Jackie Haines

Lack of detectable transmissible chromosomal instability after in vivo or in vitro exposure of mouse bone marrow cells to 224Ra alpha particles.

Abstract Bouffler, S. D., Haines, J. W., Edwards, A. A., Harrison, J. D. and Cox, R. Lack of Detectable Transmissible Chromosomal Instability after In Vivo or In Vitro Exposure of Mouse Bone Marrow Cells to 224Ra Alpha Particles. Several studies over recent years have highlighted the possibility that radiation can induce transmissible genomic instability. Most of these involve in vitro irradiation and usually in vitro culture. Here it is reported that the short-half-life bone-seeking α-particle emitter 224Ra did not induce excess transmissible chromosomal instability in CBA/H mouse bone marrow cells in a 100-day period after in vivo or in vitro exposure. Similarly, no excess transmissible chromosomal instability could be detected after in vivo whole-body X irradiation. It was noted, however, that short-term culture of murine bone marrow cells elevated yields of aberrations, as did transplantation of untreated marrow into radiation-ablated hosts. These findings emphasize the sensitivity of murine hemopoietic tissue to experimental manipulation and reinforce the importance of appropriate concurrent control experiments in any investigation of transmissible genomic instability.

Loss of heterozygosity in spontaneous and x-ray–induced intestinal tumors arising in F1 hybrid Min mice: Evidence for sequential loss of Apc+ and Dpc4 in tumor development†

Min (multiple intestinal neoplasia) mice carry a mutant allele of the murine Apc (adenomatous polyposis coli) locus and are predisposed to intestinal adenoma formation in the intestinal tract. Early studies have shown complete loss of function of Apc by whole chromosome loss on the tumor‐sensitive C57BL/6J genetic background and in AKR × B6 F1 hybrids. Gamma‐radiation–induced chromosomal losses focus the critical region on wt Apc, but because of the limited number of polymorphic markers used, no other critical regions of loss on chromosome 18 were identified. Using intestinal tumors arising spontaneously and induced by X‐rays in CBA/H × C57BL/6J F1 hybrid mice and high‐resolution microsatellite loss of heterozygosity (LOH) techniques, we provide mapping data for wt Apc loss, which confirms and extends earlier observations. In addition, high‐frequency loss events at the Dpc4 locus were found in both spontaneous and radiation‐induced tumors. These data identified LOH of Dpc4 as a critical secondary event following complete functional loss of Apc. LOH across the Trp53 genomic region of chromosome 11 was not observed. No LOH was recorded for the Mom1 candidate gene Pla2g2a or for 9 out of 10 polymorphic markers from the Mom1 genomic region on murine chromosome 4. One marker mapping distal to Pla2g2a showed LOH in a small minority of spontaneous tumors. These data support the contention that Mom1 does not act as a classical tumor suppressor. Overall, our data indicates a significant role for Dpc4 mutation in intestinal tumor progression in the mouse and provides further evidence for the importance of interstitial chromosome losses in radiation tumorigenesis. Genes, Chromosomes and Cancer 28:387–394, 2000.

A major breakpoint cluster domain in murine radiation-induced acute myeloid leukemia*

Cytogenetic and molecular studies have provided evidence of the clustering of chromosome 2 deletion breakpoints in radiation‐induced murine acute myeloid leukemia (AML). Moreover, clustering occurs in at least two fragile domains rich in telomere‐like arrays. Here we describe a physical map of the distal breakpoint cluster and confirm the presence of inverted head‐to‐head telomeric sequence arrays. These potentially recombinogenic sequences were not, however, the direct focus for post‐irradiation chromosome breakage in AML. Instead, the two arrays bordered a 2.5‐kb sequence with properties expected of a nuclear matrix attachment region (MAR). The putative MAR co‐localized in the fragile domain with genes important to the hemopoietic system (leukocyte tyrosine kinase, zinc finger protein 106, erythrocyte protein band 4.2, and β2‐microglobulin (β2m)); the β2m subdomain was a particular focus of breakage. On the basis of these and other data, we suggest that AML‐associated chromosome 2 fragility in the mouse is a consequence of domain‐specific fragility in genomic domains containing numerous genes critical to the hemopoietic system. Copyright

The distribution and retention of plutonium, americium and uranium in CBA/H mice

Groups of male and female CBA/H mice were given intraperitoneal injections of 40 kBq kg-1 of 239Pu, 241Am and 233U citrate solutions and the retention and distribution of the three radionuclides compared at times up to 448 days. Similar results were obtained for males and females and showed that: 1. Whole body retention at 448 days was very similar for 239Pu and 241Am, accounting for about 20% of injected activity for each nuclide; retention of 233U was much lower at about 3%. 2. The skeleton accounted for 85% or more of retained 239Pu, 241Am and 233U activity from 6 weeks after injection. 3. The greatest concentrations of each radionuclide were measured in the main body of the spine, limb girdles and ribs, with lowest concentrations in the paw bones, head bones and caudal vertebrae. The inhomogeneity of distribution was in the order Pu > U > Am; with a trend to more uniform activity with time. 4. Average bone doses to 448 days were calculated as about 1.6 and 1.7 Gy for 239Pu and 241Am, respectively, and 0.3 Gy for 233U, with ranges for individual bones of 0.7-3.0 Gy, 1.1-2.5 Gy and 0.1-0.6 Gy, respectively. Average liver doses to 448 days were calculated as about 0.9 Gy, 0.6 Gy and 0.007 Gy for 239Pu, 241Am and 233U respectively, whilst the dose to the kidney for 233U was about 0.1 Gy. 5. Autoradiographic studies of the distribution of the nuclides in the femur showed differences in their initial distribution and subsequent movement. Initially, concentrations of 239Pu were greater on endosteal than periosteal surfaces while 241Am distributed more evenly on bone surfaces. The initial deposition of 233U on all surfaces was uneven with concentrations probably on active surfaces. Burial of all three nuclides in areas of bone growth was observed. Transfer of activity to the marrow was greatest for 239Pu and least for 233U.

Xrcc2 Modulates Spontaneous and Radiation-Induced Tumorigenesis in Apcmin/+ Mice

XRCC2 has an important role in repair of DNA damage by homologous recombination. Adult Apcmin/+ (min, multiple intestinal neoplasia) mice, wild-type or heterozygous for Xrcc2 deficiency, were sham-irradiated or 2-Gy X-irradiated. Spontaneous mammary and intestinal tumor incidences are lower in Apcmin/+ Xrcc2+/− mice than in Apcmin/+ Xrcc2+/+ mice (mammary tumors: 14% and 38%, respectively, χ2 P = 0.03; intestinal adenomas in mice reaching full life span: 108.6 and 130.1, respectively, t-test P = 0.005). Following irradiation, the increase in mammary tumors was greatest in female mice heterozygous for Xrcc2 (7.25 ± 0.50-fold in Apcmin/+ Xrcc2+/− mice compared with 2.57 ± 0.35-fold in Apcmin/+ Xrcc2+/+ mice; t-test P < 0.001). The increase in intestinal tumor multiplicity following irradiation was significantly greater in Apcmin/+ Xrcc2+/− mice (Apcmin/+ Xrcc2+/−, 4.14 ± 0.05-fold, versus Apcmin/+ Xrcc2+/+, 3.30 ± 0.05-fold; t-test P < 0.001). Loss of heterozygosity of all chromosome 18 markers was greater in intestinal tumors from Apcmin/+ Xrcc2+/− mice than in tumors from Apcmin/+ Xrcc2+/+ mice. These findings indicate that Xrcc2 haploinsufficiency reduces spontaneous tumor incidence on an Apcmin/+ background but increases the tumorigenic response to radiation. Mol Cancer Res; 8(9); 1227–33. ©2010 AACR.

Analysis of loss of heterozygosity in lymphoma and leukaemia arising in F1 hybrid mice locates a common region of chromosome 4 loss.

Previous studies have identified five lymphoma‐related tumour suppressor gene regions on murine chromosome 4. Using detailed allelotype analysis on a range of lympho‐haematopoietic tumour types arising in F1 hybrid mice, we now show a consistent pattern of loss of heterozygosity (LOH) which identifies a common region of loss delineated by microsatellites D4Mit21 and D4Mit53 on proximal chromosome 4. This critical segment corresponds to the thymic lymphoma tumour suppressor region 5 (TLSR5) identified in an earlier study. Tumours of this type have also been reported as showing allelic loss from the Trp53 and Ikaros regions on chromosome 11. In the present study, only a small fraction of tumours showed LOH in the Ikaros region, while a minority of lymphomas, but not acute myeloid leukaemias, showed allelic loss of the chromosome 11 segment encoding Trp53. These and other data indicate strongly that the genomic regions identified as showing recurrent LOH depend on the genetic background of the mice. Overall, the results indicate a key role for a tumour suppressor gene(s) encoded in an ∼3 cM segment on proximal chromosome 4 and provide an experimental basis for the further investigation of the functional role of candidate genes which include Pax5 and Tgfbr1.

Five Quantitative Trait Loci Control Radiation-Induced Adenoma Multiplicity in Mom1R ApcMin/+ Mice

Ionising radiation is a carcinogen capable of inducing tumours, including colorectal cancer, in both humans and animals. By backcrossing a recombinant line of ApcMin/+ mice to the inbred BALB/c mouse strain, which is unusually sensitive to radiation–induced tumour development, we obtained panels of 2Gy-irradiated and sham-irradiated N2 ApcMin/+ mice for genotyping with a genome-wide panel of microsatellites at ∼15 cM density and phenotyping by counting adenomas in the small intestine. Interval and composite interval mapping along with permutation testing identified five significant susceptibility quantitative trait loci (QTLs) responsible for radiation induced tumour multiplicity in the small intestine. These were defined as Mom (Modifier of Min) radiation-induced polyposis (Mrip1-5) on chromosome 2 (log of odds, LOD 2.8, p = 0.0003), two regions within chromosome 5 (LOD 5.2, p<0.00001, 6.2, p<0.00001) and two regions within chromosome 16 respectively (LOD 4.1, p  = 4×10−5, 4.8, p<0.00001). Suggestive QTLs were found for sham-irradiated mice on chromosomes 3, 6 and 13 (LOD 1.7, 1.5 and 2.0 respectively; p<0.005). Genes containing BALB/c specific non-synonymous polymorphisms were identified within Mrip regions and prediction programming used to locate potentially functional polymorphisms. Our study locates the QTL regions responsible for increased radiation-induced intestinal tumorigenesis in ApcMin/+ mice and identifies candidate genes with predicted functional polymorphisms that are involved in spindle checkpoint and chromosomal stability (Bub1b, Casc5, and Bub1), DNA repair (Recc1 and Prkdc) or inflammation (Duox2, Itgb2l and Cxcl5). Our study demonstrates use of in silico analysis in candidate gene identification as a way of reducing large-scale backcross breeding programmes.

Tumorigenic target cell regions in bone marrow studied by localized dosimetry of 239Pu, 241Am and 233U in the mouse femur

Purpose : To study the temporal change in microdistribution of plutonium-239, americium-241 and uranium-233 in the mouse distal femur and to compare and combine calculated radiation doses with those obtained previously for the femoral shaft. Also, to relate doses to relative risks of osteosarcoma and acute myeloid leukaemia. Materials and methods : Computer-based image analysis of neutron-induced and α -track autoradiographs of sections of mouse femora was used to quantify the microdistribution of 239 Pu, 241 Am and 233 U from 1 to 448 days after intraperitoneal injection. Localized dose-rates and cumulative doses over this period were calculated for different regions of the marrow spaces in trabecular bone. The results were then combined with previous data for doses to the cortical marrow of the femoral shaft. A morphometric analysis of the distal femur was carried out. Results : Initial deposition on endosteal surfaces and dose-rates near to the trabecular surfaces at 1 day were two to four times greater than corresponding results for cortical bone. Burial was most rapid for 233 U, about twice the rate in cortical bone. As in cortical bone, subsequent uptake into the marrow was seen for 239 Pu and 241 Am but not 233 U. Cumulative doses to 448 days for different regions of trabecular marrow were greater than corresponding values for cortical marrow for each radionuclide. Combined doses reflected the greater overall volume of cortical marrow. Conclusions : Cumulative radiation doses to the 10 μ m thick band of marrow adjacent to all endosteal surfaces were in the ratio of ~7:3:1 for 239 Pu: 241 Am: 233 U. This ratio is not inconsistent with observed incidences of osteosarcoma induction by the three nuclides. Analysis of doses to different depths of marrow, however, showed that although ratios were probably not significantly different to that for a 10 μ m depth, better correlations with osteosarcomagenic risk were obtained with 20-40 μ m depths. For acute myeloid leukaemia, the closest relationship between relative risk and doses was obtained by considering only the central 5-10% of marrow, which gave a dose ratio of ~12:11:1 for 239 Pu: 241 Am: 233 U respectively.

Temporal change in microdosimetry to bone marrow and stromal progenitor cells from alpha-particle-emitting radionuclides incorporated in bone.

The microdistributions of the alpha-particle-emitting bone surface-seeking radionuclides (239)Pu, (241)Am and (233)U in the mouse femoral shaft have been studied using computer-based image analysis of neutron-induced and alpha-particle track autoradiographs, prepared from femora of CBA/H mice which had been injected with 40 kBq kg(-1) of radionuclide (as citrate solution) at times from 1 to 448 days previously. Employing dosimetric methods, radiation dose rates and cumulative radiation doses to regions of the bone marrow thought to contain hemopoietic and stromal progenitor cells susceptible to neoplastic transformation to leukemia and osteosarcomas have been calculated. It has been shown that the three radionuclides differ in their relative deposition on the bone surfaces, and that patterns of changing redistribution with time are also varied. For stromal progenitor cells, which are thought to be targets for induction of osteosarcoma and are found in proximity to the bone surfaces, cumulative doses showed the trend (239)Pu > (241)Am > (233)U, correlating well with incidences of osteosarcoma observed in mice. Cumulative doses to the primitive hemopoietic stem cells, concentrated in the central marrow and thought to be susceptible to neoplastic transformation to myeloid leukemia, were considerably lower and also showed the trend plutonium > americium > uranium.

Functional evidence from microcell-mediated chromosome transfer of myeloid leukemia suppressor genes on human chromosomes 7 and 11

The long arm of human chromosome 7 between 7q22 and 7q36 has been identified as a region harboring one or more tumor‐suppressor genes (TSGs) inactivated in acute myeloid leukemia (AML). Additional TSGs mapping to other chromosomes may well be involved in the etiology of this disease. For example, experiments using a mouse model system have indicated the possible presence of an AML TSG at 11p11–12. Microcell‐mediated chromosome transfer (MMCT) has been used to introduce human chromosomes 7 and 11 into a murine myeloid leukemia cell line. A proportion of MMCT hybrid clones containing either whole chromosome 7 or fragments of chromosome 11 showed a significant delay in leukemogenic onset when injected into syngeneic mice. Screening of hybrid clones did not associate any human microsatellite markers with decreased leukemogenic potential in vivo. However, preliminary evidence was obtained of allelic loss at chromosomal regions homologous with human 7q22 in murine F1 hybrid AMLs. Our data provide functional evidence of AML‐associated TSGs localized to human chromosomes 7 and 11 in support of previously published studies on cytogenetic and allelic losses associated with AML development.