Aromatic Sulfonamides including a Sulfonic Acid Tail: New Membrane Impermeant Carbonic Anhydrase Inhibitors for Targeting Selectively the Cancer-Associated Isoforms.

We report here a new drug design strategy for producing membrane-impermeant carbonic anhydrase (CA; EC 4.2.1.1) inhibitors selectively targeting the tumor-associated, membrane-bound human CAs IX and XII over off-target cytosolic isoforms. To date, this approach has only been pursued by including permanent positively charged pyridinium type or highly hydrophilic glycosidic moieties into the structure of aromatic sulfonamide CA inhibitors (CAIs). Aliphatic (propyl and butyl) sulfonic acid tails, deprotonated at physiological pH, were thus incorporated onto a benzenesulfonamide scaffold by a common 1,2,3-triazole linker and different types of spacers. Twenty such derivatives were synthesized and tested for their inhibition of target (hCAs IV, IX, and XII) and off-target CAs (hCAs I and II). Most sulfonate CAIs induced a potent inhibition of hCAs II, IX, and XII up to a low nanomolar KI range (0.9-459.4 nM) with a limited target/off-target CA selectivity of action. According to the drug design schedule, a subset of representative derivatives was assessed for their cell membrane permeability using Caco-2 cells and a developed FIA-MS/MS method. The complete membrane impermeability of the sulfonate tailed CAIs (≥98%) validated these negatively charged moieties as being suitable for achieving, in vivo, the selective targeting of the tumor-associated CAs over off-target ones.

Overcoming Barriers for siRNA Therapeutics: From Bench to Bedside.

The RNA interference (RNAi) pathway possesses immense potential in silencing any gene in human cells. Small interfering RNA (siRNA) can efficiently trigger RNAi silencing of specific genes. FDA Approval of siRNA therapeutics in recent years garnered a new hope in siRNA therapeutics. However, their therapeutic use is limited by several challenges. siRNAs, being negatively charged, are membrane-impermeable and highly unstable in the systemic circulation. In this review, we have comprehensively discussed the extracellular barriers, including enzymatic degradation of siRNAs by serum endonucleases and RNAases, rapid renal clearance, membrane impermeability, and activation of the immune system. Besides, we have thoroughly described the intracellular barriers such as endosomal trap and off-target effects of siRNAs. Moreover, we have reported most of the strategies and techniques in overcoming these barriers, followed by critical comments in translating these molecules from bench to bedside.

Molecular mechanisms of membrane impermeability in clinical isolates of Enterobacteriaceae exposed to imipenem selective pressure.

Intrinsic mechanisms leading to carbapenem-induced membrane impermeability and multidrug resistance are poorly understood in clinical isolates of Enterobacteriaceae. In this study, molecular behaviours during the establishment of membrane impermeability in members of the Enterobacteriaceae family under imipenem selective pressure were investigated. Clinical isolates (n = 22) exhibiting susceptibility to multiple antibiotics or characterised as extended-spectrum ß-lactamase (ESBL)- or AmpC-producers were submitted to progressive passages on Mueller-Hinton agar plates containing subclinical concentrations of imipenem [0.5 × the minimum inhibitory concentration (MIC)]. Changes in outer membrane permeability were evaluated by determination of antimicrobial MICs, sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE), and gene expression analysis related to membrane permeability (i.e. omp35-like, omp36-like and acrA) and regulatory mechanisms (i.e. marA and ompR) by quantitative reverse transcription PCR. Following imipenem induction, 73% of isolates showed increased carbapenem MICs by ≥2 doubling dilutions. At an early stage of treatment, imipenem modulated the expression of porins and efflux pump genes, represented by a reduction of 78% in omp36-like and a two-fold increase in acrA expression. Transcriptional factors marA and ompR were also affected by imipenem induction, increasing mRNA expression by 14- and 4-fold, respectively. High marA expression levels were associated with higher values of acrA expression. These results suggest that imipenem is an important factor in the development of an adaptive response to carbapenems by regulating key genes involved in the control of efflux pumps and porins, which could lead to a multidrug-resistant profile in clinical isolates, contributing to possible treatment failure.

Análise molecular da expressão do fenótipo multi-droga resistente (MDR) em enterobactérias isoladas de amostras clínicas após exposição in vitro ao Imipenem / Molecular analysis of multi-drug resistant phenotype expression (MDR) in enterobacteria isolated from clinical specimens after exposure in vitro to imipenem

Após o surgimento e disseminação das ß-lactamases de amplo espectro em membros da família Enterobacteriaceae, os antibióticos carbapenêmicos (imipenem, meropenemeertapenem) têm sido considerados a terapia de escolha devido à estabilidade apresentada contra estas enzimas. A desvantagem destes antibióticos é a sua capacidade de induzir resistência aos ß-lactâmicos e a outros antibióticos quimicamente não relacionados. O imipenem tem favorecido a indução de cefalosporinases cromossômicas (AmpC) e também tem sido relacionado, in vivo, com a seleção de mecanismos intrínsecos de resistência, contribuindo com o perfil multi -droga resistente (MDR). Esse perfil é freqüentemente associado à diminuição da permeabilidade por alteração na síntese de porinas em conjunto com um aumento da atividade de bombas de efluxo, as quais não permitem o estabelecimento de uma concentração ativa do antibiótico no interior da célula bacteriana. O presente trabalho teve como objetivo avaliar o estabelecimento do perfil MDR em enterobactérias provenientes de isolados clínicos em função da exposição a diferentes concentrações de imipenemin vitro. A seleção do grupo das amostras estudadas foi feito por meio da determinação do perfil de sensibilidade dos isolados, tipagem molecular e ensaio de hidrólise de Imipenem. Nos isolados selecionados para a indução foi realizada numa etapa inicial (etapa basal) a análise de porinas de membrana externa por SDS-PAGE e o estudo de genes codificadores de ß-lactamases pela técnica de PCR. O estudo do estabelecimento do perfil MDR foi feito por meio de passagens sucessivas das amostras em meio contendo concentrações sub-inibitórias de imipenem seguido de análise fenotípica (CIM e acúmulo do antibiótico intracelular e SDS-PAGE), e a análise da expressão gênica de genes associados a permeabilidade de membrana (ompC, ompF eAcrA) e genes reguladores(marA e ompR). Após a indução com o imipenem, 77% dos isolados induzidos aumentaram a CIM para os carbapenêmicos, mudando assim o perfil de resistência observado na etapa basal Também foi afetado o perfil de resistência para outros antibióticos não relacionados a ß-lactámicos, porém numa percentagem menor. Com relação à alteração da permeabilidade, a perda de porina foi observada apenas para um isolado, no entanto a diminuição na expressão gênica de Omp36 foi significativa desde o começo da indução. A expressão da bomba de efluxoAcrAB foi afetada pela indução com imipenem, aumentando significativamente a expressão de AcrA, enquanto os reguladores estudados, MarA e OmpR tiveram a sua expressão induzida pelo imipenem. Foi possível observar também associação do nível de expressão gênica do regulador MarA com a expressão de AcrA,porém não foi possível observar uma associação estatisticamente significativa deste regulador com o perfil de expressão de OMPs. A indução de OmpR foi associado com um aumento da expressão de RNAm de Omp35, já para Omp36 foi possível observar apenas uma tendência na repressão deste gene. O estudo da resposta destes genes reguladores e determinantes de resistência, em resposta à exposição ao com o imipenem in vitro, permitiu reportar o comportamento molecular da bactéria numa resposta adaptativa no estagio inicial do estabelecimento do fenótipo MDR. A utilização de isolados clínicos com diversos determinantes de resistência permitiu observar a variabilidade nas respostas adaptativas das enterobacterias, o que é fundamental para a compreensão dos mecanismos de adaptação da bactéria e sua contribuição na falha terapêutica

After emergence and broad dissemination of extended spectrum ß-lactamases into the Enterobacteriaceae family, the carbapenemic antibiotics (imipenem, meropenem and ertapenem) have been considered the chosen therapy in the treatment of nosocomial infections by the stability that these antibiotics show to these enzymes. The disadvantage of carbapenems is theirs capacity to induce resistance against ß-lactamics and to other chemically unrelated antibiotics. The imipenem has been shown to induce chromosomal cephalosporinases (AmpC) and it was also related, in vivo, with the selection of intrinsic mechanism leading to multi-drug resistance profile (MDR). This profile is usually associated with membrane impermeability due to reduced outer membrane porin synthesis with an incremented activity of efflux pumps, which results in a reduced concentration of antibiotics inside the bacteria. This study aimed to evaluate the establishment of the MDR profile in Enterobacteriaceae from clinical isolates by exposure to different concentrations of imipenem in vitro. The selection of the study group was performed by determination of antibiotic susceptibility profile,molecular typing and hydrolysis assay of imipenem. In the selected isolates submitted to induction, in an initial step (baseline), was performed the outer membrane porin analysis by SDS-PAGE and the gene-specific amplification of B-lactamase enzymes by PCR. The study of the establishment of MDR was performed by progressive passages with subclinical concentrations of imipenem, followed each one by the evaluation of phenotypic profile (MIC, accumulation antibiotic in celland SDS-PAGE) and gene expression analysisof genes related to membrane permeability (ompC, ompF and acrA) and regulatory genes(MarA and ompR). After induction with imipenem, 77 % of the isolates increased the MIC for the carbapenems, changing the resistance profile at the baseline. In a lesser percentage, the resistance profile to other ß-lactams-unrelated antibiotics was also affected. Loss of porin was observed only for an isolated, however a significantly decreased Omp36 mRNA expression was observed from the start of induction. The expression of the efflux pump AcrAB ,was also affected by the imipenem induction, significantly increasing the AcrA gene expression, whereas the studied regulatory genes,MarA and OmpR,were induced by the imipenem. It was also possible to observe an association between the expression of the regulator MarA and the expression of AcrA, nevertheless no association was observed between this regulator and OMPs . OmpR induction was associated with an increased Omp35mRNA expression, however only a trend for the repression of Omp36was observed. The study of the response of these regulatory genes and genetic determinants of resistance, in response to the imipenem exposure in vitro, allowed to report the molecular behavior of the bacteria in an adaptive response in the initial stage of the establishment of a MDR phenotype. The use of clinical isolates with diverse resistance determinants allowed observing the variability in adaptive responses in enterobacteria, which is important to understand the adaptive mechanisms of bacteria to this antibiotic, the involvement in the emergence of the MDR profile and its contribution to the treatment failure