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NOTE: The standard laboratory line Oregon R was used as a WT control. All flies were reared on standard cornmeal-molasses medium (containing molasses, agar, yeast, cornmeal, tegosept, propionic acid, and water) at room temperature with 12/12 h light/dark circadian rhythm.
1. Preparing for the assay
<ol>
	<li>Collect female flies (0-2 days old, non-virgin) under CO2&#160;anesthesia and allow them to recover on standard cornmeal food for at least 3 days before experiments.</li>
	<li>Starve the flies for ~24 h at room temperature (~23 &#176;C) in vials containing a laboratory wipe tissue soaked with ~2 mL of deionized water.</li>
	<li>Prepare the fly food with bromophenol blue (BPB) as follows:
	<ol>
		<li>Melt the fly food in a microwave and then let it cool until it is lukewarm.</li>
		<li>Add 1 mL of 4% BPB to 1 mL of lukewarm food and mix well.</li>
		<li>Using a pipet, add the fly food containing BPB into a single dot (~200 &#181;L) in the center of a Petri dish.</li>
	</ol>
	</li>
</ol>
2. Gut acidification monitoring assay
<ol>
	<li>Transfer starved flies into a Petri dish containing single dots (200 &#181;L) of fly food supplemented with 2% bromophenol blue (BPB). Allow the flies to forage for 4 h at room temperature while exposed to light.</li>
	<li>After 4 h, collect the flies and anesthetize them on ice; surgically isolate their guts.
	<ol>
		<li>Perform the surgery in 1x phosphate-buffered saline (PBS) with forceps under a stereomicroscope (see the&#160;Table of Materials). Isolate the gut by holding the thorax with a pair of forceps and pulling down the abdomen with a second pair until the CCR of the gut is visible, taking care to ensure that the intestine remains attached at both ends.</li>
	</ol>
	</li>
	<li>Determine acidification of the gut by examining the color of the CCR of the gut (Figure 1C; yellow indicates acidified, and blue indicates not acidified).</li>
	<li>Count only those flies that show robust BPB staining in their guts.</li>
	<li>Calculate the percentage using the following equation: 
	Percentage of flies with acidified guts = number of flies acidified&#160;&#215; 100 / (number of flies acidified + number of flies non-acidified) 
	NOTE: A percentage of 0 indicates that no flies acidified their gut, whereas a percentage of 100 indicates all flies acidified their gut.</li>
</ol>

<table><tbody><tr><td>Bromophenol blue</td><td>Sigma-Aldrich</td><td></td><td>B0126</td></tr><tr><td>&lt;em&gt;D. simulans&lt;/em&gt;</td><td>&lt;em&gt;Drosophila &lt;/em&gt;Species Stock Center at the University of California</td><td></td><td>Riverside California1 (https://www.drosophilaspecies.com/)</td></tr><tr><td>&lt;em&gt;D. erecta&lt;/em&gt;</td><td>&lt;em&gt;Drosophila &lt;/em&gt;Species Stock Center at the University of California</td><td></td><td>Dere cy1(https://www.drosophilaspecies.com/)</td></tr><tr><td>&lt;em&gt;D. pseudoobscura&lt;/em&gt;</td><td>&lt;em&gt;Drosophila&lt;/em&gt; Species Stock Center at the University of California</td><td></td><td>Eugene, Oregon(https://www.drosophilaspecies.com/)</td></tr><tr><td>&lt;em&gt;D. mojavensis&lt;/em&gt;</td><td>&lt;em&gt;Drosophila &lt;/em&gt;Species Stock Center at the University of California</td><td></td><td>Chocolate Mountains, California (https://www.drosophilaspecies.com/)</td></tr><tr><td>Forceps</td><td>Inox Biology</td><td></td><td>Catalog# 11252-20</td></tr><tr><td>Kim wipes Tissue</td><td>Kimtech</td><td></td><td></td></tr><tr><td>Oregon R</td><td>Bloomington &lt;em&gt;Drosophila &lt;/em&gt;Stock</td><td></td><td>(https://bdsc.indiana.edu/ # 2376)</td></tr><tr><td>Petri dishes</td><td>Fisher Scientific</td><td></td><td>Catalog #FB0875713A</td></tr><tr><td>Phosphate-buffered Saline (PBS)</td><td>HyClone</td><td></td><td>Catalog # SH30258.01</td></tr><tr><td>Stereomicroscope</td><td>Olympus SZ51</td><td></td><td>Visual magnification</td></tr></tbody></table>

gut acidification monitoring assay: a technique to study the acidification of the intestinal lumen in drosophila using bromophenol blue dye

Source: Abu, F., et al. <a href="https://app.jove.com/v/63141">Monitoring Gut Acidification in the Adult Drosophila Intestine.</a> J. Vis. Exp. (2021).
This video demonstrates an assay to monitor gut acidification in Drosophila flies. After the ingestion of food supplemented with a pH indicator dye, the acidification of the intestinal lumen results in a change in the color of the dye. Visual inspection of the digestive tract of the flies to examine the color change provides evidence of acidification.

<img alt="Figure 1" src="/files/ftp_upload/21239/21239_Figure1.jpg" /> 
Figure 1: Gut acidification monitoring.&#160;(A) Schematic drawing of feeding arena. The blue dot represents fly food with bromophenol blue (a pH-indicating dye). Other spots represent fruit flies. (B) Graphical representation of percentage of flies showing gut acidification fed for different durations over 4 h. Representative gut images of an acidified gut and a...

Gut Acidification Monitoring Assay: A Technique to Study the Acidification of the Intestinal Lumen in Drosophila using Bromophenol Blue Dye

Source: Abu, F., et al. Monitoring Gut Acidification in the Adult Drosophila Intestine. J. Vis. Exp. (2021).
This video demonstrates an assay to monitor ...

The insect midgut contains a copper cell region - CCR - which is responsible for gut acidification. This region contains specialized secretory cells - copper cells - that produce acid, which passes through the narrow channel formed by the neighboring interstitial cells. The acid releases into the intestinal lumen to aid digestion.
To monitor gut acidification in Drosophila, take adult flies starved for an adequate duration. Place the flies in a Petri plate containing a single drop of fly food supplemented with bromophenol blue, or BPB - a pH-sensing indicator dye. Allow the starved flies to forage for a fixed period.
After food ingestion, acid produced by the copper cells reaches the intestinal lumen and mixes with the food containing BPB. At an acidic pH, the BPB molecules get protonated, which changes their color from blue to yellow - indicating acidification.
On completion of the experimental duration, place the Petri plate on ice. A low temperature ceases neuromuscular activity in the flies and anesthetizes them. Place an individual fly under a stereomicroscope and surgically isolate the intact digestive tract.
Examine the CCR color to determine the status of gut acidification. A yellow coloration indicates acidification, while a blue coloration indicates the absence of acidification.
Inspect the digestive tract of all the flies, and calculate the percentage of individuals displaying gut acidification.

gut-acidification-monitoring-assay-technique-to-study-acidification

Research

JoVE Encyclopedia of Experiments

Biological Techniques

Assay Techniques

Biochemical assays

222 Views. المصدر: أبو، ف.، وآخرون. مراقبة تحمض الأمعاء في أمعاء ذبابة الفاكهة البالغة. J. Vis. Exp. (2021). يوضح هذا الفيديو فحصا لمراقبة تحمض الأمعاء في ذبابة الفاكهة الذبابة. بعد تناول الطعام المكمل بصبغة مؤشر الأس الهيدروجيني ، يؤدي تحمض تجويف الأمعاء إلى تغيير لون الصبغة. يوفر الفحص البصر?...

Video: مقايسة مراقبة تحمض الأمعاء: تقنية لدراسة تحمض تجويف الأمعاء في ذبابة الفاكهة باستخدام صبغة بروموفينول الزرقاء - Concept

High Fat Diet Feeding and High Throughput Triacylglyceride Assay in Drosophila Melanogaster

Heart disease is the number one cause of human death worldwide. Numerous studies have shown strong connections between obesity and cardiac malfunction in humans, but more tools and research efforts are needed to better elucidate the mechanisms involved. For over a century, the genetically highly tractable model of Drosophila has been instrumental in the discovery of key genes and molecular pathways that proved to be highly conserved across species. Many biological processes and disease mechanisms are functionally conserved in the fly, such as development (e.g., body plan, heart), cancer, and neurodegenerative disease. Recently, the study of obesity and secondary pathologies, such as heart disease in model organisms, has played a highly critical role in the identification of key regulators involved in metabolic syndrome in humans.
Here, we propose to use this model organism as an efficient tool to induce obesity, i.e., excessive fat accumulation, and develop an efficient protocol to monitor fat content in the form of TAGs accumulation. In addition to the highly conserved, but less complex genome, the fly also has a short lifespan for rapid experimentation, combined with cost-effectiveness. This paper provides a detailed protocol for High Fat Diet (HFD) feeding in Drosophila to induce obesity and a high throughput triacylglyceride (TAG) assay for measuring the associated increase in fat content, with the aim to be highly reproducible and efficient for large-scale genetic or chemical screening. These protocols offer new opportunities to efficiently investigate regulatory mechanisms involved in obesity, as well as provide a standardized platform for drug discovery research for rapid testing of the effect of drug candidates on the development or prevention of obesity, diabetes and related metabolic diseases.

High Fat Diet Feeding and High Throughput Triacylglyceride Assay in Drosophila Melanogaster

This is a high fat diet feeding protocol to induce obesity in Drosophila, a model for understanding fundamental molecular mechanisms implicated in lipotoxicity. It also provides a high throughput triacylglyceride assay for measuring fat accumulation in Drosophila and potentially other (insect) models under various dietary, environmental, genetic or physiological conditions.

تغذية حمية الدهون عالية وإنتاجية عالية بالانزيم ترياسيلجليسيريدي في Melanogaster المورفولوجية

Heart disease is the number one cause of human death worldwide. Numerous studies have shown strong connections between obesity and cardiac malfunction in ...

JoVE Journal

Genetics

A Rapid Food-Preference Assay in Drosophila

To select food with nutritional value while avoiding the consumption of harmful agents, animals need a sophisticated and robust taste system to evaluate their food environment. The fruit fly, Drosophila melanogaster, is a genetically tractable model organism that is widely used to decipher the molecular, cellular, and neural underpinnings of food preference. To analyze fly food preference, a robust feeding method is needed. Described here is a two-choice feeding assay, which is rigorous, cost-saving, and fast. The assay is Petri-dish-based and involves the addition of two different foods supplemented with blue or red dye to the two halves of the dish. Then, ~70 prestarved, 2-4-day-old flies are placed in the dish and&#160;allowed to choose between blue and red foods in the dark for about 90 min. Examination of the abdomen of each fly is followed by the calculation of the preference index. In contrast to multiwell plates, each Petri dish takes only ~20 s to fill and saves time and effort. This feeding assay can be employed to quickly determine whether flies like or dislike a particular food.

A Rapid Food-Preference Assay in Drosophila

We present a protocol for a two-choice feeding assay for flies. This feeding assay is fast and easy to run and is suitable not only for small-scale laboratory research, but also for high-throughput behavioral screens in flies.

A سريع الغذاء تفضيل المقايسة في دروسوفيليا

To select food with nutritional value while avoiding the consumption of harmful agents, animals need a sophisticated and robust taste system to evaluate ...

Neuroscience

Measuring Crop Motility and Food Passaging in Drosophila

Most animals use the gastrointestinal (GI) tract to digest food. The movement of the ingested food in the GI tract is essential for nutrient absorption. Disordered GI motility and gastric emptying cause multiple diseases and symptoms. As a powerful genetic model organism, Drosophila can be used in GI motility research. The Drosophila crop is an organ that contracts and moves food into the midgut for further digestion, functionally similar to a mammalian stomach. Presented is a protocol to study Drosophila crop motility using simple measurement tools. A method for counting crop contractions to evaluate crop motility and a method for detecting the distribution of food dyed blue between the crop and gut using a spectrophotometer to investigate the effect of the crop on food passaging is described. The method was used to detect the difference in crop motility between control and nprl2 mutant flies. This protocol is both cost-efficient and highly sensitive to crop motility.

Measuring Crop Motility and Food Passaging in Drosophila

The goal of this protocol is to measure crop contraction and quantify food distribution in the Drosophila gut.

قياس حركية المحاصيل والطعام في Drosophila

Most animals use the gastrointestinal (GI) tract to digest food. The movement of the ingested food in the GI tract is essential for nutrient absorption. ...

Gut Acidification Monitoring Assay: A Technique to Study the Acidification of the Intestinal Lumen in Drosophila using Bromophenol Blue Dye

Transcript

Gut Acidification Monitoring Assay: A Technique to Study the Acidification of the Intestinal Lumen in Drosophila using Bromophenol Blue Dye