THE PRINCIPLE OF COHESION. 55 



otbers, wLile supernumerary cords can be formed, Avhicli 

 appear to have for their function to strengthen the calyx to 

 meet the strain upon it when an insect ab'ghts upon the 

 flower. 



In the calyx of some species of Salvia, which is strongly 

 bi-lobed, though retaining its five teeth, three dorsal ((J) 

 are posterior and two are anterior. There 

 are two single marginal (m) cords between 

 the three posterior and dorsal, which coi-re- j j 



spend to the mid-ribs of three sepals. Tlie m 917 



two lateral and marginal cords are each tti m 



double; while a supernumerary cord (5) lies ^^ '^ 



beneath the lip of the corolla between the 

 two anterior marginals. The accompanying 

 diagram of the sepaline cords of 8. Verhenaca will illustrate 

 the arrangement. 



The arrangement of the cords (m and s) shows that the 

 strain being greater on the anterior side, the calyx has, as 

 it were, stretclied in that direction, the two marginals having 

 separated so widely in front, as to require an extra cord (5). 

 The two lateral ones have not separated to so great an extent, 

 while on the posterior side, where little or no strain is felt, 

 the marginal cords have remained single. 



As the cord (s) shows how Nature can add a fibro-vascular 

 cord if required, so one or more can be subtracted by atrophy 

 Avhere no stress occurs. Thus the petals of the Composite 

 have no dorsal or median cords, the five sepaline only being 

 present below, but pass up the margins of the petals. Con- 

 versely, in the Primrose, the calyx, giving no support to the 

 corolla, has no marginal cords. 



The above diagram will represent the distribution of the 

 sepaline cords of S. glutinosa and other species, as well as 

 /S\ Verhenaca, but in S. pratensis the strain has apparently 



