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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
Components of phenotypic variance of
seed traits and germination characteristics
of 20 ponderosa pine half-sib families
Componentes de varianza fenotípica de características de semilla y
germinación de 20 familias de medios hermanos de pino ponderosa
C
ÉSAR
H. R
IVERA
-F
IGUEROA
1,4
, J
OHN
G. M
EXAL
2
AND
D
ENNIS
L. C
LASON
3
Abstract
Received: February 19, 2019 Accepted: March 1, 2019
Resumen
A study was conducted to estimate phenotypic variance components of
seed traits and seed vigor of 20 ponderosa pine seed lots. A high
intraspecific within-group variation in seed germination and seedling
growth has been observed in both half-sib and full-sib families of
conifers. Some seed traits may influence seed lot quality and seedling
survival. Wind-pollinated cones were collected from 20 ponderosa pine
maternal trees, 10 cones per tree, in a stand located in Fort Defiance,
Arizona. Air-dried seeds were sown under laboratory conditions, by
using a completely randomized design to estimate components of
phenotypic variance for seed weight (SW), seed coat weight (SCW), seed
imbibition (IMB), five germination characteristics, and three Weibull
parameters (
a
,
b
and
c
). About 80% of size classes had a seed weight
(SW) e» 41 mg and e» 97% final germination. The within-plot (within-
family) variance component for SW (64.5%) and IMB (70.4%) was
higher than among-family variation (35.3 and 24.8%, respectively). The
among-family component varied from 35.1% (Weibull parameter
a
) to
62.3% (Peak Value). Results suggest a significant maternal contribution
and a high within-family genetic influence on seed quality and
germination characteristics. Finally, heavier seeds (SW e» 60 mg), whose
time of germination (TOG) occurred at day 3, increased 38.3% of their
seed weight due to water absorption before reaching 50% germination;
on the other hand, seeds whose SW was e» 45 mg and TOG = 7, showed
102.2% increase in SW before reaching 50% germination.
Keywords:
germination timing, peak value, Weibull parameters, within-
family variation.
Se realizó un estudio para estimar componentes de varianza de
características y vigor de 20 lotes de semilla de pino ponderosa. En
familias de hermanos completos y medios hermanos la varianza dentro
de grupos es elevada para la germinación y crecimiento de plántulas de
coníferas. Algunas características de semilla pueden influir en la calidad
del lote y la supervivencia de plántulas. Diez conos de polinización abierta
fueron colectados de cada uno de 20 árboles madre, en una población
localizada en Fort Defiance, Arizona. Semillas secadas al aire fueron
sembradas en el laboratorio, en un diseño completamente aleatorizado,
para estimar las componentes de varianza fenotípica de: peso (SW) y
cubierta de la semilla (SCW); imbibición de la semilla (IMB), cinco
características germinativas y tres parámetros de Weibull (
a, b
y
c
).
Un 80% de la semilla tuvo peso e» 41 mg y germinación e» 97%. La
varianza dentro de progenie/dentro de familia para las características
SW (64.5%) e IMB (70.4%) fue mayor que la varianza entre familias
(35.3 y 24.8%, respectivamente). La varianza entre familias varió de
35.1% (parámetro
a de Weibull) a 62.3% (Peak Value). Los
resultados sugieren
contribución materna y componente genética alta
dentro de familias que influyen en la calidad y características
germinativas de la semilla. Semillas con SW e» 60 mg y TOG=3,
incrementaron 38.3% de su peso por agua absorbida para alcanzar
50% de germinación. Las semillas cuyo SW fue e» 45 mg and TOG = 7,
mostraron un incremento de 102.2% en SW antes
de completar 50%
de germinación.
Palabras clave: tiempo para germinación, valor pico, parámetros
Weibull, variación dentro de familias.
_________________________________
1 UNIVERSIDAD AUTÓNOMA DE CHIHUAHUA. Facultad de Ciencias Agrotecnológicas. Ciudad Universitaria s/n, C.P. 31170. Chihuahua, Chihuahua.
México.
2 NEW MEXICO STATE UNIVERSITY. College of Agriculture. Department of Agronomy and Horticulture. Las Cruces, NM.
3 UNIVERSITY OF CINCINNATI BLUE ASH COLLEGE. Department of Mathematics. Physics and Computer Science. Cincinnati, OH.
4 Corresponding autor: crivera@uach.mx
Medio Ambiente y Desarrollo Sustentable Artículo arbitrado
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CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
C
Introduction
onifers are considered one of the most variable plant groups for many morphological
and physiological characteristics of seeds and seedlings. A high intraspecific within-
group variation in seed germination and seedling growth has been observed in both
half-sib and full-sib families, and this variability increases with age (Maze and Banerjee, 1989;
Matziris, 1998; Parker et al., 2006).
Some authors indicate that variation in seed
weight and seedling phenology is due to four major
factors: (1) genotype of seeds (Bramlett et al., 1983;
Sorensen and Campbell, 1985; Davidson et al., 1996;
Barnett, 1997); (2) maternal effects (Perry, 1976;
Perry and Hafley, 1981; (3) environmental conditions
such as chilling duration, incubation temperatures,
and soil moisture (McLemore, 1966; Gossling, 1988;
Bai et al., 2004; Pasquini and Defossé, 2012); and (4)
cultural practices such as fertilization, irrigation, and
pest control (More and Kidd, 1982; Gummerson, 1989;
Heidmann and Haase, 1989; Benjamin 1990; St. Clair
and Adams, 1993).
Seedling quality and the success of seedling
establishment are strongly correlated with
germination and emergence of seeds planted in the
nursery (Silen and Osterhaus, 1979; Mexal and Fisher,
1987; Davidson et al., 1996). It is apparent from
documented literature that seed mass, a maternally-
determined characteristic, seems to be correlated
with total germination and time of germination
(Roach and Wulf, 1987). In ponderosa pine, genetic
variation in seed morphology appears to be associated
with climatic gradients (mostly precipitation,
temperature and soil moisture); high estimates of
within-population variation seem to be associated to
adaptive mechanisms to environmental changes
(Parker et al., 2006). In addition, evidence suggests
that selective forces (temperature, soil moisture,
birds) are responsible for the origin of ecotypes
possessing unique variation in seed morphology (Ager
and Settler, 1983).
Little information exists about the genesis of
variation of germination characteristics and seeds
traits in Pinus ponderosa (Weber and Sorensen, 1992;
Matziris, 1998; Parker et al., 2006), which have
influence on quality of seed lots and seedling survival.
This study was conducted a) to estimate
phenotypic variance components of seed traits and
germination parameters of seed lots; b) to compare
seed vigor and germination characteristics of 20 half-
sib families and c) to analyze correlations of seed size
with germination and other seed traits.
Materials and methods
Study site and cone collection. The genetic
material was supplied by the Department of Navajo
Forestry Reforestation and Disease Control. Two
hundred wind-pollinated cones were collected from
twenty maternal trees, randomly selected from a stand
of ponderosa pine (Pinus ponderosa Dougl. Ex Laws.).
Trees of the ponderosa pine stand are located on the
Defiance Plateau (35° 40’ N, 111° 49’ W, at an
elevation between 2200 and 2500 meters (ASL), on
Fort Defiance, Arizona, USA. Mature cones were
collected in fall (October) and dried at room
temperature (20 °C ± 2 °C) for one month. Seeds were
then dewinged, cleaned, placed them in polyethylene
bags and stored five months in a refrigerator at 4 °C
until sown (Long and Jones, 1996; Parker et al., 2006;
Pasquini and Defossé, 2012). Seed traits of collected
cones and some morphological characteristics were
recorded for selected maternal trees (Table 1). In this
study, a seed lot is the progeny derived from each
maternal tree, each of which will be also named
subsequently as half-sib family.
Seed traits measurements. A bulked seed lot of
400 seeds was formed by combining cleaned seed
from 20 half-sib families (20 seeds randomly selected
from each half-sib family); then, seeds were weighed
and categorized into five size weight classes: a) < 31;
b) 31-40; c) 41-50; d) 51-60, and e) > 60 mg. Seed
weights (SW) were used to build an histogram of
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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frequencies (Figure 1). Seed coats of germinants were
removed, dried at 100 °C for 24 hours, weighed and
recorded (SCW). Values of seed imbibition (IMB),
expressed as amount of daily absorbed water (mg),
were calculated with the formula (Durzan, 1983;
Woodstock, 1988; Terskikh et al., 2005): IMB= [(SW2-
SW1)/SW1], where SW2=Seed weight at time 2 and
SW1=Seed weight at initial time. For each individual
seed, daily measurements of seed fresh weight changes
were registered.
Experimental design and treatments. Twenty
half-sib families, which represent 20 treatments, were
compared in a completely randomized design (give a
reference for this experimental design, e.g., Steel and
Torrie, 1980), with two replicates. The experimental
unit (EU) and sampling unit (SU) for all germination
parameters were represented by a Petri dish with 10
seeds. The SU for seed weight traits and seed
imbibition, on the other hand, was represented by a
single seed.
Table 1. Elevation (masl) and traits of mother trees from which 20 half-sib families were collected from Navajo Forest located on
Defiance Plateau (Fort Defiance, Arizona. USA).
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
p w e f
w e f
Germination test. This study was conducted
under laboratory conditions (20 ºC ± 2 ºC) at the
Department of XXX, New Mexico State University, to
estimate variance components of several seed quality
traits of 20 half-sib families. Two replicates of ten
seeds of each half-sib family were sown on Petri
dishes containing three layers of filter paper
(Whatman No. 2). After sowing the seeds, 10 ml of
deionized water were applied in each Petri dish, and
5 ml were added every other day to replace the water
lost by evaporation.
Germination parameters. The criterion to define
seed germination was when radicle protrusion
occurred (if possible, give a reference) and extended
about 5 mm. In this study, several criteria were
included to measure germinative characteristics of
seed lots. Germination capacity (GC), which is also
named final or total germination, was measured as
germination percentage at the end of the test (G) and
transformed into Arc Sine (G* 0.01). Time of
germination (TOG), which is usually named
between groups or treatments, is a random sample
derived from a ponderosa pine population; the error
term (e2), it is also known as within group
component, which represents the variation among
experimental units (EU), while the component of
variance within-plot (w2) is the variation among
individuals within each EU (Steel and Torrie, 1960).
Since at each EU were sown seeds selected from a
given family, the within-plot component of variance
is also named within-family variation. The numbers
of families, replications, and individuals/plot
(progeny size/family) were, respectively, 20 (f), 2
(r) and 10 (p). Phenotypic variance is = 2 = 2 + 2 + 2.
Table 2. ANOVA model and expected means squares (EMS).
1/ 2, 2, 2 are the within-plot, error, and family components of
w e f
germination timing, was described as the number of
days to reach 50% germination. Germination speed
(GS), it is the reciprocal of time of germination (1/
TOG). Peak value (PV), it is the highest quotient when
dividing the maximum cumulative germination
percentage by number of days to reach this percentage.
Germination value (GV), it is the result of multiplying
PV*MDG data, where MDG=Mean daily germination
= number of seeds germinating per day (Czabator,
1962; Larson, 1963; Ranal and Garcia de Santana,
2006). Weibull parameters, other seed characteristics
associated with germinative capacity of seeds, were
estimated for all half-sib families. The parameter «a»,
for instance, indicates the point in which germination
begins. Parameter «b», on the other hand, is the scale
factor. Finally, «c» defines the shape of the curve (Rink
et al., 1979; Bahler et al., 1989).
Statistical analysis and variance components.
The model of analysis of variance (ANOVA) for
estimating components of phenotypic variance of seed
traits is shown in Table 2. Sources of variation
(Source), degrees of freedom (DF), and the expected
mean squares (EMS) were calculated for a completely
randomized design (Kuehl, 1994). The family
component of variance (f2), which it is usually
named in experimental design terminology as
variance, respectively.
Phenotypic variance = p
2 = 2 + 2 + 2. f=20 families; r=2
replicates, and p=10 individuals/family.
Results and discussion
Characteristics of mother trees and seeds of half-
sib families. Recorded data for selected maternal trees
(Table 1) confirm the existence of morphological
variation among half-sib families, as it has been
mentioned by other authors (Maze and Banerjee,
1989; Barnett, 1997; Matziris, 1998); for instance,
height of trees varied from 10.7 (family 20) to 24.4 m
(family 4); diameter at breast height (DBH), on the
other hand, showed a range between 25 (family 14)
and 63 cm (family 12). Number of seeds per cone,
among families, varied from 32 (family 16) to 123
(family 3). Average seed weight showed a range from
29 to 60 mg, respectively, for family 7 and family 19.
Seed moisture content (dry weight basis), averaged
7.6%, a minimum of 7.0% (family 9) and a maximum
of 8.1% (family 18). Since most means were close to
the average seed moisture content, this suggests
similar seed maturity conditions, as it was expected
because all cones were harvested on the same day of
October. Similar results were documented in other
pine species (Durzan, 1983; Terskikh et al., 2005;
Pasquini and Defossé, 2012).
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
f
Figure 1. Frecuency distribution of seed size of a 400-seeds
balanced bulk of 20 half-sib families.
Seed weight sizes and germination capacity. The
histogram of frequencies for seed weight shows a
normally distributed curve (Figure 1); the value of
the mode corresponds to seed size 41-50 mg, since it
is the class of the highest frequency (41%). The
heavier seed weight (> 60 mg) represents 7.5% o
the seeds, while the lighter (< 31 mg) only 2.1%.
About 80% of seeds weighed 41 mg and showed .
96.9% germination (Figure 2); lighter seeds, on the
other hand, had only 10.9% germination because
89.1% were empty seeds; these results, however,
contrast studies conducted in others tree species,
under controlled environmental conditions, have
observed that seed mass effects on germination and
early seedling growth depend on resource availability
(Parker et al., 2006; Mtambalika et al., 2014);
however, results of this study agree with some
researchers who have stated that embryo abortion is
the main cause of empty seeds (Matziris, 1998).
IMB, SW and TOG relationships. Four curves of
seed imbibition (IMB), selected from the balanced
bulk of half-sib families (Figure 3), show seed weight
increases and their relationships with time of
germination 50% (TOG) and initial seed weight (SW).
As it was mentioned before, lighter seeds (seed weight
< 31 mg) showed a low percent of germination,
because they had a higher percent of empty seeds;
moreover, ungerminated small seeds increased their
weight from 26 to 35 mg (increment = 57.7%). This
could be related to damage on seed coat produced by
pathogens (fungi and bacteria), seed coat layers
structure, insects, high temperature, wind and other
environmental factors (Timonin, 1964; Tillman-Sutela
and Kaupin, 1995). On the other hand, seeds whose
TOG occurred 3, 5 and 7 days after sowing, showed
at day 3, respectively, SW increments of 38.3, 29.4
and 40%. Studies in Pinus monticola (Dougl. Ex D.
Don) seeds have been reported weight increases of
30% one day after sowing, and it has been indicated
that seeds should reach a desirable seed moisture
content before germination begins (Terskikh et al.,
2005). Barnett (1997) indicated that in Pinus taeda
(L.) seeds must reach a moisture content of 36% to
split the seed coat and to initiate germination, while
longleaf pine (Pinus palustris Mill.) seeds require
around 55% moisture content (seed dry weight basis)
before starting germination.
Figure 2. Seed size effect on percent germination (bulk of 20
half-sib families).
Table 3. Components of phenotypic variance (%) for seed fresh
weight (SFW), seed coat fresh weight (SCFW) and seed
imbibition (IMB).
** Highly significant (P 0.01).
Increases in seed weights, which were recorded
during the seven-day imbibition period (Figure 3),
showed three imbibition stages described by other
researchers (Terskikh et al., 2005): 1) Phase I (0-1
day after sowing); 2) Phase II (2-3 days after sowing);
and 3) Saturation Phase or Phase III (4-7 days after
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
sowing). Phase III is characterized by the highest
water-uptake rate and a fast increase in seed coat
permeability; important changes in SW occurred in
Phase I, since it was observed increases of 16, 12 and
13 mg, respectively, for TOG 3 (from 60 to 76 mg),
TOG 5 (from 51 to 63 mg) and TOG 7 (from 45 to 58
mg). In Phase II, on the other hand, small SW changes
were recorded from day 1 to day 2 (2-3 mg) and from
day 2 to day 3 (1-4 mg). Finally, the Saturation Phase
is characterized for another high increase and a linear
trend, whose pattern continues from day 3 to day 7. It
is also marked the superiority of seeds whose TOG is
3 and their average seed weight increases from 83 to
128 mg (day 3 to day 7). Patterns of imbibition curves
observed in this study agree with those described by
Woodstock (1988) and Terskikh et al. (2005).
Figure 3. Imbibition of seeds associated to Time of Germination
50% (TOG).
Components of variance for seed traits. Highly
significant differences (P < 0.001) were observed
among families for seed weight (SW), seed coat weight
(SCW), and seed imbibition (IMB); estimates of
components of variance, associated to family
differences (genetic variation), were 35.5, 50.1 and
24.8%, respectively, for SW, SCW and IMB (Table 3).
Within-plot (Within-family) variances estimated for
seed traits: SW, SCW and IMB were, respectively, 64.5,
41.8 and 70.4%; in most cases, the extent and magnitude
of this component is higher than family variance;
which may represent another source of genetic
variation associated to differences among individuals
of same family (within-family variance), resulting from
cross pollination between mother tress (female
parents) and male parents genetically divergent. The
great amount of among and within family variation,
observed for most characteristics analyzed, confirms
the results found by several researchers in other
species (Banerjee and Maze, 1988; Maze et al., 1989).
The existence of a high within-family variation, equal
in magnitude to within-population variance, seems to
be genetic in origin (Banerjee and Maze, 1988). As in
other conifers, germination parameters are clearly
under maternal control because a high percentage of
the phenotypic variance was determined by family
variation (Bramlett et al., 1983; St. Clair and Adams,
1993; Sorensen and Cress, 1994). On the other hand,
variation among-plots is mainly caused by
environmental differences associated to experimental
units.
Components of phenotypic variance. Significant
differences among half-sib families were found for
all germinative characteristics (Table 4); means
varied from 35.1% (parameter a) to 89.2%
(parameter b). In the former case, a low percentage
also indicates a low genetic contribution involved in
germination onset; the higher amount of variance,
associated to the scale factor «b», on the other hand,
strongly suggests that differences among seedlots
reflect a significant genetic influence on that
parameter, regardless the small number of half-sib
families compared in this study.
Table 4. Components of phenotypic variance (%) of germinative traits and Weibull´s parameters for 20 half-sib ponderosa pine families.
*Significant (P 0.05); ** Highly significant (P 0.01)
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
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LSD mean comparison test. For all seed traits and
germination parameters was used the Fisher´s Least
Significant Level (LSD) test, a multiple comparison
procedure, and the significant level of 5% (P = 0.05).
Percent seed germination (G), expressed as angular
transformation ArcSin G*0.01, varied from 45
(families 7 and 16) to 90 (families 14 and 15);
moreover, means of families with the highest
germination capacity included in group a (Table 5),
varied from 67.5 to 90, while group d, which included
families of the lowest germination capacity showed
averages between 45 and 67.5. Three groups of
significance were found for time of germination 50%
(TOG); group c, which showed the fastest
germination of them (TOG = 4), included 17 families;
while the slowest germination group consisted of
families 19, 11 and 4, whose TOG means were,
respectively, 5.5, 5 and 5 days. The Czabator´s
germination value (GV) describes completeness and
speed of germination process, so then it is a good
criterion to compare family performance. More
variation was observed in GV means (Table 5),
because seven significant groups were formed; group
a, for instance, included seven of better performance
families with the highest GV values; on the other hand,
group g included eight of lower performance families
with the smallest GV values.
Time of germination for 50% (TOG) in all
families took place 4-5.5 days after sowing. These
results agreed with other general findings in which
southern pine populations did not require pre-
chilling treatment (Larson, 1963; Hoff, 1987;
Gossling, 1988). Number of days required to start
germination was statistically the same for all half-sib
families; this result was expected because seeds were
non-dormant when running the germination test; in
other words, stratification treatments were not
required, by any seed lot compared here, to begin
germination.
Families 15, 14, and 6 had the best performance
by comparing the germination capacity (Arcsine),
TOG, and GV. Those germination parameters are
indicators of high quality seed lots, thus, they measure
germinative energy of seeds via percentage of
viability, completeness and rate of germination. Peak
Value means of ten families were statistically superior
to population mean (17.0) and families 3, 6, 14 and
15 were statistically superior to any progeny whose
mean was < 17.2. Most half-sib families (60%) had
fast germination because their average GS values were
superior to the population mean. In this germination
test, family 14 was the fastest germinating seedlot
(0.252), while family 19 performed as the slowest
germinating seedlot (GS = 0.183).
Table 5. Mean comparison test1 (LSD) for seed germination
[expressed as ArcSin (% germination)*0.01], time of
germination 50% (TOG), and germination value (GV).
1/Means with the same letters are not significantly different
(P 0.05).
The means of Weibull parameters for the seed
lots are listed (Table 6). Ten means of parameter «a»,
one of parameter «b» and 12 of parameter «c» belong
to group a and they were statistically superior to most
population means. The shape parameter «c» has a
strong genetic influence from maternal parent.
Significant effects of family component found in this
experiment, are indicative of genetic variation among
half-sib families. It was initially discussed that mean
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
parameter «c» describes among half-sib families. It
was initially discussed that mean parameter «c»
describes the shape of the curve. Values of «c» near
3.6 (Table 6), like those for families 1 and 13 (3.5),
describe a symmetrical curve (approximately
normal), which also means a more uniform
germination; if «c» decreases below that value
(families 2, 19 and 20), the shape of the curve will be
possibly skewed (the pronounces tail to the right);
shapes negatively skewed, on the other hand, are
correlated with values of «c» greater than 3.6
(Families 3, 5, 6 and 7). Several authors (Bonner and
Dell, 1976; Bahler et al., 1989) stated that an increase
in parameter «a» and decrease in «b» and «c» are
correlated with a decrease in seed quality. The scale
factor «b» is inversely associated to increase in
germination capacity and germination rate of seed
lots, so a faster or more vigorous germination will be
reflected in lower values of the parameter «b».
Comparing the larger scale parameter of family 19
(2.8) with that of family 6 (1.0), it can be suggested
that the firs progeny has a lower seed quality. In this
sense, GS and GV parameters suggest the same
conclusion.
Table 6. Mean comparison test1 (LSD) of seed germination traits and Weibull’s parameters for 20 half-sib ponderosa pine families.
1/Means with the same letters are not significantly different (P 0.05)
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
Conclusions
1. There was among-family and within-family
significant variation associated for all seed traits and
Weibull parameters. These findings suggest that
analyzed characters are under control of both genetic
and environmental control.
2. Czabator´s GV and Weibull´s parameters were
useful criteria to compare overall performance of
seed lots. Half-sib families 6, 14, and 15 were
consistently superior to the rest of seed lots for
germination parameters Arcsine, TOG, PV and GV.
3. Seed weights e» 60 mg were positively
correlated with high percentages of sound and viable
seeds, fast germination (TOG = 3) and higher
imbibition rates (IMB).
Literature cited
AGER, A.A. and R.F. Stettler. 1983. Local variation in seeds of
ponderosa pine. Can. J. Bot. 61:1337-1344.
BAHLER, C., R.R. Hill, Jr., and R.A. Byers. 1989. Comparison of logistic
and Weibull functions: The effect of temperature on
cumulative germination of alfalfa. Crop Sci. 29:142-146.
BAI, Y., D. Thompson, and K. Broersma. 2004. Douglas fir and
ponderosa pine seed dormancy as regulated by grassland
seedbed conditions. J. Range Manage. 57:661-667.
BANERJEE, S. and J. Maze. 1988. Variation in growth within and
among families of Douglas-fir through a single season. Can. J.
Bot. 66:2452-2458.
BARNETT, J.P. 1997. Relating pine seed coat characteristics to speed
of germination, geographic variation, and seedling
development. Tree Planters´ Notes 48:38-42.
BENJAMIN, L.R. 1990. Variation in time of seedling emergence within
populations: A feature that determines individual growth and
development. Adv. Agron. 44:1-25.
BONNER, F.T. and T.R. Dell. 1976. The Weibull function: A new
method of comparing seed vigor. J. Seed Technol. 1:96-103.
BRAMLETT, D.L., R.R. Dell, and W.D. Pepper. 1983. Genetic and
maternal influences on Virginia pine seed germination. Silvae
Genet. 32:1-4.
DAVIDSON, R.H., D.G.W. Edwards, O. Sziklai, and Y.A. El-Kassaby. 1996.
Genetic variation in germination parameters among
populations of pacific silver fir. Silvae Genet. 45:165-171.
DURZAN, D.J. 1983. Metabolism of tritiated water during imbibition
and germination of jack pine seeds. Can. J. For. Res. 13:1204-1218.
GOSSLING, P.G. 1988. The effect of moist chilling on the subsequent
germination of some temperate conifer seeds over a range of
temperatures. J. Seed Technol. 12:90-98.
GUMMERSON, R.J. 1989. Seed-bed cultivations and sugar-beet
seedling emergence. J. Agric. Sci. Camb. 112:159-169.
HEIDMANN, L.J. and S.M. Haase. 1989. Causes of mortality in
outplanted ponderosa pine container seedlings in the
southwest. Tree Planters´ Notes 40:16-19.
HOFF, R.J. 1987. Dormancy in Pinus monticola seed related to
stratification time, seed coat, and genetics. Can. J. For. Res.
17:294-298.
KING, J.E. and D.J. Gifford. 1997. Amino acid utilization in seeds of
loblolly pine during germination and early seedling growth.
Plant Physiol. 113:1125-1135.
KY-DEMBELE, C., M. Tigabu, J. Bayala, and P.C. Odén. 2014. Inter-
and intra-provenances variations in seed size and seedling
characteristics of Khaya senegalensis A. Juss in Burkina Faso.
Agroforestry Syst. 88:311-320.
KUEHL, R.O. 1994. Statistical principles of research design and
analysis. Duxbury Press. Belmont, C.A.
LARSON, M.M. 1965. Initial root development of ponderosa pine
seedlings as related to germination date and size of seed. For.
Sci. 9:456-460.
LONG, T.J. and R.H. Jones. 1996. Seedling growth strategies and
seed size effects in fourteen oak species native to different
soil moisture habitats. Trees 11:1-8.
MATZIRIS, D. 1998. Genetic variation in cone and seed
characteristics in a clonal seed orchard of Aleppo pine grown
in Greece. Silvae Genet. 47:17-41.
MAZE, J., S. Banerjee, and Y.A. El-Kassaby. 1989. Variation in growth
rate within and among full-sib families of Douglas-fir
(Pseudotsuga menziesii). Can. J. Bot. 67:140-145.
MAZE, J. and S. Banerjee. 1989. A comparison of variation of
Pseudotsuga menziesii seedlings from genetically defined and
undefined sources. Can. J. Bot. 67:945-947.
MCLEMORE, B.F. 1966. Temperature effects on dormancy and
germination of loblolly pine seed. For. Sci. 12:284-289.
MEXAL, J.G. and J.T. Fisher. 1987. Size hierarchy in conifer seedbeds.
1. Time of emergence. New Forests 3:187-196.
MOORE, M.B. and F.A. Kidd. 1982. Seed source variation in induced
moisture stress germination of ponderosa pine. Tree Planters´
Notes 33:12-14.
MTAMBALIKA, K.,C. Munthali, D. Gondwe, and E. Missanjo. 2014.
Effect of seed size of Afzelia quanzensis on germination and
seedling growth. Int. J. For. Res. 2014:1-5.
PARKER, W.C., T.L. Noland, and A.E. Morneault. 2006. The effect of
seed mass on germination, seedling emergence, and early
seedling growth of eastern white pine (Pinus strobus L.). New
Forests 32:33-49.
PASQUINI, N.M. and G.E. Defossé. 2012. Effects of storage conditions
and pre-chilling periods on germinability of Pinus ponderosa
seeds from Patagonia, Argentina: preliminary study. Bosque
33(1):99-103.
PERRY, T.O. 1976. Maternal effects on the early performance of
trees progenies. pp. 474-481. IN: M.G.R. Cannell and F.T. Last
(eds.). Tree physiology and yield improvement. Academic?
Press, New York.
PERRY, T.O. and W.L. Hafley. 1981. Variation in seedling growth
rates: Their genetic and physiological bases. pp. 288-301. IN:
Proceedings: Southern Forest Tree Improvement Conference.
Louisiana State University, Division of Continuing Education
in Cooperation with Southern Forest Experimental? Station,
USDA, Forest Service.
RANAL, M. and D. Garcia de Santana. 2006. How and why to measure
the germination process?. Revista Brasil. Bot. 29:1-11.
CÉSAR H. RIVERA-FIGUEROA, JOHN G. MEXAL AND DENNIS L. CLASON: Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families
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• Vol. XII, Núm. 3 • Septiembre-Diciembre 2018 •
RINK, G., R.R. Dell, G. Swuitzer, and F.T. Bonner. 1979. Use of the
Weibull function to quantify sweetgum germination data.
Silvae Genet. 7:319-329.
ROACH, D. and R. Wulff. 1987. Maternal effects in plants. Ann. Rev.
Ecol. Sys. 18:209-235.
SILEN, R. and C. Osterhaus. 1979. Reduction of genetic base by
sizing of bulked Douglas-fir seed lots. Tree Planters´ Notes
30:24-30.
SORENSEN, F.C. and R.K. Campbell. 1985. Effect of seed weight on
height growth of Douglas-fir [Pseudotsuga menziesii (Mirb.)
Franco var. menziesii] seedlings in a nursery. Can. J. For. Res.
15:1109-1115.
SORENSEN, F.C. and D.W. Cress. 1994. Effects of sib mating on cone
and seed traits in coastal Douglas-fir. Silvae Genet. 43:338-345.
ST. CLAIR, J.B. and W.T. Adams. 1993. Family composition of Douglas-
fir nursery stock as influenced by seed characters, mortality,
and culling practices. New Forests 7:319-329.
STEEL, R. y J.H. Torrie. 1960. Principles and Procedures of Statistics.
John Willey & Sons.
TILLMAN-SUTELA, E. and A. Kauppi. 1995. The morphological
background to imbibition in seeds of Pinus sylvestris L. of
different provenances. Trees 9:123-133.
TIMONIN, M.I. 1964. Interaction of seed-coat microflora and soil
microorganisms and its effects on pre- and post-emergence
of some conifer seedlings. Can. J. Microbiol. 10(1):17-22.
TERSKIKH, V.V., J.A. Feurtado, C. Ren, S.R. Abrams, and A.R. Kermode.
2005. Water uptake and oil distribution during imbibition of
seeds of western white pine (Pinus monticola Dougl. Ex D.
Don). Planta 221:17-27.
WEBER, J.C. and F.C. Sorensen. 1992. Geographic variation in speed
of seed germination in central Oregon ponderosa pine (Pinus
ponderosa Dougl. Ex Laws.). Pacific Norwest Forest & Range
Experiment Station. Res. Pap. PNW-RP-444. Portland, OR:
USDA, Forest Service, 12 p.
WOODSTOCK, L.W. 1988. Seed imbibition: A critical period for
successful germination. J. Seed Technol. 12:1-15.
Cite this paper as:
Rivera-Figueroa, C. H., J. G. Mexal and D. L. Clason. 2018. Components of phenotypic variance of seed traits and germination
characteristics of 20 ponderosa pine half-sib families. TECNOCIENCIA Chihuahua 12(3):150-159.
DOI: https://doi.org/10.54167/tch.v12i3.189
