Quantitation of cell kinetic responses using simultaneous flow cytometric measurements of DNA and nuclear protein

A rapid procedure was developed for the simultaneous flow cytometric analysis of nuclear protein using fluorescein isothiocyanate, and DNA using propidium iodide in isolated nuclei. The staining procedure did not involve centrifugation and was easily adapted to the staining of human peripheral blood lymphocytes stimulated with phytohemagglutinin, EL4 murine lymphoid tumor cells in suspension culture, and R3327-G rat prostatic adenocarcinoma solid tumor specimens. Histograms of unstimulated and PHA-stimulated HPBL perturbed by actinomycin D, hydroxyurea, 3H-TdR, colcemid, or hydroxyurea + colcemid showed that 1) resting, noncycling G1 (G1Q) cells are distinguished from late G1 (G1AB) cells, 2) early G2 (G2A) cells are distinguished from late G2 (G2B) cells, and 3) mitotic cells are distinguished from G2 cells. Treatment with hydroxyurea resulted in a build-up of cells having high nuclear protein content and 2C DNA content (G1AB), while incubation with 3H-TdR caused an increase in the number of cells with high nuclear protein content and 4C DNA content (G2B). Colcemid-blocked mitotic cells were identified as having low nuclear protein content (lower than G2A nuclei) and 4C DNA content. The nuclear DNA/protein histograms of untreated and colcemid-treated log-phase EL4 cells provided information concerning G1A, G1B, S, G2A, G2B, and M. The method was also used to quantitate the response of androgen-sensitive rat prostatic R3327-G tumors to androgen deprivation following castration. Sample preparation and staining for correlated nuclear DNA/protein measurements takes approximately the same amount of time as for single parameter nuclear DNA measurements.     

Flow cytometric discrimination of mitotic nuclei by right-angle light scatter

Flow cytometry has been used to demonstrate alterations in protein, RNA, and DNA content of cells as they traverse the cell cycle. Employing fluorescein isothiocyanate (FITC) to stain protein and propidium iodide (PI) to stain nucleic acids, multiple regions within the G1 and G2 phases of the cell cycle, in addition to the M phase, can be distinguished. In this study, cytograms of the 90 degree light scatter signal vs. PI fluorescence were remarkably similar to those of FITC fluorescence vs. PI fluorescence, suggesting a relationship between 90 degree light scatter and protein content. M-phase nuclei can be distinguished from G2-phase nuclei on cytograms of 90 degree light scatter vs. PI fluorescence. However, the percentage of mitotic nuclei obtained by this technique is less than that found by light microscopic analysis. Flow cytometric parameters of nuclei prepared by nonionic detergent (NP40) lysis in Dulbecco's PBS, Vindelov's buffer, or Pollack's hypotonic EDTA/Tris buffer were compared. The best resolution of mitotic nuclei was obtained in Pollack's buffer. However, the stainability of the M-phase nuclei is reduced, and the nuclei are located in the late S/G2 region of the single-parameter histogram.     

Altered expression of nuclear matrix proteins in etoposide induced apoptosis in HL－60 cells

INTRODUCTIIONThe nuclear matrix is an essential component ofthe nucleus which is important for the nuclear structural integrity and specific genomic functions[1, 2].Several articles have reported that the nuclear matrix, as a higher order framework structures, mightbe disassembled du-ring the apoptotic process[3-5].Accordingly3 nuclear lamins A/C or B have beenfound to decrease in apoptotic thymocytes[6], Tcells[7], and carcinoma cell line[8, 9]. The nucleolar protein B23, an obscure ma…     

Specific nuclear elimination in polyploid plasmodia of the slime mold Physarum polycephalum

In growing plasmodia of the myxomycete Physarum polycephalum (G2-phase), three distinct classes of nuclei with a relative DNA content of 1x, 2x, and 4x are observed in the presumed haploid strain CL. The 2x and 4x species comprise up to 35% and 5% of the nuclei. Quantitative cytofluorometric studies of nuclei isolated in either G2- or S-phase or after FUDR treatment (G1 arrest) show that the three nuclear populations undergo a synchronous mitotic cycle and that the relative DNA content of the nuclear fractions in G-2 phase reflects the 2c, 4c, and 8c state. The heterogeneity of the nuclear population does, however, seem to be restricted to the growth phase. During a starvation period of 4 days that always preceeds sporulation (and also meiosis), the 4c nuclear population is reduced to 7%, 8c nuclei are no longer detected. These results suggest that a mechanism exists in Physarum for the selective detection and elimination of polyploid nuclei.     

The G2 checkpoint activated by DNA damage does not prevent genome instability in plant cells

Root growth, G2 length, and the frequency of aberrant mitoses and apoptotic nuclei were recorded after a single X-ray irradiation, ranging from 2.5 to 40 Gy, in Allium cepa L. root meristematic cells. After 72 h of recovery, root growth was reduced in a dose-dependent manner from 10 to 40 Gy, but not at 2.5 or 5 Gy doses. Flow cytometry plus TUNEL (TdT-mediated dUTP nick end labeling) showed that activation of apoptosis occurred only after 20 and 40 Gy of X-rays. Nevertheless, irrespective of the radiation dose, conventional flow cytometry showed that cells accumulated in G2 (4C DNA content). Simultaneously, the mitotic index fell, though a mitotic wave appeared later. Cell accumulation in G2 was transient and partially reversed by caffeine, thus it was checkpoint-dependent. Strikingly, the additional G2 time provided by this checkpoint was never long enough to complete DNA repair. Then, in all cases, some G2 cells with still-unrepaired DNA underwent checkpoint adaptation, i.e., they entered into the late mitotic wave with chromatid breaks. These cells and those produced by the breakage of chromosomal bridges in anaphase will reach the G1 of the next cell cycle unrepaired, ensuring the appearance of genome instability.     

Effect of microgravity on the cell cycle in the lentil root

Characteristics of the cell cycle in cortical regions (0–0.6 mm from the root-cap junction) of the primary root of lentil (Lens culinaris L.) during germination in the vertical position on earth were determined by iododeoxyuridine labelling and image analysis. All cells were in the G1 phase at the beginning of germination and the duration of the first cell cycle was about 25 h. At 29 h, around 14% of the cortical nuclei were still in the G2 or M phases of the first cell cycle, whereas 53 and 33% of the nuclei were respectively in the G1 or S phase of the second cell cycle. In parallel, the cell cycle was analysed in root tips of lentil seedlings grown in space during the IML 2 mission (1994), (1) on the 1-g centrifuge for 29 h, (2) on the 1-g centrifuge for 25 h and placed in microgravity for 4 h, (3) in microgravity for 29 h, (4) in microgravity for 25 h and placed on the 1-g centrifuge for 4 h. The densitometric analysis of nuclear DNA content showed that in microgravity there were less cells in DNA synthesis and more cells in G1 than in the controls on the 1-g centrifuge (flight and ground). The comparison of the sample grown continuously on the 1-g centrifuge in space and of the sample grown first in 1-g and then in microgravity indicated that 4 h of microgravity modified cell cycle, increasing the percentage of cells in the G1 phase. On the contrary, the transfer from microgravity to the 1-g centrifuge (for 4 h) did not provoke any significant change in the distribution of the nuclear DNA content. Thus the effect of microgravity could not be reversed by a 4 h centrifugation. As the duration of the first cell cycle in the lentil root meristem is about 25 h, the results obtained are in agreement with the hypothesis that the first cell cycle and/or the second G1 phase was lengthened in absence of gravity. The difference observed in the distribution of the nuclear DNA content in the two controls could be due to the fact that the 1g control on board was subjected to a period of 15 min of microgravity for photography 25 h after the hydration of the seeds, which indicated an effect of short exposure to weightlessness. The mitotic index of cortical cells was greater on the 1-g centrifuge in space than in any other sample (flight and ground) which could show an effect of the centrifugation on the mitosis.     

Characterization of abnormal nuclei in renal proximal tubules after irradiation

The distribution and kinetics of proximal tubular cells with abnormally large nuclei, which were observed in irradiated mouse kidneys before any other obvious histological effects, were investigated. Six months after the administration of 13 or 15 Gy, little histopathological change was noted, in the kidneys of C3H mice; however, proliferation of proximal tubular cells was stimulated, and some of these cells had abnormally large nuclei. The relative DNA content of these large nuclei was measured with a quantitative image analysis system. Most of the large nuclear cells had more than diploid DNA content. The labeling index of the large nuclei was higher than that of unselected proximal tubular nuclei. These cells might be hyperploid cells that are dying after having gone through an abortive mitotic division. Examination and quantitation of these abnormal nuclei should be useful in elucidating the steps involved in cell loss in the proximal tubules after irradiation and as an assay for radiation damage to the kidney.     

DNA synthesis in the second and third cell cycles of mouse preimplantation development. A cytophotometric study

Female Swiss mice were sacrificed at 2 h intervals between 16–30 and 40–56 h after insemination. One-, 2- and 4-cell embryos were stained by the Feulgen method and cytophotometric measurement of their nuclear DNA content was carried out. The cells with 2C and 4C DNA content were assumed to be in G1 and G2 phase and those with intermediate DNA content in S phase of the cell cycle. The fractions of cells which had passed a given phase of the cell cycle were calculated for various times after insemination and utilized for measurements of the second and third cell cycle timing. Results of measurements for the second cell cycle: G1 phase 1.3 h, S phase 6.1 h, G2 phase 15.4 h, whereas for the third cell cycle: G1 phase 1.6 h, S phase 7.4 h, G2 phase 0.5 h. The first cleavage division was calculated as 1.6 h, the second as 1.3 h and the third as 1.2 h. Complete intra-embryonic synchronization of the DNA-synthesizing nuclei was preserved during the entire synthesis phase of 2-cell embryos, while in 4-cell embryos they were slightly asynchronized. Among mitotic cells of the first cleavage division and G1 cells of 2-cell embryos a slight interembryonic asynchronization was found which deepened during subsequent cell cycle phases.     

Nuclear RNA quantification in protoplast cell-cycle phases

Using acridine orange staining and flow cytometry the DNA and RNA levels (arbitrary units) of individual cells may be established. Here, this method has been applied to nuclei isolated from plant protoplasts during culture. The specificity of the technique has been validated for such plant material; ribonuclease markedly reduced nuclear staining without modifying the DNA histogram; ribonuclease inhibitor prevented the action of released cell nucleases; and protoplasts cultivated with actinomycin D did not synthesize RNA. First RNA synthesis was evident 18 h after Petunia hybrida protoplasts had been put into culture. An increase of RNA above a critical level was required for cells to be able to initiate DNA replication from G1, termed G1B. G2 nuclei had an RNA:DNA ratio similar to that of G1 nuclei.     

Protein cross-migration during isolation of nuclei from mixtures of heated and unheated HeLa cells

To investigate the cross-migration of proteins during nuclear isolation heated and control cells were mixed prior to nuclear isolation. These nuclei were stained with fluorescein isothiocyanate (FITC, a protein-specific stain) and with propidium iodide (PI, a DNA-specific stain). Flow cytometric (FCM) analysis showed two populations distinguishable on the basis of protein content. The protein content of the nuclei in the upper population was identical to that for nuclei isolated from heated cells while that for the lower population had a protein content identical to the protein content of nuclei from control cells. This result shows that the heat-induced increase in nuclear protein content occurred throughout the entire population of nuclei (i.e., in G1, S, and G2 nuclei) and that the measured protein content of nuclei was not affected by the presence of the other population during isolation. The capability of the FCM to sort subpopulations from different regions of a histogram was used to separate the subpopulations after analysis. When control cells were prelabeled with [3H]leucine and mixed with unlabeled heated cells, 11% of the radioactivity was found to be associated with the nuclei from heated cells. Autoradiographs showed grains over approximately 99% of the nuclei from heated cells. When [3H]TdR was used as a label in a similar experiment, only 0-3% of the label was observed to become associated with the population of nuclei from heated cells and autoradiography showed that 97% of these nuclei were not labeled. Comparable results were obtained when the labeled cells were heated and the control cells were left unlabeled. These results show that a small amount of protein (approximately 10% of the nuclear protein) will cross-migrate during nuclear isolation without affecting the net amount of protein in either population.     

Events associated with the initiation of mitosis in fused multinucleate HeLa cells

Large multinucleate (LMN) HeLa cells with more than 10–50 nuclei were produced by random fusion with polyethylene glycol. The number of nuclei in a particular stage of the cell cycle at the time of fusion was proportionate to the duration of the phase relative to the total cell cycle. The fused cells did not gain generation time. Interaction of various nuclei in these cells has been observed. The nuclei initially belonging to the G1-or S-phase required a much longer time to complete DNA synthesis than in mononucleate cells. Some of the cells reached mitosis 15 h after fusion, whereas others required 24 h. The cells dividing early, contained a larger number of initially early G1-phase nuclei than those cells dividing late. The former very often showed prematurely condensed chromosome (PCC) groups. In cells with a large number of advanced nuclei the few less advanced nuclei could enter mitosis prematurely. On the other hand, the cells having a large number of nuclei belonging initially to late S-or G2-phase took longer to reach mitosis. These nuclei have been taken out of the normal sequence and therefore failed to synthesize the mitotic factors and depended on others to supply them. Therefore the cells as a whole required a longer period to enter mitosis. Although the nuclei became synchronized at metaphase, the cells revealed a gradation in prophase progression in the different nuclei. At the ultrastructural level the effect of advanced nuclei on the less advanced ones was evident with respect to chromosome condensation and nuclear envelope breakdown. Less advanced nuclei trapped among advanced nuclei showed PCC and nuclear envelope breakdown prematurely, whereas mitotic nuclei near interphase or early prophase nuclei retained their nuclear envelopes for a much longer time. PCC is closely related to premature breakdown of the nuclear envelope. Our observations clearly indicate that chromosome condensation and nuclear envelope breakdown are two distinct events. Kinetochores with attached microtubules could be observed on prematurely condensed chromosomes. Kinetochores of fully condensed chromosomes often failed to become connected to spindle elements. This indicates that the formation of a functional spindle is distinct from the other events and may depend on different factors.     

Recovery of Pisum root meristems after mitotic-inhibitory treatments with 3H-thymidine. Inhibition of cell-cycle progression by unincorporated 3H-thymidine.

Primary root meristems of Pisum sativum recover form a 3H-thymidine-induced reduction in mitotic activity once the roots are no longer exposed to exogenous 3H-thymidine. Cells arrested in G2 during 3H-thymidine treatment apparently do not divide for at least 16 hours after treatment, whereas cells remaining in G1 and S do divide and thereby account for recovery. Recovery occurs only when meristems are no longer exposed to exogenous (i.e. unincorporated) 3H-thymidine, suggesting that cytoplasmic irradiation from unincorporated 3H-thymidine prevents cellular recovery from 3H-thymidine-induced inhibition of cell progression through the mitotic cycle. Concentrations of 14C-thymidine which result in cytoplasmic irradiation nearly equivalent to that achieved with 3H-thymidine, but much lower levels of nuclear irradiation, also prevent recovery from 3H-thymidine-induced inhibition of mitotic activity, but do not alone produced such inhibition. These results support the contention that cytoplasmic irradiation prevents recovery from the effects of nuclear irradiation. Unincorporated 3H-thymidine also prevents recovery from sucrose deprivation in stationary phase G2 cells which have not incorporated 3H-thymidine into nuclear DNA.     

与细胞周期G2/M期进程相关的H2AX磷酸化

γH2AX焦点(foci)被普遍当做DNA双链断裂（DSB）损伤的分子标志物.为探 讨细胞周期进程相关的H2AX磷酸化规律特征,采用胸腺嘧啶双阻滞结合噻氨酯哒唑(nocodazole)的后续处理,将HeLa细胞同步于有丝分裂的前中期．然后,用流式细胞仪检测细胞周期、Western印迹和免疫荧光法,观察γH2AX表达和γH2AX焦点的形成．结果显示,细胞进入G2/M期和有丝分裂过程中,γH2AX水平显著增加 ;在无DNA DSB发生的情况下,部分M期细胞中也存在大量的γH2AX焦点．随着细 胞完成有丝分裂从M期退出再进入G1期,γH2AX的表达水平逐渐降低．这种 γH2AX表达变化特征与G2/M期密切关联的PLK1和Cyclin B1的表达规律相类似． 在4 Gy大剂量照射下,HeLa细胞于照后8 到12 h出现明显的G2/M期阻滞．γH2AX 焦点数在照后1 h达高峰,随后降低,照后8 h又上升,出现了第2个峰值．与之不同的是,在1 Gy低剂量照射下,细胞的G2/M期阻滞微弱,γH2AX焦点数在照后 0.5 h最高,随后下降,且无反弹,符合DNA DSB的修复动力学特征．因此,将γ H2AX当做DNA DSB分子标志物时,还需要考虑细胞周期变化的影响．γH2AX适合 作为1 Gy以下照射的DNA双链断裂损伤的分子标志．     

Initiation of DNA synthesis in the prematurely condensed chromosomes of G1 cells

The objective of this study was to investigate whether G1 cells could enter S phase after premature chromosome condensation resulting from fusion with mitotic cells. HeLa cell synchronized in early G1, mid-G1, late G1, and G2 and human diploid fibroblasts synchronized in G0 and G1 phases were separately fused by use of UV-inactivated Sendai virus with mitotic HeLa cells. After cell fusion and premature chromosome condensation, the fused cells were incubated in culture medium containing Colcemid (0.05 micrograms/ml) and [3H]thymidine ([3H]ThdR) (0.5 microCi/ml; sp act, 6.7 Ci/mM). At 0, 2, 4, and 6 h after fusion, cell samples were taken to determine the initation of DNA synthesis in the prematurely condensed chromosomes (PCC) on the basis of their morphology and labeling index. The results of this study indicate that PCC from G0, G1, and G2 cells reach the maximum degree of compaction or condensation at 2 h after PCC induction. In addition, the G1-PCC from normal and transformed cells initiated DNA synthesis, as indicated by their "pulverized" appearance and incorporation of [3H]ThdR. Further, the initiation of DNA synthesis in G1-PCC occurred significantly earlier than in the mononucleate G1 cells. Neither pulverization nor incorporation of label was observed in the PCC of G0 and G2 cells. These findings suggest that chromosome decondensation, although not controlling the timing of a cell's entry into S phase, is an important step for the initiation of DNA synthesis. These data also suggest that the entry of a S phase may be regulated by cell cycle phase-specific changes in the permeability of the nuclear envelope to the inducers of DNA synthesis present in the cytoplasm.     

The action of caffeine on X-irradiated HeLa cells. VIII. Recovery from potentially lethal damage

Recovery from potentially lethal radiation damage in HeLa S3 cells has been studied by irradiating synchronous cultures with 4 Gy at selected ages in the cell cycle, initiating treatment with 4 mM caffeine, which prevents recovery, at progressively later times up to 24-30 h after irradiation, and determining the plateau level of survival after incubation with the caffeine until 36-40 h after mitotic collection. Cell recovery appears to begin immediately after irradiation at any time during interphase: an accelerating increase in survival gives way after several hours to a linear increase which lasts for an additional several hours. The median recovery time is approximately 13 h after irradiation at any time during G1, but is markedly shorter (5-7 h) after irradiation in S or G2. The rate of recovery is slightly depressed if DNA replication is inhibited with aphidicolin after irradiation and slightly enhanced if protein synthesis is inhibited with cycloheximide. Both the rate and the extent of recovery are dependent on the location of the cells in the cycle at the time of irradiation--both functions increasing with cell age from the beginning of S, but having different age dependencies in G1. Blocking cell progression with a DNA-synthesis inhibitor before irradiation halts the age-dependent changes.     

Alterations of neuronal nuclear matrix and chromatin structure after irradiation under aerobic and anoxic conditions

This study was undertaken to determine if structural alterations of the bulk chromatin and the amount of protein associated with the nuclear matrix in cerebellar neurons depend on radiation dose and a cell's state of oxygenation. After irradiation with 2.5 to 25.0 Gy under both aerobic and anoxic conditions, the sensitivity of the neuronal chromatin to m. nuclease digestion increase linearly with dose up to about 5 Gy, beyond which there was no further increase. The same increase in accessibility of chromatin to micrococcal nuclease digestion was observed when neuronal nuclei were irradiated at 4 degrees C. Neuronal nuclei were stained with propidium iodide (PI) for DNA and with fluorescein isothiocyanate (FITC) for protein, both before and after complete digestion with DNase I, and analyzed by flow cytometry. There was no change in either the PI (P greater than 0.4) or the FITC (P greater than 0.9) fluorescence of undigested nuclei after irradiation. For the DNase I digested nuclei, the PI fluorescence was unchanged after irradiation (P greater than 0.4), but the FITC fluorescence increased significantly (P less than 0.02). This increase in the FITC fluorescence was linear with dose up to about 5 Gy, beyond which there was no further increase. The flow cytometry results from DNase I digested nuclei were identical for neurons irradiated under aerobic or anoxic conditions, indicating that this phenomenon is oxygen independent. This increase in FITC fluorescence after irradiation was inhibited at ice-cold temperatures and probably reflects an increase in protein content at the nuclear matrix that requires metabolism. This may explain our previously observed resistance of nuclear matrix-associated DNA to digestion by DNase I. This protein increase at the nuclear matrix appears to follow "saturation" kinetics identical to that previously reported for repair of DNA strand breaks in cerebellar neurons. However, the exact molecular nature of this process and its role in DNA repair or cell survival remains to be determined.     

Recovery from DNA damage-induced G2 arrest requires actin-binding protein filamin-A/actin-binding protein 280

Filamin-A (filamin-1) is an actin-binding protein involved in the organization of actin networks. Our previous study shows that filamin-A interacts with BRCA2, and lack of filamin-A expression results in increased cellular sensitivity to several DNA damaging agents in melanoma cells (Yuan, Y., and Shen, Z. (2001) J. Biol. Chem. 276, 48318-48324), suggesting a role of filamin-A in DNA damage response. In this report, we demonstrated that deficiency of filamin-A results in an 8-h delay in the recovery from G2 arrest in response to ionizing radiation. However, filamin-A deficiency does not affect the initial activation of the G2/M checkpoint. We also found that filamin-A deficiency results in sustained activation of Chk1 and Chk2 after irradiation. This in turn causes a delay in the dephosphorylation of phospho-Cdc2, which is inhibitory to the G2/M transition. In addition, filamin-A-deficient M2 cells undergo mitotic catastrophe-related nuclear fragmentation after they are released from the G2 arrest. Together, these data suggest a functional role of filamin-A in the recovery from G2 arrest and subsequent mitotic cell death after DNA damage.     

Rat luminal cell nuclear area changes correlated with uterine growth responses induced by a low dose infusion or injection of estradiol-17 beta

Rat uterine luminal epithelial cells (LEC) responded differently when exposed to an injection of 1.0 microgram estradiol-17 beta (E2) compared to a continuous infusion of E2 at the rate of 1.0 microgram/24 hours. After injection or beginning infusion, LEC mean nuclear area significantly decreased by 4 h, then increased thereafter. After injection, nuclear area distributions were determined at each time point. The percentage of large nuclei (greater than 40 mu 2) decreased by 4h postinjection and remained a relatively small proportion of the population, while the percentage of nuclei of 20-30 mu 2 areas increased throughout the experiment. During infusion, the percentage of large nuclei decreased by 4h after pump implantation, then increased. Only infusion induced sustained, increased uterine protein content, DNA synthesis and ornithine decarboxylase activity. This study suggests that E2 treatment modality induces differences in nuclear size in target cells as well as in biochemical parameters.     

Deficiency in nuclear accumulation of G22p1 and Xrcc5 proteins in hyper-radiosensitive Long-Evans Cinnamon (LEC) rat cells after X irradiation

The DNA-dependent protein kinase (DNA-PK) complex has been implicated in the repair of DNA double-strand breaks (DSBs). DNA-PK is a heterotrimeric protein complex comprised of two components: a large catalytic subunit, Prkdc, with serine/threonine kinase activity and a DNA-targeting component, G22p1 and Xrcc5. In previous report, we showed that approximately 80% of the G22p1 and Xrcc5 proteins were observed in the cytoplasm of rat fibroblasts, and that nuclear translocation of the proteins from the cytoplasm is important for the repair of DNA DSBs. In the present study, we showed that nuclear accumulation of the G22p1 and Xrcc5 proteins was not observed in fibroblasts from a mutant strain of Long-Evans Cinnamon (LEC) rat that has an enhanced radiosensitivity and a reduced level of repair of DSBs after X irradiation. Nuclear translocation of the proteins was observed in both LEC rat cells and control rat cells with normal radiosensitivity at 5 min after X irradiation. Although high levels of G22p1 and Xrcc5 proteins were observed in the nuclei of control rat cells until 60 min postirradiation, the amounts of the proteins decreased rapidly in the nuclei of LEC rat cells in the first 10 min after X irradiation. These findings suggest that there are some defects in maintaining the levels of G22p1 and Xrcc5 proteins in the nuclei of LEC rat cells. An analysis of fibroblasts from backcross rats showed that the deficiency in nuclear accumulation of G22p1 and Xrcc5 proteins is genetically linked to enhanced radiosensitivity. Since the nucleotide sequences of the G22p1 and Xrcc5 genes of the LEC rats coincided with those of the control rats, the deficiency in nuclear accumulation may not be caused by mutations of the G22p1 and Xrcc5 proteins.