pH Indication of Respiration and Effects of Different Carbohydrates and Escherichia coli on Respiration Rates in Caenorhabditis elegans

P. S. Patel, R. Grammer
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Abstract

tions with a visible light spectrophotometer (Parrish amd Grammer, 2012). However, the shift in the absorption spectrum of the dye upon acidification, the pK of the shift, had to exactly match the pH range of the acidification, necessitating changes in dyes employed depending upon which pH decreases were observed. Moreover, the absorption properties of any colored additives to be investigated and the light scattering properties of any potential food sources, such as bacterial suspensions, made it difficult to interpret the spectral properties of the observed mixture due to the use of spectrophotometry. Thus, the use of pH probes was alternatively investigated. Due to the intracellular oxidation of glucose, phenol red and spectrophotometry can detect color change. It was assumed that exogenous glucose would produce significant acidification of the medium by the worms. As the sugar is oxidized through respiration, carbon dioxide is produced, which causes the medium to acidify. Previous studies have investigated the respiratory processes and demonstrated the dependence of absorption of pH indicators on time and weak dependence of respiration rate on glucose concentration (Parrish & Grammer, 2012). This study developed procedures to further detect respiration in C. elegans by using Vernier pH probes (Vernier Software and Technology, Beaverton, OR) and tested the effects of E. coli and different carbohydrates (glucose, fructose, and maltose) on respiration rates. It was hypothesized that Vernier pH probes could be utilized to detect respiration and that E. coli and glucose would show the highest respiration rates, even if all carbohydrates were metabolized to some degree. The addition of E. coli should reveal increased respiration rates because it serves as the main food source for C. elegans. Glucose was also expected to reveal high INTRODUCTION Caenorhabditis elegans are 1 mm-long, non-parasitic nematodes that can be found in the soil. They are utilized as model organisms because they are transparent, easy to maintain, inexpensive, have a sequenced genome, and have a rapid life cycle (Corsi et al., 2015). Their primary food source is Escherichia coli, a gramnegative bacterium. C. elegans provide chemotaxis indices via chemotaxis assays; chemotaxis is the movement towards or away from an attractant or a repellent, respectively (Bargmann, 2006). A mitochondrial inhibitor, sodium azide, is utilized to stop the worms once they move to the test or control spots during chemotaxis assays. Sodium azide blocks cytochrome c oxidase and adenosine triphosphate (ATP) synthase, which causes the worms to die due to inhibition of the respiration processes (Massie et al., 2003). C. elegans can also move by swimming. During the swimming period, the nematodes carry out cellular respiration, which acidifies the medium. The acidification can be detected by phenol red, a pH indicator (Parrish & Grammer, 2012). Phenol red changes colors from red to yellow as the pH level of the solution decreases; hence, the pH becomes acidic. Previously, the color change was analyzed by examining the absorbance of the experimental solupH Indication of Respiration and Effects of Different Carbohydrates and Escherichia coli on Respiration Rates in Caenorhabditis elegans
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秀丽隐杆线虫呼吸pH指示及不同碳水化合物和大肠杆菌对呼吸速率的影响
用可见光分光光度计测定(Parrish amd Grammer,2012)。然而,酸化时染料吸收光谱的偏移,即偏移的pK,必须与酸化的pH范围精确匹配,这就需要根据观察到的pH降低来改变所使用的染料。此外,由于使用了分光光度法,要研究的任何有色添加剂的吸收特性和任何潜在食物来源(如细菌悬浮液)的光散射特性使得很难解释观察到的混合物的光谱特性。因此,对pH探针的使用进行了替代性研究。由于葡萄糖的细胞内氧化,酚红和分光光度法可以检测颜色变化。据推测,外源葡萄糖会使蠕虫对培养基产生显著的酸化作用。当糖通过呼吸被氧化时,就会产生二氧化碳,从而使培养基酸化。先前的研究已经调查了呼吸过程,并证明了pH指标的吸收对时间的依赖性,以及呼吸速率对葡萄糖浓度的弱依赖性(Parrish&Grammer,2012)。本研究开发了使用Vernier pH探针(Vernier Software and Technology,Beaverton,OR)进一步检测秀丽隐杆线虫呼吸的程序,并测试了大肠杆菌和不同碳水化合物(葡萄糖、果糖和麦芽糖)对呼吸速率的影响。据推测,Vernier pH探针可用于检测呼吸,即使所有碳水化合物都被代谢到一定程度,大肠杆菌和葡萄糖也会显示出最高的呼吸率。添加大肠杆菌应该会显示出呼吸速率的增加,因为它是秀丽隐杆线虫的主要食物来源。葡萄糖也有望揭示高简介秀丽隐杆线虫是一种1毫米长的非寄生线虫,可以在土壤中找到。它们被用作模式生物,因为它们透明、易于维护、价格低廉、基因组测序且生命周期快(Corsi等人,2015)。它们的主要食物来源是大肠杆菌,一种革兰氏阴性细菌。秀丽隐杆线虫通过趋化性测定提供趋化性指数;趋化性是分别朝向或远离引诱剂或排斥剂的运动(Bargmann,2006)。一种线粒体抑制剂叠氮化钠被用来阻止蠕虫在趋化性测定过程中移动到测试或对照点。叠氮化钠阻断细胞色素c氧化酶和三磷酸腺苷(ATP)合酶,这会导致蠕虫由于呼吸过程的抑制而死亡(Massie等人,2003)。秀丽隐杆线虫也可以通过游泳来移动。在游泳期间,线虫进行细胞呼吸,使培养基酸化。酸化可以通过pH指示剂酚红检测(Parrish&Grammer,2012)。随着溶液pH值的降低,酚红的颜色从红色变为黄色;因此pH变为酸性。以前,通过检查实验溶液的吸光度H呼吸指示以及不同碳水化合物和大肠杆菌对秀丽隐杆线虫呼吸率的影响来分析颜色变化
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