Total Synthesis and Biological Evaluation of Zealactone 1a/b

Strigolactones are plant hormones, which play pivotal roles in plant growth and development with potential application in sustainable agriculture. Recently, zealactone 1a/b has been identified as the major strigolactone from the root exudates of corn. Although zealactone is a promising molecule affecting signaling in the rhizosphere as well as in planta, evaluating its biological activities has been hampered by its low natural abundance and its relative chemical instability. Herein, we present the total synthesis of zealactone 1a/b based on our studies employing a [2+2]-cycloaddition strategy and a chemoselective Baeyer-Villiger oxidation to forge the γ-butyrolactone fragment. Furthermore, we disclose the biological activities of zealactone 1a/b on corn and in soil in comparison with related synthetic analogues.     

Total Synthesis and Biological Evaluation of Heliolactone

Strigolactones are phytohormones, which affect diverse aspects of plant growth and development with potential application in modern agriculture. Recently, heliolactone has been isolated as a non‐canonical type of strigolactone from the root exudates of sunflower, and it could be involved in signaling in the rhizosphere as well as in planta. However, its biological activity is yet to be evaluated, due to its relative chemical instability and its low natural abundance. Herein, we describe the gram‐scale synthesis of heliolactone and its derivatives by using Stille cross‐coupling as the key bond‐forming reaction, and we disclose some of their biological activities (soil stability, binding ability to strigolactone receptor, corn germination, sunflower germination, Orobanche cumana germination and leaf senescence) in comparison with other canonical and non‐canonical strigolactones.     

Strigolactones: Plant Hormones with Promising Features

Almost 80 years after the discovery of the first plant hormone, auxin, a few years ago a new class of plant hormones, the strigolactones, was discovered. These molecules have unprecedented biological activity in a number of highly important biological processes in plants but also outside the plant in the rhizosphere, the layer of soil surrounding the roots of plants and teeming with life. The exploitation of this amazing biological activity is not without challenges: the synthesis of strigolactones is complicated and designing the desired activity a difficult task. This minireview describes the current state of knowledge about the strigolactones and how synthetic analogs can be developed that can potentially contribute to the development of a sustainable agriculture.     

Stereoselective Synthesis and Biological Profile of All Stereoisomers of Lactam Analogues of Strigolactones GR24 and GR18

Strigolactones (SLs) are signaling molecules involved in plant development and governing interactions with soil microorganisms in the rhizosphere as well as the germination of parasitic weeds. Developing their use in Crop Protection is a promising approach to a sustainable agriculture by mitigating biotic and abiotic stresses. Recently, a new class of lactam analogues of SL has emerged, namely strigolactams, displaying outstanding potency to induce the germination of parasitic weed O. cumana as well as enhanced chemical and soil stability. Herein, we describe the stereoselective synthesis of GR24 and GR18 lactams harnessing the chemistry of chiral keteniminium (KI) salts, in particular the unprecedented reactivity of chloro-substituted KI, supported by DFT calculations. We disclose subsequently the biological activity on corn of the 32 stereopure strigolactams prepared, highlighting the crucial influence of stereochemistry and lactam substitution, rationalized by docking analyses. Finally, we performed stability studies in soil, which reveal that stereoisomers display very different half-lives, reflecting the significant impact of stereochemistry on degradation kinetics.     

Sorgomol, germination stimulant for root parasitic plants, produced by Sorghum bicolor

A novel strigolactone sorgomol, germination stimulant for root parasitic plants Striga and Orobanche, was isolated and structure was elucidated. Sorgomol was more active on Striga than on Orobanche and may be the immediate precursor of sorgolactone in the biosynthetic pathway of strigolactones.     

丹皮酚类化合物及其生物活性研究进展

丹皮酚,即2-羟基-4-甲氧基苯乙酮,为一种天然酚类化合物,分离于毛莨科植物牡丹(Paeonia suffruticosa)的根皮和萝藦科植物徐长卿(Cynanchum paniculatum)的全株。由于丹皮酚特有的酚酮结构骨架,现代生物科学研究表明其具有广泛的生物活性。本文概述了丹皮酚的提取与合成及其生物活性,重点介绍了丹皮酚类衍生物及其生物活性。丹皮酚农用生物活性广谱,可作为开发新农药的先导结构。将丹皮酚研发成高效低风险小分子绿色农药符合社会发展需求,此方面研究值得重点关注。这对促进我国的新农药创制、农作物病虫害防治及提升现代农业的高科技含量均有积极的科学和实际意义。     

Synthesis,characterization and biological activity evaluation of new 3- methyl and 4- fluoro isoindoline-1, 3-dione/phthalimide analogues

The convenient route for the synthesis of a series of new Isoindoline-1, 3-dione/phthalimide analogues by condensation of substituted phthalic anhydride with an appropriate Ar-amine is described. Selective phthalimide derivatives were evaluated for their preliminary biological activities against Gram-positive, Gram-negative and fungi strains. These encouraging results could be helpful for the development of new antibacterial or antifungal agents.     

Rare Sugars: Recent Advances and Their Potential Role in Sustainable Crop Protection

Rare sugars are monosaccharides with a limited availability in the nature and almost unknown biological functions. The use of industrial enzymatic and microbial processes greatly reduced their production costs, making research on these molecules more accessible. Since then, the number of studies on their medical/clinical applications grew and rare sugars emerged as potential candidates to replace conventional sugars in human nutrition thanks to their beneficial health effects. More recently, the potential use of rare sugars in agriculture was also highlighted. However, overviews and critical evaluations on this topic are missing. This review aims to provide the current knowledge about the effects of rare sugars on the organisms of the farming ecosystem, with an emphasis on their mode of action and practical use as an innovative tool for sustainable agriculture. Some rare sugars can impact the plant growth and immune responses by affecting metabolic homeostasis and the hormonal signaling pathways. These properties could be used for the development of new herbicides, plant growth regulators and resistance inducers. Other rare sugars also showed antinutritional properties on some phytopathogens and biocidal activity against some plant pests, highlighting their promising potential for the development of new sustainable pesticides. Their low risk for human health also makes them safe and ecofriendly alternatives to agrochemicals.     

Discovery, structure and biological activities of the cyclotides

The cyclotides are a family of small disulfide rich proteins that have a cyclic peptide backbone and a cystine knot formed by three conserved disulfide bonds. The combination of these two structural motifs contributes to the exceptional chemical, thermal and enzymatic stability of the cyclotides, which retain bioactivity after boiling. They were initially discovered based on native medicine or screening studies associated with some of their various activities, which include uterotonic action, anti-HIV activity, neurotensin antagonism, and cytotoxicity. They are present in plants from the Rubiaceae, Violaceae and Cucurbitaceae families and their natural function in plants appears to be in host defense: they have potent activity against certain insect pests and they also have antimicrobial activity. There are currently around 50 published sequences of cyclotides and their rate of discovery has been increasing over recent years. Ultimately the family may comprise thousands of members. This article describes the background to the discovery of the cyclotides, their structural characterization, chemical synthesis, genetic origin, biological activities and potential applications in the pharmaceutical and agricultural industries. Their unique topological features make them interesting from a protein folding perspective. Because of their highly stable peptide framework they might make useful templates in drug design programs, and their insecticidal activity opens the possibility of applications in crop protection.     

Biodegradation of water-soluble and water-dispersible polymers for agricultural,consumer, and industrial applications—Challenges and opportunities for sustainable materials solutions

The development of more sustainable material solutions is one of the key challenges today. New materials are subject to an overall risk assessment of which their impact on the environment is an important aspect. The biodegradability of a material may support a positive risk assessment. Water-soluble and water-dispersible polymers are widely used in daily life in a very broad range of applications. In anticipation of a further tightening of regulatory requirements and as a consequence of the introduction of sustainability targets in industry, in the next decade or so, industry targets to replace the currently used and predominantly non-biodegradable high value water-soluble and water-dispersible polymers by biodegradable alternatives, wherever sustainably possible. This review provides an overview of the currently used water-soluble and water-dispersible polymers in detergent formulations for home care, in water treatment and in crop protection. These polymers have been engineered to near perfect performance at minimum costs. We address the challenges faced when introducing biodegradable alternatives in existing product value chains, and we highlight opportunities to further improve and fine-tune the biodegradation of these materials. This overview is intended to contribute to the development of novel biodegradable water-soluble and water-dispersible polymers, both at academia and industry.     

Rational design,properties, and applications of biosurfactants: a short review of recent advances

Biosurfactants combine physicochemical properties with biological activities. Although biosurfactants are often expressed by microorganisms, an increasing amount is produced by chemical synthesis. As many exist in the form of homologous compounds, it is often difficult to purify biosurfactants. But this has not limited the efforts to develop their commercial applications. In this short review, we have featured the recent advances in three important types of biosurfactants, lipopeptides, nucleolipids, and glycolipids. We have focused on comparing some of the key properties and functionalities between modern synthetic versions and their corresponding natural counterparts. We end the review by outlining the needs for not only strengthening their basic structure–property relationships through further research but also developing better technologies, irrespective of direct chemical synthesis or biological synthesis of biosurfactants through constructions of genetically engineered strains, to help advance the commercial use of biosurfactants.     

Synthesis of tryptophan-containing 2,5-diketopiperazines via sequential C–H activation: total syntheses of tryprostatin A,maremycins A and B

Indole 2,5-diketopiperazines (DKPs) are an important type of metabolic cyclic dipeptides containing a tryptophan (Trp) unit possessing a range of interesting biological activities. The intriguing structural features and divergent activities have stimulated tremendous efforts towards their efficient synthesis. Herein, we report the development of a unified strategy for the synthesis of three Trp-containing DKPs, namely tryprostatin A, and maremycins A and B, via a sequential C–H activation strategy. The key Trp skeletons were synthesized from the inexpensive, readily available alanine via a Pd(ii)-catalyzed β-methyl C(sp³)–H monoarylation. A subsequent C2-selective prenylation of the resulting 6-OMe-Trp by Pd/norbornene-promoted C–H activation led to the total synthesis of tryprostatin A in 12 linear steps from alanine with 25% overall yield. Meanwhile, total syntheses of maremycins A and B were successfully accomplished using a sequential Pd-catalyzed methylene C(sp³)–H methylation as the key step in 15 linear steps from alanine.

Indole 2,5-diketopiperazines (DKPs) are an important type of metabolic cyclic dipeptides containing a tryptophan (Trp) unit possessing a range of interesting biological activities.     

Occurrence, biological activities and synthesis of kaurane diterpenes and their glycosides

This paper presents a review on kaurane diterpenes and their glycoside derivatives, covering aspects of their occurrence, biological activities and the synthesis of these natural products and their analogues. First, it shows and classifies diterpenes, in accordance with the already established structural criteria in the literature. Then, kaurane diterpenes are presented, focusing on their chemical structures, occurrence in the plant kingdom and their main, recently described, biological activities. Moreover, the most significant works, published between 1964 and November 2006, which describe the total synthesis or structural transformations of some kaurane diterpenes, including either semisynthetic and/or microbiological methodologies, are consisely reviewed. At this point, some general considerations on glycosides are introduced, and kaurane glycosides are presented and discussed on the basis of their toxic importance and occurrence in the plant kingdom, having focused on related aspects of their biological activities and the relationships between these activities and the structural factors of their molecules. Finally, the principal methods of glycosidation by enzymatic and chemical processes are both presented, and a few papers on the synthesis of kaurane glycosides are succinctly discussed.     

Iron(II) promoted direct synthesis of dibenzo[b,e]oxepin-11(6H)-one derivatives with biological activity. A short synthesis of doxepin

A novel and efficient synthesis of dibenzo[b,e]oxepin-11(6H)-ones by direct intramolecular ortho-acylation from readily available 2-(phenoxymethyl)benzoic acids was developed. The method takes advantage of a newly developed cooperative system consisting of sustainable FeCl₂ and Cl₂CHOCH₃ as the key components. This methodology is compatible with a wide variety of functional groups in good to excellent yields and high regioselectivity. The synthetic application of new protocol was extended to the synthesis of known tricyclic drug doxepin as well as a small library of oxepin based derivatives. For the first time, the obtained dibenzo[b,e]oxepinone derivatives were evaluated for their biological activities on the free-living nematode Caenorhabditis elegans as an effective and cost-efficient model system for anthelmintic discovery.     

C(3)-酯基取代的1,5-苯并硫氮杂卓的合成、晶体结构及抑菌和构效关系的研究

设计、合成了三类C(3)酯基取代的1,5-苯并硫氮杂卓衍生物: 2,3/2,5-二氢和2,3,4,5-四氢-1,5-苯并硫氮杂卓-3-甲酸乙酯, 采用元素分析、IR、MS、1H NMR及X射线衍射法确定了标题化合物的分子结构．结构分析表明, 2,5-二氢-1,5-苯并硫氮杂卓-3-甲酸乙酯属单斜晶系, C2/c空间群, 晶胞参数为: a＝2.0319(4) nm, b＝1.4985(3) nm, c＝1.3659(3) nm, α＝90°, β＝120.49(3)°, γ＝90°, V＝3.5840(12) nm3, Z＝8, Dc＝1.397 g/cm3, μ＝0.351 mm－1, F(000)＝1560, R＝0.0478, Rw＝0.1304; 研究了2,3/2,5-二氢-1,5-苯并硫氮杂卓的合成反应条件, 发现该两种互变异构体分别是速度控制产物和平衡控制产物; 抑菌活性及抑真菌构效关系研究表明, 亚胺型的2,3-二氢-1,5-苯并硫氮杂卓具有明显的抑菌活性, 亚胺官能团是其抑真菌的药效团．     

Crop Yield and Essential Oil Composition of Two Thymus vulgaris Chemotypes along Three Years of Organic Cultivation in a Hilly Area of Central Italy

Thymus vulgaris L. is one of the most commonly used medicinal and aromatic plants (MAPs), owing to a range of therapeutic properties of its essential oil. Plant growth, biomass yield, essential oil content and composition are influenced by chemotype, environmental conditions, cultivation techniques and vegetative development. Since in MAPs cultivation special attention is paid on high quality of raw material, the adoption of sustainable agriculture methods is of pivotal importance. Therefore, we evaluated the agronomic and qualitative performances of two Thymus vulgaris L. chemotypes, organically cultivated under the Mediterranean climate of hilly lands of central Italy for three consecutive years (2017–2019). Along the trial, total above-ground dry biomass significantly increased from the 1st to 3rd year after planting and large variations in the main biological, biometric and productive traits were observed between the two chemotypes. The ‘thymol’ chemotype EO obviously showed thymol as the major constituent (51.26–49.87%) followed by γ-terpinene and p-cymene. The ‘linalool’ chemotype EO showed high percentages of oxygenated monoterpenes (about 90%) with linalool (75%), linalyl acetate (8.15%) and b-caryophyllene (3.2%) as main constituents. This study highlighted that T. vulgaris can be successfully organically grown in the hilly lands of Tuscany, with interesting biomass and essential oil yields, even though the plants were in the initial years of crop establishment (start in 2017). The introduction of this species into organic cultivation systems could contribute to obtain high-quality raw material, as well as to enhance crop rotation diversification, which is of pivotal importance in the management of organic farms.     

Synthesis,Crystal Structure,Cytotoxic, Antileishmanial and Docking Evaluation of 3-(4-Chloro-3-nitrophenyl)-1-phenylprop-2-en-1-one

Chalcone derivatives are of immense importance owing to their superior pharmacological profile. Minor changes in their structures create high degree of diversity that results in a broader spectrum of biological activities. The present research paper presents the synthesis of 3-(4-chloro-3-nitrophenyl)-1-phenylprop-2-en-1-one chalcone(I), single crystal XRD analysis and the evaluation of its possible biological activities like cytotoxic(LD_(50) = 5.40 ug/m L)and antileishmanial(LD_(50) = 0.81 ug/m L) activities. The results indicate the tested chalcone(I)shows superior inhibition values against leishmanial promastigotes. Further, the possible interaction sites of chalcone(I) with Try R enzyme involved in the redox metabolism of the leishmanial parasite were determined using docking simulation technique. Docking computations demonstrate that the compound establishes prominent binding interactions with the key residues of Try R and possesses the potential to effectively inhibit the catalytic activities of enzyme. Thus the results suggest that the chalcone(I) can serve as a potential scaffold for the treatment of leishmaniasis and deserve further development.     

Chirality and Crop Protection

The modern agrochemical industry is searching, more intensively than ever, for new substances to combat pests (weeds, deleterious insects, plant pathogens, etc.). In the complex and costly selection and optimization process, state-of-the-art scientific methods are always needed. The aims of the interdisciplinary optimization are mainly the reduction of the rate of application of the new substance, an increase in the selectivity against the target organism, and the optimal ecological profile. If a promising crop protection compound is a racemate or a diastereoisomeric mixture, the chemist has a unique opportunity to contribute to this optimization process through the synthesis of enantiomerically pure isomers for testing purposes. If the single isomer proves to be biologically superior to the racemate, the development of an economical and ecologically sound process for the production of the single isomer presents an even greater challenge. The average price of a crop protection compound is much lower than that for a pharmaceutical product, and this fact imposes a severe limitation upon the flexibility of the chemist who is concerned with the synthesis and production of a stereochemically pure agrochemical. This forces the crop protection chemist to make full use of both his scientific and creative capabilities. Fortunately, parallel to the development of the above optimization aims of a modern and ecologically sound crop protection research, there has been a continuous and worldwide advance in the area of asymmetric synthesis. Due to the interplay of these two parallel efforts there has been a great accumulation of chemical, biological, and agronomical knowledge in recent years, which should have implications beyond merely the synthesis of enantiomerically pure agrochemicals.     

苯丙素苷Acteoside,Isoacteoside和Ligupurpuroside J的全合成

发展了一条合成苯丙素苷类化合物的通用路线,并依据此路线完成了苯丙素苷毛蕊花糖苷（Acteoside）和异毛蕊花糖苷（Isoacteoside）的全合成及紫茎女贞苷J（Ligupurpuroside J）的首次全合成.其中的关键步骤是应用金（Ⅰ）催化的鼠李糖邻炔基苯甲酸酯给体与多羟基裸露的2-苯乙基葡萄糖苷进行区域选择性糖苷化反应,成功构建天然苯丙素苷中常见的α-（1→3）糖苷键.该合成路线减少了保护基的使用,简洁高效.     

Total Synthesis,Assignment of the Absolute Stereochemistry,and Structure‐Activity Relationship Studies of Subglutinols A and B

Immunosuppressive drugs are used to prevent rejection of transplanted organs and treat autoimmune diseases. Clinically approved immunosuppressive drugs possess undesirable side effects, including acute neurological toxicity, chronic nephrotoxicity, and osteoporosis. As a result, considerable efforts have been devoted to the identification of immunosuppressive natural products that lack cytotoxicity and undesirable side effects on bone structure. Subglutinols A ( 1 a ) and B ( 1 b ) are diterpene pyrones isolated from Fusarium subglutinans. Compounds 1 a and 1 b are equipotent in the mixed lymphocyte reaction assay and thymocyte proliferation assay (IC₅₀=0.1 μM ). Owing to the lack of toxicity, 1 a and 1 b are expected to be promising new immunosuppressive drugs. Herein, we detail our efforts that have culminated in a stereoselective synthesis of 1 a and 1 b from the (S)‐(+)‐5‐methyl‐Wieland–Miescher ketone and determined their absolute stereochemistries. We also present initial biological data to show the great potential of 1 a as an immunosuppressive drug with dose‐dependent osteogenic activity.