BIOTROPIA No. 7, 1994: 30-40 

NOTES ON SOME GROWTH CHARACTERISTICS OF MIKANIA CORD AT A 

(BURM. F.) B.L. ROBINSON*) 

B.T. MERCADO 
Institute of Biological Sciences, University of the Philippines at Los Banos, 

College, Laguna, Philippines 

ABSTRACT 

Mikania follows a sympodial dichotomy pattern of branching. Both stem (branches) and leaves give rise to 

new plants with relative ease. Internodes also root easily but do not give rise to new plants. Flower formation and 

seed germination are strongly influenced by light. Numerous seeds are produced but only few are filled; still 

fewer are the seeds that germinate. The period from early emergence to about the 3-leafed stage is most critical 

for survival of the new plant. 

Keywords: Mikania cordata, Growth, Weed physiology 

INTRODUCTION 

Mikania cordata (Burm. f.) B.L. Robinson, a creeping woody perennial is popularly 

known by its local names of climbing hempvine and mile -a-minute plant. It is described 

systematically in the compendium of the World's Worst Weeds (Holm et al. 1977). 

The stem (and its branches) and the mature leaves easily form roots when these come in 

contact with the soil (Figs, la & b). The leaves on the creeping stem or branch are strongly 

negatively geotrophic. If a portion of the stem or branch is twisted to bring the leaves to face 

the soil, overnight the leaves would be upright, held up by the petioles that had curved 

upward (Fig. 2). 

Pattern of branching 

Branching follows a sympodial dichotomy (Fig. 3). The stem produces a terminal 

shoot which dries up after some time. At its closest node emerges the first pair of branches 

which elongates. On these branches are borne several nodes. The 

*) The project was supported by a grant from the National Research Council of the Philippines (NRCP).  

30 



Notes on some growth characteristics of Mikania cordata - B.T. Mercado 

 

la Ib 

Fig.  1. New plants arising from stem (a) and leaf (b) cuttings 

 

Fig. 2. The upright bended petioles and nodal roots pointing upward indicate the strong negative geotrophic 

characteristic of leaves and stem 

31 



BIOTROPIA No. 7, 1994 

  

Fig. 3. The sympodial dichotomous branching in Mikania. The numbers indicate approximate length of the 

branches 

axillary buds on these nodes emerge to form new shoots. In most cases however, only one 

of the pair develops into a new branch, on whose nodes again emerge pairs of shoots, again 

with only one of the pairs elongating into new branches. This pattern is repeated thereafter, 

ultimately resulting in the entangled mass of branches which may be circular to the right or 

circular to the left (Holm et al. 1977). The terminals of the main branches, on the other 

hand, die off after some time, permitting the side branches to elongate rapidly. Thus this 

pattern of branching makes possible the continuous growth and rejuvenation of the plant. 

With time the stem progressively becomes woody. Considering the numerous branches 

formed, and the bulk of leaves borne by these branches, this growth pattern allows the 

plant to produce a dense mat of foliage in quite a short time. 

32 

 

144.2 



Notes on some growth characteristics of Mikania cordata - B.T. Mercado 

Rate of stem elongation of plants from leaf and stem cuttings 

 

The data in Figure 4a represent the observations from 10 plants grown from leaf cuttings, 
while those in Figure 4b, from 13 plants grown from stem cuttings. In both cases, the 

first branch that came out from the rooted cutting was tagged for the daily or weekly 

measurements. The branches of the leaf cuttings elongated much more rapidly than the 
similar branches of the stem cuttings. These were at its longest on the 26th day after the 

first measurement. These ceased to elongate after this date. Three (3) tagged branches of 

the stem cuttings died off 39 days after the initial measurement, while the rest, after the 
68

th
 day. 

 
 

 
 
Fig. 4 Rate of elongation of the first branch from leaf (a) and stem cutting (b) 

 

 

 

33 



BIOTROPIA No. 7, 1994 

Effect of sunlight on rate of stem elongation 

Three plants raised from seeds were grown under direct sunlight and another three 

plants, under partial shade. (A makeshift enclosure roofed by 2 layers of fishnets 

served this purpose). The plants were observed daily for 21 days after the 5-leafed stage. 

As before, the first branch that emerged was tagged and measured daily until the 

elongation of the branch decreased or stopped in any of the light treatments. 

Under partial shade (Fig. 5a) the branches elongated much more rapidly than those 

under direct sunlight (Fig. 5b). Its elongation continued even after the 20th day, while 

the elongation of branches under direct sunlight completely stopped on the 18th day after 

the initial measurement. The number of nodes borne on the tagged branches of both sets of 

plants did not differ very much from each other, although node count was slightly 

higher in the branches of the plants under partial shade. 

 
Fig 5. Elongation of the first branch from a seed-grown plant exposed to (a) partial shade and (b) direct 

sunlight 

 
 
34 



Notes on some growth characteristics of Mikania cordata - B.T. Mercado 

The biomass productions after a six-month growth period under partial shade or direct 

sunlight of plants grown from cuttings are given in Table la (stem cutting) and in Table 1b 

(leaf cutting). In both light treatments, the shoot dry weight of the plants under partial 

shade was 2-5 times higher than those of the plants grown under direct sunlight. Light 

apparently did not influence the dry matter production of the roots. Surprisingly, however, 

the root system of the plant was not profuse and long as might be expected of a plant 

capable of producing such dense vegetative growth (Fig. 6a). This may be due in part to the 

fact that the creeping stem or branch readily produces two kinds of roots: the usual nodal 

roots, and the internodal roots (Fig. 6b). Undoubtedly, anchorage as well as absorption of 

nutrients and water is a function well carried out by these stem-borne roots. There are 

not very many creeping plant species, succulent or woody, that develop internodal 

roots. 

On the whole, the plants grown under partial shade are much more vegetative, 

luxuriant and green than the plants grown under direct sunlight. The plants under partial 

shade remain vegetative. On the other hand, those which are exposed to sunlight start to 

flower in mid November until late January. Field observation also showed that even in the 

same plant, the shaded portion remains vegetative while the upper portion exposed 

directly to sunlight produces flowers profusely. 

The seed 

The seeds are elongated, 1.5-1.8 mm in length and about 0.3-0.4 mm at its 

widest. These are black, with a longitudinal ridge in the middle, tufted at one end with 

pappus (about 40 - 50 hairs). The pappus adds about 3.0 mm to the length of the seed. The 

seed is filled with white endosperm. Red ants are common foragers of ungerminated seeds. 
The seed dries up easily if kept in the open air. It has a very short period of viability. 

Table la.    Dry weight (g/p) of Mikania grown from stem cuttings under partial shade or direct sunlight (6 

Feb.-Sept. 1991) 

Plant 
 

                   Partial shade 
 

 

 

           Direct sunlight 
 

 

 
No. 
 

Shoot 
 

Root 
 

Shoot 
 

Root 
 1 

 
135.7 
 

3.2 
 

38.5 
 

2.2 
 2 

 
136.0 
 

2.3 
 

17.2 
 

1.4 
 3 

 
176.6 
 

3.1 
 

27.0 
 

2.1 
 4 

 
95.6 
 

2.2 
 

30.0 
 

3.0 
 5 

 
176.6 
 

1.4 
 

25.6 
 

1.4 
 

Average          144.1                                             2.44                                27.66                                  2.02 

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BIOTROPIA No. 7, 1994 

Table 1b.   Dry  weight (g/p) of  Mikania  grown   from  leaf  cuttings  under  partial  shade  or direct sunlight 

(11 March-9 Sept. 1991) 

Plant 
 

                 Partial shade 
 

 

 

                  Direct sunlight 
 

 

 No. 
 

Shoot 
 

Root 
 

Shoot 
 

Root 
 1 

 
170.5 
 

2.5 
 

46.0 
 

2.0 
 2 

 
81.5 
 

2.3 
 

40.0 
 

1.3 
 3 

 
63.5 
 

1.4 
 

43.0 
 

2.3 
 4 

 
65.6 
 

2.2 
 

35.0 
 

1.6 
 5 

 
85.3 
 

3.8 
 

43.5 
 

2.9 
 

Average 
 

93.28 
 

2.44 
 

41.5 
 

2.02 
 

 

36 

Fig. 6a. The main root system of Mikania plant 



 

Fig. 6b. The nodal and internodal roots of a creeping stem of Mikania 

Seed count and seed germination 

A panicle has as many as 134-428 seeds (Table 2), but the number of filled seeds is very 

low (6.52 - 27.62%). Similar observation was reported by Wirjahardja (1976) in the three 

Mikania species common in Indonesia. 

Fifteen (15) filled seeds were sown in petri dish lined with moist filter paper. Four (4) 

dishes were completely wrapped with two layers of carbon paper, while another four (4) 

uncovered dishes were placed on a lighted laboratory table. Germination took place within 

three days in the light-exposed dishes. The carbon paper-wrapped dishes, opened seven days 

after sowing the seeds, showed complete failure of germination. The germination of the 

light-exposed seeds (Table 3) was very low. Repeated trials failed to exceed 50% 

germination even when the germination period was extended for another week.  

Soil germination trials showed that seeds slightly buried into the soil (sticking 

the whole 1.5 — 1.8 mm length of the seed into the moist soil) failed to germinate,  
while seeds, laid flat on its side on the surface of moist soil germinated within a  

few days. . , • 

37 

Notes on some growth characteristics of Mikania cordata - B.T. Mercado 



BIOTROPIA No. 7, 1994 

Table 2. Number of seeds (cypsela) per panicle 

Panicle No. 
 

Filled  

seeds 
 

Unfilled 

 seeds 
 

Total 
 

% filled 
 

1 
 

21 
 

301 
 

322 
 

6.52 
 2 

 
41 
 

227 
 

268 
 

15.29 
 3 

 
25 
 

183 
 

208 
 

12.02 
 4 

 
25 
 

317 
 

342' 
 

7.31 
 5 

 
37 
 

97 
 

134 
 

27.61 
 7 

 
43 
 

385 
 

428 
 

10.04 
 8 

 
39 
 

239 
 

278 
 

14.03 
 

Table 3. Germination of Mikania seed (15 seeds per petri dish) 

Replication                                     No. of seeds 

                                                         germinated 

 

Germination 
% 
 

1                           4 

2                                                           4                                                                                               

3                                                         6                                                                               

4                                                          6 

 

26.6  
26.6 

40.0 
40.0 

The above observations suggest that although a Mikania plant (one exposed to 
sunlight) has the propensity to produce numerous seeds which could be dispersed at great 

distance, only a handful of these seeds are filled, and only a few of them are viable. For 

the viable seeds to germinate light is indispensable. 

The seedling 

The seedling emerges from the pole directly opposite the pappus-bearing pole of the 

seed. The thin, long primary root comes out first. The root tip is distinctly covered with a 

black root cap. Conspicuous is the tuft of short, fine and sticky roots borne at the base of 

the hypocotyl. These roots would later on constitute the root system of the plant, 

replacing the long primary root that dies off after some time. 

The hypocotyl is much bigger in diameter than the spindly primary root but a little 

shorter. The hypocotyl of the newly emerged seedlings had an average length of 0.97 cm. In 

another 12 days, however, it had already an average length of 21.83 

38 



Notes on some growth characteristics of Mikania cordata - B.T. Mercado 

cm, about twice longer than the primary root. At one end of the hypocotyl the pair of round, 

green, succulent cotyledons is borne. The cotyledons remain intact on the seedling until 

the young plant has attained the 3-leafed stage. The seedling, from germination to the early 

early 3-leafed stage is most vulnerable to wilting. However, once it has survived this critical 

period it develops rapidly into a mature and highly vegetative plant. 

SUMMARY 

Mikania has a well developed and efficient means of vegetative reproduction (Fig. 7). 

A portion of the mature stem or branch (IV-1), as long as it bears a node, easily gives rise 

to a new plant. With similar ease, the mature leaves can also give rise to new plants (IV-3). 

An internodal stem or branch (one which does not bear a node), easily forms roots but 

does not give rise to a new plant (IV-2).  

 

Fig. 7. The  life cycle of Mikania cordata 

 

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BIOTROPIA No. 7, 1994 

The development of the plant, whether derived from cuttings (I) or from seeds (III) is 

strongly influenced by light. The plant grown under partial shade elongates very rapidly, is 

dark green and luxuriant. It remains however, vegetative (I-B). In contrast, the plant 

grown under direct sunlight, develops less densely but comes to profuse bloom in 

mid-November until late January (I-A). Numerous seeds are produced but only a few are 

filled, and fewer still are viable. The pappus-bearing, minute seeds (II) are dispersed by 

wind. For the seed to germinate, light is indispensable. For the seedling to survive it 

must be located in a moist and shaded area. 

REFERENCES . 

HOLM, L.G., D.L. PLUCKNETT, J.V. PANCHO, and J.P. HERBERGER, 1977. The World's Worst Weeds. 

University Press. Hawaii, Honolulu.  

WIRJAHARDJA, J. 1976. Autecological study of Mikania spp. Proceedings of the Fifteenth Asian-Pacific 
Weed Science Society Conference. Tokyo, Japan. Asian-Pacific Weed Science Society. 

 

 

 

 

 
 

 

 

 

 

 

 

 
 

 

 

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