Development of a rapid riboflavin growth-based assay using Lactobacillus rhamnosus

Golbach, Jennifer L.

12 April 2006

Riboflavin is an essential part of the human diet. Although the United States does not have a major problem with a riboflavin deficiency, other regions of the world do. This is especially true for those regions whose main subsistence is rice. To help prevent and control riboflavin deficiencies, many cereal grains are now being fortified with riboflavin. The recommended dietary allowance of riboflavin is 1.1-1.6 mg per day. This value increases slightly for pregnant women, breast feeding women, and athletes. Because riboflavin is an essential part of the diet, it is important to ensure that the minimum requirements for this nutrient are met. By determining the amount of riboflavin in food products, an accurate estimate of daily riboflavin intake can be determined. The AOAC (Association of Official Analytical Chemists) approved microbiological riboflavin assay can be tedious and time consuming. A faster approach to the riboflavin assay would greatly benefit the food industry. By scaling down the assay to microtiter plates both, time and materials can be conserved. Use of microtiter plates would also allow for numerous samples to be assayed simultaneously. The goal for developing the microtiter plate assay is to obtain results more rapidly while maintaining the accuracy and precision of the AOAC ( method 940.33I) tube assay.

riboflavin

Lactobacillus rhamnosus

microtiter plate assay

anaerobic conditions

reducing agents

The Impact of D-amino acids on Formation and Integrity of Biofilm – Effect of Growth Condition and Bacteria Type

Li, Xuening

16 September 2013

Biofouling is a major issue in applying nanofiltration and reverse osmosis technologies for wastewater treatment. Biofilm formed on the surface of membranes will severely decline the flux and cause energy waste. In this study, a novel biofouling control method that applies D-amino acids to inhibit biofilm formation was investigated. The D-amino acids previously reported to inhibit biofilm formation and disrupt existing biofilm – D-tyrosine and the mixture of D-tyrosine, D-tryptophan, D-leucine and D-methionine were tested. Pseudomonas aeruginosa and Bacillus subtilis were used as model Gram-negative and Gram-positive bacteria, respectively. D-amino acids have little effect and some effect on inhibition of biofilm formation and disruption of exiting biofilm to Pseudomonas aeruginosa, but have good effect to Bacillus subtilis. A commonly used microtiter plate assay for quantitative biofilm measurement was systematically evaluated and optimized for screening biofilm control agents. The effect of D-tyrosine on inhibition of organic fouling and P. aeruginosa biofouling on NF90 membrane surface in bench scale dead end filtration experiment was examined, which shows that D-tyrosine can effectively inhibit organic fouling and P. aeruginosa biofouling on NF90 membrane surface.

Anti-biofouling

NF/RO membrane

D-amino acids

microtiter plate assay

Triazole-linked reduced amide isosteres: An approach for the fragment-based drug discovery of anti-Alzheimer's BACE1 inhibitors and NH-assisted Fürst-Plattner opening of cyclohexene oxides

Monceaux, Christopher Jon

14 January 2011

In the scope of our BACE1 inhibitor project we used an originally designed microtiter plate-based screening to discover 4 triazole-linked reduced amide isosteres that showed modest (single digit micromolar) BACE1 inhibition. Our ligands were designed based on a very potent (single digit nanomolar) isopththalamide ligand from Merck. We supplanted one of the amide linkages in order to incorporate our triazole and saw a 1000-fold decrease in potency. We then enlisted Molsoft, L.L.C. to compare our ligand to Merck's in silico to account for this discrepancy. They found that the triazole linkage gives rise to a significantly different docking pose in the active site of the BACE1 enzyme, therefore diminishing its potency relative to the Merck ligand. The ability to control the regio- and stereochemical outcome of organic reactions is an ongoing interest and challenge to synthetic chemists. The pre-association of reacting partners through hydrogen bonding (H-bonding) can often to yield products with extremely high stereoselectivity. We were able to show that anilines, due to their enhanced acidity relative to amines, can serve as substrate directing moieties in the opening of cyclohexene oxides. We observed that by judicious choice of conditions we could control the regiochemical outcome of the reaction. These studies demonstrate that an intramolecular anilino-NH hydrogen bond donor can direct Fürst-Plattner epoxide opening. A unified mechanism for this phenomenon has been proposed in this work which consists of a novel mechanistic route we call "NH-directed Fürst-Plattner." We further studied the opening of cyclohexene oxides by incorporating amide and amide derivative substituents in both the allylic and homoallylic position relative to the epoxide moiety. Our attempts to control regioselectivity in the allylic systems were unsuccessful; however when the directing substituent was in the homoallylic position, we could demonstrate some degree of regioselectivity. An additional project that the author worked on for approximately one year during his graduate student tenure is not described within this work. In February of 2009 AstraZeneca, Mayo Clinic, and Virginia Tech Intellectual Properties Inc. concomitantly announced that AstraZeneca licensed a portfolio of preclinical Triple Reuptake Inhibitor (TRI) compounds for depression. The lead compound, PRC200, was discovered by a collaborative effort between the Carlier and Richelson (Mayo Clinic Jacksonville) research groups in 1998. The author was tasked to develop backup candidates of PRC200 in order to improve the pharmacokinetics of the lead compound. Due to confidentiality agreements, this work is not reported herein. / Ph. D.

Fürst-Plattner (trans diaxial effect)

epoxidation

epoxide opening

click-chemistry

diazotransfer

microtiter plate-based screening

reduced amide BACE1 inhibitors

Determination of the effects that a previously uncharacterized secreted product from Klebsiella pneumoniae has on Citrobacter freundii and Enterobacter cloacae biofilms

Hastings, Cody M

01 May 2017

More so than ever, Multiple Drug Resistant (MDR) bacteria are on the rise due to overuse of antibiotics along with natural selection for adaptations that enhance drug-resistant properties. One particular bacterial family, Enterobacteriaceae, has been problematic, exhibiting several bacterial members that have developed a precipitous resistance to modern antibiotics and are also primary causative agents of nosocomial, or hospital acquired, infections. Citrobacter freundii (CF) and Enterobacter cloacae (ECL) are two species of the Enterobacteriaceae family causing significant medical concern due to their role in producing numerous opportunistic infections such as bacteremia, lower respiratory tract infections, urinary tract infections, and endocarditis. Adding to the difficulty of this situation is the ability of bacteria to produce biofilms. These biofilms are communities of bacteria that exhibit increased resistance to antibiotic treatment and eradication. Previous work in the laboratory of Dr. Fox at ETSU has identified an uncharacterized product secreted by Klebsiella pneumoniae (KP), another member of the Enterobacteriaceae family, which appears to have inhibitory effects toward CF and ECL. The current study was designed to characterize the effects this secreted product has on CF and ECL biofilms. Through a high throughput microtiter plate assay, the effects of this secreted product were examined on CF and ECL phases of biofilm attachment and maturation. Based on our findings, we have concluded that this secreted product can be categorized as a possible bacteriostatic agent against biofilm cell density, biofilm mass, and cell viability for both biofilm phases of attachment and maturation.

attachment

maturation

inhibition

biofilm

Klebsiella

microtiter assay

Bacteria

Bacteriology

Cell and Developmental Biology

Medical Cell Biology

Medical Microbiology

Microbial Physiology

Pathogenic Microbiology

Glycoconjugates : synthesis and investigation of carbohydrate-protein interactions

Spjut, Sara

January 2010

To study the functions of glycoconjugates in biological systems reliable and efficient protocols for glycoconjugate synthesis are needed. To reach this goal we have developed methods for solid-phase synthesis of glycoconjugates that can be monitored with gel-phase 19F spectroscopy using fluorinated linkers, building blocks, and protecting groups. We have developed a new fluorine containing linker suitable for solid-phase synthesis of glycoconjugates. The linker was more acid-labile than similar linkers in order to enable cleavage under mild conditions of the target compound from the linker resin.  A carbamate-based strategy has been applied to attach a spacer carrying an amino group to a fluorinated Wang linker for synthesis of amino-functionalized glycoconjugates using thioglycoside donors with fluorinated protective groups. Cleavage from the solid support was performed with trifluoroacetic acid and subsequent protecting group removal gave the target compound. The terminal amine was conjugated with didecyl squarate and this derivative can be attached to various proteins and solid surfaces carrying primary or secondary amines. To evaluate this methodology we have immobilized glycoconjugates in amino-functionalized microtiter plates and successfully probed them with lectin. In addition, a novel fluorine containing protecting group has been designed, synthesized and evaluated. The protecting group was used for protection of the unreactive 4-OH in a galactose building block that was applied in the synthesis of 6-aminohexyl galabioside and was removed with TBAF in THF. Adenovirus serotype 8 (Ad8), Ad19, and Ad37 cause the severe ocular infection, epidemic keratoconjunctivities (EKC). During infection, the adenoviruses interact with sialic acid containing glycoconjugates on the epithelial cells via fiber structures extending from the viral particles. The virus particle most likely binds to the host cell in a multivalent way by simultaneously using multiple fiber proteins and binding sites. Multivalent sialic acid containing conjugates could efficiently inhibit Ad37 cell attachment and subsequent infection of human corneal epithelial (HCE) cells. Three compact tri- and tetravalent sialic acid conjugates were prepared and evaluated as inhibitors of adenoviral host cell attachment and subsequent infection and all conjugates were potent as anti-adenoviral agents. The conjugates can readily be synthesized from accessible starting materials. A crystal structure of the Ad37 fiber knob protein and the trivalent sialic acid conjugate showed that the three binding sites were all occupied by one sialic acid residue each.

Glycoconjugates

Carbohydrates

Galactose

Glucose

Solid-phase synthesis

SPOS

Glycosylation

Gel-phase 19F NMR spectroscopy

Fluorinated linker

Carbohydrate array

Microtiter plates

Carbohydrate-protein interactions

carbamate linker

Fsec

Protecting group

Fluorinated protecting group

Multivalent glycoconjugates

Adenovirus

Ad37

Epidemic keratoconjunctivitis

EKC

Sialic acid

Adenovirus inhibitor

Trivalent

Tetravalent

X-ray crystal structure

Bioorganic chemistry

Bioorganisk kemi