Group Title: CFREC-Apopka research report
Title: Effect of potassium rate, temperature, and light on growth of Pothos
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Permanent Link: http://ufdc.ufl.edu/UF00065308/00001
 Material Information
Title: Effect of potassium rate, temperature, and light on growth of Pothos
Series Title: CFREC-Apopka research report
Physical Description: 5 p. : ; 28 cm.
Language: English
Creator: Chase, A. R ( Ann Renee )
Poole, R. T ( Richard Turk )
Central Florida Research and Education Center--Apopka
Publisher: University of Florida, Central Florida Research and Education Center-Apopka
Place of Publication: Apopka FL
Publication Date: 1991
 Subjects
Subject: Plants, Ornamental -- Effect of light on -- Florida   ( lcsh )
Plants, Ornamental -- Effect of potassium on -- Florida   ( lcsh )
Plants, Ornamental -- Effect of temperature on -- Florida   ( lcsh )
Genre: government publication (state, provincial, terriorial, dependent)   ( marcgt )
non-fiction   ( marcgt )
 Notes
Statement of Responsibility: A.R. Chase and R.T. Poole.
General Note: Caption title.
 Record Information
Bibliographic ID: UF00065308
Volume ID: VID00001
Source Institution: University of Florida
Holding Location: University of Florida
Rights Management: All rights reserved by the source institution and holding location.
Resource Identifier: oclc - 70068088

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/ i/ Effect of potassium rate, temperature, and light on growth of Pioios

A. R. Chase and R. T. Poole1' EP 3 0 1994

University of Florida, IFAS, Universitv
Central Florida Research and Education Center Apopka f' lorida
CFREC-Apopka Research Report, RH-91-11

Pothos (Epipremnwn aureum) are produced by cuttings from stock plants frequently
grown outside of Florida. When growers receive cases of these cuttings they assume that if the
cuttings appear to be of high quality, they will root rapidly and grow into a salable product
within a standard period of time. However, sometimes cuttings do not respond as expected.
Diseases, shipping conditions, or pesticide toxicity are blamed for poor rooting or plant growth,
yet it is not uncommon to find that none of these factors can be identified as the cause of the
problem. Previous work on nutrition and temperature tolerance of vining stock plants led to the
following study on minimum winter temperature, chilling temperature, potassium rate and light
levels on development of golden pothos.

Materials and Methods

Rooted cuttings of golden pothos were obtained from commercial producers and
established in Vergro potting medium. After rooting was well underway they were transplanted
to 6 inch standard plastic pots containing Vergro and amended with dolomitic lime and
Micromax at the recommended rate. Potassium treatments were top-dressed at the rate of 0, 2,
4, or 6 g (slow-release 0-0-45)/6 inch pot every two months. Nitrogen was added at the rate
of 5 g (slow-release 39-0-0) and single superphosphate was added at the rate of 4 g/6 inch pot.
Treatments were set up in a factorial experiment with four rates of potassium and four minimum
air temperatures (60, 65, 70, or 750F). Twelve replicate pots were used for each of the 16
treatments. The first part of the test was initiated on 12 December 1989 when fertilizer
treatments were applied. Leachate soluble salts were recorded monthly. Plant ratings included
number of vines, total vine length, and fresh weight of tops, all recorded between 19 and 23
January 1990. Half of each treatment was exposed to 1 week at 50F to test sensitivity to
chilling starting on 14 January 1990. The number of necrotic leaves and the number of distorted
leaves were recorded on 23 January 1990.

The second part of the test commenced on 9 February 1990 when three of the remaining
6 replicates per treatment were moved to a higher light level condition. Temperature treatments
were discontinued when the light treatment was initiated although the application of fertilizer
treatments continued as described on schedule. Total vine length and fresh top weight were
recorded on 30 April and 1 May 1990, respectively. Cuttings were rooted from the trimmed


'Professor of Plant Pathology, and Professor of Environmental Horticulture, respectively.
Central Florida Research and Education Center-Apopka, 2807 Binion Rd., Apopka, FL 32703.


[1- 5 W






vines by placing 10 per 6 inch pot containing Vergro and top-dressed with 6 g/pot of the slow-
release fertilizer Osmocote 19:6:12. After 5 weeks under an intermittent mist, top grade was
recorded using the scale: 1 (dead), 2 (poor, unsalable), 3 (moderate, salable), 4 (good, salable),
and 5 (excellent, salable).

Results and Discussion

Minimum winter temperatures between 60 and 75 F affected the growth of pothos in this
test although the potassium rates tested did not appear to influence their growth (Table 1). In
general, the higher the minimum night temperature the greater the number of vines, and vine
length. In the case of the fresh weight of tops, however, the application of potassium did result
in a trend toward greater growth as potassium level increased (Table 1). Neither minimum
temperatures under which pothos were produced nor the rate of potassium supplied affected their
tolerance of chilling at 500F although a statistical interaction between the two factors appeared
to occur (Table 1).

When the temperature treatments were discontinued on those plants which were not
exposed to the chilling treatment, they were exposed to two light levels (3000 and 5500 ft-c).
About 3 months after the light treatments were initiated, plant growth showed a significant
response in the number of vines produced as well as the total vine length and fresh weight of
tops (all decreased under the 5500 ft-c level) (Table 2). As potassium increased so did the top
weight of the vines produced, which was similar to the results noted in the first portion of this
experiment (Table 2). This was most notable under the 3000 ft-c and is likely explained by the
fact that even the highest potassium rate was too low for optimum growth of pothos under 5500
ft-c. Finally, the cuttings collected from these plants were rated about 5 weeks later and results
showed that those produced from plants under the higher light level were generally a higher
quality. All plants showed a similar increase in quality as potassium rate increased.

Conclusions

Minimum winter temperatures for pothos between 60 and 75F dramatically affected
plant growth with increased growth response as minimum temperature increased. It did not,
however, reduce sensitivity to chilling injury when exposed to 50F for 1 week. Potassium level
,even a lack of potassium) only affected the fresh weight of tops whether plants were grown
inder 3000 or 5500 ft-c. Even when low potassium rates did not appear to greatly reduce
quality of the "stock plants" it did influence the ability of the cuttings removed from these plants
:o root and produce a salable product. Vergro potting medium contains a small boost of
'ertilizer (containing potassium as well as other elements) which could account for the lengthy
ime that plants grew in the "absence" of potassium without detriment to their growth. It was
especially interesting to note that differences in the growth and appearance of the cuttings
established from potassium deficient plants appeared about 1 to 2 months before deficiencies
appeared in the stock plants. Potassium deficiency in pothos is characterized by shortened
nternodes, stunted leaves (1 inch in length or less), leaf necrosis and finally plant death. In
severall other experiments, the appearance of deficiency symptoms took 4 to 6 months. Prior








with standard sized leaves and vine appearance. Newly established pothos stock plants appear
to be able to survive for 3 or more months without any additional potassium than is present in
Vergro. Current recommendations for potassium levels in pothos may be higher than actually
required by pothos for good growth when appropriate light levels are maintained. Be especially
careful not to lower rates to levels which support adequate stock growth but decrease cutting
quality.






-uoaien rotnos .

Vine Top No. No.
Potassium No. length weight necrotic leaves
Temperature "F" levelb vines (in)c (g)d leaves' distorted'
60 0 5.8 60.8 70.2 0.2 2.2
60 2 5.3 62.6 94.7 1.0 1.3
60 4 6.1 74.3 112.8 0.2 1.0
60 6 5.0 58.9 94.0 0.3 1.8

65 0 6.7 76.0 84.6 1.0 0.8
65 2 7.3 82.2 99.6 0.2 1.0
65 4 7.2 85.1 104.3 0.2 2.2
65 6 7.7 80.3 96.2 0 1.7
70 0 8.2 112.4 110.0 0.2 2.0
70 2 8.2 109.2 122.5 0.3 2.0
70 4 8.3 105.9 117.7 0.2 1.7
70 6 8.9 101.3 113.6 0.3 1.5

75 0 7.5 125.4 124.9 0.2 1.2
75 2 8.2 133.1 127.8 0.2 1.8
"C A 01 2 1~A V 11 7 "7 2 1 O









Light level' levelb vines length(in)' (g)d quality
5500 0 12.3 121.2 107.8 2.6
5500 2 13.2 122.2 116.1 3.0
5500 4 13.8 124.1 123.2 3.5
5500 6 11.5 123.2 112.8 3.9
3000 0 15.2 173.9 140.9 2.1
3000 2 14.7 179.6 161.1 3.0
3000 4 15.6 191.4 172.0 2.7
3000 6 15.1 180.4 181.2 3.3
Significance'
Light level (L) 0.0005 0.0001 0.0001 0.0044
Potassium (K) ns ns 0.0144 0.0001
L x K ns ns ns ns

a Light level is given in foot candles.
b Potassium (0-0-46 slow-release formulation) was applied at the rate given in g/6 inch pot
once at test initiation.
c Total vine length was recorded on 30 April 1990.
d Fresh weight of vines was recorded on 30 April 1990.
Cutting grade was rated on the following scale on 7 June 1990; 1 (dead), 2 (poor,
unsalable), 3 (moderate, salable), 4 (good, salable), and 5 (excellent, salable).
f Significance of the analysis of variance (F value) is given. Numbers less than 0.05 are
considered significant.


--


Potassium No. Vine Top weight


Cutting




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