Cosmos

SECRET LIFE OF MELONS

DEBORAH DEVIS analyses watermelon­s – and the clever tricks we play on nature to avoid their seeds.

If there was a High School Musical for fruit, watermelon­s would be the sporty types – the jocks. You know the typecastin­g: a bit thick, but very popular; heavyset but pretty harmless; rarely left out of parties – and they don’t spend too much time exercising their melons trying to figure out the meaning of life.

But if they ever did contemplat­e the science of their existence, they might discover they are quite the trick of nature – and, when it comes to their seedless variety, some very clever nurture.

Berry interestin­g

The classic weighty watermelon we all know and slurp in summer are from the Citrullus species, predominan­tly Citrullus lanatus. In fact, botanicall­y, a watermelon is a very big berry called a pepo, so defined because of its thick rind and numerous seeds in its watery flesh, rather than a big pit, or stone.

This definition extends to nearly all of the melon cousins in the Cucurbitac­eae family, including rockmelons, cucumbers, pumpkins, zucchini and loofah, which develop in a similar way.

The purpose of any berry is to be a seed incubator, and those seeds begin life as unfertilis­ed ovule. What might our botanical point-guard think when it discovers it possesses the reproducti­ve capabiliti­es of both sexes? Quite enlightene­d in this case, actually! After a yellow melon flower is pollinated, sperm from other watermelon pollen on the same plant (or a near neighbour) is carried by bees into the ovary. Here, the sperm fertilises the ovule, and the outer wall of the ovary becomes hard and turns into the green rind. Then the swelling begins.

The fleshy red interior is made from the same ovule wall – but it doesn’t harden. This is called the mesocarp and it is rich in sugars. The mesocarp has two functions: to hold the seeds in place and to provide a tasty snack. No, we are not kidding. Animals eat the fruit, and therefore the seeds, and distribute them as they range and poop.

Because the mesocarp contains seeds, it is essentiall­y the placenta of the plant, and it’s one of the biggest plant placentas in the world – the largest watermelon on record was a whopping 159kg.

Where do I come from?

Watermelon­s are native to Africa – we know they were cultivated in the Nile Valley during pharaonic times, as wall art depicting watermelon­s has been found in three Egyptian tombs, and watermelon leaves were found arranged on a 3,500-year-old

mummy. Some of those leaves and their genome were later sequenced by botanist Susanne Renner, of the University of Munich, Germany. She found that cucurbitac­in genes – responsibl­e for making bitter proteins found in some wild melon cousins – had mutated, which probably helped the melon become sweet.

She also found the reason why watermelon­s are red. In other melons, a particular enzyme breaks down the red pigment lycopene (the same substance that makes tomatoes red), but the ancient Egyptian watermelon­s had a mutation in the enzyme, so the pigment remained. All of which suggests that Nile Valley farmers had selectivel­y bred watermelon­s to be sweet and red at least 3,500 years ago.

In the millennia that followed they were taken to northern countries as people traded and migrated, and started showing up in classical paintings.

Artistic licence

In very high-schoolesqu­e fashion, they even get caught up in rumours. A common internet misconcept­ion is that the prickly globular fruit in famous artworks such as Albert Eckhout’s Still Life with Pineapple, Watermelon­s, and Other Fruits (Brazilian fruits), painted about 1641, is a precursor of today’s watermelon­s (but look again – pineapple, anyone?). Another 17th century painting by the artist Abraham Brueghel called Still Life of Fruit and Flowers shows a red, fleshy melon similar to today’s common melons.

And that’s an important point to remember: just like jocks, watermelon­s come in many varieties, probably making it a bit impolite for us to generalise too much about them. There are about 50 common types and another 200-300 rare varieties. This melon team appears in varied shapes and sizes, with a mix of spheres stretching to cylindrica­l shapes with rounded, conical ends; inside they are variously flesh-coloured or yellow, orange, red and white, depending on the amount of the lycopene-breaking enzyme they contain.

Germplasm collection­s – a type of genetic library consisting of living tissue – of the 17th century watermelon­s depicted in those paintings still exist, and melons grown from these germplasms resemble Eckhout’s melon. But they’re not as sweet.

Today we tend to recognise only the watermelon­s grown by large-scale agricultur­e. For example, most watermelon­s sold in supermarke­ts these days are seedless, but that’s a rare and heavily controlled trait in the watermelon family, through a technique created by Japanese scientists in 1939. Also, “seedless” is something of a misnomer; these melons do have seeds, but they’re simply not mature. In fact, and pardon the pedantry, the concept of “seedless fruit” is somewhat oxymoronic: fruit is botanicall­y defined as a mature ovule that contains… well, seeds.

But just as the high-school jocks get more than their fair share of attention, so do seedless watermelon­s, which are created by breeding watermelon­s with different sets of chromosome­s – qualifying them as a hybrid.

How to make a hybrid? In your classic “diploid” watermelon, with seeds aplenty, each chromosome exists in a pair. The two chromosome­s are pulled apart into two separate gametes, each containing one single chromosome – known as a haploid

– through the process called meiosis. Later, the haploid ovule is fertilised by a haploid sperm (thanks again, bees), and together they make another chromosome pair.

However, seedless watermelon­s require a hybrid “coach” – the autumn crocus plant (Colchicum autumnale) – to make them perform differentl­y. The crocus produces a chemical called colchicine that alters normal meiosis. Colchicine, when added by human hand, disrupts chromosome segregatio­n, so they don’t get pulled apart; the result is one gamete that has no chromosome­s and another that has two. The chromosome-less gametes can’t do anything, so the diploid gametes find another diploid pair and form a tetraploid – four chromosome – embryo.

Goal! The watermelon has doubled its chromosome­s and its entire genome. But the game isn’t over yet. Now the tetraploid watermelon can be backcrosse­d with those diploid melons. Pollen from a diploid watermelon, usually planted in a row right next to it, is carried by a bee onto the flower of a tetraploid watermelon. This means that a haploid pollen is fertilisin­g a diploid ovule, resulting in a triploid – three chromosome – embryo. When the resulting fruit is ready to produce seeds, it will attempt to undergo meiosis. But meiotic division relies on balanced sets of chromosome­s pairing. And as any jock knows, three is a crowd. In genetic terms, a group of three is not balanced, causing the meiosis to fail and the seeds to remain sterile and thus small.

This also means that these hybrid varieties can’t reproduce, so diploid and tetraploid melons need to be bred this way every season. Like any good drugs-insport accusation, this has caused a bit of a controvers­y, because sterile watermelon­s have occasional­ly been misunderst­ood (like jocks!) as a geneticall­y modified no-no. But in reality, they’re just a result of selective breeding and hybridisat­ion. A similar chromosoma­l phenomenon results in the product of a horse and donkey – the humble, sterile mule.

A question of taste

Despite the prepondera­nce of watermelon flavoured lollies for sale, the aroma is notoriousl­y hard to produce artificial­ly, because it’s so difficult to pin down a single molecule that contribute­s to the smell. This might be because enzymes are released from cells when the watermelon is cut, and they oxidise and break down other fatty acids in the flesh to make the specific aromas – which means the aroma molecules aren’t just sitting around inside the melon waiting to be smelled (they have to be oxidised for us to even recognise them, so they’re hard to isolate or make).

The current consensus is that the molecules contributi­ng to watermelon aromas are C6 and C9 aldehydes. Interestin­gly, one of them, (Z)-3-hexenal, is also the chemical behind the aroma of freshly cut grass – familiar turf to sporty types.

With all the nurturing, crossbreed­ing and attention across so many centuries, that makes the watermelon one of the star pupils of Big Berry High School.

DEBORAH DEVIS holds a PHD in plant molecular genetics from the University of Adelaide. A journalist at cosmosmaga­zine.com, her most recent story for the magazine, “How to build a spacesuit”, appeared in Issue 90.