Czech White-Nose Syndrome Team together with international collaborators discovered mechanisms of tolerance that protect Palearctic bats from white-nose syndrome (WNS), the disease that caused mass die-off in North America. The discovery raises hope for a better future of bats in North American ecosystems. White-nose syndrome (WNS) is caused by a generalist pathogen Pseudogymnoascus destructans with the worst possible characteristics of an infectious fungal agent. The generalist nature of the WNS fungus means that it can infect any bat hibernating in a contaminated cave or mine and, moreover, it may remain viable and virulent, waiting for its hosts until the next hibernation period. Harmless to humans, the WNS fungus kills hibernating North American bats in winter. However, loss of voracious insectivorous bats from agricultural ecosystems may result in economic costs required for increased pest control. Without mass die-offs of bats harbouring the WNS agent in Europe, the response to disease is an enigma. To study the survival crossroads, the Czech WNS Team focused on the relationship between pathogen quantity and disease under natural conditions. High disease prevalence together with high fungal loads in absence of bat population declines in Eurasia indicates disease tolerance mechanisms, where hosts limit harm inflicted by the pathogen but do not hinder its growth. The tolerance mechanisms revealed by the Czech WNS Team is a function of bat adaptation to the presence of the pathogen. and Natália Martínková.
Jméno dostal teprve v roce 1986, takže tu s námi zdánlivě není dlouho. Nevzal se ale jen tak odnikud, na člověka se přenesl ze šímpanzů na přelomu 19. a 20. století. HIV řadíme mezi lentiviry, které jsou - v širším slova smyslu - mnohem starší. V roce 2008 odvodil tým ze Stanfordovy univerzity stáří jejich předchůdců na 14 milionů let. Experti z Ústavu molekulární genetiky AV ČR je však nejnovějším výzkumem datují ještě mnohem hlouběji do minulosti. Mohl být vzdálený předchůdce viru HIV současníkem dinosaurů? Nebo je dokonce napadat? and Viktor Černoch.
Teploty vzduchu okolo 100 °C, erupce sopek, blesky, dopady masivních asteroidů, silné ultrafialové zářeni. Jak v takovém pekle na Zemi před čtyřmi miliardam ilet mohl vzniknou život? Otazek je více než odpovědí a pátrání po původu živoat zůstává dobrodružnou disciplínou, v níž spolu soupeří zastánci různých teorii. and Luděk Svoboda, Stanislava Kyselová.
V odborných publikacích začínajících vědeckých pracovníků se někdy objevují logické chyby v metodice a následně i v interpretaci závěrů. Článek přináší dva takové příklady z výzkumné práce autorů. První příklad se týká logických chyb při srovnávání délky vývoje při konstantních a střídavých teplotách. Puparia pestřenek byla chována při velmi rozdílných teplotách, aby změny ve zbarvení dospělců byly velmi zřetelné. Nepřesně pochopený průměr teplotních hodnot může vést ke zkreslení výsledků Druhý příklad upozorňuje na nesprávný způsob odečítání tak zvané přirozené mortality v pokusech, při nichž se sleduje spotřeba mšic predátory., Two examples of potential logical errors in research methodologies and, consequently also in the interpretation of the results are presented. Firstly, an error can be made in the comparison of the length of development at constant and alternating temperatures. Puparia of hoverflies (Syrphidae) were reared at different temperatures in order to accentuate the colour differences between adults. The poorly understood influence of average temperature values on the development can lead to bias in the results. Secondly, the so-called natural mortality has often been assessed incorrectly in the trials in which consumption of aphids by predators is monitored., and Vítězslav Bičík, Pavel Láska.
The Algatech Centre, which is a scientific division of the Institute of Microbiology of the CAS located in the Opatovický mlýn (mill) near Třeboň in South Bohemia, focuses on the research of photosynthetic microorganisms, including algae, cyanobacteria and photosynthetic bacteria. The Laboratory of algal biotechnology studies processes and technology involved in the efficient production of algae and the use of algal biomass. It seeks new bio-active compounds in algae to be used as dietary supplements, in pharmacology and biomedicine. Scientists also carry our research into various metabolites of cyanobacteria and their effects on human cells. Special interest is paid to substances inhibiting the division of cancer cells and/or selectively inducing their apoptosis. The Laboratory of anoxygenic phototrophs is engaged in the basic research of evolutionary very old prokaryotes containing photosynthetic reaction centres composed of bacteriochlorophyll and its researchers have recently discovered an entirely new photosynthetic species - a new family of phototrophic bacteria, i.e. bacteria capable of producing energy through photosynthesis. Only three new families of phototrophic bacteria were discovered over the past 100 years.The Laboratory of cell cycles of algae aims at gaining a deeper insight into molecular mechanisms regulating the specific cells cycle in green algae hat divide by multiple fission - that is divide into more than two daughter cells. Scientists´ objective is to leam more about the regulation of cell size and division, the activity of cyclin dependant kinase and cyclin dependant kinase complexes throughout the normal cell cycle as well as their role in the cell cycle interruption in case of DNA damage. The pattern of cell cycle progression in algae can also tell us more about animal embryos, since the early phases of their growth and development are controlled by similar principles as those in green algae., The Laboratory of photosynthesis studies fundamental biochemical and molecular mechanisms regarding photosynthesis, the ways of its regulation during the day or under specific stress conditions. Special attention is paid particularly to photosystem II and researchers in the laboratory have recently made a significant step towards understanding its biogenesis. Photosystem II is a complicated protein complex present in the cells of plants, algae and cyanobacteria, the proper functioning of which is essential for photosynthesis. Research teams from the Algatech centre, together with colleagues from British universities have described the first phases of photosystem II synthesis, namely the mechanism by which chlorophyll molecules are inserted into core proteins of photosystem IIand how the functional core of this complex is assembled. Moreover, they have recently presented a substantially new view of repair mechanisms of photosystem II and the ways of recognition of its damaged protein subunits that have to be degraded and replaced. Deepening the understanding of fundamental processes in algae, cyanobacteria and photosynthetic bacteria can help use their potential in many practical applications, from biomass and biofuels to medicine., and Jana Olivová.
This paper presents biological notes on two species of Orthoptera: Tettigoniidae that emerged from old spongy-woody galls of Dryocosmus kuriphilus Yasumatsu, 1951 collected in Sicily (Italy) in April 2015: Leptophyes sicula Kleukers, Odé et Fontana, 2010 (Phaneropterinae) and Cyrtaspis scutata (Charpentier, 1825) (Meconematinae). Between the end of April and the first few days of May a total of 30 neanids emerged from the galls, were reared and their life-cycle recorded. While L. sicula laid eggs in groups, C. scutata laid single eggs inside the galls; both species in a few years have adapted to exploiting this new shelter for egg laying. No interaction with the gall inducing insect was noted., Giuliano Cerasa, Bruno Massa., and Obsahuje bibliografii
Ještě nedávno se tuková tkáň považovala za pouhou zásobarnu energie a symbol nežádoucí obezity, která má značný podíl na tzv. civilizačních chorobách. Stále víc vědeckých poznatků však začalo podobně jednostranný pohled nabouravat a ukazovat, že tuková tkáň není zbytečné zlo, ale má mnoho důležitých funkcí, bez nichž by se naše tělo neobešlo. and Jana Olivová, Stanislava Kyselová.