Measuring DNA content in live cells by fluorescence microscopy

Background

Live-cell fluorescence microscopy (LCFM) is a powerful tool used to investigate cellular dynamics in real time. However, the capacity to simultaneously measure DNA content in cells being tracked over time remains challenged by dye-associated toxicities. The ability to measure DNA content in single cells by means of LCFM would allow cellular stage and ploidy to be coupled with a variety of imaging directed analyses. Here we describe a widely applicable nontoxic approach for measuring DNA content in live cells by fluorescence microscopy. This method relies on introducing a live-cell membrane-permeant DNA fluorophore, such as Hoechst 33342, into the culture medium of cells at the end of any live-cell imaging experiment and measuring each cell’s integrated nuclear fluorescence to quantify DNA content. Importantly, our method overcomes the toxicity and induction of DNA damage typically caused by live-cell dyes through strategic timing of adding the dye to the cultures; allowing unperturbed cells to be imaged for any interval of time before quantifying their DNA content. We assess the performance of our method empirically and discuss adaptations that can be implemented using this technique.

Results

Presented in conjunction with cells expressing a histone 2B-GFP fusion protein (H2B-GFP), we demonstrated how this method enabled chromosomal segregation errors to be tracked in cells as they progressed through cellular division that were later identified as either diploid or polyploid. We also describe and provide an automated Matlab-derived algorithm that measures the integrated nuclear fluorescence in each cell and subsequently plots these measurements into a cell cycle histogram for each frame imaged. The algorithm’s accurate assessment of DNA content was validated by parallel flow cytometric studies.

Conclusions

This method allows the examination of single-cell dynamics to be correlated with cellular stage and ploidy in a high-throughput fashion. The approach is suitable for any standard epifluorescence microscope equipped with a stable illumination source and either a stage-top incubator or an enclosed live-cell incubation chamber. Collectively, we anticipate that this method will allow high-resolution microscopic analysis of cellular processes involving cell cycle progression, such as checkpoint activation, DNA replication, and cellular division.

     

Effect of gonadotropin-releasing hormone on fertility in repeat-breeder California dairy cows

To assess the potential benefit to fertility from gonadotropin-releasing hormone (GnRH) administration to third service cows managed in typical California dairy systems, 963 cows were enlisted from 14 dairies served by 6 veterinary practices. The cows were randomly assigned to receive either GnRH (100 mug) or placebo at the time of the third artificial insemination. Fertility data were entered onto a proprietary microcomputer program common to all six practices, and collated independently by a third party. For the duration of the trial (1 yr), GnRH and placebo-treated cows had 43.2 and 39.3% conception rates, respectively (P=0.35). When treatments administered in summer months (July, August, September) were excluded, conception rates were 48.1 and 41.0%, respectively (P<0.1). The conception rates of cows treated with GnRH in August tended to be lower than those of placebo-treated cows (95% logarithmic confidence intervals of odds ratio = -1.139, 0.377). Between-herd variation in benefit from GnRH was evident, with two dairies showing no benefit, one dairy showing a negative effect, and four showing a range of effects from lightly beneficial to significantly beneficial. First-lactation cows did not benefit at any time from GnRH treatment. The data suggest that GnRH administered to third-service dairy cows under California conditions may result in increased conception rates in non-summer months, but that other unidentified variables may have important influence on the outcome of such treatment.     

Acetaminophen toxicity results in site-specific mitochondrial damage in isolated mouse hepatocytes

Exposure of isolated mouse hepatocytes to a toxic concentration of acetaminophen (5 mM) resulted in damage to the mitochondrial respiratory apparatus. The nature of this damage was investigated by measuring respiration stimulated by site-specific substrates in digitonin-permeabilized hepatocytes after acetaminophen exposure. Respiration stimulated by succinate at energy-coupling site 2 was most sensitive to inhibition and was decreased by 47% after 1 h. Respiration supported by NADH-linked substrates (site 1) was also decreased but to a lesser extent, while there was no decrease in the rate of ascorbate + N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD)-supported respiration (site 3). The loss of mitochondrial respiratory function was accompanied by a decrease in ATP levels and ATP/ADP ratios in the cytosolic compartment and was preceded by a loss of reduced glutathione in both the cytosol and mitochondria. All these effects occurred well before the loss of cell membrane integrity. The putative toxic metabolite of acetaminophen, N-acetyl-p-benzoquinonimine (NAPQI), produced a similar pattern of respiratory dysfunction in isolated hepatic mitochondria. Respiration stimulated by succinate- and NADH-linked substrates was very sensitive to 50 microM NAPQI, while ascorbate + TMPD-supported respiration was unaffected. The interaction between NAPQI and the respiratory chain was further investigated using submitochondrial particles. Succinate dehydrogenase (associated with respiratory complex II) was found to be very sensitive to NAPQI, while NADH dehydrogenase (respiratory complex I) was inhibited to a lesser extent. Our results indicate that a loss of the ability to utilize succinate- and NADH-linked substrates due to attack of the respiratory chain by NAPQI causes a disruption of energy homeostasis in acetaminophen hepatotoxicity.     

Enhanced enzymatic hydrolysis of langostino shell chitin with mixtures of enzymes from bacterial and fungal sources

A combination of enzyme preparations from Trichoderma atroviride and Serratia marcescens was able to completely degrade high concentrations (100 g/L) of chitin from langostino crab shells to N-acetylglucosamine (78%), glucosamine (2%), and chitobiose (10%). The result was achieved at 32 degrees C in 12 days with no pre-treatment (size reduction or swelling) of the substrate and without removal of the inhibitory end-products from the mixture. Enzymatic degradation of three forms of chitin by Serratia/Trichoderma and Streptomyces/Trichoderma blends was carried out according to a simplex-lattice mixture design. Fitted polynomial models indicated that there was synergy between prokaryotic and fungal enzymes for both hydrolysis of crab chitin and reduction of turbidity of colloidal chitin (primarily endo-type activity). Prokaryotic/fungal enzymes were not synergistic in degrading chitosan. Enzymes from prokaryotic sources had much lower activity against chitosan than enzymes from T. atroviride.     

Biological and Integrated Control of Botrytis Bunch Rot of Grape UsingTrichodermaspp.

Field trials were carried out in upstate New York in 1990, 1992, 1993, and 1994 and in Chile in 1992–1993 and 1993–1994 in order to evaluate the ability of various strains ofTrichodermaspp. to control bunch rot of grape, to assess the compatibility and possible additive effects of selected biocontrol fungi and dicarboximide fungicides, and to determine factors affecting biocontrol efficacy. In 1990, three strains ofTrichodermaspp. were evaluated for their biocontrol ability, and all provided significant control ofBotrytis cinerea.As few as two late applications of the biocontrol fungi were nearly as effective as up to five applications throughout bloom and fruit development. Trials in New York in 1992 and in Chile in 1992–1993 indicated thatTrichoderma harzianumcould replace some applications of iprodione or vinclozolin with little reduction in efficacy. In New York in 1993, we found that applications ofT. harzianumat bloom and early fruit development followed by a tank-mix application ofT. harzianumand half rates of iprodione gave extremely effective control of bunch rot. In 1994, less effective control was obtained than in earlier years. Addition of a nutritive adhesive (Pelgel, a mixture of carboxymethyl cellulose and gum arabic) applied with the biocontrol agent tended to improve results. Thus, biological control of bunch rot of grape withT. harzianumcan be an effective method of management of this disease.