Inoculum cell count influences separation efficiency and variance in Ames plate incorporation and Ames RAMOS test

The Ames test is one of the most applied tools in mutagenicity testing of chemicals ever since its introduction by Ames et al. in the 1970s. Its principle is based on histidine auxotrophic bacteria that regain prototrophy through reverse mutations. In the presence of a mutagen, more reverse mutations occur that become visible as increased bacterial growth on medium without histidine. Many miniaturized formats of the Ames test have emerged to enable the testing of environmental water samples, increase experimental throughput, and lower the required amounts of test substances. However, most of these formats still rely on endpoint determinations. In contrast, the recently introduced Ames RAMOS test determines mutagenicity through online monitoring of the oxygen transfer rate. In this study, the oxygen transfer rate of Salmonella typhimurium TA100 during the Ames plate incorporation test was monitored and compared to the Ames RAMOS test to prove its validity further. Furthermore, the Ames RAMOS test in 96-well scale is newly introduced. For both the Ames plate incorporation and the Ames RAMOS test, the influence of the inoculum cell count on the negative control was highlighted: A lower inoculum cell count led to a higher coefficient of variation. However, a lower inoculum cell count also led to a higher separation efficiency in the Ames RAMOS test and, thus, to better detection of a mutagenic substance at lower concentrations.

Alternative type of Ames test allows for dynamic mutagenicity detection by online monitoring of respiration activity

The Ames test is the most commonly used mutagenicity test worldwide. It is based on a microbial system that uses histidine auxotrophic Salmonella typhimurium strains. Due to either spontaneous mutations or mutations induced by a mutagenic compound, the cells can regain their ability to grow without histidine supplementation. The degree of mutagenicity of a sample correlates with the number of cells that are able to grow in media that lack histidine. All test variants published up to now are endpoint determinations providing no information about cell growth and respiration activity during the cultivation time. This study aimed to develop an alternative type of Ames test by characterizing the respiration activity of Salmonella typhimurium over time for dynamic mutagenicity detection. It focuses on elucidating the mechanisms underlying this novel test system, and serves as a general proof of principle. Respiration activity (oxygen transfer and uptake rate) and biomass growth of Salmonella typhimurium TA 100 and TA 98 were mechanistically modeled to understand and predict the behavior of the bacteria during the Ames test. The results simulated by the model were experimentally validated by the online monitoring of respiration activity over cultivation time using a Respiration Activity MOnitoring System (RAMOS). The simulated prediction was observed to fit well to the experimental data. When a mutagenic compound was added, its mutagenicity could be detected online due to the elevated cell number and respiration of histidine prototrophic cells. Laborious manual evaluation of mutagenicity after cultivation is not necessary. Mutagenicity evaluation with the presented alternative Ames RAMOS test fitted well to results from an Ames fluctuation test. In the future, a miniaturized RAMOS device for microtiter plates should allow for a high-throughput Ames RAMOS test.

Optimization of the Ames RAMOS test allows for a reproducible high-throughput mutagenicity test

The Ames test is one of the most widely used mutagenicity tests. It employs histidine auxotrophic bacteria, which can mutate back to histidine prototrophy and, thus, grow on a histidine deficient medium. These mutants develop predominantly after adding a mutagenic compound during an initial growth phase on 1 mg/L histidine. In the established test systems, an endpoint determination is performed to determine the relative number of mutants. An alternative Ames test, the Ames RAMOS test, has been developed, which enables the online detection of mutagenicity by monitoring respiration activity. The reproducibility of the newly developed test system was investigated. A strong dependence of the test results on the inoculum volume transferred from the preculture was found. The more inoculum was needed to reach the required initial OD, the more mutagenic a positive control was evaluated. This effect was attributed to the histidine transfer from the preculture to the original Ames RAMOS test. The same problem is evident in the Ames fluctuation test. High reproducibility of the Ames RAMOS test could be achieved by performing the preculture on minimal medium with a defined histidine concentration and termination after histidine depletion. By using 5 mg/L initial histidine within the minimal medium, a higher separation efficiency between negative control and mutagenic samples could be achieved. This separation efficiency could be further increased by lowering the cultivation temperature from 37 to 30 °C, i.e. lowering the maximum growth rate. The optimized Ames RAMOS test was then transferred into a 48-well microtiter plate format (μRAMOS) for obtaining a high throughput test. The online detection of mutagenicity leads to a reduction of working time in the laboratory. Due to the optimization of reproducibility and the increase in separation efficiency, a sound mutagenicity evaluation, even of weak mutagenic compounds, can be achieved.

Beta-trace protein concentration in cerebrospinal fluid is decreased in patients with bacterial meningitis

Although meninges represent a major site of biosynthesis, beta-trace protein (beta-trace) has not been studied in the cerebrospinal fluid (CSF) of meningitis patients. We measured beta-trace in lumbar CSF of normal controls (n = 27) and in patients with various neurological diseases (n = 92) by an immunonephelometric assay. The mean concentration of beta-trace in CSF of control patients was 16.6+/-3.6 mg/l. In bacterial meningitis (n = 41), CSF beta-trace was significantly decreased (8.7+/-3.9 mg/l; P< 0.001), whereas in spinal canal stenosis it was elevated (29.2+/-10.3 mg/l; P= 0.002). In viral meningoencephalitis (n = 12), beta-trace CSF concentrations were normal. Beta-trace concentrations remained below the normal range even after curing of bacterial meningitis, and normalisation of CSF leucocytes and blood-CSF barrier function. Beta-trace may be a useful tool for studying the pathophysiology of bacterial meningitis.

An Fe2IVO2 diamond core structure for the key intermediate Q of methane monooxygenase

A new paradigm for oxygen activation is required for enzymes such as methane monooxygenase (MMO), for which catalysis depends on a nonheme diiron center instead of the more familiar Fe-porphyrin cofactor. On the basis of precedents from synthetic diiron complexes, a high-valent Fe2(micro-O)2 diamond core has been proposed as the key oxidizing species for MMO and other nonheme diiron enzymes such as ribonucleotide reductase and fatty acid desaturase. The presence of a single short Fe-O bond (1.77 angstroms) per Fe atom and an Fe-Fe distance of 2.46 angstroms in MMO reaction intermediate Q, obtained from extended x-ray absorption fine structure and Mössbauer analysis, provides spectroscopic evidence that the diiron center in Q has an Fe2IVO2 diamond core.

Selection effects on a linked neutral locus

Selection changes the frequency of alleles at a linked locus as well as at those under selection if the population is not in linkage equilibrium. The magnitude of this frequency change depends on the tightness of the linkage, the selection intensity, and the deviation from linkage equilibrium. Allowing a population to mate randomly without selection brings the population closer to linkage equilibrium. This decreases the effect of selection on allelic frequencies at a linked neutral locus. However, if linkage is very tight it can take many generations to make a large difference in the effect of the linked locus. The loss due to undesirable changes in allelic frequencies at linked loci when the population is not in linkage equilibrium must be weighed against the time and effort saved by beginning intense selection for the primary trait in an early generation. Effects of selection intensity, linkage intensity, and delayed selection on changes in allelic frequency at a neutral linked locus are demonstrated.