Interphase and metaphase resolution of different distances within the human dystrophin gene

Detection of the survival motor neuron (SMN) genes by FISH: further evidence for a role for SMN2 in the modulation of disease severity in SMA patients

Spinal muscular atrophy (SMA) is a common autosomal recessive neuromuscular disorder which presents with various clinical phenotypes ranging from severe to very mild. All forms are caused by the homozygous absence of the survival motor neuron ( SMN1 ) gene. SMN1 and a nearly identical copy ( SMN2 ) are located in a duplicated region at 5q13 and encode identical proteins. The genetic basis for the clinical variability of SMA remains unclear, but it has been suggested that the copy number of SMN2 could influence the disease severity. We have assessed the number of SMN2 genes in patients with different clinical phenotypes by fluorescence in situ hybridization (FISH) using as SMN probe a mixture of small specific DNA fragments. Gene copy number was established by FISH on interphase nuclei, but the presence of two SMN2 genes on the same chromosome could also be revealed by FISH on metaphase spreads. All patients had at least two SMN2 genes. We found two or three copies of SMN2 in severely affected type I patients, three copies in intermediately affected type II patients, generally four copies in mildly affected type III patients and four or eight copies in patients with very mild adult-onset SMA. No alterations of the genes were detected by Southern blot and sequence analysis, suggesting that all gene copies of SMN2 were intact. These data provide additional evidence that the SMN2 genes modulate the disease severity and suggest that knowledge of the gene copy number could be of some prognostic value.

Intranuclear relocalization of matrix binding sites during T cell activation detected by amplified fluorescence in situ hybridization

We describe a method for analyzing the nuclear localization of specific DNA sequences, with special emphasis on their binding status to the nuclear matrix, depending on the developmental stage of the cells. This method employs high-resolution fluorescence in situ hybridization procedures. For our studies, it was important to examine the nuclear localization of a particular gene locus. Previously, however, it was not possible to detect a single-copy genomic sequence using a DNA probe less than several kilobases in size. We describe here a signal amplification technique based on tyramide which makes such a task possible. Using this method, we monitored single-copy loci using a short, 509-bp DNA sequence that binds in vivo to the T cell factor SATB1 within T cell nuclei, high-salt-extracted nuclei (histone-depleted nuclei generating "halos" with distended chromatin loops), and the nuclear matrix, before and after T cell activation. We found that these loci were anchored onto the nuclear matrix, creating new bases of chromatin loops, only after T cell activation. This experimental strategy, therefore, enabled us to detect the changes in higher order chromatin structure upon activation and study gene regulation at a new dimension: the loop domain structure. The methods shown here can be widely applied to explore other functions involving chromatin, including recombination and replication.

Mapping of the breakpoints on the short arm of chromosome 17 in neoplasms with an i(17q)

Isochromosomes are monocentric or dicentric chromosomes with homologous arms that are attached in a reverse configuration as mirror images. With an incidence of 3-4%, the i(17q) represents the most frequent isochromosome in human cancer. It is found in a variety of tumors, particularly in blast crisis of chronic myeloid leukemia (CML-BC), acute myeloid leukemia (AML), non-Hodgkin's lymphoma (NHL), and medulloblastoma (MB), and indicates a poor prognosis. To determine the breakpoints on the molecular genetic level, we analyzed 18 neoplasms (six CML, four AML, one NHL, and seven MB) with an i(17q) and two MB with a pure del(17p) applying fluorescence in situ hybridization (FISH) with yeast artificial chromosome (YAC) clones, P1-artificial chromosome (PAC) clones, and cosmids from a well-characterized contig covering more than 6 Mb of genomic DNA. We identified four different breakpoint cluster regions. One is located close to or within the centromere of chromosome 17 and a second in the Charcot-Marie-Tooth (CMT1A) region at 17(p11.2). A third breakpoint was found telomeric to the CMT1A region. The fourth, most common breakpoint was detected in MB, AML, and in CML-BC specimens and was bordered by two adjacent cosmid clones (clones D14149 and M0140) within the Smith-Magenis syndrome (SMS) region. These results indicate that the low copy number repeat gene clusters which are present in the CMT and SMS regions may be one of the factors for the increased instability that may trigger the formation of an i(17q).

Large-scale chromatin unfolding and remodeling induced by VP16 acidic activation domain

Analysis of the relationship between transcriptional activators and chromatin organization has focused largely on lower levels of chromatin structure. Here we describe striking remodeling of large-scale chromatin structure induced by a strong transcriptional activator. A VP16-lac repressor fusion protein targeted the VP16 acidic activation domain to chromosome regions containing lac operator repeats. Targeting was accompanied by increased transcription, localized histone hyperacetylation, and recruitment of at least three different histone acetyltransferases. Observed effects on large-scale chromatin structure included unfolding of a 90-Mbp heterochromatic chromosome arm into an extended 25-40-micrometers chromonema fiber, remodeling of this fiber into a novel subnuclear domain, and propagation of large-scale chromatin unfolding over hundreds of kilobase pairs. These changes in large-scale chromatin structure occurred even with inhibition of ongoing transcription by alpha-amanitin. Our results suggest a functional link between recruitment of the transcriptional machinery and changes in large-scale chromatin structure. Based on the observed long-range propagation of changes in large-scale chromatin structure, we suggest a possible rationale for the observed clustering of housekeeping genes within Mbp-sized chromosome bands.

Large-scale chromatin structure and function

Recent results in living cells have now established the existence of levels of chromatin folding above the 30 nm fiber within interphase chromosomes. We discuss the potential functional impact of this large-scale chromatin organization, including its possible role in regulating gene expression.

Processing of endogenous pre-mRNAs in association with SC-35 domains is gene specific

Analysis of six endogenous pre-mRNAs demonstrates that localization at the periphery or within splicing factor-rich (SC-35) domains is not restricted to a few unusually abundant pre-mRNAs, but is apparently a more common paradigm of many protein-coding genes. Different genes are preferentially transcribed and their RNAs processed in different compartments relative to SC-35 domains. These differences do not simply correlate with the complexity, nuclear abundance, or position within overall nuclear space. The distribution of spliceosome assembly factor SC-35 did not simply mirror the distribution of individual pre-mRNAs, but rather suggested that individual domains contain both specific pre-mRNA(s) as well as excess splicing factors. This is consistent with a multifunctional compartment, to which some gene loci and their RNAs have access and others do not. Despite similar molar abundance in muscle fiber nuclei, nascent transcript "trees" of highly complex dystrophin RNA are cotranscriptionally spliced outside of SC-35 domains, whereas posttranscriptional "tracks" of more mature myosin heavy chain transcripts overlap domains. Further analyses supported that endogenous pre-mRNAs exhibit distinct structural organization that may reflect not only the expression and complexity of the gene, but also constraints of its chromosomal context and kinetics of its RNA metabolism.

Compartmentalization of interphase chromosomes observed in simulation and experiment

Human interphase chromosomes were simulated as a flexible fiber with excluded volume interaction, which represents the chromatin fiber of each chromosome. For the higher-order structures, we assumed a folding into 120 kb loops and an arrangement of these loops into rosette-like subcompartments. Chromosomes consist of subcompartments connected by small fragments of chromatin. Number and size of subcompartments correspond with chromosome bands in early prophase. We observed essentially separated chromosome arms in both our model calculations and confocal laser scanning microscopy, and measured the same overlap in simulation and experiment. Overlap, number and size of chromosome 15 subcompartments of our model chromosomes agree with subchromosomal foci composed of either early or late replicating chromatin, which were observed at all stages of the cell cycle and possibly provide a functionally relevant unit of chromosome territory compartmentalization. Computed distances of chromosome specific markers both on Mb and 10-100 Mb scale agree with fluorescent in situ hybridization measurements under different preparation conditions.

Conformation of replicated segments of chromosome fibres in human S-phase nucleus

Recent statistical analysis of the folding of G0/G1 chromosomes using fluorescence in situ hybridization (FISH) allowed development of a random walk/giant loop model of chromosome structure. According to this model there are two levels of organization of G0/G1 chromosome fibres. On the first level, the fibres are arranged in giant loops several Mbp in size, and within each loop the fibres are randomly folded. On the second level, the loop attachment sites form a chromosome backbone that also shows random folding. Newly replicated segments of mammalian chromosomes may be directly visualized at high resolution in S-phase nuclei using immunofluorescent methods and appear as worm-like fibres. In our earlier study, we analysed conformation of the fibres in human cells blocked for 16 h at the G1/S boundary with 5-fluorodeoxyuridine (FdU) and then released into S-phase by the addition of a DNA precursor. However, long treatment of cells with FdU induces very short replicons and may promote apoptosis. In this study we analysed conformation of the fibres in normally proliferating human cells that had not been blocked with FdU for a long time. It has been found that replicated chromosome fibres visualized just after 2 h of incubation of the cells with a non-radioactively labelled DNA precursor behave as flexible polymer chains without major constraints, and that their local conformation in the range of several microns of their contour length may be considered as random. Confocal analysis of human X chromosomes visualized in HeLa cells using FISH with a specific painting probe shows that in S-phase the chromosomes occupy distinct nuclear territories and their apparent size does not differ from that in non-S-phase cells. This observation indicates that the second level of chromosome organization also exists in S-phase chromosomes. It appears, therefore, that the random walk/giant loop model developed earlier for G0/G1 chromosomes is also valid for S-phase chromosomes.

Advances in fluorescence in situ hybridization

The techniques of in situ hybridization (ISH) are widely applied for analyzing the genetic make-up and RNA expression patterns of individual cells. This review focusses on a number of advances made over the last 5 years in the fluorescence ISH (FISH) field, i.e., Fiber-FISH, Multi-colour chromosome painting, Comparative Genomic Hybridization, Tyramide Signal Amplification and FISH with Polypeptide Nucleic Acid and Padlock probes.

Interphase cell cycle dynamics of a late-replicating, heterochromatic homogeneously staining region: precise choreography of condensation/decondensation and nuclear positioning

Recently we described a new method for in situ localization of specific DNA sequences, based on lac operator/repressor recognition (Robinett, C.C., A. Straight, G. Li, C. Willhelm, G. Sudlow, A. Murray, and A.S. Belmont. 1996. J. Cell Biol. 135:1685-1700). We have applied this methodology to visualize the cell cycle dynamics of an approximately 90 Mbp, late-replicating, heterochromatic homogeneously staining region (HSR) in CHO cells, combining immunostaining with direct in vivo observations. Between anaphase and early G1, the HSR extends approximately twofold to a linear, approximately 0.3-mum-diam chromatid, and then recondenses to a compact mass adjacent to the nuclear envelope. No further changes in HSR conformation or position are seen through mid-S phase. However, HSR DNA replication is preceded by a decondensation and movement of the HSR into the nuclear interior 4-6 h into S phase. During DNA replication the HSR resolves into linear chromatids and then recondenses into a compact mass; this is followed by a third extension of the HSR during G2/ prophase. Surprisingly, compaction of the HSR is extremely high at all stages of interphase. Preliminary ultrastructural analysis of the HSR suggests at least three levels of large-scale chromatin organization above the 30-nm fiber.

Comparative mapping of the DiGeorge syndrome region in mouse shows inconsistent gene order and differential degree of gene conservation

We have constructed a comparative map in mouse of the critical region of human 22q11 deleted in DiGeorge (DGS) and Velocardiofacial (VCFS) syndromes. The map includes 11 genes potentially haploinsufficient in these deletion syndromes. We have localized all the conserved genes to mouse Chromosome (Chr) 16, bands B1-B3. The determination of gene order shows the presence of two regions (distal and proximal), containing two groups of conserved genes. The gene order in the two regions is not completely conserved; only in the proximal group is the gene order identical to human. In the distal group the gene order is inverted. These two regions are separated by a DNA segment containing at least one gene which, in the human DGS region, is the most proximal of the known deleted genes. In addition, the gene order within the distal group of genes is inverted relative to the human gene order. Furthermore, a clathrin heavy chain-like gene was not found in the mouse genome by DNA hybridization, indicating that there is an inconsistent level of gene conservation in the region. These and other independent data obtained in our laboratory clearly show a complex evolutionary history of the DGS-VCFS region. Our data provide a framework for the development of a mouse model for the 22q11 deletion with chromosome engineering technologies.

Detection of 14q32.33 translocation and t(11;14) in interphase nuclei of chronic B-cell leukemia/lymphomas by in situ hybridization

Abnormalities of chromosome 14 involving band q32.33 are among the most commonly observed cytogenetic alterations in B-cell malignancies. To assess the incidence and pathogenetic implications of 14q32.33 translocation in chronic B-cell leukemia/lymphomas, we performed fluorescence in situ hybridization (FISH) analysis with variable region (V(H)) and gamma constant region (Cgamma) gene probes in 37 patients with these disorders. Chromosome 14q32.33 translocation was detected in 2 of 18 patients with chronic lymphocytic leukemia (CLL), 1 of 2 with CLL of mixed cell types (CLL/PL), 1 of 2 with pro-lymphocytic leukemia (PLL), 5 of 6 with leukemic mantle-cell lymphoma (MCL), 2 of 7 with splenic B-cell leukemia/lymphoma of possible marginal zone origin (SBLL) and 2 with leukemic follicular lymphoma (FL). To further characterize 14q32.33 translocations in these patients, we developed a new procedure using double-color FISH with PRAD1, BCL2, V(H) and Cgamma gene probes. Chromosome t(11;14) was detected in 1 patient with CLL/PL, 1 with PLL and 5 with MCL. Chromosome t(14;18) was detected in 2 patients with FL. In a PLL patient with t(11;14), the cosmid CPP29 containing the PRAD1 gene and its 5'-flanking region split and co-localized with both Cgamma and V(H) gene probes, thus spanning the breakpoint. In CLL and SBLL patients, donor chromosomes were other than chromosomes 2, 11, 18 and 19, suggesting the involvement of a novel oncogene(s) in the pathogenesis of these diseases. Interphase FISH rapidly detected 14q32.33 translocation, t(11;14) and t(14;18) in B-cell malignancies with low mitotic activity at the single-cell level, facilitating the correlation of the molecular features of these translocations with clinical characteristics.

Analysis of nucleolar transcription and processing domains and pre-rRNA movements by in situ hybridization

We have examined the cytological localization of rRNA synthesis, transport, and processing events within the mammalian cell nucleolus by double-label fluorescent in situ hybridization analysis using probes for small selected segments of pre-rRNA, which have known half-lives. In particular, a probe for an extremely short-lived 5' region that is not found separate of the pre-rRNA identifies nascent transcripts within the nucleolus of an intact active cell, while other characterized probes identify molecules at different stages in the rRNA processing pathway. Through these studies, visualized by confocal and normal light microscopy, we (1) confirm that rDNA transcription occurs in small foci within nucleoli, (2) show that the nascent pre-rRNA transcripts and most likely also the rDNA templates are surprisingly extended in the nucleolus, (3) provide evidence that the 5' end of the nascent rRNA transcript moves more rapidly away from the template DNA than does the 3' end of the newly released transcript, and (4) demonstrate that the various subsequent rRNA processing steps occur sequentially further from the transcription site, with each early processing event taking place in a distinct nucleolar subdomain. These last three points are contrary to the generally accepted paradigms of nucleolar organization and function. Our findings also imply that the nucleolus is considerably more complex than the conventional view, inferred from electron micrographs, of only three kinds of regions - fibrillar centers, dense fibrillar components, and granular components - for the dense fibrillar component evidently consists of several functionally distinct sub-domains that correlate with different steps of ribosome biogenesis.

Identification of bacterial cells by chromosomal painting

Chromosomal painting is a technique for the microscopic localization of genetic material. It has been applied at the subcellular level to identify regions of eukaryotic chromosomes. Here we describe the development of bacterial chromosomal painting (BCP), a related technology for the identification of bacterial cells. Purified genomic DNAs from six bacterial strains were labeled by nick translation with the fluorochrome Fluor-X, Cy3, or Cy5. The average size of the labeled fragments was ca. 50 to 200 bp. The probes were hybridized to formaldehyde-fixed microbial cells attached to slides and visualized by fluorescence microscopy. In reciprocal comparisons, distantly related members of the class Proteobacteria (Escherichia coli and Oceanospirillum linum), different species of the genus Bacillus (B. subtilis and B. megaterium), and different serotypes of the subspecies Salmonella choleraesuis subsp. choleraesuis (serotype typhimurium LT2 and serotype typhi Ty2) could easily be distinguished. A combination of two probes, each labeled with a different fluorochrome, was used successfully to simultaneously identify two cell types in a mixture. Lysozyme treatment was required for the identification of Bacillus spp., and RNase digestion and pepsin digestion were found to enhance signal strength and specificity for all cell types tested. Chromosome in situ suppression, a technique that removes cross-hybridizing fragments from the probe, was necessary for the differentiation of the Salmonella serotypes but was not required to distinguish the more distantly related taxa. BCP may have applications in diverse branches of microbiology where the objective is the identification of bacterial cells.

Construction and screening of a cosmid library generated from a somatic cell hybrid bearing human chromosome 15

A cosmid library has been constructed with DNA isolated from a mouse/human hybrid cell line designated A15, which was previously characterized and shown to retain chromosome 15 as the only human material. The library was generated and stored as 34 independent pools of primary colonies at 8-10,000 colonies per pool. Screening colonies representing pools of this library by hybridization with a human-specific repetitive probe has facilitated the identification of random clones bearing human inserts. To data, 43 unique clones have been isolated and the inserts mapped by fluorescence in situ hybridization (FISH) to chromosome 15. An STS was generated for each of these clones by end sequencing of the inserts. Two of these clones, c36 and MR23, were mapped by FISH to 15q26.1, and end-sequence data revealed homology to different regions of the FES protooncogene. Sequence generated from the other end of the c36 insert was found to match the previously identified and unmapped coding sequence EST00075. In addition to the identification of such random clones, establishment of the library as pools was expected to facilitate the PCR-based identification of unique clones representing specific regions of chromosome 15. Screening of the library pools with primers specific to the FES region led to the recovery of five independent clones facilitating the development of a cosmid contig encompassing the FES gene. One of the cosmids isolated by PCR-based analysis was derived from the same pool as M23 and was subsequently shown to be identical to M23. The data offer the first report of a chromosome 15 cosmid library and demonstrate the value of utilizing pools to evaluate libraries generated from complex sources like somatic cell hybrids.

Cloning and characterization of two vertebrate homologs of the Drosophila eyes absent gene

The Drosophila eyes absent (eya) gene plays an essential role in the events that lead to proper development of the fly eye and embryo. Here we report the analysis of two human and two mouse homologs of the fly eya gene. Sequence comparison reveals a large domain of approximately 270 amino acids in the carboxyl terminus of the predicted mammalian proteins that shows 53% identity between the fly sequence and all of the vertebrate homologs. This Eya-homology domain is of novel sequence, with no previously identified motifs. RNA hybridization studies indicate that the mouse genes are expressed during embryogenesis and in select tissues of the adult. Both mouse Eya genes are expressed in the eye, suggesting that these genes may function in eye development in vertebrates as eya does in the fly. The mouse Eya2 gene maps to chromosome 2 in the region syntenic with human chromosome 20q13, and the mouse Eya2 gene maps to chromosome 4 in the region syntenic with human chromosome 1p36. Our findings support the notion that several families of genes (Pax-6/eyeless, Six-3/sine oculis, and Eya) play related and critical roles in the eye for both files and vertebrates.

In vivo localization of DNA sequences and visualization of large-scale chromatin organization using lac operator/repressor recognition

We report a new method for in situ localization of DNA sequences that allows excellent preservation of nuclear and chromosomal ultrastructure and direct, in vivo observations. 256 direct repeats of the lac operator were added to vector constructs used for transfection and served as a tag for labeling by lac repressor. This system was first characterized by visualization of chromosome homogeneously staining regions (HSRs) produced by gene amplification using a dihydrofolate reductase (DHFR) expression vector with methotrexate selection. Using electron microscopy, most HSRs showed approximately 100-nm fibers, as described previously for the bulk, large-scale chromatin organization in these cells, and by light microscopy, distinct, large-scale chromatin fibers could be traced in vivo up to 5 microns in length. Subsequent experiments demonstrated the potential for more general applications of this labeling technology. Single and multiple copies of the integrated vector could be detected in living CHO cells before gene amplification, and detection of a single 256 lac operator repeat and its stability during mitosis was demonstrated by its targeted insertion into budding yeast cells by homologous recombination. In both CHO cells and yeast, use of the green fluorescent protein-lac repressor protein allowed extended, in vivo observations of the operator-tagged chromosomal DNA. Future applications of this technology should facilitate structural, functional, and genetic analysis of chromatin organization, chromosome dynamics, and nuclear architecture.

Statistical methods for gene map construction by fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) provides an efficient and powerful technique for ordering loci both on metaphase chromosomes and in less condensed interphase chromatin. Two-color metaphase FISH can be used to order pairs of loci relative to the centromere; two- and three-color interphase FISH can be used to accurately order trios of loci spaced within 1 Mb relative to one another. Loci separated by a distance > 1-2 Mb exhibit chromatin loops that often give rise to a statistically significant but incorrect order. We derive Bayesian methods for selecting the best locus order based on microscopic evaluation for each of these types of FISH mapping data. We then describe how the results from several two- and three-locus analyses can be combined to evaluate the approximate posterior probability of a given multilocus order within the limits of the technology utilized. These methods directly address the question of interest: What is the probability that the inferred two-, three-, or multilocus order actually is correct? We illustrate our analysis methods by applying them to previously described FISH mapping data of 14 markers in the BRCA1 region on chromosome 17q12-q21. We also propose design strategies to order a group of closely spaced (< 1 Mb) loci, two and three loci at a time, using a bisection strategy for two-color FISH data and a trisection strategy for three-color FISH data. These strategies have the best worst-case performance for ordering a new locus relative to a group of ordered loci and are nearly optimal for ordering a group of loci of unknown order. These, in conjunction with physical mapping strategies, provide efficient and reliable methods for gene map construction by FISH.

Organization of the Hox gene cluster in the grasshopper, Schistocerca gregaria

The conserved organization of the Hox genes throughout the animal kingdom has become one of the major paradigms of evolutionary developmental biology. We have examined the organization of the Hox genes of the grasshopper, Schistocerca gregaria. We find that the grasshopper Hox cluster is over 700 kb long, and is not split into equivalents of the Antennapedia complex and the bithorax complex of Drosophila melanogaster. SgDax and probably also Sgzen, the grasshopper homologues of fushi-tarazu (ftz) and Zerknüllt (zen), respectively, are also in the cluster, showing that the non-homeotic Antp-class genes, "accessory genes," are an ancient feature of insect Hox clusters.

Interphase fluorescence in situ hybridization mapping: a physical mapping strategy for plant species with large complex genomes

The chromatin in interphase nuclei is much less condensed than are metaphase chromosomes, making the resolving power of fluorescence in situ hybridization (FISH) two orders of magnitude higher in interphase nuclei than on metaphase chromosomes. In mammalian species it has been demonstrated that within a certain range the interphase distance between two FISH sites can be used to estimate the linear DNA distance between the two probes. The interphase mapping strategy has never been applied in plant species, mainly because of the low sensitivity of the FISH technique on plant chromosomes. Using a CCD (charge-coupled device) camera system, we demonstrate that DNA probes in the 4 to 8 kb range can be detected on both metaphase and interphase chromosomes in maize. DNA probes pA1-Lc and pSh2.5.SstISalI, which contain the maize loci a1 and sh2, respectively, and are separated by 140 kb, completely overlapped on metaphase chromosomes. However, when the two probes were mapped in interphase nuclei, the FISH signals were well separated from each other in 86% of the FISH sites analyzed. The average interphase distance between the two probes was 0.50 micron. This result suggests that the resolving power of interphase FISH mapping in plant species can be as little as 100 kb. We also mapped the interphase locations of another pair of probes, ksu3/4 and ksu16, which span the Rp1 complex controlling rust resistance of maize. Probes ksu3/4 and ksu16 were mapped genetically approximately 4 cM apart and their FISH signals were also overlapped on metaphase chromosomes. These two probes were separated by an average of 2.32 microns in interphase nuclei. The possibility of estimating the linear DNA distance between ksu3/4 and ksu16 is discussed.

Utilization of FISH in positional cloning: an example on 13q22

In positional cloning the initial assignment of a gene to a specific chromosomal locus is followed by physical mapping of the critical region. The construction of a high-resolution physical map still involves considerable effort. However, new high-resolution fluorescence in situ hybridization (FISH) techniques have facilitated this process substantially. Here we summarize a strategy that combines a spectrum of FISH techniques [metaphase, interphase, mechanically stretched chromosomes (MSCs), and fiber-FISH on free chromatin] for the construction and characterization of a high-resolution physical map for a positional cloning project. The chromosomal region 13q22, containing the locus of the variant form of the neuronal ceroid lipofuscinosis (vLINCL, CLN5) disease, serves here as an example for this process. We used metaphase FISH to exclude positionally a candidate gene, to refine the locus to 13q22, and to analyze the possible chimerism of the YACs in the region. Both metaphase and interphase FISH techniques were applied to determine the low-resolution distances between the restricting markers. FISH using MSCs confirmed the centromeric-telomeric order of the clones and facilitated the estimation of the size of the gaps between the clones. Finally, fiber-FISH was found to be the method of choice for the construction of an accurate high-resolution map of the contig established over the restricted region. Thus, FISH techniques in combination with genetic mapping data enabled the refinement of the initial 4-cM region to a high-resolution map of only 400 kb in length. Here the FISH strategy replaced the need for many laborious traditional physical mapping methods, e.g., pulsed-field gel electrophoresis.

High-resolution fluorescence in situ hybridization: a new approach in genome mapping

Mapping of the human genome has been a global effort utilizing both genetic and physical mapping techniques. One approach which has greatly facilitated the physical mapping of the human genome is fluorescence in situ hybridization (FISH). Although FISH is by now a well-established technology, new recently developed modifications have enabled an easier use and higher resolution. The high-resolution FISH techniques have given a special impact in positional cloning: searching the functional gene from a chromosomal area where the gene has been genetically localized. New high-resolution FISH techniques include hybridization of probes to free chromatin, DNA fibres or mechanically stretched chromosomes. These targets have widened the resolution of FISH to detect distances from the traditional cytogenetic resolution level down to a resolution of a few kilobases. They also have significantly speeded up high-resolution physical mapping and thus made the search of new disease genes easier.

Nonrandom gene organization: structural arrangements of specific pre-mRNA transcription and splicing with SC-35 domains

This work demonstrates a highly nonrandom distribution of specific genes relative to nuclear domains enriched in splicing factors and poly(A)+ RNA, and provides evidence for the direct involvement of these in pre-mRNA metabolism. As investigated in hundreds of diploid fibroblasts, human collagen I alpha 1 and beta-actin DNA/RNA showed a very high degree of spatial association with SC-35 domains, whereas three nontranscribed genes, myosin heavy chain, neurotensin, and albumin, showed no such preferential association. Collagen I alpha 1 RNA accumulates within the more central region of the domain, whereas beta-actin RNA localizes at the periphery. A novel approach revealed that collagen RNA tracks are polarized, with the entire gene at one end, on the edge of the domain, and the RNA extending into the domain. Intron 26 is spliced within the RNA track at the domain periphery. Transcriptional inhibition studies show both the structure of the domain and the gene's relationship to it are not dependent upon the continued presence of accumulated collagen RNA, and that domains remaining after inhibition are not just storage sites. Results support a model reconciling light and electron microscopic observations which proposes that transcription of some specific genes occurs at the border of domains, which may also function in the assembly or distribution of RNA metabolic components. In contrast to the apparently random dispersal of total undefined hnRNA synthesis through interdomain space, transcription and splicing for some genes occurs preferentially at specific sites, and a high degree of individual pre-mRNA metabolism is compartmentalized with discrete SC-35 domains.

U2 and U1 snRNA gene loci associate with coiled bodies

The coiled bodies are nuclear structures rich in a variety of nuclear and nucleolar components including snRNAs. We have investigated the possibility that coiled bodies may associate with snRNA genes and report here that there is a high degree of association between U2 and U1 genes with a subset of coiled bodies. As investigated in human HeLa cells grown in monolayer culture, about 75% of nuclei had at least one U2 gene associated with a coiled body, and 45% had at least one U1 locus associated. In another suspension-grown HeLa cell strain, 92% of cells showed associated of one or more U2 genes with coiled bodies. In contrast to the U2 and U1 gene associations, a locus closely linked to the U2 gene cluster appeared associated with a coiled body only in 10% of cells. Associated snRNA gene signals were repeatedly positioned at the edge of the coiled body. Thus, this associated was highly nonrandom and spatially precise. Our analysis revealed a much higher frequency of association for closely spaced "doublet" U2 gene signals, with over 80% of paired signals associated as opposed to 35% for single U2 signals. This finding, coupled with the fact that not all genes were associated in all cells, suggested the possibility of a cell-cycle-dependent, possibly S-phase, association. However, an analysis of S- and non-S-phase cells using BrdU incorporation or cell synchronization did not indicate an increased level of association in S-phase. These and other results suggested that a substantial fraction of paired U2 signals represented association of U2 genes on homologous chromosomes rather than only replicated DNA. Furthermore, triple label analysis showed that in a significant fraction of cells U1 and U2 genes were both associated with the same coiled body. U1 and U2 genes were closely paired in approximately 20% of cells, over 60% of which were associated with a readily identifiable coiled body. This finding raises the possibility that multiple genes of a particular class may be in association with each coiled body. Thus, the coiled body may be a dynamic structure which transiently interacts with or is formed by one or more specific genetic loci, possibly carrying out some function related to their expression.

Direct selection of cDNAs using whole chromosomes

We have developed a method for direct selection of cDNAs using whole chromosomes as target DNA. Double-strand cDNAs were synthesized from human fetal brain polyadenylated mRNAs. Flow-sorted chromosomes 17 and 19 were amplified by degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR) and used to capture ds cDNAs by an improved magnetic bead capture protocol. To demonstrate the capabilities of this method, the selected cDNAs were used as probes in FISH experiments. The selected cDNA populations specifically painted chromosomes 17 or 19 on metaphase spreads. These results demonstrate that it is possible to do chromosome painting using cDNA probes and that this method is a means to rapidly select expressed sequences encoded by any portion of the genome.

The relationship between physical and genetic distances at the Hor1 and Hor2 loci of barley estimated by two-colour fluorescent in situ hybridization

The hordeins are the major class of storage proteins in barley. They are encoded by multigene families. The B- and C-hordein loci have been mapped physically to the distal end of chromosome 5 (1I) of cultivated barley by fluorescent in situ hybridization. Based on measurements of chromosomal distances between the two hordein loci, the relationship between genetic and physical distances has been estimated to be about 1 mega base pairs per centiMorgan. This is four times higher than the mean value for the barley genome as a whole and confirms the tendency to increased recombination in distal chromosome regions. The resolving power of two-colour FISH is discussed. It is concluded that the method is suitable for estimating the relationship between genetic and physical distances of regions of about 10 Mbp or larger.

Intragenic matrix attachment and DNA-protein interactions in the human X-linked Hprt gene

To investigate the possible contribution of intragenic differentially methylated cytosines to X-linked gene expression, we examined DNA-protein interactions in a region in intron 3 of the human hypoxanthine phosphoribosyltransferase gene which contains at least one HpaII site methylated specifically on the active X. In vitro DNase I footprinting experiments using unmethylated DNA and HeLa nuclear extract identified three footprints (I-III). Footprints I and III flank an Alu repeat containing the HpaII site(s), one of which is contained within footprint II. Although methylation of the HpaII site had no effect on footprint II binding interactions, methylation of nearby CpGs substantially reduced the formation of three of the specific DNA-protein complexes binding to footprint II in mobility shift assays. Additionally, an A+T rich region immediately 5' to the HpaII-containing Alu repeat was found to bind specifically to nuclear matrices in vitro. We suggest that differential methylation of CpGs may affect the binding of regulatory proteins in vivo, and that interactions between the footprint proteins and those binding to the matrix attachment region may be involved in controlling X-linked Hprt expression.

A postprophase topoisomerase II-dependent chromatid core separation step in the formation of metaphase chromosomes

Metaphase chromatids are believed to consist of loops of chromatin anchored to a central scaffold, of which a major component is the decatenatory enzyme DNA topoisomerase II. Silver impregnation selectively stains an axial element of metaphase and anaphase chromatids; but we find that in earlier stages of mitosis, silver staining reveals an initially single, folded midline structure, which separates at prometaphase to form two chromatid axes. Inhibition of topoisomerase II prevents this separation, and also prevents the contraction of chromatids that occurs when metaphase is arrested. Immunolocalization of topoisomerase II alpha reveals chromatid cores analogous to those seen with silver staining. We conclude that the chromatid cores in early mitosis form a single structure, constrained by DNA catenations, which must separate before metaphase chromatids can be resolved.

Topographic changes in a heterochromatic chromosome block in humans (15P) during formation of the nucleolus

Fluorescence in situ hybridization and multispectral confocal laser scanning microscopy revealed a highly dynamic nucleolar-associated chromosome 15 satellite III heterochromatin cluster in humans. This nucleolar-associated DNA was highly decondensed at the metaphase plate compared with its topography at interphase and appeared to act as a centre for the post-mitotic reorganization of the nucleolus. Our data showed unexpected trans-mitotic changes in the topography of this nucleolar-associated satellite III DNA that suggest that this locus-specific heterochromatin superstructure may be involved in nucleolar organization.

‘Chromosomal puffing’ in diploid nuclei of Drosophila melanogaster

In situ hybridization has become a powerful technique for dissecting nuclear structure. By localizing nucleic acids with high precision, it is possible to infer the native structure of chromosomes, replication factories and transcript processing complexes. To increase the value of this technique, we have established the limits of resolution of two-color in situ hybridization to chromosomal DNA in diploid chromosomes of Drosophila embryonic nuclei. Using high-resolution 3-dimensional optical microscopy and computational image analysis, we establish that we can distinguish the location of chromosomal sequences that lie 27–29 kb apart within a 40 kb transcription unit with an accuracy of about 100 nm. Contrary to observations made in mammalian tissue culture cells, we find that when the gene is expressed, it assumes an open configuration, and that the extent of decondensation is variable from chromosome to chromosome. Further experiments suggest that variation in gene structure results from asynchrony in transcriptional elongation. We suggest that the phenomenon we observe is the diploid analog to chromosomal puffing that occurs in the transcriptionally active regions of Drosophila polytene chromosomes.

High-resolution physical mapping of a 250-kb region of human chromosome 11q24 by genomic sequence sampling (GSS)

A physical map of the region of human chromosome 11q24 containing the FLI1 gene, disrupted by the t(11;22) translocation in Ewing sarcoma and primitive neuroectodermal tumors, was analyzed by genomic sequence sampling. Using a 4- to 5-fold coverage chromosome 11-specific library, 22 region-specific cosmid clones were identified by phenol emulsion reassociation hybridization, with a 245-kb yeast artificial chromosome clone containing the FLI1 gene, and by directed "walking" techniques. Cosmid contigs were constructed by individual clone fingerprinting using restriction enzyme digestion and assembly with the Genome Reconstruction and AsseMbly (GRAM) computer algorithm. The relative orientation and spacing of cosmid contigs with respect to the chromosome was determined by the structural analysis of cosmid clones and by direct visual in situ hybridization mapping. Each cosmid clone in the contig was subjected to "one-pass" end sequencing, and the resulting ordered sequence fragments represent approximately 5% of the complete DNA sequence, making the entire region accessible by PCR amplification. The sequence samples were analyzed for putative exons, repetitive DNAs, and simple sequence repeats using a variety of computer algorithms. Based upon the computer predictions, Southern and Northern blot experiments led to the independent identification and localization of the FLI1 gene as well as a previously unknown gene located in this region of chromosome 11q24. This approach to high-resolution physical analysis of human chromosomes allows the assembly of detailed sequence-based maps and provides a tool for further structural and functional analysis of the genome.

Molecular cloning of a human genomic region containing the H blood group alpha(1,2)fucosyltransferase gene and two H locus-related DNA restriction fragments. Isolation of a candidate for the human Secretor blood group locus

We have used the human H blood group alpha(1,2)fucosyltransferase (FUT1) cDNA to screen chromosome 19 cosmid libraries in a search for the human Secretor (Se) blood group gene (FUT2). One cosmid has been isolated that contains two distinct segments that cross-hybridize with FUT1. We have assembled a 100-kilobase (kb) cosmid contig, localized to 19q13.3, encompassing FUT1 and the two FUT1-related sequences, termed Sec1 and Sec2, for Secretor candidate 1 and 2. Sec1 and Sec2 are separated by 12 kb and are 65.5 kb and 35 kb apart, respectively, from the FUT1 gene. We used a cosmid-dependent direct cDNA selection method to clone a cDNA corresponding to a transcript that emanates from Sec2. This cDNA detects a 3.35-kb transcript in human tissues known to express the Se locus. Together with sequence and expression data reported in the accompanying article (Kelly, R. J., Rouquier, S., Giorgi, D., Lennon, G. G., and Lowe, J. B. (1995) J. Biol. Chem. 270, 4640-4649), these data demonstrate that Sec2 corresponds to the human Se blood group locus (FUT2). Our results furthermore define the physical relationship between the H and Se loci and confirm a hypothesis that these two loci represent distinct but closely linked alpha(1,2)fucosyltransferase genes.

Application of fluorescence in situ hybridization in genome analysis of the mouse

Fluorescence in situ hybridization (FISH) is an effective technique for localizing cloned DNA probes directly onto metaphase chromosomes. Human genome mapping using FISH has been significantly enhanced by the development of new techniques, especially high-resolution gene mapping with direct R-banding FISH and physical gene ordering with multi-color FISH. By contrast, FISH techniques have not been put to practical use for the analysis of the mouse genome compared with the human. We have developed and modified FISH techniques for use in mouse genome analysis. In this article we summarize and review our recent results with FISH analyses in the following studies: (i) high-resolution gene mapping with the direct R-banding FISH, (ii) analysis of chromosomal rearrangement with multi-color FISH, (iii) establishment of centromere mapping with the major satellite DNA probe, (iv) analysis of chromatin structure in meiotic cells, and (v) application of FISH in cytogenetic studies of genetic variation in the mouse, showing that these applications of FISH are very useful for mouse genome analysis.

Treatment of cells with alkaline borate buffer extends the capability of interphase FISH mapping

Interphase fluorescence in situ hybridization (FISH) has been shown to be a means to map DNA sequences relative to each other in the 100 kb to 1-2 Mb genomic-separation range. At distances below 0.1 Mb, probe sites are infrequently resolved in interphase chromatin. In the 0.1- to 1-Mb range, interphase chromatin can be modeled as a freely flexible chain. The mean square interphase distance between two probes is proportional to the genomic separation between the probes on the linear DNA molecule. Above 1-2 Mb, the relationship between interphase distance and genomic separation changes abruptly and appears to level off. We have used alkaline-borate treatment to expand the capability of interphase FISH mapping. We show here that alkaline-borate treatment increases nuclear diameter, the interphase distance between probes on homologous chromosomes, and the distance between probes on the same chromosome. We also show that the mean square distance between hybridization sites in borate-treated nuclei is proportional to genomic separation up to 4 Mb. Thus, alkaline-borate treatment enhances the capability of interphase FISH mapping by increasing the absolute distance between probes and extending the range of the simple relationship between interphase distance and genomic separation.

D20S16 is a complex interspersed repeated sequence: genetic and physical analysis of the locus

The genomic structure of the D20S16 locus has been evaluated using genetic and physical methods. D20S16, originally detected with the probe CRI-L1214, is a highly informative, complex restriction fragment length polymorphism consisting of two separate allelic systems. The allelic systems have the characteristics of conventional VNTR polymorphisms and are separated by recombination (theta = 0.02, Zmax = 74.82), as demonstrated in family studies. Most of these recombination events are meiotic crossovers and are maternal in origin, but two, including deletion of the locus in a cell line from a CEPH family member, occur without evidence for exchange of flanking markers. DNA sequence analysis suggests that the basis of the polymorphism is variable numbers of a 98-bp sequence tandemly repeated with 87 to 90% sequence similarity between repeats. The 98-bp repeat is a dimer of 49 bp sequence with 45 to 98% identity between the elements. In addition, nonpolymorphic genomic sequences adjacent to the polymorphic 98-bp repeat tracts are also repeated but are not polymorphic, i.e., show no individual to individual variation. Restriction enzyme mapping of cosmids containing the CRI-L1214 sequence suggests that there are multiple interspersed repeats of the CRI-L1214 sequence on chromosome 20. The results of dual-color fluorescence in situ hybridization experiments with interphase nuclei are also consistent with multiple repeats of an interspersed sequence on chromosome 20.

Identification of YAC clones for human chromosome 1p32 and physical mapping of the infantile neuronal ceroid lipofuscinosis (INCL) locus

Infantile neuronal ceroid lipofuscinosis (INCL, CLN1) is a neurodegenerative disorder in which the biochemical defect is unknown. We earlier assigned the disease locus to chromosome 1p32 in the immediate vicinity of the highly informative HY-TM1 marker by linkage and linkage disequilibrium analysis. Here we report the construction of PFGE maps on the CLN1 region covering a total of 4 Mb of this relatively poorly mapped chromosomal region. We established the order of loci at 1p32 as tel-D1S57-L-myc-HY-TM1-rlf-COL9A2-D1S193-D1S6 2-D1S211-cen by combining data obtained from analysis of a chromosome 1 somatic cell hybrid panel, PFGE, and interphase FISH. We isolated YACs and constructed two separate YAC contigs, the loci L-myc, HY-TM1, rlf, and COL9A2 being present on a 1000-kb contig and the markers D1S193, D1S62, and D1S211 on a YAC contig spanning a maximum of 860 kb. Within the 1000-kb contig we were able to identify five CpG islands in addition to those associated with the earlier cloned genes. The YAC contigs as well as the physical map provide us with tools for the identification of the INCL gene.

Interstitial duplication of proximal 22q: phenotypic overlap with cat eye syndrome

We describe a child with downslanting palpebral fissures, preauricular malfunctions, congenital heart defect (total anomalous pulmonary venous return), unilateral absence of a kidney, and developmental delay with an apparent interstitial duplication of proximal 22q. Fluorescent in situ hybridization (FISH) analysis showed duplication of the IGLC locus, and C-banding of the duplicated region was negative. The duplication appears to involve 22q11.2-q12. Although the child has neither colobomas nor microphthalmia, he shows phenotypic overlap with the cat eye syndrome, which is caused by a supernumerary bisatellited chromosome arising from inverted duplication of the short arm and proximal long arm of chromosome 22. Further molecular studies of this patient should help to define the regions responsible for the manifestations of cat eye syndrome.

Optical mapping of site-directed cleavages on single DNA molecules by the RecA-assisted restriction endonuclease technique

Fluorescence in situ hybridization (FISH) resolution has advanced because newer techniques use increasingly decondensed chromatin. FISH cannot analyze restriction enzyme cutting sites due to limitations of the hybridization and detection technologies. The RecA-assisted restriction endonuclease (RARE) technique cleaves chromosomal DNA at a single EcoRI site within a given gene or selected sequence. We recently described a mapping technique, optical mapping, which uses fluorescence microscopy to produce high-resolution restriction maps rapidly by directly imaging restriction digestion cleavage events occurring on single deproteinized DNA molecules. Ordered maps are then constructed by noting fragment order and size, using several optically based techniques. Since we also wanted to map arbitrary sequences and gene locations, we combined RARE with optical mapping to produce site-specific visible EcoRI restriction cleavage sites on single DNA molecules. Here we describe this combined method, named optical RARE, and its initial application to mapping gene locations on yeast chromosomes.

Duplication 3q syndrome: molecular delineation of the critical region

The phenotype of dup(3q) syndrome partially overlaps with Brachmann-de Lange phenotype. Convulsions and eye, palate renal, and cardiac anomalies are more frequent in dup(3q) syndrome, while limb deficiencies, hirsutism, and synophrys are more characteristic of Brachmann-de Lange syndrome. Whether the two syndromes have a biological relationship has yet to be demonstrated. Using two patient translocation cell lines, each involving distal 3q, we have narrowed the critical region of the dup(3q) syndrome to the interval 3q26.31-q27.3 and initiated its molecular characterization. We have mapped in this region 6 cosmid clones spanning approximately 3-5 Mb. The critical region appears to overlap with the region where a balanced translocation was found in a Brachmann-de Lange patient. This work provides the mapping framework for finer molecular analysis of dup(3q) syndrome.

CCD microscopy and image analysis of cells and chromosomes stained by fluorescence in situ hybridization

This paper reviews methods and applications of CCD microscopy for analysing cells and chromosomes subjected to fluorescence in situ hybridization (FISH). The current status of indirect and direct FISH staining methods with respect to probe labelling, detection sensitivity, multiplicity and DNA resolution is summarized. Microscope hardware, including special multi-band pass filters and CCD cameras required for FISH analysis, is described. Then follows a detailed discussion of current and emerging applications such as the automated enumeration of chromosomal abnormalities (counting of dots in interphase cells), comparative genomic hybridization, automated evaluation of radiation-induced chromosomal translocations, and high-resolution DNA mapping on highly extended chromatin. Finally, the limitations of the present methodology and future prospects are discussed.

Semiautomated DNA probe mapping using digital imaging microscopy: II. System performance

This paper describes an evaluation of a semiautomated, multicolor image-analysis system to map cloned probes along metaphase chromosomes. Mapping with this system consists of fluorescence in situ hybridization (FISH) for probe localization, automatic acquisition of multicolor images showing total chromosomal DNA and probe location(s), and automatic determination of the fractional locations of the probes along the chromosomes relative to the short arm telomere (FLpter). The system was evaluated by mapping ten phage and ten cosmid probes previously mapped to chromosome 3 with other procedures. The standard deviations of FLpter measurements averaged 3.4 Mb and 2.6 Mb for phage and cosmid probes, respectively. With this variation, the order of two probes mapped in separate hybridizations could be determined with 95% confidence when their separation was greater than 2.5 Mb. In all cases, the probe locations and order were consistent with previous mapping data. FLpter values were converted to band locations using measurements of the band locations made using digital imaging microscopy. This proved superior to conversions made using ISCN ideograms.

Impact of the human genome project on medical practice

BACKGROUND

The Human Genome Project is a coordinated effort to define the human genetic blueprint. The goals include construction of a variety of maps of the human genome, including the identification and localization of all genes. The discovery of genes responsible for human diseases has had a significant impact on the practice of medicine.

METHODS

Methods for defining the human genome include cytogenetic, physical, and genetic mapping techniques. A variety of strategies have been used to identify human genes, especially those genes that are responsible for disease. Once a disease gene has been identified, this information can be used to develop new diagnostic and therapeutic procedures.

RESULTS

A number of disease genes have already been identified, leading to improved diagnosis and novel approaches to therapy. A new type of mutation, trinucleotide repeat expansion, has been found to be responsible for at least seven diseases with an unusual inheritance pattern.

CONCLUSIONS

Materials and technology generated by the Human Genome Project and related research have provided important tools for the diagnosis and treatment of patients afflicted with genetic diseases.

Spatial localization of pre-mRNA transcription and processing within the nucleus

The organization of transcription, processing, and transport of pre-mRNA within the nucleus is a major unsolved problem in cell biology. Several recent studies have helped to define the localization of specific DNAs, RNAs, and proteins within the nucleus and have led to various models for higher level organization of pre-mRNA metabolism.

Construction and characterization of a bacterial artificial chromosome library of Sorghum bicolor

The construction of representative large insert DNA libraries is critical for the analysis of complex genomes. The predominant vector system for such work is the yeast artificial chromosome (YAC) system. Despite the success of YACs, many problems have been described including: chimerism, tedious steps in library construction and low yields of YAC insert DNA. Recently a new E.coli based system has been developed, the bacterial artificial chromosome (BAC) system, which offers many potential advantages over YACs. We tested the BAC system in plants by constructing an ordered 13,440 clone sorghum BAC library. The library has a combined average insert size, from single and double size selections, of 157 kb. Sorghum inserts of up to 315 kb were isolated and shown to be stable when grown for over 100 generations in liquid media. No chimeric clones were detected as determined by fluorescence in situ hybridization of ten BAC clones to metaphase and interphase S.bicolor nuclei. The library was screened with six sorghum probes and three maize probes and all but one sorghum probe hybridized to at least one BAC clone in the library. To facilitate chromosome walking with the BAC system, methods were developed to isolate the proximal ends of restriction fragments inserted into the BAC vector and used to isolate both the left and right ends of six randomly selected BAC clones. These results demonstrate that the S. bicolor BAC library will be useful for several physical mapping and map-based cloning applications not only in sorghum but other related cereal genomes, such as maize. Furthermore, we conclude that the BAC system is suitable for most large genome applications, is more 'user friendly' than the YAC system, and will likely lead to rapid progress in cloning biologically significant genes from plants.

E2F-4, a new member of the E2F transcription factor family, interacts with p107

The E2F family of transcription factors has been implicated in the regulation of cell proliferation, and E2F-binding sites are present in the promoters of several growth-regulating genes. E2F family members are functionally regulated, in part, by complex formation with one or more members of the nuclear pocket protein family, RB, p107, and p130. Pocket protein regulation of E2F likely contributes to normal cellular growth control. While the three cloned species of E2F, E2F-1, E2F-2, and E2F-3, are known to be targets of RB interaction, no E2F species has yet been shown to be a specific p107 or p130 target. Here, we describe the cloning of a new member of the E2F family, E2F-4, which forms heterodimers with a member(s) of the DP family and, unlike some family members, is present throughout the cell cycle and appears to be a differentially phosphorylated p107-binding partner. p107 binding not only can be linked to the regulation of E2F-4 transcriptional activity, but also to suppression of the ability of E2F-4 to transform an immortalized rodent cell line.