ABA-regulated promoter activity in stomatal guard cells

CDeT6-19 is an ABA-regulated gene which has been isolated from Craterostigma plantagineum . The CDeT6-19 gene promoter has been fused to the β- glucuronidase reporter gene ( GUS ) and used to stably transform Arabidopsis thaliana and Nicotiana tabacum . This construct has been shown to be expressed in stomatal guard cells and often in the adjacent epidermal cells of both species in response to both exogenous ABA and drought stress. These results indicate that the stomatal guard cell is competent to relay an ABA signal to the nucleus. In contrast GUS expression directed by the promoter from a predominantly seed-specific, ABA-regulated gene, Em , or the promoter from the ABA-regulated CDeT27-45 gene is not detectable in the epidermal or guard cells of tobacco or Arabidopsis in response to ABA. The fact that not all ABA-regulated gene promoters are active in stomatal guard cells suggests that effective transduction of the signal is dependent upon particular regions within the gene promoter or that guard cells lack all or part of the specific transduction apparatus required to couple the ABA signal to these promoters. This suggests that there are multiple ABA stimulus response coupling pathways. The identification of a regulatory sequence from an ABA-induced gene which is expressed in stomatal guard cells creates the possibility of examining the role of Ca²⁺ and other second messengers in ABA-induced gene expression.     

The absorption, translocation and distribution of the herbicide glyphosate in maize expressing the CP-4 transgene

Maize (Zea mays L. var. Bonnie) transformed with a gene encoding a 5-enolpyruvylshikimate 3-phosphate synthase with altered sensitivity showed over 100-fold greater resistance to the herbicide glyphosate (N-[phosphonomethyl]glycine) in comparison with its non-transformed progenitor (parental control) at the third-leaf stage. Studies with [¹⁴C]-glyphosate at a dosage lethal to the parental control, but sublethal to the transgenic, revealed that a maximum of 45-65% of the applied dose was absorbed, with greater absorption occurring in transgenic plants. Translocation of glyphosate was closely related to its absorption (r value 0.956) with approximately 15% more of the applied dose being mobilized in transgenic plants than the parental controls. Analysis of electronic autoradiograms along the treated leaf lamina found discrete internal regions of glyphosate accumulation closely associated with the site of application. These regions contained lower amounts of glyphosate present in the treated leaf lamina was almost completely translocated in transgenic plants, while in the parental controls more remained and the leaf became necrotic. In both types of maize there was a small accumulation of herbicide in the tip region of the leaf which was not mobilized. Younger shoot tissues and roots were major sinks for translocated glyphosate accumulating approximately 25-40% of the applied dose depending upon treatment. In the parental control, equal amounts of glyphosate were found distributed between young shoot tissues and roots; while in transgenic plants, the young shoot tissue accumulated around three times more glyphosate than the roots. In both plant types, glyphosate was localized in the meristems and young, actively growing leaves. Specific glyphosate activity (the amount of glyphosate per unit dry weight of tissue) in the major sinks of the transgenic declined towards the end of the treatment period but remained relatively constant in the parental control. In conclusion, enhancing glyphosate resistance by genetic transformation influenced the absorption, translocation and distribution of this herbicide in whole plants.Keywords: Zea mays, glyphosate (N-[phosphonomethyl]-glycine), transgenic, absorption, translocation, source-sink.      

Experimental Test of Connector Rotation during DNA Packaging into Bacteriophage ϕ29 Capsids

The bacteriophage ϕ29 generates large forces to compact its double-stranded DNA genome into a protein capsid by means of a portal motor complex. Several mechanical models for the generation of these high forces by the motor complex predict coupling of DNA translocation to rotation of the head-tail connector dodecamer. Putative connector rotation is investigated here by combining the methods of single-molecule force spectroscopy with polarization-sensitive single-molecule fluorescence. In our experiment, we observe motor function in several packaging complexes in parallel using video microscopy of bead position in a magnetic trap. At the same time, we follow the orientation of single fluorophores attached to the portal motor connector. From our data, we can exclude connector rotation with greater than 99% probability and therefore answer a long-standing mechanistic question.     

Histochemical studies on the amphibian opercularis muscle (Amphibia)

Summary Histochemical studies of the opercularis muscle of the bullfrog (Rana catesbeiana) and the tiger salamander (Ambystoma tigrinum) provide evidence that the opercularis muscle of anurans is a specialized, tonic portion of the levator scapulae superior muscle. Staining results for myosin adenosine triphosphatase (ATPase) and succinate dehydrogenase (SDH), combined with measurements of muscle fiber diameters, demonstrate that the opercularis/levator scapulae superior muscle mass of both the tiger salamander and bullfrog consists of an anterior tonic portion, a middle fast oxidative-glycolytic (FOG) twitch portion, and a posterior fast-glycolytic (FG) twitch portion. In R. catesbeiana the tonic fibers represent 57.3% of the fiber total and (because they have relatively narrow diameters) about 29% of the cross-sectional area of the muscle mass, and form that part of the muscle (=opercularis muscle) that inserts on the operculum. In Ambystoma the tonic fibers represent only 8.8% of the fiber total and represent about 4% of the cross-sectional area. In the tiger salamander, the entire levator scapulae superior muscle inserts on the operculum and therefore represents the opercularis muscle. The bullfrog differs from the tiger salamander, therefore, in that the anterior tonic part of the opercularis/levator scapulae superior complex is greatly enlarged and the insertion on the operculum is limited to these tonic fibers. No evidence of a columellar muscle was found in R. catesbeiana. Previous reports of one in this species and in other anurans may be based on the tripartite nature of the opercularis/levator scapulae superior muscle mass. The middle FOG portion of the muscle may have been considered a muscle distinct from the anterior tonic portion (=opercularis muscle) and the posterior FG portion.