The prostaglandins of articular cartilage I. Correlates of prostaglandin activity in a chondrocyte culture system

Suspensions of aggregated chondrocytes display active prostaglandin (PG) production. Radioimmunoassay of culture media and thin layer chromatographic analysis suggests that PGE₂ is the primary PG synthesized. In order of decreasing concentration, the following PG were tentatively identified; PGE> PGI> PGA + PGB PGF₁₊₂ > T×B. An inverse logarithmic relationship was identified between PG synthesis and cells cultured at densities of 1.5 to 7.5 × 10⁶ cells/ml. Little or no change in the PG distribution profile was seen at these high cell densities. Maximum PG synthesis was attained after 36 hours of incubation with persistence of high synthetic levels up to 48 hours. PGE₂ production measured at various post-isolation intervals indicated an initial high rate of synthesis during the first 4 hours which decreased with time up to 24 hours. Cartilage explant organ cultures demonstrated a similar level of PG synthesis suggesting minimal effect of matrix on cellular PG production. Indomethacin (5 μg/ml) inhibited PG synthesis by 70% within 4 hours and 85% after 24 hours of exposure. Arachidonic acid supplementation (10 μM) stimulated PG synthesis by 300%.     

Bacterial Counts and Quality of Iced Fish Retailed at a Lusaka Market, Zambia

S ummary . The counts of total viable, coliform, streptococcal and sulphite reducing anaerobic bacteria and the presence of salmonellae were determined on 134 iced fish obtained from Luburma Market, Lusaka, Zambia, during June-December 1970. The quality of the uncooked fish was also assessed by appearance and odour. The purpose of these determinations was to obtain a picture of the variations of the bacterial counts in relation to season, origin, fish species and market quality. Total viable and coliform counts were of the order of millions and tens of thousands/cm² of skin surface, respectively. Higher counts were obtained in the hot season during September-October but with little change in appearance of the fish. There was a significant correlation ( P < 0·01) of both total viable and coliform bacteria with quality scores. A maximum permissible level of 10⁷ cells/cm² of skin surface was proposed for total viable counts and 10⁵/cm² for coliform bacteria, for iced fish of acceptable quality in Zambia.     

Physiological, morphological, and physicochemical characterization of a novel Escherichia coli bacteriophage, phage MM

A double-stranded DNA containing, T even-like, Escherichia coli bacteriophage, called MM, has been isolated from the local sewage and purified by polyethylene glycol precipitation followed by banding on a cesium chloride three-step gradient. It yields a burst size of 75 particles per infected cell, and has an adsorption coefficient of 3.3 x 10(-10) cm3/min and a latent period of 45 min. Electron microscopy of phage MM reveals an isometric icosahedral head, 92 nm long and 81 nm wide, and a 112-nm-long contractile tail with six pairs of 40-nm-long fibers attached to its baseplate. Phage MM appears similar to E. coli phage T4 or Salmonella phage O1. The density of phage MM in cesium chloride is 1.515 g/ml, and its total mass is 144 MDa. Gel electrophoresis of purified MM capsids displays two major capsid proteins in approximately equimolar amounts and with apparent molecular masses of 38 and 15 kDa. Similarly, purified MM tails yield two major polypeptides with apparent molecular masses of 55 and 16 kDa, most likely representing the major tail sheath and tail tube polypeptides. Its double-stranded DNA has a G-C content of 50%, a length of 131 kilobases (kb), and a mass of 89 MDa.     

Mass analysis of bacteriophage T4 proheads and mature heads by scanning transmission electron microscopy and hydrodynamic measurements.

Quantitative mass analysis of bacteriophage T4 proheads by scanning transmission electron microscopy (STEM) revealed a mass of 79.5 +/- 0.6 MDa, while hydrodynamic measurements yielded a prohead mass of about 80 MDa. This is 25% less than the prohead mass deduced from its polypeptide composition, and this finding implies that the bacteriophage T4 prohead is built of fewer polypeptide copies than previously reported. In contrast, the mass of mature heads measured by STEM, 194 +/- 2 MDa, is in agreement with previous mass measurements of DNA and protein content, and it is consistent with the previously determined stoichiometry. This good agreement of average STEM values for proheads and mature heads with corresponding hydrodynamic measurements suggests that STEM allows faithful evaluation of the masses of large supramolecular assemblies (i.e., greater than or equal to 200 MDa) such as whole viruses or cellular organelles.     

Involvement of the bacterial groM gene product in bacteriophage T7 reproduction. II. A reduced level of ion concentrations causes the blockage of T7 maturation in K-12-M cells

Cellular leakage observed in Escherichia coli K-12-M shortly after T7 infection might be the cause of arrested phage morphogenesis. We observed in this strain, but not in the normal host, a drastic reduction of the intracellular concentration of potassium (60%), magnesium (40%), putrescine (90%), and spermidine (40%), whereas ATP was not significantly reduced. Leakage started about 1 min after the addition of phage and was arrested 3 to 5 min postinfection. Larger molecules such as o-nitrophenyl-beta-D-galactopyranoside could not enter the cells, showing that the permeability of the membrane was not generally affected. To prevent their leakage, we increased the outside concentrations of several small molecules and ions. The yield of progeny phage was substantially increased by the addition of 100 mM MgSO4.     

The bacterial nucleoid revisited.

This review compares the results of different methods of investigating the morphology of nucleoids of bacteria grown under conditions favoring short generation times. We consider the evidence from fixed and stained specimens, from phase-contrast and fluorescence microscopy of growing bacteria, and from electron microscopy of whole as well as thinly sectioned ones. It is concluded that the nucleoid of growing cells is in a dynamic state: part of the chromatin is "pulled out" of the bulk of the nucleoid in order to be transcribed. This activity is performed by excrescences which extend far into the cytoplasm so as to reach the maximum of available ribosomes. Different means of fixation provide markedly different views of the texture of the DNA-containing plasm of the bulk of the nucleoid. Conventional chemical fixatives stabilize the cytoplasm of bacteria but not their protein-low chromatin. Uranyl acetate does cross-link the latter well but only if the cytoplasm has first been fixed conventionally. In the interval between the two fixations, the DNA arranges itself in liquid-crystalline form, supposedly because of loss of supercoiling. In stark contrast, cryofixation preserves bacterial chromatin in a finely granular form, believed to reflect its native strongly negatively supercoiled state. In dinoflagellates the DNA of their permanently visible chromosomes (also low in histone-like protein) is natively present as a liquid crystal. The arrangement of chromatin in Epulocystis fishelsoni, one of the largest known prokaryotes, is briefly described.     

Considérations quantitatives sur des coupes ultraminces de bactéries infectées par un bactériophage

A quantitative relationship has been established between the number of particles, for example bacteriophages, counted in ultrathin sections of bacteria and the total number present in the whole bacterial cells. The factor F relating particles counted per section with the total number of these particles per entire bacterium could be arrived at by two methods, which proved to give results in close agreement. The first involves knowledge of the average volume of a bacterial section in proportion to the average volume of a whole bacterium; if the mean number of appearances of the same particle on consecutive sections is also known, F may then be calculated. The thickness of sections and, therefore, their volume, as well as the average number of times a single particle is sectioned could be learned by examination of serial sections. By counting the relative number of T2 phage particles which had been intersected once or twice, and relating this proportion to the known phage dimensions, the thickness of the sections was determined to be about 400 A. The second measurement of F could be made in a particular case of late phage development where the number of particles per cell was countable or titratable directly in the bacterial lysate, this number being compared with the number seen in sections of the bacteria just before lysis. The different sources of errors are discussed. The statistical error is under 20 per cent, while the systematic errors are higher and cannot yet be indicated precisely. After a very cautious estimation of the upper limits, we can state, however, that the counts made with this method are certainly reliable to well within a factor of two.