A glimpse at chromosomal order

Specific inhibition of DNA binding to nuclear scaffolds and histone H1 by distamycin. The role of oligo(dA).oligo(dT) tracts

Scaffold-associated regions (SARs) are A + T-rich sequences defined by their specific interaction with the nuclear scaffold. These sequences also direct highly specific binding to purified histone H1, and are characterized by the presence of oligo(dA).oligo(dT) tracts, which are a target for the drug distamyin, an antibiotic with a wide range of biological activities. The interaction of distamycin with SAR sequences results in the complete suppression of binding to either scaffolds or histone H1, suggesting that (dA.dT)n tracts play a direct role in mediating these specific interactions and that histone H1 and nuclear scaffold proteins may recognize a characteristic minor groove width or conformation. The effect of distamycin on these specific DNA-protein interactions in vitro suggests that binding of SARs to the nuclear scaffold and SAR-dependent nucleation of H1 assembly might be important targets of the drug in vivo.

Checkpoints: controls that ensure the order of cell cycle events

The events of the cell cycle of most organisms are ordered into dependent pathways in which the initiation of late events is dependent on the completion of early events. In eukaryotes, for example, mitosis is dependent on the completion of DNA synthesis. Some dependencies can be relieved by mutation (mitosis may then occur before completion of DNA synthesis), suggesting that the dependency is due to a control mechanism and not an intrinsic feature of the events themselves. Control mechanisms enforcing dependency in the cell cycle are here called checkpoints. Elimination of checkpoints may result in cell death, infidelity in the distribution of chromosomes or other organelles, or increased susceptibility to environmental perturbations such as DNA damaging agents. It appears that some checkpoints are eliminated during the early embryonic development of some organisms; this fact may pose special problems for the fidelity of embryonic cell division.

UV-enhanced reactivation of UV-damaged SV40 is due to the restoration of viral early gene function

Mammalian cells respond to UV-radiation by inducing an increased ability to support the survival of UV-damaged virus. We have tested whether the induction of enhanced viral reactivation (ER) reflects heightened UV-resistance of specific viral functions. For this, we examined the extent of ER for SV40 containing UV-damage in three functionally distinct regions of the SV40 genome: (i) the viral regulatory region, (ii) the early genes region and (iii) the late genes region. ER corresponding to a dose reduction factor of 43% was observed for damage in the early genes region. No ER was observed for damage in the regulatory or late genes regions. We conclude that ER in SV40 reverses the lethal disruption of an essential function peculiar to the viral early genes region. This function is almost certainly transcription.

Chromosomal mapping and nucleotide sequence of a human DNA autonomously replicating sequence

A 1.1-kb human DNA fragment (ARSH1) capable of functioning as a putative origin of replication in yeast cells has been characterized both by in situ hybridization to human metaphase chromosomes and by DNA sequencing. Our hybridization studies show a preferential localization of ARSH1 in chromosome regions 1p34-36 and 2q34-37. DNA sequence analysis indicates that in addition to the consensus sequence required for ARS function in yeast cells, nuclear matrix-associated DNA motifs are also present in the 1.1-kb fragment. These results suggest that ARSH1 sequences may serve as points of anchorage to the nuclear matrix for chromosomes 1 and 2.

A nuclear DNA attachment element mediates elevated and position-independent gene activity

The transcriptional activity of genes that have randomly integrated into the genomes of transfected cells and transgenic organisms is in general unpredictable, varying with the chromosomal site of the insertion. This effect of chromosomal position on gene expression may reflect the organization of chromosomes into topologically constrained loops and functional domains. To assess the biological significance of these loop domains, the anchorage of DNA to the nuclear scaffold has been studied at specific gene loci. We have previously defined cis-acting regions flanking the chicken lysozyme-gene domain that mediate the attachment of the chromatin to the nuclear scaffold. These 'A-elements' map to the 5' and 3' boundaries of the region of general DNase sensitivity in the active chromatin, which contains the lysozyme gene and its cis-regulatory elements. Here we report that when a reporter gene is flanked by 5' A-elements from the lysozyme gene, its expression in stably transfected cells is significantly elevated and is independent of chromosomal position.

An enhancer stimulates transcription in trans when attached to the promoter via a protein bridge

Two principal models have been invoked to explain transcriptional stimulation of RNA polymerase II genes by enhancers/upstream promoter elements: in one, upstream regulatory sequences directly interact with proximal promoter elements via proteins bound to the DNA ("looping" model); in the other, RNA polymerase II (or a transcription factor) binds to distal sequences and then scans along the DNA until it reaches the promoter ("scanning" or "entry site" model). So far, it has been reported that enhancers or upstream promoter elements transmit their effect on a gene only via covalently closed DNA, i.e., in a cis configuration. The looping model predicts, however, that the effect can be transmitted also in certain trans configurations. Here we demonstrate that an enhancer from SV40 or cytomegalovirus can stimulate transcription in vitro even when noncovalently attached to the beta-globin promoter via the proteins streptavidin or avidin. These findings are consistent with the looping model rather than the scanning model. In addition, stimulation of transcription in trans, as shown by our experiments, may be found in nature in phenomena such as transvection, where one chromosome affects gene expression in the paired homolog.

Analysis of distal flanking regions of maize 19-kDa zein genes

Two genomic fragments from maize, each containing a 19-kDa zein gene with extensive flanking regions, have been sequenced and examined by computer-aided analysis and Southern blotting techniques. Sequence analysis of the distal flanking sequences has revealed interesting sequence motifs, some not seen before. In particular, four nearly identical, G + C-rich, 17 to 21-bp perfect palindromes were found clustered in a 133-bp stretch lying 2 kb upstream from the zein-coding region in the genomic clone pMS2. These palindromic sequences exhibit other interesting features, including a precise spatial organization with respect to each other, and their proximity to several other repeated motifs in the same region. Southern blot analysis indicates that these palindromes, or closely related sequences, are found frequently in the maize genome. Possible secondary structures for the palindrome units are presented, which resemble functionally important sequences found upstream from other eukaryotic genes.

Dynamics of chromatin changes in live one-cell mouse embryos: a continuous follow-up by fluorescence microscopy

Conditions of minimal dye concentration and minimal irradiation which allow the continuous observation of pronuclei in live unicellular mouse eggs by fluorescence microscopy have been found with the use of Hoechst 33342 as fluorophore and a camera of high sensitivity coupled with an image processing system allowing true integration of weak fluorescent signals and further treatment and analysis. Under these conditions the developmental potential of the embryos is not affected. Using such an approach, which avoids eventual artifacts due to fixation procedure, we describe the changes in the nuclear organization and chromatin structure, from formation of pronuclei to mitosis, with particular attention to the chromatin associated with nucleoli and the timing process of chromatin condensation.

A protein factor that enhances amsacrine-mediated formation of topoisomerase II-DNA complexes in murine mastocytoma cell nuclei

Extracts of K21 murine mastocytoma cells contain a factor that enhances formation of amsacrine-induced topoisomerase II-DNA complexes (PDCs) when added to isolated K21 nuclei. The PDC-enhancing activity is reduced in extracts from 2 or 6 h cycloheximide or cordycepin-treated cells, implying that continuous protein synthesis is required to maintain the factor. The factor is heat-labile, proteinase-sensitive and has other properties that distinguish it from the two known classes of topoisomerases. The data suggest that the factor is a labile protein with a molecular weight in excess of 50,000. This appears to be the first direct evidence of a protein factor that modulates drug-induced topoisomerase II action.

Double in situ hybridization in combination with digital image analysis: a new approach to study interphase chromosome topography

Double in situ hybridization with mercurated and biotinylated chromosome specific DNA probes in combination with digital image analysis provides a new approach to compare the distribution of homologous and nonhomologous chromosome targets within individual interphase nuclei. Here we have used two DNA probes representing tandemly repeated sequences specific for the constitutive heterochromatin of the human chromosomes 1 and 15, respectively, and studied the relative arrangements of these chromosome targets in interphase nuclei of human lymphocytes, amniotic fluid cells, and fibroblasts, cultivated in vitro. We have developed a 2D-image analysis approach which allows the rapid evaluation of large numbers of interphase nuclei. Models to test for a random versus nonrandom distribution of chromosome segments are discussed taking into account the three-dimensional origin of the evaluated 2D-distribution. In all three human diploid cell types the measurements of target-target and target-center distances in the 2D-nuclear image revealed that the labeled segments of the two chromosomes 15 were distributed both significantly closer to each other and closer to the center of the nuclear image than the labeled chromosome 1 segments. This result can be explained by the association of nucleolus organizer regions on the short arm of chromosome 15 with nucleoli located more centrally in these nuclei and does not provide evidence for a homologous association per se. In contrast, evaluation of the interphase positioning of the two chromosome 1 segments fits the random expectation in amniotic fluid and fibroblast cells, while in experiments using lymphocytes a slight excess of larger distances between these homologous targets was occasionally observed. 2D-distances between the labeled chromosome 1 and 15 segments showed a large variability in their relative positioning. In conclusion our data do not support the idea of a strict and permanent association of these homologous and nonhomologous targets in the cell types studied so far.

The ultrastructure of upstream and downstream regions of an active Balbiani ring gene

When active, the 37 kb Balbiani ring genes are known to form transcription loops with an almost fully extended chromatin axis. Here we examine the upstream and downstream regions of such transcription loops by electron microscopy. We demonstrate that a loop starts and ends in tightly packed chromatin; the two anchoring sites are clearly separated from each other in space. The upstream, nontranscribed region consists of a thin, extended, apparently flexible and nucleosome-free fiber corresponding to about 0.5 kb DNA. The downstream, nontranscribed region appears as a 200 nm long nucleofilament loosely coiled into a short, thick chromatin fiber and estimated to contain about 3 kb DNA.

Ultrastructure of somatic and meiotic nucleoids

In this review emphasis is placed on the contribution of transmission electron microscopy to the analysis of spread chromosomes and nucleoids. Support is advanced for the DNA loop and rosette organization of meiotic and metaphase chromosomes and nucleoids. Extensive discussion is given to the biochemical treatments used for producing nucleoids and the effect of divalent cations and chelating agents on chromatin compactization (supercoiling). Detailed studies on nucleoids from hepatocytes are presented, with emphasis on the significance of DNA attachment to the internal nuclear matrix and to the nuclear lamina. It is firmly predicted that from the increasing knowledge of the structural organization of eukaryotic chromatin and the genome, a greater understanding of the functional roles of the various intranuclear structures will ultimately follow.

Differential effects of chromium(VI) on constitutive and inducible gene expression in chick embryo liver in vivo and correlation with chromium(VI)-induced DNA damage

The effect of DNA damage induced by the carcinogen chromium(VI) on the function of DNA as a template for transcription of constitutive and inducible genes was examined in chick embryo liver in vivo. Changes in gene expression, determined using solution hybridization and northern blot analyses to measure steady-state mRNA levels and a nuclear run-off assay to measure gene transcription rates, were compared to chromium-DNA binding and to chromium(VI)-induced DNA damage as previously measured by DNA alkaline elution. Chromium(VI) treatment had little or no effect on either the steady-state mRNA levels or the transcription rates of the constitutively expressed genes for albumin, conalbumin (avian transferrin), or beta-actin. In contrast, chromium(VI) treatment had significant but opposite effects on the basal and drug-inducible expression of 5-aminolevulinate synthase and cytochrome PB1 P450. The changes in steady-state expression of these two inducible genes were similar to the changes in transcription rate, indicating that the effects of chromium were principally transcriptional. Chromium(VI) treatment increased the basal expression of both inducible genes four- to fivefold at maximum, and the time course of this effect was similar to the time course for chromium(VI)-induced DNA damage and repair. In contrast, chromium(VI) pretreatment suppressed by 60-70% at maximum the subsequent induction of these genes by glutethimide, a phenobarbital analog, and the time course of this effect also corresponded to that of chromium(VI)-induced DNA damage and repair. The time courses of the changes in expression of these genes were bimodal, with the second peak corresponding closely to that of chromium(VI)-induced DNA cross-links. However, the first peak occurred during a period when no DNA cross-links or strand breaks were detectable by alkaline elution, although significant levels of chromium were bound to DNA. This suggests that chromium(VI), like cisplatin, may initially produce a DNA monoadduct that subsequently leads to DNA cross-link formation and that both types of chromium(VI)-induced lesions have a significant effect on the expression of targeted genes.

The metaphase scaffold is helically folded: sister chromatids have predominantly opposite helical handedness

We have studied the three-dimensional folding of the scaffolding in histone H1-depleted chromosomes by immunofluorescence with an antibody specific for topoisomerase II. Two different types of decondensed chromosomes are observed. The majority of the chromosomes are expanded, and the central fluorescence signal is surrounded by a large halo of chromatin. A much smaller number of chromosomes are more compact in length; they contain a smaller halo of chromatin and their scaffolds are not extended but folded into a genuine, quite regular helical coil. This conclusion is based on a three-dimensional structural analysis by optical sectioning. The number of helical coils is related to chromosome length. Surprisingly, sister chromatids have predominantly opposite helical handedness; that is, they are related by mirror symmetry.

Location and methylation pattern of a nuclear matrix associated region in the human pro alpha 2(I) collagen gene

Using both a 25 mM Lithium di-iodosalicylic acid (LIS) and a 2M NaCl extraction procedure to extract nuclear matrices from white cells we have identified a 0.9 kb nuclear matrix associated region (MAR) in the human pro alpha 2(I) collagen gene. The MAR is located towards the 3' coding end of the gene, it is completely associated with the matrix in transcriptionally inactive white cells but is incompletely associated with the matrix in transcriptionally active fibroblasts. Furthermore the methylation state of the fibroblast gene in the region coinciding with the MAR showed unique differences when compared to adjacent sites in the fibroblast gene and corresponding sites of the white cell gene.

Compositional patterns in vertebrate genomes: conservation and change in evolution

The evolution of vertebrate genomes can be investigated by analyzing their regional compositional patterns, namely the compositional distributions of large DNA fragments (in the 30-100-kb size range), of coding sequences, and of their different codon positions. This approach has shown the existence of two evolutionary modes. In the conservative mode, compositional patterns are maintained over long times (many million years), in spite of the accumulation of enormous numbers of base substitutions. In the transitional, or shifting, mode, compositional patterns change into new ones over much shorter times. The conservation of compositional patterns, which has been investigated in mammalian genomes, appears to be due in part to some measure of compositional conservation in the base substitution process, and in part to negative selection acting at regional (isochore) levels in the genome and eliminating deviations from a narrow range of values, presumably corresponding to optimal functional properties. On the other hand, shifts of compositional patterns, such as those that occurred between cold-blooded and warm-blooded vertebrates, appear to be due essentially to both negative and positive selection again operating at the isochore level, largely under the influence of changes in environmental conditions, and possibly taking advantage of mutational biases in the replication/repair enzymes and/or in the enzyme make-up of nucleotide precursor pools. Other events (like translocations and changes in chromosomal structure) also play a role in the transitional mode of genome evolution. The present findings (1) indicate that isochores, which correspond to the DNA segments of individual or contiguous chromatin domains, represent selection units in the vertebrate genome; and (2) shed new light on the selectionist-neutralist controversy.

Chromosomal ARS and CEN elements bind specifically to the yeast nuclear scaffold

We describe here for the first time the isolation of a yeast nuclear scaffold that maintains specific interactions with yeast genomic DNA sequences. The scaffold-DNA interaction is reversible and saturable, and some binding sites are conserved between yeast and Drosophila KC cells. Second, we find that the specific sequences bound to the yeast nuclear scaffold are the putative origins of replication (ARS elements) and a chromosomal centromere, CENIII. The scaffold association has been closely mapped at the ARS1 locus, and appears to include the 11 bp ARS consensus, but not the ABF-1 binding site. Competition studies show that ARS1 does not compete for CENIII binding, allowing us to distinguish two classes of scaffold attachment sites by functional and structural criteria.

Precise determination of the molecular limits of a polytene chromosome band: regulatory sequences for the Notch gene are in the interband

We have aligned the molecular map of the Notch locus to the cytological features of the salivary gland polytene chromosomes of D. melanogaster in order to determine the interphase chromatin structure of this gene. Using high-resolution in situ hybridization and computer-aided optical microscope data collection and image analysis, we have determined that the coding portions and introns of the Notch gene, which is not expressed in this tissue, are all contained within the polytene chromosome band 3C7. The portion of the Notch gene that resides 5' to the start of transcription lies in an open chromatin conformation, the interband between bands 3C6 and 3C7. Our data are most consistent with condensation of the chromosomal DNA into 30 nm fibers in this polytene band.

Intranuclear distribution of SV40 large T-antigen and transformation-related protein p53 in abortively infected cells

The intranuclear localization of SV40 T-antigen (T-Ag) and the cellular protein p53 was studied in SV40 abortively infected baby mouse kidney cells using two complementary methods of ultrastructural immunocytochemistry in combination with preferential staining of nuclear RNP components and electron microscope autoradiography. Both proteins were revealed in association with peri- and interchromatin RNP fibrils containing the newly synthesized hnRNA. In addition, T-Ag and p53 remained bound, at least in part, to the residual internal nuclear matrix following nuclease and salt extractions of infected cells. The localization of T-Ag was different in SV40 lytically infected monkey kidney cells since, in addition to hnRNP fibrils, the viral protein was also associated with cellular chromatin. However, when lytic infection was performed in conditions of blocked viral DNA replication, T-Ag was no longer associated with the cellular chromatin but remained bound to the hnRNP fibrils. We conclude that the transforming and lytic functions of T-Ag can be distinguished by different subnuclear distributions. The significance of the association of T-Ag and p53 with hnRNP fibrils and the internal nuclear matrix is discussed in relation to the role of these structures in the control of cellular mRNA biogenesis.

Chromatin domain surrounding the human interferon-beta gene as defined by scaffold-attached regions

Regions attached to the nuclear scaffold have been traced after transfecting a 36-kilobase (kb) piece of DNA, surrounding the human interferon-beta gene, into mouse L-cells. An extended attached region starts 1.7 kb upstream from the gene and a moderate binding site immediately downstream. These findings could be confirmed by reconstitution experiments in vitro which predict another scaffold-attached region (SAR) starting 12 kb downstream from the gene. Since no other transcripts originate from DNA between the major SARs, these elements could be involved in interferon gene regulation.

Chromosomal loop/nuclear matrix organization of transcriptionally active and inactive RNA polymerases in HeLa nuclei

The relative distribution of transcriptionally active and inactive RNA polymerases I and II between the nuclear matrix/scaffold and chromosomal loops of HeLa cells was determined. Total RNA polymerase was assessed by immunoblotting and transcribing RNA polymerase by a photoaffinity labeling technique in isolated nuclei. Nuclear matrix/scaffold was isolated by three methods using high-salt, intermediate-salt or low-salt extraction. The distribution of RNA polymerases I and II were very similar within each of the methods, but considerable differences in distributions were found between the different preparation methods. Either intermediate-salt or high-salt treatment of DNase I-digested nuclei showed significant association of RNA polymerases with the nuclear matrix. However, intermediate-salt followed by high-salt treatment released all transcribing and non-transcribing RNA polymerases. Nuclear scaffolds isolated with lithium diiodosalicylate (low-salt) contained very little of the RNA polymerases. This treatment, however, caused the dissociation of RNA polymerase II transcription complexes. These results show unambiguously that RNA polymerases, both in their active and inactive forms, are not nuclear matrix proteins. The data support models in which the transcriptional machinery moves around DNA loops during transcription.

Interaction of DNA with nuclear scaffolds in vitro

We have previously identified a number of specific DNA fragments called SARs (scaffold-associated regions) that are associated with the nuclear scaffold and define the basis of DNA loops. We demonstrate that cloned DNA fragments containing SAR sequences bind to nuclear scaffolds in vitro with the same specificity as have genomic SAR fragments. This specific interaction is observed with the biochemically complex type I scaffolds. These scaffolds are composed of the nuclear lamina proteins and a set of other proteins that forms the internal network of these structures. So-called type II scaffolds, which are composed primarily of the lamina proteins and lack the proteins of the internal network, do not bind the SAR fragments at a detectable level. Competition experiments show that different SARs share common structural elements and can bind to the same sites on the nuclear scaffold, although with different affinities. Moreover, the SAR binding sites appear to be evolutionarily conserved, as all the Drosophila SARs also bind with identical specificity to nuclear scaffolds derived from rat liver nuclei. These Sar interaction studies were carried out with lithium 3,5-diiodosalicylate-extracted nuclei. Interestingly, scaffolds prepared by high-salt extraction also bind the genomic and exogenously added SAR fragments specifically. However, the endogenous transcribed sequences, as opposed to the same fragments added as purified DNA, associate randomly with these scaffolds.

Disparate effects of 5-bromodeoxyuridine on sister-chromatid exchanges and chromosomal aberrations in Bloom syndrome fibroblasts

The existence of a high frequency of spontaneous sister-chromatid exchanges (SCEs) in Bloom syndrome (BS) has thus far been supported by data on a small number of BS cell lines. To examine the cause of baseline SCEs more broadly, the frequencies of SCEs, as well as chromosomal aberrations (CAs) in 4 additional BS fibroblast strains were compared, under different assay and cell culture conditions, with those of normal cells in the range of approximately 0.9-90% 5-bromodeoxyuridine (BrdUrd) substitution into template DNA. SCEs at low levels of BrdUrd substitution were detected by an extremely sensitive immunofluorescent technique. From approximately 0.9% to 4.5% BrdUrd substitution, the SCE frequency in BS cells remained constant, at a level (40/cell) 8 times higher than that of normal cells. As BrdUrd substitution increased further, the SCE frequency in BS cells increased almost linearly, reaching 70-100 per cell at approximately 90% substitution, while the SCE increment in control fibroblasts was less than 5 per cell. Analysis of SCEs in 3 successive replication cycles similarly revealed that the SCE increment in BS cells depended on BrdUrd only at a high BrdUrd substitution level. In contrast to data on SCEs, CA induction by incorporated BrdUrd in BS cells was only slightly higher than that in normal cells. Thus, BS cells are extremely sensitive to BrdUrd for SCE induction, but much less so for CA induction.

Transcription elements and factors of RNA polymerase B promoters of higher eukaryotes

The promoter for eukaryotic genes transcribed by RNA polymerase B can be divided into the TATA box (located at -30) and startsite (+1), the upstream element (situated between -40 and about -110), and the enhancer (no fixed position relative to the startsite). Trans-acting factors, which bind to these elements, have been identified and at least partially purified. The role of the TATA box is to bind factors which focus the transcription machinery to initiate at the startsite. The upstream element and the enhancer somehow modulate this interaction, possibly through direct protein-protein interactions. Another class of transcription factors, typified by viral proteins such as the adenovirus EIA products, do not appear to require binding to a particular DNA sequence to regulate transcription. The latest findings in these various subjects are discussed.

Limited transcription of rat elastase I transgene repeats in transgenic mice

The rat elastase I (EI) regulatory region is an enhancer that directs efficient pancreas-specific transcription of linked genes integrated in the chromosomes of transgenic mice. However, with increasing numbers of tandemly repeated EI transgenes, the transcription rate per gene decreased. This decrease was not due to a titration of essential transcription factors, because transgenic mice with as many as 250 copies of the rat EI enhancer continued transcription of the endogenous mouse EI gene at its normal rate. Furthermore, when transgenic mice bearing 250 EI genes and mice bearing 7 copies of an EI enhancer-directed human growth hormone (hGh) gene were mated to produce mice with two unlinked arrays of EI enhancer-driven transgenes, each array was transcribed at the same rate as in mice bearing each array separately. Long tandem arrays of transgenes may inhibit efficient transcription despite the presence of ample amounts of essential transcription factors. Although the transcription rate of the mouse EI gene was not affected by the presence of large numbers of transgenes, the amounts of mouse elastase I and elastase II mRNAs were decreased in the presence of high levels of transgene mRNA, indicating an adjustment of the cell mRNA population.

The diffuse neuroendocrine system: a molecular perspective

This review seeks to illustrate that the concept of a 'diffuse neuroendocrine system' arises from a series of ontogenetic, phylogenetic and functional overlaps borne out at the molecular level, which engender an apparent global unit. Extrapolation from the overlaps should lead to the discovery of new facets in the relationships between molecular components of the DNES, and this approach will lead to a spectrum of markers and probes with a variety of clinical applications. Initial approaches progressed from cellular function toward molecular anatomy, but converse questions starting from anatomical markers are now arising.

A partial deletion of the muscular dystrophy gene transmitted twice by an unaffected male

A gene of unknown function located in band Xp21 on the short arm of the human X chromosome gives rise to X-linked recessive muscular dystrophy, of either Duchenne or Becker type, when mutated. The gene encodes a large muscle-specific transcript of about 14 kilobases (kb) and its genomic size extends over more than 1,800 kb. The high mutation rate (about 10(-4) per generation) is likely to result from the large target size. Submicroscopic deletions, detectable with one or more of the dozen cloned DNA probes available for regions within the gene, constitute a significant proportion of the mutations. Because no such deletions have been found in normal individuals, it is assumed that intragenic deletions are the molecular basis of the mutations. The origin of deletions can be traced in families. With sufficient data collected, it will soon be possible to answer questions about the relative frequencies of mutations in male and female gametogenesis and about the timing of mutational events in mitotic or meiotic stages of germ cell development. We have studied a four generation family containing males who have Duchenne muscular dystrophy due to deletion of the sequence recognized by intragenic probe J-Bir. The deletion was present in two of five daughters of a woman who herself did not have the deletion. Haplotype analysis on 15 members of this family using nine informative restriction fragment length polymorphism (RFLP) markers indicated that the J-Bir deletion chromosome was transmitted from the unaffected father.