Proteasome Inhibitor Immunotherapy for the Epithelial to Mesenchymal Transition: Assessing the A549 Lung Cancer Cell Microenvironment and the Role of M1, M2a and M2c ‘Hydrocortisone-Polarised’ Macrophages

Lung cancer is a leading cause of cancer-related deaths, primarily as a result of metastases. In this metastasis, the epithelial-to-mesenchymal transition (EMT) is essential. Interaction with the cancer cell microenvironment is primarily dependent on M1- and M2-polarized macrophage. In this study, we revealed the EMT-associated activity of M1, M2a and M2c macrophages in A549 lung cancer cells. We established a co-culture model of A549 lung cancer cells utilizing THP-1-derived M1/M2 polarised macrophages to explore the involvement of macrophages in the immune response, apoptosis, and EMT in lung cancer. Although multiple polarising agents are routinely used for M1 and M2 conversion, we assessed a new possible polarising agent, hydrocortisone. M1 increased A549 cell sensitivity to proteasome inhibitors and decreased A549 cell viability by inducing apoptosis. EMT was induced in the presence of M2c macrophages in A549 cells by the levels of vimentin, fibronectin, E-cadherin, NF-kB, CCL-17. We also revealed the antiproliferative effects of bortezomib and ixazomib on A549 cells in both 2D and 3D cultures. Our findings could help develop an immunotherapeutic strategy by shedding light on a previously undiscovered part of the EMT pathway. Furthermore, additional investigation may reveal that polarising tumour-associated macrophages to M1 and eliminating the M2a or particularly the M2c subtype are effective anti-cancer strategies.

Three-dimensional Cancer Cell Migration Directed by Dual Mechanochemical Guidance

Directed cell migration guided by external cues plays a central role in many physiological and pathophysiological processes. The microenvironment of cells often simultaneously contains various cues and the motility response of cells to multiplexed guidance is poorly understood. Here we combine experiments and mathematical models to study the three-dimensional migration of breast cancer cells in the presence of both contact guidance and a chemoattractant gradient. We find that the chemotaxis of cells is complicated by the presence of contact guidance as the microstructure of extracellular matrix (ECM) vary spatially. In the presence of dual guidance, the impact of ECM alignment is determined externally by the coherence of ECM fibers, and internally by cell mechanosensing Rho/Rock pathways. When contact guidance is parallel to the chemical gradient, coherent ECM fibers significantly increase the efficiency of chemotaxis. When contact guidance is perpendicular to the chemical gradient, cells exploit the ECM disorder to locate paths for chemotaxis. Our results underscores the importance of fully characterizing the cancer cell microenvironment in order to better understand invasion and metastasis.

Generation of Skin Organoids: Potential Opportunities and Challenges

Although several types of human skin substitutes are currently available, they usually do not include important skin appendages such as hair follicles and sweat glands, or various skin-related cells, such as dermal adipocytes and sensory neurons. This highlights the need to improve the in vitro human skin generation model for use as a tool for investigating skin diseases and as a source of cells or tissues for skin regeneration. Skin organoids are generated from stem cells and are expected to possess the complexity and function of natural skin. Here, we summarize the current literatures relating to the “niches” of the local skin stem cell microenvironment and the formation of skin organoids, and then discuss the opportunities and challenges associated with multifunctional skin organoids.

A blueprint of the topology and mechanics of the human ovary for next-generation bioengineering and diagnosis

Although the first dissection of the human ovary dates back to the 17th century, the biophysical characteristics of the ovarian cell microenvironment are still poorly understood. However, this information is vital to deciphering cellular processes such as proliferation, morphology and differentiation, as well as pathologies like tumor progression, as demonstrated in other biological tissues. Here, we provide the first readout of human ovarian fiber morphology, interstitial and perifollicular fiber orientation, pore geometry, topography and surface roughness, and elastic and viscoelastic properties. By determining differences between healthy prepubertal, reproductive-age, and menopausal ovarian tissue, we unravel and elucidate a unique biophysical phenotype of reproductive-age tissue, bridging biophysics and female fertility. While these data enable to design of more biomimetic scaffolds for the tissue-engineered ovary, our analysis pipeline is applicable for the characterization of other organs in physiological or pathological states to reveal their biophysical markers or design their bioinspired analogs.

CYTOTOXIC PROPERTIES OF NANOSTRUCTURES BASED ON ALUMINUM OXIDE AND HYDROXIDE PHASES IN RELATION TO TUMOR CELLS

Background. Currently, the use of nanoparticles and nanostructures as components of tumor therapy is the subject of numerous scientific articles. To change the parameters of cell microenvironment in presence of nanoparticles and nanostructures is a promising approach to reducing the tumor cell viability. Aluminum hydroxides and oxides have a number of advantages over other particles due to their porous surface, low toxicity, and thermal stability.The purpose of the study was to investigate the influence of the acid-base properties of aluminum hydroxide structures with different phase composition on the tumor cell viability (Hela, mda, pymt, a549, B16F10).Material and methods. Aln/al nanoparticles were used as a precursor for obtaining structures with various phase compositions. The anoparticles were produced by electric explosion of an aluminum wire in a nitrogen atmosphere. Such nanoparticles interact with water at 60 °Ϲ, resulting in formation of porous nanostructures. They are agglomerates of nanosheets with a planar size of up to 200 nm and a thickness of 5 nm. The phase composition of the structures was varied by the calcination temperature. A change in the phase composition of nanostructures led to a change in the acid-base properties of their surface. To estimate the number of acidic and basic centers on the surface of nanostructures, the adsorption of Hammett indicators was used. The amount of adsorbed dyes was determined spectrophotometrically.Results. It was found that the differences in the acid-base characteristics of the surface of the nanostructures led to a change in their antitumor activity. Γ-al2o3 had 6.5 times more basic centers than acidic ones, which determined its ability to exhibit more pronounced antacid properties, i.e. Longer to neutralize protons secreted by tumor cells. This sample had the highest antitumor activity against all tested cell lines.Conclusion. The antitumor activity of synthesized structures was found to be related not only to an increase in the ph of the cell microenvironment, but also to the ability to maintain the alkalinity of the microenvironment for a longer time due to the adsorption of protons released by tumor cells.

Regulation of Eukaryote Metabolism: An Abstract Model Explaining the Warburg/Crabtree Effect

Adaptation of metabolism is a response of many eukaryotic cells to nutrient heterogeneity in the cell microenvironment. One of these adaptations is the shift from respiratory to fermentative metabolism, also called the Warburg/Crabtree effect. It is a response to a very high nutrient increase in the cell microenvironment, even in the presence of oxygen. Understanding whether this metabolic transition can result from basic regulation signals between components of the central carbon metabolism are the the core question of this work. We use an extension of the René Thomas modeling framework for representing the regulations between the main catabolic and anabolic pathways of eukaryotic cells, and formal methods for confronting models with known biological properties in different microenvironments. The formal model of the regulation of eukaryote metabolism defined and validated here reveals the conditions under which this metabolic phenotype switch occurs. It clearly proves that currently known regulating signals within the main components of central carbon metabolism can be sufficient to bring out the Warburg/Crabtree effect. Moreover, this model offers a general perspective of the regulation of the central carbon metabolism that can be used to study other biological questions.