HOW TO READ THE TREE LEAVES
A LITTLE KNOWLEDGE OF BOTANY CAN BE HELPFUL, EVEN IF YOU’RE AN AMATEUR GARDENER
What’s going on out there — and why? Some version of that is the perennial question on any inquisitive gardener’s mind. Autumn provides plenty of dramatic subject matter along those lines, beyond the changing leaves. What is it exactly that gives the foliage of deciduous trees the signal to let go (except in the case of contrarians like certain oaks and beeches)?
Although we call them evergreens, the inner needles of many conifers show us otherwise each autumn. Why do they turn noticeably yellow and brown, in preparation for shedding?
And as the deep, cold of a northern winter approaches, what gardener does not wonder how dormant buds and other tender-looking parts of plants survive intact?
A hunger to explain such phenomena led me to a beginning botany course and its accompanying textbook. In the decades since, I have revisited those lessons time and again.
Apparently, I am not alone in my search for answers. The textbook used in that course, Brian Capon’s Botany For Gardeners: An Introduction To The Science Of Plants, has sold more than 260,000 copies since it was published in 1990. In August, the fourth edition was released.
And the course itself, Introduction to Plant Science, is now given year-round at the New York Botanical Garden, virtually and in person, with up to 12 sessions a year and as many as 20 students in each. It is one of more than 700 annual offerings in subjects as diverse as botanical illustration, landscape design, psychedelic mushrooms and paleobotany — all part of the nation’s largest plant-focused adult continuing-education programme.
Perhaps my biggest takeaway from the classes I attended: Putting some botany into our horticulture can help improve results in the garden. But best of all, it deepens our appreciation of how plants live their hard-working lives.
BATTEN DOWN THE HATCHES: DORMANCY
Dormancy is a “virtual metabolic standstill”, wrote Capon, who died last year but was a professor of botany at California State University, Los Angeles, for decades.
In the temperate zone, “it’s an ecological adaptation for living in a cold environment, to survive the cold”, said Regina Alvarez, an assistant professor of biology at Dominican University New York, in Rockland County, and one of New York Botanical Garden’s botany instructors. “Depending on the life cycle and the form of the plant, they do it in different ways.”
Herbaceous plants have two choices: They can complete their life cycles and leave only their seeds behind for the following year (annuals), or their aboveground portions can die back, leaving the roots and storage organs like rhizomes, bulbs and corms to carry on when favourable conditions resume (biennials and perennials).
But woody plants can’t completely tuck in like that. Even those that drop their leaves as part of their overall defence have parts that remain exposed. Those include organs as small and seemingly vulnerable as the buds of next year’s leaves and flowers, or the growing tips of twigs and branches where elongation will resume again come spring.
In preparation, the undeveloped flowers, leaves or shoots may become encased in overlapping bud scales every autumn. Some species may also coat the covered buds in “a thick resin to protect them from the cold and wind”, said Leslie Day, the author of urban-focused natural history guides, including Field Guide To The Street Trees Of New York City, and a plant-science instructor at the botanical garden.
THE COLOURING UP, AND THE LETTING GO
We watched the recent show, as shorter days and cooler weather triggered the breakdown of chlorophyll, the predominant pigment in most leaves. What was unmasked are known as the accessory pigments, Alvarez said, including yellow and orange carotenoids that were there all along, in a supporting role. Although hidden during the growing season, they were helping with photosynthesis.
The anthocyanin pigments that we perceive as red and purple in dogwoods, sumacs or red oaks, however, weren’t hiding. They are produced in fall, products of a chemical change involving an increased concentration of sugars in the leaves.
Then — no matter the colour, but all too soon for our liking — the foliage on most deciduous trees takes flight. The big event’s timing is determined by changing chemistry in the tiny abscission zone, a narrow band of cells at the base of each petiole, or leaf stalk, where it attaches to the stem or branch.
“None of this would happen without the plant hormones,” Day said.
Which hormone is at work in leaf drop? Not abscisic acid, the one that “abscission zone” would seem to imply. That hormone tells the plant to form the bud scales, to stop certain aspects of growth ahead of dormancy and even to keep the seed dormant until the time is right for germination, Day said.
It is now understood instead that ethylene — better known for its role in ripening fruits — is the catalyst. (Fruit and flowers, with their own specialised abscission zones and timing, are likewise influenced by ethylene on when to drop.)
“It starts to break down the cell membranes and form this zone where the leaf eventually can just fall,” Day said, “sealing itself off and leaving a scar on woody plants.” A thin cork layer forms to prevent water loss and fungal invasions.
The outline of each scar forms a shape like an oval or a heart, Alvarez said. Dots inside that outline mark where the plant’s vascular tissues, the xylem and phloem, were connected, and conducted fluids between stem and leaf.
WHEN LEAVES DON’T FALL (AT LEAST NOT RIGHT AWAY)
How can so much be governed by such a microscopic piece of real estate?
“The restriction of ethylene’s destructive effects only to cells in the abscission zone illustrates the precise control plants exercise over their hormone systems,” Capon wrote.
Nowhere is this engineering prowess more astounding than in the deciduous trees and shrubs that hold onto their dead leaves all winter, only to release them in spring. To accomplish that, they must manage to keep just that attachment point up and running — the junction of a dead leaf and a dormant twig. Preposterous.
The trait, called marcescence, is common to some witch-hazels (Hamamelis) and certain hornbeams (Carpinus), beech (Fagus) and oaks (Quercus), especially in the lower branches and in younger trees.
Scientists hypothesise that the persistent leaves may have developed long ago, as an adaptation against browsing by large animals the plants evolved alongside. A mouthful of dead leaf is a less-tasty target than a bare twig and tender buds, something today’s deer also seem to understand.
A bonus design tip for gardeners: A row of marcescent trees, although not technically evergreen, makes for an effective, nearly year-round screen.
THOSE YELLOW AND BROWN INNER CONIFER NEEDLES
For something evergreen, we often turn to conifers — although they aren’t technically evergreen. Their often narrow foliage is winter-adapted: less vulnerable to the effects of ice, snow and wind than broader leaves, and coated in a waxy substance that guards against the elements.
“They’re always green,” Alvarez said, “but that doesn’t mean it’s always the same needles.”
When she worked for the Central Park Conservancy, Alvarez heard the question regularly starting in the early autumn, when the inner foliage of many conifers turned yellow and brown. “What’s wrong with the trees?” visitors wanted to know.
As part of their life cycle, conifers undergo leaf drop, too. But it’s a sequential one — not an annual process like that of deciduous trees, and not to be confused with discoloured foliage throughout the tree or at the branch tips at other times, which may indicate disease or injury.
PUTTING SOME BOTANY INTO OUR HORTICULTURE CAN HELP IMPROVE RESULTS IN THE GARDEN