脉孢菌lca-1基因调控无性产孢及类胡萝卜素的合成

类胡萝卜素是很多生物细胞内重要的抗氧化剂,具有保护细胞免受紫外线伤害的功能。粗糙脉孢菌是少数几个类胡萝卜素合成基因比较清楚的真菌之一,为了深入了解该菌类胡萝卜素合成调控机制,通过对粗糙脉孢菌基因突变体库中6,087株突变体进行筛选,新发现6个基因敲除突变体营养生长正常,但类胡萝卜素的合成降低,其中表型较好的1个突变体,其无性产孢量与类胡萝卜素合成量均明显降低。鉴定发现该突变体所缺失的基因编码一种依赖ATP的染色体重建复合体的ATP酶链ISW1,将该基因命名为lca-1。进一步测定发现lca-1基因的突变导     

Complete DNA sequence, specific Tn5 insertion map, and gene assignment of the carotenoid biosynthesis pathway of Rhodobacter sphaeroides.

The carotenoid biosynthesis genes form a cluster within the genome of Rhodobacter sphaeroides, lying in the middle of a larger cluster and 45 kb in length, which contains genes for bacteriochlorophyll biosynthesis and for the reaction center and light-harvesting apoproteins. The positions and approximate limits of the carotenoid genes were determined previously by localized transposon Tn5 mutagenesis and by comparison with the closely related Rhodobacter capsulatus carotenoid gene cluster. In this report, analysis of the DNA and deduced amino acid sequences of the carotenoid genes in R. sphaeroides are presented. Twenty-five Tn5 insertion mutants were used to produce a base-specific Tn5 insertion map of this region, and carotenoid gene assignment was supported by spectroscopic, ultrastructural, and high-pressure liquid chromatography analyses of these mutants. A region in the 3' end of crtD which affects bacteriochlorophyll biosynthesis was discovered, and CrtA was found to possess a proline-rich C-terminal region containing a repeated (Ala-Pro)n motif. CrtF also showed a high degree of sequence conservation with eukaryotic O-methyltransferases. This study provides gene sequences and assignments based upon a comprehensive structural, spectroscopic, and biochemical analysis of a range of carotenoid biosynthetic mutants; in each mutation, the point of Tn5 insertion is determined accurate to 1 bp on the gene cluster.     

Human mutations in glucose 6-phosphate dehydrogenase reflect evolutionary history.

Glucose 6-phosphate dehydrogenase (G6PD) is a cytosolic enzyme encoded by a housekeeping X-linked gene whose main function is to produce NADPH, a key electron donor in the defense against oxidizing agents and in reductive biosynthetic reactions. Inherited G6PD deficiency is associated with either episodic hemolytic anemia (triggered by fava beans or other agents) or life-long hemolytic anemia. We show here that an evolutionary analysis is a key to understanding the biology of a housekeeping gene. From the alignment of the amino acid (aa) sequence of 52 glucose 6-phosphate dehydrogenase (G6PD) species from 42 different organisms, we found a striking correlation between the aa replacements that cause G6PD deficiency in humans and the sequence conservation of G6PD: two-thirds of such replacements are in highly and moderately conserved (50-99%) aa; relatively few are in fully conserved aa (where they might be lethal) or in poorly conserved aa, where presumably they simply would not cause G6PD deficiency. This is consistent with the notion that all human mutants have residual enzyme activity and that null mutations are lethal at some stage of development. Comparing the distribution of mutations in a human housekeeping gene with evolutionary conservation is a useful tool for pinpointing amino acid residues important for the stability or the function of the corresponding protein. In view of the current explosive increase in full genome sequencing projects, this tool will become rapidly available for numerous other genes.     

Molecular cloning and sequence analysis of the crtB gene of Thermus thermophilus HB27, an extreme thermophile producing carotenoid pigments.

We have cloned and sequenced a 1.5-kb chromosomal fragment of Thermus thermophilus which promoted the overproduction of carotenoids in T. thermophilus. An open reading frame (ORF-A) coding for a polypeptide with 289 amino acids was responsible for carotenoid overproduction. The putative ORF-A protein showed significant homology with the amino acid sequences of crtB gene products (phytoene syntheses) of other microorganisms. The clone containing the ORF-A on a multicopy plasmid produced about three times as much carotenoid as that produced by the host strain, suggesting that the crtB gene product is a rate-limiting enzyme for carotenoid biosynthesis in T. thermophilus.     

Nucleotide sequence of the Synechococcus sp. PCC7942 branching enzyme gene (glgB): expression in Bacillus subtilis

The nucleotide sequence of the Synechococcus sp. PCC7942 glgB gene has been determined. The gene contains a single open reading frame (ORF) of 2322 bp encoding a polypeptide of 774 amino acids (aa) with an Mr of 89,206. Extensive sequence similarity exists between the deduced aa sequence of the Synechococcus sp. glgB gene product and that of the Escherichia coli branching enzyme in the middle portions of the proteins (62% identical aa). In contrast, the N-terminal portions shared little homology. The sequenced region which follows glgB contains an ORF encoding 79 aa of the N terminus of a polypeptide that shares extensive sequence similarity (41% identical aa) with human and rat uroporphyrinogen decarboxylase. This suggests that the region downstream from glgB contains the hemE gene and, therefore, that the organization of genes involved in glycogen biosynthesis in Synechococcus sp. is different from that described for E. coli. A fusion gene was constructed between the 5' end of the Bacillus licheniformis penP gene and the Synechococcus sp. glgB gene. The fusion gene was efficiently expressed in the Gram+ micro-organism Bacillus subtilis and specified a branching enzyme with an optimal temperature for activity similar to the wild-type enzyme.     

Cloning of tangerine from tomato reveals a carotenoid isomerase essential for the production of beta-carotene and xanthophylls in plants

Carotenoid biosynthesis in plants has been described at the molecular level for most of the biochemical steps in the pathway. However, the cis-trans isomerization of carotenoids, which is known to occur in vivo, has remained a mystery since its discovery five decades ago. To elucidate the molecular mechanism of carotenoid isomerization, we have taken a genetic map-based approach to clone the tangerine locus from tomato. Fruit of tangerine are orange and accumulate prolycopene (7Z,9Z,7'Z,9'Z-tetra-cis-lycopene) instead of the all-trans-lycopene, which normally is synthesized in the wild type. Our data indicate that the tangerine gene, designated CRTISO, encodes an authentic carotenoid isomerase that is required during carotenoid desaturation. CRTISO is a redox-type enzyme structurally related to the bacterial-type phytoene desaturase CRTI. Two alleles of tangerine have been investigated. In tangerine(mic), loss of function is attributable to a deletion mutation in CRTISO, and in tangerine(3183), expression of this gene is impaired. CRTISO from tomato is expressed in all green tissues but is upregulated during fruit ripening and in flowers. The function of carotene isomerase in plants presumably is to enable carotenoid biosynthesis to occur in the dark and in nonphotosynthetic tissues.     

Phylogenetic and Evolutionary Patterns in Microbial Carotenoid Biosynthesis Are Revealed by Comparative Genomics

Background

Carotenoids are multifunctional, taxonomically widespread and biotechnologically important pigments. Their biosynthesis serves as a model system for understanding the evolution of secondary metabolism. Microbial carotenoid diversity and evolution has hitherto been analyzed primarily from structural and biosynthetic perspectives, with the few phylogenetic analyses of microbial carotenoid biosynthetic proteins using either used limited datasets or lacking methodological rigor. Given the recent accumulation of microbial genome sequences, a reappraisal of microbial carotenoid biosynthetic diversity and evolution from the perspective of comparative genomics is warranted to validate and complement models of microbial carotenoid diversity and evolution based upon structural and biosynthetic data.

Methodology/Principal Findings

Comparative genomics were used to identify and analyze in silico microbial carotenoid biosynthetic pathways. Four major phylogenetic lineages of carotenoid biosynthesis are suggested composed of: (i) Proteobacteria; (ii) Firmicutes; (iii) Chlorobi, Cyanobacteria and photosynthetic eukaryotes; and (iv) Archaea, Bacteroidetes and two separate sub-lineages of Actinobacteria. Using this phylogenetic framework, specific evolutionary mechanisms are proposed for carotenoid desaturase CrtI-family enzymes and carotenoid cyclases. Several phylogenetic lineage-specific evolutionary mechanisms are also suggested, including: (i) horizontal gene transfer; (ii) gene acquisition followed by differential gene loss; (iii) co-evolution with other biochemical structures such as proteorhodopsins; and (iv) positive selection.

Conclusions/Significance

Comparative genomics analyses of microbial carotenoid biosynthetic proteins indicate a much greater taxonomic diversity then that identified based on structural and biosynthetic data, and divides microbial carotenoid biosynthesis into several, well-supported phylogenetic lineages not evident previously. This phylogenetic framework is applicable to understanding the evolution of specific carotenoid biosynthetic proteins or the unique characteristics of carotenoid biosynthetic evolution in a specific phylogenetic lineage. Together, these analyses suggest a “bramble” model for microbial carotenoid biosynthesis whereby later biosynthetic steps exhibit greater evolutionary plasticity and reticulation compared to those closer to the biosynthetic “root”. Structural diversification may be constrained (“trimmed”) where selection is strong, but less so where selection is weaker. These analyses also highlight likely productive avenues for future research and bioprospecting by identifying both gaps in current knowledge and taxa which may particularly facilitate carotenoid diversification.     

Analysis of the genes flanking xabB: a methyltransferase gene is involved in albicidin biosynthesis in Xanthomonas albilineans

Transposon mutagenesis and complementation studies previously identified a gene (xabB) for a large (526kDa) polyketide-peptide synthase required for biosynthesis of albicidin antibiotics and phytotoxins in the sugarcane leaf scald pathogen Xanthomonas albilineans. A cistron immediately downstream from xabB encodes a polypeptide of 343aa containing three conserved motifs characteristic of a family of S-adenosyl-L-methionine (SAM)-dependent O-methyltransferases. Insertional mutagenesis and complementation indicate that the product of this cistron (designated xabC) is essential for albicidin production, and that there is no other required downstream cistron. The xabB promoter region is bidirectional, and insertional mutagenesis of the first open reading frame (ORF) in the divergent gene also blocks albicidin biosynthesis. This divergent ORF (designated thp) encodes a protein of 239aa displaying high similarity to several IS21-like transposition helper proteins. The thp cistron is not located in a recognizable transposon, and is probably a remnant from a past transposition event that may have contributed to the development of the albicidin biosynthetic gene cluster. Failure of 'in trans' complementation of thp indicates that a downstream cistron transcribed with thp is required for albicidin biosynthesis.     

PD-1胞外段cDNA在真核细胞的表达与其功能鉴定

PD-L/PD-1是参与肿瘤免疫逃避的一条抑制性信号途径。为了用可溶性的PD 1受体阻断PD-L/PD-1的相互作用 ,将小鼠PD-1胞外段 (aa1-aa167)作为独立可溶性分子进行了真核表达 ,并对其功能进行鉴定。构建了编码小鼠PD-1胞外段cDNA(sPD 1)的真核质粒表达载体pPD-1A和编码sPD-1-GFP重组蛋白的真核质粒表达载体pPD-1B ;细胞转染实验表明其表达产物主要是分泌到细胞外的可溶性产物 (sPD-1) ,流式细胞仪检测表明sPD-1可有效结合PD-1配体 ;肿瘤细胞杀伤实验表明 ,sPD-1作用于肿瘤细胞或在脾淋巴细胞激活过程中作用于淋巴细胞 ,均可增强Hsp70-H22抗原肽复合物激活的脾淋巴细胞杀伤肿瘤细胞的作用。sPD-1真核表达载体的构建为在肿瘤局部表达抑制性共刺激分子的可溶性受体 ,拮抗肿瘤微环境中负调节因素对T细胞的抑制作用 ,增强机体的抗肿瘤能力 ,提供了一种新的肿瘤基因治疗手段     

The <Emphasis Type="Italic">pds2</Emphasis> mutation is a lesion in the <Emphasis Type="Italic">Arabidopsis</Emphasis> homogentisate solanesyltransferase gene involved in plastoquinone biosynthesis

Plastoquinone plays critical roles in photosynthesis, chlororespiration and carotenoid biosynthesis. The previously isolated pds2 mutant from Arabidopsis was deficient in tocopherol and plastoquinone accumulation, and the biochemical phenotype of this mutant could not be reversed by externally applied homogentisate, suggesting a later step in tocopherol and/or plastoquinone biosynthesis had been disrupted. Recently, the protein encoded by At3g11950 (AtHST) was shown to condense homogentisate with solanesyl diphosphate (SDP), the substrate for plastoquinone synthesis, but not phytyl diphosphate (PDP), the substrate for tocopherol biosynthesis. We have sequenced the AtHST allele in the pds2 mutant background and identified an in-frame 6 bp (2 aa) deletion in the gene. The pds2 mutation could be functionally complemented by constitutive expression of AtHST, demonstrating that the molecular basis for the pds2 mutation is this 6 bp-lesion in the AtHST gene. Confocal microscopy of EGFP tagged AtHST suggested that AtHST is localized to the chloroplast envelope, supporting the hypothesis that plastoquinone synthesis occurs in the plastid.     

Structure and functional analysis of a marine bacterial carotenoid biosynthesis gene cluster and astaxanthin biosynthetic pathway proposed at the gene level.

A carotenoid biosynthesis gene cluster for the production of astaxanthin was isolated from the marine bacterium Agrobacterium aurantiacum. This cluster contained five carotenogenic genes with the same orientation, which were designated crtW, crtZ, crtY, crtI, and crtB. The stop codons of individual crt genes except for crtB overlapped the start codons of the following crt genes. Escherichia coli transformants carrying the Erwinia uredovora carotenoid biosynthesis genes provide suitable substrates for carotenoid biosynthesis. The functions of the five crt genes of A. aurantiacum were determined through chromatographic and spectroscopic analyses of the pigments accumulated in some E. coli transformants carrying various combinations of the E. uredovora and A. aurantiacum carotenogenic genes. As a result, the astaxanthin biosynthetic pathway is proposed for the first time at the level of the biosynthesis genes. The crtW and crtZ gene products, which mediated the oxygenation reactions from beta-carotene to astaxanthin, were found to have low substrate specificity. This allowed the production of many presumed intermediates of astaxanthin, i.e., adonixanthin, phoenicoxanthin (adonirubin), canthaxanthin, 3'-hydroxyechinenone, and 3-hydroxyechinenone.     

Carotenoid biosynthetic pathway: molecular phylogenies and evolutionary behavior of crt genes in eubacteria

Phylogenetic analysis of carotenoid biosynthetic pathway genes and their evolutionary rate variations were studied among eubacterial taxa. The gene sequences for the enzymes involved in this pathway were obtained for major phylogenetic groups of eubacteria (green sulfur bacteria, green nonsulphur bacteria, Gram-positive bacteria, proteobacteria, flavobacteria, cyanobacteria) and archeabacteria. These gene datasets were distributed under five major steps of carotenoid biosynthesis in eubacteria; isoprenoid precursor biosynthesis, phytoene synthesis, dehydrogenation of phytoene, lycopene cyclization, formation of acyclic xanthophylls, formation of cyclic xanthophylls and carotenoid biosynthesis regulation. The NJ algorithm was used on protein coding DNA sequences to deduce the evolutionary relationship for the respective crt genes among different eubacterial lineages. The rate of nonsynonymous nucleotide substitutions per nonsynonymous site (d(N)) and synonymous nucleotide substitutions per synonymous site (d(S)) were calculated for different clades of the respective phylogenetic tree for specific crt genes. The phylogenetic analysis suggests that evolutionary pattern of crt genes in eubacteria is characterized by lateral gene transfer and gene duplication events. The d(N) values indicate that carotenoid biosynthetic genes are more conserved in proteobacteria than in any other eubacterial phyla. Furthermore, of the genes involved in carotenoid biosynthesis pathway, structural genes evolve slowly than the regulatory genes in eubacteria.     

Characterization of the 9-cis-epoxycarotenoid dioxygenase gene family and the regulation of abscisic acid biosynthesis in avocado

Avocado (Persea americana Mill. cv Lula) is a climacteric fruit that exhibits a rise in ethylene as the fruit ripens. This rise in ethylene is followed by an increase in abscisic acid (ABA), with the highest level occurring just after the peak in ethylene production. ABA is synthesized from the cleavage of carotenoid precursors. The cleavage of carotenoid precursors produces xanthoxin, which can subsequently be converted into ABA via ABA-aldehyde. Indirect evidence indicates that the cleavage reaction, catalyzed by 9-cis-epoxycarotenoid dioxygenase (NCED), is the regulatory step in ABA synthesis. Three genes encoding NCED cleavage-like enzymes were cloned from avocado fruit. Two genes, PaNCED1 and PaNCED3, were strongly induced as the fruit ripened. The other gene, PaNCED2, was constitutively expressed during fruit ripening, as well as in leaves. This gene lacks a predicted chloroplast transit peptide. It is therefore unlikely to be involved in ABA biosynthesis. PaNCED1 was induced by water stress, but expression of PaNCED3 was not detectable in dehydrated leaves. Recombinant PaNCED1 and PaNCED3 were capable of in vitro cleavage of 9-cis-xanthophylls into xanthoxin and C(25)-apocarotenoids, but PaNCED2 was not. Taken together, the results indicate that ABA biosynthesis in avocado is regulated at the level of carotenoid cleavage.     

Apocarotenoid biosynthesis in arbuscular mycorrhizal roots: contributions from methylerythritol phosphate pathway isogenes and tools for its manipulation

During colonization by arbuscular mycorrhizal (AM) fungi plant roots frequently accumulate two types of apocarotenoids (carotenoid cleavage products). Both compounds, C(14) mycorradicin and C(13) cyclohexenone derivatives, are predicted to originate from a common C(40) carotenoid precursor. Mycorradicin is the chromophore of the "yellow pigment" responsible for the long-known yellow discoloration of colonized roots. The biosynthesis of apocarotenoids has been investigated with a focus on the two first steps of the methylerythritol phosphate (MEP) pathway catalyzed by 1-deoxy-D-xylulose 5-phosphate synthase (DXS) and 1-deoxy-D-xylulose 5-phosphate reductoisomerase (DXR). In Medicago truncatula and other plants the DXS2 isogene appears to be specifically involved in the AM-mediated accumulation of apocarotenoids, whereas in the case of DXR a single gene contributes to both housekeeping and mycorrhizal (apo)carotenoid biosynthesis. Immunolocalization of DXR in mycorrhizal maize roots indicated an arbuscule-associated protein deposition, which occurs late in arbuscule development and accompanies arbuscule degeneration and breakdown. The DXS2 isogene is being developed as a tool to knock-down apocarotenoid biosynthesis in mycorrhizal roots by an RNAi strategy. Preliminary results from this approach provide starting points to suggest a new kind of function for apocarotenoids in mycorrhizal roots.