Sintesi di PNA a libertà conformazionale ridotta

The present work started a research project aimed at the synthesis of conformationally “locked” PNA (Peptide Nucleic Acids) monomers. Compared to classic aeg-PNA, this structural modification would result in an improvement in the pairing properties with natural nucleic acids, due to entropic variations in the process. Specifically, an attempt was made to build a PNA monomer around a β-lactam ring. That ring could be imagined as obtained by linking the methylene groups in α position of both the nucleobase and the carboxyl function. These structural properties would imply pre-organization of the final oligomer, improving the pairing process in biological systems. The first step of this work was the investigation of the Staudinger reaction for the ciclization of the lactam ring, and in particular the activation method of the carboxylic group of the nucleobase derivatives. Use of triazine chloride led to the synthesis of the adenine-based β-lactam-PNA. Attempts to synthesize the same monomer based on cytosine, guanine and thymine were unsuccessful, so alternative methods for carboxylic group activation were investigated. Conversion of carboxylic acids to acyl chlorides led to a partial result: despite the method worked well with analogues of the final reactants, it didn’t worked with substrates needed for lactam based PNAs. Search for a valid activation process continued involving carbonyl diimidazole, Mukayama reagent, and LDA (with methylester derivative of nucelobase) without good results. Last, it was investigated a different synthetic approach by first synthesizing a proper backbone with a chlorine in the β- lactam ring. This chlorine ring should undergo substitution by a nucleobase anion to give the desired PNA monomer. Unluckily also this synthetic route didn’t lead to the desired monomers.

Engineering the synthesis of lantibiotics in e. Coli by combining the cynnamicin and nisin modification systems.

I lantibiotici sono molecole peptidiche prodotte da un gran numero di batteri Gram-positivi, posseggono attività antibatterica contro un ampio spettro di germi, e rappresentano una potenziale soluzione alla crescente problematica dei patogeni multi-resistenti. La loro attività consiste nel legame alla membrana del bersaglio, che viene quindi destabilizzata mediante l’induzione di pori che determinano la morte del patogeno. Tipicamente i lantibiotici sono formati da un “leader-peptide” e da un “core-peptide”. Il primo è necessario per il riconoscimento della molecola da parte di enzimi che effettuano modifiche post-traduzionali del secondo - che sarà la regione con attività battericida una volta scissa dal “leader-peptide”. Le modifiche post-traduzionali anticipate determinano il contenuto di amminoacidi lantionina (Lan) e metil-lantionina (MeLan), caratterizzati dalla presenza di ponti-tioetere che conferiscono maggior resistenza contro le proteasi, e permettono di aggirare la principale limitazione all’uso dei peptidi in ambito terapeutico. La nisina è il lantibiotico più studiato e caratterizzato, prodotto dal batterio L. lactis che è stato utilizzato per oltre venti anni nell’industria alimentare. La nisina è un peptide lungo 34 amminoacidi, che contiene anelli di lantionina e metil-lantionina, introdotti dall’azione degli enzimi nisB e nisC, mentre il taglio del “leader-peptide” è svolto dall’enzima nisP. Questo elaborato affronta l’ingegnerizzazione della sintesi e della modifica di lantibiotici nel batterio E.coli. In particolare si affronta l’implementazione dell’espressione eterologa in E.coli del lantibiotico cinnamicina, prodotto in natura dal batterio Streptomyces cinnamoneus. Questo particolare lantibiotico, lungo diciannove amminoacidi dopo il taglio del leader, subisce modifiche da parte dell’enzima CinM, responsabile dell’introduzione degli aminoacidi Lan e MeLan, dell’enzima CinX responsabile dell’idrossilazione dell’acido aspartico (Asp), e infine dell’enzima cinorf7 deputato all’introduzione del ponte di lisinoalanina (Lal). Una volta confermata l’attività della cinnamicina e di conseguenza quella dell’enzima CinM, si è deciso di tentare la modifica della nisina da parte di CinM. A tal proposito è stato necessario progettare un gene sintetico che codifica nisina con un leader chimerico, formato cioè dalla fusione del leader della cinnamicina e del leader della nisina. Il prodotto finale, dopo il taglio del leader da parte di nisP, è una nisina completamente modificata. Questo risultato ne permette però la modifica utilizzando un solo enzima invece di due, riducendo il carico metabolico sul batterio che la produce, e inoltre apre la strada all’utilizzo di CinM per la modifica di altri lantibiotici seguendo lo stesso approccio, nonché all’introduzione del ponte di lisinoalanina, in quanto l’enzima cinorf7 necessita della presenza di CinM per svolgere la sua funzione.

Chemical composition modification of casting aluminium alloys for engine applications

The research activities were focused on evaluating the effect of Mo addition to mechanical properties and microstructure of A354 aluminium casting alloy. Samples, with increasing amount of Mo, were produced and heat treated. After heat treatment and exposition to high temperatures samples underwent microstructural and chemical analyses, hardness and tensile tests. The collected data led to the optimization of both casting parameters, for obtaining a homogeneous Mo distribution in the alloy, and heat treatment parameters, allowing the formation of Mo based strengthening precipitates stable at high temperature. Microstructural and chemical analyses highlighted how Mo addition in percentage superior to 0.1% wt. can modify the silicon eutectic morphology and hinder the formation of iron based β intermetallics. High temperature exposure curves, instead, showed that after long exposition hardness is slightly influenced by heat treatment while the effect of Mo addition superior to 0,3% is negligible. Tensile tests confirmed that the addition of 0.3%wt Mo induces an increase of about 10% of ultimate tensile strength after high temperature exposition (250°C for 100h) while heat treatments have slight influence on mechanical behaviour. These results could be exploited for developing innovative heat treatment sequence able to reduce residual stresses in castings produced with A354 modified with Mo.

ABCA4 and ROM1: Implications for modification of the PRPH2-associated macular dystrophy phenotype

To identify the causative mutation leading to autosomal dominant macular dystrophy, cone dystrophy, and cone-rod dystrophy in a five-generation family and to explain the high intrafamilial phenotypic variation by identifying possible modifier genes.

Treatment modification in human immunodeficiency virus-infected individuals starting combination antiretroviral therapy between 2005 and 2008

Adverse effects of combination antiretroviral therapy (CART) commonly result in treatment modification and poor adherence.

Impact of acquired enamel pellicle modification on initial dental erosion

The acquired enamel pellicle that forms on the tooth surface serves as a natural protective barrier against dental erosion. Numerous proteins composing the pellicle serve different functions within this thin layer. Our study examined the effect of incorporated mucin and casein on the erosion-inhibiting potential of the acquired enamel pellicle. Cyclic acidic conditions were applied to mimic the erosive environment present at the human enamel interface during the consumption of soft drinks. One hundred enamel specimens were prepared for microhardness tests and distributed randomly into 5 groups (n = 20) that received the following treatment: deionized water, humidity chamber, mucin, casein, or a combination of mucin and casein. Each group was exposed to 3 cycles of a 2-hour incubation in human saliva, followed by a 2-hour treatment in the testing solution and a 1-min exposure to citric acid. The microhardness analysis demonstrated that the mixture of casein and mucin significantly improved the erosion-inhibiting properties of the human pellicle layer. The addition of individual proteins did not statistically impact the function of the pellicle. These data suggest that protein-protein interactions may play an important role in the effectiveness of the pellicle to prevent erosion.

Improving gene silencing of siRNAs via tricyclo-DNA modification

;Small interfering RNAs (siRNAs) can be exploited for the selective silencing of disease-related genes via the RNA interference (RNAi) machinery and therefore raise hope for future therapeutic applications. Especially chemically modified siRNAs are of interest as they are expected to convert lead siRNA sequences into effective drugs. To study the potential of tricyclo-DNA (tc-DNA) in this context we systematically incorporated tc-DNA units at various positions in a siRNA duplex targeted to the EGFP gene that was expressed in HeLa cells. Silencing activity was measured by FACS, mRNA levels were determined by RT-PCR and the biostability of the modifed siRNAs was determined in human serum. We found that modifications in the 3'-overhangs in both the sense and antisense strands were compatible with the RNAi machinery leading to similar activities compared to wild type (wt) siRNA. Additional modifications at the 3'-end, the 5'- end and in the center of the sense (passenger) strand were also well tolerated and did not compromise activity. Extensive modifications of the 3'- and the 5'-end in the antisense (guide) strand, however, abolished RNAi activity. Interestingly, modifications in the center of the duplex on both strands, corresponding to the position of the cleavage site by AGO2, increased efficacy relative to wt by a factor of 4 at the lowest concentrations (2 nM) investigated. In all cases, reduction of EGFP fluorescence was accompanied with a reduction of the EGFP mRNA level. Serum stability analysis further showed that 3'-overhang modifications only moderately increased stability while more extensive substitution by tc-DNA residues significantly enhanced biostability.

Structural modification of DNA--a therapeutic option in SLE?

Systemic lupus erythematosus (SLE) is an autoimmune disease that affects multiple organs, with glomerulonephritis representing a frequent and serious manifestation. SLE is characterized by the presence of various autoantibodies, including anti-DNA antibodies that occur in approximately 70% of patients with SLE and which contribute to disease pathogenesis. Consequently, immunosuppressive therapies are applied in the treatment of SLE to reduce autoantibody levels. However, increasing evidence suggests that DNA--especially double--stranded DNA-constitutes an important pathogenic factor that is able to activate inflammatory responses by itself in autoimmune diseases. Therefore, modifying the structure of DNA to reduce its pathogenicity might be a more targeted approach for the treatment of SLE than immunosuppression. This article presents information in support of this strategy, and discusses the potential methods of DNA structure manipulation--in light of data obtained from mouse models of SLE--including topoisomerase I inhibition, administration of DNase I, or modification of histones using heparin or histone deacetylase inhibitors.

Modification of the magnetic properties of a heterometallic wheel by inclusion of a Jahn-Teller distorted Cu(II) ion

An investigation into the physical consequences of including a Jahn-Teller distorted Cu(II) ion within an antiferromagnetically coupled ring, [R(2)NH(2)][Cr(7)CuF(8)((O(2)C(t)Bu)(16))] is reported. Inelastic neutron scattering (INS) and electron paramagnetic resonance (EPR) spectroscopic data are simulated using a microscopic spin Hamiltonian, and show that the two Cr-Cu exchange interactions must be inequivalent. One Cr-Cu exchange is found to be antiferromagnetic and the other ferromagnetic. The geometry of the Jahn-Teller elongation is deduced from these results, and shows that a Jahn-Teller elongation axis must lie in the plane of the Cr(7)Cu wheel; the elongation is not observed by X-ray crystallography, due to positional disorder of the Cu site within the wheel. An electronic structure calculation confirms the structural distortion of the Cu site.