玉米花粉单倍体植株染色体上异染色质的变异

我们用Giemsa BSG C-带技术检查了玉米花药培养获得的花粉单倍体植株根尖细胞染色体上异染色质的变异,观察结果表明,有的植株所显示的C-带数目是与供体植株的相一致,有的植株所显示的C-带数目则发生了显著变化,其中有的增加,有的减少。并讨论了异染色质发生变异的可能原因。还相应地观察到间期核中染色中心的变化是与中期染色体上C-带数目的变化相一致。     

点叶绵枣叶片培养及器官分化的研究

点叶绵枣叶外植体培养于MS 6-BA 1 PPm IBA 0.5 ppm培养基中,一月后不定芽仅从近轴面的叶表面产生。组织学的观察表明,不定芽起源于表皮细胞。     

Properties of a pentapeptide inhibitor of peptidyltransferase that is essential for cat gene regulation by translation attenuation.

Inducible chloramphenicol resistance genes cat and cmlA are regulated by translation attenuation. For both genes, the leader codons that must be translated to deliver a ribosome to the induction site specify a peptide that inhibits peptidyltransferase in vitro. The antipeptidyltransferase activity of the peptides is thought to select the site of ribosome stalling that is essential for induction. Using variations of the cat-86 leader-encoded 5-mer peptide MVKTD, we demonstrate a correlation between the in vitro antipeptidyltransferase activity and the ability of the same peptide to support induction by chloramphenicol in vivo. MVKTD footprints to nucleotides 2058, 2059, and 2060 in 23S rRNA. In vivo methylation of nucleotide 2058 by the ermC methylase interferes neither with cat-86 induction nor with peptide inhibition of peptidyltransferase. The methylation eliminates the competition that normally occurs in vitro between erythromycin and MVKTD. MVKTD inhibits the peptidyltransferase of several eubacteria, a representative Archaea species, and the eukaryote Saccharomyces cerevisiae. Bacillus stearothermophilus supports the in vivo induction of cat-86, and the RNA that is phenol extracted from the 50S ribosomes of this gram-positive thermophile is catalytically active in the peptidyltransferase assay and sensitive to peptide inhibition. Our results indicate that peptidyltransferase inhibition by a cat leader peptide is essential to induction, and this activity can be altered by minor changes in the amino acid sequence of the peptide. The broad range of organisms shown to possess peptide-inhibitable peptidyltransferase suggests that the target is a highly conserved component of the ribosome and includes 23S rRNA.     

Molecular map of Chromosome 19 including three genes affecting bleeding time: ep,ru, and bm

The mouse ruby eye (ru) and pale ear (ep) pigment dilution genes cause platelet storage pool deficiency (SPD) and prolonged bleeding times. The brachymorphic (bm) gene, in addition to causing skeletal abnormalities, is also associated with prolonged bleeding times. All three hemorrhagic genes are found within 10 cM on Chromosome (Chr) 19. In this study, 15 microsatellite markers and five cDNAs, spanning 21 cM of Chr 19, were mapped in relation to the bm, ep, and ru genes in 457 progeny of an interspecific backcross utilizing the highly inbred strain PWK derived from the Mus musculus musculus species. Several markers were found to be closely linked to the three genes and should be useful as entry points in their eventual molecular identification.     

Elevated ozone decreases the multifunctionality of belowground ecosystems

Elevated tropospheric ozone (O₃) affects the allocation of biomass aboveground and belowground and influences terrestrial ecosystem functions. However, how belowground functions respond to elevated O₃ concentrations ([O₃]) remains unclear at the global scale. Here, we conducted a detailed synthesis of belowground functioning responses to elevated [O₃] by performing a meta-analysis of 2395 paired observations from 222 publications. We found that elevated [O₃] significantly reduced the primary productivity of roots by 19.8%, 16.3%, and 26.9% for crops, trees and grasses, respectively. Elevated [O₃] strongly decreased the root/shoot ratio by 11.3% for crops and by 4.9% for trees, which indicated that roots were highly sensitive to O₃. Elevated [O₃] impacted carbon and nitrogen cycling in croplands, as evidenced by decreased dissolved organic carbon, microbial biomass carbon, total soil nitrogen, ammonium nitrogen, microbial biomass nitrogen, and nitrification rates in association with increased nitrate nitrogen and denitrification rates. Elevated [O₃] significantly decreased fungal phospholipid fatty acids in croplands, which suggested that O₃ altered the microbial community and composition. The responses of belowground functions to elevated [O₃] were modified by experimental methods, root environments, and additional global change factors. Therefore, these factors should be considered to avoid the underestimation or overestimation of the impacts of elevated [O₃] on belowground functioning. The significant negative relationships between O₃-treated intensity and the multifunctionality index for croplands, forests, and grasslands implied that elevated [O₃] decreases belowground ecosystem multifunctionality.