Team:Paris Bettencourt/Project/Eliminate Smell

Figure 1. Enzymes responsible for body odor in the human axilla (Tauch, 2013).


Figure 2. 14 people smelled two tubes of E. coli grown to saturation in LB. One culture carried synthetic agaA and other an empty vector control. 13 people out of 14 rated the E. coli carrying agaA as more smelly (pink) than the control(violet). Experiments were double-blind. Significance was confirmed by Chi square test (p-value = 0.001341).

[figure 3 GC analysis]


Figure 4. Phylogenetic tree produced from 16S sequencing of Corynebacterium from human axillary samples. Corynebacterium was cultured on blood agar plates and the 16S region of selected colonies was sequenced. Sequencing results are presented here in a phylogenetic tree format. The tree was made by creating a multiple sequence alignment (MSA) using the CLUSTALW algorithm and then creating a neighbor-joining tree using the MSA. The length and order of the branches is not accurate due to the evolutionary closeness of the species sampled.

[Figure 5: smell test data??]

[Figure 6: megane's stuff??]

1. The Microbiome: Looking for Genes Responsible for Body Odor

Achievements

- Clone AgaA biobrick in E. coli.
- Find Corynebacterium species in axillary samples.
- Find genes related to odor in skin sweat samples.

Introduction

In previous literature, it has been determined that there are a few key enzymes responsible for body odor, such as AgaA, AecD, Ldh, and AckA. Fig. 1 shows a description of the enzymes studied in our project and the reactions corresponding to each enzyme.

The AgaA enzyme in Corynebacterium striatum is found to be a major source of "pungent" or "musky" odor in humans (Kligman, 1981). A specific bacterial aminoacylase cleaves odorant precursors secreted in the human axilla (Acuna,2003), and hydrolyzes 3-methyl-2-hexenoyl-glutamine (3M2H-gln) into 3-methyl-2-hexenoic acid (3M2H) and free glutamine. The enzyme is known to have a low specificity for the acyl group, and to act on a range of glutamine conjugates. We cloned agaA into the standard BioBrick vector, and expressed it in E. coli.

Results

In order to analyze the smell created by AgaA, agaA was successfully cloned into E. coli. A noticeable odor was produced by agaA-expressing E. coli grown in selective LB, described as "beer-like" or "cheese-like". We took this to be evidence that the enzyme was functional and acting on a non-native substrate in LB media. We confirmed this observation with a formal smell test (Fig. 2) as well as analysis by gas chromatography (Fig. 3).

We analyzed human sweat samples for two things. First, we conducted 16S sequencing of the samples collected in order to determine the types of Corynebacterium species present in the sample. The reason we were interested in Corynebacterium was because it is known from literature that one of the main enzyme responsible for the body odor smell (AgaA) is found in Corynebacterium species. Not only did we do 16S sequencing on these samples, but also conducted smell tests on the same samples in order to see if there was a correlation between odor smell and presence of Corynebacterium species.

Second, we conducted Sanger sequencing of axillary sweat samples for the genes in Fig. 1. [MEGANE ADD STUFF HERE ABOUT WHAT YOU DID EXACTLY / HOPED TO DO].

Methods

1. Cloning AgaA into E. coli

The AgaA enzyme from Corynebacterium (Genbank: AF534871.1) was codon optimized using IDT online tool (Integrated DNA Technologies, Belgium) for E. coli K12 and was commercially synthesized by IDT. PCR was performed to obtain the AgaA construct using a forward primer that contained the Biobrick prefix and a RBS designed using the Salis online tool; and a reverse primer that contained the BioBrick suffix. The PCR product was purified.

The agaA construct and PSB1C3 vector were digested using EcoRI and PstI. After, the agaA construct was purified using the PCR Purification Kit . The vector was gel extracted and purified. Both parts were ligated using Ligase T4.

Competent E. coli Neb Turbo were transformed with the ligation product by heat shock. Then, they were recovered during 2 hours in 200 uL of LB medium at 37ºC and plated in selective plates with LB and chloramphenicol in a concentration of 1 uL/mL. The transformation was confirmed by analytical digestion.

2. Find Corynebacterium species in axillary samples.

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2. Find genes related to odor in skin sweat samples.

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2. CRISPRs: finding natural odorless mutants

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3. Probiotic cream: a cure for body odor

Figure X: Cream with Corynebacterium striatum.


Figure X: Cream with fluorescent E. coli.

Ingredients
- Beeswax (known antibacterial)
- Soy milk (substitute medium for tryptophan soy for C. striatum growth)
- Jojoba oil

Formulation of the cream
- Tested cream formulation with RFP E. coli (Fig. X) and checked for growth.
- Tested cream with Corynebacterium striatum (Fig. X).
- Tested raw soy milk versus soy milk hydrolyzed with lemon juice. No significant difference in growth was found.
- Tested shelf life of soy milk and cream formulation. Unspoiled after two months.