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Most, following a juvenile phase, are rooted or fixed, not motile, and both their structure and their precise programme of development are not predictable but ‘indeterminate’. After several years’ growth, depending on circumstances, the same germinating tree seed could either give rise to a stunted sapling with a handful of leaves or a thriving young tree with many branches and thousands of leaves. It is modularity and the differing birth and death rates of modules that give rise to this plasticity. Reviews of the growth, form, ecology and evolution of a wide range of modular organisms may be found in Harper et al. (1986), Hughes (1989) and Collado‐Vides (2001).

Photos depict modular plants (left) and animals (right) show the underlying parallels in the various ways they may be constructed. (a) Modular organisms that fall to pieces as they grow: duckweed and Hydra sp. (b) Freely branching organisms in which the modules are displayed as individuals on stalks. (c) Stoloniferous organisms in which colonies spread laterally and remain joined by stolons or rhizomes: strawberry plants reproducing by means of runners, and a colony of the hydroid Tubularia crocea. (d) Tightly packed colonies of modules: a tussock of yellow marsh saxifrage, and a segment of the sea fan Acanthogorgia. (e) Modules accumulated on a long persistent, largely dead support: an oak tree.

      what is the size of a modular population?

      It follows from this that in modular organisms, the number of surviving zygotes (individuals in a genetic sense) can give only a partial and misleading impression of the ‘size’ of the population. Kays and Harper (1974) coined the word genet to describe this ‘genetic individual’ – the product of a zygote – and we can see that in modular organisms, the distribution and abundance of genets is important, but it is often more useful to study the distribution and abundance of modules (ramets, shoots, tillers, zooids, polyps or whatever). The amount of grass in a field available to cattle is not determined by the number of genets but by the number of leaves (modules).

      4.2.2 Growth forms of modular organisms

      We can see how modular organisms grow by taking higher plants as a good example. The fundamental module of construction above ground is the leaf with its axillary bud (the bud emerging where the leaf meets the stem) and the attendant section of stem. As the bud develops and grows, it produces further leaves, each bearing buds in their axils. The plant grows by accumulating these modules. At some stage in the development, a new sort of module appears, associated with reproduction (flowers in higher plants) and ultimately giving rise to new zygotes. Such specialised reproductive modules usually cease to give rise to new modules. The programme of development in modular organisms is typically determined by the proportion of modules that are allocated to different roles (e.g. to reproduction or to continued growth).

      Depending on how they grow, modular organisms may broadly be divided into those that concentrate on vertical growth, and those that spread their modules laterally, over or in a substrate. Among plants that mostly extend laterally, many produce new root systems at intervals along the lateral stem: these are the rhizomatous and stoloniferous plants. The connections between the parts of such plants may die and rot away, so that the product of the original zygote becomes represented by physiologically separated parts. (Modules with the potential for separate existence are known as ‘ramets’.) The most extreme examples of plants ‘falling to pieces’ as they grow are the many species of floating aquatics like duckweeds (Lemna) and the water hyacinth (Eichhornia). Whole ponds, lakes or rivers may be filled with the separate and independent parts produced by a single zygote.

      Trees are the supreme example of plants whose growth is concentrated vertically. The peculiar feature distinguishing trees and shrubs from most herbs is the connecting system linking modules together and connecting them to the root system. This does not rot away, but thickens with wood, conferring perenniality. Most of the structure of such a woody tree is dead, with a thin layer of living material lying immediately below the bark. The living layer, however, continually regenerates new tissue, and adds further layers of dead material to the trunk of the tree. This solves, by the strength it provides, the difficult problem of obtaining water and nutrients below the ground, but also light, perhaps 50 m away at the top of the canopy.

      modules within modules

      We can often recognise two or more levels of modular construction. The strawberry (Figure 4.1c) is a good example of this: leaves are repeatedly developed from a bud, but these leaves are arranged into rosettes. The strawberry plant grows (i) by adding new leaves to a rosette and (ii) by producing new rosettes on stolons grown from the axils of its rosette leaves. Trees also exhibit modularity at several levels: the leaf with its axillary bud, the whole shoot on which the leaves are arranged, and the whole branch systems that repeat a characteristic pattern of shoots.

      Many animals, despite variations in their precise method of growth and reproduction, are as ‘modular’ as any plant. And in corals, for example, just like many plants, the individual may exist as a physiologically integrated whole, or may be split into a number of colonies – all part of one individual, but physiologically independent (Hughes et al., 1992).

      4.2.3 Senescence – or the lack of it – in modular organisms

Schematic illustration of the compilation of patterns of mortality and reproduction from across the plant and animal kingdoms from reproductive maturity to the age where only 5% of the adult population is still alive. To emphasise variations in pattern, mortality and fertility are scaled relative to their means. Survivorship is plotted on a log scale. The plots are arranged in order of decreasing mortality at the terminal age.