Carrie A. Hendricks

Spontaneous mitotic homologous recombination at an enhanced yellow fluorescent protein (EYFP) cDNA direct repeat in transgenic mice.

A transgenic mouse has been created that provides a powerful tool for revealing genetic and environmental factors that modulate mitotic homologous recombination. The fluorescent yellow direct-repeat (FYDR) mice described here carry two different copies of expression cassettes for truncated coding sequences of the enhanced yellow fluorescent protein (EYFP), arranged in tandem. Homologous recombination between these repeated elements can restore full-length EYFP coding sequence to yield a fluorescent phenotype, and the resulting fluorescent recombinant cells are rapidly quantifiable by flow cytometry. Analysis of genomic DNA from recombined FYDR cells shows that this mouse model detects gene conversions, and based on the arrangement of the integrated recombination substrate, unequal sister-chromatid exchanges and repair of collapsed replication forks are also expected to reconstitute EYFP coding sequence. The rate of spontaneous recombination in primary fibroblasts derived from adult ear tissue is 1.3 ± 0.1 per 106 cell divisions. Interestingly, the rate is ≈10-fold greater in fibroblasts derived from embryonic tissue. We observe an ≈15-fold increase in the frequency of recombinant cells in cultures of ear fibroblasts when exposed to mitomycin C, which is consistent with the ability of interstrand crosslinks to induce homologous recombination. In addition to studies of recombination in cultured primary cells, the frequency of recombinant cells present in skin was also measured by direct analysis of disaggregated cells. Thus, the FYDR mouse model can be used for studies of mitotic homologous recombination both in vitro and in vivo.

Three-dimensional tissue cytometer based on high-speed multiphoton microscopy.

Image cytometry technology has been extended to 3D based on high‐speed multiphoton microscopy. This technique allows in situ study of tissue specimens preserving important cell–cell and cell–extracellular matrix interactions. The imaging system was based on high‐speed multiphoton microscopy (HSMPM) for 3D deep tissue imaging with minimal photodamage. Using appropriate fluorescent labels and a specimen translation stage, we could quantify cellular and biochemical states of tissues in a high throughput manner. This approach could assay tissue structures with subcellular resolution down to a few hundred micrometers deep. Its throughput could be quantified by the rate of volume imaging: 1.45 mm3/h with high resolution. For a tissue containing tightly packed, stratified cellular layers, this rate corresponded to sampling about 200 cells/s. We characterized the performance of 3D tissue cytometer by quantifying rare cell populations in 2D and 3D specimens in vitro. The measured population ratios, which were obtained by image analysis, agreed well with the expected ratios down to the ratio of 1/105. This technology was also applied to the detection of rare skin structures based on endogenous fluorophores. Sebaceous glands and a cell cluster at the base of a hair follicle were identified. Finally, the 3D tissue cytometer was applied to detect rare cells that had undergone homologous mitotic recombination in a novel transgenic mouse model, where recombination events could result in the expression of enhanced yellow fluorescent protein in the cells. 3D tissue cytometry based on HSMPM demonstrated its screening capability with high sensitivity and showed the possibility of studying cellular and biochemical states in tissues in situ. This technique will significantly expand the scope of cytometric studies to the biomedical problems where spatial and chemical relationships between cells and their tissue environments are important.

Age-dependent accumulation of recombinant cells in the mouse pancreas revealed by in situ fluorescence imaging.

Mitotic homologous recombination (HR) is critical for the repair of double-strand breaks, and conditions that stimulate HR are associated with an increased risk of deleterious sequence rearrangements that can promote cancer. Because of the difficulty of assessing HR in mammals, little is known about HR activity in mammalian tissues or about the effects of cancer risk factors on HR in vivo. To study HR in vivo, we have used fluorescent yellow direct repeat mice, in which an HR event at a transgene yields a fluorescent phenotype. Results show that HR is an active pathway in the pancreas throughout life, that HR is induced in vivo by exposure to a cancer chemotherapeutic agent, and that recombinant cells accumulate with age in pancreatic tissue. Furthermore, we developed an in situ imaging approach that reveals an increase in both the frequency and the sizes of isolated recombinant cell clusters with age, indicating that both de novo recombination events and clonal expansion contribute to the accumulation of recombinant cells with age. This work demonstrates that aging and exposure to a cancer chemotherapeutic agent increase the frequency of recombinant cells in the pancreas, and it also provides a rapid method for revealing additional factors that modulate HR and clonal expansion in vivo.

A single acute exposure to a chemotherapeutic agent induces hyper-recombination in distantly descendant cells and in their neighbors

Homologous recombination can induce tumorigenic sequence rearrangements. Here, we show that persistent hyper-recombination can be induced following exposure to a bifunctional alkylating agent, mitomycin C (MMC), and that the progeny of exposed cells induce a hyper-recombination phenotype in unexposed neighboring cells. Residual damage cannot be the cause of delayed recombination events, since recombination is observed after drug and template damage are diluted over a million-fold. Furthermore, not only do progeny of MMC-exposed cells induce recombination in unexposed cells (bystanders), but these bystanders can in turn induce recombination in their unexposed neighbors. Thus, a signal to induce homologous recombination can be passed from cell to cell. Although the underlying molecular mechanism is not yet known, these studies reveal that cells suffer consequences of damage long after exposure, and that can signal unexposed neighboring cells to respond similarly. Thus, a single acute exposure to a chemotherapeutic agent can cause long-term changes in genomic stability. If the results of these studies of mouse embryonic stem (ES) cells are generally applicable to many cell types, these results suggest that a relatively small number of cells could potentially induce a tissue-wide increase in the risk of de novo homologous recombination events.

The S. cerevisiae Mag1 3-methyladenine DNA glycosylase modulates susceptibility to homologous recombination.

DNA glycosylases, such as the Mag1 3-methyladenine (3MeA) DNA glycosylase, initiate the base excision repair (BER) pathway by removing damaged bases to create abasic apurinic/apyrimidinic (AP) sites that are subsequently repaired by downstream BER enzymes. Although unrepaired base damage may be mutagenic or recombinogenic, BER intermediates (e.g. AP sites and strand breaks) may also be problematic. To investigate the molecular basis for methylation-induced homologous recombination events in Saccharomyces cerevisiae, spontaneous and methylation-induced recombination were studied in strains with varied MAG1 expression levels. We show that cells lacking Mag1 have increased susceptibility to methylation-induced recombination, and that disruption of nucleotide excision repair (NER; rad4) in mag1 cells increases cellular susceptibility to these events. Furthermore, expression of Escherichia coli Tag 3MeA DNA glycosylase suppresses recombination events, providing strong evidence that unrepaired 3MeA lesions induce recombination. Disruption of REV3 (required for polymerase zeta (Pol zeta)) in mag1 rad4 cells causes increased susceptibility to methylation-induced toxicity and recombination, suggesting that Pol zeta can replicate past 3MeAs. However, at subtoxic levels of methylation damage, disruption of REV3 suppresses methylation-induced recombination, indicating that the effects of Pol zeta on recombination are highly dose-dependent. We also show that overproduction of Mag1 can increase the levels of spontaneous recombination, presumably due to increased levels of BER intermediates. However, additional APN1 endonuclease expression or disruption of REV3 does not affect MAG1-induced recombination, suggesting that downstream BER intermediates (e.g. single strand breaks) are responsible for MAG1-induced recombination, rather than uncleaved AP sites. Thus, too little Mag1 sensitizes cells to methylation-induced recombination, while too much Mag1 can put cells at risk of recombination induced by single strand breaks formed during BER.

Applications of fluorescence for detecting rare sequence rearrangements in vivo.

Homologous recombination (HR) is an important pathway for the accurate repair of potentially cytotoxic or mutagenic double strand breaks (DSBs), as well as double strand ends that arise due to replication fork breakdown. Thus, measuring HR events can provide information on conditions that induce DSB formation and replicative stress. To study HR events in vivo, we previously developed Fluorescent Yellow Direct Repeat (FYDR) mice in which a recombination event at an integrated transgene yields a fluorescent signal. Recently, we published an application of these mice demonstrating that fluorescent recombinant cells can be directly detected within intact pancreatic tissue. Here, we show that in situ imaging is a more sensitive method for detecting exposure-induced recombinant cells, yielding statistical significance with smaller cohorts. In addition, we show inter-mouse and gender-dependent variation in transgene expression, examine its impact on data interpretation, and discuss solutions to overcoming the effects of such variation. Finally, we also present data on EYFP expression, showing that several tissues, in addition to the pancreas, may be amenable for in situ detection of recombinant cells in the FYDR mice. The FYDR mice provide a unique tool for identifying genetic conditions and environmental exposures that induce genotoxic stress in a variety of tissues.

Tissue-specific differences in the accumulation of sequence rearrangements with age.

Mitotic homologous recombination (HR) is a critical pathway for the accurate repair of DNA double strand breaks (DSBs) and broken replication forks. While generally error-free, HR can occur between misaligned sequences, resulting in deleterious sequence rearrangements that can contribute to cancer and aging. To learn more about the extent to which HR occurs in different tissues during the aging process, we used Fluorescent Yellow Direct Repeat (FYDR) mice in which an HR event in a transgene yields a fluorescent phenotype. Here, we show tissue-specific differences in the accumulation of recombinant cells with age. Unlike pancreas, which shows a dramatic 23-fold increase in recombinant cell frequency with age, skin shows no increase in vivo. In vitro studies indicate that juvenile and aged primary fibroblasts are similarly able to undergo HR in response to endogenous and exogenous DNA damage. Therefore, the lack of recombinant cell accumulation in the skin is most likely not due to an inability to undergo de novo HR events. We propose that tissue-specific differences in the accumulation of recombinant cells with age result from differences in the ability of recombinant cells to persist and clonally expand within tissues.

Three-dimensional image cytometer based on a high-speed two-photon scanning microscope

We developed a 3-D image cytometer based on two-photon scanning microscopy. The system keeps the inherent advantages from two-photon scanning microscopy: (1) The ability of imaging thick tissue samples up to a few hundred micrometers, (2) The ability to study tissue structures with subcellular resolution, (3) The ability to monitor tissue biochemistry and metabolism, and (4) The reduction of specimen photobleaching and photodamage. Therefore, 3-D image cytometer has the ability to characterize multiple cell layer specimens, in contrast with 2-D image cytometer where only single cell layer samples can be imaged. 3-D image cytometry increases its frame rate by adapting a polygonal mirror scanner and high-speed photomultiplier tubes. The current frame rate is 13 frames per second. High throughput rate is achieved by imaging multiple cell layer specimens in 3-D at a high frame rate. The throughput rate of this system is dependent on the choice of objective lenses, specimen properties, and the speed of computer-controlled specimen stage. It can be up to approximately 100 cells per second which is comparable with that of 2-D image cytometers. With the high throughput rate and deep tissue imaging capability, 3-D image cytometer has the potential for the detection of rare cellular events inside living, intact tissues. A promising application of this 3-D image cytometer is the study of mitotic recombination in tissues. Mitotic recombination is a mechanism for genetic change. Therefore it is one of causes for carcinogenesis. However, the study of this process is difficult because recombination event is rare and it occurs at a rate of one cell in 105 cells. The new method for the study is (1) to engineer transgenic mice whose cells will express fluorescence in the presence of mitotic recombination, (2) to detect cells which have undergone mitotic recombination with 3-D image cytometry. The estimated time required to quantify spontaneous recombination rate is approximately within a few hours in the case that the mutation occurs at a rate of 1/105. The ability of this 3-D image cytometer to resolve tissue structures at video rate was demonstrated in the study of ex vivo human skin dermal structure. 25 X 25 section images were taken by shifting the acquisition region with computer- controlled specimen stage. Wide area images were reconstructed by combining each image sections. The size of complete wide area images is approximately 25 mm X 25 mm. We further performed experiments to verify this cytometers ability for population statistics measurement. We prepared cell cultures containing a mixture of cells expressing cyan and yellow fluorescent proteins. These cell cultures with mixing ratio ranging from 1/10 up to 1/105 were imaged. Experimental results show that the presence of a few rare cells in large pool of the other cells can be quantitatively measured. We also imaged a punched ear specimen from a transgenic mouse which carries green fluorescent protein. The data demonstrates that this system can resolve a single green fluorescent cells in the tissue.