Ungerine Nitrate

Ungerine Nitrate Catalog number: BADC-00081

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Alkaloid , from plants of the Ungernia genus, Amaryllidaceae.

Category
ADCs Cytotoxin
Product Name
Ungerine Nitrate
Catalog Number
BADC-00081
Molecular Formula
C18H20N2O8
Molecular Weight
392.36
Purity
97 % (TLC).
Ungerine Nitrate

Ordering Information

Catalog Number Size Price Quantity
BADC-00081 -- $-- Inquiry
Description
Alkaloid , from plants of the Ungernia genus, Amaryllidaceae.
IUPAC Name
(3R,9R)-9-methoxy-4-methyl-11,16,18-trioxa-4-azapentacyclo[11.7.0.02,10.03,7.015,19]icosa-1(20),7,13,15(19)-tetraen-12-one;nitric acid
Canonical SMILES
CN1CCC2=CC(C3C(C21)C4=CC5=C(C=C4C(=O)O3)OCO5)OC.[N+](=O)(O)[O-]
InChI
InChI=1S/C18H19NO5.HNO3/c1-19-4-3-9-5-14(21-2)17-15(16(9)19)10-6-12-13(23-8-22-12)7-11(10)18(20)24-17;2-1(3)4/h5-7,14-17H,3-4,8H2,1-2H3;(H,2,3,4)/t14-,15?,16+,17?;/m1./s1
InChIKey
PSCZYIVKEHPWIP-VYRMFUMRSA-N
Solubility
Well in water
Melting Point
260 °C.
Appearance
Solid powder
Shipping
Room temperature, or blue ice upon request.
Storage
Store at +4 °C, in dark place.
1. Predicting nitrate leaching under potato crops using transfer functions
M O Gasser, R Lagacé, J Caron, M R Laverdière J Environ Qual . 2003 Jul-Aug;32(4):1464-73. doi: 10.2134/jeq2003.1464.
Nitrate leaching is a major issue in many cultivated soils. Models that predict the major processes involved at the field scale could be used to test and improve management practices. This study aims to evaluate a simple transfer function approach to predict nitrate leaching in sandy soils. A convective lognormal transfer (CLT) function is convoluted with functional equations simulating N mineralization, plant N uptake, N fertilizer dissolution, and nitrification at the soil surface to predict solute concentrations under potato (Solanum tuberosum L.) and barley (Hordeum vulgare L.) fields as a function of drainage water. Using this approach, nitrate flux concentrations measured in drainable lysimeters (1-m soil depth) were reasonably predicted from 29 Apr. 1996 to 3 Dec. 1996. With average application rates of 16.9 g m(-2) of N fertilizer in potato crops, mean nitrate-leaching losses measured under potato were 8.5 g N m(-2). Tuber N uptake averaged 9.7 g N m(-2) and soil mineral N at start (spring) and end (fall) of N mass balance averaged 1.7 and 4.5 g N m(-2), respectively. Soil N mineralization was estimated by difference (4.3 g N m(-2) on average) and was small compared with N fertilization. Small nitrate flux concentrations at the beginning of the cropping season (May) resulted mainly from initial soil nitrate concentrations. Measured and predicted nitrate flux concentrations significantly increased at mid-season (July-August) following important drainage events coupled with complete dissolution and nitrification of N fertilizers, and declining N uptake by potato plants. Decreases in nitrate concentrations before the end of year (November-December) underlined the predominant effect of N fertilizers applied for the most part at planting acting as a pulse input of solute.
2. The Arabidopsis abscisic acid catabolic gene CYP707A2 plays a key role in nitrate control of seed dormancy
Alessandro Alboresi, Theodoros Matakiadis, Olivier Pichon, Jean-Pierre Renou, Eiji Nambara, Kiyoshi Tatematsu, Yuji Kamiya, Hoai-Nam Truong, Yusuke Jikumaru Plant Physiol . 2009 Feb;149(2):949-60. doi: 10.1104/pp.108.126938.
Nitrate releases seed dormancy in Arabidopsis (Arabidopsis thaliana) Columbia accession seeds in part by reducing abscisic acid (ABA) levels. Nitrate led to lower levels of ABA in imbibed seeds when included in the germination medium (exogenous nitrate). Nitrate also reduced ABA levels in dry seeds when provided to the mother plant during seed development (endogenous nitrate). Transcript profiling of imbibed seeds treated with or without nitrate revealed that exogenous nitrate led to a higher expression of nitrate-responsive genes, whereas endogenous nitrate led to a profile similar to that of stratified or after-ripened seeds. Profiling experiments indicated that the expression of the ABA catabolic gene CYP707A2 was regulated by exogenous nitrate. The cyp707a2-1 mutant failed to reduce seed ABA levels in response to both endogenous and exogenous nitrate. In contrast, both endogenous and exogenous nitrate reduced ABA levels of the wild-type and cyp707a1-1 mutant seeds. The CYP707A2 mRNA levels in developing siliques were positively correlated with different nitrate doses applied to the mother plants. This was consistent with a role of the CYP707A2 gene in controlling seed ABA levels in response to endogenous nitrate. The cyp707a2-1 mutant was less sensitive to exogenous nitrate for breaking seed dormancy. Altogether, our data underline the central role of the CYP707A2 gene in the nitrate-mediated control of ABA levels during seed development and germination.
3. Plant hormone transporters: what we know and what we would like to know
Youngsook Lee, Enrico Martinoia, Markus Geisler, Jiyoung Park BMC Biol . 2017 Oct 25;15(1):93. doi: 10.1186/s12915-017-0443-x.
Hormone transporters are crucial for plant hormone action, which is underlined by severe developmental and physiological impacts caused by their loss-of-function mutations. Here, we summarize recent knowledge on the individual roles of plant hormone transporters in local and long-distance transport. Our inventory reveals that many hormones are transported by members of distinct transporter classes, with an apparent dominance of the ATP-binding cassette (ABC) family and of the Nitrate transport1/Peptide transporter family (NPF). The current need to explore further hormone transporter regulation, their functional interaction, transport directionalities, and substrate specificities is briefly reviewed.
The molarity calculator equation

Mass (g) = Concentration (mol/L) × Volume (L) × Molecular Weight (g/mol)

The dilution calculator equation

Concentration (start) × Volume (start) = Concentration (final) × Volume (final)

This equation is commonly abbreviated as: C1V1 = C2V2

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