Magnussenshepard1205

This review discusses the characteristics, designing strategies, and recent progress in the development and application of antimicrobial CPPs as potent antibacterial agents against multidrug-resistant bacteria.Ultrasound is not only the most widely used medical imaging mode for diagnostics owing to its real-time, non-radiation, portable, and low-cost merits, but also a promising targeted drug/gene delivery technique by exhibiting a series of powerful bioeffects. The development of micron-sized or nanometer-sized ultrasound agents or delivery carriers further makes ultrasound a distinctive modality in accurate diagnosis and effective treatment. In this review, we introduce one kind of unique biogenic gas-filled protein nanostructures called gas vesicles, presenting some unique characteristics than the conventional microbubbles. Gas vesicles can not only serve as ultrasound contrast agents with innovative imaging methods such as cross-amplitude modulation harmonic imaging but also can further be adjusted and optimized via genetic engineering techniques. Moreover, they could not only serve as acoustic gene reporters, acoustic biosensors to monitor the cell metabolism, but also serve as cavitation nuclei and drug carriers for therapeutic purposes. In this study, we focus on the latest development and applications in the area of ultrasound imaging and targeted therapeutics, and also provide a brief introduction of the corresponding mechanisms. In summary, these biogenic gas vesicles show some advantages over conventional MBs that deserve more efforts to promote their development.

Endometrial cancer is the fourth most common malignancy in the female population worldwide. It was estimated that 65,620 new cases and 12,590 subsequent deaths occurred in 2020 in the United States. Patients with type II and advanced endometrial cancer do not respond well to the current treatments. Therefore, endometrial cancer should be better understood in order to develop more effective treatments.

To provide an overview of genetic, metabolic characteristics, therapeutic strategies and current application of nanotechnology surrounding endometrial cancer.

Relevant articles were retrieved from Pubmed and were systematically reviewed.

Hypoxia-inducible factor-1 and Von Hippel-Lindau factor participated in oncogenesis and progression of endometrial cancer, and Nrf2 was associated with oncogenesis. Various genetic alterations were found in endometrial cancer. The examination of the abnormal X chromosome inactivation may help with the diagnosis of endometrial cancer and its precancerous lesions. Some abs studied, but the current researches showed great results in treating endometrial cancer. It needs further researching.Langerin is a C-type Lectin expressed at the surface of Langerhans cells, which play a pivotal role in protecting organisms against pathogen infections. To address this aim, Langerin presents at least two recognition sites, one Ca2+-dependent and another one independent, capable of recognizing a variety of carbohydrate ligands. In contrast to other lectins, Langerin recognizes sulfated glycosaminoglycans (GAGs), a family of complex and heterogeneous polysaccharides present in the cell membrane and the extracellular matrix at the interphase generated in the trimeric form of Langerin but absent in the monomeric form. The complexity of these oligosaccharides has impeded the development of well-defined monodisperse structures to study these interaction processes. However, in the last few decades, an improvement of synthetic developments to achieve the preparation of carbohydrate multivalent systems mimicking the GAGs has been described. Despite all these contributions, very few examples are reported where the GAG multivalent structures are used to evaluate the interaction with Langerin. These molecules should pave the way to explore these GAG-Langerin interactions.Carbohydrates, either free or as glycans conjugated with other biomolecules, participate in many essential biological processes. Their apparent simplicity in terms of chemical functionality hides an extraordinary diversity and structural complexity. Deeply deciphering at the atomic level their structures is essential to understand their biological function and activities, but it is still a challenging task in need of complementary approaches and no generalized procedures are available to address the study of such complex, natural glycans. The versatility of Nuclear Magnetic Resonance spectroscopy (NMR) often makes it the preferred choice to study glycans and carbohydrates in solution media. The most basic NMR parameters, namely chemical shifts, coupling constants and nuclear Overhauser effects, allow defining short or repetitive chain sequences and characterize their structures and local geometries either in the free state or when interacting with other biomolecules, rendering additional information on the molecular recognition processes. The increased accessibility to carbohydrate molecules extensively or selectively labeled with 13C boosts the resolution and detail that analyzed glycan structures can reach. read more In turn, structural information derived from NMR, complemented with molecular modeling and theoretical calculations can also provide dynamic information on the conformational flexibility of carbohydrate structures. Furthermore, using partially oriented media or paramagnetic perturbations, it has been possible to introduce additional long-range observables rendering structural information on longer and branched glycan chains. In this review, we provide examples of these studies and an overview of the recent and most relevant NMR applications in the glycobiology field.Diabetic nephropathy (DN) is one of the most common complications of diabetes and the main cause of end-stage renal disease (ESRD). The inflammatory response plays a key role in the pathological process of DN. As the most deeply studied inflammasome, NLRP3 should not be overlooked in DN. Its abnormal activation accelerates DN progression. In this review, we summarize our understanding of the structural composition and activation factors of the NLRP3 inflammasome. Moreover, the relationship between NLRP3 inflammasome activation, and the potential of the NLRP3 inflammasome as a therapeutic target for DN will also be discussed.