rongsheng li pricelist

War, pandemic and sluggish markets hit the world’s billionaires this year. There are 2,668 of them on Forbes’ 36th-annual ranking of the planet’s richest people—87 fewer than a year ago. They’re worth a collective $12.7 trillion—$400 billion less than in 2021. The most dramatic drops have occurred in Russia, where there are 34 fewer billionaires than last year following Vladimir Putin’s invasion of Ukraine, and China, where a government crackdown on tech companies has led to 87 fewer Chinese billionaires on the list.

Still, Forbes found more than 1,000 billionaires who are richer than they were a year ago. And 236 newcomers have become billionaires over the past year—including the first ever from Barbados, Bulgaria, Estonia and Uruguay.

America still leads the world, with 735 billionaires worth a collective $4.7 trillion, including Elon Musk, who tops the World’s Billionaires list for the first time. China (including Macau and Hong Kong) remains number two, with 607 billionaires worth a collective $2.3 trillion.

Al Bachchu MA, Jin SB, Park JW, Boo KH, Sun HJ, Kim YW, Lee HY, Riu KZ, Kim JH. Functional Expression of Miraculin, a Taste-modifying Protein, in Transgenic Miyagawa Wase Satsuma Mandarin (Citrus unshiu Marc.). Journal of the Korean Society for Applied Biological Chemistry 2011;54(1):24-29.

de Campos MKF, de Carvalho K, de Souza FS, Marur CJ, Pereira LFP, Bespalhok JC, Vieira LGE. Drought tolerance and antioxidant enzymatic activity in transgenic "Swingle" citrumelo plants over-accumulating proline. Environmental and Experimental Botany 2011;72(2):242-250.

Dutt M, Vasconcellos M, Grosser JW. Effects of antioxidants on Agrobacterium-mediated transformation and accelerated production of transgenic plants of Mexican lime (Citrus aurantifolia Swingle). Plant Cell Tissue and Organ Culture 2011;107(1):79-89.

Fan, J., Liu, X., Xu, S., Xu, Q., and Guo, W. (2011). T-DNA direct repeat and 35S promoter methylation affect transgene expression but do not cause silencing in transgenic sweet orange. Plant Cell Tissue and Organ Culture 107,225-232.

Fu, X., Khan, E.U., Hu, S., Fan, Q., and Liu, J. (2011). Overexpression of the betaine aldehyde dehydrogenase gene from Atriplex hortensis enhances salt tolerance in the transgenic trifoliate orange (Poncirus trifoliata L. Raf.). Environ. Exp. Bot. 74,106-113.

He YR, Chen SC, Peng AH, Zou XP, Xu LZ, Lei TG, Liu XF, Yao LX. Production and evaluation of transgenic sweet orange (Citrus sinensis Osbeck) containing bivalent antibacterial peptide genes (Shiva A and Cecropin B) via a novel Agrobacterium-mediated transformation of mature axillary buds. Scientia Horticulturae 2011;128(2):99-107.

Loeza-Kuk E, Gutierrez-Espinosa MA, Ochoa-Martinez DL, Villegas-Monter A, Mora-Aguilera G, Palacios-Torres EC, Perez-Molphe-Balch E. RESISTANCE ANALYSIS IN GRAPEFRUIT AND MEXICAN LIME TRANSFORMED WITH the p25 Citrus tristeza virus GEN. Agrociencia 2011;45(1):55-65.

Reyes CA, Zanek MC, Velazquez K, Costa N, Plata MI, Garcia ML. Generation of Sweet Orange Transgenic Lines and Evaluation of Citrus psorosis virus-derived Resistance against Psorosis A and Psorosis B. Journal of Phytopathology 2011;159(7-8):531-537.

Xu SX, Cai XD, Tan B, Li DL, Guo WW. Effect of ploidy increase on transgene expression: example from Citrus diploid cybrid and allotetraploid somatic hybrid expressing the EGFP gene. Protoplasma 2011;248(3):531-540.

Yang L, Hu CH, Li N, Zhang JY, Yan JW, Deng ZN. Transformation of sweet orange Citrus sinensis (L.) Osbeck with pthA-nls for acquiring resistance to citrus canker disease. Plant Molecular Biology 2011;75(1-2):11-23.

Li ZM, Zhang JZ, Mei L, Deng XX, Hu CG, Yao JL. PtSVP, an SVP homolog from trifoliate orange (Poncirus trifoliata L. Raf.), shows seasonal periodicity of meristem determination and affects flower development in transgenic Arabidopsis and tobacco plants. Plant Molecular Biology 2010;74(1-2):129-142.

Lopez C, Cervera M, Fagoaga C, Moreno P, Navarro L, Flores R, Pena L. Accumulation of transgene-derived siRNAs is not sufficient for RNAi-mediated protection against Citrus tristeza virus in transgenic Mexican lime. Molecular Plant Pathology 2010;11(1):33-41.

Mendes BMJ, Cardoso SC, Boscariol-Camargo RL, Cruz RB, Mourao FAA, Bergamin A. Reduction in susceptibility to Xanthomonas axonopodis pv. citri in transgenic Citrus sinensis expressing the rice Xa21 gene. Plant Pathology 2010;59(1):68-75.

Nishikawa F, Endo T, Shimada T, Fujii H, Shimizu T, Kobayashi Y, Araki T, Omura M. Transcriptional changes in CiFT-introduced transgenic trifoliate orange (Poncirus trifoliata L. Raf.). Tree Physiology 2010;30(3):431-439.

Wang J, Liu JH, Kurosawa T, Nada K, Ban Y, Moriguchi T. Cloning, biochemical identification, and expression analysis of a gene encoding S-adenosylmethionine decarboxylase in navel orange (Citrus sinensis Osbeck). Journal of Horticultural Science & Biotechnology 2010;85(3):219-226.

Barbosa-Mendes JM, Mourao FDA, Bergamin A, Harakava R, Beer SV, Mendes BMJ. Genetic transformation of Citrus sinensis cv. Hamlin with hrpN gene from Erwinia amylovora and evaluation of the transgenic lines for resistance to citrus canker. Scientia Horticulturae 2009;122(1):109-115.

Cervera M, Navarro L, Pena L. Gene stacking in 1-year-cycling APETALA1 citrus plants for a rapid evaluation of transgenic traits in reproductive tissues. Journal of Biotechnology 2009;140(3-4):278-282.

de Oliveira MLP, Febres VJ, Costa MGC, Moore GA, Otoni WC. High-efficiency Agrobacterium-mediated transformation of citrus via sonication and vacuum infiltration. Plant Cell Reports 2009;28(3):387-395.

Deng W, Luo KM, Li ZG, Yang YW, Hu N, Wu Y. Overexpression of Citrus junos mitochondrial citrate synthase gene in Nicotiana benthamiana confers aluminum tolerance. Planta 2009;230(2):355-365.

Li DL, Tan B, Duan YX, Guo WW. Regeneration of transgenic citrus plants from the trimmed shoot/root region of etiolated seedlings. Biologia Plantarum 2009;53(3):578-582.

Pasquali G, Orbovic V, Grosser J. Transgenic grapefruit plants expressing the P(APETALA3)-IPT (gp) gene exhibit altered expression of PR genes. Plant Cell Tissue and Organ Culture 2009;97(2):215-223.

Tan B, Li DL, Xu SX, Fan GE, Fan J, Guo WW. Highly efficient transformation of the GFP and MAC12.2 genes into precocious trifoliate orange (Poncirus trifoliata L. Raf), a potential model genotype for functional genomics studies in Citrus. Tree Genetics & Genomes 2009;5(3):529-537.

Tong Z, Tan B, Zhang JC, Hu ZY, Guo WW, Deng XX. Using precocious trifoliate orange (Poncirus trifoliata L. Raf.) to establish a short juvenile transformation platform for citrus. Scientia Horticulturae 2009;119(3):335-338.

Ananthakrishnan, G., Orbovic, V., Pasquali, G., Alovi, M., & Grosser, J. W. (2008). Transfer of citrus tristeza virus (CTV)-derived resistance candidate sequences to four grapefruit cultivars through Agrobacterium-mediated genetic transformation. In vitro cellular & developmental biology - plant, 43 (6), 593-601.

Guo, W. W., Duan, Y. X., Li, D. L., Liu, X., Tan, B., Cai, X. D., Grosser, J. W., Deng, X. X. (2008). Citrus genetic transformation with interest target genes and further uses of transgenic lines in somatic fusion. Acta Horticulturae, 773, 25-28.

Rodriguez, A., Cervera, M., Peris, J. E., & Pena, L. (2008). The same treatment for transgenic shoot regeneration elicits the opposite effect in mature explants from two closely related sweet orange (Citrus sinensis (L.) Osb.) genotypes. Plant Cell, Tissue, and Organ Culture, 93 (1), 97-106.

Zou, XiuPing, Li, DeMou, Ying, Luo Xiao, KeMing, Luo, & Yan, Pei. (2008). An improved procedure for Agobacterium-mediated transformation of trifoliate orange (Poncirus trifoliata L. Raf.) via indirect organogenesis. In Vitro Cellular & Developmental Biology - Plant, 44 (3), 169-177.

Omar, A. A., Song, W. Y., & Grosser, J. W. (2007). Introduction of Xa21, a Xanthomonas-resistance gene from rice, into "Hamlin" sweet orange [Citrus sinensis (L.) Osbeck] using protoplast-GFP co-transformation or single plasmid transformation. Journal of Horticultural Science and Biotechnology, 82 (6), 914-923.

Omar, A. A., & Grosser, J. W. (2007). Protoplast co-transformationa nd regeneration of transgenic "Hamlin" sweet orange plants containing a cDNA Xa21 Xanthomonas resistance gene and GFP. Acta Horticulturae, 738, 235-243

Orbovic, V., Pasquali, G., & Grosser, J. W. (2007). A GFP-containing binary vector for Agrobacterium tumefaciens-mediated plant transformation. Acta Horticulturae, 738, 245-253.

Several studies were recently performed to identify the QTL–environmental effects in soybean. Xing et al. (2012) studied the resistance to bean pyralid under multiple environments in RIL populations. Seed coat cracking of epistatic effects and QTL-by environment interactions was analyzed by QTLnetwork (Ha et al. 2012). These studies implied QTL were affected greatly by environment. In this study, at the HRB location across 9 ys three additive main effect QTL and six pairs of epistatic QTL were identified for oil content. OilA1-6, OilA2-1 and OilE-1 showed additive main effects explaining 0.3–3.05% of phenotypic variances. OilA2-1 is also detected under seven environments by individual analysis using CIM and MIM methods. Six QTL pairs showed epistatic effects (AA) and interaction with environment (AAE), phenotypic variation explained by epistatic QTL ranged from 0.91 to 3.25% and phenotypic variation explained by epistasis×environment (AAE) interactions ranged from 0.2 to 1.92%. At the JMS location across 4 yr, one additive main effect QTL and one pair of epistatic QTL were identified for oil content. OilB2-4 showed additive main effects explaining 0.08% of phenotypic variances. One QTL pair showed epistatic effects (AA) and interaction with the environment (AAE), phenotypic variation explained by epistatic QTL is 3.33% and phenotypic variation explained by epistasis×environment (AAE) interactions is 0.85%. At the HXL location across 4 yr, no additive main effect QTL was detected for oil content. Two QTL pairs showed epistatic effects (AA) and interaction with environment (AAE). Phenotypic variation explained by epistatic QTL and epistasis×environment (AAE) interactions ranged from 1.56 to 2.16% and from 2.12 to 2.62%, respectively.

Wu et al. (2012) utilized the Hanxuan 10×Lumai 14 doubled haploid population to examine the genetic control of yield and yield-associated traits under different water-related conditions. Oil content data from 17 environments were analyzed by QTLnetwork. No additive main effect QTL was detected for oil content. Four QTL pairs showed epistatic effects (AA) and interaction with environment (AAE), phenotypic variation explained by epistatic QTL ranged from 1.71 to 2.4% and phenotypic variation explained by epistasis×environment (AAE) interactions ranged from 0.41 to 1.96%. However, there were no identical epistasis QTL pairs or additive main effect QTL among different data sets, which were from the HRB location across 9 yr, the JMS location across 4 yr, the HXL location across 4 yr, and all 17 environments. The reason is that QTL effects are environmentally sensitive and epistatic interactions have not received much attention in QTL analysis of seed oil concentration in soybean. This could be due in part to the difficulty in exploiting them in plant breeding programs, especially when a large number of interactions are involved and associated with the trait of interest. It could also be because the amount of total phenotypic variances explained by each interaction tends to be small (Bernardo 2010; Eskandari et al. 2013). Furthermore, genes may have different actions in different environment data sets; the predicted superior genotypes will have different combinations in different data sets (Yang and Zhu 2005).

Arnórsson S. and Andrésdóttir A. 1995. Processes controlling the distribution of boron and chlorine in natural waters in Iceland. Geochimica et Cosmochimica Acta, 59: 4125–4146.

Boschetti T., Toscani L., and Salvioli Mariani E. 2015. Boron isotope geochemistry of Na-bicarbonate, Na-chloride, and Ca-chloride waters from the Northern Apennine Foredeep basin: other pieces of the sedimentary basin puzzle. Geofluids, 15: 546–562.

Capaccioni B., Aguilera F., Tassi F., Darrah T., Poreda R.J., and Vaselli O. 2011. Geochemical and isotopic evidences of magmatic inputs in the hydrothermal reservoir feeding the fumarolic discharges of Tacora Volcano (Northern Chile). Journal of Volcanology and Geothermal Research, 208(3–4): 77–85.

Chen L., Ma T., Du Y., Yang J., Liu L., Shan H., and Cai H. 2014. Origin and evolution of formation water in North China Plain based on hydrochemistry and stable isotopes (2H, 18O, 37Cl, and 81Br). Journal of Geochemical Exploration, 145: 250–259.

Connolly C.A., Walter L.M., Baadsgaard H., and Longstaffe F.J. 1990. Origin and evolution of formation waters, Alberta Basin, Western Canada Sedimentary Basin. I. Chemistry. Applied Geochemistry, 5: 375–395.

Davisson M.L., Presser T.S., and Criss R.E. 1994. Geochemistry of tectonically expelled fluids from the northern Coast ranges, Rumsey Hills, California, USA. Geochimica et Cosmochimica Acta, 58(7): 1687–1699.

Ellis A.J. and Mahon W.A.J. 1964. Natural hydrothermal systems and experimental hot-water/rock interactions. Geochimica et Cosmochimica Acta, 28(8): 1323–1357.

Ellis A.J. and Mahon W.A.J. 1967. Natural hydrothermal systems and experimental hot water/rock interactions (Part II). Geochimica et Cosmochimica Acta, 31: 519–538.

Geological environment monitoring station of Jilin Province. 2004. Report on the survey and evaluation of geothermal resources. Hua Pingchang to Jiu Zhan district in Yishu Graben, Jilin City. [In Chinese.]

Kharaka Y.K., Maest A.S., Carothers W.W., Law L.M., Lamothe P.J., and Fries T.L. 1987. Geochemistry of metal-rich brines from central Mississippi Salt Dome basin, U.S.A. Applied Geochemistry, 2(5–6): 543–561.

Li M., Lou Z., Jin A., Zhu R., Shang C., Ye Y., and Zhu Z. 2013. Origin, flow of formation water and hydrocarbon accumulation in the Zhenwu Area of the North Jiangsu Basin, China. Acta Geologica Sinica, 87(3): 819–829.

Li Z. 2010. JilinWan chang - The analysis of the development and utilization of geothermal resource exploration in Gudian area. Business China, 196: 84–85.

Lin, Y.-W., Gao, Q.-W., and Yu, Q.-T. 1999. A study of chemical characteristics of geothermal fluid in Tianchi Volcanic Region, Changbai Mountains. Geological Review, 45(Suppl.): 241–247. [In Chinese.]

Liu B., Liu C.Q., Zhang G., Zhao Z.Q., Li S.L., Hu J., Ding H., Lang Y.C., and Li X.D. 2013. Chemical weathering under mid- to cool temperate and monsoon-controlled climate: A study on water geochemistry of the Songhuajiang River system, northeast China. Applied Geochemistry, 31: 265–278.

Liu G., Fang Y., Gao H., and Han Y.-L. 2014. Exploration and research on the Shengdequan geothermal resources in Jilin City, Jilin Province. Jilin Geology, 33: 87–89. [In Chinese.]

Liu Z., Yuan D., He S., Zhang M., and Zhang J. 2000. Geochemical features of the geothermal CO2-watercarbonate rock system and analysis on its CO2 sources. Science in China Series D: Earth Sciences, 43(6): 569–576.

Lowry R.M., Faure G., Mullet D.I., and Jones L.M. 1988. Interpretation of chemical and isotopic compositions of brines based on mixing and dilution, “Clinton” sandstones, eastern Ohio, U.S.A. Applied Geochemistry, 3: 177–184.

Michard G.D., Pearson F.J., and Gautschi A. 1996. Chemical evolution of waters during long term interaction with granitic rocks in Northern Switzerland. Applied Geochemistry, 11: 757–744.

Ren J., Lu Y., Li S., Yang S., and Zhuang X. 1999. The tectonic evolution of Yishu Graben and its depositional filling response. Scientia Geologica Sinica, 34: 196–123. [In Chinese.]

Rittenhouse G. 1967. Bromine in_oil-field waters and its use in determining possibilities of origin of these waters. American Association of Petroleum Geologists Bulletin, 51: 2430–2440.

Toran L.E. and Saunders J.A. 1999. Modeling alternative paths of chemical evolution of Na-HCO3-type groundwater near Oak Ridge, Tennessee, USA. Hydrogeology Journal, 7: 355–364.

Venturelli G., Boschetti T., and Duchi V. 2003. Na-Carbonate waters of extreme composition: Possible origin and evolution. Geochemical Journal, 37: 351–366.

Wan C.B., Sun Y.W., Xue Y.F., Qiao X.Y., Jin Y.D., and Zhang Y.Y. 2014. Neogene palynological assemblages in the west slope of Songliao Basin and their geological implications. Science China: Earth Sciences, 44(7): 1429–1442. [In Chinese.]

Wang W., Li J., Zhang S., Wang G., Yan X., and Tian W. 2015. U–Pb zircon geochronology of basal granite by LA-ICP-MS in Yitong Basin, Northeast China. Implications for origin of limestone. Marine and Petroleum Geology, 68: 583–595.

Wang, X.-M. 2003. Palynology, Paleovegetation and Paleoclimate of Middle and Late Paleogene of Northern China. Shandong University of Science and Technology.

Xiao C., Liu J., Liang X., and Du S. 2016. Hydrogeochemistry characteristics of groundwater and its suitability for water supply and irrigation in Jilin City, China. Arabian Journal of Geosciences, 9(6): 434.

Xiao Q., Yang L., Pu J.B., Liang Z.B., Yuan D.X., and Qiu S.L. 2016. The environmental significance of sulfur isotope in surface water-ground water-shallow thermal water in Wentang Gorge Anticline, Chongqing, China. Acta Geologica Sinica, 90(8): 1945–1954. [In Chinese.]

Yu G.-M., Zhang X.-N., and Wang C.-S. 1990. Geological interpretation on the results of cluster analysis of trace elements from argillaceous rocks in the Jurassic, Cretaceous and Tertiary strata in Xizang. Lithofacies Paleogeography, 5(5): 1–7. [In Chinese.]

Zhao, R., Shan, X., Yi, J., Du, X., Liang, Y., and Zhang, Y. 2017. Geochemistry of HCO3-Na thermal water from the Gudian slope: Insights into fluid origin, formation mechanism and circulation in the Yitong Basin, Northeast. Applied Geochemistry. In Press.

If you want to stay at the best hotel in Wenling, Trip.com is here to help! Planning a trip to Wenling? Wenling is not a big city. When traveling here, you can choose to stay in hotels around the city center. You can plan a day tour in Wenling. Other than just visiting Wenling, you can also visit surrounding cities such as Taizhou, Yuhuan, Yueqing, etc. for a couple of days.

There are not many hotels in Wenling. Guests are advised to book in advance. The local average price is 44 USD per night. There are a variety of hotels to meet the needs of different types of travelers. There are 1 five-star hotels in Wenling at an average price of 56 USD per night. There are 5 four-star hotels in Wenling at an average price of 60 USD per night. There are 7 three-star hotels in Wenling at an average price of 44 USD per night. There are 4 two-star hotels in Wenling at an average price of 32 USD per night. Hotels in Wenling offer great value for your money, so a high accommodation budget isn"t necessary. Hangting Hotel is the most popular brand among tourists. In Wenling, chain hotels such as Hangting Hotel are one of the top choices among travelers. Crystal Spade Hotel is one of the most popular hotels in Wenling. Many tourists also stay at Wanchang Hotel.

For short trips in Wenling, Taizhou Shicheng Flying Waterfall are all good options. The most famous attractions locally are Changyu Dongtian, Donghaitang Park. This area boasts amazing cultural sights with attractions like Wang Bomin Art Historical Science Hall, Wenling Museum. For those interested in the outdoors, attractions like Yingyue Park, Wangfuji Park, Hushan Park are excellent options.

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