Frontal, Parietal, and Temporal Brain Areas Are Differentially Activated When Disambiguating Potential Objects of Joint Attention.

Humans establish joint attention with others by following the other's gaze. Previous work has suggested that a cortical patch (gaze-following patch, GFP) close to the posterior superior temporal sulcus (pSTS) may serve as a link between the extraction of the other's gaze direction and the resulting shifts of attention, mediated by human lateral intraparietal area (hLIP). However, it is not clear how the brain copes with situations in which information on gaze direction alone is insufficient to identify the target object because more than one may lie along the gaze vector. In this fMRI study, we tested human subjects on a paradigm that allowed the identification of a target object based on the integration of the other's gaze direction and information provided by an auditory cue on the relevant object category. Whereas the GFP activity turned out to be fully determined by the use of gaze direction, activity in hLIP reflected the total information needed to pinpoint the target. Moreover, in an exploratory analysis, we found that a region in the inferior frontal junction (IFJ) was sensitive to the total information on the target. An examination of the BOLD time courses in the three identified areas suggests functionally complementary roles. Although the GFP seems to primarily process directional information stemming from the other's gaze, the IFJ may help to analyze the scene when gaze direction and auditory information are not sufficient to pinpoint the target. Finally, hLIP integrates both streams of information to shift attention to distinct spatial locations.

Identification of SV40 T-antigen mutants that alter T-antigen-induced chromosome damage in human fibroblasts.

The SV40 T antigen causes numerical (aneuploidy) and structural (aberrations) chromosome damage when expressed in human diploid fibroblasts. This chromosome damage precedes the acquisition of neoplastic traits such as anchorage independence, colony formation in reduced serum growth factors, immortalization, or tumorigenicity. Therefore, chromosome damage may be important in acquiring these traits because it could provide a mutational mechanism. To determine how the T antigen causes chromosome damage, point mutations were constructed that altered previously defined biochemical functions of the T protein. Mutant T antigen constructs were introduced into human diploid fibroblasts and selected by using G418. Clones of G418r cells that expressed mutant T antigens were expanded and scored for chromosome damage. Most of these mutant T antigens caused [corrected] levels of chromosome damage similar to those caused by [corrected] the wild-type T antigen. However, some T-antigen mutants induced fewer chromosome changes. A subset of these clones that induced less chromosome damage than wild-type T were examined further. Mutant T-antigen protein levels from this subset were quantified with flow cytometry and compared with wild-type protein expression levels. Mutations of T antigen shown previously to form less stable complexes with p53 caused less chromosome damage. A mutation in the zinc finger domain of T antigen also caused less chromosome damage. Interestingly, a mutant that caused loss of the ATPase activity of T antigen caused an increase in endoreduplicated cells. Also, a correlation was noted between cells expressing very low levels of T antigen (below detection limits when using flow cytometry) and an undamaged karyotype. This correlation indicates that there is a threshold level of T-antigen expression that induces chromosome damage and that expression levels on a per-cell basis rather than on a population basis should be considered in subsequent studies.

Immortalization of human fibroblasts by SV40 large T antigen results in the reduction of cyclin D1 expression and subunit association with proliferating cell nuclear antigen and Waf1.

Protein complexes containing cyclins and cyclin-dependent protein kinases (cdks) have been shown to be rearranged in both spontaneous and viral tumor antigen-transformed cells. We have examined G1- and S-phase cyclin/cdk complexes as a function of the neoplastic progression of human diploid fibroblasts transfected with the SV40 large T antigen. We find that the expression of cyclin D1 and its association with proliferating cell nuclear antigen (PCNA) and Waf1 remain unchanged in precrisis human fibroblasts transfected with SV40 large T antigen. However, in these same cells the association of cdk4 with cyclin D1, PCNA, and Waf1 is disrupted. Upon immortalization, cyclin D1 protein expression is decreased, and binding of both PCNA and Waf1 with the remaining cyclin D1 is reduced. In contrast, large T antigen increased the expression of cyclin A and cyclin E proteins in both precrisis and immortal cells and did not reduce the binding of PCNA or Waf1 to either cdk2 or cyclin A proteins. These results show that large T-antigen expression in human fibroblasts selectively uncouples cyclin D1 from cdk4, and subsequent immortalization of these cells results in additional changes to the cyclin D1-dependent cell cycle regulatory pathways.

Iterative chromosome mutation and selection as a mechanism of complete transformation of human diploid fibroblasts by SV40 T antigen.

The acquisition of an extended lifespan and of neoplastic properties, including anchorage independence, ability to grow in low serum-containing media, morphological transformation, immortalization and tumorigenicity in nude mice were studied in 31 human fibroblast lineages transfected with plasmids containing the SV40 early genes. Plasmids were used that contained sequences for large T alone, or large T plus small t or large T plus small t plus the SV40 origin. Cells expressing large T antigen gradually acquired the ability to form colonies in low serum or to form anchorage-independent colonies. Large T antigen was sufficient to cause complete transformation to tumorigenicity if multi-step lineage evolution was obtained by prolonged serial passage and if in vivo progression was assisted by means of a gelatin sponge implantation technique. Cells derived from progressive tumors initiated in sponges showed enhanced tumorigenicity as measured by ability to obtain tumors without using sponges and with reduced latent period, higher incidence and with fewer cells inoculated. Multiple lineages of human fibroblasts have been converted to tumorigenicity without additional treatments such as transfection with activated oncogenes or exposure to carcinogens. These data, taken in conjunction with earlier studies showing that T antigen causes chromosome mutation preceding and accompanying the accumulation of the neoplastic phenotype, suggests that the T protein drives the transformation process by acting as a mutagen and cells with growth advantages were selected for in vitro and in vivo. With the possible exception of morphological transformation, the presence or absence of genes for small t and the SV40 origin were not critical for the process.

Abrogation of a kinase-mediated G1 cell cycle arrest point is a late event in the neoplastic progression of human fibroblasts transfected with the SV40 large T antigen gene.

Cell cycle arrest points that are sensitive to the kinase inhibitor staurosporine have been shown to have widely differing sensitivities for processes in G1 and G2. In addition, the exquisitely sensitive G1 arrest point has been reported to be abrogated in neoplastically transformed cells. Using a multistep model of the neoplastic process in human cells, we show here that abrogation of the G1 arrest point occurred in 5 of 11 tumorigenic cell populations. The abrogation, in those instances when it occurred, was a late step and associated with the acquisition of tumorigenicity, but apparently independent of conventional criteria for in vitro transformation.

SV40 T antigen induced chromosomal changes reflect a process that is both clastogenic and aneuploidogenic and is ongoing throughout neoplastic progression of human fibroblasts.

In human fibroblasts, the expression of SV40 large T antigen is known to cause a variety of chromosomal aberrations and especially dicentric chromosomes. In some cases, the later aberrations have been reported to be reversible telomeric associations. We report here aberration and chromosome number studies of twenty-nine T antigen positive lineages, studied from their initiation by transfection of T antigen sequences into human diploid fibroblasts, until crisis or immortalization occurred or, in some cases until the lines became tumorigenic in nude mice. The data show that T antigen consistently produced chromosomal instability of both number and structure by an active process that began before transformation indicators were positive and continued throughout neoplastic progression. The most frequently observed aberrations were dicentric chromosomes, which were shown to be true dicentrics by examination by in situ hybridization with telomeric sequences. These data are consistent with the hypothesis that T antigen causes human fibroblasts to become neoplastically transformed by successive rounds of chromosomal mutation and lineage evolution.

Frequent deletions in nine newly immortal human cell lines.

Nine newly immortal lines of human fibroblasts transfected with SV40 T antigen were examined for recurrent chromosome losses. In order of decreasing frequency, all nine lines had three or more of the following minimal deletions specifically associated with the immortalization event: del(6)(q21), del(3)(p24), del(1)(p34), del(4)(p25), del(5)(p14), del(11)(p11), del(11)(q14), del(12)(p12), and del(14)(p?). Many other chromosome changes were not clearly associated with immortalization, but were acquired during other stages of this multistep model of neoplastic transformation. We propose that these chromosome loci associated with immortalization are candidates for the location of genes involved in cellular senescence.

Karyotype evolution in a simian virus 40-transformed tumorigenic human cell line.

Normal human foreskin fibroblasts (HSF4) were transfected using the pSV3-neo plasmid. A pool of 10 G418-resistant colonies, HSF4-T12, showed a progressive increase in the expression of a number of in vitro transformation markers with passage in culture and became immortalized. Although no tumors were formed when cells were injected subcutaneously into nude mice, this cell line produced progressive tumors when cells were injected into preimplanted Gelfoam sponges in the mice. When these tumors were cultured in vitro and subsequently injected subcutaneously, progressive tumors were produced with median latency periods as short as 4 weeks. Three phases of cytogenetic change could be distinguished. At early passages after transfection. HSF4-T12 exhibited many random chromosomal changes. At a time just after immortalization, both flow karyotype and G-banded analyses showed the appearance of balanced clonal rearrangements. These included t(2;4), t(2;14), t(3;?), 6p-, i(6p), 8p-, t(14;15), i(15), and t(18;?). These clonal rearrangements were stable with passage in culture, and less variability from cell to cell was noted. The only consistent chromosomal loss observed was -Y. Analysis of three independent tumors showed characteristic loss of chromosomal material rather than balanced chromosomal rearrangements. Frequent loss of 6q and chromosomes #13, 15, 20, and Y was noted.

Trans-acting factors in chromosomal instability.

The hypothesis that trans-acting factors affect chromosome stability was explored using human X Chinese hamster somatic cell hybrids. Two types of hybrids were examined. In either case, the human parent consisted of human diploid fibroblasts, the chromosomes of which tended to be lost from the hybrid cell. Comparisons were made between hybrid clones in which the hamster parent had a very stable karyotype (line CHO) and clones from a hamster parent with an unusual ongoing unstable karyotype (line CHX). Chinese hamster-human hybrid cell clones were expanded, and metaphase spreads were analyzed with an in situ hybridization procedure that uses biotin-labeled human genomic DNA as probe. Analyses of chromosome numbers and interspecies translocations were made after 20, 60, and 100 population doublings. Throughout the experiments, the generation of human-hamster-translocated chromosomes was more frequent in the hybrid cells with the CHX background. In addition, these cells also generated human acentric fragments, which were rare in cells with the CHO background. These results favor explanations for the instability of the CHX line that involve ongoing production of a diffusible clastogenic factor.

SV40 T antigen alone drives karyotype instability that precedes neoplastic transformation of human diploid fibroblasts.

To define the role of SV40 large T antigen in the transformation and immortalization of human cells, we have constructed a plasmid lacking most of the unique coding sequences of small t antigen as well as the SV40 origin of replication. The promoter for T antigen, which lies within the origin of replication, was deleted and replaced by the Rous sarcoma virus promoter. This minimal construct was co-electroporated into normal human fibroblasts of neonatal origin along with a plasmid containing the neomycin resistance gene (neo). Three G418-resistant, T antigen-positive clones were expanded and compared to three T antigen-positive clones that received the pSV3neo plasmid (capable of expressing large and small T proteins and having two origins of replication). Autonomous replication of plasmid DNA was observed in all three clones that received pSV3neo but not in any of the three origin minus clones. Immediately after clonal expansion, several parameters of neoplastic transformation were assayed. Low percentages of cells in T antigen-positive populations were anchorage independent or capable of forming colonies in 1% fetal bovine serum. The T antigen-positive clones generally exhibited an extended lifespan in culture but rarely became immortalized. Large numbers of dead cells were continually generated in all T antigen-positive, pre-crisis populations. Ninety-nine percent of all T antigen-positive cells had numerical or structural chromosome aberrations. Control cells that received the neo gene did not have an extended life span, did not have noticeable numbers of dead cells, and did not exhibit karyotype instability. We suggest that the role of T antigen protein in the transformation process is to generate genetic hypervariability, leading to various consequences including neoplastic transformation and cell death.

Spontaneous in vitro neoplastic evolution of cultured Chinese hamster cells. Nucleolus organizing region activity.

Silver staining to demonstrate active nucleolus organizing regions (NORs) was performed at four different stages of the spontaneous tumorigenic progression in vitro of Chinese hamster WCHE/5 cells. The number of active NORs increased for fully transformed, highly tumorigenic, late passage cells. The increase of NOR material was due to additional NOR-bearing chromosomes or chromosome arms, i.e., trisomy 5, trisomy 8, and the marker chromosome i(3q). Intermediate stages of the neoplastic evolution showed changing patterns of NOR activity, but not an overall increase. We postulate that the increase of active rDNA enhances cell growth and provides undefined selective advantage, and that this supports our previous conclusion that selectable karyotype changes provide competitive advantages rather than being essential for neoplastic evolution in vitro.

Clonal diversity of the Kirsten-ras oncogene during tumor progression in athymic nude mice: mechanisms of amplification and rearrangement.

Single-cell clones from primary and lung metastatic tumors have been evaluated for the state of the viral-Kirsten-ras oncogene (v-Ki-ras) by Southern blot analysis after injection of Kirsten sarcoma virus-transformed BALB/c 3T3 cells (KiMSV, with a replication-defective provirus) into athymic nude mice by four different injection routes. While all clones of early-passage KiMSV cells contained an EcoRI-generated 5.3-kilobase DNA fragment at high dosage level, most clones of late-passage cells had lost this v-Ki-ras fragment or had greatly diminished levels. However, all clones of all tumors (greater than 90 tested) obtained after injection of these late-passage cells contained a dosage of the 5.3-kilobase v-Ki-ras band similar to that of the early-passage KiMSV cells, suggesting either a very strong selection for v-Ki-ras-bearing cells of the early-passage type in tumor formation and/or the ability of a subset of late-passage cells to amplify this gene to some minimal dosage level. Both flow cytometric analyses for DNA content and quantitation of chromosomes showed that all primary and lung metastatic tumors had more than twice the number of chromosomes as the late-passage KiMSV cells; however, four of 80 late-passage cells had a chromosome count in the range of tumors, consistent with their importance in tumor generation and possibly amplification of the v-Ki-ras-bearing chromosome. Clonal analyses of lung micrometastatic tumors revealed a v-Ki-ras blot pattern identical to that of the s.c. primary tumors. However, two of five lung metastases from the footpad (as large rapidly growing nodules) and i.v. routes had multiple copies of v-Ki-ras in new sites; a second injection round led to even greater complexity in v-Ki-ras patterns in clones of lung tumors. Two assays were used to demonstrate that these new v-Ki-ras integrations were generated by superinfection with a "helper" retrovirus, not sarcomagenic by itself in the nude mice, that led to rescue/reinfection of tumor cells with the defective Kirsten sarcoma proviral genome--cellular transformation of 3T3 or C3H10T1/2 cells and RNA dot blot analyses for medium-secreted retrovirus specific for LTR or v-Ki-ras sequences. This "helper" retrovirus could not be detected in early- or late-passage KiMSV cells used for inoculation but could be detected in certain tissues of normal nude mice, demonstrating its in vivo origin.(ABSTRACT TRUNCATED AT 400 WORDS)

Isolation and reactivity of host effectors associated with the manifestation of concomitant tumor immunity.

In this study, we have measured the specific tumoricidal activity of tumor-infiltrating lymphocytes that prevent the growth of secondary tumors in animals harboring progressing primary tumors (concomitant immunity). Since no tumor grows at the challenge site when concomitant immunity is established, tumor cells were inoculated into a preimplanted gelatin sponge whose subsequent solubilization in collagenase permitted the retrieval of leukocytes after tumor challenge. Primary progressing EMT6 tumors were established in normal BALB/c mice and 10 days later they were challenged with a secondary tumor inoculum introduced through a preimplanted gelatin sponge. At 3, 7, and 10 days after the administration of the tumor inoculum challenge, a monodispersed suspension of infiltrating leukocytes was recovered by collagenase digestion of the sponge matrix and tested for cytotoxicity toward EMT6 tumor targets. Cytotoxic T-lymphocytes with tumoricidal activity accumulated at the site of the secondary tumor challenge by 3 days. This antitumor activity was maximal 7 days following challenge and decayed thereafter. Splenic lymphocytes from these animals showed little cytotoxicity. In animals harboring a primary tumor, lymphocytes found in sponges that were not inoculated with tumor cells were not cytotoxic. We interpret these data to indicate that cytotoxic lymphocytes migrate to, and accumulate at the site of the tumor but not at other sites and that peripheral sources of lymphocytes in tumor-bearing animals such as the spleen may not be the best source of effector cells for evaluating the host's immune response to its tumor. The approach described here may also be useful in studying the mechanisms for host control of metastatic disease.

Spontaneous in vitro neoplastic evolution: selection of specific karyotypes in Chinese hamster cells.

Recurrent cytogenetic changes occurred reproducibly in vitro during the spontaneous neoplastic evolution of cultured Chinese hamster cells. In particular, excess 3q material appeared shortly after immortalization in numerous independent trials. By contrast, when clones were isolated at the earliest possible time after immortalization, a wide spectrum of types of cytogenetic evolution followed, which also resulted in transformed and tumorigenic cells. Clones with stable distinct colonial morphologies were used to demonstrate growth rate interactions when subpopulations compete. We conclude that specific recurring karyotypes are associated with specific stem lines with transient growth advantage during the early stages of in vitro carcinogenesis. Stem lines with other karyotypic change or no detectable karyotypic change are almost equally capable of undergoing the entire spontaneous neoplastic process in vitro.

Amplification and rearrangement of the Kirsten ras oncogene in virus-transformed BALB/c 3T3 cells during malignant tumor progression.

Analyses of the cellular and viral Kirsten ras genes (c-Ki-ras and v-Ki-ras, respectively) during malignant tumor progression were performed by using Kirsten murine sarcoma virus-transformed BALB/c 3T3 cells that harbor a replication-defective provirus. After injection into athymic nude mice by four different routes, primary tumors and secondary lung metastases were isolated, adapted to in vitro growth, and analyzed for DNA levels and mRNA expression of both genes for comparison with the originally injected transformed cells and untransformed 3T3 cells. For all tumors (primary or secondary), the v-Ki-ras gene was amplified and v-Ki-ras mRNA expression was highly elevated above that observed in the original transformed cell population. In two of five lung metastases from the i.v. and footpad injection routes, rearranged Ki-ras DNA sequences were observed. Micrometastases from the s.c. route of injection did not display these alterations. Injection of footpad lung tumor cells with rearrangements into a second group of animals led to multiple lung metastases with even further rearrangements correlating with more effective lung colonization/growth ability (overt lung tumors in five of eight animals less than 20 days after injection). However, reinjection of an i.v. lung tumor with rearranged Ki-ras led to no further rearrangements in the lung microfoci tumors isolated greater than 40 days after injection. These data suggest (i) the significance of amplification and elevated expression of v-Ki-ras in tumor formation, (ii) correlation of this amplification with more effective tumor progression, and (iii) the selective advantage that cells with Ki-ras DNA sequence additions have in the formation of overt lung tumors.

A gelatin sponge model for studying tumor growth: quantitation of tumor cells and leukocytes in the CHO tumor.

A gelatin sponge model system for tumor cell inoculation and retrieval of tumor-associated leukocytes is described. Gelatin sponges pre-implanted in nude mice harboring tumorigenic Chinese hamster ovary cells (line CHO) were examined at 2 and 11 days after injection of tumor cells for tumor cell content and leukocyte accumulation after digesting the sponge matrix in collagenase solution. The data indicate a progressive influx of host cells consisting primarily of macrophages, neutrophils and lymphocytes. The total number of viable tumor cells as well as the fraction of surviving tumor cells with clonogenic potential also increased with tumor age. Blank sponges not harboring tumor cells elicited an inflammatory response in the animals which did not change appreciably with length of sponge residence. However, when the sponges were harboring tumor cells, the accumulation of host leukocytes far exceeded that which occurred in blank sponges. This observation suggests a host response directed toward the tumor which is absent in animals bearing blank sponges. Apart from providing anchorage for injected cells, the gelatin sponge, by virtue of its digestibility in collagenase, makes possible the easy retrieval and precise quantitation of tumor-associated host cells.

Cultured Bloom's syndrome substrains: a relationship between growth in low serum and the expression of double minute chromosomes.

Four Bloom's syndrome fibroblast strains were examined for chromosome changes, immortalization, tumorigenicity, anchorage independent growth, and the ability to grow in low serum. Only one strain (GM 1492) exhibited some of these characteristics, which are generally associated with neoplastic cells. Strain GM 1492 also exhibited a low frequency of cells that contained double minute chromosomes. Substrains from GM 1492 were cloned, and showed that some of the above characteristics were expressed as a heritable trait. Karyotype instability (heteroploidy) was seen in all clones studied, with modal chromosome numbers ranging from near-diploid to near-tetraploid, as confirmed by DNA content distributions. Although no clones studied were tumorigenic in nude mice or immortalized, some showed an increased cellular proliferative capacity. Several clones were isolated after growth in 1% fetal bovine serum, and these all showed an increased expression of double minute chromosomes. Two of these 1% serum-isolated clones, (1492/clone 3-1% and clone 8-1%) were further studied by G-banding analysis, and found to show specific chromosomal anomalies. Clone 3 showed monosomy for chromosomes #4, #13, and #19, along with the absence of both copies of chromosome #7 but with both i(7p) and i(7q) chromosomes consistently seen. Clone 8 showed monosomy for chromosome #13. Preliminary experiments using DNA slot blots indicated that erb a and b, v-fes, v-mos, c-myc, n-myc, v-src, and v-sis showed no sequence amplification in GM 1492 cells or subclones.