Технология подготовки попутного газа для газлифтной эксплуатации скважин на нефтяном месторождении Пильтун-Астохское (Сахалинская область)

Целью выпускной работы является анализ влияния технологических параметров установки подготовки на качество газа для последующего применения в газлифтной эксплуатации нефтяных скважин. В процессе исследования изучены виды газлифтной эксплуатации, технологии подготовки нефтяного газа: компримирование газа, адсорбция, адсорбция и низкотемпературная сепарация. Обоснован выбор технологии низкотемпературной сепарации, построена моделирующая схема установки подготовки газа в программной среде UniSim Design Suite R460. Установлено влияние давления и температуры в изкотемпературном сепараторе на точки росы по углеводородам и воде подготовленного газа, а также на массовый расход конденсата.The aim of this graduation work is to analyze the influence of the technological parameters of the treatment unit on the quality of gas for subsequent use in gas-lift operation of oil wells. During the study the types of gas lift operation, associated gas treatment technologies (gas compression, adsorption, adsorption and low-temperature separation) were studied. The choice of low-temperature separation technology is justified, a simulating scheme of a gas treatment unit in the UniSim Design Suite R460 software environment is built. The effect of pressure and temperature in the low-temperature separator on the mass flow of condensate and the dew points of the prepared gas (hydrocarbon and water dew point) is established

Defending the genome from the enemy within:mechanisms of retrotransposon suppression in the mouse germline

The viability of any species requires that the genome is kept stable as it is transmitted from generation to generation by the germ cells. One of the challenges to transgenerational genome stability is the potential mutagenic activity of transposable genetic elements, particularly retrotransposons. There are many different types of retrotransposon in mammalian genomes, and these target different points in germline development to amplify and integrate into new genomic locations. Germ cells, and their pluripotent developmental precursors, have evolved a variety of genome defence mechanisms that suppress retrotransposon activity and maintain genome stability across the generations. Here, we review recent advances in understanding how retrotransposon activity is suppressed in the mammalian germline, how genes involved in germline genome defence mechanisms are regulated, and the consequences of mutating these genome defence genes for the developing germline

A Developmental Stage-Specific Switch from DAZL to BOLL Occurs during Fetal Oogenesis in Humans, but Not Mice

The Deleted in Azoospermia gene family encodes three germ cell-specific RNA-binding proteins (DAZ, DAZL and BOLL) that are essential for gametogenesis in diverse species. Targeted disruption of Boll in mice causes male-specific spermiogenic defects, but females are apparently fertile. Overexpression of human BOLL promotes the derivation of germ cell-like cells from genetically female (XX), but not male (XY) human ES cells however, suggesting a functional role for BOLL in regulating female gametogenesis in humans. Whether BOLL is expressed during oogenesis in mammals also remains unclear. We have therefore investigated the expression of BOLL during fetal oogenesis in humans and mice. We demonstrate that BOLL protein is expressed in the germ cells of the human fetal ovary, at a later developmental stage than, and almost mutually-exclusive to, the expression of DAZL. Strikingly, BOLL is downregulated, and DAZL re-expressed, as primordial follicles form, revealing BOLL expression to be restricted to a narrow window during fetal oogenesis. By quantifying the extent of co-expression of DAZL and BOLL with markers of meiosis, we show that this window likely corresponds to the later stages of meiotic prophase I. Finally, we demonstrate that Boll is also transiently expressed during oogenesis in the fetal mouse ovary, but is simultaneously co-expressed within the same germ cells as Dazl. These data reveal significant similarities and differences between the expression of BOLL homologues during oogenesis in humans and mice, and raise questions as to the validity of the Boll(-/-) mouse as a model for understanding BOLL function during human oogenesis

Nature of the spermatogenic arrest in Dazl -/- mice

Dazl encodes an RNA-binding protein essential for spermatogenesis. Mice that are deficient for Dazl are infertile, lacking any formation of spermatozoa, and the only germ cells present are spermatogonia and a few spermatocytes. To gain more insight regarding the timing of the spermatogenic arrest in Dazl -/- mice, we studied the spermatogonial cell types present in testis sections and in seminiferous tubular whole mounts. Most of the seminiferous tubular cross-sections contained A spermatogonia as the most advanced cell type, with only very few containing cells up to pachytene spermatocytes. Both 5-bromodeoxy-uridine incorporation and mitotic index indicated that the remaining A spermatogonia were actively proliferating. C-kit immunohistochemical studies showed that most of the A spermatogonia were positively stained for the c-Kit protein ( approximately 80%). The clonal composition of the A spermatogonia in tubular whole mounts indicated these cells to be A(single) (A(s)), A(paired) (A(pr)), and A(aligned) (A(al)) spermatogonia. It is concluded that the prime spermatogenic defect in the Dazl -/- mice is a failure of the great majority of the A(al) spermatogonia to differentiate into A(1) spermatogonia. As a result, most seminiferous tubules of Dazl -/- mice only contain actively proliferating A(s), A(pr), and A(al) spermatogonia, with cell production being equaled by apoptosis of these cell

Differential expression of c-kit in mouse undifferentiated and differentiating type A spermatogonia

The proto-oncogene c-kit is encoded at the white-spotting locus and in the mouse mutations at this locus affect the precursor cells of melanocytes, hematopoietic cells, and germ cells. c-kit is expressed in type A spermatogonia, but whether or not c-kit is present both in undifferentiated and differentiating type A spermatogonia or only in the latter cell type is still a matter of debate. Using the vitamin A-deficient mouse model, we studied messenger RNA (mRNA) and protein expression in undifferentiated and differentiating type A spermatogonia. Furthermore, we quantified the immuno-positive type A spermatogonia in the epithelial stages VI, VII, IX/X, and XII in normal mice to correlate c-kit expression in type A spermatogonia with the differentiation of these cells. Our results show that in the VAD situation undifferentiated type A spermatogonia express little c-kit mRNA. The A spermatogonia with a larger nucleus expressed c-Kit protein, whereas the A spermatogonia with a smaller one did not. After induction of differentiation of these cells into type A1 spermatogonia, c-kit mRNA was enhanced. The percentage of A spermatogonia expressing c-Kit protein did not change during this process, suggesting that A spermatogonia, which are committed to differentiate express c-kit. Under normal circumstances in epithelial stage VI 16%+/-2% (mean +/- SD), in VII 45%+/-15%, in IX/X 78%+/-14% and in XII 90%+/-1.9% of the type A spermatogonia were c-kit positive, suggesting that Aaligned spermatogonia gradually change from c-Kit negative to c-Kit positive cells before their differentiation into A1 spermatogonia. It is concluded that c-kit can be used as a marker for differentiation of undifferentiated into differentiating type A spermatogoni

The hot-spot p53R172H mutant promotes formation of giant spermatogonia triggered by DNA damage

10.1038/onc.2016.374Oncogene36142002-201