Showing papers on "Chromosome 21 published in 1983"

The Chromosomal Basis of Human Neoplasia

Abstract: High-resolution banding techniques for the study of human chromosomes have revealed that the malignant cells of most tumors analyzed have characteristic chromosomal defects. Translocations of the same chromosome segments with precise breakpoints occur in many leukemias and lymphomas, and a specific chromosome band is deleted in several carcinomas. Trisomy, or the occurrence of a particular chromosome in triplicate, is the only abnormality observed in a few neoplasias. It is proposed that chromosomal rearrangements play a central role in human neoplasia and may exert their effects through related genomic mechanisms. Thus, a translocation could serve to place an oncogene next to an activating DNA sequence, a deletion to eliminate an oncogene repressor, and trisomy to carry extra gene dosage.

Isolation and characterization of a major tandem repeat family from the human X chromosome

Abstract: We report the identification and characterization of a family of repeated restriction fragments whose molecular organization is apparently specific to the human X chromosome. This fragment, identified as an ethidium bromide-staining 2.0 kilobase (kb) band in BamHI-digested DNA from a Chinese hamster-human somatic cell hybrid containing a human X chromosome, has been cloned into pBR325 and characterized. The 2.0 kb repeated family has been assigned to the Xp11 leads to Xq12 region on the X by Southern blot analysis of somatic cell hybrids and is predominantly arranged in tandem clusters of up to seven 2.0 kb monomers. Homologous DNA sequences, not organized as 2.0 kb BamHI fragments, are found elsewhere on the X chromosome and on at least some autosomes, but are not found on the Y chromosome. From a dosing experiment using various amounts of the cloned repeat, we estimate that there are 5,000-7,500 copies of the 2.0 kb BamHI repeat per haploid genome. Since the vast majority, if not all, of these are confined to the X chromosome, this repeated DNA family must account for 5-10% of all X chromosome DNA and must constitute the major sequence component of the pericentromeric region of the X.

Transcriptionally active c-myc oncogene is contained within NIARD, a DNA sequence associated with chromosome translocations in B-cell neoplasia.

Abstract: NIARD (non-immunoglobulin-associated rearranging DNA) is located on mouse chromosome 15 at the break point of a commonly observed translocation event involving chromosomes 15 and 12 in murine plasmacytomas. The human cellular analogue of the v-myc oncogene of avian myelocytomatosis virus, strain MC-29, is known to reside on the distal end of human chromosome 8 and has been observed to translocate to chromosome 14 in Burkitt lymphomas. Using a cDNA clone specific for the transcript of the human c-myc gene (H c-myc), we show that the mouse c-myc (M c-myc) gene is contained within NIARD. NIARD-associated chromosome translocations occurred 1.3-2 kilobases (kb) 5′ of the mouse c-myc gene where NIARD recombines with the switch region of the Cα immunoglobulin gene in various murine plasmacytomas. The mouse c-myc encoding region within NIARD spanned <2.4 kb of DNA and expressed a low level of a 2.3-kb polyadenylylated RNA in BALB/c spleen. Increased (10- to 20-fold) levels of rearranged mouse c-myc transcripts (i.e., ≈1.8-2.1 kb) were observed in plasmacytomas that have NIARD-associated chromosome translocations. Human c-myc and NIARD probes detected DNA rearrangements of human c-myc in four of seven Burkitt lymphomas. DNA sequences adjacent to the human c-myc gene recombined with the Cμ immunoglobulin gene locus on chromosome 14 in several Burkitt lymphomas. The activation of the c-myc oncogene by chromosome translocation implicates its involvement in B-cell oncogenesis.

Nucleotide sequence and expression of human chromosome 21-encoded superoxide dismutase mRNA

Abstract: Cytoplasmic superoxide dismutase (SOD-1; EC 1.15.1.1) is encoded by human chromosome 21. The SOD-1 gene locus is located at chromosomal region 21q22, which is involved in Down syndrome. cDNA clones containing sequences of human SOD-1 were previously isolated. In the present study the nucleotide sequence of one clone, designated pS61-10, was determined. It contains 459 nucleotides representing the entire coding region and 95 nucleotides of the 3' untranslated region. In human cells two poly(A)-containing SOD-1 RNAs of 0.7 and 0.5 kilobases were detected. These two species are also present in monkey cells, whereas mouse cells contain only a 0.5-kilobase RNA. In a mouse/human hybrid line that contains chromosome 21 as the only human chromosome, the two human SOD-1 RNAs were detected, indicating that both are encoded by this chromosome. These RNAs were found in poly(A)-containing polysomal RNA and were translated in vitro to SOD-1 polypeptide; they are therefore functional mRNAs. In normal human fibroblasts 0.002-0.006% of the poly(A)-containing RNA was SOD-1 RNA. The level in monosomic 21 cells was 70% of this value and the level in fibroblasts from Down syndrome patients was about 2 times higher than normal.

Genetic evidence that a Y-linked gene in man is homologous to a gene on the X chromosome.

Abstract: The mammalian sex chromosomes are thought to be related to each other by sharing a common origin. That is, the X and Y chromosomes originally evolved from a pair of chromosomes that only differed at the locus determining sexual differentiation1,2. For example, this evolutionary relationship is reflected during meiosis3 in chromosomal pairing between the tip of the human X chromosome short arm and the Y chromosome which presumably implies sequence homology4. However, compelling genetic evidence for functional homology between the mammalian X and Y chromosome is lacking. We describe here the localization of a gene to the tip of the short arm of the human X chromosome and evidence for a related gene on the Y chromosome.

Cytological and genetic analysis of the Y chromosome of Drosophila melanogaster. I: Organization of the fertility factors

Abstract: By applying quinacrine-, Hoechst- and N-banding techniques to neuroblast prometaphase chromosomes the Y chromosome of Drosophila melanogaster can be differentiated into 25 regions defined by the degree of fluorescence, the stainability after N-banding and the presence of constrictions. Thus these banding techniques provide an array of cytological landmarks along the Y chromosome that makes it comparable to a polytene chromosome for cytogenetic analysis. — 206 Y-autosome translocations (half of them carrying Y-linked sterile mutations) and 24 sterile y + Y chromosomes were carefully characterized by these banding techniques and used in extensive complementation analyses. The results of these experiments showed that: (1) there are four linearly ordered fertility factors in Y L and two fertility factors in Y S . (2) These fertility factors map to characteristic regions of the Y chromosome, specifically stained with the N-banding procedure. (3) The most extensively analyzed fertility factors are defined by a series of cytologically non-overlapping and genetically noncomplementing breaks and deficiencies distributed over large chromosome regions. For example, the breakpoints which inactivate the kl-5 and ks-1 loci are scattered along regions that contain about 3,000 kilobases (kb) DNA. Since these enormous regions formally define single genetic functions, the fertility genes of the Y chromosome have an as yet unappreciated physical dimension, being larger than euchromatic genes by two orders of magnitude.

Isolation of amplified DNA sequences from IMR-32 human neuroblastoma cells: facilitation by fluorescence-activated flow sorting of metaphase chromosomes

Abstract: Human neuroblastoma IMR-32 cells have large homogeneously staining regions (HSRs), primarily in the short arms of chromosome 1. We have constructed a recombinant phage library that is enriched for DNA present in the HSR of this chromosome by using fluorescence-activated flow sorting for initial chromosome purification. Eleven distinct cloned DNA segments were identified that showed significantly greater hybridization to IMR-32 genomic DNA, detected by Southern blotting, than to normal human genomic DNA. These sequences have also been localized to the HSR of chromosome 1 by in situ hybridization. Based on an approximate 50-fold sequence amplification for each cloned segment and a total HSR size of 150,000 kilobases, the amplified unit in the HSR is estimated to be 3,000 kilobases. Sequences homologous to all cloned HSR DNA segments were mapped to human chromosome 2 by using human-mouse hybrid cells. Further work using in situ hybridization demonstrated that cloned HSR segments were localized in the short arm of chromosome 2 in both normal and IMR-32 cells. Thus, the amplification of these sequences in IMR-32 cells may have involved transposition from chromosome 2 to chromosome I.

Down's syndrome in the male. Reproductive pathology and meiotic studies

Abstract: Studies on testicular histology and meiosis were carried out by the use of light and electron microscopy in an 18-year-old Down's syndrome male in an attempt to follow the fate of the extra chromosome 21 and to evaluate the effects of this condition on spermatogenesis and the reproductive functions. The histological changes in the testes corresponded to spermatogenic arrest. Electron microscopic whole-mount spreadings of meiotic cells in the pachytene stage showed that in most nuclei an extra chromosome 21 was not detectable. Only in a small number of nuclei, univalents or trivalents with segmental pairing structures of an extra chromosome could be discovered. In contrast, the great majority of (C-banded) diakinesis figures showed the presence of a supernumerary G (no. 21) chromosome. The absence of a traceable extra chromosome 21 in most pachytene cells is explained by the assumption that it is intimately connected with and hidden in the sex vesicle, whose complex structure does not allow the identification of single elements. Strong support for this assumption is seen (a) in the general tendency of narrow spatial association of unpaired segments with the XY complex and (b) in close structural similarities occurring between univalents or nonsynapsed segments of trivalents and the nonpaired segments of the sex chromosomes. It is suggested that the association or connection of an extra chromosome with the XY complex during pachytene interferes with the phenomenon of X inactivation. In animal systems such abnormal interference is related with spermatogenic breakdown and, in a general way, with male hybrid type sterility. So far, the range of sterility vs. fertility in cases of male Down's syndrome is not yet fully clear, but it appears that impairment of fertility, and sterility are most frequent. If so, it is proposed that the effect of the trisomy 21 condition on spermatogenesis (and fertility) is a consequence of the behavior of the extra chromosome in the meiotic prophase.

Nonrandom Chromosome Changes in Malignant Melanoma

Abstract: Chromosome aberrations were analyzed in 4 cases of malignant melanoma (MM) after disaggregation of the tumors with collagenase and short-term culture. In all cell cultures, the MM cells displayed a typical triangular spindle form. The chromosome number was near-diploid in one case and near-triploid in three cases. A total of 27 abnormal chromosomes were identified with the Giemsa banding technique. By far, the most common types of abnormalities were translocations, followed by deletions and isochromosomes. Chromosomes 1, 6, and 7 were found to be most frequently involved in structural aberrations. Markers originating from chromosomes 1 and 6 were found in all four cases, and abnormalities of chromosome 7 were found in three. Each marker chromosome was unique for a given case; no common markers for two or more cases were found. Based on the present results and an analysis of reports on the chromosomal constitution of MM cells in the literature, we suggest that abnormalities involving chromosomes 6 and 7 may be a characteristic feature of MM. Aberrations of chromosome 1, although common in MM, may be part of a general cytogenetic feature in human neoplasia.

Single-copy DNA sequences specific for the human Y chromosome

Abstract: Detailed studies of the role of the mammalian Y chromosome in primary sex determination are limited by the lack of available specific markers and by the fragmentary knowledge of its molecular organization. Y-derived unique DNA sequences could provide powerful analytical tools to probe directly the structure of the Y chromosome and provide a means of searching for specific expressed sequences. We report here the construction of a partial cosmid library of the human Y chromosome. From independent clones we have isolated 30 unrelated DNA probes that are free of highly repetitive sequences, and have examined their reaction pattern on male and female genomic blots. Of the 30 probes tested, six were specific for the Y chromosome. In addition, four probes gave a male-female differential hybridization pattern and the remaining 20, although Y-derived, reacted similarly with both male and female DNA.

Chromosomal localization of the human c-fms oncogene

Abstract: A molecular probe was prepared with specificity for the human cellular homologue of transforming sequences represented within the McDonough strain of feline sarcoma virus (v-fms). By analysis of a series of mouse-human somatic cell hybrids containing variable complements of human chromosomes it was possible to assign this human oncogene, designated c-fms, to chromosome 5. Regional localization of c-fms to band q34 on chromosome 5 was accomplished by analysis of Chinese hamster-human cell hybrids containing as their only human components, terminal and interstitial deleted forms of chromosome 5. The localization of c-fms to chromosome 5 (q34) is of interest in view of reports of a specific, apparently interstitial, deletion involving approximately two thirds of the q arm of chromosome 5 in acute myelogenous leukemia cells.

Rat c-myc oncogene is located on chromosome 7 and rearranges in immunocytomas with t(6:7) chromosomal translocation

Abstract: Two B-cell-derived tumours, human Burkitt's lymphoma (BL) and murine plasmacytoma (MPC), are regularly associated with a distinctive form of chromosomal translocation (for reviews see refs 1, 2) In BL, the distal portion of chromosome 8 breaks off and is transposed, in most cases, to chromosome 14, known to carry the immunoglobulin heavy-chain locus In about 5% of the cases the same distal part of the chromosome 8 has moved to either chromosome 2 or 22, to the neighbourhood of the kappa or the lambda locus, respectively In MPC the distal region of chromosome 15 is transposed to the chromosome 12, known to carry the immunoglobulin heavy-chain locus, or enters into reciprocal exchange with the kappa locus-carrying chromosome 6 (ref 7) Several laboratories have located c-myc, the cellular homologue of the MC29 retroviral oncogene v-myc, to human chromosome 8 (refs 8-10) and mouse chromosome 15 (refs 11-13) It has also been shown that the BL- and MPC-associated translocations remove the c-myc gene from its original site and transpose it into or close to one of the immunoglobulin gene clusters In view of the above findings we also looked for possible involvement of the c-myc gene in a B-cell-derived tumour of a third species, the rat Rat immunocytomas of spontaneous origin carry a reciprocal translocation between chromosomes 6 and 7 (ref 17) Here we have localized the c-myc locus to chromosome 7 of the rat Moreover, we have found that the c-myc gene was rearranged in four of five immunocytomas carrying the characteristic chromosomal translocation

Amplified C lambda and c-abl genes are on the same marker chromosome in K562 leukemia cells

Abstract: The human leukemia cell line K562, derived from a patient with Philadelphia chromosome-positive chronic myelogenous leukemia, contains amplified c-abl oncogenes and unrearranged C lambda genes. Using in situ hybridization techniques, we have determined that the amplified c-abl and C lambda DNA sequences of K562 cells are both located on the same abnormal acrocentric marker chromosome, which may represent an altered Philadelphia chromosome.

The origin of wheat chromosomes 4A and 4B and their genome reallocation

Abstract: Triticum aestivum chromosome "4A" is, like the B genome chromosomes, extensively heterochromatic while the remaining six A genome chromosomes are not. In the presence of the Ph gene it does not pai...

Adult T-cell leukemia. Chromosome analysis of 15 cases.

Abstract: Chromosome studies was conducted on 15 patients with adult T-cell leukemia. Cells with chromosomal abnormality were seen in 14 of the 15 patients. The modal chromosome number was near diploid range in all the patients. The most common abnormality was 14q+ marker chromosome and partial deletion of the long arm of chromosome 6, i.e., 6q-, which were seen in eight and seven cases, respectively. Donor chromosomes involved in the 14q+ marker chromosome varies, i.e., Yq, #5p, #5q, #9q, #10q or #12q, except for two patients whose donor chromosome origins were unable to determine. The break point in 14q+ marker chromosome was band at q32. The 6q- chromosome was due to a deletion in one patient and interstitial deletion in six patients. A 14q- chromosome having break point at q24 was found in one patient and duplication of Yq chromosome in two patients. In addition, four patients showed a 5q- chromosome or a 9q- chromosome which was due to a translocation or deletion. The significance of these chromosome abnormalities was discussed.

Deficiency, transposition, and duplication of one 15q region may be alternatively associated with Prader-Willi (or a similar) syndrome. Analysis of seven cases after varying ascertainment

Abstract: Seven patients are described who have some or all of the symptoms of Prader-Willi syndrome. They were ascertained by varying criteria starting either from the clinical picture or from the identification of a chromosome abnormality involving the proximal portion of the long arm of chromosome 15. The chromosome abnormalities consisted of two balanced translocations (15;18 and 8;15), three unbalanced ones (15;18, 15;19, and 9;15), and one interstitial deletion of bands 15q11 and q12. The seventh case had an unidentified extra chromosome. These data and a review of the literature led to the conclusion that deficiency, transposition, and even duplication of the region(s) 15q11-q13 may all result in a syndrome which is identifiable with or similar to the Prader-Willi syndrome.

Genetic analysis of the 15;17 chromosome translocation associated with acute promyelocytic leukemia.

Abstract: Somatic cell hybrids have been constructed between a thymidine kinase-deficient mouse cell line and blood leukocytes from a patient with acute promyelocytic leukemia showing the 15q+;17q- chromosome translocation frequently associated with this disease. One hybrid contains the 15q+ translocation chromosome and very little other human material. We have shown that the c-fes oncogene, which has been mapped to chromosome 15, is not present in this hybrid and, therefore, probably is translocated to the 17q- chromosome. Analysis of the genetic markers present in this hybrid has enabled a more precise localization of the translocation breakpoints on chromosomes 15 and 17. Our experiments also have enabled an ordering and more precise mapping of several genetic markers on chromosomes 15 and 17.

Down's syndrome and acute megakaryoblastic leukaemia. Case report and review of the literature.

Abstract: A case is reported of a child with Down's syndrome who developed acute megakaryoblastic leukaemia, and in whom the evolution of the disease was accompanied by increasing cytogenetic abnormalities. A review of the literature suggests that the presence of an abnormal chromosome 21 may predispose to the development of this type of leukaemia.

Triple chromosome synapsis in oocytes from a human foetus with trisomy 21

Abstract: Summary Oocytes from a human foetus with trisomy 21 were spread using detergent and examined by light and electron microscopy. The three chromosomes 21 occurred as bivalent and univalent or trivalent configurations. In the trivalents the lateral elements of the synaptonemal complex were associated in threes, either completely along the length of the trivalent, or partially, forming a variety of forked structures. This triple association demonstrates that, contrary to the classical view of chromosome pairing, three homologous chromosomes can be held in register at the same site.

Direct hybridization of sorted human chromosomes: localization of the Y chromosome on the flow karyotype

Abstract: A method is described for directly hybridizing a small number of sorted chromosomes with specific DNA probes. The chromosomes are analyzed by flow cytometry and sorted by deflecting the droplets containing the desired chromosomes onto a nitrocellulose filter. By using probes specific for the human Y chromosome, it has been possible to unambiguously identify the peak corresponding to the Y chromosome in the flow karyotypes of a variety of male cell lines. The position of this peak was found to vary significantly from individual to individual, correlating with the heterochromatin chromosomal polymorphism of the human Y chromosome. The sensitivity of the hybridization was such that, with a probe for a male-specific repetitive sequence, only 2,500 sorted chromosomes were enough to obtain a clear, positive signal; 10,000 were needed with a probe specific for a weakly repeated (maximum, 3-fold) sequence of Y chromosome. With this new method, chromosome sorting may be a rapid and efficient way to assign DNA sequences to chromosomes.

Identification and isolation of transcribed human X chromosome DNA sequences

Abstract: A human X chromosome specific phage library has been used as a source of X-specific genomic DNA clones which hybridize with cellular RNA. Random cDNA clones were mapped for X chromosome sequence localization and 8 were identified as hybridizing to X chromosome Hind III fragments. All eight also hybridized with autosomal Hind III fragments. The X chromosome genomic sequences corresponding to two of these cDNA clones were isolated from a phage library constructed with the Hind III endonuclease digest products of X enriched DNA. One genomic DNA segment, localized to the short area of the X, shared sequence homology with at least one region of the human Y chromosome. The methodology developed represents a rapid means to obtain a specific genomic DNA clone from a single chromosome when multiple different genomic loci homologous to an expressed DNA sequence exist.

Localization of the restriction fragment length polymorphism D14S1 (pAW-101) to chromosome 14q32.1 leads to 32.2 by in situ hybridization.

Abstract: The restriction fragment length polymorphism D14S1 is delineated by the cloned, single-copy DNA fragment pAW-101. This cloned fragment can therefore serve as a useful marker for gene linkage studies, and the exact location on the gene map is of great interest. pAW-101 was 3H-labeled and hybridized in situ to normal, prometaphase chromosome preparations. Analysis of the grain distribution shows this fragment to be localized to the long arm of chromosome 14 at band q32. Using lymphoid cell lines with 8;14 reciprocal translocations (q24.1;q32.3) from patients with Burkitt lymphoma, we found that the DNA fragment hybridizes to the rearranged chromosome 14 proximal to the breakpoint. These results localize D14S1 to the region 14q32.1 leads to 32.2 This is consistent with localization of this fragment utilizing somatic cell hybrids and family studies.

Homologue destabilization by a putative transposable element in Drosophila melanogaster

Abstract: We postulate the presence of a transposable element, designated the L factor, to explain the properties of an unstable X chromosome and its derivatives. These chromosomes generate recessive lethal mutations at high rates, as does a stable X chromosome that has been associated with them for only one generation. The stable X chromosome does not become highly mutable in the absence of the unstable X chromosome, even when autosomes from the unstable stock are present. These facts suggest that the L factor is confined to the X chromosome and that it transposes to other X chromosomes paired with it. We propose the term "homologue destabilization" to denote the change in the stable chromosome brought about by this transposition. The lethal mutations caused by the L factor occur preferentially in the region around the cut wing locus (ct) and are sometimes associated with recognizable chromosome aberrations. The breakpoints of these aberrations are most often in the vicinity of ct, implying that the L factor is located near ct on the unstable chromosome, but it may reside at other sites as well. Alternately, the ct region may simply be a preferred target for the insertion of this transposable element.

Ring chromosome 6: variability in phenotypic expression.

Abstract: We present four children with a ring chromosome 6. Clinically, these cases are quite variable. A review of ten previously reported cases also suggests difficulty of phenotype-karyotype correlation in patients with a ring 6.

Human telomeric 6; 19 translocation chromosome with a tendency to break at the fusion point.

Abstract: The behavior of a translocation chromosome t(6; 19) in the lymphocytes of a mentally retarded woman with other anomalies has been analyzed. The two chromosomes were attached at the telomeres of their short arms without any apparent deletion. The centromere of chromosome 19 was marked by a primary constriction and the site of the centromere of chromosome 6 by a C-band, but no constriction. The translocation chromosome showed two primary constrictions once in 8,800 metaphases, probably resulting from mitotic crossing-over. One or both chromatids of the translocation chromosome were broken at the attachment point with a frequency of 1/733 cells. In addition, the chromosome was often bent at this point and the translocated chromosomes 19 and 6 showed a differential spiralization. In this characteristic as well as the weakness of the fusion point, this chromosome differed from other translocations; the fusion obviously was not as firm as in translocations in general. The broken-off chromosome 6 did not regain a primary constriction, but had the appearance of a large acentric fragment. The segregation of the translocation chromosome and the fragment gave rise to a complicated mosaicism with various levels of ploidy for the fragment lacking a functional centromere. The data are in quantitative agreement with the equilibrium expectations under the assumption that each fragment goes to either pole at random in mitosis and that cells divide at the same rate regardless of ploidy. The high rate of nondisjunction of the fragment showed that the inactivated centromere of the translocation chromosome did not regain its activity when chromosome 19 with the functional centromere became separated from it. — The fragility and the behavior of the translocation chromosome and the production of telomeric associations are briefly discussed.

Human and mouse cellular myc protooncogenes reside on chromosomes involved in numerical and structural aberrations in cancer.

Abstract: A molecular clone of viral myc (v-myc), the oncogene of avian myelocytomatosis virus, MC29, detected homologous human, mouse, and Chinese hamster cellular myc (c-myc) sequences by Southern filter hybridization. A v-myc probe, containing sequences from the 3' domain of the gene, hybridized to single human HindIII and mouse EcoRI genomic DNA fragments of the cellular myc genes whose segregation could be followed in interspecies somatic cell hybrids. Human c-myc segregated concordantly with the enzyme marker glutathione reductase and with a karyotypically normal chromosome 8. A rearrangement of human c-myc was observed in Burkitt's lymphoma cells possessing the t(8;14) translocation. These results suggest that human c-myc is located close to the breakpoint on chromosome 8 (q24) involved in the t(8;14) translocation. The mouse c-myc gene segregated concordantly with chromosome 15 in mouse-Chinese hamster cell hybrids. These gene assignments are noteworthy, as structural and numerical abnormalities of human chromosome 8 and mouse chromosome 15 are associated frequently with B-cell neoplasms.

Ring chromosome 21 in phenotypically apparently normal persons: Report of two families from Switzerland and Italy

Abstract: If a ring 21, originating from breaks close to the telomere of 21q and anywhere in 21p, replaces a normal 21, it may be associated with an apparently normal phenotype. An apparently normal mother and son were ascertained by a prenatal chromosome study. A second mother, with a ring 21 but without gross anomalies, is short of stature, has epilepsy and has a low normal intelligence. He daughter is a mosaic: 46,XX/47,XX,+r(21) and has the Down's syndrome. None of these four persons was found to have mitoses with more than one ring 21 or with rings of double size.

Analysis of Y-Linked Mutations to Male Sterility in DROSOPHILA MELANOGASTER.

Abstract: The frequencies of newly induced male-sterilizing lesions on both the X and Y chromosomes of Drosophila melonogaster were determined after either 4000 r of y-irradiation or adult feeding of ethyl methanesulfonate. The Y chromosome is approximately twice as sensitive as the X chromosome to newly induced male-sterilizing lesions after y-irradiation, but slightly less sensitive after ethyl methanesulfonate treatment. A large proportion of the radiation-induced lesions are associated with Y-autosome or X-autosome translocations, with the Y chromosome recovered in translocations far in excess of the frequency expected from metaphase lengths. Although translocations between the X and Y chromosomes or between autosomes do not appear to sterilize heterozygous males, interchanges between sex chromosomes and autosomes often sterilize males carrying them in a dominant manner, suggesting that the organization of the genome is critical for normal spermatogenesis. Complementation tests between recessive Y-linked male-sterilizing mutants do not reveal the existence of any additional fertility loci beyond the six previously defined. HE Y chromosome of Drosophila melanogaster accounts for 13% of the T metaphase chromosome length in a normal diploid male (after BRIDGES, from DOBZHANSKY 1929; GOWEN and GAY 1933) but is dispensable in all cells except the germ line of the male; males lacking a Y chromosome are viable but sterile (BRIDGES 1916). In an earlier paper (KENNISON 1981) the organization of the Y chromosome of D. melanogaster into six restricted regions necessary for male fertility separated by large blocks of chromosomal material not necessary for male fertility was described. These fertility regions appear to be associated with the nonfluorescent blocks that are seen after Hoechst 33258 staining. All male-sterilizing X-Y translocations with genetic breakpoints in the same fertility region fail to complement, suggesting that each region contains only one functional unit. The X chromosome, approximately the same metaphase length as the Y chromosome (after BRIDGES, from DOBZHANSKY 1929), is estimated to contain 100-150 genes that can mutate to male sterility (LINDSLEY and LIFSCHYTZ 1972), whereas only six male fertility loci on the Y chromosome have been identified. ' The work reported here was submitted in partial fulfillment of the requirements for the Doctor of Philosophy,