1. LON-CAPA Logo
  2. Help
  3. Log In
 


 

Section 8

Table of Contents

Section 10

 

9. Branching patterns of herbaceous plants

In spite of its simplicity, the simple model of a compound leaf shown in Plate 13 properly reflects one of the general principles of the development of higher plants.

It is called the principle of subapical growth, and means that only apices can create new branches. Internodes may elongate, but cannot initiate branches. These rules are illustrated schematically in Plate 14.

A variety of structures can be produced through subapical growth, depending on which apices remain active and initiate new branches, and which ones do not. In line with the research interests of Lindenmayer and other biologists using L-systems, this section focuses on the modeling and simulation of the inflorescences of herbaceous plants. For a more complete description see Chapter 3 of [Pru1990]

The simplest case occurs when only the apex of the main axis of the growing plant produces new branches, as shown in Plate 15.

These lateral branches carry buds and then flowers, but do not branch any further. The resulting structure is called a monopodial branching structure, and the corresponding inflorescence is called a raceme. Plate 16 illustrates the development of a common weed Capsella bursa-pastoris, or shepherd's purse, following this principle.


The creeping bellflower Campanula rapunculoides, presented in Animation 9, develops in the same manner.



Additional views of this development are included in Animation 10, which combines models of several plants in a single scene, and Animation 11, which presents a view of the flowers.


Plate 17 shows a form of branching which, in a sense, is opposite to the previous one. In this case, called sympodial branching, the apex produces a flower bud terminating the development of the current axis, but in addition produces one or more active lateral apices. This process repeats recursively, with the main thrust of the development always going into the lateral branches.

The resulting inflorescence type is called a cyme. The development of Lychnis coronaria, or rose campion, shown in Animation 12 and Animation 13, provides a good example of the described process.


Animation 14 presents a view of the development of a single flower.


Yet another branching type, called polypodial branching, is presented schematically in Plate 18.

In this case, both the apex of the main axis and the lateral apices produce new branches until, at some point in time, the apices undergo a developmental switch and are transformed into flower buds. The resulting inflorescence, called a panicle, may adopt various forms depending on the geometric parameters.

For example, Plate 19) shows a so-called decussate branching pattern, in which pairs of lateral branches are arranged in mutually perpendicular planes.

By terminating each of these branches with a flower we can model lilac inflorescences, as presented in Plate 20.