Susumu Takayama

Differential giemsa staining of sister chromatids after extraction with acids

Chromosomes of Chinese hamster strain cells were air-dried on slides after BrdU substitution for two or three rounds of replication. The preparations were treated with 20% PCA at 55° C for 20–30 min, or 5N HCl at 55° C for 15–20 min. After staining with Giemsa, unifilarly BrdU-substituted chromatids stained faintly and bifilarly substituted chromatids stained darkly. Such a pattern of sister chromatid differential staining was confirmed by the examination of metaphase cells grown with BrdU for three rounds of replication.

Interchromosomal connectives in squash preparations of L cells

Abstract Prominent chromosomal connecting fibers were observed by light microscopy. Preparations were usually made by squashing colchicine-treated L cells together with Giemsa stain after hypotonic treatment without fixation. The connectives were also observed in preparations from which either the colchicine treatment or the hypotonic treatment, or even both, were omitted. Most of the prominent connecting fibers were interchromosomal, but interchromatid connectives also occurred. No fibrous structures were observed at the kinetochore regions.

High-order structure of metaphase chromosomes: evidence for a multiple coiling model

When chromosome preparations made by the conventional air-drying method were processed with the OsO4/TCH technique and examined by scanning electron microscopy (SEM), spiral structures in chromatids, which have been frequently observed to be present by light microscopy, were found to be composed of 30 nm fibres. In some portions these fibres appeared to be arranged in coils to form thicker fibres. When chromosome preparations were processed for SEM without air drying, chromosomes appeared to consist of fairly homogeneous thick fibrous structures measuring about 200 nm in diameter. In relatively condensed chromosomes, these 200 nm fibres appeared to be arranged perpendicular to the long axis of the chromatid. These findings suggest that chromatid spiral structures represent a regularly loosened state of the compactly spiralized 200 nm fibres which in turn consist of spiralized 30 nm fibres.

Configurational changes in chromatids from helical to banded structures

Induction of configurational changes in the helical chromatids of air dried chromosomes was used to explore the mechanism of G-banding. From the water-Giemsa stained metaphase spreads of Chinese hamster cells, chromosomes having clearly helical chromatids were selected and photographed. Then the chromosomes were decolorized, treated with trypsin, and restained with saline-Giemsa (1 x SSC). Such procedures were repeatedly carried out upon the same chromosomes. Subsequent examination of the chromosomes showed that configurational changes from a helical structure to a banded structure had occurred. Some chromosomes revealed a variety of transitional changes between these two configurations. During the repeated G-banding treatments, the distances between bands along the same chromatids changed each time. The results obtained seem to indicate that the G-banding results from locally induced compaction of chromosomal materials along the chromatids.

Two opposite types of sister chromatid differential staining in BUdR-substituted chromosomes using tetrasodium salt of EDTA

Abstract The direct staining of BUdR-substituted Chinese hamster chromosomes in a 4Na-EDTA-Giemsa solution resulted in a B-dark type of sister chromatid differential staining (SCD) in which bifilarly substituted chromatids stained dark. On the other hand, when BUdR-substituted chromosomes were pretreated with a 4Na-EDTA solution and then stained with Giemsa, a B-light type SCD was obtained in which bifilarly substituted chromatids stained light.

Analysis of the replication mode of double minutes using the PCC technique combined with BrdUrd labeling

A cultured line of neuroblastoma cells (NB) was found to contain double minute chromosomes (DMs). DMs have been reported to be acentric and, therefore, to be segregated randomly into daughter cells without separating their sister elements. When NB cells were fused with Chinese hamster metaphase cells, prematurely condensed chromosomes (PCCs) were induced. DMs seen together with G2 PCCs appeared to be closely paired, dot-like structures resembling DMs observable in metaphase cells. In contrast, DMs in G1 cells showed a tendency to become single as the stage progressed so that the majority of DMs in late G1 cells were actually no longer double. DMs in S-phase cells, however, again appeared double. These results clearly indicate why DMs are invariably double and never assume a quadruple configuration in metaphase cells in spite of their non-disjunctional segregation at anaphase. Such a characteristic mode of DM replication was further confirmed by a 5-bromo-2′-deoxyuridine (BrdUrd) labeling experiment: when NB cells were exposed to BrdUrd for two successive rounds of DNA replication prior to PCC induction, half of the resulting single G1 minutes as well as G1 PCCs stained dark and the other half stained light after staining for sister chromatid differentiation.

Effects of bromodeoxyuridine substitution on metaphase chromosome structures examined by scanning electron microscopy

Chinese hamster chromosomes were differentially substituted with 50 μM 5-bromodeoxyuridine (BrdU) to obtain chromosomes with bifilarly and unifilarly substituted (BB-TB) and unifilarly and non-substituted (TB-TT) chromatid constitutions. To avoid the effect of Giemsa staining on the ultrastructure of chromosomes, unstained preparations were exclusively used. When TB-TT chromosomes were prepared with the conventional air-drying method followed by the osmium tetroxide-thiocarbohydrazide (OsO4-TCH) technique and examined by scanning electron microscopy (SEM), the TB-chromatid appeared somewhat more slender and showed more conspicuous spiral structures, thereby appearing more loosened compared to the TT-chromatid. At higher magnifications, however, 30 nm chromatin fibres which were seen to constitute both chromatids showed no discernible differences in dimension between the TT- and TB-chromatids. On the other hand, TB-TT chromosomes specially prepared for SEM without the process of air-drying appeared in their entirety less extended and no spiral configuration was observed even in the TB-chromatid. The TB-chromatid instead appeared rather less loosened than the TT-chromatid whereas thick fibre-like structures which in turn seemed to consist of 30 nm fibres were more easily discernible in the TT-chromatid compared to the TB. Such seemingly contradictory results obtained from the two different preparatory procedures were tentatively explained on the basis of our multiple coiling model (Taniguchi and Takayama 1986).

G-band-like structures and centromeric asymmetry in the BrdU containing mouse chromosomes

Mouse cells cultured in the presence of BrdU or BrdC for one replication cycle were stained in a 4Na-EDTA Giemsa solution which stains BrdU-containing chromatin preferentially (Takayama and Tachibana, 1980). With this treatment clear bands (B-bands) were revealed along the length of the chromosomes. The B-banding patterns were identical with the G-banding patterns of this species except for the centromeric region in which lateral asymmetry of Giemsa staining was seen. The concomitant occurrence of the lateral asymmetry with the B-banding supports the assumption that the B-bands visualized by the present technique reflect the BrdU-rich chromatin regions differentially localized along the chromosomes. Most of the chromosomes constituting the mouse karyotype showed their own characteristic appearance of the asymmetry, but in some of them the asymmetry was not clear and the Y did not show any specific, centromeric staining. The marked coincidence of the B- and G-banding patterns seems to provide evidence for the involvement of AT-rich chromatin in the induction of positive G-bands. The present technique also seems quite useful to analyze chromosomes of some species in which ordinary G-banding techniques have been known to bring about only unsatisfactory results.

Reverse differential staining of sister chromatids after substitution with BUdR and incubation in sodium phosphate solution

Abstract Chinese hamster strain cells were cultured in the presence of BUdR and air-dried on slides. The chromosome preparations were incubated in 1 M NaH2PO4 at 88 °C for 4–6 min and stained with Giemsa. The reverse type of sister chromatid differential staining occurred, in which unifilarly BUdR-substituted chromatids stained faintly and bifilarly substituted chromatids stained darkly. Feulgen reaction performed on the same chromosomes after removing Giemsa stain showed the same type of differential staining.

Scanning electron microscopy of the centromeric region of L-cell chromosomes after treatment with Hoechst 33258 combined with 5-bromodeoxyuridine

When mouse L-cells were treated with a combination of 5-bromodeoxyuridine (BrdUrd) and Hoechst 33258, the metaphase chromosomes revealed undercondensation of the chromatin fibers in the sister centromeres. The application of the osmium-thiocarbohydrazide technique to the air-dried chromosome preparations made it possible to elucidate the ultrastructure of the undercondensed centromeric region at the level of the 30 nm chromatin fiber. Scanning electron microscopy revealed that the undercondensed region consisted of a coiled fiber with a diameter of about 400 nm, and a gyre diameter of approximately 600 nm. The coiled fiber was composed of the 30 nm chromatin fiber loops. These findings indicate that a continuous coiled structure, which is the final higher order structure of the condensed chromatin fiber, exists throughout the entire length of the mouse L-cell metaphase chromosome.