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Notes: Abstract Surface spread spermatocytes of mice heterozygous for a tandem duplication show nuclei in late zygotene-early pachytene in which the heteromorphic synaptonemal complex (SC) contains a lateral element that is buckled out into an unpaired loop as a consequence of the added length of the duplication (estimated in another study to be 21.7%, with breakpoints at 0.50 and 0.72 of the length of the chromosome). The ends of the buckle, marking the interstitial termini of synapsis proceeding from opposite directions, vary over a wide range of positions, but within limits: the proximal end of the loop does not exceed the distal end of the duplication segment, while the distal end of the loop does not lie closer to the kinetochore than the proximal end of the segment. Thus, synapsis (SC formation) at zygotene is restricted to homologous regions (exclusive homosynapsis). — In the last half of pachytene, no buckles are found, only simple SCs with lateral elements of equal length, as a consequence of synaptic adjustment. Intermediate stages of adjustment are found throughout the first half of pachytene. Shortly after homosynapsis is complete, synaptic adjustment begins: the ends of the duplication loop separate (desynapsis of homosynapsed regions); the long axis shortens with respect to the short axis in both the unpaired loop and in the SC portions; asymmetrical twists take up inequalities; the loop is reduced to from 1 to 3 asymmetrical twists; the axes (lateral elements) equalize as the long axis shortens; and a simple SC is formed, indistinguishable from others in the complement, in which the region of the duplication and those adjacent to it have heterosynapsed, while the distal regions of the SC are presumably still homosynapsed. Synaptic adjustment evidently involves two sequential events: localized instability of the homosynapsed condition, leading to desynapsis, then restoration of the SC by heterosynapsis. Adjustment therefore represents the loss of strict homosynapsis. It is concluded that the asymmetry produced by the duplication loop constitutes an instability that triggers synaptic adjustment.

Notes: Abstract. Antimitotic agents administered at the time of synapsis (leptotene/zygotene) have been shown to induce synaptic abnormalities visible during pachytene in the male mouse. The object of this study was to test the hypothesis that cells with relatively large amounts of colchicine-induced damage to the synaptonemal complex (SC) are eliminated from prophase whereas cells with relatively small amounts of SC damage proceed through to the end of prophase. Male mice were injected with tritiated thymidine to mark a cohort of spermatocytes at premeiotic S-phase for tracking through pachytene. Forty-eight hours later, when those cells were at leptotene/zygotene, colchicine was administered intratesticularly. Whole-mount SC spreads were made from animals sacrificed at various times following colchicine administration, and prepared for autoradiography. The marked cells were examined by light and electron microscopy and the kind and number of synaptic abnormalities were scored throughout pachytene. Colchicine-induced SC damage included single axial elements (univalents), together with partially synapsed and nonhomologously synapsed SCs. The amount of SC damage (amount and type per cell and frequency of cells with damage) scored at early pachytene exceeded by three- to fivefold the amount at late pachytene. This is consistent with spermatogenic cell loss from the seminiferous tubule via colchicine-induced destruction of Sertoli cell microtubules. The presence of spermatocytes with no more than four autosomal univalents at late pachytene indicates that some cells with low amounts of synaptic damage progress to the end of pachytene. The loss of the most severely damaged cells may represent a meiotic checkpoint at early pachytene in the male mouse.

Notes: Abstract Electron microscopy of surface-spread spermatocytes from mice heterozygous for a tandem duplication shows the heteromorphic synaptonemal complex (SC) to comprise two lateral elements of unequal length, the longer of which is buckled out in a characteristic loop, representing the unsynapsed portion of the duplication. The loop is a regular feature of late zygotene-early pachytene nuclei; it is longest at these early stages, but, through equalization of the two axes as a consequence of synaptic adjustment, it is replaced by a normal appearing SC at late pachytene. Because equalization, as indicated by a decrease in the percent difference between axes, may begin shortly after completion of synapsis, estimates of duplication segment length are restricted to a sample selected for least adjustment. — Although the mean position of the loop is constant at various pachytene substages, individual positions vary widely from cell to cell, consistent with the behavior expected of a duplication, but not of a deletion or an inversion. The length of the segment that is duplicated is estimated to be 22% of the normal chromosome, the midpoint of the segment is mapped at 0.61 of the chromosome distal to the kinetochore, and the ends of the segment are mapped at 0.50 to 0.72. Measurements of G-banded mitotic chromosomes give comparable values: duplication length, 24%; midpoint, 0.60, and segment ends, 0.48 and 0.71. This agreement constitutes further validation of the SC/spreading method for detecting and analyzing chromosomal rearrangements at pachytene and substantiates the fidelity with which the axes and SCs represent the behavior of chromosomes in synapsis.

Notes: Abstract Synaptonemal complex (SC) analysis by electron microscopy of spermatocytes in surface microspreads was carried out in mice heterozygous for two paracentric inversions: either In(1)1RK or In(2)5Rk. Characteristic SC inversion loops are formed at synapsis in bivalents carrying the rearrangements. Although all loops were observed to be eliminated by late pachytene through synaptic adjustment, every spermatocyte at early pachytene contained a fully synapsed loop. Cells in the earliest stage of pachytene contained the longest loops and thus had undergone minimal adjustment. The SC estimates of inversion lengths and breakpoint positions in such cells corresponded well with those from mitotic chromosome banding and could be correlated with genetic maps of chromosomes # 1 and # 2, thus demonstrating the basis for the mapping of pachytene chromosomes. The regularity of loop formation and reproducibility of the SC analysis are reflected in the constant relative positions of the estimated breakpoints. The method is sensitive enough to reflect small, real, interstitial length differences between meiotic and mitotic chromosomes. The results demonstrate the feasibility and precision of detection and quantitative characterization of inversions at early meiotic prophase by SC analysis.

Notes: Abstract In Psammomys obesus there is no pairing between the X and Y chromosomes and no chiasma formation (Solari and Ashley, 1977). It is demonstrated that ends of the axial elements of the X and Y chromosomes come together during pachytene, and regularly form at least one end-to-end junction. This achiasmatic physical connection between the ends of the X and Y persists until anaphase I, thus assuring the normal distribution of the sex chromosomes observed by light microscopy. In addition, there are no differentiations of the axes of the X and Y similar to those observed in other mammalian species thus far examined, a fact that could influence chromatid cohesiveness and disjunction.

Notes: Abstract Two paracentric inversions in the mouse, In(1)1 Rk and In(2)5 Rk, have been studied in surface microspreads of spermatocytes from heterozygotes. At zytogene, synaptic initiation occurs independently in three regions: within the inversion, and without, on either side. Synaptonemal complex (SC) formation is restricted to homologous regions, resulting in inversion loops in all early pachytene spermatocytes. An adjusting phase then occurs during pachytene in which the inversion loop is reduced by desynapsis of homologously synapsed SC, followed immediately by non-homologous synapsis with the alternate pairing partner, progressing from the ends toward the middle. Adjustment occurs during the first half of pachytene, but is not closely synchronized with sub-stage. It is complete by late pachytene, the loop having been eliminated in all cases and replaced by “straight” SCs in which the inverted region is heterosynapsed. Synapsis in the adjustment phase is evidently permitted only after the homosynaptic phase, and is indifferent to homology. It may lead to heterosynapsis, as in the inversion region, or to synapsis of homologous regions not synapsed at zytogene. The anaphase bridge frequency, a measure of crossing over within the inversion, is about 34% for both inversions studied, indicating that such crossovers do not block adjustment, that crossing over probably occurs before or during the adjustment period, and that there is some crossover suppression. The last could be the consequence of blocking by desynapsis/heterosynapsis. Synaptic adjustment appears to be a general phenomenon that occurs to varying extents in different forms. A hypothetical scheme for two phases of synapsis is proposed: at zytogene, a basic propensity for indifferent SC formation is limited by a restricting condition to synapsis between homologous regions. Subsequently, the restriction is lifted, whereupon synaptic instability is resolved by desynapsis, followed by resynapsis that is indifferent to homology, but that results in a topologically more stable structure.

Notes: Abstract Relative length is a constant and distinctive characteristic for each autosomal SC, despite variations in absolute length from cell to cell. Arm ratio is distinctive for each SC except for two of the three sub-acrocentrics, and serves, together with relative length, for identification. The constancy of relative length and arm ratios indicates biological stability and lack of physical distortion in these spread preparations. There is a 1∶1 relationship between relative lengths of autosomal SCs and mitotic autosomes; their arm ratios are also similar. These close parallels provide strikingly similar SC and somatic karyotypes. Variability was observed in sub-acrocentric arm ratios and in lengths of unpaired X and Y axes, correlated with the presence of constitutive heterochromatin. — Utilizing progressive differentiations of the X and Y chromosomes for staging, it is demonstrated that autosomal SCs decrease in length from late zygotene to mid-pachytene, and then increase at late pachytene. Within a nucleus, synchrony of length changes is maintained. It is concluded that the factors governing autosomal SC length are regular for any given bivalent from cell to cell, and may be related to those that control somatic autosome length relationships. — The X and Y axes differ quantitatively as well as qualitatively from autosomal SCs. The SC portion of the X and Y is constant in length through most of pachytene; the unpaired axes shorten and lengthen, but not in proportion to autosomal SCs. X and Y relative lengths and arm ratios vary throughout pachytene and do not maintain proportionality with somatic values. The evidence suggests, but does not prove, that the long arm of the X is paired with the short arm of the Y. — Twists occur in autosomal SCs at increasing frequencies throughout pachytene but cannot account for length changes. The number of twists per SC is directly proportional to SC length. Intertwining of SCs is random and proportional to SC length. End-to-end associations of autosomal SCs appear to be random; however, the ends of the X and Y are less often involved in such connections. — The length of axial material in all chromosomes at pachytene, expressed as an equivalent length of DNA double helix, represents 0.013% of the diploid DNA complement.

Notes: Abstract Synaptonemal complexes (SCs), X and Y axes, and various nucleolar structures stain preferentially with silver in surface microspread preparations and are analyzable by both light and electron microscopy. Central elements, kinetochore region material and nuclear annuli which stain with ethanolic phosphotungstic acid are seldom visible after silver staining. SCs can be characterized by length measurements equally well in light and electron micrographs, from which stages of pachytene can also be determined by differentiation of the axes of the XY pair. By electron microscopy, the lateral elements appear as single strands at zygotene and early pachytene, then become double in a plane perpendicular to that of the SC and appear denser and thicker until late pachytene when they become progressively more attenuated and again appear single. These transitions are difficult to explain in terms of separation of associated chromatids. Identification of various silver stained bodies as nucleoli is supported by their orange-red fluorescence with acridine orange. SCs, X and Y axes and associated sex body material are, with a few exceptions, virtually indistinguishable from the background yellow-green fluorescence of the chromatin. Comet-shaped nucleolar bodies are regularly associated with five (in one animal) or six (in two animals) SCs; their positions along particular SCs identifiable by relative lengths indicate these bodies to be expressions of nucleolus organizer regions. They first appear at leptotene in association with unpaired axes and undergo progressive changes through late pachytene, at which time they redistribute their contents coincident with disappearance of the SCs. A characteristic nucleolar double dense body appears at zygotene; unlike the comet-shaped nucleoli, it is unassociated with other nuclear structures, and is assumed to arise from coalescence of previously existing smaller dense bodies. — The silver staining method described is remarkable for the speed and simplicity with which large numbers of spermatocyte nuclei are obtainable for light and electron microscopy. The fidelity of the light microscopic counterpart of the electron microscopic image has been directly assessed at different stages of pachytene. For cytogenetic analysis, critical information often lies beyond the limits of light optical resolution; the correlated electron microscopy required for verification is easily obtained with this method.

Notes: Abstract Pairing of pachytene chromosomes was studied in oocytes and spermatocytes of mice heterozygous for the male-sterile Is(7;1)40H insertion using light and electron microscopy for synaptonemal complex analysis in surface-spread, silver-stained preparations. The data comprised four males and four female embryos. The insertion/deletion configurations appeared as either two bivalents or one quadrivalent in both sexes, but the proportion of bivalents was higher in oocytes. Some insertion and deletion bivalents showed synaptic adjustment. The insertion/deletion configurations were associated with, or adjacent to, the XY bivalent in the majority of spermatocytes. End-to-end association of different bivalents was more frequent in oocytes than in spermatocytes. It is suggested that physiological differences between male and female gametocytes may lead to the difference in their reproductive potential.