Interaction of rabbit hemopexin with rose bengal and photooxidation of the rose bengal-hemopexin complex.

Rabbit hemopexin associates with rose bengal producing a hypochromic shift in the absorption spectrum of the dye; the extinction coefficient of the dye bound to heme-saturated hemopexin is approximately 20% lower than that of the dye bound to the apoprotein. The interaction of apo- and heme-saturated hemopexin with rose bengal was studied in detail by difference spectroscopy. Apo-hemopexin has one tight binding site for the dye with a dissociation constant in the micromolar range and a set of several weaker binding sites. In contrast, heme-saturated hemopexin has a very low affinity for the dye. Evidence that histidine residues of hemopexin participate in the binding of heme was obtained by photooxidation of hemopexin sensitized by rose bengal. Progressive modification of the 16 histidine residues of hemopexin is effected by illumination of the dye-hemopexin complexes. The midpoint of this pH-dependent reaction is at pH 6.8 +/- 0.1. In 15 min of irradiation, apo-hemopexin loses 50% of its ability to form a low spin hemichrome complex with deuteroheme while only 10% of the ligand coordination to heme iron of the deuteroheme-hemopexin is lost. At that time, approximately 2 more histidine residues are modified in apo-hemopexin than in deuteroheme-hemopexin, and no change is found in other potentially photolabile amino acid residues. The characteristic circular dichroism positive extremum at 231 nm of hemopexin also was decreased by photooxidation, and the loss was slower in the deuteroheme-hemopexin complex than in the apoprotein. When deuteroporphyrin IX was used as the photosensitizing agent, similar results were obtained.     

Inhibition of Escherichia coli DNA polymerase I by rose bengal

The fluorescein dye, rose bengal, inhibits Escherichia coli DNA polymerase I reversibly in the dark and irreversibly in the light. The reversible inhibition, which occurs in the micromolar concentration range, is competitive with respect to the poly(dA-T) template/ primer and noncompetitive with respect to the complementary deoxynucleoside triphosphates. The Hill coefficient for the inhibition by rose bengal is 3.0. Equilibrium dialysis experiments using ¹³¹I-labeled rose bengal have demonstrated direct binding of the inhibitor to the enzyme. No dye binds to poly(dA-T) at concentrations where the inhibition is observed. There are 22 ± 3 rose bengal binding sites per polymerase which can be subdivided into a class of high affinity sites and one of low affinity sites. The high affinity sites (3 μm) bind rose bengal with a Hill coefficient of 1.7 and are responsible for the observed inhibition. The low affinity sites (7μm) are more numerous (about 16) and bind rose bengal in a noncooperative manner. The displacement of rose bengal from the enzyme by poly(dA-T) at equilibrium confirms the competition between poly(dA-T) and rose bengal inferred from the kinetic data for the polymerization reaction. The inhibition of the 3′,5′ exonuclease activity and the template-directed dATP ? P-P exchange reaction by rose bengal is fully consistent with the interaction of rose bengal at the polynucleotide binding site. The enzyme induces an extrinsic Cotton effect in the visible absorption of rose bengal. The abolition of this Cotton effect by poly(dA-T) further supports the proposed site of binding of the dye.     

Phototoxicity of rose bengal in mycological media--implications for laboratory practice

The effects of Rose Bengal (RB) on plate counts of the bacteria Escherichia coli and Pseudomonas aeruginosa, and the yeast Saccharomyces cerevisiae, were studied under natural sunlight and artificial fluorescent lighting. While RB was not inherently toxic in darkness at concentrations found in mycological media, the illumination of media containing RB caused a decrease in colony counts in all cases, and especially for surface spread plates. A negative synergy was observed between chloramphenicol, RB and illumination using a spring water sample containing substantial numbers of Gram-negative bacteria. Exposure of media containing RB to moderate amounts of light during standard laboratory procedures may inhibit microbial growth, with positive benefits in relation to the suppression of contaminant bacteria, or negative implications where fungi are inhibited.     

Synthesis of amphiphilic derivatives of rose bengal and their tumor accumulation

It is known that the combination of laser light and its sensitizer is effective for noninvasive tumor treatment, referred to as photodynamic therapy. Using the combination of ultrasound and its sensitizer has also been suggested for a similar kind of tumor treatment, referred to as sonodynamic therapy. The purpose of this paper is to obtain such sensitizers accumulating selectively in tumors. Amphiphilic derivatives of rose bengal (RB) were synthesized to add a tumor-accumulating property to RB. One type of the synthesized RB derivatives (RBD3), having an alkyl chain with a branching carboxyl group, was found to be superior in amphiphilicity to the other types. Tumor tissue distribution of the synthesized derivatives in mice bearing colon 26 carcinoma was evaluated. It was found that RBD3s with carbon chain lengths of 12, 14, and 16 had higher concentrations in the tumor tissue than RB by more than 1 order of magnitude, several hours after administration. The concentrations correlated well with their water/1-octanol partition coefficients. Since RB is known to induce in vitro cell damage in combination with either laser light or ultrasound, the newly synthesized amphiphilic RB derivatives may be potentially useful as a tumor-selective sensitizer for both light and ultrasound.     

Hepatic storage and biliary excretion of rose bengal in the rat

The distribution of intravenously administered rose bengal (RB) depends on its dose. At a low dose (10 mg/kg), RB can be found almost solely in the liver and plasma. However, at higher doses (from 25 up to 200 mg/kg) the amount of RB found in extra-hepatic tissues gradually increases. In this experiment the hepatic transfer maximum of RB amounted to 146 micrograms/kg/min. By increasing the dose from 10 to 200 mg/kg, the hepatic concentration of RB also approached a maximum (1250 micrograms/g). The storage capacity of the liver, however, did not limit the transfer maximum of RB.     

真菌玫瑰红钠培养基平皿计数验证法的改进

为了避免玫瑰红钠培养基平皿法计数验证时细菌在培养基上生长而干扰真菌计数的准确性这一问题,采用在该培养基中选加了0.08g/L、0.10g/L和0.12g/L三种不同浓度的氯霉素的方法。结果证实,在玫瑰红钠培养基中加入浓度为0.10g/L的氯霉素可完全抑制供试大肠杆菌CMCC(B)44102株的生长,但又不影响供试真菌如白色念珠菌CMCC(F)98001、黑曲霉CMCC(F)98003的培养生长。因此,在微生物限度检查时的玫瑰红钠培养基中加入氯霉素最适宜的有效浓度为0.10g/L。     

Analysis of vagally induced sinus arrhythmias.

Vagal stimulation at precise times in successive cardiac cycles can elicit sinus arrhythmias. Two mechanisms have been identified that can, but do not necessarily, cause these vagally induced sinus arrhythmias. First, changes in cycle length elicited by a given concentration of acetylcholine (ACh) depend on the phase of the pacemaker cell action potential when the ACh binds to muscarinic receptors. Second, acetylcholinesterase degrades ACh rapidly enough for the mean concentration of ACh per cardiac cycle to vary from cycle to cycle. We used a mathematical model of the underlying cellular physiology, to examine whether these mechanisms are responsible for arrhythmogenesis. Computer simulation showed that both mechanisms contribute to the vagally induced sinus arrhythmias.     

Photodynamic action of rose bengal on isolated rat pancreatic acini: stimulation of amylase release

The halogenated fluorescein derivative, rose bengal, upon photon activation, elicits amylase secretion from isolated, perifused pancreatic acini. This effect is due to production of highly reactive singlet delta oxygen which can permeabilize the cell membrane and may also react chemically with secretagogue receptors, or other functional components of the membrane such as the G-proteins. The profile of photodynamically induced amylase secretion is anion-dependent: it becomes biphasic when the chloride ion is substituted by the glutamate ion, an effect attributed to the action of glutamate on the ionic transport systems of the zymogen granule membrane.     

FTIR studies of the photoactivation processes in squid retinochrome

Retinochrome is a photoisomerase of the invertebrate visual system, which converts all-trans-retinal to the 11-cis configuration and supplies it to visual rhodopsin. In this paper, we studied light-induced structural changes in squid retinochrome by means of low-temperature UV-visible and Fourier transform infrared (FTIR) spectroscopy. In PC liposomes, lumi-retinochrome was stable in the wide temperature range between 77 and 230 K. High thermal stability of the primary intermediate in retinochrome is in contrast to the case in rhodopsins. FTIR spectroscopy suggested that the chromophore of lumi-retinochrome is in a relaxed planar 11-cis form, being consistent with its high thermal stability. The chromophore binding pocket of retinochrome appears to accommodate both all-trans and 11-cis forms without a large distortion, and limited protein structural changes between all-trans and 11-cis chromophores may be suitable for the function of retinochrome as a photoisomerase. The analysis of N-D and O-D stretching vibrations in D(2)O revealed that the hydrogen bond of the Schiff base is weaker in retinochrome than in bovine rhodopsin and bacteriorhodopsin, while retinochrome has a water molecule under strongly hydrogen-bonded conditions (O-D stretch at 2334 cm(-)(1)). The hydrogen bond of the water is further strengthened in lumi-retinochrome. The formation of meta-retinochrome accompanies deprotonation of the Schiff base, together with the peptide backbone alterations of alpha-helices, and possible formation of beta-sheets. It was found that the Schiff base proton is not transferred to its counterion, Glu181, but directly released to the aqueous phase in PC liposomes (pH 7.5). This suggests that the Schiff base environment is exposed to solvent in meta-retinochrome, which may be advantageous for the hydrolysis reaction of the Schiff base in the transport of 11-cis-retinal to its shuttle protein.