Ultrastructural localization of photosynthetic activity in thylakoids during chloroplast development in maize

The localization of photosynthetic activity in developing maize (Zea mays L.) chloroplasts was studied in situ by two electron-microscopic-cytochemical methods. The activity of photosystem I was detected by photooxidation of 3,3-diaminobenzidine (DAB) and the activity of the photosystem II by photoreduction of thiocarbamyl nitrotetrazolium blue (TCNBT). During the transformation of proplastids into chloroplasts, at the base of the leaf blade the DAB reaction appeared before the TCNBT reaction. A positive DAB reaction was observed in the single thylakoids of plastids in cells located only about 0.5 mm above the base. Dark, osmiophilic DAB polymers accumulated in the lumina of the thylakoids. Plastid envelopes and tubules of the prolamellar bodies in immature chloroplasts were DAB-negative. In fully differentiated leaf tissue the DAB reaction was intense in the thylakoids of bundle-sheath chloroplasts, as well as in the stroma thylakoids and the peripheral grana thylakoids of mesophyll chloroplats. The photoreduction of TCNBT started in leaf tissue about 1 mm above the base. Dark granular material of reduced TCNBT appeared mostly in the partitions of grana, i.e. interthylakoidally, but some granules were also attached to the stroma thylakoids. The membranes of plastid envelopes and the tubules of prolamellar bodies showed a negative TCNBT reaction. Young bundle-sheath chloroplasts contained some reduced TCNBT in their grana; these deposits largely disappeared in the course of further differentiation. In mature leaf tissue the photoreduction of TCNBT was conspicuous in the grana of mesophyll chloroplasts, but very weak in the single thylakoids and in the granal rudiments of bundle-sheath chloroplasts.Abbreviations DAB 3,3-diaminobenzidine·4 HCl - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PS(I,II) photosystem (I,II) - TCNBT thiocarbamyl nitrotetrazolium blue chloride     

DNA methylation levels in porcine fetal fibroblasts induced by an inhibitor of methylation, 5-azacytidine

Removal of the somatic DNA methylation pattern from donor cells and remodeling of embryonic status have been suggested as integral processes for successful nuclear transfer (NT) reprogramming. This study has investigated the effects of 5-azacytidine (5-azaC), a DNA methylation inhibitor, on global methylation changes in porcine fetal fibroblasts (PFF); this may improve NT attributable to the potential reprogramming of the methyl groups. PFF in 5th passage cultures were treated with 0, 0.5, 1.0, 2.0, and 3.0 μM 5-azaC for 96 h; 5-azaC inhibited the growth at all tested concentrations. At the higher concentrations of 5-azaC used, cells appeared to exhibit morphological changes and to become apoptotic as observed by TUNEL assay. Thus, cells were negatively affected by 5-azaC. Differences in cellular ploidy were also observed at higher concentrations. Analysis showed no considerable changes in the proportion of cells at the G₁-phase of the cell cycle with 5-azaC concentrations. The fractional part of the methylated DNA of these cells was significantly reduced by 5-azaC treatment. Confocal microscopy confirmed the inhibition of methylation levels in PFF with increased concentrations of 5-azaC. Exposure to 5-azaC altered the expression of genes involved in imprinting (IGF2) or pro-apoptosis (BAX), whereas there was a reduction in the expression of the main enzyme responsible for replicating the DNA methylation pattern (DNMT1) and anti-apoptosis (BCL2L1). Therefore, 5-azaC induces a relative reduction in methylation in PFF, and cells treated with 0.5 μM 5-azaC may have enhanced potential for porcine NT.The financial support of BioGreen 21 (grant no. 100052004002000) and KOSEF (grant no. R05-2004-000-10702-0) in Korea is gratefully acknowledged.     

A comparison of light-dependent RNA metabolism in wild-type Euglena with that of mutants impaired for chloroplast development

Summary The possibility that ³²PO ₄ ^3- (³²P_i) labeling of both chloroplast and non-chloroplast RNAs during light-induced chloroplast development in Euglena is due, in part, to the break-down of existing RNAs and their resynthesis into labeled RNAs has been examined by comparing the RNA content of dark-grown, non-dividing cells after completion of light-induced chloroplast development with that of identical cells maintained in darkness for the same period of time. The involvement of the photo-conversion of protochlorophyll to chlorophyll and other photoreceptor systems in the labeling of RNA during chloroplast development has been considered by comparing the labeling pattern obtained with wild-type cells with the patterns obtained with mutants of Euglena which either lack detectable amounts of protochlorophyll and chlorophyll or form only rudimentary chloroplasts upon light induction.No significant difference in RNA content between dark-grown, non-dividing cells containing fully developed chloroplasts and the same cells maintained in darkness for the development period can be detected. This observation is interpreted to mean that in non-dividing cells precursors for chloroplast-associated RNAs are derived from pools and pre-existing RNAs, including non-chloroplast RNAs, and that the matebolic entrapment of ³²P_i involves a light-dependent turnover and DNA-directed RNA synthesis in wild-type cells.The RNA profiles on sucrose gradients of mutants of Euglena show no remarkable deviation from the profile established for wild-type cells. The labeling patterns obtained after 24 hours of incubation in light and in darkness differ from that obtained for wild-type cells in that all mutants show less of a light-minus-dark difference than wild-type and that mutants lacking plastid-associated DNA and detectable amounts of chlorophyll incorporate considerably more ³²P_i into RNA in darkness than wild-type. One such mutant shows no significant difference in its light-dark labeling pattern.These observations indicate that cells possessing normal proplastids capable of forming functional chloroplasts regulate metabolism of RNA in darkness in a different manner than with either rudimentary chloroplasts or containing no detectable plastids structures. The possible involvement of more than one photoreceptor system in metabolic control is discussed.Supported by a grant from the National Institutes of Health, GM 14595     

Tissue specific protochlorophyll(ide) forms in dark-forced shoots of grapevine (<Emphasis Type="Italic">Vitis vinifera</Emphasis>L.)

Cuttings of grapevine (Vitis vinifera L. cv. Chardonnay) were dark-forced at least three weeks. Pigment contents, 77 K fluorescence emission, excitation spectra of the leaves, petioles, stems, transmission electron micrographs of the etioplasts from leaves, the chlorenchyma tissues of the stems were analysed. The dark-grown leaves, stems contained 8 to 10, 3 to 5 μg/g fresh weight protochlorophyllide, its esters, respectively. HPLC analysis showed that the molar ratio of the unesterified, esterified pigments was 7:3 in the shoot developed in darkness. The dark-forced leaves contained carotenoids identified as: neoxanthin, violaxanthin, antheraxanthin, lutein, β-carotene. Detailed analyses of the fluorescence spectra proved that all tissues of the dark-forced shoots had protochlorophyllide or protochlorophyll forms with emission maxima at 628, 636, 644, 655, 669 nm. The 628, 636 nm emitting forms were present in all parts of the dark-forced shoot, but dominated in the stems, which may indicate an organ specificity of the etioplast development. Variations in the distribution of the pigment forms were even found in the different tissues of the stem. The subepidermal layers were more abundant in the 655 nm form than the parenchyma cells of the inner part of the cortex, the pith. In the latter cells, the plastid differentiation stopped in intermediary stages between proplastids, etioplasts. The plastids in the subepidermal layers had developed prolamellar body structures, which were similar to those of etiolated leaves. The results highlight the importance of organ-, tissue specificity of plastid differentiation for chlorophyll biosynthesis, greening of different plant organs. This revised version was published online in June 2006 with corrections to the Cover Date.     

DEVELOPMENT OF CHLOROPLAST FINE STRUCTURE IN ASPEN TISSUE CULTURE

Chloroplast ontogeny has been examined in 42-day etiolated triploid aspen callus (Populus tremuloides Michx.) subjected to two different light conditions. White and low-intensity red illumination showed little differences in their stimulatory effects on plastid development, the red light-irradiated plastids developing only slightly more slowly. Asynchronous plastid development was noted in both lighting systems. Etioplasts contained an interconnected tubular net, phytoferritin aggregates, electron-transparent vesicles which seem to invaginate from the inner plastid membrane, membrane-bound homogeneous spheroids and starch grains. Irradiation caused various morphological changes within the proplastids; the tubular complex became transformed into the more ordered prolamellar body-like structure from which radiated membrane-bound sacs filled with electron-dense material. These sacs, characterized as thylakoid precursors, were transformed into a thylakoidal system typical of mature chloroplasts. This ontogenetic scheme represents an additional pathway for the development of photosynthetic lamellae. Other light-induced changes in the developing plastid include disappearance of phytoferritin particles and homogeneous spheroids, decrease in starch content, and appearance of osmiophilic droplets.     

Cytological Characterization of a Giant Strain of Euglena gracilis Obtained from Dark-starved Cultures

Euglena gracilis green cells were dark-starved for four months. After this period almost the entire population died, while a few giant, viable cells appeared in the culture. The giantism was maintained after repeated subcultures in growth medium in light or dark conditions. However, the phenomenon was not permanent, and the morphological characteristics of the wild-type Euglena were gradually restored. In giant cells nuclei enlarged greatly, DNA content increased and the Golgi apparatus greatly proliferated. Chloroplasts and mitochondria increased in number and size and often presented structural modifications when compared with normal Euglena. Importantly, in the giant cells that were maintained in darkness in resting or growth conditions chloroplasts persisted as structured organelles which appeared red-fluorescent under UV illumination. Whether giantism is a phenotypic or a genotypic change is still debated. In our case, the evolution of this phenomenon, chiefly the enhanced DNA content, suggests that teratism is a multiploid mutation with the possibility of a return to the normoploid condition. Constitutive chloroplasts are present in most algae, except for a few species, among which is Euglena gracilis. The persistence of differentiated plastids in darkness in giant Euglena is considered to be a return to an ancestral condition and may, therefore, be phylogenetically important.     

PLASTIDS IN LATICIFERS OF PAPAVER. I. DEVELOPMENT AND CYTOCHEMISTRY OF LATICIFER PLASTIDS IN P. SOMNIFERUM L. (PAPAVERACEAE)

Plastids were observed in all stages of laticifer differentiation in Papaver somniferum L. Plastids in laticifer initials were present as proplastids that later developed electron-dense inclusions, but never possessed the thylakoids or starch grains that characterize chloroplasts in other cells. Electron-dense inclusions in laticifer plastids were membrane-bound and appeared to arise from the accumulation of material within an invagination of the inner plastid membrane. Cytochemical studies of these plastid inclusions indicated that their matrix was not composed of crystalline protein, α-amylose, amylopectin or polysaccharide. The results suggest that the electron-dense, membrane-bound inclusions in laticifer plastids may be composed of lipoprotein.     

Phylogeny of Plastids Based on Cladistic Analysis of Gene Loss Inferred from Complete Plastid Genome Sequences

Based on the recent hypothesis on the origin of eukaryotic phototrophs, red algae, green plants, and glaucophytes constitute the primary photosynthetic eukaryotes (whose plastids may have originated directly from a cyanobacterium-like prokaryote via primary endosymbiosis), whereas the plastids of other lineages of eukaryotic phototrophs appear to be the result of secondary or tertiary endosymbiotic events (involving a phototrophic eukaryote and a host cell). Although phylogenetic analyses using multiple plastid genes from a wide range of eukaryotic lineages have been carried out, some of the major phylogenetic relationships of plastids remain ambiguous or conflict between different phylogenetic methods used for nucleotide or amino acid substitutions. Therefore, an alternative methodology to infer the plastid phylogeny is needed. Here, we carried out a cladistic analysis of the loss of plastid genes after primary endosymbiosis using complete plastid genome sequences from a wide range of eukaryotic phototrophs. Since it is extremely unlikely that plastid genes are regained during plastid evolution, we used the irreversible Camin-Sokal model for our cladistic analysis of the loss of plastid genes. The cladistic analysis of the 274 plastid protein-coding genes resolved the 20 operational taxonomic units representing a wide range of eukaryotic lineages (including three secondary plastid-containing groups) into two large monophyletic groups with high bootstrap values: one corresponded to the red lineage and the other consisted of a large clade composed of the green lineage (green plants and Euglena) and the basal glaucophyte plastid. Although the sister relationship between the green lineage and the Glaucophyta was not resolved in recent phylogenetic studies using amino acid substitutions from multiple plastid genes, it is consistent with the rbcL gene phylogeny and with a recent phylogenetic study using multiple nuclear genes. In addition, our analysis robustly resolved the conflicting/ambiguous phylogenetic positions of secondary plastids in previous phylogenetic studies: the Euglena plastid was sister to the chlorophycean (Chlamydomonas) lineage, and the secondary plastids from the diatom (Odontiella) and cryptophyte (Guillardia) were monophyletic within the red lineage.     

Differential processing of plastid development during sporangial ontogeny inThelypteris palustris schott

Direction and degree of plastid development in the tissue differentiation of sporangiogenesis inThelypteris palustris were studied, and are discussed through aspects of the plastome continuity and cell differentiation. Particular attention was paid to proplastid reproduction and segregative allocation of the plastids at the first division of the sporangial initial cell. Nascent proplastids were separately located in the outer cell for further generative differentiation. Preexisting chloroplasts were allocated to the inner cell as further vegetation cells of sporangium. Proplastids in the generative cells were followed by retarded processing of development, then transformed to amyloplasts in sponrocyte differentiation. The amyloplasts were noted due to their significance for direct transmittance of plastome to following generationsvia spores, while well developed functional chloroplasts were characterized as ending up in the ephemeral terminal of sporangial vegetative tissues.     

CHLOROPLAST DEVELOPMENT DURING SPOROGENESIS IN SIX SPECIES OF MOSSES

Chloroplast development during sporogenesis in Mnium cuspidatum, M. medium, M. rostratum, Aulacomnium heterostichum, Bartramia pomiformis, and Timmia megapolitana is as follows: During the early mitotic divisions in the sporogenous area of the capsule the number of plastids is reduced from many to one cup-shaped plastid per sporogenous cell. This single plastid divides during the early spore-mother-cell stage. A second division of plastids produces four plastids within each spore-mother-cell. A massive accumulation of starch occurs within each of the four plastids. Following meiosis, the single plastid allocated to each spore produces distinct lobes that are “blebbed” off as proplastids. A photosynthetic membrane system is established within the many proplastids as each spore matures.     

Light requirement,phytochrome and photoperiodic induction of flowering of Pharbitis nil Chois

For dark-grown seedlings of Pharbitis nil capacity to flower in response to a single inductive dark period was established by 24 h white, far-red (FR) or ruby-red (BCJ) light and by a skeleton photoperiod of 10 min red (R)-24 h dark-10 min R. FR alone was ineffective without a brief terminal (R) irradiation, confirming that the form of phytochrome immediately prior to darkness is a crucial factor for flowering in Pharbitis. The magnitude of the flowering response was significantly greater after 24 h FR or white light (WL) (at 18° C and 27° C) than after two brief skeleton R irradiations, but the increased flowering response was not attributable to photosynthetic CO₂ uptake because this could not be detected in seedlings exposed to 24 h WL at 18° C. Photophosphorylation could have contributed to the increased flowering response as photosystem I fluorescence was detectable in plants exposed to FR, BCJ, or WL, but there were large differences between flowering response and photosystem I capacity as indicated by fluorescence. We conclude that phytochrome plays a major role in photoresponses regulating flowering. There was no simple correlation between developmental changes, such as cotyledon expansion and chlorophyll formation during the 24-h irradiation period, and the capacity to flower in response to a following inductive dark period. Changes in plastid ultrastructure were considerable in light from fluorescent lamps and there was complete breakdown of the prolamellar body with or without lamellar stacking at 27 or 18° C, respectively, but plastid reorganization was minimal in FR-irradiated seedlings.Abbreviations BCJ irradiation from photographic ruby-red lamps - FR far-red light - P_fr far-red-absorbing from of phytochrome - P total phytochrome content - R red light - WL white light from fluorescent lamps     

Deregulation of Light-Induced Plastidogenesis in Etiolated Euglena gracilis Klebs Treated with DNA Hypermethylating 3'-Azido-3'-deoxythymidine

Abstract: The effect of the DNA hypermethylating 3'-azido-3'-deoxythymidine (AZT) on plastidogenesis was investigated on asynchronous, etiolated Euglena gracilis exposed to continuous light for 72 h. Based on (i) fluorescence and electron microscope aspects of the plastids, (ii) cytochemical localizations of functional PSI and PSII, (iii) immunolocalization of LHCII apoproteins, and (iv) spectrophotometric and HPLC analyses of the photosynthetic pigments, it was found that AZT, at a dose of 5 μM, which does not encroach on cell viability and only slightly interferes with cell proliferation, causes profound alterations of plastids in 10 - 15 % of the cells, without apparently affecting the rest of the cell population. Proplastid-to-chloroplast transformation slowed in this cell sub-population and occurred without the normal co-regulation that characterizes the process in wild type Euglena. In particular, thylakoid assembly was partially prevented while building materials continued to be synthesized and accumulated in the stroma. Chlorophylls were over-synthesized, while carotenoids, phaeophytin and phylloquinone dramatically diminished. The assemblage of PSI and PSII was inhibited. The external envelopes and thylakoid membranes were frequently damaged. Plastids, whose total volume increased with respect to the controls, were often malformed and interconnected. Their fluorescence under UV light declined quickly. The fact that AZT acts specifically at the plastid level, causing effects that are greatly opposed to those previously observed in the alga treated with the DNA demethylating 5-azacytidine, points to a relationship between DNA methylation and plastid differentiation in Euglena.     

Changes in DNA methylation during somatic embryogenesis in <Emphasis Type="Italic">Cucurbita pepo</Emphasis> L.

Three pumpkin embryogenic lines were initiated on wounded zygotic embryos cultured on medium with or without 2,4-dichlorophenoxyacetic acid (2,4-D). Somatic embryo development was controlled by the availability of various compounds in the medium: presence/absence of 2,4-D, nitrogen sources. The highest rate of DNA methylation was in the early embryo stages, predominantly on MSC medium with 2,4-D and on auxin-free medium supplemented with 1.0 mM NH₄Cl. DNA methylation was correlated with early embryo development in a manner that was not exclusively dependent on the presence/absence of exogenous auxin. DNA methylation decreased during embryo maturation on auxin-free MSC medium and on auxin-free MSC supplemented with 12.3 M 5-azacytidine (5-azaC). The embryogenic features of the pumpkin tissue were preserved, even after a 2-month treatment with 5-azaC.Abbreviations 5-azaC 5-Azacytidine - CRED-RA Coupled restriction enzyme digestion and random amplification - 2,4-D 2,4-Dichlorophenoxyacetic acid - DNMRT Duncans new multiple range test - IAA Indole-3-acetic acid - 5-mC 5-Methylcytosine     

Epigenetics of long-term somatic embryogenesis in <Emphasis Type="Italic">Theobroma cacao</Emphasis> L.: DNA methylation and recovery of embryogenic potential

In Theobroma cacao L., declined embryogenic potential was observed in regenerated somatic embryos from long-term secondary somatic embryogenesis (SE). In order to explore the relationship between DNA methylation and the long-term secondary SE, the embryogenic potential and global DNA methylation levels in young (12 months-old), aged (36 months-old) and extra somatic embryogenesis (39 months-old) subjected to different 5-Azacytidine (5-azaC) treatments were comparatively assessed. Global DNA methylation levels increased in aged somatic embryos with long-term in vitro culture, but 5-azaC-supplemented treatments resulted in unaltered levels. In addition, DNA methylation pattern during SE was not affected by 5-azaC. DNA methylation increased during SE expression. Interestingly, the extra SE induction showed that aged somatic embryos can recovery the embryogenic potential in treatment supplemented with 5-azaC at specific concentration. The outcome of this study suggested that the long-term SE in cacao induced the decline on embryogenic potential, which can be reversible trough 5-azaC supplementation. Besides, increased DNA methylation levels might be a response to the stress conditions that plant cells were exposed to during SE.     

Antimutators of mitochondrial and nuclear DNA in Saccharomyces cerevisiae. Relationship with gamma-ray sensitivity

Summary In Saccharomyces cerevisiae ten antimutator mutants have been isolated. The spontaneous occurrence of mitochondrial mutants resistant to erythromycin, oligomycin, and diuron is decreased 2-60-fold in these strains. The rate of forward and reverse spontaneous mutations of the nuclear genome is also reduced. The meiotic progenies arising from the crosses of seven mutants (LB₁, LB₂, LB₄, LB₅, LB₆, LB₇, LB₁₀) with an isogenic parental strain exhibit 2:2 segregations and therefore are the result of mutations in a single nuclear gene. The six mutants LB₁, LB₂, LB₄, LB₆, LB₇, LB₁₀ are semidominant and determine six complementation groups. The mutant LB₅ is dominant and therefore cannot be assigned to any complementation group. The mutants. LB₁, LB₄ and LB₁₀ are gamma-ray sensitive and, by tetrad analysis, it has been shown that gamma-ray sensitivity and spontaneous antimutability are the result of a single nuclear gene mutation. The other three mutants LB₃, LB₈ and LB₉ exhibit complex tetrad segregations typical of cytoplasmic inheritance and do not complement each other. However, although the mutations are semidominant, it has not been possible to detect any antimutator cytoductant among some 500 cytoductants carrying the kar1-1 nucleus. These results suggest that either several nuclear genes are involved in the expression of the antimutator phenotype or that the antimutator gene is located on nonchromosomal elements of the nucleus. The present study leads to the conclusion that a large number of nuclear genes are able to control simultaneously the spontaneous mutation rate of nuclear and mitochondrial genes. Since out of the ten antimutator mutants, three are also deficient in the repair of gamma-ray damage, it is also concluded that spontaneous and gamma-ray-induced lesions of DNA can be repaired by the same error-free process.     

Rapid induction of genomic demethylation and T-DNA gene expression in plant cells by 5-azacytosine derivatives

We have optimized conditions for demethylation of the genome and induction of a silent, hypermethylated T-DNA gene (ipt) by 5-azacytosine (5-azaCyt) derivatives in a suspension culture of tobacco cells. In this system, 5-azacytidine (5-azaC) is more effective in causing genomic demethylation and ipt gene induction than 5-azaCyt or 5-azadeoxycytidine (5-azadC). A single treatment with 2.5 M 5-azaC resulted in a maximal level of ipt gene induction without inhibiting cell growth. However, we could not reduce the level of genomic methylation below approximately 2/3 of that found in untreated controls, even after extensive 5-azaC treatment. Furthermore, remethylation of the genome occurred after removal of 5-azaC. The use of 5-azaC as an inducer of silent plant genes is discussed, along with differences in the response of plant and animal genomes to demethylating agents.Abbreviations C cytidine - Cyt cytosine - 5-azaCyt 5-azacytosine - 5-azaC 5-azacytidine - 5-azadC 5-azadeoxycytidine - m⁵Cyt 5-methylcytosine     

delta-Aminolevulinic Acid Biosynthesis from Glutamatein Euglena gracilis: Photocontrol of Enzyme Levels in a Chlorophyll-Free Mutant

Wild-type Euglena gracillis cells synthesize the key chlorophyll precursor, δ-aminolevulinic acid (ALA), from glutamate in their plastids. The synthesis requires transfer RNA^Glu (tRNA^Glu) and the three enzymes, glutamyl-tRNA synthetase, glutamyl-tRNA reductase, and glutamate-1-semialdehyde aminotransferase. Non-greening mutant Euglena strain W₁₄ZNaIL does not synthesize ALA from glutamate and is devoid of the required tRNA^Glu. Other cellular tRNA^Glus present in the mutant cells were capable of being charged with glutamate, but the resulting glutamyl-tRNAs did not support ALA synthesis. Surprisingly, the mutant cells contain all three of the enzymes, and their cell extracts can convert glutamate to ALA when supplemented with tRNA^Glu obtained from wild-type cells. Activity levels of the three enzymes were measured in extracts of cells grown under a number of light conditions. All three activities were diminished in extracts of cells grown in complete darkness, and full induction of activity required 72 hours of growth in the light. A light intensity of 4 microeinsteins per square meter per second was sufficient for full induction. Blue light was as effective as white light, but red light was ineffective, in inducing extractable enzyme activity above that of cells grown in complete darkness, indicating that the light control operates via the nonchloroplast blue light receptor in the mutant cells. Of the three enzyme activities, the one that is most acutely affected by light is glutamate-1-semialdehyde aminotransferase, as has been previously shown for wild-type Euglena cells. These results indicate that the enzymes required for ALA synthesis from glutamate are present in an active form in the nongreening mutant cells, even though they cannot participate in ALA formation in these cells because of the absence of the required tRNA^Glu, and that the activity of all three enzymes is regulated by light. Because the absence of plastid tRNA^Glu precludes the synthesis of proteins within the plastids, the three enzymes must be synthesized in the cytoplasm and their genes encoded in the nucleus in Euglena.     

基于森林群落和光谱曲线特征分异的福建省森林生物量遥感反演

基于福建省Landsat8 OLI影像,利用混合像元分解模型筛选出"纯净"的植被像元,提取296个调查样地对应植被像元的红光和近红外波段的中心波长(分别CWR和CWNIR)及其对应的反射率(分别R和NIR),构建以(NIR-R)/(CWNIR-CWR)为特征指数的叶生物量回归模型。然后根据针叶林、阔叶林及针阔混交林叶生物量与干、枝、叶所组成的地上生物量的关系方程,结合福建省植被覆盖分类数据,估测了整个福建省针叶林、阔叶林、混交林的地上生物量,并绘制了福建省地上生物量分布图。结果表明:红光和近红外两个波段反射率和其中心波长所组成的斜率与叶生物量相关性显著,与针叶林、阔叶林、混交林叶生物量的精度分别达到70.55%、68.89%、51.75%,采用这种方法对福建省叶生物量和地上总生物量进行估算,并进行精度验证,其中,针叶林、阔叶林、混交林叶物量的模型误差(RMSE)分别达到29.2467 t/hm~2(R~2=66.64%)、14.0258 t/hm~2(R~2=61.13%)、10.1788 t/hm~2(R~2=55.43%),地上总生物量的模型精度分别达到49.8315 t/hm~2(R~2=54.65%)、45.1820 t/hm~2(R~2=49.01%)、41.5131 t/hm~2(R~2=38.79%),这说明,采用红光波段和近红外波段与其中心波长所组成的斜率估测森林叶生物量,进而估算其地上总生物量的方法是可行的。     

Mutations in the dim-1 gene of Neurospora crassa reduce the level of DNA methylation

Mutants that show reduced DNA methylation were identified in a mutant screen based on the assumptions that (i) the nucleoside analog 5-azacytidine (5-azaC) promotes the formation of potentially lethal DNA-methyltransferase adducts; (ii) reduction in DNA methyltransferase will decrease the sensitivity of cells to 5-azaC; and (iii) this potential selective advantage will be enhanced in mutants that are deficient in the repair of 5-azaC-induced DNA damage. Of fifteen potential repair mutants screened for sensitivity to 5-azaC, five (mus-9, mus-10, mus-11, mus-18, and uvs-3) showed moderately increased sensitivity and two (mus-20, mei-3) showed highly increased sensitivity. A mus-20 mutation was used to isolate three non-complementing methylation mutants. The mutations, named dim-1 (defective in methylation), reduced female fertility, reduced methylation by 40–50%, and altered patterns of methylation. In wild-type strains hypomethylation perse fails to alter methylation specificity. We demonstrate a growth-phase-dependent change in methylation patterns, detectable only in hypomethylated DNA from dim ⁺ cultures. This may represent a growth-phase-dependent change in the relative amounts of distinct species of methyltransferase, one of which may be encoded by the dim-1 gene. Received: 3 January 1998 / Accepted: 26 March 1998     

Pigments associated with the flagellum ofEuglena gracilis

The pigments associated with the flagellum of the phytoflagellateEuglena gracllis were characterized by HPLC. The pigment pattern of the wild-type strain was compared with a set of white mutants which did not display phototaxis and photoaccumulation in response to blue light. Flagella of the wild type contained FMN and FAD. Two mutants which lacked the stigma but retained a small paraxonemal body (PAB) contained less flavins. The whiteEuglena mutant FB, which retained a residual stigma and also a PAB, and the white phytoflagellateAstasia longa, a close relative ofEuglena, had normal amounts of flagellar flavins. Cells and flagella ofEuglena wild type contained an unldentified pterin-like pigment, called Pt₁₆, which was substantially reduced inAstasia and theEuglena mutants. A third pigment, designated P₅₂₈ with major absorption at 528 nm and fluorescence emission at 550 nm was present mainly in flagella. The association of the three pigment types with flagella and their respective alterations in the white strains indicates their possible role in photoreception. Dedicated to Pill-Soon Song on the occasion of his 60th birthday.