Leaf plastochron index

Last updated January 07, 2022

Leaf plastocron index is a measure of plant leaf age based on morphological development (the plastochron). It is useful in studying plant development requiring destructive measurement on multiple individuals. By measuring a metric against morphological age, instead of chronological time, one can reduce variations occurring between individuals, thus allowing greater focus on variations due to development.^[1]

What is the leaf plastochron index?

The leaf plastochron index, also referred to simply as the plastochron index (PI) as it is derived from, is a demography formula used to determine the developmental age and growing rate of a leaf or other growing plant organ.^[2] This formula was useful when first introduced as it allowed scientists to be able to track the progression and growth of a plant. According to American Journal of Botany, the typical variation of the formula for the plastochron index is as follows;

$P.I.=n+{(1nL_{n}-1nR) \over (1nL_{n}-1nL_{n+1})}$ ^[3]

However, another common variation as according to Hans Burström's book Growth and Growth Substances/Wachstum und Wuchsstoffe, the leaf plastochron index for a certain leaf on a plant is as follows;

$(L.P.I)_{a}=(P.I.)-a=n-a+{logL_{n}-log_{1}0 \over logL_{n}-logL_{n+1}}$

This is derived from Burström's variation of the plastochron index which is as follows;

$P.I.=n+{logL_{n}-log_{10} \over logL_{n}-logL_{n+1}}$

Other data, not including morphological features, that can be used to determine the leaf's developmental age include uptake of oxygen, weight, chlorophyll, etc.^[4]

How to use the leaf plastochron index

To use the plastochron index, it is important to be able to understand how to use the formula. The following is the key to use the typical variation of the formula;

“n” is the leaf's sequential index (or serial) number. This number is increasing but if the seedling's leaves of the organ are the source of study, n = 0.

“R” is the reference length of the leaf.

“ $L_{n}$ ” is the length of the leaf that is longer, or equal, to the reference length.

“ $L_{n+1}$ ” is the length of which is shorter than the reference length.

However, when using the formula supplied by the American Journal of Botany there are multiple assumptions or requirements of the leaf that is being studied for the calculation to be accurate. Erickson and Michelini dictate that the “organ growth must be exponential” meaning the leaf must be growing. Also, “successive organs must be growing at the same relative rates” meaning the measurement will not equate to other plant growth unless they share the same growth rate even if they are co-dependently growing. Finally, “Successive plastochrons must be equal, where here, plastochrons are defined as the time intervals between the attainment of length R by successive organs” meaning that some research of the leaf's reference length is needed for the formula to be verifiable.^[3]

In Burström's variation, he uses a Xanthium plant as an example which was 10 mm (thus, why 10 was used as the reference unit). This was used to show that the plastochron age of this plant is 0. A plant longer than this would have a positive number for its plastochron age and an organ shorter than the reference unit of 10 mm will have a negative plastochron age.^[4]

Leaf plastochron index in action

An example of the leaf plastochron index in action is Philip R. Larson and J. G. Isebrands’ article The Plastochron Index as Applied to Developmental Studies of Cottonwood. A cottonwood leaf was the organ used for this research as this plant has uniform rates of growth, meaning it falls under the requirements needed for the formula's verifiability. Two tests were conducted; the first test showed the results of the plastochron intervals ranging between 2-2.76 days but the second test was to calculate the statistical models of the leaf plastochron indexes for all 5 size classes. The five size classes were directly related to the five dependent variables of their study; leaf length, leaf area, vessels per internode, vessels per petiole and leaf weight (dry).

This study shows how the leaf plastochron index can be used within scientific research to explore and predict certain developmental events of a leaf or other plant organ's life cycle through a non destructive method of morphological feature identification.^[5]

Another example of the leaf plastochron index in action is O.E. Ade-Ademilua C.E.J. Botha and R.J. Strasser's South African Journal of Botany article A re-evaluation of plastochron index determination in peas -- a case for using leaflet length. For this study the following variation of the leaf plastochron index formula was used;

$P.I.=n+{logL_{n}-log\lambda \over logL_{n}-logL_{n+1}}$

This study was conducted in order to determine whether the leaf plastochron index works for pea plants (Pisum sativum).The researchers’ results showed that the pea plant (Pisum sativum) met all the requirements needed to use the leaf plastochron index formula in a verifiable manner when finding plastochron age through leaf length. However, these results can only be deduced if early development is measured successfully. This shows that the leaf plastochron index can measure successive pairs of leaflets in pea plants (Pisum sativum).^[6]

Creators of leaf plastochron index

This formula was introduced in 1957 by scientists Ralph O. Erickson and Francis J. Michelini, making this scientific formula over 60 years old.^[3] Erickson and Michelini's formula was first published for The Journal of March in the American Journal of Botany.^[2] Although Erickson and Michelini were responsible for introducing the formula, the concept of the plastochron being used as a unit of measurement was inspired by scientist Askenasy originally in 1880. Other names that have contributed to the use of the plastochron are Schmidt in 1924 and Esau in 1953 and again in 1965.^[3]

Dr. Ralph O. Erickson was born in Duluth, Minnesota, in 1914.^[7] He received an education from Gustavus Adolphus College (St. Peter) in 1939 and Washington University (St. Louis) where he inevitably attained his Ph.D. in 1944. Although he first began teaching at Rochester in 1944 until 1947, much of his career was spent at the University of Pennsylvania where he received his professorship between 1949 until 1985. His primary focus of study was on plant morphology, which he stated in his autobiography that developmental plant morphology was actually one of his most enjoyable courses to teach. Erickson went on to write in his autobiography that when conversing with Michelini that he “Found [himself] writing the formula for the plastochron index on the blackboard, as if by inspiration. The plastochron index has now been used by many authors, including [themselves], in a variety of ways.” He later went on to receive his Guggenheim Fellowship for his work in plant physiology where he used the plastochron index in order to determine and assess the temperature and light effects on the developmental growth of the plants.^[8] Erickson passed away in March 2006.^[7]

Dr. Francis J. Michelini was born in Clifton, New Jersey in 1925. He received an education at Seton Hall College, the University of Delaware and the University of Pennsylvania where he received his Doctorate of Philosophy degree in Biological science. This was where he met Ralph O. Erickson.^[9] He began his teaching career at Wilkes College and received his Professorship of Biology in 1963. He was announced as the second President of Wilkes College in 1970 and later served as President of the Commission for Independent Colleges and Universities. In 1957, Michelini published his article The Plastochron Index with Ralph O. Erickson.^[2] Michelini passed away in September 2019.^[10]

Related Research Articles

In computer science, binary search, also known as half-interval search, logarithmic search, or binary chop, is a search algorithm that finds the position of a target value within a sorted array. Binary search compares the target value to the middle element of the array. If they are not equal, the half in which the target cannot lie is eliminated and the search continues on the remaining half, again taking the middle element to compare to the target value, and repeating this until the target value is found. If the search ends with the remaining half being empty, the target is not in the array.

In computer science and information theory, a Huffman code is a particular type of optimal prefix code that is commonly used for lossless data compression. The process of finding or using such a code proceeds by means of Huffman coding, an algorithm developed by David A. Huffman while he was a Sc.D. student at MIT, and published in the 1952 paper "A Method for the Construction of Minimum-Redundancy Codes".

Signal-to-noise ratio is a measure used in science and engineering that compares the level of a desired signal to the level of background noise. SNR is defined as the ratio of signal power to the noise power, often expressed in decibels. A ratio higher than 1:1 indicates more signal than noise.

A cotyledon is a significant part of the embryo within the seed of a plant, and is defined as "the embryonic leaf in seed-bearing plants, one or more of which are the first to appear from a germinating seed." The number of cotyledons present is one characteristic used by botanists to classify the flowering plants (angiosperms). Species with one cotyledon are called monocotyledonous ("monocots"). Plants with two embryonic leaves are termed dicotyledonous ("dicots").

Tendril Specialisation of plant parts used to climb or bind

In botany, a tendril is a specialized stem, leaf or petiole with a threadlike shape used by climbing plants for support and attachment, as well as cellular invasion by parasitic plants such as Cuscuta. Tendrils are responsive to touch and to chemical factors by curling, twining, or adhering to suitable structures or hosts.

The cowpea is an annual herbaceous legume from the genus Vigna. Due to its tolerance for sandy soil and low rainfall, it is an important crop in the semiarid regions across Africa and Asia. It requires very few inputs, as the plant's root nodules are able to fix atmospheric nitrogen, making it a valuable crop for resource-poor farmers and well-suited to intercropping with other crops. The whole plant is used as forage for animals, with its use as cattle feed likely responsible for its name.

In geometric group theory, Gromov's theorem on groups of polynomial growth, first proved by Mikhail Gromov, characterizes finitely generated groups of polynomial growth, as those groups which have nilpotent subgroups of finite index.

Equisetidae is one of the four subclasses of Polypodiopsida (ferns), a group of vascular plants with a fossil record going back to the Devonian. They are commonly known as horsetails. They typically grow in wet areas, with whorls of needle-like branches radiating at regular intervals from a single vertical stem.

Allometry is the study of the relationship of body size to shape, anatomy, physiology and finally behaviour, first outlined by Otto Snell in 1892, by D'Arcy Thompson in 1917 in On Growth and Form and by Julian Huxley in 1932.

Leaf area index (LAI) is a dimensionless quantity that characterizes plant canopies. It is defined as the one-sided green leaf area per unit ground surface area in broadleaf canopies. In conifers, three definitions for LAI have been used:

As the tip of a plant shoot grows, new leaves are produced at regular time intervals if temperature is held constant. This time interval is termed the plastochron. The plastochrone index and the leaf plastochron index are ways of measuring the age of a plant dependent on morphological traits rather than on chronological age. Use of these indices removes differences caused by germination, developmental differences and exponential growth.

Phenotypic plasticity refers to some of the changes in an organism's behavior, morphology and physiology in response to a unique environment. Fundamental to the way in which organisms cope with environmental variation, phenotypic plasticity encompasses all types of environmentally induced changes that may or may not be permanent throughout an individual's lifespan. The term was originally used to describe developmental effects on morphological characters, but is now more broadly used to describe all phenotypic responses to environmental change, such as acclimation (acclimatization), as well as learning. The special case when differences in environment induce discrete phenotypes is termed polyphenism.

In finance, return is a profit on an investment. It comprises any change in value of the investment, and/or cash flows which the investor receives from that investment, such as interest payments, coupons, cash dividends, stock dividends or the payoff from a derivative or structured product. It may be measured either in absolute terms or as a percentage of the amount invested. The latter is also called the holding period return.

Phytomorphology is the study of the physical form and external structure of plants. This is usually considered distinct from plant anatomy, which is the study of the internal structure of plants, especially at the microscopic level. Plant morphology is useful in the visual identification of plants. Recent studies in molecular biology started to investigate the molecular processes involved in determining the conservation and diversification of plant morphologies. In these studies transcriptome conservation patterns were found to mark crucial ontogenetic transitions during the plant life cycle which may result in evolutionary constraints limiting diversification.

Evolutionary developmental biology (evo-devo) is the study of developmental programs and patterns from an evolutionary perspective. It seeks to understand the various influences shaping the form and nature of life on the planet. Evo-devo arose as a separate branch of science rather recently. An early sign of this occurred in 1999.

Important structures in plant development are buds, shoots, roots, leaves, and flowers; plants produce these tissues and structures throughout their life from meristems located at the tips of organs, or between mature tissues. Thus, a living plant always has embryonic tissues. By contrast, an animal embryo will very early produce all of the body parts that it will ever have in its life. When the animal is born, it has all its body parts and from that point will only grow larger and more mature. However, both plants and animals pass through a phylotypic stage that evolved independently and that causes a developmental constraint limiting morphological diversification.

This glossary of botanical terms is a list of definitions of terms and concepts relevant to botany and plants in general. Terms of plant morphology are included here as well as at the more specific Glossary of plant morphology and Glossary of leaf morphology. For other related terms, see Glossary of phytopathology and List of Latin and Greek words commonly used in systematic names.

A leaf is the principal lateral appendage of the vascular plant stem, usually borne above ground and specialized for photosynthesis. The leaves, stem, flower and fruit together form the shoot system. Leaves are collectively referred to as foliage, as in "autumn foliage". In most leaves, the primary photosynthetic tissue, the palisade mesophyll, is located on the upper side of the blade or lamina of the leaf but in some species, including the mature foliage of Eucalyptus, palisade mesophyll is present on both sides and the leaves are said to be isobilateral. Most leaves are flattened and have distinct upper and lower surfaces that differ in color, hairiness, the number of stomata, the amount and structure of epicuticular wax and other features. Leaves are mostly green in color due to the presence of a compound called chlorophyll that is essential for photosynthesis as it absorbs light energy from the sun. A leaf with lighter-colored or white patches or edges is called a variegated leaf.

Specific leaf area (SLA) is the ratio of leaf area to leaf dry mass. The inverse of SLA is Leaf Mass per Area (LMA).

Plant growth analysis refers to a set of concepts and equations by which changes in size of plants over time can be summarised and dissected in component variables. It is often applied in the analysis of growth of individual plants, but can also be used in a situation where crop growth is followed over time.

References

↑ Meicenheimer, R. D. (2014). The plastochron index: Still useful after nearly six decades. American Journal of Botany, 101(11), 1821-1835.
1 2 3 Erickson, R. and Michelini, F., 1957. THE PLASTOCHRON INDEX. American Journal of Botany, 44(4), pp.297-305.
1 2 3 4 Meicenheimer, R., 2014. The plastochron index: Still useful after nearly six decades. American Journal of Botany, 101(11), pp.1821-1835.
1 2 Burström, H., 1961. Growth And Growth Substances / Wachstum Und Wuchsstoffe. Berlin, Heidelberg: Springer Berlin Heidelberg, p.86.
↑ Larson, P. and Isebrands, J., 1971. The Plastochron Index as Applied to Developmental Studies of Cottonwood. Canadian Journal of Forest Research, 1(1), pp.1-11.
↑ Ade-Ademilua, O., Botha, C. and Strasser, R., 2005. A re-evaluation of plastochron index determination in peas — a case for using leaflet length. South African Journal of Botany, 71(1), pp.76-80.
1 2 Sprugel, D., 2015. Ralph O. Erickson – The Ecological Society Of America's History And Records. [online] Esa.org. Available at: <https://esa.org/history/erickson-r-o/> [Accessed 27 May 2020].
↑ Erickson, R., 1988. Growth And Development Of A Botanist. Philadelphia, pp.4-16.
↑ Obits.pennlive.com. 2019. Francis Michelini Obituary - Mechanicsburg, PA | Patriot-News. [online] Available at: <https://obits.pennlive.com/obituaries/pennlive/obituary.aspx?n=francis-michelini&pid=193898544&fhid=4629> [Accessed 27 May 2020].
↑ Wilkes.edu. 2020. Dr. Francis J. Michelini - Wilkes University. [online] Available at: <https://www.wilkes.edu/dr-michelini/> [Accessed 27 May 2020].

This plant article is a stub. You can help Wikipedia by expanding it.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Meicenheimer, R. D. (2014). The plastochron index: Still useful after nearly six decades. American Journal of Botany, 101(11), 1821-1835.

[auto-2] 1 2 3 Erickson, R. and Michelini, F., 1957. THE PLASTOCHRON INDEX. American Journal of Botany, 44(4), pp.297-305.

[auto2-3] 1 2 3 4 Meicenheimer, R., 2014. The plastochron index: Still useful after nearly six decades. American Journal of Botany, 101(11), pp.1821-1835.

[auto3-4] 1 2 Burström, H., 1961. Growth And Growth Substances / Wachstum Und Wuchsstoffe. Berlin, Heidelberg: Springer Berlin Heidelberg, p.86.

[5] Larson, P. and Isebrands, J., 1971. The Plastochron Index as Applied to Developmental Studies of Cottonwood. Canadian Journal of Forest Research, 1(1), pp.1-11.

[6] Ade-Ademilua, O., Botha, C. and Strasser, R., 2005. A re-evaluation of plastochron index determination in peas — a case for using leaflet length. South African Journal of Botany, 71(1), pp.76-80.

[auto1-7] 1 2 Sprugel, D., 2015. Ralph O. Erickson – The Ecological Society Of America's History And Records. [online] Esa.org. Available at: <https://esa.org/history/erickson-r-o/> [Accessed 27 May 2020].

[8] Erickson, R., 1988. Growth And Development Of A Botanist. Philadelphia, pp.4-16.

[9] Obits.pennlive.com. 2019. Francis Michelini Obituary - Mechanicsburg, PA | Patriot-News. [online] Available at: <https://obits.pennlive.com/obituaries/pennlive/obituary.aspx?n=francis-michelini&pid=193898544&fhid=4629> [Accessed 27 May 2020].

[10] Wilkes.edu. 2020. Dr. Francis J. Michelini - Wilkes University. [online] Available at: <https://www.wilkes.edu/dr-michelini/> [Accessed 27 May 2020].

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]