大麦G－带变动性以及与染色粒的一致性分析

以大麦为材料,进行了Ｇ－带带纹变动性分析以及Ｇ－带与减数分裂粗线期染色粒的比较。有丝分裂早中期至中期两个不同时期Ｇ－带带纹总数减少３６％,染色体组的绝对长度缩短２５％,带数减少的幅度大于染色体长度缩短的幅度。染色体组中每条染色体之间带纹减少的比例不尽相同,变幅在０．２９－０．５０之间。不同染色体绝对长度减少的幅度在０．２７－３．７０μ之间。从早中期至中期,每单位染色体绝对长度带数具相对减少的趋势。选择第６染色体进行的比较显示,减数分裂的染色粒与有丝分裂的Ｇ－带带纹之间具有很好的对应关系,Ｇ－带带纹和染色粒间的数目、位置和着色程度上都具一致性。对Ｇ－带性质和植物中Ｇ－带的应用等问题进行了讨论。     

脏器微血管对荧光素钠通透性的实验方法

大鼠颈动脉注射１％ＦｌＮａ,荧光显微镜下活体观察肠系膜微血管血流状态及ＦｌＮａ的渗出情况,并在不同时间点经股动脉采血,测定血浆内ＦｌＮａ浓度随时间的变化,利用组织匀浆测定不同脏器中ＦｌＮａ的分布,再辅以冰冻切片进行观察。活体观察发现,ＦｌＮａ注入体内后,经微血管迅速向周围组织渗出,最后汇集于淋巴管,血浆及组织匀浆ＦｌＮａ浓度的测定表明,ＦｌＮａ浓度随时间的变化呈指数衰减,各脏器ＦｌＮａ的分布极不相同。冰冻切片也显示了同样的分布差别。这些结果表明,我们所建立的方法可直观、定量地反映ＦｌＮａ在微血管的通透情况。     

贺兰山不同生境旱生灌木的解剖学研究

贺兰山荒漠地带三种不同基质生境的２０种旱生灌木的营养器官的比较解剖学研究表明：其共同特点是叶片的表面积／体积的比值小,叶表具厚的角质层、表皮毛,气孔下陷、并具孔下室,叶向中栅栏组织发达;轴器官中木栓层细胞层数多,皮层较厚,机械组织发达,木薄壁组织及髓部细胞的细胞壁术化加厚,根内都具周皮、木质部的导管分子大小不一、频率较高。此外,根、茎、叶中普遍存在粘液细胞和草酸钙结晶,部分植物的根和茎内有异常维管组织。这些结构特征都与早生环境相关,而不同基质生境中生长的植物尚存在一定差异。     

一类三维非线性系统空间周期解的存在性及唯一性

本文研究了一类描述天然林内红松林种群变化的三维非线性教学模型     

一类一级饱和反应系统的极限环

本文对一类一级饱和反应系统进行定性分析,得到（1）存在一个唯一环和存在两个（内不稳外稳）环的条件。     

植酸对稻米品质影响的研究（Ⅰ）

本文报道在水稻生长的抽穗期、齐穗期、灌浆期和蜡熟期喷施不同浓度植酸改良稻米品质的研究。结果表明,在水稻生长的不同阶段,控制喷施植酸浓度可提高糙米率,降低稻米垩白。     

人重组GM－CSF／HAS－D3嵌合蛋白（GM－HSA）在大肠杆菌中的表达及其产物稳定性的研究

将人粒细胞－巨噬细胞集落刺激因子（ＧＭ－ＣＳＦ）和人血清白蛋白第三功能区（ＨＡＳ－Ｄ３）的基因串联后,在Ｅ．ｃｏｌｉ中获高效表达,表达量占菌体蛋白的３２．６％．利用ＴＦ－１体外细胞活性测定表明,ＧＭ－ＨＳＡ的活性单位为１．０４×１０~６Ｕ／ｍｇ,虽然其比活性低于ＧＭ－ＣＳＦ,但比后者具有更高的体外热稳定性和储藏稳定性．     

人胸腺素α原cDNA的克隆及在大肠杆菌中的表达

采用基因工程方法制取人胸腺素α原获得成功。用２０ｕｇ／ｍｌ植物血球凝集素（ＰＨＡ）和５００Ｕ／ｍｌ重组人白细胞介素２（ＩＬ－２）联合刺激人胎儿胸腺细胞,从中提取总ＲＮＡ,经反转录ＰＣＲ获得了人胸腺素α原ｃＤＮＡ;将之克隆入ｐＵＣ１９中,序列测定表明与已报道序列一致,进一步将之亚克隆入原核表达载体ｐＢＶ２２０,转化大肠杆菌ＤＨ５ａ．观察到在不改变氨基酸编码的前提下,增加胸腺素ａ原上游引物中Ａ、Ｔ含量,可以明显提高胸腺素α原的表达量,同时,不同培养基对它的表达也有影响。胸腺素α原在大肠杆菌中以可溶形式表达,不需复性。初步活性测定显示,它可明显刺激人外周血淋巴细胞Ｅ－玫瑰花结形成率。重组人胸腺素α原在大肠杆菌中表达,为其临床应用及基础研究奠定了基础。     

Reduction of metabolic rate and thermoregulation during daily torpor

Physiological mechanisms causing reduction of metabolic rate during torpor in heterothermic endotherms are controversial. The original view that metabolic rate is reduced below the basal metabolic rate because the lowered body temperature reduces tissue metabolism has been challenged by a recent hypothesis which claims that metabolic rate during torpor is actively downregulated and is a function of the differential between body temperature and ambient temperature, rather than body temperature per se. In the present study, both the steady-state metabolic rate and body temperature of torpid stripe-faced dunnarts, Sminthopsis macroura (Dasyuridae: Marsupialia), showed two clearly different phases in response to change of air temperature. At air temperatures between 14 and 30°C, metabolic rate and body temperature decreased with air temperature, and metabolic rate showed an exponential relationship with body temperature (r ²=0.74). The Q ₁₀ for metabolic rate was between 2 and 3 over the body temperature range of 16 to 32°C. The difference between body temperature and air temperature over this temperature range did not change significantly, and the metabolic rate was not related to the difference between body temperature and air temperature (P=0.35). However, the apparent conductance decreased with air temperature. At air temperatures below 14°C, metabolic rate increased linearly with the decrease of air temperature (r ²=0.58) and body temperature was maintained above 16°C, largely independent of air temperature. Over this air temperature range, metabolic rate was positively correlated with the difference between body temperature and air temperature (r ²=0.61). Nevertheless, the Q ₁₀ for metabolic rate between normothermic and torpid thermoregulating animals at the same air temperature was also in the range of 2–3. These results suggest that over the air temperature range in which body temperature of S. macroura was not metabolically defended, metabolic rate during daily torpor was largely a function of body temperature. At air temperatures below 14°C, at which the torpid animals showed an increase of metabolic rate to regulate body temperature, the negative relationship between metabolic rate and air temperature was a function of the differential between body temperature and air temperature as during normothermia. However, even in thermoregulating animals, the reduction of metabolic rate from normothermia to torpor at a given air temperature can also be explained by temperature effects.Abbreviations BM body mass - BMR basal metabolic rate - C apparent conductance - MR metabolic rate - RMR resting metabolic rate - RQ respiratory quotient - T _a air temperature - T _b body temperature - T _lc lower critical temperature - T _tc critical air temperature during torpor - TMR metabolic rate during torpor - TNZ thermoneutral zone - T difference between body temperature and air temperature - VO₂ rate of oxygen consumption     

Processing of Procarboxypeptidase E into Carboxypeptidase E Occurs in Secretory Vesicles

Abstract: Carboxypeptidase E (CPE) functions in the posttranslational processing of bioactive peptides. Like other peptide processing enzymes, CPE is initially produced as a precursor ("proCPE") that undergoes posttranslational processing at a site containing five adjacent Arg residues near the N-terminus and at other sites near the C-terminus of proCPE. The time course of the N-terminal processing step suggests that this conversion occurs in either the Golgi apparatus or the secretory vesicles. To delineate further the site of proCPE processing, pulse/chase analysis was performed under conditions that block transit out of the Golgi apparatus (brefeldin A, carbonyl cyanide m -chlorophenylhydrazone, or 20°C) or that block acidification of vesicles (chloroquine, monensin, or ammonium chloride). The results of these analysis suggest that efficient proCPE processing requires an acidic post-Golgi compartment. To test whether known processing enzymes can perform this cleavage, purified proCPE was incubated with furin, prohormone convertase 1, or a dynorphin converting enzyme, and the products were analyzed on denaturing polyacrylamide gels. Furin cleaves proCPE within the N-terminal region, although the reaction is not very efficient, requiring relatively large amounts of furin or long incubation times. The other two peptide processing enzymes did not cleave proCPE, whereas a relatively small amount of secretory granule extract was able to convert proCPE into CPE. Taken together, these findings suggest that the conversion of proCPE into CPE occurs primarily in secretory vesicles.