Relative lower extremity length in Mexican American and in American black and white youth

Stature, sitting height, estimated leg (subischial) length and the sitting height/stature ratio are compared in Mexican American, American White and American Black boys 9 through 14 years of age and girls 12 through 17 years of age. Mexican American youth are shorter in stature and have absolutely shorter lower extremities. The sitting height of Mexican American youth is similar to that of Black youth and shorter than that of White youth. The sitting height/stature ratio is virtually identical in Mexican American and White youth, indicating similar proportions of lower extremities to stature. In contrast, Black youth have absolutely and relatively longer lower extremities than Mexican American and White youth. These results would thus seem to suggest that reference data for the body mass index (BMI) based on American White youth can be used with Mexican American youth, while race-specific values may be necessary for American Black youth. However, ethnic variation in physique, perhaps frame size, may be a factor which should be more systematically considered in evaluating the utility of the body mass index.     

Realistic Variation in Species Composition Affects Grassland Production,Resource Use and Invasion Resistance

We investigated the effects of realistic variation in plant species and functional group composition, with species occurring at realistic abundances, on ecosystem processes in exotic-dominated California grassland communities. Progressive species removals from microcosm communities, designed to mimic nested variation in diversity observed in the field, reduced grassland production, resistance to intentional invasions, and resistance to natural colonization by new species. Three lines of evidence point to the particular importance of intensified competition within a single functional group—late-active forbs—in explaining the observed effects of realistic species loss order on community resistance. First, reduced success of naturally colonizing species in more diverse assemblages was dominated by declining colonization by late-active forbs. Second, increasing late-active forb biomass appeared to reduce the biomass of intentionally introduced yellow starthistle (Centaurea solstitialis, a late-season forb) both within and across diversity levels. Finally, starthistle addition reduced biomass of resident late-season forbs but not of any other functional group. Increasing diversity increased light levels and soil moisture availability in spring and summer, providing a proximate mechanism linking our realistic species loss order to decreased community resistance. Starthistle addition reduced light and soil moisture availability but not N across richness levels, mirroring the apparent effects of the additional late-active forb species present in higher diversity treatments. Species losses that entail the early loss of whole or key functional groups could, through mechanisms like those we explore, have greater ecosystem consequences than those suggested by randomized-loss experiments.     

Mycorrhizal response of <Emphasis Type="Italic">Clusia pusilla</Emphasis> growing in two different soils in the field

Arbuscular mycorrhizas (AM) are important for promoting the mineral nutrition, growth and survival of plants used to rehabilitate degraded areas. Clusia pusilla is an evergreen shrub which is tolerant of high irradiance, germinates readily and can be easily reproduced by cuttings. All these characteristics make this species useful in the recovery of deforested areas. The aim of this work was to explore the response of C. pusilla to AM in the field, in two types of soil: the shrubland soil in which the species naturally grows and in a soil of a riparian forest. Eight treatments were performed in each type of soil. The treatments consisted of a non-mycorrhizal control and mycorrhizal plants colonized by one of the three AM inocula tested in the presence or absence of triple superphosphate (150 kg ha^-1). After 11 months of growth in the shrubland soil, C. pusilla seedlings showed an increase in height and dry weight in response to the fertilizer but not to mycorrhizas. In contrast, in the forest soil the arbuscular mycorrhizal fungi (AMF) effect was equivalent to the fertilizer effect, and the two effects interacted positively. The lack of response to AM in shrubland soil was caused by its high sand content, which hinders the retention of the inocula. Due to a higher clay content, the forest soil binds inocula more tightly than shrubland soil. In conclusion, C. pusilla appears to benefit greatly from the addition of AMF in forest soil, though it requires an additional P source for such benefits in shrubland soil. This P source must be organic so that phosphorus is not lost by leaching. Although the growth rate of this species is very low, its survival can be guaranteed with the application of AMF inocula together with P-fertilizer applied at a low rate.     

Photosystem II Cyclic Heterogeneity and Photoactivation in the Diazotrophic, Unicellular Cyanobacterium Cyanothece Species ATCC 51142

The unicellular, diazotrophic cyanobacterium Cyanothece sp. ATCC 51142 demonstrated important modifications to photosystem II (PSII) centers when grown under light/dark N₂-fixing conditions. The properties of PSII were studied throughout the diurnal cycle using O₂-flash-yield and pulse-amplitude-modulated fluorescence techniques. Nonphotochemical quenching (q_N) of PSII increased during N₂ fixation and persisted after treatments known to induce transitions to state 1. The q_N was high in cells grown in the dark, and then disappeared progressively during the first 4 h of light growth. The photoactivation probability, ε, demonstrated interesting oscillations, with peaks near 3 h of darkness and 4 and 10 h of light. Experiments and calculations of the S-state distribution indicated that PSII displays a high level of heterogeneity, especially as the cells prepare for N₂ fixation. We conclude that the oxidizing side of PSII is strongly affected during the period before and after the peak of nitrogenase activity; changes include a lowered capacity for O₂ evolution, altered dark stability of PSII centers, and substantial changes in q_N.     

A sequence variation in the human cystatin D gene resulting in an amino acid (Cys/Arg) polymorphism at the protein level

A polymorphism in the coding region of the human cystatin D gene has been detected by direct sequencing of amplified DNA from different individuals. The variation, resulting from a T/C transition in exon 1 of the gene, causes an amino acid variation, Cys/Arg, at the protein level. An allele-specific oligonucleotide hybridization assay was developed and used to demonstrate this polymorphism in the population. The deduced frequencies were 0.55 and 0.45 for the Cys and Arg variant-encoding alleles, respectively.     

DNA sequences specific for Caucasian G3m(b) and (g) allotypes: allotyping at the genomic level

Assignment of the G3m(g) and (b) correlative amino acid residues was performed at the genomic level by direct sequencing of DNA from nine Caucasian individuals. Two oligonucleotide primers were used for subclass-specific enzymatic amplification of a DNA segment comprising a major portion of the second and third constant region domains (C_H2 and C_H3) fo the human IgG3 heavy chain gene. Comparison of the sequences of amplified DNA from individuals serologically typed as homozygous for G3m(b) or G3m(g) or as heterozygous, G3m(b,g), revealed differences in the codons for the amino acid residues 291, 296, and 384. Proline, phenylalanine, and serine at these positions corresponded to G3m(b), and leucine, tyrosine, and asparagine to G3m(g). Heterozygotic individuals, typed G3m(b,g), displayed both the G3m(b) and G3m(g) codons at these three positions. The polymorphism at each of these three codons could be identified either as the appearance, or the loss, of recognition sites for the two restriction endonucleases, Nsp BII and Rsa I. This allowed the development of a polymerase chain reaction (PCR)-based assay permitting the distinction of G3m ^b and G3m ^g alleles by analyzing the electrophoretical mobility of the DNA fragments generated by digestion of the PCR-products with Nsp BII and Rsa I. Correspondence to: R. Grubb.     

Predicting species responses to climate change: demography and climate microrefugia in California valley oak (Quercus lobata)

Anticipating species movement under climate change is a major focus in conservation. Bioclimate models are one of the few predictive tools for adaptation planning, but are limited in accounting for (i) climatic tolerances in preadult life stages that are potentially more vulnerable to warming; and (ii) local‐scale movement and use of climatic refugia as an alternative or complement to large‐scale changes in distribution. To assess whether these shortfalls can be addressed with field demographic data, we used California valley oak (Quercus lobata Nee), a long‐lived species with juvenile life stages known to be sensitive to climate. We hypothesized that the valley oak bioclimate model, based on adults, would overpredict the species' ability to remain in the projected persisting area, due to higher climate vulnerability of young life stages; and underpredict the potential for the species to remain in the projected contracting area in local‐scale refugia. We assessed the bioclimate model projections against actual demographic patterns in natural populations. We found that saplings were more constricted around surface water than adults in the projected contracting area. We also found that the climate envelope for saplings is narrower than that for adults. Saplings disappeared at a summer maximum temperature 3 °C below that associated with adults. Our findings indicate that rather than a complete shift northward and upward, as predicted by the species bioclimate model, valley oaks are more likely to experience constriction around water bodies, and eventual disappearance from areas exceeding a threshold of maximum temperature. Ours is the first study we know of to examine the importance of discrete life stage climate sensitivities in determining bioclimate modeling inputs, and to identify current climate change‐related constriction of a species around microrefugia. Our findings illustrate that targeted biological fieldwork can be central to understanding climate change‐related movement for long‐lived, sessile species.     

Molecular phylogeny endorses the relationship between carnivorous and filter‐feeding tunicates (Tunicata,Ascidiacea)

Tatián, M., Lagger, C., Demarchi, M. & Mattoni, C. (2011). Molecular phylogeny endorses the relationship between carnivorous and filter‐feeding tunicates (Tunicata, Ascidiacea).—Zoologica Scripta, 40, 603–612. The phylogeny of the tunicates (animals considered the closest relatives to the vertebrates) is not yet completely defined, especially the evolutionary relationships within the class. Molecular studies do not include particular benthic deep‐sea species that show morphological changes in the evolution from filter feeding into a carnivorous‐feeding habit. According only to morphological features, these animals are considered as a part of the Class Ascidiacea (Family Hexacrobylidae), but also as a different class, Sorberacea, belonging to the Phylum Tunicata. In this study, we present a phylogenetic analysis based on 18S rDNA sequences, which clearly included these animals in Ascidiacea but in the Family Molgulidae, faster‐evolving ascidians with a high evolution rate. This finding supports the idea that carnivory in Molgulidae represents a more recent adaptation to life in the ocean deep bottoms, where organisms have to adapt themselves to a less plentiful particulate organic carbon supply. Based on molecular and morphological evidence, we propose the following new synonymy: Hexacrobylidae Seeliger 1906 = Molgulidae Lacaze‐Duthiers, 1877 .