Spot-blot analysis of sorted chromosomes assigns a fructose intolerance disease locus to chromosome 9

The aldolase B gene was mapped to chromosome 9 using a rapid gene mapping system. This system uses a dual-laser sorter to identify and separate metaphase human chromosomes stained with either DIPI-chromomycin or Hoechst-chromomycin. Chromosome panels were constructed from a normal cell line by sorting 22 chromosome fractions directly onto nitrocellulose filters. Twelve labeled gene probes hybridized to the sorted chromosomal DNA fractions predicted by previous chromosome assignments. Eighteen newly cloned genes have been mapped using the same protocol.     

Optimising human chromosome separation for the production of chromosome-specific DNA libraries by flow sorting

Summary A number of cell lines, some containing chromosomes with distinctive heteromorphisms, have been flow karyotyped using a single laser flow sorter in an attempt to select those suitable for sorting all human chromosomes individually. Using the non-base-specific DNA stain ethidium bromide, chromosomes 3,4,5, and 6 form individual peaks in practically all normal subjects, while the right combination of heteromorphisms enables chromosomes 1, 2, 8, 9, 13, 16, 17, 18, 19, 20, 21, 22, and Y to be sorted separately. Two male cell lines, one containing a duplication and one a deletion of the X, produce flow karyotypes suitable for sorting chromosomes 7 and 8. The use of numerical chromosome abnormalities to enrich the sex chromosomes and the autosomes 18 and 21 is also illustrated. The DNA stain Hoechst 33258 binds preferentially to AT base pairs. Flow karyotypes produced with this fluorochrome separate some chromosomes not well separated with ethidium bromide. Chromosomes 5, 6, 8, 13, 14, 15, 17, and 20, and Y can be sorted individually with Hoechst 33258 with the right combination of heteromorphisms. Using these techniques, all human chromosomes apart from 10, 11, and 12 have been found as individual flow karyotype peaks, suitable for sorting with a high degree of purity.     

High-speed photodamage cell selection using bromodeoxyuridine/Hoechst 33342 photosensitized cell killing

One of the major drawbacks of droplet sorting in a flow cytometer is the relatively low sorting speed. Thus, we have developed an alternative, faster sorting technique: photodamage cell sorting. In a photodamage cell sorter all unwanted cells, as detected with the first, measuring laser, are killed with the second, damaging laser. Thus, the cells need to be photosensitive to the second laser. In addition, a mechanism is needed to switch this laser on and off based on the sorting criteria. In our photodamage cell sorter, the ZAPPER, we use an acousto-optic crystal to switch the laser beam. Cells are made photosensitive by vital staining with photosensitizers. With cells grown in the presence of 5-bromo-2'-deoxyuridine (BrdUrd) and stained with Hoechst 33342 (H42) at least a 5-decade cell reduction is accomplished after irradiation with 400 mW UV light. With this system, sorting rates have been achieved of 30,000 cells per second. Due to the selection based on photodynamic killing, this sorting technique is restricted to the selection of viable cells. Photodamage cell sorting seems well suited for isolating viable cells occurring in low percentages or for the sorting of large numbers of cells. Another application can be the sorting of large or fragile cells.     

Dual-laser flow cytometry of single mammalian cells.

An improved dual-laser flow cytometric system for quantitative analysis and sorting of mammalian cells has been developed using a low-power argon and high-power krypton laser as illumination sources, thus permitting the excitation of fluorescent dyes having absorption regions ranging from the ultraviolet to infrared. Cells stained in liquid suspension with fluorescent dyes enter a flow chamber where they intersect two spatially separated laser beams. Separate pairs of quartz beam-shaping optics focus each beam onto the cell stream. Electro-optical sensors measure fluorescence and light scatter signals from cells that are processed electronically and displayed as frequency distribution histograms. Cells also can be electronically separated and microscopically identified. The ease and versatility of operation designed into this system represent a marked technological improvement for dual-laser excited flow systems. Details of this instrument are described along with illustrative examples of cells stained with mithramycin and rhodamine and analyzed for DNA content, total protein, and nuclear and cytoplasmic diameter.     

Modification of a commercial cell sorter to support efficient and reliable preparation of ALDH-bright cells for clinical use

BACKGROUND: Cell populations manufactured by conventional commercial cell sorters have been safely infused into patients, but reliably sterilizing these instruments remains challenging. We are developing clinical protocols involving use of ALDH bright cells manufactured by cell sorting in patients. However, we encountered problems when we attempted to reliably sterilize the FACSAria cell sorter using standard methods. RESULTS: We have identified and modified potential sources of microbial contamination in several FACSAria systems. We added new filter systems to the sheath and sample air lines, to the wet cart fluid supply, and to the sample line. Sheath was provided from an external sterile, disposable bag through sterile disposable tubing sets. The plenum reservoirs were modified in several ways to allow efficient decontamination of internal surfaces. A new bubble filter assembly was added and one valve was eliminated from the sample pathway to improve flow cell sterilization. A new cleaning and sterilization protocol was developed and validated. All cell products manufactured using the modified instrument and validated cleaning protocol have met lot release criteria for prevention of microbial contamination and safe clinical use. DISCUSSION: The instrument modification and cleaning protocol described enable reliable manufacture of ALDH bright cell populations that are suitable for clinical trials. We have manufactured nineteen consecutive samples that meet all clinical release criteria in an on-going Phase 1 human trial.     

Mammalian artificial chromosome pilot production facility: large-scale isolation of functional satellite DNA-based artificial chromosomes.

BACKGROUND: A pilot production facility has been established to isolate mammillian artificial chromosomes at high purity by using flow cytometric techniques. Dicentric chromosomes have been generated by the targeted amplification of pericentric heterochromatic and centromeric DNA by activating the "megareplicator." Breakage of these dicentric chromosomes generates satellite DNA-based artificial chromosomes (SATAC) from 60 to 400 megabases. METHODS: For large-scale production, we have developed cell lines capable of carrying one or two SATACs. A SATAC, because of a high adenine-thymine (AT) composition, is easily identified and sorted by using chromomycin A3 and Hoechst 33258 stains and a dual laser high-speed flow cytometer. A prototype SATAC (60 megabases) has been characterized. The prototype SATAC has been isolated from an original rodent/human hybrid cell line and transferred by using modified microcell fusion into a CHO production cell line. RESULTS: Metaphase chromosomes from this production cell line were isolated in a modified polyamine buffer, stained, and sorted by using a modified sheath buffer that maintains condensed chromosomes. SATACs are routinely sorted at rates greater than 1 million per hour. Sorted SATACs have been transferred to a variety of cells by using microcell fusion technology and were found to be functional. CONCLUSIONS: By developing new SATAC containing cell lines with fewer numbers of chromosomes in conjunction with operating a high speed flow sorter we have effectively generated an efficient production facility geared purely for the isolation of SATACs.     

Alignment and focusing unit for dual-laser excitation in the fluorescence-activated cell sorter

The two laser beams in a dual-laser fluorescence-activated cell sorter FACS-II can be aligned and focused independently on the sample stream with an additional unit, which can be fitted easily on the optical bench of the FACS. The unit consists of two spherical lenses, which have been mounted in separate holders and can be moved in three directions by way of micrometer gauges. The lenses, which have different focal lengths, have been cut off on one side so each laser beam only passes one lens. The setup has been tested using the flow analysis of a suspension of double-stained chicken red blood cells. The histograms of both fluorescence signals showed normal distributions with a coefficient of variation of approximately 6%. After willful interference with the adjustments, the laser beams could be readily readjusted within five minutes.     

Flow analysis and sorting of microchromosomes (<3 Mb)

BACKGROUND: The analysis and isolation of high numbers of chromosomes smaller than 3 Mb in size (microchromosomes) with good purity is dependent primarily on the detection sensitivity of the flow cytometer and the precision of the sort unit. The aim of this study was to investigate the capability of using a conventional flow cytometer for the detection and sorting at high purity microchromosomes with an estimated size of 2.7 Mb. METHODS: Chromosomes were isolated from a human cell line containing a pair of X-derived microchromosomes, using a modified polyamine isolation buffer. The chromosome preparation was labeled with Hoechst and Chromomycin and analyzed and purified using a MoFlo sorter (DAKO) configured for high-speed sorting. The purity of the flow-sorted microchromosomes was assessed by reverse chromosome painting. RESULTS: Improved resolution of the peak of microchromosomes in a bivariate plot of Hoechst versus Chromomycin fluorescence was obtainable after discriminating clumps and debris based on gating data within a FSC versus pulse width plot. CONCLUSIONS: Chromosomes of smaller size, less than 3 Mb, can be detected with high resolution and flow-sorted with high purity using a conventional flow sorter.     

Isolation of giant DNA fragments from flow-sorted human chromosomes

We have established a method using a conventional cell sorter equipped with a single argon laser to sort intact human chromosomes that can be used as a source for the production of giant DNA fragments. Various improvements were made to both the equipment and sorting method to enhance the sorting resolution and avoid destruction of chromosomal DNA. Using this improved method chromosomes 21 and 22 were sorted from the B-lymphoblastoid line GM00130B, digested with the rare cutting restriction endonuclease NotI, and analyzed by pulsed field gel electrophoresis followed by Southern hybridization using the Alu repetitive sequence as a probe. More than 25 discrete NotI giant DNA fragments ranging from 50 kb to longer than 2.5 Mb were separated and the size distribution pattern was unique for each chromosome, indicating successful sorting of intact chromosomes. The cumulative size of these Alu-positive NotI DNA fragments were 22.7 Mb and 25.5 Mb for chromosomes 21 and 22, respectively. These values are 47% and 49% of the estimated size of chromosomes 21 (48 Mb) and 22 (52 Mb).     

Instrument for real-time pulse-shape analysis of slit-scan flow cytometry signals

An instrument is described which analyses shapes of fluorescence profiles generated by particles passing through the focussed laser beam of a flow cytometer. The output signal of this pulse-shape analyzer is used as input for the signal processing electronics of a commercial flow cytometer system. The instrument detects dips in pulse-profiles; a shape parameter named Pulse Dip Index (PDI) is defined as the ratio of the integrated signal from the beginning of the pulse until the first dip, relative to the integrated signal of the complete profile. This PDI is similar to the Centromeric Index of chromosomes. The composition of aggregates in mixtures of fluorescent particles of different sizes was evaluated by PDI analysis. In our experiments the PDI was determined within 30 microseconds from the onset of the pulse-profile and particles with a specified morphology of interest were selected for on-line registration of their profiles as digitized pulse-shapes. In a cell sorter system, the PDI can be used as a parameter for sorting.     

The thyroglobulin gene resides on chromosome 8 in man and on chromosome 7 in the rat

Human chromosomes were separated by a dual laser FACS sorter and their DNA hybridized with a thyroglobulin gene probe. A strong hybridization signal was obtained with DNA from chromosome 8. A panel of mouse-rat cell hybrids was used to determine the chromosomal localization of the rat thyroglobulin gene by the Southern blotting method. Comparison of the cytogenetic data with the hybridization signals obtained with the rat thyroglobulin probe allowed assignment of this gene to rat chromosome 7. It is concluded that the synteny relationship between the thyroglobulin gene and the c-myc oncogene has been conserved in rat and man.     

Counterstaining human chromosomes for flow karyology

Isolated human metaphase chromosomes stained with the fluorochromes 4'-6-diamidino-2-phenylindole (DAPI) and chromomycin A3(CA3), and counterstained with nonfluorescent netropsin (NTR), have been analyzed by dual-laser flow cytometry. Counterstaining with NTR reduces DAPI fluorescence except at regions on chromosomes 1,9,15,16, and Y, corresponding to C-band heterochromatin. Bivariate flow karyology of human chromosomes treated with this triple-stain combination resolves chromosomes 1,9, and Y distinctly from the remaining chromosomes and resolves variations between chromosome homologues not detected by staining with propidium iodide (PI) or with the double stain combination Hoechst 33258(HO) and CA3.     

Anti-kinetochore staining for single laser, bivariate flow sorting of Indian muntjac chromosomes.

Flow cytometric chromosome sorting typically relies upon dual-laser, bivariate analysis after staining with two different base pair-specific dyes for resolution of chromosomes with similar DNA content. The availability of FITC-conjugated antibodies offers the possibility of single-laser bivariate analysis when combined with propidium iodide (PI) DNA staining, but requires exploitable antigenic differences between chromosomes of interest. A technique was developed for indirect immunofluorescent anti-kinetochore staining of Indian muntjac chromosomes in suspension. Primary antibody binding within permeabilized whole cells minimized centrifugation-induced loss of chromosomal integrity. Subsequent FITC-conjugated second antibody binding was not affected by concurrent PI-counterstaining. Anti-kinetochore staining facilitated resolution of chromosomes No. 2 and X, which formed a doublet peak upon univariate DNA content analysis, as well as recognition of the Y2 peak which was indistinguishable from debris by univariate analysis. The technique allowed greater than 90% purification of each Indian muntjac chromosome.     

Chromosome sorting of primates: Isolation and identification of Y chromosome in green monkeys

Single laser flow cytometry was applied to the karyotype analysis of green monkeys. Clear sex difference in flow karyotype was recognized in this monkey, because Y chromosome could be identified as a single peak in the histogram of male specimens. We could isolate Y chromosome of this species by the use of a cell sorter, and demonstrate by polymerase chain reaction that the sorted-out chromosomes contained the Y chromosome specific nucleotide sequence (SRY). This chromosome sorting technique provides a powerful strategy for constructing the DNA library specific to Y chromosome in this species.     

Improving the biosafety of cell sorting by adaptation of a cell sorting system to a biosafety cabinet.

BACKGROUND: The jet-in-air cell sorters currently available are not very suitable for sorting potentially biohazardous material under optimal conditions because they do not protect operators and samples as recommended in the guidelines for safe biotechnology. To solve this problem we have adapted a cell sorting system to a special biosafety cabinet that satisfies the requirements for class II cabinets. With aid of this unit, sorting can be performed in conformance with the recommendations for biosafety level 2. METHODS: After integrating a modified fluorescence-activated cell sorter (FACS) Vantage into a special biosafety cabinet, we investigated the influence of the laminar air flow (LAF) inside the cabinet on side stream stability and the analytical precision of the cell sorter. In addition to the routine electronic counting of microparticles, we carried out tests on the containment of aerosols, using T4 bacteriophage as indicators, to demonstrate the efficiency of the biosafety cabinet for sorting experiments performed under biosafety level 2 conditions. RESULTS: The experiments showed that LAF, which is necessary to build up sterile conditions in a biosafety cabinet, does not influence the conditions for side stream stability or the analytical precision of the FACS Vantage cell sorting system. In addition, tests performed to assess aerosol containment during operation of the special biosafety cabinet demonstrated that the cabinet-integrated FACS Vantage unit (CIF) satisfies the conditions for class II cabinets. In the context of gene transfer experiments, the CIF facility was used to sort hematopoietic progenitor cells under biosafety level 2 conditions. CONCLUSIONS: The newly designed biosafety cabinet offers a practical modality for improving biosafety for operators and samples during cell sorting procedures. It can thus also be used for sorting experiments with genetically modified organisms in conformance with current biosafety regulations and guidelines.     

Application of laser optical tweezers in immunology and molecular genetics.

Optical tweezers, based on a compact diode pumped Nd:YAG laser providing 350 mW at 1,064 nm coupled into a Zeiss IM 35 microscope, were used to sort CD4+ T cells into a capillary for further mechanical handling and to establish contact between single human natural killer (NK) cells and human erythroleukemia cells (K562) as targets. After contact and a lag phase of a few tens of seconds, the target cell starts to change its morphology and membrane blebbing occurs. The kinetics of the attack of the NK cell on K562 cells is not straightforward but governed by temporal oscillations in the shape of the target cell (zeosis). In a second application, the optical tweezers are combined with a UV laser microbeam based on a pulsed UV laser and with flow cytometry and sorting. With the pulsed laser, segments of sorted chromosome 1 of the chinese hamster karyotype (CHV 79) can be easily micro-dissected and subsequently collected using the optical tweezers. This allows preparation of a few hundred chromosome segments per day without mechanical contact and in an absolutely sterile way and thus may provide an interesting basic technique in any type of genome sequencing project.     

The ontogeny and distribution of B cells in normal and mutant immune-defective CBA/N mice: two-parameter analysis of surface IgM and IgD

A dual-laser fluorescence-activated cell sorter was utilized to study the distribution of the surface IgM and IgD on individual B cells of normal and immune-defective CBA/N mice. Cells from different lymphoid organs and from developing mice were studied. Two major populations of cells were seen. Those with low densities of surface IgM and intermediate-high densities of surface IgD were relatively or totally absent from the bone marrow, spleens, and lymph nodes of adult, immune-defective (CBA/N x DBA/2)F1 male mice, and developed late in ontogeny in the lymphoid organs of normal F1 female mice. By contrast, the second major population, with intermediate-high surface IgM and low surface IgD, was found in highest frequency in the lymphoid organs of immature mice, the bone marrow of adult mice, and the lymphoid organs of F1 male mice compared to F1 female mice at any age. These two major populations of B cells were further subdivided into five groups of cells to better define the surface IgM and IgD characteristics of developing B cells of immune-defective and normal mice. The relationship of these groups of cells to populations defined by other criteria are discussed.     

Preservation of cells sorted individually onto microscope slides with a fluorescence-activated cell sorter

Fluorescence-activated cell sorters permit analyses and separation of cell populations based on light scatter and surface immunofluorescence parameters. Since a sorter can deposit individually identifiable cells onto a microscope slide, it was considered of interest to combine the flow measurements with analyses available on cells adhering to a surface as in, for example, morphological studies, cytoplasmic immunofluorescent staining, and mRNA in situ hybridization. A necessary condition for these studies is the preservation of cell structures after sorting. We report here a procedure suitable for this purpose. The most important features of this procedure are A) reducing the saline content of the sorter sheath fluid to about 0.0015 M (one-hundredth that of normal saline) to prevent cell damage due to hypertonicity during drying, and B) coating the substrate with a thin layer of newborn calf serum to promote the adherence of the cells to the substrate during subsequent fixing and staining.     

光钳及其在生物学中的应用

本文综述了光钳的原理及其在细胞生物学、免疫学及分子遗传学中的应用。将光钳和激光微束系统联合使用可以进行显微操作。其特点是操作简便,无机械接触並且绝对无菌。光钳和微束系统可用来切割染色体,收集染色体片段,融合细胞以及改变细胞和细胞器的行为。     

Intracellular nanosurgery with near infrared femtosecond laser pulses.

We report on laser-assisted knocking out of genomic nanometer-sized regions within the nucleus of living cells. The intranuclear nanosurgery was possible by application of highly intense near infrared femtosecond laser pulses. The non-contact laser treatment was performed within a closed sterile cell chamber. The destructive multiphoton effect was based on 10(12) W/cm2 light intensities and limited to a sub-femtoliter focal volume of a high numerical aperture objective. We used the intracellular nanoscalpel for highly precise non-contact dissection of Hoechst-labelled chromosomes within a nucleus of a living Chinese hamster ovary cell. Following laser treatment, the cell remained alive and did not show any signs of membrane perturbation. The use of near infrared pulses provide the possibility of non-invasive intracellular nanoprocessing also within living tissue in depths of more than 100 microns.