Genetic diversity of <Emphasis Type="Italic">Magnolia ashei</Emphasis> characterized by SSR markers

The Ashe magnolia (Magnolia ashei) is a deciduous small tree most noted for its large 1–2 foot long leaves and fragrant creamy white flowers. Although the species is adapted to and used in landscapes in many parts of the U.S., it is endemic only to Northwest Florida where it is limited to ten counties growing on undisturbed bluffs and ravine banks. The populations are highly fragmented and are threatened by degradation of habitat, leading the species to be listed as endangered in the state of Florida. SSR markers were developed to determine the genetic diversity of wild populations of M. ashei in order to guide long-term conservation strategies. 18 marker loci identified a total of 82 alleles that were used to characterize allelic diversity of M. ashei from 11 wild populations, 14 cultivated sources, five accessions of M. macrophylla, and three interspecific hybrids. Results indicated a higher than expected level of heterozygosity within populations, and a clear distinction between Eastern and Western populations; conservation efforts should therefore focus on maintaining these distinct groups in corresponding ex situ seed orchards to counteract pressures due to overcollection, pollution, and loss of habitat due to development. Clustering of individuals was similar using several analytical methods, indicating that despite relatively small sample sizes, our analysis is a valid reflection of the diversity among and relationships between these populations.     

Radial transport of ions in roots

Measurements were made of the relative amounts of ⁸⁶Rb, ³⁶Cl, and ³²P accumulated in the cortex and stele of intact roots of corn (Zea mays), either detached or attached to their shoots. Both 4- and 7-day-old roots accumulated as much or more ⁸⁶Rb in the stele as in the cortex. In experiments with ³⁶Cl, cortex and stele accumulated the same amount, except for 4-day-old and 7-day-old attached roots, in which the cortex contained more ³⁶Cl than the stele after 23 hr. An additional study of ³²P uptake showed greater accumulation in the cortex than the stele for a short period of time, but as much in the stele as in the cortex after 8 to 24 hr. Transport of ⁸⁶Rb, ³⁶Cl, and ³²P into the xylem exudate increased with increasing accumulation of these ions in stele and cortex of the root. These experiments show no consistent difference between cortex and stele of intact corn roots with respect to their ability to accumulate several kinds of ions.     

Ficin-Catalyzed Reactions. Hydrolysis of alpha-N-Benzoyl-l-Arginine Ethyl Ester and alpha-N-Benzoyl-l-Argininamide

The effect of pH on the hydrolysis of α-N-benzoyl-l-arginine ethyl ester (BAEE) and α-N-benzoyl-l-argininamide (BAA) by a proteolytic enzyme component purified from Ficus carica var. Kadota latex has been studied in detail over the pH range of 3 to 9.5. k_cat (lim) values for the hydrolysis of BAEE and BAA were essentially identical (5.20 and 5.01 sec⁻¹, respectively at 30°). k_cat values for hydrolysis of BAEE and BAA were dependent on prototropic groups with apparent pK values of 4.24 and 8.53 and 4.10 and 8.59, respectively. k_cat (lim) values for tht hydrolysis of BAEE and BAA were essentially identical (5.20 and groups of pK 4.33 and 8.60 and 4.55 and 8.51, respectively. Thus the pH optimum is 6.5 for both substrates. K_m (app) values for BAEE and BAA were 3.32 × 10⁻²m and 6.03 × 10⁻²m respectively over the pH range of 3.9 to 8.0. These data are interpreted in terms of the involvement of a carboxyl and a sulfhydryl group in the active center of the enzyme. The data do not support the concept that deacylation of the acyl-enzyme is completely the rate controlling step in the hydrolyses. Rather, it appears that the magnitude of k₂ and k₃ are not greatly different.     

Considering ploidy when producing and using mixed‐source native plant materials for restoration

There is a clear need to maximize the genetic diversity of plant material used in restorations to ensure restored populations are equipped to handle current and future conditions. This increasingly translates to focused efforts to intentionally increase the genetic diversity of seed sources in production and/or restoration settings. For example, multiple populations may be brought together to create plant materials with more genetic diversity than is present in any single population. Recent literature showing minimal risk of outbreeding depression and extensive benefits of genetic rescue has helped justify this approach, with the exception of mixing populations with fixed chromosomal differences. In these cases, extensive loss of fertility may occur after mixing. Some types of incompatible chromosomal differences are difficult to detect and therefore have unknown occurrence and distribution within and among species. However, the most extreme form of chromosomal differences—intraspecific ploidy variation (IPV)—is relatively easy to quantify with current technology and known to be fairly common in angiosperms. To encourage more systematic consideration of IPV in native plant restoration, we used available data on IPV to estimate its incidence in 115 species widely used for restoration in the United States. Over one‐third have IPV. Additional focused research is needed to understand the consequences of IPV for restoration, particularly given the current trend toward mixing natural collections for materials development and use. We provide recommendations to explicitly incorporate the reality of IPV into the production and use of genetically diverse plant materials for restoration.     

Preliminary evaluation of non-native rainbow trout (Oncorhynchus mykiss) impact on the Cederberg ghost frog (Heleophryne depressa) in South Africa’s Cape Fold Ecoregion

We evaluated the impact of non-native rainbow trout Oncorhynchus mykiss on a population of endemic Cedarberg ghost frog Heleophryne depressa in the upper Krom River (Olifants-Doring River Catchment, Cape Fold Ecoregion). We compared H. depressa abundance (using kick-sampling and underwater video analysis) and environmental conditions between sites above and below a waterfall that marks the upper distribution limit of O. mykiss. Heleophryne depressa abundance was significantly greater above the waterfall than that below it, and, because there was no significant difference in measured environmental variables, O. mykiss presence is identified as the most likely explanation for the observed decrease in H. depressa abundance.     

Evidence that U5 snRNP recognizes the 3' splice site for catalytic step II in mammals.

The first AG dinucleotide downstream from the branchpoint sequence (BPS) is chosen as the 3'' splice site during catalytic step II of the splicing reaction. The mechanism and factors involved in selection of this AG are not known. Early in mammalian spliceosome assembly, U2AF65 binds to the pyrimidine tract between the BPS and AG. Here we show that U2AF65 crosslinking is replaced by crosslinking of three proteins of 110, 116 and 220 kDa prior to catalytic step II, and we provide evidence that all three proteins are components of U5 snRNP. These proteins interact with pre-mRNA in the region spanning from immediately downstream of U2 snRNP''s binding site at the BPS to just beyond the 3'' splice site. We also demonstrate that there are strict constraints on both the sequence and the distance between the BPS and AG for catalytic step II. Together, these observations suggest that U5 snRNP is positioned on the 3'' splice site by an interaction (direct or indirect) with U2 snRNP bound at the BPS and by a direct interaction with the pyrimidine tract. The functional AG for catalytic step II may be specified, in turn, by its location with respect to the U5 snRNP binding site.     

Association of U2 snRNP with the spliceosomal complex E.

In metazoans, the E complex is operationally defined as an ATP-independent spliceosomal complex that elutes as a single peak on a gel filtration column and can be chased into spliced products in the presence of an excess of competitor pre-mRNA. The A complex is the first ATP-dependent functional spliceosomal complex. U1 snRNP first binds tightly to the 5'splice site in the E complex and U2 snRNP first binds tightly to the branch site in the A complex. In this study, we have generated and characterized a monoclonal antibody (mAb 4G8) directed against SAP 62, a component of U2 snRNP and a subunit of the essential mammalian splicing factor SF3a. We show that this antibody is highly specific for SAP 62, detecting only SAP 62 on Western blots and immunoprecipitating only SAP 62 from nuclear extracts. The anti-SAP 62 antibody also immunoprecipitates U2 snRNP and the A complex. Significantly, however, we find that the E complex is also efficiently immunoprecipitated by the anti-SAP 62 antibody. This antibody does not cross-react with any E complex-specific components, indicating that SAP 62 itself is associated with the E complex. To determine whether other U2 snRNP components are associated with the E complex, we used antibodies to the U2 snRNP proteins B"and SAP 155. These antibodies also specifically immunoprecipitate the E complex. These observations indicate that U2 snRNP is associated with the E complex. However, we find that U2 snRNP is not as tightly bound in the E complex as it is in the A complex. The possible significance of the weak association of U2 snRNP with the E complex is discussed.     

The effect of methionine, ethylene and polyamine catabolic intermediates on polyamine accumulation in detached soybean leaves

In the present study we determined the effects of methionine, intermediates of polyamine catabolic pathways and inhibitors of either ethylene biosynthetic or polyamine catabolic pathways on polyamine accumulation in soybean leaves. Inhibitors to SAM decarboxylase and spermidine synthase, methylglyloxal-bis-(guanylhy-drazone) and cyclohexylamine, respectively, suggest that methionine may provide aminopropyl groups for the synthesis of polyamine via S-adenosylmethionine (SAM). Results from experiments that utilized a combination of compounds which altered either ethylene or polyamine biosynthesis, namely, aminoethoxyvinyl glycine, CoSO₄, 2,5-norbornadiene, and CuSO₄, suggest the two pathways compete for a common precursor. However, exogenous addition of ethylene (via ethephon treatments) had little or no effect on polyamine biosynthesis. Likewise, polyamine treatments had little or no effect on ethylene biosynthesis. These data suggest that there are few or no inhibitory effects from the end products of one pathway on the synthesis of the other. Data from leaves treated with metabolic intermediates in the catabolic pathway of polyamines and inhibitors of enzymes in the catabolic pathway, i.e. aminoguanidine, hydroxyethyldrazine and gabaculine, suggest that the observed increases in polyamine titers were not due to decreased catabolism of the polyamines. One catabolic intermediate, γ-aminobutyric acid (GABA), elevated putrescine, spermidine and spermine by 12-, 1.4-, and 2-fold, respectively, Ethylene levels decreased (25%) in GABA-treated leaves. This small decrease in ethylene could not account for such large increase in putrescine titers. Further analysis demonstrated that the GABA-mediated polyamine accumulation was inhibited by difluoromethylarginine, an inhibitor of arginine decarboxylase, but not by difluoromethylornithine, an inhibitor of ornithine decarboxylase. These data suggest that GABA directly or indirectly affects the biosynthesis of polyamines via arginine decarboxylase.