Regrowth resistance in cancer: why has it been largely ignored?

In drug-sensitive malignancies, treatment failure is a complex phenomenon resulting from both drug resistance and the rapid regrowth of malignant cells in between cycles of chemotherapy. This phenomenon has been referred to as regrowth resistance, and has been identified as a common impediment to the successful treatment of many neoplastic diseases. This phenomenon has received little attention in the past. The administration of maximally tolerated individual dosages of chemotherapeutic agents, combined with the use of biological response modifiers to slow the regrowth between courses of therapy, would be an effective approach to reduce the regrowth resistance. This also could reduce the emergence of drug resistant clones.     

Crystal structure of a tripeptide,L-alanyl-glycyl-glycine and its relevance to the poly(glycine)-II type of conformation

A tripeptide molecule, L -alanyl-glycyl-glycine, crystallizes in the form of a left-handed helix with (?,ψ) = ?83°, 170°. A pseudohexagonal packing arrangement and interchain hydrogen-bonded interactions are reminiscent of the model for the structure of poly(glycine)-II. Observations of certain intermolecular interactions appear to be relevant to the stereochemical assumptions incorporated in the models proposed for poly(glycine)-II and related polypeptides.     

Biosafety in DIY‐bio laboratories: from hype to policy: Discussions about regulating DIY biology tend to ignore the extent of self‐regulation and oversight of DIY laboratories

Policymakers should treat DIY‐biology laboratories as legitimate parts of the scientific enterprise and pay attention to the role of community norms. Subject Categories: Synthetic Biology & Biotechnology, S&S: Economics & Business, S&S: Ethics

DIY biology – very broadly construed as the practice of biological experiments outside of traditional research environments such as universities, research institutes or companies – has, during the past decade, gained much prominence. This increased attention has raised a number of questions about biosafety and biosecurity, both in the media and by policy makers who are concerned about safety and security lapses in “garage biology”. There are a number of challenges here though when it comes to policies to regulate DIY biology. For a start, the term itself escapes easy definition: synonyms or related terms abound, including garage biotechnology, bio‐hacking, self‐modification/grinding, citizen science, bio‐tinkering, bio‐punk, even transhumanism. Some accounts even use ‘DIY‐bio’ interchangeably with synthetic biology, even though these terms refer to different emerging trends in biology. Some of these terms are more charged than others but each carries its own connotations with regard to practice, norms and legality. As such, conversations about the risk, safety and regulation of DIY‐bio can be fraught.

Synonyms or related terms abound, including garage biotechnology, bio‐hacking, self‐modification/grinding, citizen science, bio‐tinkering, bio‐punk, even transhumanism.

Given the increasing policy discussions about DIY‐bio, it is crucial to consider prevailing practice thoughtfully, and accurately. Key questions that researchers, policy makers and the public need to contemplate include the following: “How do different DIY‐bio spaces exist within regulatory frameworks, and enact cultures of (bio)safety?”, “How are these influenced by norms and governance structures?”, “If something is unregulated, must it follow that it is unsafe?” and “What about the reverse: does regulatory oversight necessarily lead to safer practice?”.The DIY‐bio movement emerged from the convergence of two trends in science and technology. The first one is synthetic biology, which can broadly be defined as a conception of genetic engineering as systematic, modular and programmable. While engineering living organisms is obviously a complex endeavour, synthetic biology has sought to re‐frame it by treating genetic components as inherently modular pieces to be assembled, through rational design processes, into complex but predictable systems. This has prompted many “LEGO” metaphors and a widespread sense of democratisation, making genetic engineering accessible not only to trained geneticists, but also to anyone with an “engineering mindset”.The second, much older, trend stems from hacker‐ and makerspaces, which are – usually not‐for‐profit – community organisations that enable groups of enthusiasts to share expensive or technically complex infrastructure, such as 3D printers or woodworking tools, for their projects. These provide a model of community‐led initiatives based on the sharing of infrastructure, equipment and knowledge. Underpinning these two trends is an economic aspect. Many of the tools of synthetic biology – notably DNA sequencing and synthesis – have seen a dramatic drop in cost, and much of the necessary physical apparatus is available for purchase, often second‐hand, through auction sites.DIY‐bio labs are often set‐up under widely varying management schemes. While some present themselves as community outreach labs focusing on amateur users, others cater specifically to semi‐ or professional members with advanced degrees in the biosciences. Other such spaces act as incubators for biotech startups with an explicitly entrepreneurial culture. Membership agreements, IP arrangements, fees, access and the types of project that are encouraged in each of these spaces can have a profound effect on the science being done.     

Protection against X-ray radiation-induced cellular damage of human peripheral blood lymphocytes by an aminothiazole derivative of dendrodoine

The present study was aimed to evaluate the radioprotective efficacy of dendrodoine analog (DA), an aminothiazole derivative against X-ray radiation-induced cellular damage in cultured human peripheral blood lymphocytes. Different concentrations of DA (2, 4, 6, 8, 10 μg/ml or 6.15, 12.29, 18.44, 24.59, 30.73 μM) were pre-incubated with lymphocytes for 30 min prior to irradiation [4 Gy] and the micronuclei (MN) scoring and comet assay were performed to fix the effective concentration of DA against 4 Gy irradiation-induced cellular damage. The results indicated that among all the concentrations, 6 μg/ml concentration of DA showed optimum protection by effectively decreasing the MN frequencies and comet attributes. Based on the above results, 6 μg/ml concentration of DA was fixed as the effective dose to further investigate its radioprotective efficacy. This was carried out by pre-incubating the lymphocytes with 6 μg/ml concentration of DA followed by exposure of the lymphocytes to different doses (1, 2, 3 and 4 Gy) of radiation and investigating the radiation-induced genetic damage (MN, comet assay, DNA fragmentation assay) and biochemical changes (changes in the level of enzymic and non-enzymic antioxidants, lipid peroxidation). The results indicated a dose-dependent increase in both genetic damage and thiobarbituric acid reactive substances (TBARS), accompanied by a significant decrease in the antioxidant status in the irradiated groups compared to DA treated groups which modulated the toxic effects through its antioxidant potential. Thus the current study shows DA to be an effective radioprotector against X-ray radiation induced in vitro cellular damage in lymphocytes.     

MicroRNA-26a-mediated regulation of interleukin-2 expression in transformed avian lymphocyte lines

Background  

Micro(mi)RNAs are a class of small non-coding RNAs that play critical roles in the induction of various cancers, including lymphomas induced by oncogenic viruses. While some of the miRNAs are oncogenic, miRNAs such as miR-26a are consistently downregulated in a number of cancers, demonstrating their potential tumor suppressor functions. Global miRNA expression profiles of a number of virus-transformed avian lymphoma cell lines have shown downregulation of gga-miR-26a expression, irrespective of molecular mechanisms of transformation or the viral aetiology. The neoplastic transformation of lymphocytes by many viruses accompanies high levels of proliferative responses, mostly mediated through cytokines such as IL-2. Chicken IL-2 can modulate T-cell proliferation and cytotoxicity in vitro and in vivo and dysregulation of IL-2 expression is observed in diseases such as leukaemia.     

Role of chitin in the survival of Vibrio parahaemolyticus at different temperatures

Washed cells of Vibrio parahaemolyticus declined in numbers when incubated in phosphate-buffered saline for 6 h at different temperatures. Addition of chitin flakes to phosphate-buffered saline not only helped the organism to survive, but also resulted in an increase in cell numbers, particularly at 10 degrees C. The effect of chitin could not be simulated by N-acetylglucosamine, yeast extract, starch, or casein.