Wednesday, March 31, 2010

Botanical Flypaper

The tiny insect in the photo above, just a couple of millimetres long, is doomed. Its body and wings are held fast by the sticky leaf hairs of.....
.... this plant, a butterwort Pinguicula moranensis that originates from Guatemala and Mexico. Like all butterworts, it captures small insects on its leaf surface and then, when they die of exhaustion, slowly digests them.
Almost the whole of the plant surface is covered with these minute stalked hairs, of varying heights for maximum trapping efficiency,each tipped with a droplet of sticky mucilage.
Seen here at higher magnification and in side view, each bottle-shaped hair is composed of a single cell rising from one of the surface epidermal cells, topped with a glandular cap that at higher magnification still...
... is revealed to be made up of eight separate secretory cells, each shaped like a slice of cake, perched on the top of the stalk. Meanwhile, down below and embedded in the leaf surface.......
... there's a different kind of gland, seen here in surface view amongst the jigsaw puzzle-shaped epidermal cells of the leaf. Each leaf upper surface is studded with hundreds of these glands. Once and insect is trapped the glands nearby........
..... like this one, seen here in side view at higher magnification, secrete digestive enzymes. When the insect finally dies....
... it collapses into the pool of digestive enzymes and is slowly dissolved, until only its outer chitin exoskeleton remains, like a ghost of the plant's victim. Then the plant absorbs the resultant 'soup', rich in the essential nitrogen that's lacking in this carnivorous plant's boggy habitat. However, not all insects succumb so easily. The plants in my conservatory almost always host...
... small colonies of to these tiny aphids. Even though they are held fast, they can still use their piecing mouthparts to puncture the plant's cells and feed, and survive long enough to produce the next generation of young, which are born by virgin birth (parthenogenesis) without the need for mating.  If you double-click on this image for a larger view you'll see a pair of minute claws at the tip of each aphid leg. On most host plants these would allow the aphid to grip the plant surface and walk, but the epidermal cells of butterwort are so smooth and slippery that the claws cannot grip. If you watch under a microscope, you can see the claws simply sliding over the plant surface, so the anchored aphid can do nothing other than feed and breed before it eventually dies, leaving a ghostly shell and a clone of itself behind.


Butterworts' flypaper-like properties make them very useful plants to grow if you are troubled by the tiny mushroom flies that emerge from potting composts - a single plant will trap and kill scores of them.

Sunday, March 28, 2010

Grey Killer

Spring is a rollercoaster ride of hope and despair for gardeners, as tender new seedlings run the gauntlet of frosts, pests and diseases. This fungus, grey mould Botrytis cinerea, is one of the worst killers of plants grown in poorly ventilated, cold clammy greenhouses. Initially, it usually colonies dead or damaged plant tissue like last season's leaves or stems ....

... producing a furry coating for spore clusters on short aerial hyphae.
The fungus can produce these clusters of spores, known as conidiospores, in vast numbers, and at higher magnification you can see...
... that each hyphae is branched at the tip. You can also see the cross-walls in the hyphae that indicate that this is an ascomycete fungus
At high magnification the tip of the hypha can be seen to branch, with clusters of spores at the end of every branch....
... that are dispersed on the breeze as a grey cloud when infected plants are disturbed. Grey mould is a major killer of plants but paradoxically it does have its uses. Grapes that are infected with 'noble rot' - as the fungus is known in viticultural circles, produce a much more intense flavour, as the fungus withdraws water from the grape and concentrates the flavour..... a property that's exploited in the production of sauternes dessert wine.

Sunday, March 21, 2010

Anticlockwise tubeworms

The calcareous spiral tubes of tubeworms, attached to wracks and kelps that are washed up on the strandline, are a common sight on the seashore. There are several different species and the first step to identification is to see whether the tube coils clockwise or anticlockwise. If it's clockwise, then it'll be a species of Spirorbis but if it's anticlockwise, like these, and the tube has three distinct ridges, then it's a worm called Janua pagenstecheri. The coiled tube is about 2mm. in diameter.
If you watch the live worm under the microscope it soon everts its crown of transparent feeding tentacles. If you look just to the right of the tentacles you can see a brown, translucent flap. This has a dual function, closing off the tube when the worm withdraws its tentacles and acting as a brood chamber for the worm's embryos. The pink encrustation in front of the worm is a alga, not part of the animal.

Tuesday, March 16, 2010

Fungal Artillary


Most fungi tend to be associated with autumn but there are a number of perennial species that can be found at any time of year, including this one - variously known as King Alfred's cakes, cramp balls or Daldinia concentrica. The first name refers to King Alfred's culinary accident while hiding from marauding Danes in the humble abode of a cowherd; the second refers to the folklore that carrying this fungus around in your pocket stops you getting cramp in the legs (doesn't work for me); the last refers to .....

.... the concentric rings of annual growth that you can see if you cut the fungus open.
The blackened surface of the fungus is covered with scores of these 'pimples', each with a pore in the centre. Each leads to a chamber below, packed with tubular flask-shaped fungal hyphae called asci, each with eight ascospores inside. Cut one of these chambers (in mycological parlance a perithecium) open and this....
... is what you see under the microscope - rows or rugby-ball shaped spores, seen here at around x100 magnification and ....


.... here at x400 magnification. In spring each ascus of eight ascospores elongates in turn, until its tip protrudes from the pore in one of those surface 'pimples', like a cannon protruding from the gun port of a man 'o war. Pressure builds inside the ascus until it ruptures and fires out its salvo of spores. Then it withers, another elongates to take its place and the discharge is repeated. This can go on for 6-7 weeks before all the asci have fired their broadsides, with most of the spore discharge taking place at night. You can watch this by placing the fungus in a light beam in a warm room - if you've got sharp eyes you can see what look like little puffs of smoke all over the surface - the fungus firing its silent broadsides. In England Daldinia concentrica mostly grows on ash trees but in Scotland it also grows on birch.

Sunday, March 7, 2010

Another Living Jewel


My last post showed a jewel-like case made by a single-celled amoeba. This one shows the remarkable case made by a marine worm.  We found this little tapered tube, about 5 cm. long, on the sandy beach at Warkworth in Northumberland this afternoon. It was made by a worm called Pectinaria koreni and when the animal inside is alive only the last few millimetres of the narrow end of the tube protrudes above the sand. The worm lives head-down in the sand, drawing in a current of water through the narrow end of the tube.


You can see the dark zone at the narrow end here - that's the bit that normally protrudes above the sand. The tube is made up of hundreds of sand grains and minute shell fragments, selected for smoothness inside and outside the tube and ....


.... neatly fitted together with a degree of precision that a stonemason would envy....

 

.... and although the tube is only one sand grain thick it's remarkably strong. That's because....



... the worm secretes a form of cement that glues the grains together, like mortar in a wall ......


.... as you can see here at higher magnification.



A pair would make rather fine ear-rings, provided the wearer didn't have any qualms about wearing jewellery made by a worm rather than by a jeweller.

You can see a picture of the worm here.