Recent Developments in Nematode Steroid Biochemistry

Current knowledge of steroid nutrition, metabolism, and function in free-living, plant-parasitic and animal-parasitic nematodes is reviewed, with emphasis upon recent investigation of Caenorhabditis elegans. A number of 4-desmethylsterols with a trans-A/B ring configuration can satisfy the steroid nutritional requirement in C. elegans, but sterols with a cis-A/B ring configuration or trans-A/B sterols with a 4-methyl group cannot. C. elegans removes methyl or ethyl substituents at C-24 of the plant sterols sitosterol, campesterol, stigmasterol, stigmastanol, and 24-methylene-cholesterol to produce various sterols with structures partially dependent upon that of the dietary sterol. Additional metabolic steps in C. elegans include reduction of Δ²²- and Δ⁵-bonds, C-7 dehydrogenation, isomerization of a Δ⁷-bond to a Δ⁸⁽¹⁴⁾-bond, and 4α-methylation. An azasteroid and several long-chain alkyl amines interfere with the dealkylation pathway in C. elegans by inhibiting the Δ²⁴-sterol reductase; these compounds also inhibit growth and reproduction in various plant-parasitic and animal-parasitic nematodes. A possible hormonal role for various steroids identified in nematodes is discussed.     

植物多肽抗生素研究进展

植物多肽抗生素是一类对细菌、真菌等微生物及某些昆虫和动植物细胞具有抑制或杀灭作用的小分子多肽. 根据多肽抗生素的氨基酸序列及二级结构,可将植物多肽抗生素分为9类,包括硫素（thionins）、植物防御素（plant defensins）、转脂蛋白（lipid transfer proteins, LTPs）、橡胶素（heveins）、打结素（knottins）、凤仙花素(1b-AMPs)和新近发现的荠菜素（shepherdins）、蜕皮素（snakins）、环肽（cyclotides）. 对近年来植物多肽抗生素的分类、抗菌机理、生物活性及基因工程等方面的研究情况作一介绍,希望有助于我国在这一领域的研究与开发.     

Peptide Derivatives of Antibiotics Tylosin and Desmycosin, Protein Synthesis Inhibitors

Biologically active peptide derivatives of 16-member macrolide antibiotics were synthesized as potential probes for the investigation of nascent peptide chain topography in the ribosomal exit tunnel. The tylosin and desmycosin aldehyde groups at the C6 position of the lactone ring were modified by the aminooxyacetyl-L-alanyl-L-alanine methyl ester.     

肽抗生素，控制感染的新希望

传统的抗生素都是由霉菌产生的 ,霉菌是寻找抗生素的传统领域。然而 ,新近的研究表明 ,动物、植物和人体的基因组中也有编码抗生素的基因。这些基因编码的多为一些短肽 ,富含带阳离子的氨基酸残基 ,称为肽抗生素 (ｐｅｐｔｉｄｅａｎｔｉｂｉｏｔｉｃｓ)或抗微生物肽 (ａｎｔｉｍｉｃｒｏｂｉａｌｐｅｐｔｉｄｅ) [1] 。肽抗生素和干扰素、补体等一样是宿主免疫防御系统的重要组成部分。因肽抗生素具有抗菌活性强 ,抗菌广谱性等特点 ,其研究受到广泛重视。1.肽抗生素的特点及其分类肽抗生素在自然界中广泛存在 ,代表宿主防御系统进化的古老…     

Isolation and Structures of New Peptide Antibiotics,Cirratiomycin A and B

We measured the concentrations of acetyl-CoA and malonyl-CoA in shoots and roots of corn (Zea mays, L., cv. “Peter Corn”). Acetyl-CoA and malonyl-CoA concentrations were found to be relatively constant in shoots and in roots under a light-dark cycle. Acetyl-CoA concentrations were lower in shoots than in roots, whereas malonyl-CoA concentrations were higher in shoots than in roots.     

The Structures of Cirratiomycin A and B,the New Peptide Antibiotics

The structures of cirratiomycin A and B have been elucidated by a degradative study and ¹H-and ¹³C-NMR spectral analysis. It is revealed here that cirratiomycin A and B are heptapeptides containing three unusual new amino acids, viz, hydroxymethylserine, 2,3,4,5-tetrahydropyridazine-3-carboxylic acid and 2,3-didehydroisoleucine.     

Synergistic Effect and Antibiofilm Activity Between the Antimicrobial Peptide Coprisin and Conventional Antibiotics Against Opportunistic Bacteria

Coprisin is a 43-mer defensin-like peptide from the dung beetle, Copris tripartitus. In this study, we tested its minimum inhibitory concentration and performed combination assays to confirm the antibacterial susceptibility of coprisin and synergistic effects with antibiotics. The synergistic effects were evaluated by testing the effects of coprisin in combination with ampicillin, vancomycin, and chloramphenicol. The results showed that coprisin possessed antibacterial properties and had synergistic activities with the antibiotics. To understand the synergistic mechanism(s), we conducted hydroxyl radical assays. Coprisin alone and in combination with antibiotics generated hydroxyl radicals, which are highly reactive oxygen forms and the major property of bactericidal agents. Furthermore, the antibiofilm effect of coprisin alone and in combination with antibiotics was investigated. Biofilm formation is the source of many relentless and chronic bacterial infections. The results indicated that coprisin alone and in combination with antibiotics also had antibiofilm activity. Therefore, we conclude that coprisin has the potential to be used as a combinatorial therapeutic agent for the treatment of infectious diseases caused by bacteria.