Zygotene-pachytene substaging and synaptonemal complex karyotyping of boar spermatocytes

Synaptonemal complex analysis, by electron microscopy of spread spermatocytes after phosphotungstic acid staining, made possible description of the chromosomal synaptic patterns and the synaptonemal complex karyotype of the pig (Sus scrofa domestica). The autosomal synaptic pattern in conjunction wi...

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Bibliographic Details
Published in:Hereditas 1993-01, Vol.118 (1), p.87-99
Main Author: Villagomez, D.A.F. (Sveriges Lantbruksuniv., Uppsala (Sweden). Inst. foer Husdjursfoeraedling och Sjukdomsgenetik)
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
BOARS
CARIOTIPOS
CARYOTYPE
Cell Cycle
CITOGENETICA
Classical genetics, quantitative genetics, hybrids
CYTOGENETICS
CYTOGENETIQUE
ESPERMATOGENESIS
ESPERMATOZOO
Fundamental and applied biological sciences. Psychology
Genetics of eukaryotes. Biological and molecular evolution
KARYOTYPES
Karyotyping
Male
Spermatocytes - cytology
Spermatocytes - ultrastructure
SPERMATOGENESE
SPERMATOGENESIS
SPERMATOZOA
SPERMATOZOIDE
Swine
Synaptonemal Complex
VERRACO
VERRAT
Vertebrata
X Chromosome
Y Chromosome
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Summary:Synaptonemal complex analysis, by electron microscopy of spread spermatocytes after phosphotungstic acid staining, made possible description of the chromosomal synaptic patterns and the synaptonemal complex karyotype of the pig (Sus scrofa domestica). The autosomal synaptic pattern in conjunction with the sex chromosome morphology and pairing behaviour can serve as a reference for the meiotic cell progression from the zygotene stage to the pachytene. The autosomes started terminal synapsis at early zygotene (Z1) and at mid‐zygotene (Z2) some of the small bivalents were completely paired. The extension of pairing between the X and the Y chromosome, and the differentiation of their axes, disclosed seven types of sex bivalent (Types 0‐VI). The Type 0 sex bivalent occurred in late zygotene (Z3), at which the X and Y axes began terminal synapsis by their short arms. Each one of the pachytene substages, early, mid‐, and late, included two sex bivalent types. By early pachytene (P1–P2) the entire Y chromosome was paired with the X axis. Subsequently, progressive desynapsis and differentiation of the sex chromosome axes denned the mid‐(P3–P4) and late pachytene substages (P5–P6). At mid‐pachytene, the unpaired XY segments were associated end‐to‐end and showed differing degrees of complexity (thickening, splitting, despiralization and strandedness). These axial complexities were replaced at late pachytene by fine excrescences along the sex chromosome axes, which still formed a short SC stretch. Additionally, an attempt to construct an SC karyotype for the pig is presented. There was general agreement between the autosomal SC karyotype and the autosomal somatic karyotype when comparisons were made, considering the relative lengths and arm ratios of individual chromosome pairs.
ISSN:0018-0661
1601-5223
DOI:10.1111/j.1601-5223.1993.t01-3-00087.x