Principles and biotechnological applications of bacterial ice nucleation.

Certain aerobic, Gram-negative bacteria, including the epiphytic plant pathogen, Pseudomonas syringae, possess a membrane protein that enables them to nucleate crystallization in supercooled water. Currently, these ice-nucleating (IN) bacteria are being used in snow making and have potential applications in the production and texturing of frozen foods, and as a replacement of silver iodide in cloud seeding. A negative aspect of these IN bacteria is frost damage to plant surfaces. Thus, of the various types of biological ice nucleators, bacteria have been the subject of most research and also appear relevant to the anticipated practical uses. The intent of this review is to explain the identification and ecology of the ice-nucleating bacteria, as well as to discuss aspects of molecular biology related to ice nucleation and consider existing and potential applications of this unique phenomenon.     

Enhancing structural complexity: An experiment conducted in the Black Forest National Park,Germany

We report on a structural complexity enhancement (SCE) experiment that was designed to test ecological restoration measures in the Black Forest National Park, Germany. The main goal was to understand as to whether the creation of standing and downed deadwood within previously managed, single-layered Norway spruce (Picea abies L.) forests accelerates the development of forest structure, richness, and diversity of a range of taxonomic groups. Here we introduce the experimental design and describe the development of stand structure including abundance and richness of tree-related microhabitats (TreMs) within 5 years after initiation of the experiment in October 2016. To enhance structural complexity in treatment plots, 10 trees per plot were toppled using a skidder winch, and another 10 trees were ring barked at a height of around 60 cm above ground level with a chainsaw. To monitor stand structure, we collected data on common forest attributes such as diameter at breast height (DBH), tree height, and TreMs of all trees in the six experimental and six control plots measuring 0.25 ha in size before the treatments were carried out in 2016 and again in 2020/21. We analyzed the abundance and richness of TreMs using generalized linear mixed models with DBH and treatment vs. control as predictors. The SCE treatment resulted in a significant increase in deadwood volumes (4.2 vs. 439.5 m³) as well as in TreM abundance and richness (increase of 0.74 TreMs per tree). This indicates that the SCE treatment was effective to increase biodiversity-relevant structures such as deadwood and TreMs, in previously managed Norway spruce-dominated stands. The ongoing monitoring of a range of taxonomic groups (birds, bats, small mammals, coleoptera, fungi, mosses, and vascular plants) in this experiment will demonstrate to what extent the enhancement in structural complexity will lead to an enrichment in species richness and diversity.     

Production of xylanase by the thermophilic fungusThielavia terrestris

Summary The effect of varying fermentation pH and temperature on extracellular xylanase production by the thermophilic fungus,Thielavia terrestris (ATCC 26917), was studied using a stirred tank bioreactor. Maximum xylanase activity (18.8 I.U/mL) was obtained when the temperature was controlled at 48°C and the initial pH set at 4.0. Under these conditions, the volumetric productivity of xylanase was 1044 l. U./L. h. which is superior to that achieved by many mesophilic xylanolytic micro-organisms.     

Quantitative estimation of gibberellic acid by paper chromatography

Метод для количественного определения от gibberellic кислоты в процессе брожения средства массовой информации, с использованием бумаги по убыванию хроматографии в butylacetate воды описана. Образца корректируется, чтобы рН 2.5-3.0, добыто с н-бутанола, и 0,05 мл. органического слоя пятнами на Хроматографический бумагу. После equilibration от Атмосфера в банке, chromatogram Разработана в butylacetate насыщенных с водой, за 7 часов, и растворитель разрешено покинуть капельного нижней части листа. Обнаружение осуществляется путем опрыскивания с 3% раствор серной кислоты в метаноле и после сушки бумаги, пятна с синий u.v. флуоресценции наблюдается. Определенный артикль площадь пятна оценивается с помощью калибровочной кривой, заговор с ценностей, стандартов, соответствующих 20, 60 и 120 μ g. gibberellic кислоты. Погрешность оценки составляет ± 10-15% когда оценки выполняются тщательно. Низкий предел чувствительности 5 μg.     

Poly(glutamic acid) for biomedical applications.

Paclitaxel is a widely used anti-cancer agent. Conjugates of paclitaxel with poly(glutamic acid) have shown great promise in preclinical trials, and clinical trials are now underway. Preclinical data suggest that more paclitaxel is preferentially delivered to tumor sites vs. nonconjugated paclitaxel. When poly(glutamic acid) is conjugated to other families of cancer drugs, similar improvements in effectiveness and reduced toxicity are observed. Optimization of poly(glutamic acid) for use in drug delivery applications is a key step in making this technology viable.     

Ultrastructural features and formation of the micropylar apparatus in the cherry fly Rhagoletis cerasi

The micropylar apparatus (MA) in Rhagoletis cerasi (Diptera, Tephritidae) is located at the anterior pole of the egg and consists of two parts: an outer chorion and an inner vitelline membrane. Sperm entry takes place through the micropylar canal, 2.0–2.5 μm in diameter, which penetrates the micropylar endochorion and terminates in the thick vitelline membrane, thus forming the “pocket.” The pore of the micropylar canal, i.e., the micropyle, is covered by the exochorionic tuft. The formation of the MA is accomplished by 40 micropylar cells during oogenesis. These cells secrete the successive eggshell layers: the vitelline membrane, the wax layer, the innermost chorionic layer, the micropylar endochorion, and the exochorion. Two among 40 micropylar cells differentiate and form two tightly connected projections. The latter contain a bundle of parallel microtubules and participate in the formation of the micropylar canal and the pocket. At the tip of the projections there are two thin extensions full of microfilaments. In late developmental stages the two projections and the extensions degenerate and leave the canal and the pocket behind. We also discuss the structural features of the MA in relation to its physiology among Diptera.