The natural abundance of 15N in mat-forming lichens

Natural abundance of (15)N and [N] was studied in thalli of mat-forming lichens collected from tundra and heathland sites in the northern and southern hemispheres. The study includes samples of British Cladonia portentosa from sites in regions of high and low N-loading and in heathland growing both directly on peat and independently of the soil substratum, in a canopy of prostrate gorse ( Ulex minor). In the mat-forming lichens examined, a non-random pattern in [N] and delta(15)N was characterised by a minimum in delta(15)N, which occurred most frequently at 20-40 mm below the thallus apex. Nitrogen concentration increased above this point, towards the apex, though remained invariably low towards the thallus base. We discuss the significance of the pattern in [N] and delta(15)N for current theories describing the uptake and recycling of nitrogen by mat-forming lichens in oligotrophic habitats. Our data are incompatible with the suggested uptake of soil organic-N depleted in (15)N, though are consistent with possible internal recycling and the development of a structural necromass. The study emphasises the internal fractionation of nitrogen isotopes and provides a caveat against the assumption that values of delta(15)N provide an unequivocal indicator of source-sink relationships in nitrogen cycling.     

Genetic Mapping of the Cloned Subgroup A Avian Sarcoma and Leukosis Virus Receptor Gene to the TVA Locus

A chicken gene conferring susceptibility to subgroup A avian sarcoma and leukosis viruses (ASLV-A) was recently identified by a gene transfer strategy. Classical genetic approaches had previously identified a locus, TVA, that controls susceptibility to ASLV-A. Using restriction fragment length polymorphism (RFLP) mapping in inbred susceptible (TVA*S) and resistant (TVA*R) chicken lines, we demonstrate that in 93 F₂ progeny an RFLP for the cloned receptor gene segregates with TVA. From these analyses we calculate that the cloned receptor gene lies within 5 centimorgans of TVA, making it highly probable that the cloned gene is the previously identified locus TVA. The polymorphism that distinguishes the two alleles of TVA in these inbred lines affects the encoded amino acid sequence of the region of Tva that encompasses the viral binding domain. However, analysis of the genomic sequence encoding this region of Tva in randomly bred chickens suggests that the altered virus binding domain is not the basis for genetic resistance in the chicken lines analyzed.Avian sarcoma and leukosis viruses (ASLV) may be classified into several subgroups based on properties of the viral envelope proteins. Five major subgroups of ASLV (A to E) have been defined based on immunological reactivity of the viral envelope proteins, host range, and infection interference patterns (reviewed in reference 18). The subgroup specificity of the virus maps to the env gene, and distinct hypervariable regions within env have been shown to determine the viral subgroup (2, 3, 7, 8).Patterns of susceptibility of inbred chicken lines to infection with the various ASLV subgroups suggest that three loci control viral entry for the five major ASLV subgroups (11, 12, 15, 17). Dominant alleles at the TVA and TVC (TVA*S and TVC*S) loci confer susceptibility to subgroups A and C viruses, respectively. The TVB locus is more complex, with various alleles determining infection by subgroup B, D, and E viruses. TVA, TVB, and TVC appear to act at the level of viral entry into the cell; therefore, it has been assumed that the TV loci encode or control expression of the cellular receptors for ASLV (5, 13).Recently, a gene that confers susceptibility to subgroup A ASLV (ASLV-A) was cloned by a gene transfer strategy (1, 19). Molecular clones containing coding sequences for this gene relieve the block to viral entry when expressed in a number of mammalian cell lines (1, 19). The gene encodes a surface glycoprotein that has been shown to bind directly and specifically to the ASLV-A envelope protein (4, 9). In addition, binding of the receptor protein to ASLV-A envelope protein induces conformational changes in the viral glycoproteins that appear to be associated with viral entry (10). Finally, an antibody to the receptor protein specifically blocks infection of chicken cells by subgroup A viruses, suggesting that this gene encodes the normal ASLV-A receptor on chicken cells (1). Taken together, these results demonstrate that the cloned gene encodes a subgroup A virus receptor.Since it is clear that the cloned gene encodes an ASLV-A receptor, the protein supposed to be encoded by the classical TVA locus, we asked whether the identified receptor gene mapped to the TVA locus. In this paper we show that a restriction fragment length polymorphism (RFLP) of DNA from inbred chickens can be used to demonstrate that the cloned ASLV-A receptor gene maps to within 5 centimorgans (cM) of the TVA locus as defined by susceptibility to ASLV-A, making it highly probable that the cloned gene is TVA. In addition, analysis of the genomic sequences encoding the viral interaction domain of the receptor in both inbred and randomly bred chickens demonstrates that alterations in this region of the receptor are not responsible for the resistance phenotype.

TVA segregation analysis.

Inbred chicken lines homozygous for TVA alleles encoding either sensitivity (TVA*S) or resistance (TVA*R) were used to generate birds in which the TVA segregation pattern could be studied. Regional Poultry Research Lab lines 6₃ (TVA*S/*S TVB*S/*S) and 7₂ (TVA*R/*R TVB*R/*R) (6) were crossed, and the resulting heterozygous F₁ progeny were mated to generate 93 F₂ chicks. The susceptibility phenotype of the F₂ chicks was determined on the basis of tumor formation following subcutaneous injection of 500 focus-forming units (FFU) of subgroup A Bryan high-titer Rous sarcoma virus (RSV) (RAV-1) and 500 FFU of subgroup B Bryan high-titer RSV (RAV-2) into the right and left wing webs, respectively, of 4-week-old chicks. At 2, 3, and 4 weeks postinjection the wings were palpated to check for tumor development. Chicks were scored as positive for susceptibility (e.g., TVA*S/*S or TVA*S/*R) if a tumor of any size formed in the appropriate wing web.Table ​Table11 summarizes the distribution of susceptibility to subgroups A and B RSV in the F₂ chicks. Segregation of TVB yielded roughly the predicted frequency of susceptible (67 observed versus 70 expected) and resistant (26 observed versus 23 expected) progeny for a dominant locus (P > 0.05). In contrast, the distribution of subgroup A-susceptible and -resistant birds deviated significantly from the expected 3:1 ratio, with an excessive number of subgroup A-resistant chicks observed and a ratio of 2:1 (χ² = 3.4) (Table ​(Table1).1). Previous analysis of the segregation of TVA using the same chicken lines did not reveal an altered distribution of sensitive and resistant birds (6), suggesting that the bias seen here may be a chance deviation from the expected ratio. Segregation of two endogenous virus loci, ALVE2 (previously designated ev2) (carried by line 7₂) and ALVE3 (previously designated ev3) (carried by line 6₃), also gave roughly the expected 3:1 ratio in these F₂ chicks (data not shown). When the segregation bias in the ASLV-A-susceptible birds was accounted for, then susceptibility to subgroup A and B RSV segregated independently, as was expected since the TVA and TVB genes have been reported to be unlinked (6). Recent mapping studies also confirmed that TVA and TVB are found on different linkage groups (3a).

TABLE 1

Segregation of resistance and susceptibility to subgroup A and B viruses in F₂ progeny obtained by crossing lines 6₃ and 7₂

MIP-3alpha transfection into a rodent tumor cell line increases intratumoral dendritic cell infiltration but enhances (facilitates) tumor growth and decreases immunogenicity

Dendritic cells are powerful APCs for activation of specific antitumor T lymphocytes. To present tumor Ags efficiently, they have first to migrate to the tumor site, engulf Ag, and then process them. To attract immature DCs to the tumor site, we transfected tumor cells with MIP-3alpha which is strongly chemotactic for DCs. Surprisingly, MIP-3alpha-transfected tumor cells grew faster than the mock-transfected tumor cells. Histological analysis and tumor dissociation confirmed that the MIP-3alpha-transfected tumors contain three to four times more DCs than mock-transfected tumors. FACS analysis of the intratumor DCs showed that they were predominantly immature. Functional analysis showed that the alloreactivity mediated by these infiltrating MIP-3alpha-transfected tumor DCs is strongly reduced. In conclusion, MIP-3alpha is an efficient chemokine for attracting DCs in vivo, but the high density of DCs in the tumor site injection is not a sufficient condition to induce an immune response. Furthermore, this attraction of immature DCs may always have an adverse effect by inducing a tolerance to the tumor cells.     

Adhesion of bifidobacteria to granular starch and its implications in probiotic technologies

Adhesion of 19 Bifidobacterium strains to native maize, potato, oat, and barley starch granules was examined to investigate links between adhesion and substrate utilization and to determine if adhesion to starch could be exploited in probiotic food technologies. Starch adhesion was not characteristic of all the bifidobacteria tested. Adherent bacteria bound similarly to the different types of starch, and the binding capacity of the starch (number of bacteria per gram) correlated to the surface area of the granules. Highly adherent strains were able to hydrolyze the granular starches, but not all amylolytic strains were adherent, indicating that starch adhesion is not a prerequisite for efficient substrate utilization for all bifidobacteria. Adhesion was mediated by a cell surface protein(s). For the model organisms tested (Bifidobacterium adolescentis VTT E-001561 and Bifidobacterium pseudolongum ATCC 25526), adhesion appeared to be specific for alpha-1,4-linked glucose sugars, since adhesion was inhibited by maltose, maltodextrin, amylose, and soluble starch but not by trehalose, cellobiose, or lactose. In an in vitro gastric model, adhesion was inhibited both by the action of protease and at pH values of < or =3. Adhesion was not affected by bile, but the binding capacity of the starch was reduced by exposure to pancreatin. It may be possible to exploit adhesion of probiotic bifidobacteria to starch granules in microencapsulation technology and for synbiotic food applications.     

The In Vitro and In Vivo Inhibitory Effects of Some Sulfonamide Derivatives on Rainbow Trout (Oncorhynchus Mykiss) Erythrocyte Carbonic Anhydrase Activity

The in vitro and in vivo inhibitory effects of 5-(3α, 12α-dihydroxy-5-β-cholanamido)-1,3,4-thiadiazole-2-sulfonamide (1), 5-(3α, 7α, 12α-trihydroxy-5-β-cholanamido)-1,3,4-thiadiazole-2-sulfonamide (2), 5-(3α, 7α, 12α-triacetoxy-5-β-cholanamido)-1,3,4-thiadiazole-2-sulfonamide (3) and acetazolamide on rainbow trout (Oncorhynchus mykiss) (RT) erythrocyte carbonic anhydrase (CA) were investigated. The RT erythrocyte CA was obtained by affinity chromatography with a yield of 20.9%, a specific activity of 422.5?EU/mg protein and a purification of 222.4-fold. The purity of the enzyme was confirmed by SDS-PAGE. Inhibitory effects of the sulfonamides and acetazolamide on the RT erythrocyte CA were determined using the CO₂-Hydratase method in vitro and in vivo studies. From in vitro studies, it was found that all the compounds inhibited CA. The obtained I₅₀ value for the sulfonamides (1), (2) and (3) and acetazolamide were 0.83, 0.049, 0.82 and 0.052?μM, respectively. From in vivo studies, it was observed that CA was inhibited by the sulfonamides (1), (2) and (3) and acetazolamide.     

Effects of Climate, Site Conditions, and Seed Quality on Recent Treeline Dynamics in NW Russia: Permafrost and Lack of Reproductive Success Hamper Treeline Advance?

Treeline advance alters albedo and carbon storage and is an important feedback mechanism to the global climate system. Establishment of trees north of the treeline requires favorable climate, suitable microsites, and viable seeds. Here we studied the influence of climate and microsite conditions on tree and seedling growth at four transects from forest through woodland to tundra in NW Russia, and tested the viability of seeds from the region. General growth patterns and establishment periods of the treeline species Picea obovata are similar across the study sites suggesting a regional driver (for example, climate). Individuals established as early as the 1640s, but mainly between 1850 and 1880, and during a major and continental scale establishment wave in the 1950s and 1960s. No establishment occurred after 1982. Older trees mainly showed significant and stable positive relationships to growing year summer temperatures and significant stable negative correlations to previous year summer temperatures in nearly all plots. Trees from the last establishment wave showed more mixed responses, but current year summer temperature positively affected growth. Active layer depth was similar in all plots with trees but decreased sharply in treeless tundra. A major role for the lack of recent establishment seems to be very low seed viability, possibly combined with early strong fall frosts, which might have severely limited successful recruitment in the last decades of the twentieth century. For a successful establishment of P. obovata in tundra areas of NW Russia, permafrost degradation and (generally) warmer winters might be a prerequisite.     

Carbohydrate-binding protein 35: identification of the galactose-specific lectin in various tissues of mice.

In previous studies, a lectin designated as carbohydrate-binding protein 35 (CBP35) has been isolated from cultured mouse 3T3 fibroblasts. In this study, antibodies directed against CBP35 were used to screen for cross-reactive proteins in various cultured cells and in various organs and tissues of mice. Cross-reactive proteins of the same molecular weight (Mr, 35,000) were found in human, mouse, and chicken fibroblasts and in a macrophage-like cell line, P388D1. Similarly, cross-reactive proteins were also found in the embryonic liver, lung, spleen, thymus, skin, and muscle tissue and in the lung, artery, thymus, and spleen of the adult mouse. Fractionation of extracts of mouse lung on affinity columns of asialofetuin-Sepharose yielded a protein whose molecular weight, carbohydrate-binding specificity, and immunological properties suggest that it is CBP35 derived from the lung, hereafter designated CBP35 (lung). The binding of 125I-labeled CBP35 (lung) to rabbit erythrocytes was quantitated in the presence and absence of various carbohydrates. It was found that only carbohydrates containing galactose were inhibitors of the binding; the disaccharide lactose was 100-fold more potent as an inhibitor than was the monosaccharide galactose. When extracts of the adult mouse liver were fractionated by asialofetuin-Sepharose chromatography, only a protein corresponding to CBP16 was isolated; no CBP35 was found. These results corroborate the immunoblotting data, which indicated that CBP35 was not detectable in the adult mouse liver.     

Lichen-forming fungi: potential sources of novel metabolites.

The challenge for today's pharmaceutical industry lies in the discovery and development of new, pharmacologically active molecules. Metabolites produced by microorganisms, and fungi in particular, are a resource for which the therapeutic potential has been recognized, but one that remains largely unexplored and unexploited. Approximately 20% of all known fungal species are obligate symbionts in lichens; this major group of fungi has been long neglected by mycologists, and overlooked by industry.