Pollinators – Page 7 – Maryland Grows

Wild ginger spices up the Maryland spring

April 12, 2021April 9, 2021Maryland Grows2 Comments

As a pollination biologist, I have the immense privilege of studying really cool plants who trick their pollinators in fancy and incredible ways, and I tend to be naturally attracted to flowers that may not be super showy to most (but are among some of the most mind-blowing things in nature). These flowers are such a wonderful thing in their own right, and in this post I want to do them justice. Because it’s spring and some of these are starting to point their noses out of the ground, in today’s post I would like to (re)introduce you to a plant you may be familiar with, but that I hope after today you will get to look at with new amazed eyes (in case you don’t already 😉 ). Come with me and let’s chat a bit about the wonderful hidden queen of our forests: the wild ginger!

Is wild ginger, ginger?

The short answer is no. While ginger (the plant we eat) is native to Southeast Asia, wild ginger (Asarum canadense) is native to right here, and more specifically to the deciduous forests of Eastern North America. In case you are not familiar with the plant, it belongs to the family of birthworts, which have really interesting ways of interacting with their pollinators. Unlike other birthworts that tend to have flowers that hang in the air from the plant, wild gingers are very “shy” and the whole plant is restricted to the ground level.

Wild ginger is starting to peek out their leaves right now. Once the leaves are fully grown, they get their characteristic heart-shape and can create nice mats to cover the ground. Photos: A. Espíndola; threelark.

The plant is perennial (it lives for several seasons) and exits dormancy in the early spring when its heart-shaped and fuzzy leaves start to unfurl and emerge from the ground. Eventually, the plant becomes a little mat and over time it creates colonies. This is a reason why wild ginger can be a great groundcover plant to use under trees or in shadier and humid parts of one’s yard (see here for how to do this).

Wild ginger is cool – The flowers!

Unlike other birthworts, wild ginger holds its flowers close and parallel to the ground. Wild ginger’s flowers are not showy, being of dark brown and not very large. These flowers are engaged in mimicry pollination, meaning that “disguise” as something else (here, fungi), to trick pollinators into doing something they don’t necessarily want to do. In the case of wild ginger, the flowers are held low to the ground and close to the base of the stems.

Wild ginger flowers are displayed on the ground, at the base of the fuzzy stems. Being dark and close to the ground helps them lure their pollinators, small flies that feed on decaying matter. Photo: A. Carlson.

Wild ginger flowers are dark, particularly moist, and produce specific odors that attract small flies that feed on decaying matter. The tricking consists in making the flies enter the flowers to lay eggs in what the flies consider is fungi (their egg laying sites). While doing this, the flies contact the pollen-bearing structures, and while visiting different flowers, they cross-pollinate them. In this case, we talk about antagonistic interactions between the plants and their pollinators because the interaction does not benefit both partners. In fact, here the plants have the upper hand, and the flies simply loose their eggs to the plant since their larvae can’t feed on the floral tissues. If this is not sufficient to amaze you, keep reading; it gets better!

Wild ginger is cool – The seeds!

After pollination, the flower ovules grow into seeds. Unlike seeds in most plants, wild ginger seeds have a special “addition”. Indeed, the seeds have attached a special extension (called an elaiosome) that is particularly rich in lipids and proteins. This structure makes the seeds very attractive to ants, who collect the seeds, carry them away from the plant, and, after having consumed the elaiosome, discard the seed. By doing this, the seeds can get dispersed farther away from the mother plant, and the population can slowly grow and expand. Isn’t that super neat????!!!

The seeds of wild ginger have a special nutrient-rich body called elaiosome, which is a delicatessen for ants. This allows the plant to use ants to disperse their seeds. The shiny brown (left) and yellow (right) bodies attached to the seeds are the elaiosomes (arrows). Photos: Sid Vogelpohl, Arkansas Native Plants Society; B. Patterson.

Wild ginger as a human ally

Wild ginger was and is still well known to Native Americans of Eastern North America, and it is very likely that they were the ones who showed the European colonists how to use it. Among the Native names still known for this plant is namepin (see here to learn how to say it), which means “plant of small tubers”. Even though it is hard to find the original local names for Maryland tribes, we know that the roots of the plant were used to treat fever and coughs by Cherokees, Iroquois, and Rappahannocks, and that it is very likely that most of the tribes and bands of Maryland (e.g. Shawnee, Piscataway, Pocomoke, Assateague, Nause-Waiwash, Accohannock) use(d) it as well because the plant was and is abundantly present in the area.

By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí.

New! Anahí also writes an Extension Blog in Spanish! Check it out here, extensionesp.umd.edu, and please share and spread the word to your Spanish speaking friends and colleagues in Maryland. Bienvenidos a Extensión en Español!

This Year, Host Bees in Your Garden

March 8, 2021February 7, 2024Maryland Grows9 Comments

The sun and the warm(er) days are back! Oh gosh, it felt like forever! And now, of course, I am feeling like I have to get out there and start doing stuff outdoors! And because I love the little creatures, one of the things I want to do is make sure that this year my garden becomes a pollinator’s paradise. If you are in the same boat as me, come along, and let’s talk about how to make our gardens inviting to pollinators!

Like us, pollinators need food and a place to live

We hear a lot about pollinators and the plants we can plant to help them. And it is true, that to live and thrive pollinators need food, and that food usually comes from plants. Indeed, to sustain pollinators, it is key that we provide food for them. However, we often forget that they need something else to thrive: a place to live! And because there are SO MANY types of pollinators, let’s for this one time focus on only one group, the bees!

Even though many people think only of honeybees when we talk about bees, most bees do not live in colonies like honeybees do, and are in fact solitary. These bees are indeed the vast majority of bees, and, only in Maryland, we have about 400 different species of them, going from tiny to very large (check out this awesome free PDF book about bees from our region).

Unlike honeybees, each of these wild bee species has different nesting requirements, and many of them will readily nest close to our houses if they find the right conditions. Here I will give you some pointers on how to create those conditions to not only attract bees with flowers but also help them live close to your garden.

How do wild bees live?

Unlike honeybees, who lay eggs throughout the growing season, wild bees usually lay eggs only at certain times of the year, meaning that their life cycle is different from that of honeybees. Most solitary bees in fact lay eggs at only one point throughout the growing season (for example, only in the spring, the summer, or the fall).

inside of a stem showing nesting bees — Wild bees lay eggs in their nests and leave food for them. When the larvae
hatch they find the food and can finish their development in the absence of the mother. Photo: USDA ARS

Whenever they are ready to lay eggs, bee mothers start looking for a place to nest, and it is only during this time that they will be building their nests. Once the eggs are laid, the mother leaves and those eggs stay in the nest along with some food (usually pollen mixed with some nectar). After hatching, the larvae go on and eat the food the mother left for them, and continue feeding and growing until they are ready to leave the nest as adults, usually the following year. This means that for most bees, there is no or very little maternal care for the offspring and that most of the time spent in a bee’s life is as a larva, growing and getting ready for the “outside” world.

Where do wild bees live and how can I help them nest?

Wild bees have a variety of nesting preferences, with some nesting in the ground, where they dig galleries, others digging holes in the wood, others using already-existing cavities, and others parasitizing other bees’ nests (yeah, bees can also be sneaky like that!). Understanding this is important because depending on the resources we provide for nesting, different species will be attracted to our gardens.

Keep some ground undisturbed – Ground-nesting bees

green sweat bees on flowers — The green sweat bees are very common in Maryland and can be often seen
digging on bare ground and visiting flowers. Photos: J. Gallagher; Ilexin

If you would like to support these bees in your garden, you can make sure to leave some of your garden soil undisturbed or bare. If you do this, you will realize that many bees will be attracted to that section, and if you pay attention, you’ll realize that many are actually coming in and out of the ground! These are your ground-nesting bees! In Maryland, some ground-nesting bees that you may have seen visiting flowers are the small and shiny green sweat bees.

Leave some wood in your yard – Carpenter bees

closeup of a carpenter bee — The large carpenter bees nest in shallow galleries they excavate in soft
wood. Photo: Missouri Department of Conservation

In our region, these bees are represented by the very large shiny carpenter bees of the genus Xylocopa. These bees have strong mandibles that they use to excavate softwood, to build their nests in it. If you would like to attract these bees to your garden, make sure to leave relatively large branches and logs available for them to nest in. For this, you can turn a corner of your yard a bit wilder, and at the same time, leaving those branches in there will also allow other beneficial organisms to establish in your garden.

Bee hotels! – Cavity-nesting bees

a closeup of a bee and a bee hotel — Cavity-nesting bees are attracted to bee hotels. Photos: M. Lankford;
Piqsels

Unlike carpenter or ground-nesting bees, these bees do not create the cavities but rather use those that already exist. This is the group of bees that is attracted by those cute bee hotels one can build or buy. A natural option for supporting these bees is also by not cutting down to the ground the hollow stems of some plants at the end of the season. Many bees nest within these stems and will die if they are chopped off during the winter. Species in this group of bees nest in the spring, summer, or fall. For this reason, if one wants to use bee hotels to attract these bees, one should establish them early in the spring.

There are a multitude of types of bee hotels, with those involving little tubes that can be removed, holes drilled into the wood, a collection of small hollow twigs and branches, paper rolls, etc. (Check out this site to see many options.) Independently of the type of bee hotel you want to use, something important is to make sure that you keep the cavities clean for the bees to develop in healthy conditions. Failing to do so may actually harm the bees we’re trying to support, because they may still be attracted to the nesting site we’re providing, but may eventually become sick and die because the place is unhealthy.

Now it’s our turn!

I really love watching bees build their nests, independently of what they look like. Maybe I’m just nosy, or maybe this is really why I’m a biologist, but that peek into these little animals’ lives makes me feel connected to them and keeps me in awe at how wonderfully diverse and fascinating life can be. When you’re planning your garden this year, I invite you to consider the flowers for your bees, but also count on where you plan to have them live! And then, later in the season, go check those places out; I’m sure you won’t be disappointed!

By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí.

Anahí also writes an Extension Blog in Spanish! Check it out here, extensionesp.umd.edu, and please share and spread the word to your Spanish-speaking friends and colleagues in Maryland. ¡Bienvenidos a Extensión en Español!

Herbs in Veggie Gardens

March 5, 2021January 18, 2022Maryland Grows6 Comments

One of the most common pieces of advice I give out is to plant flowers in your vegetable garden. Blooming flowers are a big draw to many beneficial insects, including pollinating insects such as bees and butterflies, and predators and parasitoids like the tiny wasps who help to keep pest insects under control in your garden. Plus, flowers are pretty, you can cut them to bring inside, many of them smell nice; they are just pleasant to be around.

To attract a good range of beneficials, it’s best to have something blooming in or around your garden all season long, and a wide range of flower types and sizes is also good. From giant sunflowers to tiny forget-me-not or alyssum, if you see bees on it, it’s good to have around. But sometimes we forget that herbs are also flowering plants—we plant them for a burst of flavor in the kitchen, but don’t consider their other qualities, including as a source of nectar for flying insects. Some herbs have flowers that are great in size and shape for butterflies to visit, many attract bees, and those with the tiniest flowers bring in those useful little wasps. So when you’re planning what flowers to plant in your garden, consider adding more culinary herbs as well, and let them do double duty.

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Some plants are not cool, skunk cabbage heats up

February 8, 2021August 23, 2023Maryland GrowsLeave a comment

IMG_3725-eastern skunk cabbage at pine hole bog Eastern skunk cabbage at pine hole bog by dreamexplorer is licensed under CC BY-NC-SA 2.0

The middle of the winter may seem like an odd moment to think about flowers. In fact, if I look out my window, I can barely see the ground, with most of it covered in snow or ice. So, flowers and all the greenery of spring and summer seem like something that happened in another world which today seems sooooo far away! There are some flowers, however, that defy some of these rules of low temperatures and do a revolution in nature (OK, maybe not a revolution, but still…). In today’s post, and although surrounded by ice and snow, I invite you to join me and warm up using the heat that some plants produce, since we’ll be talking about heat-producing plants!

Really?! Can plants produce heat?

The short answer is yes, which is super cool in itself. The long answer is yes, but let me tell you how, and what are the advantages of producing heat (and why not all plants do it). The production of heat in plants is relatively rare, and this feature is found mostly in plants considered to have evolved a long time ago from an ancestor to most living plants. Today, heat production in plants is restricted to groups associated mostly with tropical and subtropical environments, such as water lilies, aroids, palms, and birthworts. Unlike what we may expect, heat production in these groups has not evolved to keep the plant alive, but rather to help the plant reproduce. In these groups, heat production is associated with floral maturation and in particular to pollinator attraction. In these cases, different parts of the flowers increase their metabolism at a specific point in their development, leading to an increase of temperature that in some cases can be extremely noticeable. In some cases, the heat has been described as a reward for pollination. (Check out this other post for other “special” rewards pollinators get from plants.) This is because it may occur at times of the year (or the day) when the environmental temperatures drop a lot, and when pollinators that visit the flower could benefit from an extra source of heat. In other cases, heat is known to promote the release and spread of floral odors, which attracts the preferred pollinators. In many cases where heat production is present, it has been observed that plants also display a way to retain the pollinators, such as floral chambers, and in many of those cases the interaction between the plant and its pollinators involves luring and temporarily trapping the pollinators!

plants in the arum family — Some arum family plants (here, the European *Arum maculatum*) temporarily trap their pollinators. The species shown here displays a chamber in the lower part of its “flower” that is closed by hairs (shown on the right), which let the insects in but makes it hard for them to leave. While the flies are trapped in the chamber, the flowers mature, dropping pollen on the flies. These flies will be released after a while, and some of them will be caught again by another plant, leading to the cross-pollination of the species. Sneaky, sneaky! Photos: A. Espíndola.

While it takes a lot of energy from the plants to produce heat, this usually allows them to flower early in the season while other flowers are not around. This reduces inter-plant competition for pollinators, makes the plants easy to find by pollinators, and increases the chances of having pollen be transferred from one flower to another — all of which increases the number of seeds plants are able to produce.

Our very own heat-producing plant, the Eastern skunk cabbage

Many of you may be familiar with Eastern skunk cabbage (Symplocarpus foetidus), which is among the first plants we see peek out their leaves in the snow or the ice in the early spring. Besides being among the first plants to appear in our region, they are actually also among the first to flower, and that flowering and their pollination are intrinsically related to heat production. Skunk cabbages belong to a mostly tropical family of plants, the arum family (Araceae). Fortunately to us, some of them do occur also in more temperate regions like ours (another native Araceae from our region is the beautiful Jack-in-the-Pulpit, Arisaema triphyllum). As with many other Araceae (for example, the titan arum), skunk cabbage attracts their pollinators through the production of a very pungent odor, which gives the plant its common name. And like all Araceae, their flowers have a very special shape that allows them to not only produce but also retain heat.

When their flowers start to mature, the “head” of the flowers heats up reaching temperatures of about 70˚F (!!!), even if the surrounding temperatures are below freezing. This heating leads to the release of aromatic odor bouquets, formed mostly by compounds rich in sulfides (thus, the stinky odor). Even though this odor may not be the most attractive to us, it is very much so to the skunk cabbage’s favorite pollinators: small flies and beetles that may be lured by the flower “thinking” it is their favorite food or egg-laying site. In defense of the plant, though, even though the attraction may be slightly dishonest, the lured pollinators may actually benefit a bit from the visit. While some of them may indeed find laying sites on the plant material, most of them will benefit from the heat received, which especially that early in the season is a much-welcome reward! This heat also allows the pollinators to become more active and sometimes even mate within the plant’s flower, which also benefits their own reproduction. Finally, and most importantly for the plant, through this heat release and all the insect movement associated with it, insects passively pollinate the flowers, getting covered in pollen and later transferring it to other equally stinky and warm skunk cabbage flowers. Isn’t this super cool?… I mean, warm? By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí. New! Anahí is starting an Extension Blog in Spanish! Check it out here, extensionesp.umd.edu, and please share and spread the word to your Spanish speaking friends and colleagues in Maryland. Bienvenidos a Extensión en Español!

Hot cocoa, bugs, and forests

December 14, 2020December 11, 2020Maryland Grows3 Comments

Last week my neighborhood hosted the traditional Christmas tree lighting event. Usually this event involves lighting the large Christmas tree across my street, having Santa come visit the kids on the firefighter truck, and sharing a cup of warm chocolate while chatting with the neighbors. This year, things were a bit different, with the lighting being live broadcasted, Santa parading the neighborhood on a truck, and chocolate being picked-up at one of our neighbor’s yard and enjoyed at home.

I have been since thinking a lot about this event, and how important it is to maintain the social ties in our neighborhood. However, I also have been thinking a lot about how the food at this event is almost as important as the event itself; how the chocolate was not left out of this year’s modified event. And this made me realize yet again how foods are central to our social ties, and how losing them would also make us a bit lonelier. So today’s post, the third in our comfort foods series, will be about that food that was so important to my neighborhood this past weekend: chocolate. Join me today in exploring how cacao comes to be, and how partnering with nature helps its (re)production.

cupcakes with chocolate sprinkles — Chocolate – the ultimate winter comfort food. Photo: Kathy Smail

What is cocoa?

The cocoa we find in the chocolate we eat and drink comes from beans of the cacao tree, a small tree in the mallow family. As for the other comfort foods we talked about in my last two posts (spices and vanilla), cacao is also not grown in the USA, and thus has to be imported. (Interestingly, it also has to be 100% imported into the countries we usually associate with chocolate, like Switzerland and Belgium.) Cacao, indeed, can only grow in very humid rainforests and can only be cultivated close to the Equator. Today, the major producers of cacao are in West Africa (e.g., Ivory Coast, Ghana) and the Americas (e.g., Ecuador, Brazil).

cacao tree a the forest — *The plant of cacao,* Theobroma cacao, *is a small tree naturally occurring in South and Central America. The fruits of cacao plants grow directly attached to the trunk. Photo: F. and K. Starr*

Even though cultivated in Africa, the cacao plant originates in South and Central America, where the species grows in the wild. Studies demonstrated that the wild plant was domesticated one or two times, first about 5,000 years ago in the Amazon, and about 3,500 years ago in Central America.

Although, as I said before, cacao beans are the central ingredient of chocolate, it is suspected that the first uses of cacao were not based on the consumption of their beans, but rather of their pulp, which is sweet and readily ferments to produce alcoholic beverages. Researchers believe that the use of beans for making the chocolate drinks the first Spaniards saw Aztec emperors drink was indeed a secondary use of the fruit.

How is cacao produced?

Unlike many of the crops we eat, most of cacao production is done by small-scale farmers. Being small trees, cacao fruits are produced in cacao orchards, usually established in areas previously occupied by rain forests. The fruits grow directly on the trunk of the tree, and need to be harvested regularly, since all fruits do not ripen at the same time. Once harvested, the fruits are cut open, and the pulp and beans are separated from the husks. While the husks are discarded, the beans are left to dry out, at which point they become dark and start looking like the little pictures we sometimes see on our chocolate bars.

cacao pod split open — The fruits of cacao are large husks that contain the beans and a sweet pulp. Note the violet/whitish color of the fresh beans, which will eventually turn brown after drying. Photo: Presidencia República Dominicana

As we see, a central part of cocoa production (and us getting the yummy chocolate we like) is the production of fruits, which seems to be defined by many aspects of the production. On the one hand, poor soils lead to yield reductions. Interestingly, cacao trees are adapted to growing in the understory of the rain forest and for this reason had been initially grown under other trees. However, once it was observed that their productivity increased if exposed to full sun, the accompanying trees started to get cut off, further contributing to the deforestation of the rain forests where they are usually grown, and increasing the monoculture of cacao plants.

After some years of higher yield, farmers realized that their trees became less and less productive, and came to understand that the presence of other trees in the orchards maintained the nutrients in the orchard’s soil, what eventually benefited fruit production. Today, in order to maintain yield and sustain the soils, cacao is recommended to be grown in what is called agroforestry systems, meaning that orchards are interplanted with other trees, which enrich the soil with nutrients, and provide a more natural shady environment in which the cacao trees can grow. The little label with a frog that we see on some certified chocolate packages indicates indeed that the farms where the cocoa used in that chocolate was produced following such environmentally friendly practices. Interestingly, as for many environmental practices, it was shown later that using agroforestry methods for cocoa production was not only beneficial to soil fertility; it also indirectly improved fruit pollination, thus improving yield through different paths!

Agroforestry practices allow cacao plants to grow under the canopy of larger trees. This improves the quality of the soil, promotes the presence of pollinators, and leads to higher yield. Photo: J. Rocha, from Rocha et al., 2019

How is cacao pollinated?

Why am I talking about pollination if I was just talking about planting trees? There’s a relationship, I promise! Let’s back up a bit. Unlike other crops (e.g., pecans) most cacao plants need to be cross-pollinated to produce pods and beans. This means that most cacao varieties need to receive pollen from another plant to produce fruit. In the case of cacao, the pollen cannot be transferred by wind, which makes animal pollinators central to cocoa production. In a surprising turn of events, even though we tend to think about pollinators as bees or butterflies, this wonderful fruit is mainly pollinated by a very unexpected organism: a biting midge! 🤯

cacao flower and pollinator midge — Midges of the genus Forcipomyia are the main pollinators of cocoa flowers. These tiny flies visit cocoa flowers and get covered in pollen, as seen in the picture on the left. Photos; left: S. Forbes; right: C. Quintin

Males and females of a group of midges (genus Forcipomyia) act as the main pollinators of the small cacao flowers. These midges visit the flowers to feed on nectar and pollen, which provides energy to the insects and helps females in egg production. While moving from flower to flower to feed, they transfer pollen between flowers from different trees, and increase fruit production. From this perspective, we need to thank these midges for the delicious chocolate we eat and drink!

And this is where planting trees relates to pollination. These midges prefer to develop on humid and shady environments, using leaf litter as a laying site. Making the soils shadier and increasing their leaf residues, agroforestry practices in cacao plantations directly benefit midges’ populations… and cacao production! Thus, through increasing the diversity of trees in these plantations, farmers can both make the soils provide nutrients for the plants to grow, and maintain large midge populations that ensure the effective pollination of cacao flowers. Isn’t it impressive what we can accomplish when we work with nature? And I mean, isn’t chocolate worth it?

Happy Holidays, everybody!

By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí.

Vanilla and food: not plain when it comes to pollination

November 9, 2020Maryland Grows2 Comments

You decide to bake some cookies. You have your butter stick ready to go, you open your pantry to look for the ingredients. There is flour, oats, sugar, chocolate chips; things look good. You then realize that you’re missing that one ingredient, the one that makes it all come together: vanilla! Luckily, you can quickly buy some fresh vanilla pods or vanilla extract. In a couple hours you are there, enjoying your cookies and the pretty fall landscape.

This is all good, but have you ever thought how that spice – vanilla – gets to your pantry? And who is allowing for that to happen? In today’s blog, the second in our comfort food series (part 1 is here), we will talk about this spice that is so present in our lives that we may not even think about it. Let’s talk about vanilla and how appreciating it is tightly linked to understanding pollination and the key role of pollinators in our food system.

What is vanilla?

What we consume as vanilla is the fruit and the seeds of an orchid, the vanilla plant. This fruit comes in the form of a pod, and the tiny “dust” that comes off it is the hundreds of tiny seeds that this plant produces in each fruit. Vanilla orchids have a vine habit and in the wild are found clinging to trees in the forests of Central and South America. Considering this natural habit, all vanilla cultivation is done vertically, using different types of support.

vanilla plants — Vanilla orchids have a vine habit, and the pollination of their flowers leads to the development of the pods and the tiny seeds we consume. Photos: M. Paredes, M. Manners, Joy.

Although vanilla is now cultivated in several parts of the world, it is accepted that all cultivated varieties/species are Meso- and South American. Indeed, the plant species had been known to be selected and used by Natives of those regions prior to the arrival of Europeans in the New World, but it is only following that arrival that Europeans created a strong demand for the spice. From this respect, if we can today enjoy our yummy cookies and cakes (and more!), recognition is due to the ancient selection done by Aztecs, Totonac, and Mayas in the current Mexican territories.

vanilla vines and pods with a historical description about use — Each plant produces several pods that are harvested and dried before commercialization. Historical descriptions (here, from 1651) indicate that the plant we know today was cultivated by Natives in current Mexico, who called it “Tlilxochitl” or “black flower”. Images: Hernández (1651), Foam.

Today, vanilla is produced mostly in Madagascar, Indonesia, and Mexico, and is the second most valuable spice in the world (after saffron). Its production, however, experienced a bumpy road and still today goes through regular difficulties, which leads to extreme annual fluctuations in vanilla prices. In fact, vanilla plantations occur in regions regularly affected by extreme weather events, such as cyclones, which can destroy a whole year of production. These events lead to large variations in yield from year to year, leading to crazy changes in vanilla prices, going for example from $20/kg in 2010 to the current $350/kg.

How is vanilla produced?

Although vanilla became a European favorite quickly after it was first introduced to the continent, the production of vanilla pods remained elusive for a long time. Indeed, people realized very quickly that without active transfer of pollen to the stigma of the flower, the flowers would not develop into fruits (see how that works), and thus the much-searched-for vanilla beans would not develop at all!

In fact, after much observation of the plants in their natural habitat, people realized that their pollination required especially the visit of a group of bees restricted to the New World, the euglossines, or orchid bees. Restricted to South and Central America, these bees have strong associations with orchids, from which the males are known to collect floral scents they use for courting females (this is super fascinating, and worth a future blog post). Some species of this group of bees are currently suspected to act as pollinators of vanilla flowers in the wild. During their visits, they passively deposit pollen on the stigma of the flower, which leads to the vanilla bean development. Although these bees do pollinate, flower visits by these bees are not common, so even in regions with bee populations, fruiting rates remain relatively low.

bee approaching a vanilla flower — In their natural habitats, vanilla flowers are thought to be pollinated by beautifully metallic *euglossine* bees. Photo: Gil Wizen, www.gilwizen.com.

Adding to this, once vanilla was “discovered” by Europeans, it was introduced into a variety of colonial lands, especially to Indian Ocean islands (e.g., Madagascar, the Comoros, la Réunion) and to French Polynesia. However, and because as I said before, the pollinators of this plant are restricted to the Americas, vanilla production was not successful in those regions. Plants would flower, but the lack of pollinators would lead to virtually no pod production. This changed when a solution was found. Indeed, there had been some early attempts to develop human-based pollination methods, which were as complex as impossible to use. It was finally a slave from the Réunion Islands, Edmond Albius, who developed a simple method to pollinate the flowers by hand, helped with a stick and his own fingers. It was only after this method development that vanilla production could bloom (actually, fruit 😉) to reach its current extent.

hand pollinating a vanilla flower — Edmond Albius was the Réunion slave who revolutionized vanilla production, developing the hand-pollination method still currently used today across the globe. Photos: Antoine Roussin (1863), F. and K. Starr.

Although one may expect the techniques to have changed since the first development of this method, the vast majority of today’s global vanilla production is still hand-pollinated following Albius’ technique! In other words, the production of the second most valuable spice in the world is currently based on pollination done by hand. And this is what I wanted to stress today. We hear a lot about the importance of pollinators, but I feel that the case of vanilla is such a clear example of how important pollinators are to maintaining not just food supplies, but also global economies: take the pollinators away and you lose basically the whole vanilla bean production chain and market. Doesn’t that make you feel especially thankful for pollination and pollinators for that great flavor in your cookies?

Happy Thanksgiving to all!

By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí.

The buzz in your seasonal latte: Who pollinates the pumpkin spices?

October 12, 2020Maryland Grows4 Comments

Wow, fall is here. When did that happen?! And because this fall comes after a tortuous year, I want to spend time doing some soul pampering. It is for this reason that, until the end of the year, I will be talking about many of the yummy foods we love and that many times help us through rough times. And to start the series, and matching the fall season, let’s talk about how the spices that create “pumpkin spice” – cinnamon, nutmeg, ginger, cloves – go around getting pollinated and reproduced.

pumpkin spice products — How do you know it’s the fall in the US? We’re surrounded by pumpkin-spice
everything! Photos: PatentingPatch, M. Mozart, J. Kramer, theimpulsiveguy.

As a general introduction to these spices, we have to realize that they all originate outside of the US, and that most of them are even today not produced in the US. This is important to mention because it is humbling to realize how much our food habits (especially those related to comfort foods) are based on foods that are imported by the US. Further, even if that may seem futile, markets for these spices have been historically and are still currently huge, with power over these markets driving major geopolitical clashes, setting the foundations of the current global distribution of wealth, and sustaining (and sometimes undermining) societies around the world.

Cinnamon

The cinnamon we eat comes from the bark of cinnamon trees. This bark is either ground or consumed in strips, which are added to savory and sweet foods. Cinnamon trees originate in South Asia and are adapted to growing in wet tropical forests. Today, the most important cinnamon producer is Sri Lanka, and most of the exports go to the USA and Western Europe. Even though we do not eat the fruits of this plant, pollinators play a key role in their reproduction. Cinnamon flowers are poor “selfers,” meaning that they produce the most seeds if receiving pollen from a different flower. These flowers thus rely on insect pollinators for their reproduction (see this post for more details about how flowers function) and among the most abundant species are three Asian “cousin” species of the managed honeybee, as well as some flies.

Nutmeg

The nutmeg we consume is the seed of the fragrant nutmeg tree, which originates in Indonesia. Even though currently it is cultivated heavily in Indonesia and Malaysia, it is also produced in the Caribbean. Because the food we consume is part of the fruit of this tree (there is no nut if there is no fruit), pollination of this crop is central for food production — and this is a super-fun crop to learn about!

Indeed, only some nutmeg trees bear fruit, because half of the seeds of this plant produces male trees (which produce pollen) and the other half produces female trees (which will make fruits and nutmegs). The fun pollination story doesn’t end there, though. The flowers of these plants are tiny, bloom in the night, and need pollinators to transport the pollen from the male trees to the female flowers. So who does this job? A lot of insects! Studies in the species have demonstrated that most pollination is done by tiny thrips, and probably also some beetles, flies, and maybe some bees (here you can read about pollinators other than bees).

But let’s spice up (pun intended) this story! This plant is not only pollinated by uncommon types of pollinators; it also tricks them into pollinating! In fact, the insects are interested only in male flowers, where they can collect pollen they can feed on, and they do not care about visiting female flowers, which do not offer any pollen or nectar. Thus, the strategy used by female flowers to attract pollinators is to trick them by making them assume they are actually male flowers, a strategy known as “mistake pollination”. It’s only after they entered the female flower and deposited pollen on the stigma that the insects realize their mistake.

Ginger

The part of the plant we consume from ginger is its rhizome, meaning that one can plant the piece of ginger one buys in the store and one would grow a ginger plant! This plant species also originated from the Southeast Asian archipelago. The plant is easy to grow, and thrives in warm climates, but most of the world production is currently from India. Under production conditions, ginger is multiplied through the planting of rhizomes, meaning that most of the production is not based on seeds. For this reason, the pollination of this species was not of high production interest until only recently. Indeed, while ginger propagation is based on rhizomes, this does not allow for the use of sexual reproduction for the development of better new varieties that may be resistant to diseases or pests. Recent studies indicated that ginger is extremely hard to pollinate because pollen has a low rate of successful pollination, leading to very low seed success. Several researchers are now focusing on identifying its pollinators, so stay tuned to know more!

Cloves

As with most other spice plants treated here, cloves also come from a tree, which originates from the Moluccas, in Indonesia. While the plant originates in those islands, most of clove production is currently from Indonesia and Madagascar. The part of the plant consumed is the flower buds, which are harvested and then dried to produce the spice we buy. Although we consume the flowers, these plants still require seed production to reproduce, and this is central to maintaining clove production. Because the plant can self-pollinate but its genetics are improved by cross-pollination, pollinators are very important for its reproduction. Here, again, pollination is not very well known, but flies, bees, and some butterflies are suspected to play an important role in transferring pollen, as it has been observed in a closely related (but not cultivated) species.

Note: this blog post is dedicated with love to Luke Harmon, who despises Pumpkin Spice. <3

By Anahí Espíndola, Assistant Professor, Department of Entomology, University of Maryland, College Park. See more posts by Anahí.