Introduction

1 Plant growth and development

This book is about how plants interact with their environment. In Chapter 2 to 4 we consider how they obtain the necessary resources for life (energy, CO2, water and minerals) and how they respond to variation in supply. The environment can, however, pose threats to plant function and survival by direct physical or chemical effects, without necessarily affecting the availability of resources; such factors, notably extremes of temperature and toxins, are the subjects of Chapters 5 and 6. Nevertheless, whether the constraint exerted by the environment is the shortage of a resource, the presence of a toxin, an extreme temperature, or even physical damage, plant responses usually take the form of changes in the rate and/or pattern of growth. Thus, environmental physiology is ultimately the study of plant growth, since growth is a synthesis of metabolic processes, including those affected by the environment. One of the major themes of this book is the ability of some successful species to secure a major share of the available resources as a consequence of rapid rates of growth (the concept of pre-emption or 'asymmetric competition'; Weiner, 1990).

When considering interactions with the environment, it is useful to discriminate between plant growth (increase in dry weight) and development (change in the size and/or number of cells or organs, thus incorporating natural senescence as a component of development). Increase in the size of organs (development) is normally associated with increase in dry weight (growth), but not exclusively; for example, the processes of cell division and expansion involved in seed germination consume rather than generate dry matter.

The pattern of development of plants is different from that of other organisms. In most animals, cell division proceeds simultaneously at many sites throughout the embryo, leading to the differentiation of numerous organs. In contrast, a germinating seed has only two localized areas of cell division, in meristems at the tips of the young shoot and root. In the early stages of development, virtually all cell division is confined to these meristems but, even in very short-lived annual plants, new meristems are initiated as development proceeds. For example, a root system may consist initially of a single main axis with an apical meristem but, in time, primary laterals will emerge, each with its own meristem. These can, in turn, give rise to further branches (e.g. Figs. 3.20, 3.22). Similarly, the shoots of herbaceous plants can be resolved into a set of modules, or phytomers, each comprising a node, an internode, a leaf and an axillary meristem (Fig. 1.1). Such branching patterns are common in nature (lungs, blood vessels, neurones, even river systems); in each case, the ‘daughters’ are copies of the parent branches from which they arose.

The modular mode of construction of plants (Harper, 1986) has important consequences, including the generalization that development and growth are essentially indeterminate: the number of modules is not fixed at the outset, and a branching pattern does not proceed to an inevitable endpoint. Whereas all antelopes have four legs and two ears, a pine tree may carry an unlimited number of branches, needles or root tips (Plate 1). Plant development and growth are, therefore, very flexible, and capable of responding to environmental influences; for example, plants can add new modules to replace tissues destroyed by frost, wind or toxicity. On the other hand the potential for branching means that, in experimental work, particular care must be exercised in the sampling of plants growing in variable environments: adjacent pine trees of similar age can vary from less than 1 m to greater than 30 m in height, with associated differences in branching, according to soil depth and history of grazing (Plate 1). Such a modular pattern of construction, which is of fundamental importance in environmental physiology, can also pose problems in establishing individuality; thus, the vegetative reproduction of certain grasses can lead to extensive stands of physiologically-independent tillers of identical genotype.

Even though higher plants are uniformly modular, it is simple, for example, to distinguish an oak tree from a poplar, by the contrasting shapes of their canopies. Similarly, although an agricultural weed such as groundsel (Senecio vulgaris) can vary in size from a stunted single stem a few centimetres in height with a single flowerhead, to a luxuriant branching plant half a metre high with 200 heads, it will never be confused with a grass, rose or cactus plant. Clearly recognizable differences in form between species (owing to differences in the number, shape and three-dimensional arrangement of modules) reflect the operation of different rules governing development and growth, which have evolved in response to distinct selection pressures. For example, the phyllotaxis of a given species is a consistent character whatever the environmental conditions. The rules of ‘self assembly’ (the plant assembling itself, within the constraints of biomechanics, by reading its own genome or ‘blueprint’) are still poorly understood (e.g. Coen, 1999; Niklas, 2000).

Where the environment offers abundant resources, few physical or chemical constraints on growth, and freedom from major disturbance, the dominant species will be those which can grow to the largest size, thereby obtaining the largest share of the resource cake by overshadowing leaf canopies and widely ramifying root systems – in simple terms, trees. Over large areas of the planet, trees are the natural growth form, but their life cycles are long and they are at a disadvantage in areas of intense human activity or other disturbance. Under such circumstances, herbaceous vegetation predominates, characterized by rapid growth rather than large size. Thus, not only size but also rate of growth are influenced by the favourability of the environment; where valid comparisons can be made among similar species, the fastest-growing plants are found in productive habitats, whereas unfavourable and toxic sites support slower-growing species (Fig. 1.2).

The assumption (Box 1) that the growth rate of a plant is in some way related to its mass, as is generally true for the early growth of annual plants, is dramatically confirmed by the growth of a population of the duckweed Lemna minor in a complete nutrient solution (Fig. 1.4). The assumption is, however, not tenable for perennials. For example, the trunk of an oak tree contributes to the welfare of the tree by supporting the leaf canopy in a dominant position, and by conducting water to the crown, but most of its dry matter is permanently immobilized in dead tissues, and cannot play a direct part in growth. If relative growth rate were calculated for a tree as explained in Box 1, then ludicrously small values would result. Alternative approaches have been proposed, for example excluding tissues which are essentially non-living, but these serve to underline the ecological limitations of the concept. All plants use the carbohydrate generated by photosynthesis for a range of functions, such as support, resistance to predators and reproduction, with the result that growth rate is lower than the maximum potential rate; indeed such a maximum would be achieved by a plant consisting solely of meristematic cells. It is no accident that the fastest growth rate measured in an extensive survey by Grime and Hunt (1975) was for Lemna minor, a plant comprising one leaf and a single root a few millimetres long; or that the unicellular algae, the closest approximations to free-living chloroplasts, are the fastest-growing of all green plants.