Managing soil nitrogen to restore annual grass-infested plant communities: effective strategy or incomplete framework?

Theoretical and empirical work has established a positive relationship between resource availability and habitat invasibility. For nonnative invasive annual grasses, similar to other invasive species, invader success has been tied most often to increased nitrogen (N) availability. These observations have led to the logical assumption that managing soils for low N availability will facilitate restoration of invasive plant-dominated systems. Although invasive annual grasses pose a serious threat to a number of perennial-dominated ecosystems worldwide, there has been no quantitative synthesis evaluating the degree to which soil N management may facilitate restoration efforts. We used meta-analysis to evaluate the degree to which soil N management impacts growth and competitive ability of annual and perennial grass seedlings. We then link our analysis to current theories of plant ecological strategies and community assembly to improve our ability to understand how soil N management may be used to restore annual grass-dominated communities. Across studies, annual grasses maintained higher growth rates and greater biomass and tiller production than perennials under low and high N availability. We found no evidence that lowering N availability fundamentally alters competitive interactions between annual and perennial grass seedlings. Competitive effects of annual neighbors on perennial targets were similar under low and high N availability. Moreover, in most cases perennials grown under competition in high-N soils produced more biomass than perennials grown under competition in low-N soils. While these findings counter current restoration and soil N management assumptions, these results are consistent with current plant ecological strategy and community assembly theory. Based on our results and these theories we argue that, in restoration scenarios in which the native plant community is being reassembled from seed, soil N management will have no direct positive effect on native plant establishment unless invasive plant propagule pools and priority effects are controlled the first growing season.

Stomatal conductance is a key parameter to assess limitations to photosynthesis and growth potential in barley genotypes.

Fourteen genotypes of barley were compared for response to salinity by monitoring the parameters gas exchange and chlorophyll fluorescence. We present relationships between stomatal conductance (gs) gas exchange chlorophyll fluorescence parameters and aboveground dry matter (AGDM). We found that genetic variability provided a continuum of data for gs across control and saline conditions. We used this continuum of gs values to test the overall relationships between gs and net photosynthesis (A), leaf internal CO2 concentration (Ci), actual quantum yield of PSII electron transport (PhiPSII), relative electron yield over net CO2 assimilation rate (ETR/A), and AGDM. The relationship between gs and A was highly significant (P < 0.0001) for both control and saline treatments, while correlations between gs and Ci, and Ci and A were significant only under control conditions. Unexpectedly, we found positive correlations between gs and PhiPSII (P < 0.0001) for both conditions. A comparison between relationships of gs and A, and gs and PhiPSII seemed to indicate a possible acclimation to salinity at the chloroplastic level. Finally, the relationships between gs and ETR/A were exceptionally strong for both growing conditions (P < 0.0001) indicating that, as gs values were negatively affected in barley by genetics and salinity as main or interactive effects, there was a progressive increase in photorespiration in barley. Overall, we found that stomatal conductance was a key parameter in the study of barley responses to limiting situations for photosynthesis. We also found a strong relationship between AGDM and gs regardless of growing conditions and genotypes. For breeding evaluations to select barley genotypes for salinity tolerance, it may be possible to replace all measurements of gas exchange and chlorophyll fluorescence by the simple use of a porometer.

Pregnant patients in the intensive care unit: a descriptive analysis.

We present a descriptive analysis of experience with pregnant women in the intensive care units at a tertiary hospital. During the period from 1983 through 1990, 38 women were admitted to our intensive care units during their pregnancy or within 2 weeks postpartum. This was a rate of 1 per 400 pregnant patients. The mean age of these 38 women was 25 years; 68% of them were white and 32% were primigravidas. Nineteen of the 38 women were mechanically ventilated. Twelve women were admitted for hypertensive disease and 10 for adult respiratory distress syndrome. Maternal mortality was 18% (7/38). Follow-up was available for 33 women. The fetal and neonatal loss rate in this group was 4 of 33 pregnancies. In this case series of 38 very ill women, it was apparent that a team approach of obstetricians, anesthesiologists, and intensive care workers provided optimal management for the mother and child.

Activity of an NAD-dependent 5,10-methylenetetrahydrofolate dehydrogenase in normal tissue, neoplastic cells, and oncogene-transformed cells.

As an extension of the previously reported observation concerning the existence of NAD-dependent 5,10-methylenetrahydrofolate dehydrogenase in transformed cells a variety of tissues and cell lines have been assayed for this activity. This activity was found in all assayed transformed cells. Results with rat liver derived epithelial (RLE) cells transformed with a series of oncogenes (v-raf, v-raf/v-myc (J2), v-myc (J5), and v-Ha-ras (pRNR16)) indicated that expression of activity correlates with the extent of transformation and was independent of the oncogene used for transformation. Compared to previously reported values for normal tissue, surprisingly high levels of the NAD-dependent 5,10-methylenetetrahydrofolate dehydrogenase were found in the rat adrenal cortex. This activity was not seen in mouse or bovine adrenal. Enzymatic activity was also detected in mouse bone marrow and was strain dependent. The levels of activity in mouse bone marrow were lower than previously reported. The NAD-dependent 5,10-methylenetetrahydrofolate dehydrogenase activity in rat adrenal and RLE cells may represent tools for studying the regulation of expression of this activity.

Molecular heterogeneity of translocations associated with muscular dystrophy.

Individual translocation chromosomes from six girls suffering from Duchenne or Becker muscular dystrophy (DMD or BMD) have been isolated in human-mouse somatic cell hybrids. DNA prepared from these hybrids was probed with sequences physically close to the locus; these include a junction fragment from the site of the X:21 translocation (pXJ1) and subclones from the pERT 87 (DXS164) region which are absent in a minority of male DMD patients. Both sets of sequences mapped within the area defined by the translocation breakpoints, confirming their close proximity to the DMD and BMD loci. Furthermore, the X chromosome breakpoints of the translocations can be divided into three categories depending upon their position in relation to the sequences recognised by pXJ1 and pERT 87. The genomic target disrupted by the translocations examined here is a minimum of 176 kb.