Abstract
Giemsa-11, G-banding and Lateral Asymmetry staining techniques were used to define the substructure of the C-band heterochromatin of human chromosome 9, in a sample of 108 different chromosomes 9, from 54 individuals. In this sample, the juxtacentromeric portion of the C-band region stained positive by the G-banding technique while Giemsa-11 delineated a more distally located block. Examination of the pericentric inversions generally revealed that the entire C-band region is changed with the substructural organization left intact; i.e. the G-band is proximal, the G-11 distal to the centromere. The “partial pericentric inversions” were found to have larger than average amounts of G-band heterochromatin on the short arm. The G-11 staining was in its usual position on the long arm with none on the short arm. Such apparent inversions therefore may not represent true inversions. — Long heterochromatic regions frequently had a segmented appearance when stained with G-11; there was a dark G-band within the pale heterochromatic region when stained with the G-banding technique which corresponded in location to the achromatic gap produced by G-11. This extra G-band may have been derived from the juxtacentromeric G-band by processes analogous to unequal crossing over. — Simple lateral asymmetry was consistently present only in the G-band heterochromatin of those chromosomes 9 containing large blocks of G-band positive material. Examination of the portion of the C-band which would correspond to the G-11 positive material revealed no consistent patterns of asymmetry. Usually both strands were heavily stained and symmetrical but occasionally there were light areas present on one strand suggestive of compound lateral asymmetry.
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References
Angell, R.R., Jacobs, P.A.; Lateral asymmetry in human constitutive heterochromatin. Chromosoma (Berl.) 51, 301–310 (1975)
Angell, R.R., Jacobs, P.A.; Lateral asymmetry in human constitutive heterochromatin: frequency and inheritance. Amer. J. Hum. Genet. 30, 144–152 (1978)
Beauchamp, R.S., Mitchell, A.R., Buckland, R.A., Bostock, C.J.; Specific arrangements of human satellite III DNA sequences in human chromosomes. Chromosoma (Berl.) 71, 153–166 (1979)
Bobrow, M., Madan, K., Pearson, P.L.; Staining of some specific regions of human chromosomes, particularly the secondary constriction of No. 9. Nature (Lond.) New Biol. 238, 122–124 (1972)
Bobrow, M., Madan, K.; A comparison of chimpanzee and human chromosomes using the Giemsa-11 and other chromosome banding techniques. Cytogenet. Cell Genet. 12, 107–116 (1973)
Bühler, E.M., Tsuchimoto, T., Jurik, L.P., Stalder, G.R.; Satellite DNA III and alkaline Giemsa staining. Humangenetik 26, 329–333 (1975)
Buys, C.H.C.M., Ypma, J.M.M., Gouw, W.L.; Complete deficiency of constitutive heterochromatin on a chromosome 9. Hum. Genet. 49, 129–132 (1979)
Buys, C.H.C.M., Gouw, W.L., Blenkers, J.A.M., Dalen, C.H. Van; Heterogeneity of human chromosome 9 constitutive heterochromatin is revealed by sequential Distamycin A/DAPI staining and C-banding. Hum. Genet. 57, 28–30 (1981)
Cooke, H.J., Hindley, J.; Cloning of human satellite III DNA: different components are on different chromosomes. Nucleic Acids Res 6, 3177–3197 (1979)
Craig-Holmes, A.P., Moore, F.B., Shaw, M.W.; Polymorphism of human C-band heterochromatin. I. Frequency of variants. Am. J. Hum. Genet. 25, 181–192 (1973)
Donlon, T.A.; Cytologic characterization of human constitutive heterochromatin. Master of Science Thesis, Portland State University (1981)
Eiberg, H.; New selective Giemsa technique for human chromosomes. Cd staining. Nature (Lond.) 248, 55 (1974)
Fitzgerald, P.H.; The nature and inheritance of an elongated secondary constriction on chromosome 9 of man. Cytogenet. Cell Genet. 12, 404–413 (1973)
Gagné, R., Laberge, C.; Specific cytological recognition of the heterochromatic segment of number 9 chromosome in man. Exp. Cell Res. 73, 239–242 (1972)
Gagné, R., Laberge, C. and Tanquay, R.; Aspect cytologique et localisation intranucléaire de l'hétérochromatine constitutive des chromosomes C9 chez l'homme. Chromosoma (Berl.) 41, 159–166 (1973)
Galloway, S.M., Evans, H.J.; Asymmetrical C-bands and satellite DNA in man. Exp. Cell Res. 94, 454–459 (1975)
Ghosh, P.K., Rani, R., Nand, R.; Lateral asymmetry of constitutive heterochromatin in human chromosomes. Hum. Genet. 52, 79–84 (1979)
Gosden, J.R., Mitchell, A.R., Buckland, R.A., Clayton, R.P., Evans, H.J.; The location of four human satellite DNAs on human chromosomes. Exp. Cell Res. 92, 148–158 (1975)
Hansmann, I.; Structural variability of human chromosome 9 in relation to its evolution. Hum. Genet. 31, 247–262 (1976)
Hungerford, D.A., Ashton, F.T., Balaban, G.B., LaBadie, G.U., Messatzzia, L.R., Haller, G. and Miller, A.E.; The C-group pachytene bivalent with a locus characteristic for parachromosomally situated particulate bodies (parameres): a provisional map in human males. Proc. nat. Acad. Sci. (Wash.) 69, 2165–2168 (1972)
Jacobs, P.A.; Human chromosome heteromorphisms (variants). Prog. Med. Genet. 2, 251–274 (1977)
Jones, K.W.; Repetitive DNA and primate evolution. In: Molecular structure of human chromosomes (J. Yunis, ed.), p. 322–323 New York: Academic Press 1977
Kurnit, D.M.; Satellite DNA and heterochromatin variants; the case for unequal mitotic crossing over. Hum. Genet. 47, 169–189 (1979)
Lin, M.S., Alfi, O.S.; Detection of lateral asymmetry in the C-band of human chromosomes by BrdU-DAPI fluorescence. Somat. Cell Genet. 4, 603–608 (1978)
Madan, K.; An extra band in human 9qh + chromosomes. Hum. Genet. 43, 259–264 (1978)
Madan, K., Bobrow, M.; Structural variation in chromosome No. 9. Ann. Génét. 17, 81–86 (1974)
Magenis, R.E., Donlon, T.A., Wyandt, H.E.; Giemsa-11 staining of chromosome 1: a newly described heteromorphism. Science 202, 64–65 (1978)
Metaxotou, C., Kalpini-Mavrou, A., Panagou, M., Tsenghi, C.; Polymorphism of chromosome 9 in 600 Greek subjects. Amer. J. Hum. Genet. 30, 85–89 (1978)
Page, B.; Identification of chromosome 9 in human male meiosis. Cytogenet. Cell Genet. 12, 254–263 (1973)
Pech, M., Streeck, R.E., Zachau, H.G.; Patchwork structure of a bovine satellite DNA. Cell 18, 883–893 (1979)
Seabright, M.; A rapid banding technique for human chromosomes. Lancet 1971 II, 971–972
Van Dyke, D.L., Palmer, C.G., Nance, W.E. and Yu, P.; Chromosome polymorphism and twin zygosity. Amer. J. Hum. Genet. 29, 431–447 (1977)
Wyandt, H.E., Wysham, D.G., Minden, S.K., Anderson, R.S., Hecht, F.; Mechanisms of Giemsa banding of chromosomes. I. Giemsa-11 banding with Azure and Eosin. Exp. Cell Res. 102, 85–94 (1976)
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Donlon, T.A., Ellen Magenis, R. Structural organization of the heterochromatic region of human chromosome 9. Chromosoma 84, 353–363 (1981). https://doi.org/10.1007/BF00286025
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DOI: https://doi.org/10.1007/BF00286025