal unfolding of G-actin has been determined by differential scanning calorimetry (DSC) to be 142 +/- 5 kcal/mol, with the Tm (melting temperature) at 57.2 +/- 0.5 degrees C, at pH 8.0 (heating rate 0.5 K/min). The transition is broad and cannot be treated as a single transition that mimics a two-state process, suggesting the existence of domains. Deconvolution is done to fit it into two quasi-independent two-state transitions. For F-actin, the transition is more cooperative, with a cooperative ratio (the ratio of van't Hoff enthalpy and calorimetric enthalpy) of 1.4, indicating intermonomer interaction. The delta H of the thermal unfolding of F-actin is 162 +/- 10 kcal/mol with a Tm at 67.0 +/- 0.5 degrees C. A state of G-actin similar to that of the heat-denatured form, designated D-actin, is obtained by removing tightly bound Ca2+ with EGTA. The DSC-detectable cooperative transition is completely lost when the free calcium concentration of the medium is 1 x 10(-11) M or lower, using a Ca2+/EGTA buffer system. However, circular dichroism (CD) shows that the helix content of actin, 32% in the G-form, is only partially reduced to 19% in this apo form. The CD spectrum and the helix content of the calcium-depleted actin are almost identical with those of the heat-denatured D form. This loss of 40% of the native helical content is irreversible in both cases. The remaining 60% of the native helical content cannot be further eliminated by heating to 95 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Location of a contact site between actin and myosin in the three-dimensional structure of the acto-S1 complex

Using fluorescence resonance energy transfer (FRET), we measured distances from chromophores located at or near the actin-binding stretch of amino acids 633-642 of myosin subfragment 1 (S1), to five points in the acto-S1 complex. Specific labeling of this site was achieved by first attaching the desired chromophore to an "antipeptide" that by means of its charge complementarity specifically binds to this segment of S1 [Chaussepied & Morales (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 7471] and then cross-linking the fluorescent peptide to the protein. According to this technique, antipeptides containing three different labels, viz., N-dansylaziridine, (iodoacetamido)fluorescein, and monobromobimane, were purified and covalently bound to S1. A second chromophoric group, required for FRET measurements, was selected in such a way as to provide a good spectral overlap with the corresponding peptide chromophore. Cys-707 (SH1) and Cys-697 (SH2) on S1 were modified by using iodoacetamido and maleimido derivatives of rhodamine, 1,N6-ethenoadenosine 5'-diphosphate was trapped at the S1 active site with orthovanadate, Cys-374 on actin was modified with either N-[4-[4-(dimethylamino)phenyl]azo]phenyl]maleimide or N-[(iodoacetyl)-amino]ethyl]-5-naphthylamine-1-sulfonate, and ADP bound to F-actin was exchanged with the fluorescent etheno analogue. By use of excited-state lifetime fluorometry, the following distances from the stretch 633-642 of S1 to other points on S1 or actin have been measured: Cys-707 (S1), 50.3 A; Cys-697 (S1), 49.4 A; active site of S1, greater than or equal to 44 A; nucleotide binding site (actin), 41.1 A; and Cys-374 (actin), approximately 53 A.(ABSTRACT TRUNCATED AT 250 WORDS)

Probe diffusion in cross-linked actin gels

The diffusion of monodisperse polystyrene latex spheres (PLS) in column-purified 0.65 mg/mL actin solutions, polymerized with 100 mM KCl in the absence and presence of a cross-linker, actin binding protein (ABP), has been studied using dynamic light scattering. Measurements over a wide range of scattering angles from 90 degrees to 8 degrees, corresponding to inverse scattering vector probing distances of about 40-400 nm, respectively, give a measure of both the fraction of PLS mobile over the probing distance (from the normalized time autocorrelation function amplitude) and the average diffusion coefficient of the mobile PLS. Both 100- and 500-nm diameter PLS are fully mobile in polymerized actin solutions over distances of less than 100 nm, as reported previously (Newman, J., Schick, K. S. & Gukelberger, G. Biophys. J. 53, 573a, and Newman, J., Mroczka, N. & Schick, K. L. Biopolymers, 28, 655-666). At increasing probing distances, or when ABP is added at molar ratios of 1:750 or 1:150, greater fractions of the PLS are immobilized, up to almost 99% at the conditions of a 400-nm probing distance with 500-nm probes and at a ratio of 1:150 added ABP to actin. The degree of immobilization correlated well with the amount of added ABP, the size of the PLS, and the probing distance. At increasing probe distances, as the degree of immobilization increases, the remaining mobile fraction of PLS has an increasing average diffusion coefficient. These results suggest a range of pore sizes in the actin gels with a mean size of a few hundred nanometers.

Protein kinase C inhibitor H-7 alters the actin cytoskeleton of cultured cells

The effects of the protein kinase C inhibitor H-7 on the actin cytoskeleton of cultured cells (Swiss 3T3 and PTK2) are described. As documented by fluorescence microscopy and the higher-resolution technique of photoelectron microscopy, the effects are rapid and dramatic; exposure to 30 microM H-7 in culture medium for less than 6 min is sufficient to induce a significant reduction in the numbers and thickness of actin microfilament bundles and alterations in the morphology of cell-cell boundaries in PTK2 cells. One-hour exposure to 30 microM H-7 results in nearly complete depletion of normal actin microfilament bundles from all of the cell types examined, without dramatic changes in overall cell shape. The intermediate filament and microtubule cytoskeletal networks did not appear to be affected to any extent over the times and doses examined. Forty-five minutes of exposure of Swiss 3T3 cells to 200 microM of either HA1004 (which is comparable to H-7 with respect to inhibition of cyclic nucleotide dependent kinases) or to the protein kinase C inhibitor sangivamycin did not induce the actin alterations characteristic of H-7. In addition, depletion of protein kinase C from Swiss 3T3 cells by means of phorbol ester-induced down-regulation did not prevent the effects of H-7 on the actin cytoskeleton. These results demonstrate that the protein kinase C inhibitor H-7 has a specific and rapid effect on the actin cytoskeleton, and furthermore H-7 may have biochemical effects beyond those mediated by inhibition of protein kinase C or the cyclic nucleotide dependent kinases.

Actin-binding ability of the protein with the molecular weight of 47,000 phosphorylated during platelet activation

The platelet protein, P47, with the molecular weight of 47,000 that is phosphorylated during platelet activation is closely associated with secretion from granules in these cells. P47 interacts with actin directly or indirectly. We investigated the ability of P47 to bind to actin by actin-affinity chromatography. In the eluate from an actin-Sepharose column, there was no phosphorylated P47, but in the first fraction that passed through the column, there was. The results suggested that P47 does not bind to actin directly.

Gel electrophoresis of native actin and the actin-deoxyribonuclease I complex

Electrophoresis of monomeric actin (G-actin) on 8-25% acrylamide Pharmacia PhastGels was carried out using gels and agarose buffer strips preequilibrated in buffer containing adenosine triphosphate (ATP), calcium ions (Ca2+) and dithiothreitol. On these gels G-actin ran as a sharp band at an apparent molecular mass of 45 kDa relative to standard proteins which is slightly greater than its actual molecular mass of 42 kDa. Electrophoresis in the absence of these solutes led to denaturation and aggregation of the protein, as reflected by a long streak. Filamentous actin (F-actin) did not enter the gel. The actin monomer-binding protein, deoxyribonuclease I, (DNase I) forms a binary complex with G-actin. The purity and apparent molecular mass 74 kDa of this complex were determined by native gel electrophoresis. By the simple procedure of preequilibrating both gel and buffer strips with appropriate ligands, this technique could be extended to investigate interactions between actin and other G-actin-binding proteins and other proteins whose stability is ligand dependent.

Helical diffraction. I. The paracrystalline helix and disorder analysis

In a new approach to helical diffraction a helix generating function is defined, and thence an expression for the autocorrelation function (a.c.f.) for a helix is obtained. The Fourier transform of this a.c.f. gives a new expression for the diffracted intensity, which is shown to be equivalent formally to the classical expression of Cochran, Crick & Vand [Acta Cryst. (1952), 5, 581-586] and A. R. Stokes (unpublished). The new expression allows straightforward examination of the effects of helical disorders on the diffracted intensity. The thermal and paracrystalline effects of disorders with cylindrical symmetry are shown, and examples are given from the diffraction of a model of the actin helix. The general case, disorder with no symmetry, is derived and the effects of axial and radial disorder, separately and together, are computed, again for the model actin helix. Translational disorder is also included, and its effects are explained. The new results are compared with existing accounts of the effects of helical disorders on fibre diffraction.

Structural changes in the thin filament during activation studied by X-ray diffraction of highly stretched skeletal muscle

The actin layer-lines were recorded from a frog semitendinosus muscle stretched to a sarcomere length greater than 4.4 microM. On activation of the muscle, the equator, the second layer-line at 1/18 nm-1 and the 5.9 nm layer-line increased in integrated intensity. On the other hand, the integrated intensity of the first layer-line at 1/36 nm-1 decreased markedly on activation. This decrease was not fully attributable to shifts of tropomyosin strands and therefore suggested a structural change in the actin subunit. The decrease may account for the apparent lack of an intensity increase of this layer-line on activation at normal muscle lengths where attachment of myosin heads to actin increases the intensities of other layer-lines.

In vivo modulation of endothelial F-actin microfilaments by experimental alterations in shear stress

F-actin microfilament reorganization in response to alterations in shear stress has not been experimentally tested in vivo. In the current study, we analyzed changes in F-actin distribution in endothelial cells around the site of a coarctation performed in the midabdominal aorta of rabbits. The coarctation caused a 60% decrease in luminal diameter and produced three distinct zones: 1) a high shear region immediately upstream of the coarct (Zone I); 2) a region of low, fluctuating shear immediately downstream of the coarct (Zone II); and 3) an annular vortex characterized by high shear extending 0.5 to 3 mm downstream of the coarct (Zone III). Endothelial cells of control abdominal aortas were ellipsoid in shape and aligned in the direction of blood flow. They displayed a prominent circumferential band of microfilaments and short, thin stress fibers. Near coarctations, cells of Zone I were much more elongate, and stress fibers were markedly thicker and longer than in control abdominal aortas. In Zone II, cells were polygonal in shape and showed a prominent peripheral band of microfilaments and central stress fibers. Zone III cells were similar in shape to control abdominal aortic endothelial cells but showed very striking central stress fibers. These findings indicate that in vivo F-actin microfilament distribution can be modulated by experimentally altering flow conditions. F-actin redistribution in response to elevated shear stresses may increase cell-substrate adhesion and thus maintain endothelial integrity.

Ultrastructure of the contractile apparatus of rat skeletal muscle embedded in an aqueous medium

The method of tissue embedding in melamine resin was applied to rat skeletal muscle. This method does not require tissue dehydration with organic solvents; only aqueous solutions are used. Electron micrographs of muscles embedded in melamine differ from those embedded in the conventional epoxy resin. In melamine-embedded muscles the actin and myosin filaments appear larger in diameter and subunits can be recognized in cross-sectioned myosin filaments. Within the Z-line, the characteristic patterns described for muscles embedded in epoxy resin are not visible; the spaces between the actin filaments are filled with electron-dense material. This suggests that the Z-line is more compact than could be concluded from epoxy resin-embedded muscle specimens. The M-line appears to be different from what is observed in epoxy-embedded muscle. The membranes appear as several clearly delineated layers. Dehydration rather than the action of the organic solvents per se is the main reason for the differences in the structure of the contractile apparatus between melamine- and epoxy-embedded muscles.

A role for the macrophage in normal hemopoiesis: III. In vitro and in vivo erythropoietin gene expression in macrophages detected by in situ hybridization

Macrophages derived from unstimulated and unseparated mouse bone marrow cells cultivated on hydrophobic foils can release hemopoietic regulator molecules into the surrounding medium. To prove that one of these regulators exists in macrophages in vitro, in situ hybridization using a 1.2-kb erythropoietin (Epo) gene probe was employed. The probe was biotinylated and the signal developed using a streptavidin-gold reagent. Observation was performed using reflection-contrast microscopy. The results indicate that from a 98% pure population of macrophages, 34% F4/80 (mouse, macrophage-specific antigenic determinant)-positive macrophages exhibited Epo gene expression. The technique was also applied to normal, steady-state mouse bone marrow in which approximately 10% of the cells are F4/80-positive and of which about 3% demonstrated simultaneous Epo gene expression. As positive control, kidneys from anemic mice were hybridized with the biotin-labeled Epo DNA. A second positive control utilized biotin-labeled actin DNA hybridized to cultured macrophages and normal bone marrow cells. The accumulating information, demonstrating that the unstimulated kidney does not express the Epo gene, indicates that Epo is produced in other areas of the body under normal, steady-state conditions. The present results show that 1) macrophages can express the Epo gene, 2) this function is carried out by a subpopulation of macrophages, and 3) bone marrow macrophages in vivo may be responsible for the Epo production-target cell mechanism evoked by short-range and/or cell-to-cell interactions under normal, steady-state conditions.

Primary acute renal failure ("acute tubular necrosis") in the transplanted kidney: morphology and pathogenesis

"Acute tubular necrosis" (ATN) in the transplanted kidney, when properly differentiated from other causes of acute renal failure, appears to be a relatively benign condition. It has been widely assumed to be pathologically identical to ATN in the native kidney, but its histopathologic features have not been studied in detail. Because immunosuppressive therapy with cyclosporine adds an additional layer of complexity to the morphologic changes observed, in the present study we have confined our observations to patients immunosuppressed with steroids and azathioprine. Thirteen renal allograft biopsies from patients with ATN and 5 biopsies from patients with normal allograft function were compared with the previously obtained series of 57 native kidney ATN biopsies and 20 control biopsies. Both qualitative and quantitative differences between transplant and native kidney ATN were found. Compared with native kidney ATN, transplant ATN showed significantly less thinning and absence of proximal tubular brush border and less variation in size and shape of cells in individual tubular cross-sections. There were also significantly fewer casts and less dilatation of Bowman's space and a significantly greater number of polarizable crystals presumed to be oxalate in transplant ATN. In native kidney ATN the tubular injury sites were mostly characterized by desquamation of individual epithelial cells leaving areas of bare basement membrane (the "non-replacement" phenomenon). In transplant ATN, sites of tubular injury, although rare and affecting only short tubular segments, were characterized by the actual presence of identifiable necrotic tubular cells, a finding seldom seen in native kidney ATN. There also was a greater interstitial infiltrate of mononuclear inflammatory cells in transplant ATN compared to native kidney ATN. Electron microscopic studies of 9 transplant ATN biopsies showed a mild reduction in proximal tubular brush border compared with controls but this alteration was significantly less than that observed in native kidney ATN. There was no significant alteration in proximal or distal basolateral infoldings and this contrasted sharply with the marked reduction in basolateral infoldings of the plasma membrane observed in native kidney ATN. Disintegrated necrotic cells were found by electron microscopy in transplant ATN whereas these were not observed in native kidney ATN. There were significantly more cells with apoptosis (shrinkage necrosis) in transplant ATN than in native kidney ATN. There were significantly more cells with apoptosis (shrinkage necrosis) in transplant ATN than in native kidney ATN. On the other hand, there were significantly greater numbers of "non-replacement" sites in the distal tubules in native kidney ATN compared to transplant ATN.(ABSTRACT TRUNCATED AT 400 WORDS)