中国苋科苋属新记录种——鲍氏苋和布氏苋

我国有记录的苋属植物20余种,主要为外来杂草。苋属植物形态相近,常被误鉴。作者从送检的误鉴的标本中发现2个新外来种,根据拉丁文名种加词释义,分别命名为鲍氏苋(Amaranthus powellii S. Watson)和布氏苋(A. bouchonii Thell.)。鲍氏苋和布氏苋形态相近,分别产自美国西南部和欧洲,雌雄同株,具3～5雌花花被片,花被片不等长,等于或短于胞果,胞果开裂或不开裂。鲍氏苋和布氏苋可通过花被片数目和形态、胞果是否开裂、苞片大小相区分。该文还提供了鲍氏苋和布氏苋的中文形态描述及彩色图片,并对其分布、生境和危害状况进行了报道。     

光对尾穗苋幼苗内苋红素合成的诱导

不同苗龄的尾穗苋黄化苗对10 min,15Wm~(-2)白光的反应能力不同。光诱导的苋红素合成始于播种后第 20h,至50h合成能力最大,82h以后幼苗对短时光照的反应能力趋于消失。苋红素合成的滞后期为3h,光处理后18h色素积累达到高峰。光调节苋红素合成符合红光—远红光可逆诱导反应等两个基本模式,确证光敏色素参与调控苋红素合成.     

中国新归化种广布苋的分布及其与腋花苋的关系

本文报道了中国苋科苋属的一新记录归化植物——广布苋(Amaranthus graecizans L.).该种植株常匍匐,叶片狭长椭圆形至线状披针形,有时线形或菱形卵形,长至少为宽的2.5倍,花被片3枚,近等长,与中国有分布的本属其他物种有所区别.该种原产于欧洲地中海地区、非洲北部至亚洲西部,归化于欧洲其他地区、东亚、澳...     

长芒苋--中国苋属一新归化种

首次记载长芒苋 Amaranthus palmeri S. Watson,一种原产美国西南部和墨西哥北部的有毒植物,为中国归化杂草一新记录.     

长芒苋——中国苋属一新归化种

首次记载长芒苋Amaranthus palmeri S. Watson,一种原产美国西南部和墨西哥北部的有毒植物,为中国归化杂草一新记录。     

基于ITS序列的中国外来苋属植物系统关系分析

通过ITS序列对21种中国外来苋属植物进行系统进化关系研究。通过ITS序列种间、种内遗传距离分析,发现苋属种间变异为0~0.055 1,种内变异为0~0.009 2。使用TAXON DNA软件分析ITS序列种间、种内变异的分布图看出规律,结果表明苋属ITS序列的种间变异适中,种间变异明显大于种内变异。采用最大似然法(ML)构建的系统树将中国苋属分为5或6个进化支(根据自展支持率取值不同)。异株苋亚属长芒苋和苋亚属刺苋聚类在一起,西部苋和糙果苋单独成为一个进化支。苋亚属中苋组苋亚组反枝苋和绿穗苋亚组鲍氏苋有着更近的亲缘关系,苋组苋亚组尾穗苋和绿穗苋亚组绿穗苋、繁穗苋等亲缘关系更近。白苋亚属分为2或3个类群,根据自展支持率取值不同,合被苋可以和白苋、北美苋并为一支,也可以单独成为一支。综上所述,该文认为苋属经典分类体系中3亚属或2~3组的分类地位不成立,建议中国苋属采取5组2亚组或6组2亚组的分类体系。5组2亚组分别由长芒苋组、糙果苋组、苋组(苋亚组和绿穗苋亚组)、白苋组和凹头苋组组成。其中,合被苋也可从白苋组分出,单独构成1组,形成6组2亚组的分类体系。表明该序列对苋属大部分种类分类效果较好,对西部苋和糙果苋复合群,绿穗苋复合群以及白苋亚属的分类价值不高。     

中国苋属植物酯酶同工酶研究

用聚丙烯酰胺凝胶盘状电泳技术对中国苋属植物１３种的酯酶同工酶谱进行了研究。结果表明：苋属植物酯酶同工酶有２条属的标志带在生化水平上认为是一个自然的分类群;     

Ca~(2 )和CaM抑制剂在尾穗苋幼苗苋红素形成中的效应

光和BA均可促进尾穗苋幼苗苋红素的形成。Ca~(2 )专一性螯合剂EGTA,Ca~(2 )通道竞争性抑制剂 La~(3 )以及 CaM拮抗剂氯丙嗪(CPZ)都能明显地抑制光、暗下苋红素的形成。增加培养介质中Ca~(2 )不但可以促进苋红素形成,而且能部分逆转La~(3 )的抑制效应。La~(3 )和 CPZ亦可抑制 BA促进苋红素的形成。     

林地苋属(苋科)一新种

Yunnan(云南):Lushui(泸水),alt.900m,near streams among Shrubs,Exp.Liujiang(柳江考察队)481(holotype, KUN);Daguan(大关),alt.2200m,in broad-leaved ever-green forest along the valley,Fl.yellowish green,1975-07-20,B.S.Sun(孙必兴)699. 本新种与林地苋Psilotrichum ferrugineum近缘,其区别点为前者花被片被毛;苞片披针形;穗状花序腋生及顶生;体态非纤细草本而为半灌木。     

Leishmaniasis worldwide and global estimates of its incidence

As part of a World Health Organization-led effort to update the empirical evidence base for the leishmaniases, national experts provided leishmaniasis case data for the last 5 years and information regarding treatment and control in their respective countries and a comprehensive literature review was conducted covering publications on leishmaniasis in 98 countries and three territories (see 'Leishmaniasis Country Profiles Text S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14, S15, S16, S17, S18, S19, S20, S21, S22, S23, S24, S25, S26, S27, S28, S29, S30, S31, S32, S33, S34, S35, S36, S37, S38, S39, S40, S41, S42, S43, S44, S45, S46, S47, S48, S49, S50, S51, S52, S53, S54, S55, S56, S57, S58, S59, S60, S61, S62, S63, S64, S65, S66, S67, S68, S69, S70, S71, S72, S73, S74, S75, S76, S77, S78, S79, S80, S81, S82, S83, S84, S85, S86, S87, S88, S89, S90, S91, S92, S93, S94, S95, S96, S97, S98, S99, S100, S101'). Additional information was collated during meetings conducted at WHO regional level between 2007 and 2011. Two questionnaires regarding epidemiology and drug access were completed by experts and national program managers. Visceral and cutaneous leishmaniasis incidence ranges were estimated by country and epidemiological region based on reported incidence, underreporting rates if available, and the judgment of national and international experts. Based on these estimates, approximately 0.2 to 0.4 cases and 0.7 to 1.2 million VL and CL cases, respectively, occur each year. More than 90% of global VL cases occur in six countries: India, Bangladesh, Sudan, South Sudan, Ethiopia and Brazil. Cutaneous leishmaniasis is more widely distributed, with about one-third of cases occurring in each of three epidemiological regions, the Americas, the Mediterranean basin, and western Asia from the Middle East to Central Asia. The ten countries with the highest estimated case counts, Afghanistan, Algeria, Colombia, Brazil, Iran, Syria, Ethiopia, North Sudan, Costa Rica and Peru, together account for 70 to 75% of global estimated CL incidence. Mortality data were extremely sparse and generally represent hospital-based deaths only. Using an overall case-fatality rate of 10%, we reach a tentative estimate of 20,000 to 40,000 leishmaniasis deaths per year. Although the information is very poor in a number of countries, this is the first in-depth exercise to better estimate the real impact of leishmaniasis. These data should help to define control strategies and reinforce leishmaniasis advocacy.     

Assembly of the central domain of the 30S ribosomal subunit: roles for the primary binding ribosomal proteins S15 and S8

Assembly of the 30S ribosomal subunit occurs in a highly ordered and sequential manner. The ordered addition of ribosomal proteins to the growing ribonucleoprotein particle is initiated by the association of primary binding proteins. These proteins bind specifically and independently to 16S ribosomal RNA (rRNA). Two primary binding proteins, S8 and S15, interact exclusively with the central domain of 16S rRNA. Binding of S15 to the central domain results in a conformational change in the RNA and is followed by the ordered assembly of the S6/S18 dimer, S11 and finally S21 to form the platform of the 30S subunit. In contrast, S8 is not part of this major platform assembly branch. Of the remaining central domain binding proteins, only S21 association is slightly dependent on S8. Thus, although S8 is a primary binding protein that extensively contacts the central domain, its role in assembly of this domain remains unclear. Here, we used directed hydroxyl radical probing from four unique positions on S15 to assess organization of the central domain of 16S rRNA as a consequence of S8 association. Hydroxyl radical probing of Fe(II)-S15/16S rRNA and Fe(II)-S15/S8/16S rRNA ribonucleoprotein particles reveal changes in the 16S rRNA environment of S15 upon addition of S8. These changes occur predominantly in helices 24 and 26 near previously identified S8 binding sites. These S8-dependent conformational changes are consistent with 16S rRNA folding in complete 30S subunits. Thus, while S8 binding is not absolutely required for assembly of the platform, it appears to affect significantly the 16S rRNA environment of S15 by influencing central domain organization.     

Structural insight into the transmembrane segments 3 and 4 of the hERG potassium channel

The hERG (human ether‐a‐go‐go related gene) potassium channel is a voltage‐gated potassium channel containing an N‐terminal domain, a voltage‐sensor domain, a pore domain and a C‐terminal domain. The transmembrane segment 4 (S4) is important for sensing changes of membrane potentials through positively charge residues. A construct containing partial S2–S3 linker, S3, S4 and the S4–S5 linker of the hERG channel was purified into detergent micelles. This construct exhibits good quality NMR spectrum when it was purified in lyso‐myristoyl phosphatidylglycerol (LMPG) micelles. Structural study showed that S3 contains two short helices with a negatively charged surface. The S4 and S4–S5 linker adopt helical structures. The six positively charged residues in S4 localize at different sides, suggesting that they may have different functions in channel gating. Relaxation studies indicated that S3 is more flexible than S4. The boundaries of S3–S4 and S4–S4–S5 linker were identified. Our results provided structural information of the S3 and S4, which will be helpful to understand their roles in channel gating. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Proteomic characterization of the small subunit of Chlamydomonas reinhardtii chloroplast ribosome: identification of a novel S1 domain-containing protein and unusually large orthologs of bacterial S2, S3, and S5

To understand how chloroplast mRNAs are translated into functional proteins, a detailed understanding of all of the components of chloroplast translation is needed. To this end, we performed a proteomic analysis of the plastid ribosomal proteins in the small subunit of the chloroplast ribosome from the green alga Chlamydomonas reinhardtii. Twenty proteins were identified, including orthologs of Escherichia coli S1, S2, S3, S4, S5, S6, S7, S9, S10, S12, S13, S14, S15, S16, S17, S18, S19, S20, and S21 and a homolog of spinach plastid-specific ribosomal protein-3 (PSRP-3). In addition, a novel S1 domain-containing protein, PSRP-7, was identified. Among the identified proteins, S2 (57 kD), S3 (76 kD), and S5 (84 kD) are prominently larger than their E. coli or spinach counterparts, containing N-terminal extensions (S2 and S5) or insertion sequence (S3). Structural predictions based on the crystal structure of the bacterial 30S subunit suggest that the additional domains of S2, S3, and S5 are located adjacent to each other on the solvent side near the binding site of the S1 protein. These additional domains may interact with the S1 protein and PSRP-7 to function in aspects of mRNA recognition and translation initiation that are unique to the Chlamydomonas chloroplast.     

S6:S18 ribosomal protein complex interacts with a structural motif present in its own mRNA

Prokaryotic ribosomal protein genes are typically grouped within highly conserved operons. In many cases, one or more of the encoded proteins not only bind to a specific site in the ribosomal RNA, but also to a motif localized within their own mRNA, and thereby regulate expression of the operon. In this study, we computationally predicted an RNA motif present in many bacterial phyla within the 5′ untranslated region of operons encoding ribosomal proteins S6 and S18. We demonstrated that the S6:S18 complex binds to this motif, which we hereafter refer to as the S6:S18 complex-binding motif (S6S18CBM). This motif is a conserved CCG sequence presented in a bulge flanked by a stem and a hairpin structure. A similar structure containing a CCG trinucleotide forms the S6:S18 complex binding site in 16S ribosomal RNA. We have constructed a 3D structural model of a S6:S18 complex with S6S18CBM, which suggests that the CCG trinucleotide in a specific structural context may be specifically recognized by the S18 protein. This prediction was supported by site-directed mutagenesis of both RNA and protein components. These results provide a molecular basis for understanding protein-RNA recognition and suggest that the S6S18CBM is involved in an auto-regulatory mechanism.     

Central domain assembly: thermodynamics and kinetics of S6 and S18 binding to an S15-RNA complex

The 30 S ribosomal subunit assembles in vitro through the hierarchical binding of 21 ribosomal proteins to 16 S rRNA. The central domain of 16 S rRNA becomes the platform of the 30 S subunit upon binding of ribosomal proteins S6, S8, S11, S15, S18 and S21. The assembly of the platform is nucleated by binding of S15 to 16 S rRNA, followed by the cooperative binding of S6 and S18. The prior binding of S6 and S18 is required for binding of S11 and S21. We have studied the mechanism of the cooperative binding of S6 and S18 to the S15-rRNA complex by isothermal titration calorimetry and gel mobility shift assays with rRNA and proteins from the hyperthermophilic bacterium Aquifex aeolicus. S6 and S18 form a stable heterodimer in solution with an apparent dissociation constant of 8.7 nM at 40 degrees C. The S6:S18 heterodimer binds to the S15-rRNA complex with an equilibrium dissociation constant of 2.7 nM at 40 degrees C. Consistent with previous studies using rRNA and proteins from Escherichia coli, we observed no binding of S6 or S18 in the absence of the other protein or S15. The presence of S15 increases the affinity of S6:S18 for the RNA by at least four orders of magnitude. The kinetics of S6:S18 binding to the S15-rRNA complex are slow, with an apparent bimolecular rate constant of 8.0 x 10(4) M(-1) s(-1) and an apparent unimolecular dissociation rate of 1.6 x 10(-4) s(-1). These results, which are consistent with a model in which S6 and S18 bind as a heterodimer to the S15-rRNA complex, provide a mechanistic framework to describe the previously observed S15-mediated cooperative binding of S6 and S18 in the ordered assembly of a multi-protein ribonucleoprotein complex.     

RNase catalyzed hydrolysis of ribosomes in several functional states

The RNase A catalyzed hydrolysis of rRNA in ribosomes has been studied for nonwashed 50S and 70S ribosomes, for washed 50S and 70S ribosomes, for runoff 50S ribosomes and for 70S ribosomes in polysomes. The regions available to hydrolysis in the 50S ribosome remain available when the 50S ribosomes become a part of a 70S ribosome or a polysome. The regions available to hydrolysis in the 30S ribosome become unavailable when the 30S ribosome becomes part of a 70S ribosome or a polysome. Removal of tRNA, mRNA and factors from the 50S and 70S ribosome lowers the rate of hydrolysis of one site in the 23S rRNA. This shows that the conformation of one region of the 23S RNA changes for ribosomes in different functional states.     

Comprehensive identification of post-translational modifications of rat bone osteopontin by mass spectrometry

Osteopontin (OPN) is a highly modified protein that is found in many tissues and has been associated with a variety of physiological and pathological processes. Bone OPN is a potent inhibitor of hydroxyapatite crystal formation and stimulates bone resorption by osteoclasts; these activities, as well as others, are dependent upon phosphorylation of the protein. We have used mass spectrometry (MS) to perform a comprehensive analysis of the post-translational modification of OPN purified from rat bone. Matrix-assisted laser desorption time-of-flight (MALDI-TOF) MS showed masses of 37.6 and 36.8 kDa before and after enzymatic dephosphorylation, respectively, corresponding to a content of approximately 10.4 phosphate groups. Using proteolytic digestion and tandem MS, we localized 29 sites of phosphorylation: S10, S11, S46, S47, T50, S60, S62, S65, S146, T154, S160, S164, S167, S193, S196, S203, S220, S223, S232, S241, S245, S257, S262, S267, S278, S290, S295, S296, and S297. In addition, Y150 was shown to be sulfated and T107, T110, T116, and T121 are O-glycosylated. No glycan was detected at the potential N-glycosylation site. Other modifications, including deamidation, oxidation, and carbamylation, are also present. A 36-amino acid sequence from residues 67-102 could not be analyzed in detail, even after sialidase treatment, presumably because of the presence of a large number of acidic residues. In comparison to the previously characterized cow milk isoform, rat bone OPN is sulfated and has an additional site of glycosylation, many different sites of phosphorylation, and a lower overall phosphate content.     

Production of an S RNase with dual specificity suggests a novel hypothesis for the generation of new S alleles

Gametophytic self-incompatibility in plants involves rejection of pollen when pistil and pollen share the same allele at the S locus. This locus is highly multiallelic, but the mechanism by which new functional S alleles are generated in nature has not been determined and remains one of the most intriguing conceptual barriers to a full understanding of self-incompatibility. The S(11) and S(13) RNases of Solanum chacoense differ by only 10 amino acids, but they are phenotypically distinct (i.e., they reject either S(11) or S(13) pollen, respectively). These RNases are thus ideally suited for a dissection of the elements involved in recognition specificity. We have previously found that the modification of four amino acid residues in the S(11) RNase to match those in the S(13) RNase was sufficient to completely replace the S(11) phenotype with the S(13) phenotype. We now show that an S(11) RNase in which only three amino acid residues were modified to match those in the S(13) RNase displays the unprecedented property of dual specificity (i.e., the simultaneous rejection of both S(11) and S(13) pollen). Thus, S(12)S(14) plants expressing this hybrid S RNase rejected S(11), S(12), S(13), and S(14) pollen yet allowed S(15) pollen to pass freely. Surprisingly, only a single base pair differs between the dual-specific S allele and a monospecific S(13) allele. Dual-specific S RNases represent a previously unsuspected category of S alleles. We propose that dual-specific alleles play a critical role in establishing novel S alleles, because the plants harboring them could maintain their old recognition phenotype while acquiring a new one.     

Effects of aminoethylation of cysteine residues on the structural and functional activities of the Escherichia coli 30 S ribosomal proteins

The purified 30 S ribosomal proteins from Escherichia coli strain Q13 were chemically modified by reaction with ethyleneimine, specifically converting cysteine residues to S-2-aminoethylcysteine residues. Proteins S1, S2, S4, S8, S11, S12, S13, S14, S17, S18 and S21 were found to contain aminoethylcysteine residues after modification, whereas proteins S3, S5, S6, S7, S9, S10, S15, S16, S19 and S20 did not. Aminoethylated proteins S4, S13, S17 and S18 were active in the reconstitution of 30 S ribosomes and did not have altered functional activities in poly(U)-dependent polyphenylalanine synthesis, R17-dependent protein synthesis, fMet-tRNA binding and Phe-tRNA binding. Aminoethylated proteins S2, S11, S12, S14 and S21 were not active in the reconstitution of complete 30 S ribosomes, either because the aminoethylated protein did not bind stably to the ribosome (S2, S11, S12 and S21) or because the aminoethylated protein did not stabilize the binding of other ribosomal proteins (S14). The functional activities of 30 S ribosomes reconstituted from a mixture of proteins containing one sensitive aminoethylated protein (S2, S11, S12, S14 or S21) were similar to ribosomes reconstituted from mixtures lacking that protein. These results imply that the sulfhydryl groups of the proteins S4, S13, S17 and S18 are not necessary for the structural or functional activities of these proteins, and that aminoethylation of the sulfhydryl groups of S2, S11, S12, S14 and S21 forms either a kinetic or thermodynamic barrier to the assembly of active 30 S ribosomes in vitro.