Browse > Article
http://dx.doi.org/10.1080/19768354.2011.615147

Relationship between the nucleolar cycle and chromatoid body formation in the spermatogenesis of $Phrynops$ $geoffroanus$ (Reptilia Testudines)  

Peruquetti, Rita L. (Sao Paulo State University (UNESP/IBILCE))
Taboga, Sebastiao R. (Sao Paulo State University (UNESP/IBILCE))
Cabral, Silvia R. (Sao Paulo State University (UNESP/IBILCE))
De Oliveira, Classius (Sao Paulo State University (UNESP/IBILCE))
Azeredo-Oliveira, Maria T. (Sao Paulo State University (UNESP/IBILCE))
Publication Information
Animal cells and systems / v.16, no.2, 2012 , pp. 104-113 More about this Journal
Abstract
The nucleolus is a distinct nuclear territory involved in the compartmentalization of nuclear functions. There is some evidence of a relationship between nuclear fragmentation during spermatogenesis and chromatoid body (CB) formation. The CB is a typical cytoplasmic organelle of haploid germ cells, and is involved in RNA and protein accumulation for later germ-cell differentiation. The goal of this study was to qualitatively and quantitatively describe the nucleolar cycle during the spermatogenesis of $Phrynops$ $geoffroanus$ (Reptilia Testudines), and compare this nucleolar fragmentation with CB formation in this species through the use of cytochemical and ultrastructural analysis. Qualitative analysis showed a fragmentation of the nuclear material after pachytene of the first meiotic division in the primary spermatocytes. Quantitative analysis of the nucleolar cycle revealed a significant difference in the number of nucleoli and in the size of the nucleolus between spermatogonia and early spermatids. Using ultrastructural analysis, we recorded the beginning of the CB formation process in the cytoplasm of primary spermatocytes at the same time as when nuclear fragmentation occurs. In the cytoplasm of primary spermatocytes, the CB was observed in association with mitochondrial aggregates and the Golgi complex. In the cytoplasm of early spermatids, the CB was observed in association with lipid droplets. In conclusion, our data show that the nucleolus plays a role in the CB formation process. During spermatogenesis of $P.$ $geoffroanus$, the CB is involved in some important biological processes, including acrosome formation and mitochondrial migration to the spermatozoon tail and middle piece region.
Keywords
nucleolar cycle; spermatogenesis; chromatoid body; reptiles;
Citations & Related Records
 (Related Records In Web of Science)
연도 인용수 순위
  • Reference
1 Montanaro L, Trere D, Derenzini M. 2007. Nucleolus, ribosomes, and cancer. Am J Pathol. 173(2):301-310.
2 Tang XM, Lalli MF, Clermont Y. 1982. A cytochemical study of the Golgi apparatus of the spermatid during spermiogenesis in the rat. Am J Anat. 163:283-294.   DOI
3 Tartarotti E, Azeredo-Oliveira MTV. 1999. Patterns of nucleolar activity during spermatogenesis of two triatomines, Panstrongylus megistus and P. herreri. Caryologia. 5(3-4):177-184.
4 Teruel M, Cabrero J, Perfectti F, Camacho JPM. 2007. Nucleolus size variation during meiosis and NOR activity of a B chromosome in the grasshopper Eyprepocnemis plorans. Chromosome Res. 15:755-765.   DOI
5 Venable JH, Coggeshall RA. 1965. A simplified lead citrate stain for use in electron microscopy. J Cell Biol. 25:407-408.   DOI
6 Visitin R, Hwang ES, Arnon A. 1999. Cfi1 prevents premature exit from mitosis by anchoring Cdc14 phosphatase in the nucleolus. Nature 398:818-823.   DOI
7 Wachtler F, Stahl A. 1993. The nucleolus: a structural and functional interpretation. Micron. 24:473-505.   DOI
8 Walt H, Armbruster BL. 1984. Actin and RNA are components of the chromatoid bodies in spermatids of the rat. Cell Tissue Res. 236:487-490.
9 Watson ML. 1958. Staining tissue section of electron microscopy with heavy metals. J Biophys Biochem Cytol. 4:475-478.   DOI
10 Yokota S. 2008. Historical survey on chromatoid body research. Acta Histochem Cytochem. 41(4):65-82.   DOI
11 Zar JH. 1999. Biostatiscical analysis. Upper Saddle River (NJ): Prentice Hall.
12 Pudney J. 1990. Comparative cytology of the non-mammalian vertebrae Sertoli cell. In: Russell LD, Griswold MD, editors. The Sertoli cell. Clearwater (FL): Cache River Press.
13 Reunov A, Isaeva V, Au D, Wu R. 2000. Nuage constituents arising from mitochondria: is it possible? Dev Growth Differ. 42:139-143.   DOI
14 Ribeiro MG, Lima SR. 2000. Iniciacao as tecnicas de preparacao de material para estudo e pesquisa em morfologia. Belo Horizonte (Minas Gerais, Brazil): SEGRAC Editora e Grafica Limitada.
15 San-Segundo PA, Roeder GS. 1999. Pch2 links chromatin silencing to meiotic checkpoint control. Cell. 97:31-324.
16 Saunders PTK, Millar MR, Maguire SM, Sharpe RM. 1992. Stage-specific expression of rat transition protein 2 mRNA and possible localization to the chromatoid body of step 7 spermatids by in situ hybridization using a nonradioactive riboprobe. Mol Reprod Dev. 33:385-391.   DOI
17 Shubert I, Kunzel G. 1990. Position dependent NOR activity in barley. Chromosoma. 99:352-359.   DOI
18 Schmid M, Lo ser C, Schmidtke J, Engel W. 1982. Evolutionary conservation of a common pattern of activity of nucleolus organizers during spermatogenesis in vertebrates. Chromosoma. 86:149-179.   DOI
19 Severi-Aguiar GDC, Morielle A, Azeredo-Oliveira MTV. 2002. Nucleolar activity during the spermatogenesis in Heteroptera. Biocell. 26:303.
20 Shou W, Seol JH, Shevchenko A, Baskerville C, Moazerd D, Chen ZW, Jang J, Shevchenko A, Charbonneau H, Deshaies RJ. 1999. Exit from mitosis is triggered by tem1-dependent release of the protein phosphatase Cdc14 from nucleolar RENT complex. Cell. 97:233-244.   DOI
21 Sirri V, Urcuqui-Inchima S, Roussel P, Hernandez-Verdun D. 2008. Nucleolus: the fascinating nuclear body. Histochem Cell Biol. 129:13-31.   DOI
22 So derstrom K, Parvinen M. 1976. Transport of material between the nucleus, the chromatoid body and the Golgi complex in the early spermatids of the rat. Cell Tissue Res. 168:335-342.
23 Soley JT. 1994. Centriole development and formation of the flagellum during spermiogenesis in the ostrich (Struthio camelus). J Anat. 185:301-313.
24 Straight AF, Shou W, Dowd GJ, Turck CW, Deshaies RH, Johnson AD, Moazed D. 1999. Net1, a Sir2-associated nucleolar protein required for rDNA silencing and nucleolar integrity. Cell. 97:245-256.   DOI
25 Sud B. 1961. Morphological and histochemical studies of the chromatoid body and related elements in the spermatogenesis of rat. Q J Microsc Sci. 102:273-292.
26 Taboga SR. 1997. Estudo citoquimico e morfometrico em nucleos e distribuicao das fibras no estroma e lesoes da pro stata humana. [PhD thesis]. Bioscience Institute, UNICAMP, Campinas.
27 Mello MLS. 1997. Cytochemistry of DNA, RNA and nuclear proteins. Braz J Genet. 20(2):257-262.
28 Takeuchi IK, Takeuchi YK. 1990. Ethanol-phosphotungstic acid and bismuth staining of spermatid nucleoli in mouse spermiogenesis. J Struct Biol. 103:104-112.   DOI
29 Kotaja N, Bhattacharyya SN, Jaskiewics L, Kimmins S, Parvinen M, Filipowicz W, Sassone-Corsi P. 2006. The chromatoid body of male germ cells: Similarity with processing bodies and presence of Dicer and microRNA pathway components. PNAS. 103(8):2647-2652.   DOI
30 Lefevre B. 2008. The nucleolus of the maternal gamete is essential for life. BioEssays. 30:613-616.   DOI
31 Mello MLS, Vidal BC. 1980. Praticas de Biologia Celular. Sao Paulo: FUNCAMP Editora Edgard Blucher LTDA.
32 Mosgoeller W. 2004. Nucleolar ultrastructure in vertebrates. In: Olson MOJ, editor. The nucleolus. New York: Kluwer.
33 Nakamoto K, Ito A, Watabe K, et al. 2001. Increased expression of a nucleolar Nop5/Sik family member in metastatic melanoma cells: evidence for its role in nucleolar sizing and function. Am J Pathol. 159:1363-1374.   DOI
34 Paniagua R, Nistal M, Amat P, Rodriguez MC. 1986. Ultrastructural observations on nucleoli and related structures during human spermatogenesis. Anat Embryol. 174:301-306.   DOI
35 Parvinen M. 2005. The chromatoid body in spermatogenesis. Int J Androl. 28:189-201.   DOI
36 Parvinen M, Parvinen L. 1979. Active movements of the chromatoid body: A possible transport mechanism for haploid gene products. J Cell Biol. 80:621-628.   DOI
37 Peruquetti RL, Taboga SR, Azeredo-Oliveira MTV. 2010a. Characterization of Mongolian gerbil chromatoid bodies and their correlation with nucleolar cycle during spermatogenesis. Reprod Dom Anim. 45:399-406.
38 Parvinen M, Salo J, Toivonen M, Nevalainen O, Soini E, Pelliniemi L. 1997. Computer analysis of living cells: movements of the chromatoid body in early spermatids compared with its ultrastructure in snap-frozen preparations. Histochem Cell Biol. 108:77-81.   DOI
39 Pederson T. 2002. Proteomics of the nucleolus: more proteins, more functions? Trends Biochem Sci. 27(3):111-112.   DOI
40 Peruquetti RL, Assis IM, Taboga SR, Azeredo-Oliveira MTV. 2008. Meiotic nucleolar cycle and chromatoid body formation during the rat (Rattus novergicus) and mouse (Mus musculus) spermiogenesis. Micron. 39:419-425.   DOI
41 Peruquetti RL, Taboga SR, Azeredo-Oliveira MTV. 2010b. Nucleolar cycle and its correlation with chromatoid bodies in the Tilapia rendalli (Teleostei, Cichlidae) spermatogenesis. Anat Rec. 293:900-910.   DOI
42 Peruquetti RL, Taboga SR, Santos LRS, Oliveira C, Azeredo-Oliveira MTV. 2011. Nucleolar cycle and chromatoid body formation: is there a relationship between these two processes during spermatogenesis of Dendropsophus minutus (Amphibia, Anura)? Micron. 42:87-96.   DOI
43 Pikaard CS. 2002. Transcription and tyranny in the nucleolus: the organization, activation, dominance and repression of ribosomal RNA genes. In: Somerville CR, Meyerowits EM, editors. The Arabidopsis book. Rockville: American Society of Plant Biologists.
44 Cabral SRP, Zieri R, Franco-Belussi L, Santos LRS, Zago CES, Taboga SR, Oliveira C. 2011. Morphological changes of the epididymis and description of the excurrent ducts of Phrynops geoffroanus (Testudines: Chelidae) during the reproductive cycle. Anat Rec. 294:145-155.   DOI
45 Comings DE, Okada TA. 1972. The chromatoid body in mouse spermatogenesis: evidence that it may be formed by the extrusion of nucleolar components. J Ultrast Res. 39(1):15-23.   DOI
46 Carmo-Fonseca M, Mendes-Soares L, Campos I. 2000. To be or not to be in the nucleolus. Nat Cell Biol 2:E107-E112.   DOI
47 Caspersson T. 1950. Cell growth and cell function, a cytochemical study. New York: WW Norton.
48 Cmarko D, Smigova J, Minichova L, Popov A. 2008. Nucleolus: The ribosome factory. Histol Histopathol. 23:1291-1298.
49 Cotta-Pereira G, Rodrigo FG, David-Ferreira JF. 1976. The use of tannic acid glutaraldehyde in the study of elastic related fibers. Stain Technol. 51:7-11.   DOI
50 Fawcett DW, Eddy EM, Phillips DM. 1970. Observations on the fine structure and relationships of the chromatoid body in mammalian spermatogenesis. Biol Reprod. 2(1):129-153.   DOI
51 Figueroa J, Burzio LO. 1998. Polysome-like structures in the chromatoid body of rat spermatids. Cell Tissue Res. 291:575-579.   DOI
52 Garcia SN, Pillus L. 1999. Net results of nucleolar dynamics. Cell. 97:825-828.   DOI
53 Gerbi SA, Borovjagin AV, Lange TS. 2003. The nucleolus: a site of ribonucleoprotein maturation. Curr Op Cell Biol. 15:318-325.   DOI
54 Gribbins KM, Gist DH, Congdon JD. 2003. Cytological evaluation of spermatogenesis and organization of the germinal epithelium in the male slider turtle, Trachemys scripta. J Morph. 255:337-346.   DOI
55 Guo M, Davis D, Birchler JA. 1996. Dosage effects on gene expression in a maize ploidy series. Genetics. 142:1349-1355.
56 Ha RR, Ha JC. 2007. Integrative statistics for behavioral science. Boston, MA: Pearson.
57 Howell WM, Black DA. 1980. Controlled silver staining of nucleolus organizer regions with protective colloidal developer: I-step method. Experientia. 36:104-105.   DOI
58 Haraguchi CM, Mabuchi T, Hirata S, Shoda T, Hoshi K, Akasaki K, Yokota S. 2005. Chromatoid bodies: aggresomelike characteristics and degradation sites for organelles of spermiogenic cells. J Histochem Cytochem. 53(4):455-465.   DOI
59 Hernandez-Verdun D. 1991. The nucleolus today. J Cell Sci. 99:465-471.
60 Hess RA, Miller LA, Kirby JD, Margoliash E, Goldberg E. 1993. Immunoelectron microscopic localization of testicular and somatic cytochromes c in the seminiferous epithelium of the rat. Biol Reprod. 48:1299-1308.   DOI
61 Kotaja N, Sassone-Corsi P. 2007. The chromatoid body: a germ-cellspecific RNA-processing centre. Mol Cell Biol. 8:85-90.
62 Andersen K. 1978. Fine structure of spermatogonia and spermatocytes in the blue fox (Alopex lagopus). Acta Veter Scandi (Denmark) 19(2):229-242.
63 Andonov M. 1990. Further study of the chromatoid body in rat spermatocytes and spermatids. Z. Mikrosk Anat. 104:46-54.
64 Andonov MD, Chaldakov GN. 1989. Morphological evidence for calcium storage in the chromatoid body of rat spermatids. Experientia. 45:377-378.   DOI
65 Anton E. 1983. Association of Golgi vesicles containing acid phosphatase with the chromatoid body of rat spermatids. Experientia 39:393-394.   DOI
66 Aumuller G, Seitz J. 1988. Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa. Histochemistry. 39:261-267.
67 Biggiogera M, Kaufmann SH, Shaper JH, Gas N, Amalric F, Fakan S. 1991. Distribution of nucleolar proteins B23 and nucleolin during mouse spermatogenesis. Chromosoma. 100:162-172.   DOI
68 Boisvert FM, van Koningsbruggen S, Navascues J, Lamnond AI. 2007. The multifunctional nucleolus. Nature Reviews: Mol Cell Biol. 8:574-585.