Chile breeding

Plant breeding involves a great deal of luck and you can have some really good success with that. Luther Burbank produced numerous amazing plant varieties, but at the same time, he never believed in genetics. The key aspects of his method were to just try things, to grow large numbers at every stage, and to pay close attention to every plant (to find the differences). He tried crossing a strawberry and a raspberry... and actually got something.

With some knowledge, you can make predictions about what is more likely to work. To that end, plant breeders have researched what techniques are needed to hybridize different species. Usually there is limited success with hybridizing species in different genera, where the plants are less closely related, but there are exceptions. In the end, species labels are things we make for our convenience. Nature is under no obligation to follow what we think a species is or should be.

---

In peppers there are several domesticated or partially domesticated species:

• Capsicum annum : common sweet & hot peppers in North America.
• C. baccatum : more common in South America.
• C. chinense : habanero type peppers.
• C. frutescens : generally smaller, less common peppers. 
• C. pubescens : rocoto, manzano, locoto; tropical peppers with black seeds.

There are many more wild species that are only occasionally or rarely grown by gardeners. Those species contain a wealth of potentially useful genes though. Disease resistances, agronomic traits, and novel flavors can all potentially be moved from the crop wild-relatives into domesticated peppers. Towards that end, researchers have tried crossing almost any pair of species related to domesticated peppers. The following figure shows a crossability polygon, summarizing the results from attempts to hybridize between eleven species in the pepper genus.

I found the figure several years ago at: www.plantsciences.ucdavis.edu/vc221/pepper/PEPPERrd.htm. I have not yet been able to find the paper in which this figure was first published.

There are other wild pepper species, which could maybe be included in a more recent version of the figure.

• C. lanceolatum: a cloud-forest species sharing the trait of black seeds with C. pubescens.
  C. rhomboideum: a species barely considered to belong to the genus Capsicum, with yellow flowers, sweet berries, and brown seeds.
• C. annum var glabriusculum : tiny, very hot, wild pepper of the desert southwest US.
• And many others...

---

What this diagram suggests is that you could transfer an interesting trait from any one of these species into any other species you're interested in working with, either directly or through intermediaries. It would just take motivation, time, and money to do so. More generally, hybrids between the species would let one introduce much more genetic diversity into their pepper breeding projects, even if there wasn't a specific trait of interest.

I'm working with lines that include C. annum var glabriusculum in their recent ancestry. This was the wild pepper which grew in San Antonio and Austin Texas where I grew up. I started by growing seeds for the species which I (or friends and family) had collected from the wild. At one point, a few seeds collected from a large, seemingly wild plant grew up showing the parent plant had been a hybrid with some unknown domesticated type. I've been growing the descendants of those plants since.

At left is an side view of a patch of miniature pepper plants grown in 2022. Here they're about 4.5 inches tall and the tallest matured to about 8 inches in height. The smallest stayed under an inch (and didn't mature any pods). This line has the small leaves and pods of its wild ancestor, but has a far more dense branching structure and short stems. They produced more and more dark purple/black pigment in the leaves as the season went on. The pods matured from black to bright red at final maturity. The pods range from very hot to volcanic. The plants were covered in black and red pods at the end of the season.

Other plants derived from that initial wild hybrid had larger, more typical forms, though they were still small in size compared to many garden types. Among those, one plant (at right) stood out as extra productive in 2021. I had been hoping to select up a productive hot pepper type since the more standard types have been not doing so well with my short growing season. I grew 25 plants in 2022 from seeds saved from this plant.

Those plants made it clear the productive parent plant had been a new hybrid, between the wild hybrid derived plants I was growing and the Pimenta da Neyde pepper I had been growing the year before. In addition to a wild range of leaf color and plant growth habit in these F2 plants, I also found several with decently large pods at various heat levels.

The split pod at left came from a single plant which seemed to mimic a habanero. The pods had very thin walls and had a heat comparable or higher than habaneros. The internal membranes look so enriched in capsaicin oils that I was hesitant to try tasting them. Other plants seemed to mimic jalapenos, with their thick flesh and corked skin. These peppers are smaller than real jalapenos with a moderate heat level. The plants with both types of pods were far more productive than any habanero or jalapeno I had grown in my gardens, so I took this as a win.

Though I can't be sure, I have a pretty good feeling that all of these peppers are able to grow as well as they do for me in part because of some genes inherited from their recent wild ancestor. They handle the poor soil and limited water in my garden far better than usual garden types. The miniature peppers absolutely have their size and growth habit in part due to their wild ancestry.

In the next several years I hope to stabilize several new varieties from this project. Even if I don't, I'll be getting plenty of hot peppers along the way.

References:

• Burbank's strawberry/raspberry hybrid: https://the-biologist-is-in.blogspot.com/2015/01/hybrid-sterility-and-speciation.html
• Intergeneric hybrid orchids: https://www.aos.org/orchids/additional-resources/intergeneric-hybrids.aspx

Botanizing in Hawaii: Hawaiian Pepper

One of the plants I really wanted to find on my trip to Hawaii is known as the Hawaiian Pepper. This semi-wild pepper plant is generally referred to as a type of Capsicum frutescens, though you will often find references to it as different varieties of C. annuum. The ancestors of these chiles were first introduced to the islands around 1815, but they have since been integrated into the local culture and are often described as native. The small size and non-aggressive growth of the plants has allowed them to integrate into the island ecosystem without being too disruptive. Like other wild peppers around the world, birds also help distribute the seeds.

You can order seeds for it (I have no affiliation with the linked company, but found them via a quick search.), but I wanted to find the species growing wild on the islands.

The plants I found were... not exactly growing wild. As I walked along part of the resort where we were attending a conference, I glanced through a gap in some hedges and saw the characteristic look of chile plants. When I walked around behind the hedges, I found what looked like a little guerrilla garden someone had setup outside the watered and maintained landscaping of the resort. There were several Hawaiian Pepper plants of about the same age/size spaced about the area. I suspect someone who works on the resort planted them and would go by every now and again to tend to them.

I collected a few dried pods that had dropped to the ground around the plants. I didn't grow any this year, but I did send some seeds to a collaborator out in California. (They're on twitter as @ChaoticGenetics. Go check them out!) Last I heard the plants were growing well.


References

• https://mauiseeds.com/products/hawaiian-chile-pepper
• https://themolokaidispatch.com/hot-hawaiian-chile-peppers/
• https://en.wikipedia.org/wiki/Guerrilla_gardening

Chromosome Painting

The figure at left shows the metaphase chromosomes of a pepper root-tip, in all their squiggly false-color glory. In it you can count the number of chromosomes and (with some little background research) determine the overall ploidy of the source plant. (It has 24 chromosomes, so is a diploid.)

The original image had all the same information, but it was much harder to look at and learn from. This is a fundamental lesson of, and reason for, data visualization.

---

Step 0.

The original image comes from Twitter user @ChaoticGenetics. They're studying chile genetics and routinely post cool photos derived from their work. The question paired with this image was, "How many chromosomes does everyone see?" I figured I'd take a stab at it.

Lets dive into the details of how I made my figure. I use GIMP for essentially all my image editing needs. With each step figure I'll include the menu options for each command I use in brackets, so others can repeat the procedure.

0) Load the image with GIMP. Open "Tool Options" [Control-B] and "Layers" [Control-L] windows.

Step 1.

Step 3.

1) Select a rectangular region around the interesting looking chromosomes, then crop [Image > Crop to Selection] the image.

Step 2.

2) Select the "Eraser Tool" and erase all the background color and spots that don't appear as chromosomes.

3) Right-click on the image in the layer window. Select, "Add Alpha Channel". Discard the color information in the image [Colors > Desaturate]. Remove the background color [Colors > Color to Alpha (Set "From:" color to white.)].

Step 4.

4) From the layer window, make a new image layer filled in white. Move this layer beneath the image layer. Select the image layer.

Step 5.

5) Using the "Free Select Tool", draw around a visually distinct chromosome. Invert the color of the selection [Colors > Invert]. Change the color of the selection [Colors > Components > Channel Mixer... (red=50,0,0; green=0,0,0; blue=0,0,50)].

Step 6.

6) Many of the chromosomes in this example are adjacent or overlapping with another. For these, we have to use some knowledge about chromosomes and some artistry. Lets have a look at the cluster here highlighted in green.

Step 7.

7) At this scale, chromosomes are essentially linear structures. They don't branch and they don't loop. From this we can tell the green feature in step 6 is actually three chromosomes. I cut each chromosome out of the image and pasted into a new layer. From there I could clean up their shape a little before changing the colors and recombining them.

Step 8.

8) Going progressively through the image, isolating and coloring the most apparent chromosomes at each stage, we come to 16 chromosomes that we can be confident about. (So, our cell isn't a haploid with 12 chromosomes.)

We're left with the region at left I've highlighted in pink. This region would need to account for a further 8 chromosomes to reach the expected diploid count of 24 in total. Though there are probably a few chromosomes in this region that we can confidently separate, much of it is down to guesswork.

It is possible for this specific pepper plant to have fewer chromosomes. Though it is unlikely for a chromosome pair to be lost, since each has been conserved over a long time period and likely contains critical genes, it is common enough evolutionarily for chromosomes to fuse. That pink mess could hypothetically be 6 or 4 chromosomes, though this one image isn't sufficient evidence to make me think it is likely. If the same pattern is shown in a few more images from the same plant, especially if the chromosomes are better spread, then I'd start to consider that as increasingly likely.

---

For now, the balance of the evidence leads me to think there are 24 chromosomes and they're just not perfectly isolated. So, I divided the uncertain pile of chromosomes into the number that I expect are remaining. Any figure you make will invariably include your assumptions. The key is to try and make those assumptions reasonable or at least apparent to the reader (though this may require some nice caption-writing).

Interestingly, there's a protocol which can experimentally produce the sorts of painted chromosomes we're simulating here. Fluorescent In-Situ Hybridization (FISH) relies on making DNA probes which are stained a unique color for each chromosome. When the probes are applied to a chromosome spread, the result helps visualize chromosome crossovers, deletions, and other large scale alterations that can be important in diagnosing cancer and other disorders. The setup work for this is pretty intense, so it's probably not going to be used for the simple task of seeing how many chromosomes a plant has.

---

While I was in grad school, I routinely modified figures from papers I was reviewing for in-class (or in-lab) presentations. Usually highlighting different components of the figure in different colors (like here), to make them stand out more when displayed. I was doing the hard work of figuring out the important parts of the figures so students watching my presentation didn't have to. My goal was for them to focus on what I was saying about the figures and see what wanted them to see at a glance.

Using colors to present different partitions of a larger dataset ended up being central to my last large graduate project (YMAP) as well as an important part of my current [non-academic] job. While using colors for data presentation, it is important to keep in mind that not everyone has the same ability to see color. The most common forms of color-blindness are often called Red-Green-colorblindness. From this, it is a good idea to try and avoid the commonly used Red-Green color scheme seen so often in biology research figures. (Blue-Yellow is a good alternative, but there are subtleties I'll have to go into later.) Being conscious of the issues means they will inform your decisions, even if you're not fully aware of the topic.

---

This post was inspired by a conversation over on Twitter. (You can follow me there as @thebiologistisn.)

#pepper root tip squash, farmer's fixative, aceto-orcein stain. Top: 400x, bottom: middle left spread, 1000x. @ukitel_ My problem, don't get reliable, countable spreads. @jmahoney515 Not sure about woody plants, what is the issue? #science #photography #cytogenetics pic.twitter.com/gpxiCc4ppM

— ChaoticGenetics (@ChaoticGenetics) February 4, 2018

The original picture of the chromosome spread was made by @ChaoticGenetics, who gave permission for me to use it in this post.


References:

• twitter.com/ChaoticGenetics
• Starting image: twitter.com/ChaoticGenetics/status/960242439746306048
• GIMP: www.gimp.org/
• Pepper chromosome counts: www.plantsciences.ucdavis.edu/vc221/pepper/pepperrd.htm
• Yeast Mapping Analysis Pipeline (YMAP): genomemedicine.biomedcentral.com/articles/10.1186/s13073-014-0100-8
• Fluorescent In-Situ Hybridization (FISH): www.nature.com/scitable/topicpage/fluorescence-in-situ-hybridization-fish-327

https://twitter.com/ChaoticGenetics/status/9602424397463060

Pepper Permutations

Whenever I interact with a plant breeder, I first want to know what their goals are with their projects. Then I want to know about how they're approaching the problem and what results they've had so far. There are other interesting conversations to be had with breeders (What got you started in plant breeding? What got you interested in this crop? etc.), but these are the ones I keep asking when a breeder mentions their projects.

I've got a few pepper breeding projects I'm working on. I figured I'd answer my own questions regarding them, though I may ramble on a bit.

---

Upright fruit on plant from 2nd generation.
Upper-right: Overlay of fruit ripening brown.

My first pepper breeding project started with a simple observation. I was growing a batch of plants from seed I had saved from a tasty small brown bell pepper I found at the grocer. One of the plants had fruit which pointed upwards. I decided I liked the look of the plant, so it was to only one I saved seed from.

The next year, I grew several plants and only found 2 of the 7 had the upright fruit posture I liked. I was disappointed, but this told be something important about the genetics of the trait. Since the female parent had the trait, but not all of the kids did, the trait didn't have a dominant inheritance. This is consistent with the description of the trait in a review of published research, indicating there are two recessive genes that interact to produce the trait.

The review of pepper genes says, "Upright fruit orientation is controlled by two recessive genes — up-1 and up-2 — that show specific dominant and recessive epistasis respectively." In short, this means there are two genes that lead to upright fruit when present in the recessive version, but that the two genes interact such that a dominant version at one locus can override the recessive version at the other locus (but not when the dominant/recessive versions at the two loci are swapped). Ok, that wasn't so short.

My seed-parent plant having the trait, but the minority of the offspring also sharing the trait initially can look like a dominant inheritance with the parent being heterozygous. This isn't consistent with the published literature, but it is what things would look like if there was a large amount of cross-pollination from other plants in the garden.

At the end of the last growing season, I dug up the plants for this project and moved them into my basement under lights. This lets me ensure the next batch of seeds will only be from selfing the selected plants. This should help ensure the next generation of plants will all have the upright fruit trait.

(The next generation have been entirely consistent with the upright pod trait. Either I lucked out and both plants each carried two copies of the dominant version of the gene, or the trait really is recessive and both plants carried two copies of the dominant version. In subsequent generations, the pendant pod trait never re-appeared. In the end, the data confirmed it was a recessive trait as suggested by the research literature.)

This project was pretty simple to plan and is moving forward nicely. I'm hoping the plants I grow out this year will show the project is essentially complete. 

---

I have other projects that aren't so simple, in that they will require one or more directed hybridizations. These projects will take several years to accomplish, that is if I ever complete them.

What are my breeding goals?

1. White Habanero: A Habanero with very little of any pigment, so appear "white".
2. Black Habanero: A Habanero with high levels of anthocyanins, so appear "black".
3. Fancy Jalapeno: A Jalapeno which ripens to red with brown stripes; bonus points for having dark purple marks too when ripe.
4. Floral peppers: Arbitrary fruit, with large and colorful flowers. Ideally with flowers presented above leaves.

How am I approaching these goals?

1. White Habanero: A review of the

   

   [+;c1;+] and [y;+;c2]

   primary color genes for peppers (in an earlier post) indicates I can get a "white" chile with the genotype [y/y;c1/c1;c2/c2]. I have pale-orange (genotype [+/+;c1/c1;+/+]) and yellow (genotype [y/y;+/+;c2/c2]) habanero varieties. They both have the shape I'm looking for, so it is just the color genes I'll have to worry about. The F1 formed by crossing the two strains will be red and have the genotype [+/y;+/c1;+/c2]. Among the F2s, 1/64 should be homozygous for all three recessive traits needed to make a "white" chile.
• All the other red/orange/yellow colors should also turn up in the F2s, so this will be an interesting cross to play with.
• There is a variety called "White Habanero", but it doesn't have the shape I think of when I think of a Habanero pepper.
• I've even thought of a name for the final variety: "Pale Horse".



[A;MoA;an]

2. Black Habanero: I already have a "black" chile called "Pimenta da Neyde" (genotype [A;MoA;an]). It doesn't have the habanero shape, but I can cross it to a habanero for those traits. The boxy shape is dominant to the elongated shape, so the F1 should be boxy (and have some arbitrary color). Among the F2s, 1/64 should be homozygous for the three recessive traits needed to make the "black" color. 3/4s should have the boxy habanero shape, with 1/3 of those being homozygous for the dominant trait. All together, 1/192 of the F2s should have the ideal combination of traits.
1. Depending on what color genes are hidden beneath the black of "Pimenta da Neyde", as well as what traits are brought to the party by the habanero, lots of other colors are likely to turn up in the F2s.
2. There is also a variety called "Black Habanero", but it has neither the black color or the shape I'm looking for.
3. I've also thought of a name for the final variety: "Black Death".
3. Fancy Jalapeno: his concept will

   

   Hypothetical ripe and immature.

   take combining traits from several varieties. "Fish" has a recessive striped trait. I have a nice Jalapeno with a black top when unripe (which is probably related to sun exposure). I have a bell pepper which ripens brown because the chlorophyll isn't degraded upon ripening. "Pimenta da Neyde" has the trait to retain anthocyanin when the fruit is ripe. Getting all these traits, due to at least 6 different genes, into one plant is going to be a challenge. My plan so far is to make crosses between two pairs of the four strains. Once I've selected F2s from each cross that have their parents' traits, I'll then cross them, then select among the new F2s.
1. I don't yet have a name in mind to go with this project.
2. I may give up before this project is done. We shall see.



Floral variations.

4. Floral Peppers: I have a bell pepper line with very large, white flowers. I have a pepper with relatively large intense-magenta flowers. I also have a pepper with relatively tiny, but greenish-yellow flowers. The plan is to cross each of the two colored-flower chiles to the bell pepper, then screen the resulting F2s for larger flowers with improved color. The fruit characteristics are entirely arbitrary.

What have I accomplished towards these goals?

1. 

   Left: Chile with magenta flowers crossed to bell.
   Right: Chile with greenish flowers crossed to bell.

   White Habanero: I have a mature habanero plant with yellow fruit. I am about to plant seeds for the one pale-orange fruit. Later in the season I'll be able to do the initial cross.
2. Black Habanero: I have a mature habanero. I have several plants of "Pimenta da Neyde", but they're all very slow growers and have yet to flower. Hopefully later in the season I'll be able to do the initial cross with them.
3. Fancy Jalapeno: I have got basically nothing done towards this goal. I have all the seeds and will be planting them shortly.
4. Floral Peppers: I've made each of the initial crosses between the chiles with colored flowers and the bell pepper with extra-large white flowers.

---

It took me a while to figure out what sort of peppers I might want to breed. I've got a few other projects in mind, but I figured this post was getting rather long already.

It helps to keep an open mind when working on breeding projects, since you will find variations and combinations of traits that you didn't expect from the outset. So long as you're doing the breeding project for your own purposes (as I am), there is no harm in changing direction along the way. I expect the F2s from the habanero crossed to the bell pepper to be all sorts of interesting. Even if my ideas about floral peppers never comes to fruition, something useful will come out of it.

Among pepper plants I've grown, I've already found a couple really interesting traits that have caused me to change course. I'm not willing to discuss them publicly yet. I'm still trying to decide if they're the sort of thing that would have value to a larger market, so to speak.

Edit (02/25-2026): The crossed-out and yellow highlighted passage was awkwardly written, had an incorrect inference, and finally the link used to support it has failed. So, it was time to rewrite. Thanks go to Bryan Alexander (in comments) for pointing out the issue. New passages are highlighted in green.

References:

• Pepper genes: https://journals.ashs.org/view/journals/hortsci/41/5/article-p1169.xml
• Selfing chiles: growingfoodsavingseeds.blogspot.com/2016/06/gluing-chilli-flowers-way-to-save-pure.html
• Chile genes: hortsci.ashspublications.org/content/41/5/1169.full.pdf
• Chile colors: the-biologist-is-in.blogspot.ca/2015/11/the-color-of-peppers-2.html
• Varieties:
• Pimenta da Neyde: www.fatalii.net/Articles/Pimenta-da-Neyde
• White Habanero: www.worldshottestgarlicpepper.com/white-habanero.php
• Black Habanero: www.superhotchiles.com/blackhabanerogallery.html
• Fish: www.rareseeds.com/fish-pepper/

Biology of the Enjoya Pepper

"Enjoya" pepper; marketing
photo from the TwitterVerse.

A few years ago a new pepper turned up in markets of Europe and then in the USA (and elsewhere). The bell peppers were a dramatic yellow splashed with red flames and were sold as "Enjoya" or "Flame" peppers.

There was no information available about the genetics of the trait, as there had been no academic literature published on the new variety. Gardeners with the habit of growing their own plants from seed took this as a challenge. People around the globe independently said, "Can I can grow seeds from that pepper and get striped fruit in my garden?" Seeds were collected by those who found the peppers in their grocers and then shared via online forums to those who had not yet found them. Soon after, there were many little green seedlings being tended to around the world.

Typical flowers and fruit.

Months later, the first reports on the plants started coming in. The plants were producing large bell peppers, but they were all ripening yellow. (I have reports of 11 plants maturing to produce yellow fruit.) As these reports were posted to the forums, interest in the plants waned. (Dreams of crossing the trait into jalapenos and other hot peppers quietly died.) If the amazing red flames weren't going to reappear, then why would anyone want to be growing these plants?

---

Where did these peppers come from?

The marketing site for the pepper says:

Now, 30 years later, nature has once again surprised us with a natural variation: the red/yellow striped pepper. In 2013, Wilfred van den Berg found this beautiful variety in his greenhouse in Est.

But the US patent applied for the pepper says:

[0011] `E20B3751` was discovered in a screening trial of mutants of pepper variety `Maduro` conducted at Est, Netherlands. The mutant `E20B3751` was selected based on its vertical red and yellow stripes color and propagated vegetatively (i.e., asexually).

I strongly suspect those responsible for writing the marketing site didn't want to say the variety was the result of a mutation breeding project in a high-tech lab, as such things tend to get a lot of people suspicious about their foods. This is only a slight fib, since the mutated variety is a variation of the natural pepper.

What draws my attention more is that the patent doesn't say anything at all about how the pepper plant was produced (aside from the general concept of a mutagenesis screen). The entirety of the patent starting on line [0046] is simply a rehashing of general plant biology and breeding. None of that tells us anything at all about the origin of the striped peppers. This is strongly counter to the basic idea of what patents are supposed to be. The earlier paragraphs of the patent do give a concise description of what the pepper is, as well as a listing of specific traits associated with it, so it isn't entirely a useless document.

---

Since there isn't any academic research published on the pepper and neither the patent or marketing information provide any biological details, we're going to have to see what we can figure out from basic principles.

Mutations in genes typically produce traits which are either dominant or recessive. (There are a few other scenarios, but we're not going to worry about them for now.) If the striped trait is recessive, then essentially all of the next generation would also have the trait.

If the striped trait was dominant, then [with perfect selfing] the next generation might all have the trait, but there are other scenarios. If the Enjoya pepper plant (remember, from the patent they are propagated assexually and so are all from the same genetic plant) was heterozygous for the dominant trait, then half of the next generation would remain heterozygous and have the trait. Another quarter would be homozygous for the no-stripes trait and the remaining plants would be homozygous for the striped trait. Dominant traits can sometimes also have recessive lethal characteristic, though it is rare. All together, at the very least 66.6% of the next generation should have stripes if the trait was due to a dominant nuclear mutation.

In either scenario, we should have the majority of the next generation with stripes. What do we see? Between my plants and those reported by other growers, we have 16 plants that have ripened fruit. All of which matured to yellow with no red stripes. This would be a very unexpected result for either model discussed above.

---

Meristem figure from Wikipedia.

There is another scenario that might be important. A growing meristem of a plant include multiple tissue layers which replicate independently. A mutation in one layer generally won't transfer to the other layers. As the plant grows, the mutated and non-mutated tissues will be maintained separately. As leaves or other organs develop, the different meristem layers contribute to different parts and so would result in visible variegation if the mutation had a visible impact.

Photo cropped from one at link.

After looking around a bit, I found a photo which might provide some clarity to the situation. In the cropped close-up at right, it is clear that all the seeds are attached directly to yellow tissue. There is red tissue in the core of the seed mass, but none at the surface where the eggs (and then seeds) developed.

It looks like some of the red core cells are able to migrate to the surface of the fruit during early development. This results in the red stripes as the fruit then expands in size.

Since the red color is carried in tissue which isn't made into eggs or seeds, it appears unlikely that the seed-grown progeny of an Enjoya pepper would produce red or striped fruit.

Sorry folks, I think the game is up. We probably won't be able to breed flame-colored jalapenos. At least we've learned something about the biology of these peppers.

---

That the striped trait can't be passed down through seeds tells us something about the experiments which led to the Enjoya pepper. The patent indicates it came from a mutagenesis experiment, but gives no details. One of the easiest ways to do it would have been to soak a large batch of seeds in a chemical mutagen (like EMS) and then grow them out after treatment. EMS is relatively easy to work with and it would produce point mutations all over the nuclear and cytoplasmic genomes. I bet when that first plant matured its first fruit, there were amazed expressions all around.

The classical story of pepper color genetics (described at the-biologist-is-in.blogspot.ca/2015/11/the-color-of-peppers-2.html) suggests it would take two separate mutations to produce the rich yellow color seen in the Enjoya pepper. However, there are a lot of mutations which impact pepper color that don't really seem to fit the classical story. I strongly suspect the visible difference between the red and yellow fruit tissues is down to one mutation.

However, EMS is not something that would be used to make a single point mutation. It would instead create hundreds or thousands of point mutations per seed in this sort of mutagenesis experiment. Selection of the resulting progeny, as well as backcrossing to the parent type, would normally be used to clean up any unwanted deletarious mutations... but the striped trait would not have survived this process.

This means that the genome of the Enjoya pepper is probably chock-full of other potentially interesting mutations. Many of those mutations will be recessive and so only become visible in the second generation after treatment. The plants we've been growing from saved seed represent that second generation (referred to in shorthand as M2).

Enjoya-M2 with a transient anthocyanin shoulder.

One of my seven M2 plants produced a dark shoulder of anthocyanin pigments on the unripe fruit. These anthocyanins were later broken down as the fruit matured to its [now] expected yellow. Dark shoulders are pretty common in peppers, so I'm still trying to decide if I want to save any seeds from this plant.

Enjoya-M2 with color-marked flowers.
Interesting stripes on the unripe fruit.

Another of my seven plants produced flowers with distinctive purple highlights. The fruit on this plant later showed a distinctive green striping on the shoulder while unripe. (The fruit of every other plant was solidly dark green.) I'm still expecting this one to mature to a solid yellow, but there remains the slim chance that a red cell fought its way into the seed. (The pepper has since ripened to the expected yellow.)

Two of my seven plants produced distinctively different plants. This suggests there are indeed numerous hidden recessive mutations in the Enjoya pepper. The relatively large fruit I've been getting from these plants and the potential to find other novelty mutations means I'll probably be growing quite a few of these M2 plants in the coming years.


References:

• Marketspeak:
• www.enjoya.com/en/taste-of-nature
• www.hortidaily.com/article/17276/New-red-and-yellow-striped-pepper-is-named-Enjoya
• Patent: appft.uspto.gov/netacgi/nph-Parser?Sect1=PTO2&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&co1=AND&d=PG01&s1=pepper.AB.&s2=striped.AB.&OS=ABST%2Fpepper%20AND%20ABST%2Fstriped&RS=ABST%2Fpepper%20AND%20ABST%2Fstriped
• Discussions:
• www.tomatoville.com/showthread.php?t=41113&page=10
• www.growingfoodsavingseeds.co.uk/forum/main-forum/sweet-peppers-and-chillies/6906-enjoya-peppers
• www.growingfoodsavingseeds.co.uk/forum/welcome/welcome/6307-hi-nicollas
• c2cpeppers.proboards.com/thread/3987/flame-enjoya-pepper 
• en.wikipedia.org/wiki/Meristem
• en.wikipedia.org/wiki/Variegation
• en.wikipedia.org/wiki/Ethyl_methanesulfonate
• EMS mutagenesis in seeds:
• cals.arizona.edu/research/schumaker/pdfs/Kim%202005.pdf
• www.ncbi.nlm.nih.gov/pubmed/22485968
• file.scirp.org/pdf/AS_2014072414110807.pdf
• www.esalq.usp.br/tomato/Induced Mutagenesis and Natural Genetic Variation in Tomato 'Micro-Tom'.pdf
• www.imedpub.com/articles/gamma-rays-and-ems-induced-flower-color-and-seed-mutants-in-cowpeavigna-unguiculata-l-walp.pdf
• www.insa.nic.in/writereaddata/UpLoadedFiles/PINSA/Vol55B_1989_5and6_Art25.pdf
• the-biologist-is-in.blogspot.ca/2015/11/the-color-of-peppers-2.html

Early Chile Domestication

I first discussed Capsicum annuum var. glabriusculum in an earlier post. I've collected wild seeds for this species from a few different sources throughout the desert southwest.

The two views at right are the same plant, grown from seed collected in Phoenix-Az. The comparison of above and side views shows how well the down-hanging fruit of this plant are hidden from above, where birds would be more likely to see them while flying overhead. Since birds are the primary distributors of wild chile seeds, this trait would not encourage dispersal of the seeds and so the trait would not spread.

Early human farmers would have found this trait useful, as it would help reduce crop loss to birds. The majority of non-ornamental chile varieties grown today share this trait.

The lack of any other traits associated with domestication make me think this plant either represents the impact of selection pressure by early farmers, or a much more recent introgression event where all the other modern traits were heavily selected against. The seeds were wild-collected in Arizona (where humans have been living and using chiles for thousands of years) and modern chiles are commonly grown in the area, so either scenario is likely.

---

An approach which might help clarify the plant's ancestry is to compare its genome to more domesticated types. If it has this trait due to a modern introgression, there will be regions of its genome that match the relatively low diversity found in domesticated chiles. If it has had this trait for far longer, it's genome will be covered in variations not found in domesticated chiles.

Processing out some genomic DNA (gDNA) is a pretty easy thing. The difficulty will come in getting the material sequenced. I do have reasonably simple access to a nanopore DNA sequencer, but the data that comes from that technology has been problematic for some whole genome analyses in my experience (and in the experience of others). Ideally I'd have the gDNA sequenced using Illumina technology. This technology also introduces errors into the resulting data, but at lower levels and in ways that I have already written software to compensate for.

As I continue to build out my lab, this is probably one of the projects I'll be investigating further. Clarifying the ancestry questions for this chile would be personally rewarding, but also might fill in a tiny little detail about how people of the desert southwest lived. This might be very interesting to a large number of people.

---

I expect the other seed lines I have for C. annuum var. glabriusculum will grow to have upright fruit, but otherwise match the characteristics of these plants. I like the small size and pungency of the fruit, so I'll probably keep growing them even if I can't think of a breeding project to use them in.


References:

• the-biologist-is-in.blogspot.com/2015/10/wild-capsicum-annuum.html
• Chile genome info:
• www.ncbi.nlm.nih.gov/pmc/articles/PMC3986200/
• www.pnas.org/content/111/14/5135.full.pdf
• www.nature.com/ng/journal/v46/n3/pdf/ng.2877.pdf
• gDNA prep:
• www.thermofisher.com/us/en/home/life-science/dna-rna-purification-analysis/dna-extraction/genomic-dna-extraction/plant-dna-extraction.html
• Nanopore sequencing:
• nanoporetech.com/applications/dna-nanopore-sequencing
• seqanswers.com/forums/showthread.php?t=63896

Unstable Genetics

Collecting germplasm is a key step for any plant breeding project. For the amateur plant breeder, this can seem like an arduous task. Fortunately, you can take a quick shortcut by saving seeds from hybrid plants. A hybrid plant will be heterozygous for many alleles, because it was made by crossing two (more or less) unrelated plants. The seeds produced by a hybrid will be segregating out a diverse set of different combinations of the alleles.

Growing these seeds means you may get some plants that are simply worthless, or wonderful in your eyes. Farmers (or others wanting a precise and predictable crop) won't generally accept this uncertainty. (This is probably why there is so much online dismissing the idea of saving seeds from hybrids.) However, if you're ok with each plant being unique and changing from year to year, this may be exactly the sort of thing you're looking for.

Some small plant breeders sell seeds from the unstable early stages of their breeding projects. The good ones will be entirely clear about the unstable nature of the seeds they're selling. The bad ones won't even let you know there is an issue. I have no connection to the breeders I've linked to below, but they seem to be up-front about how their seeds are not a stable end-product of a breeding program. Their seeds should give you plenty of variation to work with.

Seed sources have been periodically updated since first posting:

• Cultivariable (Potatoes and various other tubers you probably haven't heard of.)
• Double Helix Farms (Potatoes, tomatoes, corn, beans, melons, peppers, etc.) 
• Ford's Fiery Foods and Plants (Hot peppers) 
• Mojo Pepper (Hot peppers) 
• Uncle B's Chiles and Etc. (Hot pepper "Free for all", at very bottom of page.) 
• Wild Garden Seed (Lettuces, kale, celery, leeks, etc.) 
• Joseph Lofthouse (Tomatoes, melons, squash, corn, and more!)
• Peace Seeds Live (Lots of interesting stuff.)
• Salt of the Earth Seed Co. (Lots of cool seeds. You have to explore the site.)
• Adaptive Seeds (Wide range of unique varieties and mixed genetics.)
• White Hot Peppers (Lots of peppers with a high potential of crosses!)
• Useful Seeds (Onions, leeks, parsley, lettuce, & parsnip.)
• ChaoticGenetics (Diverse pepper crosses.)
• OIKOS Tree Crops (Diverse potato seed in the link, other interesting things.)
  

This company is closing soon!!!

• Aster Lane Edibles (Many varieties bred for short-season areas! Go check them out!)

If you know of any other vendors offering similar seeds, please let me know!


References:

• en.wikipedia.org/wiki/Germplasm
• en.wikipedia.org/wiki/Zygosity 
• www.nature.com/scitable/definition/principle-of-segregation-law-of-segregation-mendel-301
• Don't save your seeds!
• aggie-horticulture.tamu.edu/archives/parsons/vegetables/SEED.html 
• www.theselfsufficienthomeacre.com/2013/10/can-you-save-seeds-from-hybrid-plants.html
• Do save your seeds!
• permies.com/t/46886/Saving-Seeds-Breeding-Plants-Landrace
• blog.arrowheadalpines.com/2011/08/go-ahead-save-seeds-from-your-hybrid.html
• www.aces.uiuc.edu/vista/html_pubs/PLBREED/pl_breed.html
• blog-yard-garden-news.extension.umn.edu/2009/02/seed-savers-garden-demonstration-of.html
• Seed sources
• www.cultivariable.com/
• doublehelixfarms.com/ 
• www.fordsfieryfoodsandplants.com/hybrids
• chilipepperseeds.tictail.com/
• www.unclebschilies.com/pepper-seeds
• www.wildgardenseed.com/newproducts.php
• garden.lofthouse.com/seed-list.phtml
• peaceseedslive.blogspot.com
• saltoftheearthseeds.com
• www.adaptiveseeds.com/seeds/highlighted-varieties/adaptive-seeds-originals
• www.whitehotpeppers.com/collections/non-isolated/unstable
• www.usefulseeds.com/product-category/breeders-lines
• www.asterlaneedibles.ca/shop.html
• www.chaoticgenetics.com
• oikostreecrops.com/products/seeds-ecos/vegetable-annual-seeds/perennial-potato-seeds/

The Color of Peppers 2

I previously posted about some of the genetics involved in determining the color of tomatoes (the-biologist-is-in.blogspot.com/2014/04/the-color-of-tomatoes.html). I've also written about the genetics of color in chile peppers (the-biologist-is-in.blogspot.com/2015/05/the-color-of-peppers.html), but I recently decided the topic should be approached a second time. The following post is a much improved version of the original, with better photos (mostly my own) and a few more mutations being described.

---

Ripe chile peppers (Capsicum spp.) come in a very similar range of colors to ripe tomatoes. Both vegetables (along with potatoes, tomatillos, and ground-cherries) belong to the Solanaceae family of plants. Because of the close relationship of the plants, there are strong similarities in how the basic biology of color operates in each of them.

The red color of a classic ripe tomato is due to lycopene. The red color of a classic ripe pepper is not due to lycopene, but instead due to a combination of Capsanthin and Capsorubin. These are produced by the carotenoid pathway like lycopene, but they're produced further along the pathway. The figure at right illustrates the carotenoid pathway in peppers, to the degree I've been able to learn about it from reading primary research literature. Most of the pathway here is identical to that seen in tomatoes (and other plants), but with an extension after Zeaxanthin.

Compared with tomatoes, there is less research available to elucidate the genetics of color in pepper. The following figures are close-up versions of the main figure above, highlighting the placement of a series of mutations in the pathway which result in color changes. The mutations are indicated by a large negative, highlighted in red, at the location of the change to the pathway.

---

Carotenoid Mutations

"Red", "orange", & "pale-orange"
mature habanero chiles.

The first major color mutations are abbreviated as "c1" and "c2". Each mutation acts to reduce the levels of carotenoids produced in the ripe fruit. When both mutations are in the same plant, they interact to reduce pigment levels dramatically.

Mutant "c2".

In the photo at left, the left-most chile is the typical wild-type red. The middle chile shows the orange caused by the presence of the "c2" mutation. The right-most chile shows the pale-orange caused by the presence of both the "c2" and "c1" mutations.

The gene containing the "c2" mutation has been identified as that of phytoene synthase (Psy). This defect at a very early stage in the carotenoid pathway results in a strong suppression of every later product in the pathway. (Mutations in the same gene in tomatoes are responsible for the production of yellow or white fruit.) The "c1" mutation has not been associated with a specific gene.

Mutant "y".

The next major mutation (left) specifically knocks out the intense red Capsanthin and Capsorubin pigments of chiles. The mutant is abbreviated as "y" because the resulting fruit are yellow when compared to the wild-type red color.

"Red" & "yellow"
mature habanero chiles.

To get the lovely lemon-yellow chile at right, the plant also needs to carry the "c2" mutation described in the previous section. The "y" mutation alone results in fruit with a orangish-yellow color (though I have not yet seen a chile I could be sure had this genotype). The variations of how different authors called colors as yellow or orange has led to different papers using the same color terms to refer to the colors produced by different combinations of genes. This can make it difficult to sort out how the results in one paper relate to those from another.

 y 

 c1 

 c2 

  ripe-fruit-color

+

+

+

  red

+

c1

+

  pale-red

+

+

c2

  orange

+

c1

c2

  pale-orange

y

+

+

  yellow-orange

y

c1

+

  pale-yellow

y

+

c2

  lemon-yellow

y

c1

c2

  "white"

These three mutations, in various combinations can produce anything from a rich "red" fruit to one that is as close to "white" as peppers get. At the left I've tried to represent the colors that would be produced by each genetic combination. I haven't seen some of the combinations, so the colors for those are more of my theory of what they would look like based on the descriptions in all the research I've read.

Mutant "bc".

A complication to this story is that there are other mutations which produce a fruit that ripens to orange. The "bc" mutation interferes with the conversion of β-carotene into β-cryptoxanthin, thus resulting in increased β-carotene and an orange color. The mutated gene has been identified as  β-carotene hydroxylase 2 (Bch2)

There's a pair of other mutations, called "B" and "t", that also result in a high level of β-carotene. These two mutations are described as complementing, but it isn't entirely clear what genes they're involved in.

I can't find photos for strains with these last three mutations, but I'm assuming they're more orange than red or yellow due to the enhanced level of β-carotene. Part of the problem is that there isn't a central repository for mutant lines of chiles, so many lines are not generally available. (The Chile Pepper Institute is supposedly working to resolve this by collecting strains discussed in research.)

---

Mutant "cl".

Chlorophyll Mutations

The chlorophyll that makes an immature pepper green is typically broken down during maturation of the fruit, revealing the bright red color of the ripe fruit. A mutation "cl" interferes with this breakdown and is therefore called "chlorophyll retainer". When the chlorophyll doesn't break down, darker colors result.

Photos from www.semillas.de.

In an otherwise red pepper, the result is a chocolate-brown color. In an otherwise yellow pepper, the result is a ripe pepper with an olive-green color. I'm not going to try simulating the colors we would expect for all the combinations of mutations, but I imagine an otherwise orange pepper would be an interesting shade in between brown and green.

I don't have any seed lines carrying this mutation, so I had to look to the web for illustrative photos. (www.semillas.de has lots of interesting chiles, but ordering from them would be problematic for me due to being in a different country.)

"Green" & "light-green"
immature habanero chiles.

About the chlorophyll I just mentioned? There are mutations impacting the amount of it produced in immature fruits. In particular, an alleleic series has been identified which results in immature chiles ranging from the typical medium-green all the way to a sulfury-white color. It isn't clear how many distinct alleles are around, leading to them being called "sw" with various subscript labels (like "sw₁", "sw₂", ..., "sw_n") to indicate the specific alleles.

"Green" & "light-green"
habanero chiles, now mature.

There's no way to know what the proper names for the alleles I have examples of are. They're both lighter than the wild-type color seen on other chiles and at best I can call them "sw₁" (for the darker) and "sw₂" (for the lighter) until I get some further examples of the series. These two chiles matured to an orange shade intermediate between the "red" and "orange" chiles I described earlier.

The lighter green color of the chiles indicates a reduction in the amount of chloroplasts. During ripening, the chloroplasts develop into chromoplasts as chlorophyll is degraded and carotenoids are synthesized. Fewer chloroplasts when immature means less chromoplasts when mature, thus a lighter "red" color. This phenomenon, where one gene impacts two or more seemingly unrelated traits, is called pleiotropy. (The darker green chile maturing to the lighter orange says that things are complicated and there may be other mutations involved. I hope to sort it out over the next several years.)

---

Anthocyanin Mutations

"Red" & "yellow", above.
"Pimenta da Neyde", below.

There are several pepper varieties that have purple or black immature fruit. This trait is driven by two genes. The "A" mutation allows the plant to produce purple anthocyanin pigments in its leaves, stems, and immature fruit. The "MoA" mutation modifies the effect of "A" to increase the amount of anthocyanins produced, resulting in more of a black color.

These anthocyanins are typically broken down as the fruit matures and so even black immature chiles will ripen to red/yellow/etc. A very rare trait which interferes with this breakdown is seen in the variety "Pimenta da Neyde". This trait results in mature fruit which remain purple or black. I haven't been able to find any publications describing this trait, so I've decided to refer to it as anthocyanin-retainer. I've found some of illustrative images of the the fruit produced in F1 plants: ("Pimenta da Neyde" x "Bubblegum 7" -> "Neyde x Bubblegum 7"), ("Pimenta da Neyde" x "Trinidad Douglah" ->  "Douglah x Neyde"). These photos indicate the anthocyanin-retainer mutation is recessive, so the short-hand label for the trait should be the lower-case "an". (I would only have to prove this pattern and write it up in a proper research publication to make the label official.)

---

Pattern Mutations

There are a several mutations ("pi", "bv", "m-1", "m-2", "m-3", "m-4", "vg^m", "vg^v", "chl", "dvg") which result in various forms of variegation of chile plants/fruit. Unfortunately, I haven't heard of any of these mutations being associated with any available strain.

"Fish" peppers; photo from
www.seedsavers.org.

The oldest variety of a striped chile that I've come across is called "Fish". The entire plant shows variegation and produces immature peppers with stripes of green and white. When the fruit matures, they change to the rich red color of typical peppers. I've read anecdotes of the variegation trait in "Fish" spreading to other strains when hybridized, which suggests dominance, but I haven't read any real research about the genetic patterns of the trait in "Fish" chiles.

"Enjoya" pepper; marketing
photo from the TwitterVerse.

Another type of striping is evident in a new variety called "Enjoya" which is currently only available in the Netherlands. (Anyone over there want to send me some seeds?) I managed to find one photo (in this article) that shows the "Enjoya" plant and its immature fruit, which show no variegation. Stripes that appear only during fruit maturation does not match any mutation I can find descriptions for.

"Pink Tiger" pepper; photo edited
from mojopepper.blogspot.com.

Another type of striping is seen in a series of pepper varieties still undergoing development. The first I came across is the iconic "Pink Tiger" which was derived from a cross between "Pimenta da Neyde" and "Bhut Jolokia". All of this group ("Pink Tiger"; "Pimenta Tiger"; "Black Scorpion Tongue"; others?) seem to be derived from crosses with "Pimenta da Neyde". This form of striping appears more random than the previous two. The peppers almost look like they have purple tears on the pale skin of the fruit. This trait also isn't associated with variegation in the rest of the plant. The extent of stripes/spots a plant produces seems to depend on how the plant was grown, though details of what conditions encourage or discourage the trait remain unclear to me.

---

References

• Intro: www.plantsciences.ucdavis.edu/vc221/pepper/PEPPERrd.htm
• Hurtado & Smith 1985: jhered.oxfordjournals.org/content/76/3/211
• Thorup et al. 2000: www.pnas.org/content/97/21/11192.full.pdf
• Lefebre et al. 1998: www.ncbi.nlm.nih.gov/pubmed/9526511
• Huh et al. 2001: link.springer.com/article/10.1007%2Fs001220051677
• Yellow caused by defect in Ccs gene:
• www.ncbi.nlm.nih.gov/pubmed/17728301
• www.ncbi.nlm.nih.gov/pubmed/9526511
• Orange color:
• Orange caused by two different mechanisms:
• www.ncbi.nlm.nih.gov/pmc/articles/PMC2889374
• Recessive orange caused by defect in Bch2 gene:
• www.ncbi.nlm.nih.gov/pubmed/23124390
• Recessive orange caused by defect in Ccs gene:
• www.jstage.jst.go.jp/article/jsbbs/54/1/54_1_33/_pdf
• Dominant orange color (patent)
• www.google.com/patents/US5440069
• Green color:
• www.ncbi.nlm.nih.gov/pmc/articles/PMC2330295/
• Chlorophyll-retainer (cl) gene:
• www.ncbi.nlm.nih.gov/pubmed/18427769
• Purple color:
• jhered.oxfordjournals.org/content/99/2/105.full
• www.ncbi.nlm.nih.gov/pubmed/18222931
• Gps, Ps, and Pd genes not coregulated:
• www.ncbi.nlm.nih.gov/pubmed/8250898
• Carotenoids in peppers:
• ucanr.edu/datastoreFiles/608-70.pdf
• Color genes map:
• www.ncbi.nlm.nih.gov/pubmed/11027328
• Questionable genotype::phenotype results contradict previous results.
• Genes of Capsicum:
• www.chilepepperinstitute.org/content/files/Genes%20of%20Capsicum%281%29.pdf
• www.chilepepperinstitute.org/content/files/no13.pdf
• The Chile Pepper Institute:
• www.chilepepperinstitute.org
•  Chile seed sources:
• "Habanero Brown":
• www.semillas.de/cgi-bin/shop_en/shop.cgi?shop=&keywords=Habanero%20+%20chinense%20+%20%22Habanero%20Brown%22
• www.tomatogrowers.com/HABANERO-BROWN/productinfo/9836/
• "Green Habanero": www.semillas.de/cgi-bin/shop_en/shop.cgi?shop=&keywords=Habanero%20+%20chinense%20+%20green
• "Fish": www.seedsavers.org/onlinestore/on-sale-now/Pepper-Fish.html
• "Enjoya":
• www.enjoya.com/en
• www.hortidaily.com/article/17276/New-red-and-yellow-striped-pepper-is-named-Enjoya
• "Pink Tiger": mojopepper.blogspot.com/p/pimenta-pink-tiger-2013.html
• "Bhut Jolokia": en.wikipedia.org/wiki/Bhut_jolokia 
• Allelic Series:
• www.wikipremed.com/mcat_course.php?code=0404030201030000
• Pleiotropy:
• en.wikipedia.org/wiki/Pleiotropy