Abstract
Lampbrush chromosomes (LBCs) are highly extended bivalents that function in the growing oocytes of many animals. Due to their distinctive chromomere-loop organization and intense transcriptional activity of lateral loops the LBCs, mainly amphibian ones, have served as a powerful system for exploring the general principles of chromosome organization and function. The exploitation of avian LBCs has considerably broadened the opportunities for comparative genome research and for cytogenetic analysis of domestic species. In this review we highlight the advantages of avian LBCs for research in different areas including integration of genome organization studies with studies on gene activity in vivo, analysis of co-transcriptional events occurring on nascent transcripts and investigation of chromosome-associated intranuclear domains. Recent findings concerning the organization of transcriptionally active and silent chromatin together with involvement of cohesin and condensin complexes into maintenance of structural integrity of LBCs are presented. The biological significance of the LBC phenomenon is discussed. The intensive transcription on LBCs shows some specific features: very long transcription units, deregulated termination, and transcription of non-coding satellite repeats. Here, based on the modern view on a role of RNA interference machinery in regulation of genome expression, we suggest a mechanism of initiation of satellite DNA transcription and offer a novel interpretation of the ‘classical’ hypothesis that sought to explain the significance of widespread transcription during oocyte growth.
References
1.
Aguilera A: Cotranscriptional mRNP assembly: from the DNA to the nuclear pore. Curr Opin Cell Biol 17:242–50 (2005).
2.
Almedia R, Allshire RC: RNA silencing and genome regulation. Trends Cell Biol 5:251–258 (2005).
3.
Angelier N, Penrad-Mobayed M, Billoud B, Bonnafant-Ja’is M-L, Coumailleau P: What role might lampbrush chromosomes play in maternal gene expression? Int Dev BioI 40:645–652 (1996).
4.
Baldwin L, Macgregor HC: Centromeric satellite DNA in the newt Triturus cristatus karelinii and related species: its distribution and transcription on lampbrush chromosomes. Chromosoma 92:100–107(1985).
5.
Barsacchi-Pilone G, Batistoni R, Andronico F, Vitelli L, Nardi I: Heterochromatic DNA in Triturus (Amphibia, Urodela). I. A satellite DNA component of the pericentric C-bands. Chromosoma 93:435–446 (1986).
6.
Beenders B, Watrin E, Legagneux V, Kireev I, Bellini M: Distribution of XCAP-E and XCAP-D2 in the Xenopus oocyte nucleus. Chromosome Res 11:549–564 (2003).
7.
Brambell FWR: The oogenesis of the fowl (Gallus bankiva). Phil Trans R Soc London Ser B 214:113–151 (1926).
8.
Bromley SE, Gall JG: Transcription of the histone loci on lampbrush chromosomes of the newt Notophthalmus viridescens. Chromosoma 95:396–402 (1987).
9.
Calderón PL, Pigozzi MI: MLH1-focus mapping in birds shows equal recombination between sexes and diversity of crossover patterns. Chromosome Res 14:605–612 (2006).
10.
Callan HG, Lloyd L: Lampbrush chromosomes of crested newts Triturus cristatus (Laurenti). Phil Trans R Soc London Ser B 243:135–219 (1960).
11.
Callan HG: Lampbrush Chromosomes (Springer-Verlag, London 1986).
12.
Callebaut M: [3H] Uridine incorporation during previtellogenesis and early vitellogenesis in the oocytes of the chick (Gallus gallus). J Embryol Exp Morphol 20:169–174 (1968).
13.
Chelysheva LA, Solovei IV, Rodionov AV, Yakovlev AF, Gaginskaya ER: The lampbrush chromosomes of the chicken. The cytological map of macrobivalents. Tsitologiia 32:303–316 (1990).
14.
Chin SH, Gaginskaya ER, Kalinina EI: Peculiarities of oogenesis in the chicken. I. Extrafollicular period in the development of oocytes. Ontogenes (Russ) 10:340–349 (1979).
15.
Christidis L: Animal Cytogenetics 4: Chordata 3 B: Aves (Gebrüder Borntraeger, Berlin 1990).
16.
Davidson EH: Gene Activity in Early Development. Third edition (Academic Press, London 1986).
17.
Davidson EH, Hough BR: Genetic information on oocyte RNA. О Mol Biol 56:491–506 (1971).
18.
Derjusheva S, Kurganova A, Krasikova A, Saifitdinova A, Habermann FA, Gaginskaya E: Precise identification of chicken chromosomes in the lampbrush form using chromosome painting probes. Chromosome Res 11:749–757 (2003).
19.
Deryusheva S, Krasikova A, Kulikova T, Gaginskaya E: Tandem 41-bp repeats in chicken and Japanese quail genomes: FISH mapping and transcription on lampbrush chromosomes. Chromosoma 116:519–530 (2007).
20.
Diaz MO, Barsacchi-Pilone G, Mahon KA, Gall JG: Transcripts from both strands of a satellite DNA occur on lampbrush chromosome loops of the newt Notophthalmus.Cell 24:649–659 (1981).
21.
Dreyfuss G, Matunis MJ, Piñol-Roma S, Burd CG: hnRNP proteins and the biogenesis of mRNA. Annu Rev Biochem 62:289–321 (1993).
22.
Duryee WR: Isolation of nuclei and non-mitotic chromosome pairs from frog eggs. Arch Exp Zellforsch 19:171–176 (1937).
23.
Epstein LM, Mahon KA, Gall JG: Transcription of a satellite DNA in the newt. J Cell Biol 103:1137–1144 (1986).
24.
Fischer D, Hock R, Scheer U: DNA topoisomerase II is not detectable on lampbrush chromosomes but enriched in the amplified nucleoli of Xenopus oocytes. Exp Cell Res 209:255–260 (1993).
25.
Gaginskaya ER: The nuclear structures in oocytes of adult birds. I. Chromosome behavior during the oocyte cytoplasm growth. Tsitologiia 14:426–432 (1972a).
26.
Gaginskaya ER: The nuclear structures in oocytes of adult birds. II. Protein bodies and the karyosphere. Tsitologiia 14:568–577 (1972b).
27.
Gaginskaya ER: The problem of classification of oogeneses. Ontogenes (Russ)6:539–545 (1975).
28.
Gaginskaya ER: The lampbrush chromosomes in the amphibian oocytes. Tsitologiia 31:1267–1291 (1989).
29.
Gaginskaya ER, Chin SH: Peculiarities of oogenesis in the chicken. II. Follicular period in oocyte development. Ontogenes (Russ) 11:213–221 (1980).
30.
Gaginskaya ER, Gruzova MN: Peculiarities of the oogenesis in chaffinch. Tsitologiia 11:1241–1251 (1969).
31.
Gaginskaya ER, Gruzova MN: Detection of the amplified rDNA in ovarial cells of some insects and birds by hybridization in situ.Tsitologiia 17:1132–1137 (1975).
32.
Gaginskaya ER, Tsvetkov AG: Electron microscopy research on the chromatin structure of dispersed lampbrush chromosomes in the hen. Tsitologiia 30:142–150 (1988).
33.
Galkina S, Lukina N, Zakharova K, Rodionov A: Interstitial (TTAGGG)(n) sequences are hot spots of recombination in the chicken lampbrush macrochromosomes 1–3. Chromosome Res 13:551–557 (2005).
34.
Galkina S, Deryusheva S, Fillon V, Vignal A, Crooijmans R, et al: EFISH on avian lampbrush chromosomes produces higher resolution gene mapping. Genetica 128:241–251 (2006).
35.
Gall JG: Lampbrush chromosomes from oocyte nuclei of the newt. J Morphol 94:283–352 (1954).
36.
Gall JG: Techniques for the study of lampbrush chromosomes, in Prescott DM (ed): Methods in Cell Physiology, vol II, pp 37–60 (Academic Press, London 1966).
37.
Gall JG: Organelle assembly and function in the amphibian germinal vesicle. Adv Dev Biol 1:1–29 (1992).
38.
Gall JG: The centennial of the Cajal body. Nat Rev Mol Cell Biol 4:975–980 (2003).
39.
Gall JG, Callan HG: The sphere organelle contains small nuclear ribonucleoproteins. Proc Natl Acad Sci USA 86:6635–6639 (1989).
40.
Gall JG, Diaz MO, Stephenson EC, Mahon KA: The transcription unit of lampbrush chromosomes, in Subtelny S, Kafatos F (eds): Gene Structure and Regulation in Development. Soc Dev Biol Symp 41:137–146 (1983).
41.
Gall JG, Wu Z, Murphy C, Gao H: Structure in the amphibian germinal vesicle. Exp Cell Res 296:28–34 (2004).
42.
Greenfield ML: The oocyte of the domestic chicken shortly after hatching, studied by electron microscopy. Embryol Exp Morph 15:297–316 (1966).
43.
Griffin DK, Robertson LB, Tempest HG, Vignal A, Fillon V, et al: Whole genome comparative studies between chicken and turkey and their implications for avian genome evolution. BMC Genomics 9:168–184 (2008).
44.
Gruzova MN, Parfenov VN: Karyosphere in oogenesis and intranuclear morphogenesis. Int Rev Cytol 144:1–52 (1993).
45.
Guraya SS: Correlative cytological and histochemical studies on the avian oogenesis. Z Mikrosk Anat Forsch 90:91–150 (1976).
46.
Hagstrom KA, Meyer BJ: Condensin and cohesin: more than chromosome compactor and glue. Nat Rev Genet 4:520–534 (2003).
47.
Hartley SE, Callan HG: RNA transcription on the giant lateral loops of the lampbrush chromosomes of the American newt Notophthalmus viridescens. J Cell Sci 34:279–288 (1978).
48.
Hock R, Moorman A, Fischer D, Scheer U: Absence of somatic histone H1 in oocytes and preblastula embryos of Xenopus laevis. Dev Biol 158:510–522 (1993).
49.
Holl M: Uber die Reifung derEizelle des Huhnes. Sitzungsber Akad Wiss Wien 99:311–370 (1890).
50.
Hori T, Susuki Y, Solovei I, Saitoh Y, Hutchison N, et al: Characterization of DNA sequences constituting the terminal heterochromatin of the chicken Z chromosome. Chromosome Res 4:411–426 (1996).
51.
Hutchison N: Lampbrush chromosomes of the chicken. J Cell Biol 105:1493–1500 (1987).
52.
ICGSC (International Chicken Genome Sequencing Consortium): Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution. Nature 432:695–716 (2004).
53.
Itoh Y, Mizuno S: Molecular and cytological characterization of Ssp I-family repetitive sequence on the chicken W chromosome. Chromosome Res 10:499–511 (2002).
54.
Jamrich M, Warrion R, Steele R, Gall JG: Transcription of repetitive sequences on Xenopus lampbrush chromosomes. Proc Natl Acad Sci USA 80:3364–3367 (1983).
55.
Khutinaeva MA, Kropotova EV, Gaginskaya ER: Morpho-functional organization of the lampbrush chromosomes in oocytes of the pigeon Columba livia.Tsitologiia 31:1185–1192 (1989).
56.
Kim VN: Small RNAs: Classification, biogenesis, and function. Mol Cells 19:1–15 (2005).
57.
Koecke HU, Müller M: Change of form and number of chromosomes in chicken and duck. Naturwissenschaften 52:483 (1965).
58.
Koschelt E, Heider K: Lehrbuch der Vergleichenden Entwicklungsgeschichte der Wirbellosen Thiere. Allgemeiner Theil I.-IV. Capitel; Ei und Eibildung (Gustav Fischer, Jena 1902).
59.
Krasikova A, Kulikova T, Saifitdinova A, Derjusheva S, Gaginskaya E:Centromeric protein bodies on avian lampbrush chromosomes contain a protein detectable with an antibody against DNA topoisomerase II. Chromosoma 113:316–323 (2004).
60.
Krasikova A, Barbero JL, Gaginskaya E: Cohesion proteins are present in centromere protein bodies associated with avian lampbrush chromosomes. Chromosome Res 13:675–685 (2005).
61.
Krasikova A, Deryusheva S, Galkina S, Kurganova A, et al: On the positions of centromeres in chicken lampbrush chromosomes. Chromosome Res 14:777–789 (2006).
62.
Kropotova EV, Gaginskaya ER: Lampbrush chromosomes from the Japanese quail oocytes: light and electron microscopic study. Tsitologiia 26:1008–1015 (1984).
63.
Lintern-Moore S, Moore GP, Tyndale-Biscoe CH, Poole WE: The growth of the oocyte and follicle in the ovaries of monotremes and marsupials. Anat Rec 185:325–332 (1976).
64.
Loyez M: Recherches sur le développement ovarian des oeufs méroblastiques à vitellus nutritive abundant. Arch Anat Microsc Morphol Exper 8:69–397 (1906).
65.
Lund E, Paine PL: Nonaqueous isolation of transcriptionally active nuclei from Xenopus oocytes. Methods Enzymol 181:36–43 (1990).
66.
Macgregor HC: Recent developments in the study of lampbrush chromosomes. Heredity 44:3–35 (1980).
67.
Macgregor HC: Lampbrush chromosomes and gene utilization in meiotic prophase. Symp Soc Exp Biol 38:333–347 (1984).
68.
Macgregor HC: Lampbrush chromosomes. J Cell Sci 88:7–9 (1987).
69.
Macgregor HC: Lampbrush chromosomes. Retrieved from http://www.exeter.ac.uk/projects/lampbrush/ (2002).
70.
Macgregor HC, Andrews C: The arrangement and transcription of ‘middle repetitive’ DNA sequences on lampbrush chromosomes of Triturus. Chromosoma 63:109–126 (1977).
71.
Macgregor HC, Klosterman L: Observations on the cytology of Bipes (Amphisbaenia) with special reference to its lampbrush chromosomes. Chromosoma 72:67–87 (1979).
72.
Macgregor HC, Varley J: Working with Animal Chromosomes 2nd edition (John Wiley & Sons, New York 1988).
73.
Macgregor HC, Varley JM, Morgan GT: The transcription of satellite and ribosomal DNA sequences on lampbrush chromosomes of crested newts, in Schweiger H-G (ed): International Cell Biology, pp 33–46 (Springer-Verlag, Berlin 1981).
74.
Macgregor HC, Solovei I, Mizuno S: Lampbrush chromosomes as system for high resolution studies of meiotic chromosome structure, in Abbondandolo A, Vig BK, Roi R (eds): Chromosome Segregation and Aneuploidy, pp 172–183 (European Commission Joint Research Centre Publication, 1997).
75.
Marko JF: Micromechanical studies of mitotic chromosomes. Chromosome Res 16:469–497 (2008).
76.
Masi T, Johnson AD: Read-through histone transcripts containing 3′ adenylate tails are zygotically expressed in Xenopus embryos and undergo processing to mature transcripts when introduced into oocyte nuclei. Biochem Biophys Res Commun 304:612–618 (2003).
77.
Matunis EL, Matunis MJ, Dreyfuss G: Association of individual hnRNP proteins and snRNPs with nascent transcripts. J Cell Biol 121:219–228 (1993).
78.
Matzke MA, Birchler JA: RNAi-mediated pathways in the nucleus. Nat Rev Genet 6:24–35 (2005).
79.
Mizuno S, Macgregor H: The ZW lampbrush chromosome of birds: a unique opportunity to look at the molecular cytogenetics of sex chromosomes. Cytogenet Cell Genet 80:149–157 (1998).
80.
Morgan GT: Lampbrush chromosomes and associated bodies: new insights into principles of nuclear structure and function. Chromosome Res 10:177–200 (2002).
81.
Morgan GT: Localized co-transcriptional recruitment of the multifunctional RNA-binding protein CELF1 by lampbrush chromosome transcription units. Chromosome Res 15:985–1000 (2007).
82.
Morgan GT, Macgregor HC, Colman A: Multiple ribosomal gene sites revealed by in situ hybridization of Xenopus rDNA to Triturus lampbrush chromosomes. Chromosoma 80:309–330 (1980).
83.
Ogawa A, Solovei I, Hutchison N, Saitoh Y, Ikeda JE, et al: Molecular characterization and cytological mapping of a non-repetitive DNA sequence region from the W chromosome of chicken and its use as a universal probe for sexing carinatae birds. Chromosome Res 5:93–101 (1997).
84.
Old RW, Callan GH, Gross KW: Localization of histone gene transcripts in newt lampbrush chromosomes by in situ hybridization. J Cell Sci 27:57–79 (1977).
85.
Organ CL, Shedlock AM, Meade A, Pagel M, Edwards SV: Origin of avian genome size and structure in non-avian dinosaurs. Nature 446:180–184 (2007).
86.
Parra MT, Viera A, Gomez R, Page J, Benavente R, et al: Involvement of the cohesin Rad21 and SCP3 in monopolar attachment of sister kinetochores during mouse meiosis I. J Cell Sci 117:1221–1234 (2004).
87.
Patel SB, Novikova N, Bellini M: Splicing-independent recruitment of spliceosomal small nuclear RNPs to nascent RNA polymerase II transcripts. J Cell Biol 178:937–949 (2007).
88.
Patel S, Novikova N, Beenders B, Austin C, Bellini M: Live images of RNA polymerase II transcription units. Chromosome Res 16:223–232 (2008).
89.
Prasanth KV, Spector D: Eukaryotic regulatory RNAs: an answer to the ‘genome complexity’ conundrum. Genes Dev 21:11–42 (2007).
90.
Prasanth KV, Prasanth SG, Xuan Z, Hearn S, Freier SM, et al: Regulating gene expression through RNA nuclear retention. Cell 123:249–263 (2005).
91.
Rodionov AV, Chechik MS: Cytogenetic map of the Japanese quail lampbrush chromosomes. Genetika (Russ) 38:1246–1251 (2002).
92.
Rodionov AV, Chelysheva LA, Kropotova EV, Gaginskaya ER: Heterochromatin regions of the chromosomes of the hen and Japanese quail in mitosis and at the lampbrush stage. Tsitologiia 31:867–873 (1989).
93.
Rodionov AV, Myakoshina YA, Chelysheva LA, Solovei IV, Gaginskaya ER: Chiasmata in the lampbrush chromosomes of Gallus gallus domesticus: The cytogenetic study of recombination frequency and linkage map lengths. Genetika (Russ) 28:53–63 (1992a).
94.
Rodionov AV, Chel’sheva LA, Soloveĭ IV, Miakoshina IuA: Chiasma distribution in the lampbrush chromosomes of the chicken Gallus gallus domesticus: hot spots of recombination and their possible role in proper dysjunction of homologous chromosomes at the first meiotic division. Genetika (Russ) 28:151–160 (1992b).
95.
Rodionov AV, Galkina SA, Lukina NA, Solovei I, Saccone S: Crossing over in chicken oogenesis: cytological and chiasma-based genetic maps of the chicken lampbrush chromosome 1. J Hered 93:125–129 (2002).
96.
Rutkowska J, Badyaev AV: Meiotic drive and sex determination: molecular and cytological mechanisms of sex ratio adjustment in birds. Phil Trans R Soc Lond B Biol Sci 363:1675–1686 (2008).
97.
Ryan J, Llinas AJ, White DA, Turner BM, Sommerville J: Maternal histone deacetylase is accumulated in the nuclei of Xenopus oocytes as protein complexes with potential enzyme activity. J Cell Sci 112:2441–2452 (1999).
98.
Saifitdinova A, Derjusheva S, Krasikova A, Gaginskaya E: Lampbrush chromosomes of the chaffinch (Fringilla coelebs L.). Chromosome Res 11:93–113 (2003).
99.
Saitoh Y, Saitoh H, Ohtomo K, Mizuno S: Occupancy of the majority of DNA in the chicken W chromosome by bent-repetitive sequences. Chromosoma 101:32–40 (1991).
100.
Sallacz NB, Jantsch MF: Chromosomal storage of the RNA-editing enzyme ADAR1 in Xenopus oocytes. Mol Biol Cell 16:3377–3386 (2005).
101.
Schmid M, Nanda I, Hoehn H, Schartl M, Haaf T, et al: Second report on chicken genes and chromosomes. Cytogenet Genome Res 109:415–479 (2005).
102.
Smillie DA, Llinas AJ, Ryan JT, Kemp GD, Sommerville J: Nuclear import and activity of histone deacetylase in Xenopus oocytes is regulated by phosphorylation. J Cell Sci 117:1857–1866 (2004).
103.
Solovei I, Gaginskaya E, Allen T, Macgregor H: A novel structure associated with a lampbrush chromosome in the chicken, Gallus domesticus. J Cell Sci 101:759–772 (1992).
104.
Solovei I, Gaginskaya E, Hutchison N, Macgregor H: Avian sex chromosomes in the lampbrush form: the ZW lampbrush bivalent from six species of bird. Chromosome Res 1:153–166 (1993).
105.
Solovei I, Gaginskaya ER, Macgregor HC: The arrangement and transcription of telomere DNA sequences at the ends of lampbrush chromosomes of birds. Chromosome Res 2:460–470 (1994).
106.
Solovei I, Macgregor H, Gaginskaya E: Single stranded nucleic acid binding structures on chicken lampbrush chromosomes. J Cell Sci 108:1391–1396 (1995).
107.
Solovei IV, Joffe BI, Gaginskaya ER, Macgregor HC: Transcription on lampbrush chromosomes of a centromerically localized highly repeated DNA in pigeon (Columba) relates to sequence arrangement. Chromosome Res 4:588–603 (1996).
108.
Solovei I, Ogawa A, Naito M, Mizuno S, Macgregor H: Specific chromomeres on the chicken W lampbrush chromosome contain specific repetitive DNA sequence families. Chromosome Res 6:323–327 (1998).
109.
Sommerville J, Baird J, Turner BM: Histone H4 acetylation and transcription in amphibian chromatin. J Cell Biol 120:277–290 (1993).
110.
Stewart MD, Sommerville J, Wong J: Dynamic regulation of histone modifications in Xenopus oocytes through histone exchange. Mol Cell Biol 26:6890–6901 (2006).
111.
Teranishi M, Shimada Y, Hori T, Nakabayashi O, Kikuchi T, Macleod T, et al: Transcripts of the MHM region on the chicken Z chromosome accumulate as non-coding RNA in the nucleus of female cells adjacent to the DMRT1 locus. Chromosome Res 9:147–165 (2001).
112.
Thomas TL, Posakony JW, Anderson DM, Britten RJ, Davidson EH: Molecular structure of maternal RNA. Chromosoma 84:319–335 (1981).
113.
van Durme M: Nouvelles recherches sur la vitellogenèse des oeufs d’oiseaux studies d’ac-croissement, de fécundation et du début la germentation. Arch boil (Liège) 29:71–200 (1914).
114.
Varley JM, Macgregor HC, Erba HP: Satellite DNA is transcribed on lampbrush chromosomes. Nature 283:686–688 (1980a).
115.
Varley JM, Macgregor HC, Nardi I, Andrews C, Erba HP: Cytological evidence of transcription of highly repeated DNA sequences during the lampbrush stage in Triturus cristatus carnifex. Chromosoma 80:289–307 (1980b).
116.
Weber T, Schmidt E, Scheer U: Mapping of transcription units on Xenopus laevis lampbrush chromosomes by in situ hybridization with biotin-labeled cDNA probes. Eur J Cell Biol 50:144–153 (1989).
117.
Wylie CC: Nuclear morphology and nuclear DNA synthesis during meiotic prophase in oocytes of the chick (Gallus domesticus). Cell Diff 1:325–334 (1972).
118.
Zakharova KV, Galkina SA, Lukina NA, Rodionov AV: Crossing over in the oogenesis of Gallus gallus domesticus chickens: periodicity in the distribution of chiasmata over the length of chromosomes. Genetika (Russ) 42:844–849 (2006).
119.
Zhao J, Hyman L, Moore C: Formation of mRNA 3′ ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis. Microbiol Mol Biol Rev 63:405–445 (1999).
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