Origin of complementary incompatibility systems in flowering plants

Theoretical and Applied Genetics - The complementary incompatibility system, characterized by co-operative control of a single S specificity by alleles of two or more distinct S genes, has raised...     

Intron-size constraint as a mutational mechanism in Rothmund-Thomson syndrome

Rothmund-Thomson syndrome (RTS) is an autosomal recessive disorder caused by deleterious mutations in the RECQL4 gene on chromosome 8. The RECQL4 gene structure is unusual because it contains many small introns <100 bp. We describe a proband with RTS who has a novel 11-bp intronic deletion, and we show that this mutation results in a 66-bp intron too small for proper splicing. Constraint on intron size may represent a general mutational mechanism, since human-genome analysis reveals that approximately 15% of genes have introns <100 bp and are therefore susceptible to size constraint. Thus, monitoring of intron size may allow detection of mutations missed by exon-by-exon approaches.     

Rhizosphere acidification as a response to iron deficiency in bean plants

Iron deficiency in higher plants causes accumulation of salts of organic acids in the roots, the most characteristic being citrate. We show that citrate and malate accumulate in beans (Phaseolus vulgaris L. var Prélude), not because of a lack of the iron-containing enzyme aconitase (EC 4.2.1.3), but in close coupling to the extrusion of protons during rhizosphere acidification, one of the `Fe-efficiency' reactions of dicotyledonous plants. When proton excretion is induced in roots of control bean plants by addition of fusicoccin, only malate, not citrate, is accumulated. We propose that iron deficiency induces production of organic acids in the roots, which in beans leads to both proton excretion and an increased capacity to reduce ferric chelates via the induced electron transfer system in the root epidermis cells.     

Screening of visible and UV radiation as a photoprotective mechanism in plants

Prolonged exposure of plants to high fluxes of solar radiation as well as to other environmental stressors disturbs the balance between absorbed light energy and capacity of its photochemical utilization resulting in photoinhibition of and eventually in damage to plants. Under such circumstances, the limiting of the light absorption by the photosynthetic apparatus efficiently augments the general photoprotective mechanisms of the plant cell, such as reparation of macromolecules, elimination of reactive oxygen species, and thermal dissipation of the excessive light energy absorbed. Under stressful conditions, plants accumulate, in different cell compartments and tissue structures, pigments capable of attenuation of the radiation in the UV and visible parts of the spectrum. To the date, four principle key groups of photoprotective pigments are known: mycosporine-like amino acids, phenolic compounds (including phenolic acids, flavonols, and anthocyanins), alkaloids (betalains), and carotenoids. The accumulation of UV-absorbing compounds (mycosporine-like amino acids and phenolics in lower and higher plants, respectively) is a ubiquitous mechanism of adaptation to and protection from the damage by high fluxes of solar radiation developed by photoautotrophic organisms at the early stages of their evolution. Extrathylakoid carotenoids, betalains, and anthocyanins play an important role in long-term adaptation to the illumination conditions and in protection of plants against photodamage. A prominent feature of certain plant taxa lacking some classes of photoprotective pigments (such as anthocyanins) is their substitution by other compounds (e.g. keto-carotenoids or betalains) disparate in terms of chemical structure and subcellular localization but possessing close spectral properties.     

Biochemical and enzymatic changes in rice plants as a mechanism of defense

A laboratory study was undertaken to ascertain the impact and the extent of feeding by different pests on biochemical constituents and various enzyme levels in rice plants. The difference in these parameters due to the pest damage by three different modes of feeding was also studied and compared. The borer pest—yellow stem borer (YSB), Scirpophaga incertulas (W); surface feeder—-leaf roller (LR), Cnaphalocrosis medinalis (G) and a sucking pest—brown plant hopper (BPH), Nilaparvata lugens (S) fed rice plants were analyzed for the quantitative and qualitative changes in biochemical profile and enzymatic changes that occur as plant’s defensive responses were analyzed spectrophotometrically. The phenolic acids were analyzed using HPLC and quantitated with the standard samples. The quantity of biochemicals such as proteins, phenols and carbohydrates has been enhanced along with the enzyme activities of peroxidase (POD), catalase (CAT), chitinase (CHI). A decrease in superoxide dismutase (SOD), phenyl alanine ammonia lyase (PAL), β-1, 3-glucanase (GLU) enzyme activities were evident in pest infested plants. Phenolic acids like vanillic acid, syringic acid, cinnamic acid, and p-coumaric acids were mostly found in the infested plants. We demonstrate that the elevated levels of biochemicals, phenolic acids, and enzymes may play a major role in plant defense.     

Genotype frequencies associated with incompatibility systems in tristylous plants

A general procedure has been given previously for calculating frequencies of the morphs Long, Mid, and Short in equilibrium populations of tristylous plants. It is now demonstrated that an equilibrium state actually exists at the genotype level if this procedure produces admissible morph frequencies. This result holds in a diploid model, with or without linkage between the two loci involved. It is shown how the genotype frequencies may be determined for any set of mating probabilities. It is also explained how these frequencies may be calculated in a tetraploid model incorporating double reduction. The general theory is applied to a particular situation where the Mid morph is at a selective disadvantage as a seed parent.     

Cell death as a possible mechanism for tissue limited mosaicism in Pallister-Killian syndrome

Pallister-Killian syndrome is a chromosomal mosaic syndrome with a normal and an isochromosome 12p cell line, the latter rarely seen in peripheral blood. The isochromosome 12p cell line decreases with serial passages of fibroblasts in vitro and with age of patient in vivo. To evaluate cell death as a possible mechanism for loss of the abnormal cell line, amniocytes from a fetus with Pallister-Killian syndrome were identified as normal or aneuploid using a chromosome 12 alpha-satellite DNA probe by fluorescent in situ hybridization (FISH) and then subsequently stained with Annexin V, which stains the cytoplasm of cells that are dying. Although not conclusive, our preliminary results suggest that the abnormal cell line is going through apoptosis or necrosis at a higher rate than normal cells. Cell death may be a possible mechanism for decrease of the aneuploid cell line in patients with Pallister-Killian syndrome.     

A new look at incompatibility relationships in higher plants

Summary Pollen tube growth was evaluated using an 18-step scale after both intra- and interspecific pollinations of genotypically widely differing diploid potato species and potato dihaploids expressing monofactorial gametophytic incompatibility. The results obtained account for a wide array of types of pollen tube growth resulting from crossing partners with distinct incompatibility behavior. Based on the assumption that inhibition of pollen tubes is the rule and solely prevented by the pollen itself, a model proposing one common cause underlying different mechanisms for both intraspecific selfincompatibility and interspecific incompatibility in diploids is put forward. Data supporting the model are presented from the experimental results of this study and from the literature. The strength of pollen-style interaction depends on particular S-alleles in combination with recognition and activity properties of the basic S-genotypes. The model is suitable to explain all former observations on incompatibility in diploids with a gametophytic system of incompatibility and, with modifications of the manner of phenotypic expression, also in plants with sporophytic incompatibility. The proposed scheme of pollen tube growth phenotypes permits prediction of pollen tube growth behavior in an intended cross combination. The model is based on both classical Mendelian genetics and recent molecular genetic insight.     

Competition for DNA steroid response elements as a possible mechanism for neuroendocrine integration

For the analysis of a simple steroid-dependent mating behavior, careful response definition, complete neural circuit delineation and placement of estrogen-responsive cells within this circuit have been accomplished. Molecular studies of two relevant genes have emphasized DNA/RNA hybridization assays nd DNA binding techniques. For both the rat preproenkephalin gene and the gene for the progesterone receptor, a strong induction by estrogen, tissue specificity of expression and a sex difference in regulation are prominent phenomena. On the rat preproenkephalin promoter, estrogen (ER) and thyroid receptors may compete for a DNA binding site. Likewise, progesterone (PR) and glucocorticoid receptors may compete for the same sites. On the rat PR gene, interactions between ER and AP-1 binding proteins are of special interest. Such interactions could underlay competitions and synergies between steroid hormones and neurally signalled events in the environment.     

Autoimmune response in cartilage-delivered peptides in a patient with osteoarthritis

Whatever the initiating factor of osteoarthritis (OA), the process ultimately unmasks the immunogenic determinants of chondrocytes, proteoglycans and collagens, which then triggers autoimmune reactions. Although the precise mechanism of the immune responses in the pathogenesis of OA requires further investigation, here I postulate that the presence of autoimmunity to cartilage components has an important role in the process of cartilage degradation in OA. Current studies strongly suggest that a immunoregulatory therapeutic strategy should be established.     

Autoimmune response in cartilage-delivered peptides in a patient with osteoarthritis

Whatever the initiating factor of osteoarthritis (OA), the process ultimately unmasks the immunogenic determinants of chondrocytes, proteoglycans and collagens, which then triggers autoimmune reactions. Although the precise mechanism of the immune responses in the pathogenesis of OA requires further investigation, here I postulate that the presence of autoimmunity to cartilage components has an important role in the process of cartilage degradation in OA. Current studies strongly suggest that a immunoregulatory therapeutic strategy should be established.     

Iodine as a micronutrient for plants

Summary In sand-culture experiments in pots it was shown that various crops react to minute applications of iodide or iodate. The vegetative growth of spinach, white clover, fodderbeet, tomatoes, perennial ryegrass, turnips (aerial parts), barley, flax, wheat and mustard was favourably influenced by iodine. No distinctly positive effect was observed, however, with buckwheat. The development of oats and to a lesser extent of the roots of turnips was hindered at all the rates of application used.In general, iodate had a more favourable effect on growth than iodide, particularly in the initial stages of development. This may be due partly to the fact that plants absorb iodate more slowly than iodide, since during early life plants are highly sensitive to an overdosage of iodine.     

Radiationless transitions as a protection mechanism against photoinhibition in higher plants and a red alga

Exposure of the red alga Porphyra perforata or leaves of Phytolacca americana and Echinodorus sp. to white light equivalent to full sunlight for short periods induced large decreases of variable fluorescence measured at 695 nm at 77K. This change was not produced by photoinhibition but rather appeared to result from an inorease in the rate constant of radiationless transition in the reaction centers of photosystem II. It is proposed that this increase is related to the formation of the high energy state which serves as a photoprotective mechanism in plants.     

Nucleo-cytoplasmic incompatibility in cybrid plants possessing an Atropa genome and a Nicotiana plastome.

Summary Twenty-nine cybrids possessing an Atropa belladonna nuclear genome and a Nicotiana tabacum plastome were selected from two independent protoplast fusion experiments. In contrast to the previously described reciprocal, green and fertile cybrids with a Nicotiana nuclear genome and an Atropa plastome (Kushnir et al. 1987), the plants obtained were totally chlorophyll-deficient. An Atropa nuclear genome and a Nicotiana plastome from these chlorophyll-deficient cybrids were combined with an Atropa or a Scopolia plastome and a Nicotiana nuclear genome, respectively, in control fusion experiments. All of these nuclear genome/plastome combinations gave rise to normal, green plants. Therefore, we conclude that an N. tabacum plastome is incompatible with an A. belladonna nuclear genome.     

Stimulated repopulation as a basis of antimutagenesis and the adaptive response in plants

Wheat seeds were used to study (1) modification of the radiation adaptive response (AR) with antioxidant anphen and (2) modification of the clustogenic effect of N-methyl-N-nitrosourea (MNU) with various agents. Pretreatment with anphen enhanced AR. Each pretreatment (irradiation with 0.25 Gy, treatment with anphen, treatment with anphen followed by irradiation with 0.25 Gy) decreased aberration frequency. This parameter proved to be in a linear dependence with mitotic index (MI) with correlation coefficient -0.978; the regression line passed through the point corresponding to spontaneous MI and spontaneous aberration frequency. Upon treatment with MNU, the antimutagenic effect was observed for various pretreatments (a low concentration of MNU, antioxidant phenoxan, irradiation with 0.25 Gy). Again, MI and aberration frequency were in inverse proportion with correlation coefficient -0.99, and the regression line passed through the point with spontaneous MI and spontaneous aberration frequency. The same dependence was observed for previously published data on modification of radiation AR with phenoxan. The results were hard to explain in terms of the repair-associated mechanism of AR and the antimutagenic effect. Hence, a nonspecific inducible process of stimulated repopulation was assumed to be a common mechanism of AR and the antimutagenic effect in plants.