氦氖激光对种公牛精子生物学效应的研究

本文采用氦氖激光辐射种公牛的精液,发现低剂量的氖氦激光可以提高精子的活力,存活时间和呼吸强度,降低精子的畸形率,并对其机理作了探讨。     

氦氖激光辐射绵羊精子顶体反应效应的研究

以不同剂量的氦氖激光辐射绵羊精液,发现低剂量的激光可以提高精子的活力,促进精子的顶体反应,改善精液的品质。     

CO2激光辐射奶山羊精液生物学效应的研究

本研究表明,３．５７Ｊ／ｃｍ＾２和７．４Ｊ／ｃｍ６２激光组可以改善精液品质,提高精子的代谢功能状态,以增强精子活力,认为是最佳剂量;１４．２８Ｊ／ｃｍ６２激光组虽然对精子的代谢,活力有效应,但不能维持,认为是临界剂量;２８．５６Ｊ／ｃｍ＾２激光对精子的损害作用,认为是抑制剂量。     

激光辐射公牛精液效应的研究

用不同剂量的激光辐射公牛的离体精液,发现低剂量的氦氖激光可以提高精子的活力、顶体完整率和顶体反应率,降低精液中的钙含量,表明激光能改善公牛的精液品质,可应用于养牛生产中。     

肌肽,棉酚对绵羊精子呼吸的影响

肌肽可刺激绵羊精子呼吸增强,尤以４ｍＭ／ｍｌ肌肽浓度效果最为显著,肌肽浓度继续增大,呼吸呈下降趋势,高浓度棉酚抑制绵羊精子呼吸,低浓度则刺激精子呼吸增强。加入２－ＤＯＧ（２－脱氧葡萄糖）后精子呼吸强度普遍提高,高浓度棉酚处理精子组织吸强度也有提高,但未精子活力得到改善。     

线粒体呼吸功能与精子活力、核DNA损伤的相关性分析

为探讨线粒体呼吸功能与精子活力、核DNA损伤程度之间的相关性,按WHO标准收集34例不同活力的精液标本,采用蔗糖差速离心法或密度梯度离心法提取精子线粒体,通过铂氧电极-溶氧仪测定线粒体呼吸耗氧率并计算状态III呼吸、状态IV呼吸、呼吸控制率（RCR）、磷氧比（P／0）及氧化磷酸化效率（0PR）;应用精子染色质扩散（sperm chromatin dispersion,SCD）实验检测精子DNA损伤情况。结果表明：不同活力精子线粒体状态Ⅲ呼吸耗氧量之间具有显著差异俨〈0．01）;弱精子症组RcR和OPR与正常对照组比较,分别降低了17．03％（P〈0．05）和40．74％（P〈0。01）;精子DNA损伤程度与精子活力、状态III呼吸及OPR均呈极显著负相关（r值分别是-0．812、-0．788和-0．696）。以上结果提示：精子线粒体呼吸耗氧和氧化磷酸化功能与精子活力之间存在着密切的联系;精子DNA（包括mtDNA）损伤可能影响精子的正常功能。     

激光辐照对绵羊精子代谢和体外获能的影响

本文采用He—Ne激光处理绵羊精液,通过测试精于超弱化学发光强度、TST染色,以了解精子代谢的变化,观察精子顶体反应的发生情况,进一步从受精学角度了解激光的辐照效应。     

激光对青蛙卵作用的生物效应

用He—Ne激光分别照射青蛙的卵子、精子和早期胚胎,在相同的激光剂量条件下,观察不同激光照射时间对胚胎发育的影响。通过电镜观察卵膜的超微结构,分析激光作用于细胞的刺激作用机制。     

CO2激光辐射提高蔬菜种子活力的研究

本文总结了ＣＯ２激光辐射提高蔬菜种子活力的研究成果，适量ＣＯ２激光辐射蔬菜种子可增强种子活力，提高幼苗素质，增加产量，促进早熟，加强生物机能，改善解剖结构，提出一些需要解决的问题和对其进行的初步研究。     

He-Ne激光对水分胁迫下小麦幼苗生理特性的影响

用He-Ne激光(5.23×10-3W.mm-2)处理经不同浓度PEG6000胁迫的小麦幼苗,研究水分胁迫条件下激光辐照对小麦幼苗生理特性的影响。结果表明,He-Ne激光辐照可显著提高水分胁迫下小麦幼苗的根系活力以及抗坏血酸过氧化物酶(APX)和谷胱甘肽还原酶(GR)活性(P<0.05),并使其脯氨酸含量显著增加(P<0.05),而对其超氧化物歧化酶(SOD)的活性没有显著影响。可见,He-Ne激光可通过提高根系活力、抗氧化酶活性和脯氨酸含量来显著增强小麦幼苗的抗旱性。     

The activating effects of bicarbonate on sperm motility and respiration at ejaculation

Mature porcine sperm preserved in the cauda epididymis are quiescent. At ejaculation, they are mixed with the seminal vesicle fluid containing HCO3- and are rapidly activated. The role of HCO3- on the sperm activation process at ejaculation was studied in vitro. HCO3- quickly increased the motility, respiration rate and cAMP content of the porcine epididymal sperm. The extent of activation was proportional to the pCO2 in the medium. The activating effect of HCO3- on the motility was observed even in the absence of fructose as well as in the presence of KCN. 8-Bromoadenosine 3',5'-cyclic monophosphate and theophylline showed similar activating effects to that of HCO3-. However, HCO3(-)-free seminal plasma, Ca2+, amino acids, intermediates of the Krebs cycle, substrates of respiration and increases in the intracellular pH, extracellular pH or ionic strength of the medium had no effect. Fructose sustained the active state of the sperm and gradually increased both the motility and respiration rate when the dose of HCO3- was low. The anion channel blocker enhanced the activating effect of HCO3-. These results suggest that, upon ejaculation, HCO3- is a unique activator in vivo which makes the quiescent sperm motile via the HCO3(-)-adenylate cyclase-cAMP system, to which an endogenous HCO3- derived from metabolic CO2 may be related.     

Exhaustive exercise, animal stress, and environmental hypercapnia on motility of sperm of steelhead trout (Oncorhynchus mykiss)

Motility of salmonid sperm is inhibited by the presence of carbon dioxide (CO2) in vitro; however, whether this occurs in response to challenges to the adult in vivo is not known. To determine whether CO2 negatively impacts sperm function in vivo, mature males were exposed to exhaustive exercise as well as to acute stress, chronic stress, tricaine anesthesia and environmental hypercapnia and sperm motility and semen CO2 tensions and pH values assessed. Semen CO2 rose and pH decreased significantly only in response to exhaustive exercise and environmental hypercapnia (13 kPa CO2). These changes in semen CO2 and pH were associated with reductions in numbers of sperm becoming motile upon water activation. Chronic and acute stress and tricaine anesthesia were without effect on sperm motility or on semen CO2 or pH. The time course of CO2 inhibition and recovery was evaluated in vitro. At least 50 min was required to note 50% of the inhibitory effect of low CO2 tensions on motility when sperm were exposed to 1.6-3.1 kPa CO2. At higher CO2 levels sperm motility displayed 50% of the inhibitory effect of these tensions within about 30 min. Sperm recovered maximal motility within 1 h of being placed in a nominally CO2-free environment. This study demonstrates sperm vulnerability to not only in vitro CO2 exposure but also in vivo exposure during exhaustive exercise and as result of environmental hypercapnia.     

The effect of the acrosome reaction on the respiratory activity and fertilizing capacity of echinoid sperm.

We have examined the relationship between the acrosome reaction, sperm respiration, and fertilization using gametes of the sea urchin Strongylocentrotus purpuratus. The results indicate that when sperm are exposed to jelly coat isolated from homologous eggs, the following sequence of events occurs: (1) Sperm undergo the acrosome reaction within 30 sec with little or no loss in their capacity to fertilize eggs; (2) by 60 sec there is a dramatic decrease in fertilizing capacity which stabilizes after 4 or 5 min at a greatly reduced level; (3) by 1.5 to 2 min a progressive decrease in the rate of mitochondrial respiration becomes detectable and continues for 8 to 10 min, finally stabilizing at a greatly reduced rate. This decrease in respiration rate is paralleled by a decline in sperm motility. The effects of jelly coat on the acrosome reaction, sperm respiration, and motility are species specific. From these results we conclude that sperm which have undergone the acrosome reaction retain full fertilizing capacity for a very short time. The rapid decline in fertilizing capacity is followed by a decrease in respiration rate and motility.     

Does CO2 enhance short-term storage success of Chinook salmon (Oncorhynchus tshawytscha) milt?

Successful short-term storage of salmonid milt depends on numerous factors, including temperature, fluid volume, and gaseous environment, with storage at low temperatures under an atmosphere of 100% O2 being the most common method. Salmonid sperm maintained in a storage environment with elevated carbon dioxide (CO2) levels, such as the approximately 4% CO2 in exhaled air, are not motile when activated. While these modest levels of CO2 inhibit sperm motility, the effect is reversible within hours after exposure to a CO2-free oxygenated environment. Therefore, the effect of CO2 (as a component gas in the storage environment) on chinook salmon (Oncorhynchus tshawytscha) sperm motility and viability was examined. The hypothesis of the current investigation was that CO2-exposure with subsequent CO2 removal would be beneficial during short-term chinook salmon milt storage. Milt samples were collected from mature (adult) and precocious (jack) male chinook salmon and stored under various CO2 and O2 levels at 3 to 4 degrees C for up to 14 days. Milt samples were then removed from the incubation environments and maintained under CO2-free humidified air with continuous mixing for 4 h at 10 degrees C before analysis of motility. The resultant motility of samples incubated under 3.5% or less CO2 was not different than controls during the 14 d incubation period; motility of samples stored under higher CO2 tensions were significantly lower. The motility of samples incubated under 3.5% CO2 reached the maximum recovered motility after 2 h exposure to CO2-free humidified air, while the motility of sperm incubated under 13.4% CO2 levels recovered no motility even after 6 h exposure to CO2-free humidified air. The motility of samples incubated under normoxia was significantly greater than that of samples incubated under hyperoxia (approximately 90% O2) at both 7 and 14 d, regardless of the CO2 level. Sperm viability was relatively unaltered by any of the incubation conditions examined. The results of this investigation suggest that there is no apparent advantage to storage of chinook salmon sperm in the presence of CO2 and that storage under hyperoxia negatively affects sperm function compared to storage under normoxia.     

A volatile inhibitor immobilizes sea urchin sperm in semen by depressing the intracellular pH

Sea urchin spermatozoa are normally immotile in semen, but motility can be initiated by increasing gas flow over the semen--for example, by blowing N2 gas over a thin layer of semen. This result indicates that sperm motility is not O2 limited and suggests that seminal fluid contains a volatile inhibitor of motility which is responsible for the paralysis of sperm in semen. This inhibitor might be carbon dioxide, which reversibly immobilizes sperm. 31P-NMR measurements of pH show that the sperm intracellular pH (pHi) increases by 0.36 pH unit upon dilution of semen into seawater. Since previous studies have shown that this magnitude of pH increase is sufficient to trigger sperm motility, we suggest that the volatile inhibitor is inhibiting sperm motility in semen by depressing the pHi. A simple hypothesis that explains these observations is that the volatile motility inhibitor is CO2, which could acidify pHi as a diffusable weak acid. In this regard, sperm diluted into seawater release acid, and this acid release is related to the pHi increase and motility initiation. In fact, nearly half of the acid released by sperm upon dilution is volatile and may therefore be due to CO2 efflux. Most of the acid, however, cannot be attributed to CO2 release because it is not volatile. Thus, when sperm are diluted into seawater, they raise their pHi by releasing CO2 and protons from the cytoplasm into the surrounding seawater.     

Glycolysis plays a major role for adenosine triphosphate supplementation in mouse sperm flagellar movement

The mammalian sperm must be highly motile for a long time to fertilize a egg. It has been supposed that ATP required for sperm flagellar movement depends predominantly on mitochondrial respiration. We assessed the contribution of mitochondrial respiration to mouse sperm motility. Mouse sperm maintained vigorous motility with high beat frequency in an appropriate solution including a substrate such as glucose. The active sperm contained a large amount of ATP. When carbonyl cyanide m-chlorophenylhydrazone (CCCP) was applied to suppress the oxidative phosphorylation in mitochondria, the vigorous motility was maintained and the amount of ATP was kept at the equivalent level to that without CCCP. When pyruvate or lactate was provided instead of glucose, both sperm motility and the amount of ATP were high. However, they were drastically decreased when oxidative phosphorylation was suppressed by addition of CCCP. We also found that sperm motility could not be maintained in the presence of respiratory substrates when glycolysis was suppressed. 2-Deoxy-d-glucose (DOG) had no effect on mitochondrial respiration assessed by a fluorescent probe, 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolylcarbocyanine iodide (JC-1), but, it inhibited motility and decreased ATP content when pyruvate or lactate were provided as substrates. The present results suggest that glycolysis has an unexpectedly important role in providing the ATP required for sperm motility throughout the length of the sperm flagellum.     

Production of nitric oxide by sperm of the steelhead (Oncorhynchus mykiss) and its actions on motility and respiration

The objective was to characterize nitric oxide (NO) involvement in steelhead sperm physiology with respect to modulation of motility and quiescent sperm respiration, and to assess NO production. Activation of sperm motility in the presence of a NO scavenger (PTIO) decreased path straightness (STR; from 62 to 44%, P < 0.05) and wobble (indicator of lateral head movement, WOB; from 68 to 61%, P < 0.05), whereas activating solution containing a NO donor (SNAP) increased STR (from 62 to 71%, P < 0.05). Neither SNAP nor PTIO impacted percent motility or velocity when present in activating media alone. Incubation of quiescent sperm with SNAP reduced motility (from 96 to 53%, P < 0.0001), curvilinear velocity (from 156 to 83 μm/s P < 0.0001), and WOB (from 77 to 50%, P < 0.0001); however, these effects were abolished by inclusion of PTIO. Response of quiescent sperm to SNAP was reversible with time, whereas PTIO alone had no effect. Incubation of sperm with SNAP decreased respiration to approximately one half of control (P < 0.05). With the fluorescent NO indicator, DAF-FM DA, intracellular NO was detected in quiescent, but not activated, sperm. Incubation of activated sperm in an immobilization buffer resulted in reappearance of NO. In addition to illustrating NO sensitivity of steelhead sperm motility, we inferred that the effects of NO on quiescent sperm occurred via inhibition of respiration, and that these sperm produced NO prior to activation.     

Modulation of mammalian sperm motility by quercetin

The flavonoid quercetin inhibits collective motility of ejaculated ram spermatozoa in the first 2 hr of incubation; during the next 3-4 hr motility is stimulated. To explain this interesting effect, we followed the influence of quercetin on sperm glycolysis, extracellular pH, ATP content, mitochondrial respiration, and lipid peroxidation. The collective motility of untreated cells is decreased to about 40% of the original motility during two hours of incubation. During this time, the rate of glycolysis is constant, respiration rate is increasing, there is no change in ATP content, the rate of lipid peroxidation is very slow, and the extracellular pH became very acidic (pH 5.5). It is concluded that motility is decreased due to this acidification. This acidification is prevented to some extent by quercetin, which indirectly inhibits glycolysis. Quercetin inhibits motility due to the inhibition of the plasma membrane calcium pump, as we showed previously (Breitbart et al., J Biol Chem 260:11548-11553, 1985). The motility of untreated cells is arrested after 3.5 hr of incubation, whereas quercetin-treated cells show high motility, which continues for additional 2-3 hr. After 3.5 hr, the control cells show no glycolytic activity, ATP content and respiration rates are decreased, and rate of lipid peroxidation is highly increased. At this time, quercetin-treated cells show no glycolytic activity, only a small decrease in ATP content and respiratory rate, and a very low rate of lipid peroxidation. Based on these data it is concluded that sperm motility after 3.5 hr of incubation is dependent mainly on mitochondrial respiration.(ABSTRACT TRUNCATED AT 250 WORDS)