Silica directly increases permeability of alveolar epithelial cells.

Alveolar epithelial cell injury and increased alveolar-capillary membrane permeability are important features of acute silicosis. To determine whether silica particles contribute directly to this increased permeability, we measured paracellular permeability of rat alveolar epithelium after exposure to silica, in vitro, using markers of the extracellular space. Silica (Minusil) markedly increased permeability in a dose- and time-dependent manner. This was not the result of cytolytic injury, because lactate dehydrogenase release from monolayers exposed to silica was not increased. Pretreatment of the silica with serum, charged dextrans, or aluminum sulfate blocked the increase in permeability. Scanning electron microscopy demonstrated adherence of the silica to the surface of the alveolar epithelial cells. Thus silica can directly increase permeability of alveolar epithelium.     

Radiation-induced changes in permeability in unilamellar phospholipid liposomes

Gamma-radiation-induced oxidative damage in unilamellar dipalmitoylphosphatidylcholine liposomes was investigated using a fluorescence technique. Liposomal changes in permeability induced by gamma radiation were monitored by measuring the leakage of pre-encapsulated 6-carboxyfluorescein, and alterations in lipid bilayer fluidity were determined by 1,6-diphenyl-1,3,5-hexatriene fluorescence polarization. The changes in permeability and fluidity in the bilayer were found to be dependent on the radiation dose in a biphasic fashion. The results are interpreted in terms of lipid bilayer fluidization after exposure to doses up to 1 kGy, but rigidization of the bilayer at higher doses. These results indicate a relationship between alterations in permeability and fluidity in the lipid bilayer after irradiation. The vesicles were protected significantly against radiation-induced oxidative damage in the presence of alpha-tocopherol and ascorbic acid. Radiation-induced changes in the permeability of the liposomes after exposure to gamma radiation and their modification by antioxidants indicate the involvement of a free radical mechanism in the production of damage, which may offer new insights in to the modification of cellular radiosensitivity by modulation of membrane damage.     

Glucose modulates basement membrane fibroblast growth factor-2 via alterations in endothelial cell permeability

The effects of glucose extremes on vascular physiology and endothelial cell function have been examined across a range of time scales. Not unexpectedly, chronic glucose exposure induces long term tissue effects. Yet short term exposure can also impose lasting consequences. The persistence of vascular pathology after euglycemic restoration further suggests a glucose exposure memory. Slow turnover reservoirs such as basement membrane are candidates for prolongation of acute events. We hypothesized that glucose-induced vascular dysfunction is related to altered vasoactive compound handling within the endothelial cell-basement membrane co-regulatory unit. Endothelial cell basement membrane-associated fibroblast growth factor-2 increased linearly with culture glucose within days of elevated glucose exposure. Surprisingly, basement membrane fibroblast growth factor-2 binding kinetics remained unchanged. The glucose-induced increase in basement membrane fibroblast growth factor-2 was instead related to enhanced endothelial cell fibroblast growth factor-2 release and permeability. Cellular fibroblast growth factor-2 release occurred concomitant with apoptosis but was not blocked by caspase inhibitors. These data suggest that release was associated with sub-lethal early apoptotic cell membrane damage, perhaps related to reactive oxygen species formation. High glucose basement membrane in turn enhanced endothelial cell proliferation in a fibroblast growth factor-2-dependent manner. We now show that glucose-induced alterations in endothelial cell function promote changes in basement membrane composition, and these changes further affect endothelial cell function. These data highlight the interrelationship of cell and basement membrane in pathological conditions such as hyperglycemia. These phenomena may explain long term effects on the endothelium of short term exposure to glucose extremes.     

Effect of gamma radiation on resting B lymphocytes. I. Oxygen-dependent damage to the plasma membrane results in increased permeability and cell enlargement

Although the susceptibility of resting B lymphocytes to radiation-induced interphase death is well known, the mechanism by which this occurs is not understood. In this report, we use three measures of plasma membrane integrity (increase in cell volume, uptake of trypan blue, and release of 51Cr) to assess the effect of radiation on the resting B cell plasma membrane. The delivery of 500 to 1000 rad caused the majority of resting B cells to enlarge slightly, whereas 3000 rad caused virtually all of the cells to approximately double in size within 3 to 4 hr. Measurement of the release of 51Cr from resting B cells revealed a similar relationship between the dose of radiation and the loss of radioactive label. Trypan blue exclusion was also found to diminish as a function of radiation dose. An analysis of a variety of lymphoid cells suggested that sensitivity to the membrane damaging effects of gamma radiation was in the order of resting B cells greater than resting T cells greater than a long-term L3T4+ T cell clone greater than a B cell lymphoma. LPS-induced B cell blasts treated with 3000 rad were equivalent to 1000 rad-treated resting B cells. The effects of the gamma radiation could be ameliorated by excluding oxygen (a diradical molecule that can potentially enhance the generation and propagation of highly reactive free radicals) at the time of irradiation, or by adding the free radical scavenging agent cysteamine. These data are compatible with the hypothesis that gamma radiation results in damage to the plasma membrane of resting lymphocytes via the generation of highly reactive free radical species. This damage is reflected in a rapid increase in plasma membrane permeability and swelling of the cells, and may play a major role in causing interphase death.     

Single exposure to radiation produces early anti-angiogenic effects in mouse aorta

Radiation exposure can increase the risk for many non-malignant physiological complications, including cardiovascular disease. We have previously demonstrated that ionizing radiation can induce endothelial dysfunction, which contributes to increased vascular stiffness. In this study, we demonstrate that gamma radiation exposure reduced endothelial cell viability or proliferative capacity using an in vitro aortic angiogenesis assay. Segments of mouse aorta were embedded in a Matrigel-media matrix 1 day after mice received whole-body gamma irradiation between 0 and 20 Gy. Using three-dimensional phase contrast microscopy, we quantified cellular outgrowth from the aorta. Through fluorescent imaging of embedded aortas from Tie2GFP transgenic mice, we determined that the cellular outgrowth is primarily of endothelial cell origin. Significantly less endothelial cell outgrowth was observed in aortas of mice receiving radiation of 5, 10, and 20 Gy radiation, suggesting radiation-induced endothelial injury. Following 0.5 and 1 Gy doses of whole-body irradiation, reduced outgrowth was still detected. Furthermore, outgrowth was not affected by the location of the aortic segments excised along the descending aorta. In conclusion, a single exposure to gamma radiation significantly reduces endothelial cell outgrowth in a dose-dependent manner. Consequently, radiation exposure may inhibit re-endothelialization or angiogenesis after a vascular injury, which would impede vascular recovery.     

Role of the mitochondrial permeability transition in apoptotic and necrotic death after ischemia/reperfusion injury to hepatocytes

Reperfusion of ATP-depleted tissues after warm or cold ischemia causes pH-dependent necrotic and apoptotic cell death. In hepatocytes and other cell types as well, the mechanism underlying this reperfusion-induced cell death involves onset of the mitochondrial permeability transition (MPT). Opening of permeability transition (PT) pores in the mitochondrial inner membrane initiates the MPT, an event blocked by cyclosporin A (CsA) and pH less than 7.4. Thus, both acidotic pH and CsA prevent MPT-dependent reperfusion injury. Glycine also blocks reperfusion-induced necrosis but acts downstream of PT pore opening by stabilizing the plasma membrane. After the MPT, ATP availability from glycolysis or other source determines whether cell injury after reperfusion progresses to ATP depletion-dependent necrosis or ATP-requiring apoptosis. Thus, apoptosis and necrosis after reperfusion share a common pathway, the MPT. Cell injury progressing to either necrosis or apoptosis by shared pathways can be more aptly termed necrapoptosis.     

射线照射后大鼠骨髓、十二指肠、小脑微血管通透性的改变

本文观察了r线全身照射后,大鼠骨髓、十二指肠和小脑微血管通透性的改变。结果表明:正常时骨髓微血管通透性最高,十二指肠次之,小脑最低。照后骨髓微血管通透亢进发生早、增加快、变化大、恢复慢,主要发生在血窦;照后十二指肠微血管通透亢进发生较早、增加较快、变化较大、恢复较快,主要发生在肠绒毛的毛细血管和细静脉;照后小脑微血管通透性变化较小,在400.0Gy组可见通透亢进,主要发生在小脑皮质的毛细血管。所有这三个脏器微血管通透亢进部位,实质细胞的退变明显加重。说明微血管邇透亢进可明显加重实质细胞的损伤,而实质细胞的再生修复,就发生在微血管通透恢复,基底背景较清净地方。说明:照后骨髓、十二指肠、小脑微血管通透性的改变,在造血型、胃肠型和脑型急性放射病的发病机理上有重要意义。     

Temporal expression of hypoxia-regulated genes is associated with early changes in redox status in irradiated lung

The development of normal lung tissue toxicity after radiation exposure results from multiple changes in cell signaling and communication initiated at the time of the ionizing event. The onset of gross pulmonary injury is preceded by tissue hypoxia and chronic oxidative stress. We have previously shown that development of debilitating lung injury can be mitigated or prevented by administration of AEOL10150, a potent catalytic antioxidant, 24h after radiation. This suggests that hypoxia-mediated signaling pathways may play a role in late radiation injury, but the exact mechanism remains unclear. The purpose of this study was to evaluate changes in the temporal expression of hypoxia-associated genes in irradiated mouse lung and determine whether AEOL10150 alters expression of these genes. A focused oligo array was used to establish a hypoxia-associated gene expression signature for lung tissue from sham-irradiated or irradiated mice treated with or without AEOL10150. Results were further verified by RT-PCR. Forty-four genes associated with metabolism, cell growth, apoptosis, inflammation, oxidative stress, and extracellular matrix synthesis were upregulated after radiation. Elevated expression of 31 of these genes was attenuated in animals treated with AEOL10150, suggesting that expression of a number of hypoxia-associated genes is regulated by early development of oxidative stress after radiation. Genes identified herein could provide insight into the role of hypoxic signaling in radiation lung injury, suggesting novel therapeutic targets, as well as clues to the mechanism by which AEOL10150 confers pulmonary radioprotection.     

Placenta growth factor-1 exerts time-dependent stabilization of adherens junctions following VEGF-induced vascular permeability

Increased vascular permeability is an early event characteristic of tissue ischemia and angiogenesis. Although VEGF family members are potent promoters of endothelial permeability the role of placental growth factor (PlGF) is hotly debated. Here we investigated PlGF isoforms 1 and 2 and present in vitro and in vivo evidence that PlGF-1, but not PlGF-2, can inhibit VEGF-induced permeability but only during a critical window post-VEGF exposure. PlGF-1 promotes VE-cadherin expression via the trans-activating Sp1 and Sp3 interaction with the VE-cadherin promoter and subsequently stabilizes transendothelial junctions, but only after activation of endothelial cells by VEGF. PlGF-1 regulates vascular permeability associated with the rapid localization of VE-cadherin to the plasma membrane and dephosphorylation of tyrosine residues that precedes changes observed in claudin 5 tyrosine phosphorylation and membrane localization. The critical window during which PlGF-1 exerts its effect on VEGF-induced permeability highlights the importance of the translational significance of this work in that PLGF-1 likely serves as an endogenous anti-permeability factor whose effectiveness is limited to a precise time point following vascular injury. Clinical approaches that would pattern nature's approach would thus limit treatments to precise intervals following injury and bring attention to use of agents only during therapeutic windows.     

The cell membrane as a biosensor of oxidative stress induced by radiation exposure: a multiparameter investigation

The role of biological membranes as a target in biological radiation damage remains unclear. The present study investigates how the biochemical and biophysical properties of a simple biological model, i.e. human erythrocyte membranes, are altered after exposure to relatively low doses of (60)Co gamma rays. Lipid peroxidation increased in the hours after radiation exposure, based on measurements of MDA and on the lipid peroxidation index after parinaric acid incorporation. Protein carbonyl content also increased rapidly after radiation exposure. An imbalance between the radiation-mediated oxidative damages and the antioxidant capacity of the erythrocytes was observed in the hours after radiation exposure. Antioxidant enzyme activities, mainly catalase and glutathione peroxidase, were found to decrease after irradiation. The development of a radiation-induced oxidative stress probably explains the reorganization of the fatty acid pattern 72 h after radiation exposure. The phosphatidylethanolamine (PE) fatty acids of the (n-3) and (n-6) series decreased, while the PE saturated fatty acid content increased. All these modifications may be involved in the variation of the biophysical properties of the membranes that we noted after radiation exposure. Specifically, we observed that the lipid compartment of the membrane became more fluid while the lipid-protein membrane interface became more rigid. Taken together, these findings reinforce our understanding that the cell membrane is a significant biological target of radiation. Thus the role of the biological membrane in the expression and course of cell damage after radiation exposure must be considered.     

Determining the repair rate for radiation-induced chromatid deletions during the first 24 hours after irradiation

The number of chromatid plus isochromatid deletions present in the testes and bone marrow of the Chinese hamster was measured as a function of time following acute exposure to cobalt-60 gamma irradiation. The number of breaks remaining scorable at any time after irradiation exposure could be represented by a simple exponential equation (N = Noe-kt). The values of No and k, calculated after 100 roentgens of cobalt-60 gamma irradiation, were 1.15 breaks/cell and 0.16/hour, respectively, for the testes, and 0.53 break/cell and 0.14/hour, respectively, for the bone marrow. The average length of time that the breaks remain scorable, 1/k, was found to be 6.3 hours for the testes and 7.1 hours for the bone marrow. By suitable formulation, it was possible to predict the number of breaks present by using varied radiation exposure rates and times after exposure. This formulation could be used for both single and multiple radiation exposures.     

Plerixafor, a CXCR4 antagonist, mitigates skin radiation-induced injury in mice

Even with modern 3D conformal treatments skin radiation injury can be an inadvertent complication associated with clinical radiotherapy particularly at tissue folds. It is also of concern in the context of a radiological terrorism incident or accident, since skin irradiation lowers the lethal dose of whole body radiation. We hypothesize that radiation-induced skin injury originates from a loss of stem and progenitor cells, accompanied by excessive ROS production and proinflammatory cytokines. Plerixafor, a CXCR-4 antagonist, is one of the most efficient bone marrow stem cell mobilizers and these studies were designed to experimentally assess the potential of Plerixafor to reduce skin radiation injury. The right hind legs of groups of C57BL/6 mice were exposed to radiation alone or in combination with Plerixafor. Plerixafor was administered intraperitoneally at a dose of 5 mg/kg given in two doses separated by two days and started either on day 0, 4, 7, 15 or 24 after irradiation. The primary end point was skin injury, which was assessed three times a week for at least 2 months using a semi-quantitative scale. Secondary end points measured at selected time points included histology (primarily H&E) and cytokine levels (TGF-β and TNF-α). The acute and late skin injury in mice receiving Plerixafor was highly dependent on the timing of administration of the drug. The maximum benefit was observed when the drug was started 1 week after radiation exposure, and earlier or later administration of the drug decreased its efficacy. Secondary damage end points (cytokine levels and histologically assessed tissue thickness) provided confirmatory observations. In an attempt to gain insight into the effect of timing of administration of the agent on the mitigation effect, the ligand to CXCR4, stromal derived factor, SDF-1, was measured as a function of time after radiation exposure. Expression of SDF-1 monitored in skin as a function of time after a 30 Gy radiation exposure suggested a strong correlation between timing of administration of Plerixafor and expression of SDF-1 in irradiated skin: optimum drug administration timing coincided with maximal SDF-1 expression in the skin of irradiated mice. This report presents the first observation that CXCR4 antagonist improves both acute and late skin response to radiation exposure. ? 2012 by Radiation Research Society.     

Biochemical basis of ozone toxicity

Ozone (O3) is the major oxidant of photochemical smog. Its biological effect is attributed to its ability to cause oxidation or peroxidation of biomolecules directly and/or via free radical reactions. A sequence of events may include lipid peroxidation and loss of functional groups of enzymes, alteration of membrane permeability, and cell injury or death. An acute exposure to O3 causes lung injury involving the ciliated cell in the airways and the type 1 epithelial cell in the alveolar region. The effects are particularly localized at the junction of terminal bronchioles and alveolar ducts, as evident from a loss of cells and accumulation of inflammatory cells. In a typical short-term exposure the lung tissue response is biphasic: an initial injury-phase characterized by cell damage and loss of enzyme activities, followed by a repair-phase associated with increased metabolic activities, which coincide with a proliferation of metabolically active cells, for example, the alveolar type 2 cells and the bronchiolar Clara cells. A chronic exposure to O3 can cause or exacerbate lung diseases, including perhaps an increased lung tumor incidence in susceptible animal models. Ozone exposure also causes extrapulmonary effects involving the blood, spleen, central nervous system, and other organs. A combination of O3 and NO2, both of which occur in photochemical smog, can produce effects which may be additive or synergistic. A synergistic lung injury occurs possibly due to a formation of more powerful radicals and chemical intermediates. Dietary antioxidants, for example, vitamin E, vitamin C, and selenium, can offer a protection against O3 effects.     

Nitric oxide: a signaling molecule against mitochondrial permeability transition- and pH-dependent cell death after reperfusion

Reperfusion of ischemic tissue can precipitate cell death. Much of this cell killing is related to the return of physiological pH after the tissue acidosis of ischemia. The mitochondrial permeability transition (MPT) is a key mechanism contributing to this pH-dependent reperfusion injury in hepatocytes, myocytes, and other cell types. When ATP depletion occurs after the MPT, necrotic cell death ensues. If ATP levels are maintained, at least in part, the MPT initiates apoptosis caused by mitochondrial swelling and release of cytochrome c and other proapoptotic factors. Cyclosporin A and acidotic pH inhibit opening of permeability transition pores and protect cells against oxidative stress and ischemia/reperfusion injury, whereas Ca²⁺, mitochondrial reactive oxygen species, and pH above 7 promote mitochondrial inner membrane permeabilization. Reperfusion with nitric oxide (NO) donors also blocks the MPT via a guanylyl cyclase and protein kinase G-dependent signaling pathway, which in turn prevents reperfusion-induced cell killing. In isolated mitochondria, a combination of cGMP, cytosolic extract, and ATP blocks the Ca²⁺-induced MPT, an effect that is reversed by protein kinase G inhibition. Thus, NO prevents pH-dependent cell killing after ischemia/reperfusion by a guanylyl cyclase/cGMP/protein kinase G signaling cascade that blocks the MPT.     

The release of membrane-bound calcium by radiation and sulfhydryl reagents

Effects of ionizing radiation and of sulfhydryl reagents on the ⁴⁵Ca binding of red cell membranes were studied. Corresponding effects of these agents on potassium leak from intact red cells were also determined. Essentially all the ⁴⁵Ca associated with the ghosts appeared to be bound. Calcium binding could be described by assuming two independent groups of binding sites with dissociation constants of about 6 × 10^?4 m and 2 × 10^?4 m. The total binding capacity was about 2.5 × 10^?4 moles/g ghost protein. Membrane calcium was decreased by radiation and by the two sulfhydryl reagents, p-chloromercuribenzoate (PCMB) and N-ethyl maleimide (NEM). The tightly bound calcium fraction appeared to be most affected by these agents. Changes in potassium leak evoked by varying doses of agents appeared to parallel effects on membrane calcium. These investigations suggest that the increased cation permeability observed after exposure or red cells to radiation or sulfhydryl reagents may be related to alterations in the calcium-binding properties of the cell membrane.     

Cinnamic acid nanoparticles modulate redox signal and inflammatory response in gamma irradiated rats suffering from acute pancreatitis

Acute Pancreatitis (AP) is a multifactorial disease. It was characterized by severe inflammation and acinar cell destruction. Thus, the present study was initiated to evaluate the role the of Cinnamic acid nanoparticles (CA-NPs) as a modulator for the redox signaling pathway involved in the development of pancreatitis. AP in rats was induced by L-arginine and exposure to gamma radiation. The pancreatic injury was evaluated using biochemical and histological parameters. Upon the oral administration of CA-NPs, both the severity of acute pancreatitis and the serum levels of amylase and lipase were decreased. Furthermore, the malondialdehyde (MDA) levels of the pancreatic tissue were significantly reduced and the depletion of glutathione was considerably restored. The injury and apoptosis of pancreatic tissues were markedly improved by the reduction of the caspase-3 levels. Additionally, the alleviation of pancreatic oxidative damage by CA-NPs was accompanied by a down-regulation of the NLRP3, NF-κB, and ASK1/MAPK signaling pathways. Collectively, the current findings showed that CA-NPs could protect the pancreatic acinar cell from injury not only by its antioxidant, anti-inflammatory effect but also by modulation of the redox-sensitive signal transduction pathways contributed to acute pancreatitis severity. Accordingly, cinnamic acid nanoparticles have therapeutic potential for the management of acute pancreatitis.     

Thrombomodulin as a marker of radiation-induced endothelial cell injury.

Cultured confluent human umbilical vein endothelial cells were irradiated in vitro with 60Co gamma rays at doses from 0 to 50 Gy. After irradiation thrombomodulin was measured at different times over 6 days in the supernatants of endothelial cell culture medium, on the surface of the cells, and within the cells. At 24 h after irradiation, an increase in the release of thrombomodulin from irradiated endothelial cells and an increase in the number of molecules and the activity of thrombomodulin on the surface of the cells were observed; these reactions were dependent on radiation dose. The capacity of the cells to produce and release thrombomodulin was decreased from 2 to 6 days after exposure to 60Co gamma rays. Our data indicate that radiation can injure endothelial cells, and that thrombomodulin may be used as a marker of radiation-induced injury in endothelial cells. The interrelationship between the dysfunction of irradiated endothelial cells and the pathological mechanisms of acute radiation disease is also discussed.     

The assessment of recovery of the intestine after acute radiation injury

Several aspects of intestinal function and morphology are affected by acute radiation damage, including changes in the activity of proliferative cells in the crypts, immune cell populations, and the transport of various substrates. This study was designed to compare the time course of the recovery of intestinal proliferation, transport, and leukocyte population following radiation injury. Rats received a single dose of 6 Gy to the abdomen from a 137Cs source and were studied 3, 7, and 14 days later. No changes in the passive uptake of L-glucose or D-leucine were observed in the jejunum. Active transport of D-glucose and maximal water uptake were reduced at 3 days but had returned to normal by 7 days, whereas L-leucine uptake required more than 7 days to return to control levels. Mucosal permeability, assessed by an in vivo potential difference technique, remained increased 7 days after irradiation. Ornithine decarboxylase, an indicator of DNA synthetic activity, was elevated following radiation treatment and remained so even after 14 days. By comparison, myeloperoxidase activity, used as a quantitative monitor of granulocyte numbers, was still reduced after 7 days. These data indicate that while certain parameters of gut function may return to normal soon after radiation injury, the recovery of other factors is more prolonged. Thus the return of transport function to normal values post irradiation may be viewed as an adaptive change rather than simply the recovery of the tissue.     

Radiobiology of the acute radiation syndrome

Acute radiation syndrome or acute radiation sickness is classically subdivided into three subsyndromes: the hematopoietic, gastrointestinal and neurovascular syndrome but many other tissues can be damaged. The time course and severity of clinical signs and symptoms are a function of the overall body volume irradiated, the inhomogeneity of dose exposure, the particle type, the absorbed dose and the dose rate. Classical pathophysiology explain the failure of each of these organs and the timing of appearance of their signs and symptoms due to radiation-induced cytocidal effects of a great number of parenchymal cells of hierarchically organized tissues. Contemporaneously, many other radiation-induced effects has been described and all of them may lead to tissue injury with their corresponding signs and symptoms that can be expressed after short or long period of time. Radiation-induced multi-organ involvement is thought to be due to radiation-induced systemic inflammatory response mediated by released pro-inflammatory cytokines.     

The Mechanism of the Gram Reaction. II. The Function of Iodine in the Gram Stain

Fifty-five reagents were studied as to their ability to replace iodine in the Gram stain. None gave results as good as iodine. Eight gave usable Gram preparations, and forty-seven gave negative results. Omission of the counterstain resulted in increasing to thirty-three the number of reagents giving differentiation, but this, was not considered a true Gram differentiation. Many oxidizing agents were shown not to be substitutes for iodine; therefore the function of iodine must be more than to serve as an oxidizing agent. Many reagents which formed precipitates with the dye could not replace iodine; therefore factors other than precipitate formation must be involved. However, all agents which were good substitutes for iodine were both good oxidizing and dye precipitating agents. Experiments involving the study of cell membrane permeability showed that Gram-positive cells were less permeable to iodine in alcoholic solution than Gram-negative cells. This difference could not be demonstrated for iodine in aqueous solution. It was concluded that iodine served to form a dye-iodine precipitate (or complex) in the cell. Since Gram-positive cells were less permeable to iodine in alcohol than Gram-negative cells, this resulted in a slower dissolving out of this complex from Gram-positive cells during de-colorization and hence a slower decolorization time. The relative solubilities of dye precipitates in alcohol and in aqueous safranin solution were also indicated as an important factor influencing decolorization. Dyes which formed highly soluble precipitates with iodine could not be used in the Gram stain. It is not proposed that the mechanism of the Gram stain is entirely one of membrane permeability; chemical factors are undoubtedly important and will be discussed in a later paper. However, it is proposed that the chemical and physical factors are closely interrelated in the Gram stain mechanism.