Deficiency of X and Y chromosomal pairing at meiotic prophase in spermatocytes of sterile interspecific hybrids between laboratory mice (Mus domesticus) and Mus spretus

The normal association between the X and Y chromosomes at metaphase I of meiosis, as seen in air-dried light microscope preparations of mouse spermatocytes, is frequently lacking in the spermatocytes of the sterile interspecific hybrid between the laboratory mouse strains C57BL/6 and Mus spretus. The purpose of this work is to determine whether the separate X and Y chromosomes in the hybrid are asynaptic, caused by failure to pair, or desynaptic, caused by precocious dissociation. Unpaired X-Y chromosomes were observed in air-dried preparations at diakinesis, just prior to metaphase I. Furthermore, immunocytology and electron microscopy studies of surface-spread pachytene spermatocytes indicate that the X and Y chromosomes frequently fail to initiate synapsis as judged by the failure to form a synaptonemal complex between the pairing regions of the X and Y Chromosomes. Several additional chromosomal abnormalities were observed in the hybrid. These include fold-backs of the unpaired X or Y cores, associations between the autosome and sex chromosome cores, and autosomal univalents. The occurrence of abnormal autosomal and XY-autosomal associations was also correlated with cell degeneration during meiotic prophase. The primary breakdown in hybrid spermatogenesis occurs at metaphase I (MI), with the appearance of degenerated cells at late MI. In those cells, the X and Y are decondensed rather than condensed as they are in normal mouse MI spermatocytes. These results, in combination with the previous genetic analysis of spermatogenesis in hybrids and backcrosses with fertile female hybrids, suggest that the spermatogenic breakdown in the interspecific hybrid is primarily correlated with the failure of XY pairing at meiotic prophase, asynapsis, followed by the degeneration of spermatocytes at metaphase I. Secondarily, the failure of XY pairing can be accompanied by failure of autosomal pairing, which appears to involve an abnormal sex vesicle and degeneration at pachytene or diplotene.by C. Heyting     

The binding of ATP to the catalytic and the regulatory site of Ca2+,Mg2+-dependent ATPase of the sarcoplasmic reticulum

Two kinds of ATP binding sites were found on the ATPase molecule in deoxycholic acid-treated sarcoplasmic reticulum. One was the catalytic site (1 mol/mol active site) and its affinity was high. Upon addition of Ca²⁺, all the ATP bound to the catalytic site disappeared at 75 mM KCl, while a significant amount of ATP remained bound to the site at 0–2 mM KCl. The latter binding was found to be due to the formation of a slowly exchanging enzyme-ATP complex, which is in equilibrium with phosphoenzyme + ADP. The other binding site was the regulatory one (1 mol/mol active site) and its affinity was low, changing only insignificantly upon addition of Ca²⁺. The ATP binding to the regulatory site shifted the equilibrium between the slowly exchanging complex and EP toward EP.     

An anchorage-dependent locus in the cell cycle for the growth of 3T3 cells

Mouse fibroblasts, 3T3 cells, require a solid surface for continuous growth, but when 3T3 cells, during their exponential phase in Petri dishes, were transferred to a suspension culture, the number of cells roughly doubled by 30 h. During the suspension culture the number of pairing cells (c₂) increased, but that of the single cells decreased. When cells synchronized at mitosis or at the G1-S boundary were transferred to the suspension culture, the number of pairing cells peaked at 30 min and at 10 h, respectively. DNA synthesis began immediately after the cells, which were cultured for 16 h in the suspension, had settled onto the surface of the Petri dishes. When cells in a confluent culture were arrested at an early G1 period and were suspended, the number of pairing cells did not increase. These results indicate that the most important locus for anchorage growth seems to be at a late G1 period of the cell cycle.     

A non-destructive screenable marker,OsFAST, for identifying transgenic rice seeds

The production of transgenic plants has contributed greatly to plant research. Previously, an improved method for screening transgenic Arabidopsis thaliana seeds using the FAST (Fluorescence-Accumulating-Seed Technology) method and FAST marker was reported. Arabidopsis seeds containing the FAST marker may be visually screened using a fluorescence stereomicroscope or blue LED handy-type instrument. Although the FAST method was originally designed for Arabidopsis screens, this study endeavors to adapt this method for the screening of other plants. Here, an optimized technology, designated the OsFAST method, is presented as a useful tool for screening transgenic rice seeds. The OsFAST method is based on the expression of the OsFAST-G marker under the control of a seed-embryo-specific promoter, similar to the Arabidopsis FAST-G marker. The OsFAST method provides a simple and non-destructive method for identifying transgenic rice seeds. It is proposed that the FAST method is adaptable to various plant species and will enable a deeper analysis of the floral-dip method.Key words: Oryza sativa, oleosin, seed, green fluorescent protein, transformation, screenable markerThe production of transgenic plants has significantly enhanced many areas of plant science research. Antibiotic/herbicide-resistance genes are traditionally used as screenable markers for the selection of transgenic plants. However, this approach does have disadvantages. First, antibiotics or herbicides occasionally inhibit the growth of transgenic plants, regardless of the incorporation of antibiotic- or herbicide-resistance genes¹ into the transgenic plants. Second, the identification of resistant transgenic plants requires that the seed population be sown onto plates containing antibiotics or herbicides. Third, the selection process is slow and labor intensive, often involving the screening of vast numbers of potentially transgenic seeds on selective plates.To overcome these disadvantages, an improved approach for selecting transgenic Arabidopsis thaliana, designated the FAST (Fluorescence-Accumulating-Seed Technology) method, was developed. This method employs the use of a fluorescent protein that is expressed in seeds and used as a visual screenable marker for the identification of transgenic seeds. The seed-specific protein oleosin, a family of oil-body-membrane proteins,² has an important role as a size regulator of oil bodies.³ AtOLE1, the most abundant oleosin, functions in the freezing tolerance of Arabidopsis seeds.⁴ A plasmid containing an AtOLE1-GFP fusion gene controlled by the AtOLE1 promoter was constructed and designated the FAST-G (Fluorescence-Accumulating-Seed Technology with OLE1-GFP) marker. Interestingly, Arabidopsis seeds containing the FAST-G marker emitted clear fluorescence under a fluorescence stereomicroscope or blue LED handy-type instrument. The transgenic seeds were visually identified by the seed fluorescence without the use of antibiotics or herbicides, thus indicating that the FAST method offers a nondestructive approach. The FAST marker permits the identification of homozygous seeds among the T2 population with a false discovery rate of less than 1% as a co-dominant screenable marker. In contrast to conventional methods using antibiotics or herbicides, the FAST method reduces the amount of time required to acquire homozygous transgenic plants from 7.5 months to 4 months. The fluorescence of the FAST-G marker was limited to a specific organ (i.e., in seeds) and a specific time (i.e., during dormancy), desirable characteristics of selectable and/or screenable markers. Furthermore, the FAST marker does not require sterile seeding and the handling of large numbers of plants.     

Phosphorylation on tyrosine-15 of p34(Cdc2) by ErbB2 inhibits p34(Cdc2) activation and is involved in resistance to taxol-induced apoptosis

ErbB2 overexpression confers resistance to taxol-induced apoptosis by inhibiting p34(Cdc2) activation. One mechanism is via ErbB2-mediated upregulation of p21(Cip1), which inhibits Cdc2. Here, we report that the inhibitory phosphorylation on Cdc2 tyrosine (Y)15 (Cdc2-Y15-p) is elevated in ErbB2-overexpressing breast cancer cells and primary tumors. ErbB2 binds to and colocalizes with cyclin B-Cdc2 complexes and phosphorylates Cdc2-Y15. The ErbB2 kinase domain is sufficient to directly phosphorylate Cdc2-Y15. Increased Cdc2-Y15-p in ErbB2-overexpressing cells corresponds with delayed M phase entry. Expressing a nonphosphorylatable mutant of Cdc2 renders cells more sensitive to taxol-induced apoptosis. Thus, ErbB2 membrane RTK can confer resistance to taxol-induced apoptosis by directly phosphorylating Cdc2.     

K-ras Gene Mutation Related to Histological Atypias in Human Colorectal Adenomas

To investigate the relationship of oncogene analysis to morphology, we analyzed K-ras gene mutations by dot-blot hybridization with and without consideration of histological atypias in individual colorectal adenomas. Each of 54 colon polyps were divided into two parts after fixation. One part was used as a mass to assess point mutations; the remaining portion of each polyp was paraffin-embedded, stained with hematoxylin and eosin, and examined for point mutations related to histological atypias. In the first part of our study, K-ras gene mutations at codon 12 were detected in 13 cases (24%). In the second part of our study, 12 cases had distinctly different histological atypias. From each of these 12 cases, two areas, one with higher or one with lower grade atypia in the same polyp were excised to analyze for K-ras gene mutation. Two of these 12 cases (17%) had the mutation in different areas of the same tumor. These two cases contained the mutation only in the areas with higher grade atypia, and only one case added information regarding ras mutation upon microdissection when compared to the entire biopsy. These results suggest that oligonucleotide hybridization can identify the majority of cases containing ras mutations despite regional morphologic variation. Individual cases, however, may contain clonal subpopulations within adenomas with different ras sequences from other regions within the same adenoma.     

Foam fractionation of protein: correlation of protein adsorption onto bubbles with a pH-induced conformational transition

A foam fractionation apparatus was prepared to aid protein separation at the gas–liquid interface. Using lysozyme as a model protein, we investigated the alteration of enzymatic and optical activities through foaming. The lysozyme transferred to the gaseous nitrogen phase after 5 min of bubbling with no exogenous detergent. The bacteriolytic and optical activities of lysozyme from the foamate were nearly equivalent to those of the original lysozyme. This result indicated that lysozyme did not irreversibly denature during foam fractionation. We then performed protein separation using binary mixtures of lysozyme and α-amylase. When the two proteins were dissolved in bulk solution of pH 10.5, which is close to the isoelectric point (pI) of lysozyme (10.7), selective fractionation of lysozyme from the foam was observed. Indeed, this fractionation was identical to that from a single component solution of lysozyme. Similarly, selective fractionation of α-amylase was achieved in pH 3.0 buffer. Furthermore, circular dichroism (CD) and subsequent model fitting revealed that the protein had a reduced or nearly complete absence of α-helical content, whereas the amount of β-sheet structure and random coil was elevated in the buffer conditions that promoted protein adsorption. These results indicate that a pH-induced conformational transition might correlate with protein foaming.     

Development and characterization of EST‐SSR markers for the genus Rhododendron section Brachycalyx (Ericaceae)

Simple sequence repeat (SSR) markers were developed from expressed sequence tags (ESTs) for Rhododendron section Brachycalyx in order to elucidate its evolutionary processes and reproductive ecology. Nineteen polymorphic EST‐SSR markers were developed from EST libraries of R. amagianum and R. hyugaense. Polymorphisms for these markers were assessed using four species of section Brachycalyx. The number of alleles ranged from 1 to 14, and the observed and expected heterozygosity ranged from 0.000 to 0.931 and 0.000 to 0.904, respectively. The EST‐SSR markers developed in this study will be useful for elucidating population genetic structure and breeding systems in section Brachycalyx.