Antimicrobial activity of phenol and benzoic acid derivatives

Vinyl monomers with phenol and benzoic acid as pendant groups were synthesized, and their antimicrobial activities were examined on equal weight basis using the halo zone test. For both bacteria and fungi, the halo zone diameter decreased in the order of p-hydroxyphenyl acrylate (M2)>allyl p-hydroxyphenyl acetate (M1)≈p-2-propenoxyphenol (M3). Polymerization of the monomers decreased their antimicrobial activity significantly, but the order of the halo zone diameter for the polymers was the same as that of the corresponding monomers. Glassy polymers exhibited low antimicrobial activity when compounded with low molecular weight antimicrobial agents due to the extremely slow diffusion. Antimicrobial polymers could find a successful application such as coating on glassy polymers, in spite of the lower antimicrobial activity compared to the respective monomers.     

Degradation of phenol and benzoic acid in a three-phase fluidized-bed reactor

Degradation of phenol and benzoic acid was studied in a fluidized-bed reactor (liquid volume 2.17 L) under nonsterile conditions with special emphasis on maximizing the flow through the reactor and investigating reactor performance at fluctuating feeds. Reactor response to substrate pulses was investigated by applying substrate square-wave inputs at a liquid flow of 1.00 L h(-1). A twofold increase of the phenol and benzoic acid feed concentrations for 2.5 h did not lead to accumulation and breakthrough. The cells were able to survive four to fivefold increases of the feed concentration for 1 h without loss of viability, although the phenol pulse lead to phenol accumulation in the reactor. Reactor performance at constantly fluctuating loads was investigated by varying the feed concentrations using sine wave functions. No accumulation of phenol or benzoic acid was observed. Influence of induction was studied using shift experiments. After 35 days of operation (369 hydrodynamic residence times) with phenol as sole substrate (carbon source) the reactor was able to mineralize benzoic acid without any adaptation or lag phase. The capability of phenol degradation, on the other hand, was lost by most cells after only 3 days operation with benzoic acid as the sole substrate. The experiments underline the importance of induction. In order to maximize the flow through the reactor, the liquid flow was increased stepwise while the feed concentrations were reduced correspondingly, keeping the volumetric conversion rates of phenol (0.24 g L(-1) h(-1)) and benzoic acid (0.17 g L(-1) h(-1)) constant. By this means, liquid flow could be increased up to 13.32 L h(-1), which was more than 20-fold higher than the maximum liquid flow achievable in a chemostat using the same conditions.     

Structure of cycloheptaamylose inclusion-complexes: crystal structure of substituted benzoic acid and phenol derivatives

Cycloheptaamylose has been crystallized with 2,5-diiodobenzoic acid as guest. The X-ray crystal structure at 1.2-Å resolution with space group C2 and cell dimensions a  19.192 (13), b  24.759 (20), c  15.739 (13) Å, and β  109.6 (3)° was solved by using rotation-translation functions. Complexes of other meta-substituted guests were found to be isomorphous, and were solved by using the phases of the cycloamylose of the 2,5-diiodobenzoic acid complex. The complex with 2-bromo-5-tert-butylphenol having a  19.235 (11), b  24.662 (17), c  16.018 (11) Å, and β  108.9 (2)° was determined at 1.0 Å resolution, and the complexes with m-bromobenzoic acid, m-iodobenzoic acid, m-iodophenol, m-toluic acid, and 2-bromo-4-tert-butylphenol were determined at 2.0-Å resolution. In all cases, the guest molecule was disordered. However, by using information from all the structures, it may be concluded that the functionally important carboxylic acid group lies in the primary-hydroxyl end of the cycloheptaamylose molecule. As studies in solution have shown that the hydrogen-bonding groups of guest molecules interact with the secondary-hydroxyl end of the cycloheptaamylose molecule, it is concluded that the structure seen in the crystals here does not correspond to a catalytically active species. Cyclo-heptaamylose exists as a dimer in the crystal by means of extensive hydrogen bonding across the secondary-hydroxyl ends of two cycloheptaamylose molecules. A continuous channel throughout the crystal is achieved by the stacking of these dimer units.     

Difference of the liver and kidney in glycine conjugation of ortho-substituted benzoic acids

The relative importance of the liver and kidney for glycine conjugation of ortho-substituted benzoic acids was investigated. Glycine conjugation of ortho-substituted benzoic acids was investigated in mouse liver and kidney mitochondria. The extent of glycine conjugation of benzoic acids with the halogen group decreased in the order F > Cl > Br > I. The conjugation of salicylic acid with glycine took place in only the kidney. 2-Methoxybenzoic acid exhibited no activity in the liver and kidney. The difference in glycine conjugation of ortho-substituted benzoic acids was observed between liver and kidney. The kidney was more active in glycine conjugation of ortho-substituted acids than the liver. In addition, the relationship between glycine conjugation and the chemical structure of ortho-substituted acids was examined in the liver and kidney. The size of the substituent had a far greater influence over glycine conjugation in the liver and kidney. Glycine conjugation was also dependent on the substituent electronegativity. It may be important that the substrates undergoing glycine conjugation contain a flat region coplanar to the carboxylate group.     

Stimulatory effects of 2,4-dichlorophenoxyacetic acid and of 1-naphthylacetic acid on sucrose level,invertase activity and sucrose utilization in the latex ofHevea brasiliensis

Summary Treatment of the bark ofHevea brasiliensis with 2,4-dichlorophenoxyacetic acid (2,4-D) or l-naphthylacetic acid (NAA) greatly increases sucrose level, invertase activity and sucrose utilization in the latex; the efficacy of 2,4-D is considerably greater than that of NAA. The greater sucrose utilization is the consequence of increased invertase activity. The changes occur as soon as the first tapping following bark treatment. It is suggested that the rise in both sucrose level and utilization in the latex serum mediate the effect of auxins on latex production. This is most likely related to a faciliation of latex outflow resulting from an increase in the osmotic and turgor pressure in the laticiferous tissue, as well as to enhanced regeneration of latex.The latex invertase has been found to be of a weakly alkaline type, with a sharp pH optimum at 7.15–7.20 in citrate-phosphate buffer. Its activity falls of rapidly on the acid side, being almost zero at pH 6.4. Since the natural pH of latex generally varies between pH 6.5 and 7.0, it is suggested that pH is an important factor in the regulation of invertase activity in the latex, and that the limiting nature of invertase-mediated sucrose hydrolysis in latex serum is caused by unfavourable conditions for invertase activity rather than by a scarcity of this enzyme.Expert of the International Atomic Energy Agency.     

Isolation and characterization of a new bacterium carboxylating phenol to benzoic acid under anaerobic conditions.

A consortium of spore-forming bacteria transforming phenol to benzoic acid under anaerobic conditions was treated with antibiotics to eliminate the four Clostridium strains which were shown to be unable to accomplish this reaction in pure culture and coculture. Clostridium ghonii was inhibited by chloramphenicol (10 micrograms/ml), whereas Clostridium hastiforme (strain 3) and Clostridium glycolicum were inhibited by clindamycin (20 micrograms/ml), without the transformation of phenol being affected. Electron microscopic observations of resulting liquid subcultures revealed the presence of two different bacilli: a dominant C hastiforme strain (strain 2) (width, 1 micron) and an unidentified strain 6 (width, 0.6 micron) which was not detected on solid medium. Bacitracin (0.5 U/ml) changed the ratio of the strains in favor of strain 6. C hastiforme 2 was eliminated from this culture by dilution. The isolated strain 6 transformed phenol to benzoic acid and 4-hydroxybenzoic acid to phenol and benzoic acid in the presence of proteose peptone. Both of these activities are inducible. This strain is a gram- variable, flagellated rod with a doubling time of 10 to 11 h in the presence of phenol. It has a cellular fatty acid composition like that of C. hastiforme. However, strain 6 does not hydrolyze gelatin or produce indole. The 16S rRNA sequence of strain 6 was found to be most similar to that of some Clostridium species, with homology ranging from 80 to 86%. Tbe evolutionary relationships of strain 6 to different groups of Clostridium and Clostridium-related species revealed that it does not emerge from any of these groups. Strain 6 most likely belongs to a new species closely related to Clostridium species.     

The fate of benzoic acid in various species

1. The urinary excretion of orally administered [¹⁴C]benzoic acid in man and 20 other species of animal was examined. 2. At a dose of 50mg/kg, benzoic acid was excreted by the rodents (rat, mouse, guinea pig, golden hamster, steppe lemming and gerbil), the rabbit, the cat and the capuchin monkey almost entirely as hippuric acid (95–100% of 24h excretion). 3. In man at a dose of 1mg/kg and the rhesus monkey at 20mg/kg benzoic acid was excreted entirely as hippuric acid. 4. At 50mg/kg benzoic acid was excreted as hippuric acid to the extent of about 80% of the 24h excretion in the squirrel monkey, pig, dog, ferret, hedgehog and pigeon, the other 20% being found as benzoyl glucuronide and benzoic acid, the latter possibly arising by decomposition of the former. 5. On increasing the dose of benzoic acid to 200mg/kg in the ferret, the proportion of benzoyl glucuronide excreted increased and that of hippuric acid decreased. This did not occur in the rabbit, which excreted 200mg/kg almost entirely as hippuric acid. It appears that the hedgehog and ferret are like the dog in respect to their metabolism of benzoic acid. 6. The Indian fruit bat produced only traces of hippuric acid and possibly has a defect in the glycine conjugation of benzoic acid. The main metabolite in this animal (dose 50mg/kg) was benzoyl glucuronide. 7. The chicken, side-necked turtle and gecko converted benzoic acid mainly into ornithuric acid, but all three species also excreted smaller amounts of hippuric acid.     

The structure of the glucuronide of sulphadimethoxine formed in man

1. The major metabolite of 2,4-dimethoxy-6-sulphanilamidopyrimidine (sulphadimethoxine) in urine in man is a non-reducing glucuronide, which has been isolated and characterized as its S-benzylthiouronium salt. 2. The same compound was made synthetically by standard methods from sodium sulphadimethoxine and methyl 2,3,4-tri-O-acetyl-1-bromoglucuronate. 3. On hydrolysis with acid, the glucuronide yielded sulphanilic acid, glucuronic acid and barbituric acid, and with beta-glucuronidase it slowly yielded sulphadimethoxine and glucuronic acid. 4. Evidence based on infrared spectra and other data showed that the urinary and synthetic glucuronide was 1-deoxy-1-[N(1)'-(2',4'-dimethoxypyrimidin-6' -yl)sulphanilamido-beta-d-glucosid]uronic acid or sulphadimethoxine N(1)-glucuronide. 5. N(1)-Methyl- and N(ring)-methyl derivatives of sulphadimethoxine and 4-methoxy-6-sulphanilamidopyrimidine were prepared and their infrared and ultraviolet spectra determined for comparison.     

Microbial production of cis,cis-muconic acid from benzoic acid

Summary The authors isolated numerous microorganisms with the capacity to assimilate large amounts of benzoate from many soil samples. Several of them were selected and subjected to mutation mainly by ultraviolet irradiation. One mutant lacking active muconate-lactonizing enzyme, the parent strain of which was identified as belonging to the genus Arthrobacter, was isolated and found to be capable of producing cis, cis-muconic acid with a quantitative yield of 44.1 g/l over 48 h in a 30 1 jar fermentor by successive feeding of small amounts of benzoate. This mutant, however, was more sensitive to high concentrations of the substrate than the parent strain. As few intermediates and isomers other than cis, cis-muconic acid were accumulated in the large fermentor, a large amount of pure cis, cis-muconic acid was easily obtained from the broth by salting out and recrystallization at a high recovery rate.     

Rates of cuticular penetration of 1-naphthylacetic acid (NAA) as affected by adjuvants, temperature, humidity and water quality

When NAA is used for fruit thinning, results can be unpredictable. Problemswith foliar penetration of NAA can contribute to this variability. Usingisolated pear leaf cuticles we have investigated effects of humidity,temperature, hard water and selected adjvants on rates of cuticularpenetration of NAA. If NAA was dissolved in deionised water about 40% ofthe applied dose penetrated in 8 h, while water having a pH > 7 practicallyeliminated cuticular penetration of NAA, even at high humidity (100%) andmoderate temperatures (20°C). Rates of penetration were much lowerat 10°C and 55% humidity. Adding urea, ammonium sulphate or Tween20 increased rates of penetration but not to a great extent. Highest rates ofpenetration were obtained when solutions were buffered at pH 4 with DL-lactic acid and the accelerator adjuvant Genapol C-100 was added. Withthis combination, about 70% of the applied NAA dose penetrated within 8 hat 20°C and 40% at 10°C, respectively, even at low humidity(55 to 60%) and when hard water was used as carrier. It is argued thatpoor performance of NAA as chemical thinner must be expected when hardwater is used for spraying and when the pH of the spray liquid is notadjusted to values around 4, such that a significant proportion of the NAAis non-ionised. Only non-ionised NAA can penetrate cuticles. Rates of foliarpenetration of NAA can be greatly increased, especially at low temperatures,by adding 0.2 to 2.0 g l^–1 Genapol C-100. Since NAA is destroyed byUV light, spraying should be done in the evening. High humidity during thenight is favourable for foliar penetration, but low temperatures aredetrimental and addition of an accelerator adjuvant (i.e. Genapol C-100) isnecessary. If NAA must be sprayed during cold weather (5–10°C),higher NAA concentrations may be used because rates of penetrationduring the night are proportional to dose and excess NAA left on the foliagewill be destroyed by UV light after sunrise.     

Effect of top excision and replacement by 1-naphthylacetic acid on partition and flow of potassium in tobacco plants

The effect of removal of the shoot apex of 92-d-old tobacco plants and its replacement by 1-naphthylacetic acid (NAA) on sink-source relationships and on the flows and partitioning of potassium and water has been studied over a short-term period of 7 d (intact control plants) or 8 d (decapitated and NAA-treated plants). For determining flows an upper, middle and lower stratum of three leaves each were analysed. Within the study period three new leaves were formed in control plants and 57.7% of the total dry matter increment during the experimental period was allocated to the apex and these newly formed leaves. An even higher proportion of the K+ taken up (93.8%) was deposited in these organs and this was imported via xylem (72%) and phloem (28%). Only 18.7% and 9.8% of the total dry matter increment were found in the previously present upper leaves and the roots, respectively, and substantial net K+ export occurred from middle and lower leaves and roots. Decapitation removed the dominant phloem sink and caused marked changes in sink-source relationships. After decapitation the net increase in root dry matter was twice that of control plants. 56.2% of the total net increments in dry matter and 70% of the absorbed K+ were deposited in upper leaves (below the excised apex). There was only slight net K+ export from the middle leaves. Application of NAA on the cut surface of the stem stump did not change the growth of plants that much, apart from a substantial increase in stem growth, correspondingly it stimulated the partitioning of K+ into the upper leaves and most dramatically into the stem, which deposited 64.5% or 27% of the K+ uptake, respectively. In these plants K+ uptake was increased and the K+ concentrations in upper, middle and lower leaves were increased from 4.7, 5.4 and 5.6 to 5.1, 6.1 and 6.1% of dry matter, respectively. Possible mechanisms of this effect of NAA on the improvement of K+ concentration in tobacco leaves are discussed in detail.