Effects of intrinsic fluorescence and quenching on fluorescence-based screening of natural products

To evaluate the effects of intrinsic (natural) fluorescence and quenching as confounding variables in fluorescence-based enzyme inhibition assays of natural products, we measured the fluorescence and quenching properties of 25 components of popular herbal products. The analyses were performed under conditions typically employed in drug-drug interaction studies that use c-DNA-derived P450 isoforms and surrogate fluorogenic substrates. Four of the 25 compounds tested (isorhamnetin, quercetin, vitexin, and yangonin) fluoresced or quenched sufficiently to interfere with these assays. Intrinsic fluorescence had a greater effect on these assays than quenching and for one compound, yangonin, was sufficient to mask inhibition and potentially produce a false negative result. Quenching had less of an effect on these assays, but was significant enough for one compound, quercetin, to mimic "weak" inhibition. Therefore, because intrinsic fluorescence or quenching could render some natural products unsuitable for testing in certain fluorometric assays, it would be prudent to include an evaluation of these properties in experimental protocols.     

Selection and screening for enzymes of nitrile metabolism

This work critically reviews the assays of nitrile-converting and nitrile-forming enzymes (nitrilases, nitrile hydratases, amidases, aldoxime dehydratases). Most of the strains producing such enzymes were obtained by selection on media with nitriles, amides or aldoximes as nitrogen sources. Activity and enantioselectivity of the enzymes was usually assayed by time-consuming chromatographic analysis of substrates and the corresponding reaction products. Attempts at introducing faster assays resulted in several spectrophotometric methods for reaction product (ammonia, hydroxamate, methacrylamide, benzamide, etc.) determination. Recently, new methods for colorimetric and fluorimetric determination of ammonia have been developed, which appear promising for high-throughput assays. Alternatively, methods consisting in determination of NADH consumed in a coupled amination reaction or pH-responsive methods are promising for this purpose. All the above selection and screening methods establish fundamental conditions for the design of hierarchical screening projects. However, the potential of these principles, in particular spectrophotometric and fluorimetric methods, will be probably further exploited and adapted to multiwell plate and robotic systems.     

ATP reduces gel compaction in osteoblast-populated collagen gels.

Bone remodeling is a localized process, but regulated by systemic signals such as hormones, cytokines, and mechanical loading. The mechanism by which bone cells convert these systemic signals into local signals is not completely understood. It is broadly accepted that the "prestress" in cytoskeleton of cells affects the magnitude of cellular responses to mechanical stimuli. Prestress derives from stiff cytoskeletal proteins and their connections within the cell and from cell contractility upon attaching to matrix. In an in vitro model of three-dimensional gel compaction, the relative cellular prestress levels in the same matrix environment were determined by matrix compaction rate: a greater compaction rate resulted in a higher level of prestress. In the present study, the effects of ATP on the prestress of osteoblasts were studied using mouse MC3T3-E1 cells grown in three-dimensional bioartificial tissues (BATs). ATP (> or =100 microM) reduced the compaction rate of BATs in a dose-dependent manner. ADP, 2'-(or 3')-O-(4-benzoylbenzoyl) ATP, and UTP, but not alpha,beta-methylene ATP, also reduced the compaction rate but to a lesser extent. Pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid tetrasodium did not block the effect of ATP on BAT compaction rate. These results indicate that both P2X and P2Y receptors are involved in ATP-induced reduction of BAT compaction rate. Steady fluid flow and RT-PCR results showed that ATP reduced cell attachment on type I collagen by downregulating the expression of integrin alpha(1). These results suggest a potential role for P2 receptors in matrix remodeling and repair and as a potential drug target in treatment of bone diseases.     

Novel bioactive natural products from bacteria via bioprospecting,genome mining and metabolic engineering

For over seven decades, bacteria served as a valuable source of bioactive natural products some of which were eventually developed into drugs to treat infections, cancer and immune system-related diseases. Traditionally, novel compounds produced by bacteria were discovered via conventional bioprospecting based on isolation of potential producers and screening their extracts in a variety of bioassays. Over time, most of the natural products identifiable by this approach were discovered, and the pipeline for new drugs based on bacterially produced metabolites started to run dry. This mini-review highlights recent developments in bacterial bioprospecting for novel compounds that are based on several out-of-the-box approaches, including the following: (i) targeting bacterial species previously unknown to produce any bioactive natural products, (ii) exploring non-traditional environmental niches and methods for isolation of bacteria and (iii) various types of ‘genome mining’ aimed at unravelling genetic potential of bacteria to produce secondary metabolites. All these approaches have already yielded a number of novel bioactive compounds and, if used wisely, will soon revitalize drug discovery pipeline based on bacterial natural products.     

Analysis of covalently bound polyketide intermediates on 6-deoxyerythronolide B synthase by tandem proteolysis-mass spectrometry

Polyketide natural products are biosynthesized via successive chain-elongation events mediated by elaborate protein assemblies. Facile detection of protein-bound intermediates in these systems will increase our understanding of enzyme reactivity and selectivity. We have developed a tandem proteolysis/mass spectrometric method for monitoring substrate loading and elongation in 6-deoxyerythronolide B synthase (DEBS), responsible for production of the macrolide precursor to erythromycin. Information regarding ketosynthase loading and polyketide unit elongation is readily acquired without need for complex protein or small molecule labels. A panel of structurally related substrates is evaluated through competition experiments and kinetic assays using LC-MS to resolve closely related species. Strong stereochemical effects are observed for ketosynthase substrate specificity. Semiquantitative kinetic analyses allow the resolution of the effects of structural and stereochemical changes on the individual ketosynthase-catalyzed steps of acyl-enzyme formation and polyketide chain extension.     

Consequences of protist-stimulated bacterial production for estimating protist growth efficiencies

The trophic link between bacteria and bacterivorous protists is a complex interaction that involves feedback of inorganic nutrients and growth substrates that are immeadiately available for prey growth. These interactions were examined in the laboratory and in incubations of concentrated natural assemblages of bacterioplankton. Growth dynamics of estuarine and marine bacterivorous protists were determined in laboratory culture using Vibrio natriegens as prey and were compared to growth of protists on bacterioplankton assemblages concentrated by tangential flow filtration from four northwest Florida Estuaries. Biomass transfers from bacteria to protists were monitored by tracing elemental carbon and nitrogen in particulate fractions of protist added and grazer free controls. Gross growth efficiencies of the protists on naturally occurring bacteria were within the range determined in lab estimates of growth efficiency on cultured bacteria (50%). However, bacterial response to protist excretion products was different in the lab and field incubations, and bacterial growth contributed to the biomass available to protists in the field incubations. As determined by radioisotope-labeled substrate incorporation, a time lag in bacterial reponse to protist excretion products was observed for laboratory batch cultures, allowing accurate estimation of growth efficiency. In incubations with concentrated natural bacterial assemblages, bacterial growth response coincided with protist growth and excretion. The additional bacterial production on protist excretion products reached a maximum of 2–3-fold higher than protist-free controls. In addition, ammonium concentrations increased with protist grazing and growth in lab cultures, but ammonium excreted by protists in concentrates did not accumulate. The C:N values for the bacterial concentrates suggests that these bacteria were nitrogen limited. It is speculated that dissolved organic carbon, concentrated by tangential flow filtration (> 100,000 MW membrane) with the bacterioplankton, was utilized by bacteria when nitrogen was supplied as ammonium and amino acids from protist excretion. Thus, estimates of protist growth efficiency on naturally occurring bacterioplankton, corrected for protist-stimulated bacterial production, were in the range of 13–21%.     

Development of novel assays for proteolytic enzymes using rhodamine-based fluorogenic substrates

Components within synthetic chemical and natural product extract libraries often interfere with fluorescence-based assays. Fluorescence interference can result when the intrinsic spectral properties of colored compounds overlap with the fluorescent probes. Typically, fluorescence-based protease assays use peptide amidomethylcoumarin derivatives as substrates. However, because many organic compounds absorb in the ultraviolet region, they can interfere with coumarin-based fluorescence assays. Red-shifted fluorescent dyes such as peptidyl rhodamine derivatives are useful because there is generally less interference from organic compounds outside the ultraviolet wavelengths. In this report, rhodamine-based fluorogenic substrates, such as bis-(Leu)(2)-Rhod110 and bis-(Ala-Pro)-Rhod110, were developed for leucine aminopeptidase and dipeptidyl aminopeptidase. Novel, tandem rhodamine substrates such as Ala-Pro-Rhod110-Leu were designed with 2 protease cleavage sites and used to assay 2 proteases in a multiplex format. General endpoint high-throughput screening (HTS) assays were also developed for leucine aminopeptidase, dipeptidyl aminopeptidase, and trypsin that incorporated both amidomethylcoumarin and rhodamine-based fluorogenic substrates into a single screening format. These dual-substrate assays allowed for the successful screening of the LOPAC trade mark collection and natural product extracts despite high levels of fluorescence interference.     

HSP60/10 chaperonin systems are inhibited by a variety of approved drugs,natural products,and known bioactive molecules

All living organisms contain a unique class of molecular chaperones called 60?kDa heat shock proteins (HSP60 – also known as GroEL in bacteria). While some organisms contain more than one HSP60 or GroEL isoform, at least one isoform has always proven to be essential. Because of this, we have been investigating targeting HSP60 and GroEL chaperonin systems as an antibiotic strategy. Our initial studies focused on applying this antibiotic strategy for treating African sleeping sickness (caused by Trypanosoma brucei parasites) and drug-resistant bacterial infections (in particular Methicillin-resistant Staphylococcus aureus – MRSA). Intriguingly, during our studies we found that three known antibiotics – suramin, closantel, and rafoxanide – were potent inhibitors of bacterial GroEL and human HSP60 chaperonin systems. These findings prompted us to explore what other approved drugs, natural products, and known bioactive molecules might also inhibit HSP60 and GroEL chaperonin systems. Initial high-throughput screening of 3680 approved drugs, natural products, and known bioactives identified 161 hit inhibitors of the Escherichia coli GroEL chaperonin system (4.3% hit rate). From a purchased subset of 60 hits, 29 compounds (48%) re-confirmed as selective GroEL inhibitors in our assays, all of which were nearly equipotent against human HSP60. These findings illuminate the notion that targeting chaperonin systems might be a more common occurrence than we previously appreciated. Future studies are needed to determine if the in vivo modes of action of these approved drugs, natural products, and known bioactive molecules are related to GroEL and HSP60 inhibition.     

Glycosyltransferases involved in the biosynthesis of biologically active natural products that contain oligosaccharides

A unique characteristic of carbohydrates is their structural diversity which is greater than that of many other classes of biological compounds. Carbohydrate-containing natural products show many different biological activities and some of them have been developed as drugs for medical use. The biosynthesis of carbohydrate-containing natural products is catalysed by glycosyltransferases. In this review we will present information on the function of glycosyltransferases involved in the biosynthesis of oligosaccharide antibiotics focusing especially on urdamycins and landomycins, two angucycline antibiotics with interesting antitumor activities. We will also discuss the use of glycosyltransferases in combinatorial biosynthesis to generate new "hybrid" antibiotics.     

Plant drugs in the twenty-first century

Lack of effective cooperation among researchers in the applicable biological, physical, and clinical sciences has accounted, in large measure, for the lack of successful development in the United States of any significant number of new plant drugs during the latter part of the 20th century. Unrealistic federal regulations that tend to render unprofitable such research have also played an important role in hindering the development of new plant drugs. It is likely that both of these factors will change in the future as health-conscious consumers demand more accurate information and wider availability of natural drug products. Several anticipated developments will greatly facilitate research and production in this previously difficult area. These include the development of new, simplified bioassay procedures; improved, easily applied analytical methods; and innovative plant-cell-culture methodologies, possibly involving genetic manipulation. The kinds of drugs that need to be developed using such techniques are discussed. It is concluded that significant new plant drugs and new methods of producing them will be developed to serve mankind during the 21st century.     

Brown adipose tissue as a derivative of mesoderm grafted below the kidney capsule. A model for differentiation of isolated rat mesoderm.

During development, mesoderm differentiates into connective tissue, cartilage, bone, muscle and kidney. In experimental conditions the developmental spectrum of mesoderm grafted below the kidney capsule is reduced so that mostly brown adipose tissue (BAT) appears. Since BAT is a particular tissue with a specific developmental pattern, the structural and functional characteristics of experimentally developed BAT were analyzed in the present study. Mesoderm from nine-day-old rat embryos was grafted below the kidney capsule of adult rats and one month later the BAT-containing tumors were analyzed. The ultrastructural and morphometrical data of BAT-containing tumors were the same as in BAT developed in situ. Tissue-specific mRNA for uncoupling protein (UCP) was expressed in BAT-containing tumors, and immuno-electron microscopical analysis showed that mitochondria of these brown adipocytes contained UCP. Injections of noradrenaline and exposure of BAT-tumor-bearing rats to cold stress increased both the amount of UCP and the expression of UCP mRNA in tumors of BAT; i.e., experimentally developed BAT entirely resembled standard BAT. It is proposed that mesoderm isolated and displaced below the kidney capsule lacks the inductive stimuli of ectoderm and endoderm, and as a result mesoderm can not realize the natural pattern of differentiation. Here, in a new environment, mesoderm is exposed to new stimuli which induce differentiation of mesoderm into BAT, probably through neuro-vascular elements from the medial side of the kidney (BAT area). Thus, although mesoderm contains a wide differentiation capacity, it can differentiate into only one type of tissue, depending on the presence and range of inductive stimuli.     

Enzymatic assays for NAD-dependent deacetylase activities

The NAD-dependent deacetylases are a new class of enzymes responsible for the removal of acetyl groups from lysines on proteins. Instead of water, the NAD-dependent deacetylases use a highly reactive ADP-ribose intermediate as a recipient for the acetyl group. The products of the reaction are nicotinamide, acetyl-ADP-ribose, and a deacetylated substrate. Many assays have been developed for the measurement of NAD-dependent deacetylase activity. In this review we present assays based on each of the two reactions catalyzed by these enzymes, deacetylation and NAD hydrolysis. First we describe methods for the production of acetylated protein and peptide substrates for use in deacetylation reactions. Then we describe four methods for assaying deacetylation, three of which directly measure the loss of acetyl groups from a protein or peptide substrate, and one that measures acetate production. We also describe two indirect methods for following enzyme activity, NAD hydrolysis and a novel NAD-nicotinamide exchange reaction. Finally, a quantitative method using a monoacetylated peptide as a substrate and HPLC to measure products is described.     

A BODIPY fluorescent microplate assay for measuring activity of calpains and other proteases

The use of 4,4-difluoro-5,7-dimethyl-4-bora-3a, 4a-diaza-s-indacene-3-propionic acid (BODIPY-FL) labeled casein in autoquenching assays of proteolytic activity has been recently described, and we have adapted this assay to measurement of calpain activity. BODIPY-FL coupled to casein at a ratio of 8 mol of BODIPY-FL/mol of casein or higher produces a BODIPY-FL-casein substrate that can be used in an autoquenching assay of calpain proteolytic activity. This assay has a number of advantages for measuring calpain activity. (1) The procedure does not require precipitation and removal of undegraded protein, so it is much faster than other procedures that require a precipitation step, and it can be used directly in kinetic assays of proteolytic activity. (2) The BODIPY-FL-casein assay is easily adapted to a microtiter plate format, so it can be used to screen large numbers of samples. (3) Casein is an inexpensive and readily available protein substrate that more closely mimics the natural substrates of endoproteinases, such as the calpains, than synthetic peptide substrates do. Casein has K(m) values for micro- and m-calpain that are similar to those of other substrates such as fodrin or MAP2 that may be "natural" substrates for the calpains, and there is no reason to believe that calpain hydrolysis of casein is inherently different from hydrolysis of fodrin or MAP2, which are much less accessible as substrates for protease assays. (4) The BODIPY-FL-casein assay is capable of detecting 10 ng ( approximately 5 nM) of calpain and is nearly as sensitive as the most sensitive calpain assay reported thus far. (5) The BODIPY-FL-casein assay is as reproducible as the FITC-casein assay, whose reproducibility is comparable to or better than the reproducibility of other methods used to assay calpain activity. The BODIPY-FL-casein assay is a general assay for proteolytic activity and can be used with any protease that cleaves casein.     

A cDNA library functional screening strategy based on fluorescent protein complementation assays to identify novel components of signaling pathways

Progress towards a deeper understanding of cellular biochemical networks demands the development of methods to both identify and validate component proteins of these networks. Here, we describe a cDNA library screening strategy that achieves these aims, based on a protein-fragment complementation assay (PCA) using green fluorescent protein (GFP) as a reporter. The strategy combines a simple cell-based cDNA-screening approach (interactions of a "bait" protein of interest with "prey" cDNA products) with specific functional assays that use the same system and provide initial validation of the cDNA products as being biologically relevant. We applied this strategy to identify novel interacting partners of the protein kinase PKB/Akt. This method provides very general means of identifying and validating genes involved in any cellular process and is particularly designed for identifying enzyme substrates or regulatory proteins for which the enzyme specificity can only be defined by their interactions with other proteins in cells in which the proteins are normally expressed.     

High-throughput assays for botulinum neurotoxin proteolytic activity: serotypes A, B, D, and F

Botulinum neurotoxins (BoNT) are zinc metalloproteases that cleave and inactivate cellular proteins essential for neurotransmitter release. Because the paralytic effect of BoNT is a consequence of its enzymatic activity, selective inhibitors may be useful as drugs or as tools for further research. To expedite inhibitor discovery, we developed high-throughput, solid-phase protease activity assays for four of the seven BoNT serotypes: A, B, D, and F. Each assay consisted of a cleavable oligopeptide, based on the natural substrate sequence, labeled with fluorescein and covalently attached to maleimide-activated multiwell plates. Solutions of holotoxin or nontoxic catalytic domain of BoNT were incubated in substrate-coated wells, with or without test compounds, followed by transfer and assay of solubilized product in a multiwell fluorometer. Routine toxin concentrations ranged from 10 to 100 ng/ml, but concentrations as low as 2 ng/ml gave reproducible signals. The fluorescence assays were selective, gave very low background readings, and were stable upon prolonged storage. Using the nontoxic catalytic domain of BoNT A, we determined the relative inhibitory potencies of a family of structurally related pseudotripeptide compounds. Unlike previous methods, our assays did not employ antibodies or reverse-phase extraction steps, only well-to-well transfers, and were easily adapted to a high-throughput automated environment.     

Prospects for novel inhibitors of peptidoglycan transglycosylases

The lack of novel antimicrobial drugs under development coupled with the increasing occurrence of resistance to existing antibiotics by community and hospital acquired infections is of grave concern. The targeting of biosynthesis of the peptidoglycan component of the bacterial cell wall has proven to be clinically valuable but relatively little therapeutic development has been directed towards the transglycosylase step of this process. Advances towards the isolation of new antimicrobials that target transglycosylase activity will rely on the development of the enzymological tools required to identify and characterise novel inhibitors of these enzymes. Therefore, in this article, we review the assay methods developed for transglycosylases and review recent novel chemical inhibitors discovered in relation to both the lipidic substrates and natural product inhibitors of the transglycosylase step.     

新型抗结核药物研发：微生物非常规培养与沉默基因激活策略

由结核分枝杆菌感染引起的结核病是人类重要传染病之一。临床上结核菌耐药性日趋严重,不断出现的耐多药及广泛耐药结核病患者,使现有的一线至五线药物不能满足结核病防控需求。微生物来源的天然产物是药物先导化合物的重要来源。环境中存在大量常规培养条件下未培养微生物,同时微生物基因组中也存在大量未被表达的"沉默代谢途径"。运用各种方法对未培养微生物进行再培养,同时激活微生物的沉默代谢途径,进而获得潜在的新型抗生素药物已成为目前研究热点。文中系统阐述了近年来获取天然化合物所采用的微生物非常规培养技术及沉默代谢途径激活策略,同时总结了利用这两种方法获得的新型抗结核天然产物,并展望了这些方法在抗结核药物进一步研发中的应用前景。     

Pharmaceutical Compounds and Ecosystem Function: An Emerging Research Challenge for Aquatic Ecologists

The number of anthropogenic compounds that occur in aquatic ecosystems today is in the thousands, many at trace concentrations. One group of compounds that has captured the interest of both the scientific community and the general public is pharmaceutical and personal care products (PPCPs), for example, hormones, chemotherapy drugs, antihistamines, stimulants, antimicrobials and various cosmetic additives. Toxicology of some PPCPs is currently understood, but their effect on ecological structure and function of aquatic ecosystems is largely unknown. We review sources and fates of these compounds in aquatic ecosystems and discuss how methods developed to study aquatic ecosystem ecology can contribute to our understanding of the influence of PPCPs on aquatic ecosystems. We argue that aquatic ecology has a well-developed tool kit for measuring the transformation, fate, and transport of solutes using assays and experiments and that these methods could be employed to investigate how PPCPs impact ecological function. We discuss the details of these approaches and conclude that application of existing ecological methods to the study of this issue could substantially improve our understanding of the effect of these compounds in aquatic ecosystems.