Golgi requires a new casting in the screenplay of mucopolysaccharidosis II cytopathology

Lysosome (L), a hydrolytic compartment of the endo-lysosomal system (ELS), plays a central role in the metabolic regulation of eukaryotic cells. Furthermore, it has a central role in the cytopathology of several diseases, primarily in lysosomal storage diseases (LSDs). Mucopolysaccharidosis II (MPS II, Hunter disease) is a rare LSD caused by idunorate-2-sulphatase (IDS) enzyme deficiency. To provide a new platform for drug development and clarifying the background of the clinically observed cytopathology, we established a human in vitro model, which recapitulates all cellular hallmarks of the disease. Some of our results query the traditional concept by which the storage vacuoles originate from the endosomal system and suggest a new concept, in which endoplasmic reticulum-Golgi intermediate compartment (ERGIC) and RAB2/LAMP positive Golgi (G) vesicles play an initiative role in the vesicle formation. In this hypothesis, Golgi is not only an indirectly affected organelle but enforced to be the main support of vacuole formation. The purposes of this minireview are to give a simple guide for understanding the main relationships in ELS, to present the storage vacuoles and their relation to ELS compartments, to recommend an alternative model for vacuole formation, and to place the Golgi in spotlight of MPS II cytopathology.

The Dingo Barrier Fence: Presenting the case to decommission the world’s longest environmental barrier in the United Nations Decade of Ecosystem Reconstruction 2021–2030

The longest environmental barrier in the world is Australia's 5614 km Dingo Barrier Fence. The structure was completed in the 1950s, designed to facilitate the eradication of the country's apex predator and cultural keystone species the dingo (Canis dingo) from sheep (Ovis aries) grazing areas to the south-east of the continent. The fence and its support systems now present an immense obstacle to ecological restoration in Australia's arid zone, preventing traditional management practices, and are hazardous to all terrestrial wildlife in the immediate vicinity. The barrier presents a worst-case scenario for animal-generated seed dispersal patterns over the wider region and limits genetic transfer. Plummeting biodiversity inside the fence line and increasing pressures of climate change have left this region highly vulnerable to ecological collapse. Concurrently, sheep numbers have contracted over 75% in the arid zone since 1991, due to market forces and climate change, while demand for ethically produced goods such as predator-friendly meat production and organic produce is increasing. Decommissioning the Dingo Barrier Fence, moving the stock protection zone south and diversifying land use would not impact significantly on the current livestock production. It offers a sound economic alternative for the region, with the potential for regeneration of 82 million hectares of land, a scale encouraged for inclusion in the global initiative the United Nations Decade for Ecosystem Reconstruction (2021–2030). This would restore connectivity across the region, including vital access to the waters of the Murray Darling Basin. This would provide mitigation for the effects of climate change, new markets in organic and sustainable industries, and support ecological and cultural renewal.

Testing pigeon control efficiency by different methods in urban industrial areas, Hungary

The development of cities and urban sprawl has made room for wildlife inhabiting human environments. Among birds, feral pigeons (Columba livia domestica) are often present in large numbers in the cities. Problems related to pigeon occurrence result in economic loss and health issues for humans. There are different methods of controlling pigeon populations in urban areas. In this study, we compared three techniques that can be used for pigeon pest control. In two urban industrial sites in Hungary, we used trapping, falconry (in both Study Area 1 and 2) and mist-netting (only in Study Area 2) to remove pigeons. We compared the effectiveness and limitations of each method. Our results show that over 105 days in Study Area 1, we managed to remove 173 individual pigeons. We did not find a significant difference between the effectiveness of trapping or falconry. In Study Area 2, the overall number of pigeons removed was 1412 over a period of 150 days. There, we managed to catch significantly more birds by netting than by trapping or falconry, but the latter two did not differ statistically. We recommend a combination of techniques for pigeon control. Mist-netting can be the most effective way for direct pigeon removal, whereas trapping is an easier but less efficient method to catch pigeons. Falconry is the least efficient in pigeon catching and requires the most investments, but the bird of prey may chase the pigeons away for a short time.