© The Authors, 2023, Published by the Universidad del Zulia*Corresponding author: bmurillo04@cibnor.mx
Keywords:
Biomass
Growth
Vigna unguiculata L. Walp.
Lablab purpureus L. Sweet
Clitoria ternatea L.
Canavalia ensiformis L. DC.
Emergence capacity and seedlings early growth of four legumes in arid zones under NaCl-stress
Capacidad de emergencia y crecimiento inicial de plántulas de cuatro leguminosas en zonas áridas
en condiciones de estrés por NaCl
Capacidade de emergência e crescimento inicial de plântulas de quatro leguminosas em zonas áridas
sob estresse por NaCl
Francisco Higinio Ruiz-Espinoza
1
Juan José Reyes-Perez
2
Felix
Alfredo Beltrán-Morales
1
Bernardo Murillo-Amador
3
*
Juan Carlos Rodríguez-Ortiz
4
Pablo Misael Arce-Amézquita
1
Rev. Fac. Agron. (LUZ). 2023, 40(2): e234020
ISSN 2477-9407
DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v40.n2.10
Crop production
Associate editor: Dr. Jorge Vilchez-Perozo
University of Zulia, Faculty of Agronomy
Bolivarian Republic of Venezuela
1
Universidad Autónoma de Baja California Sur, La Paz, Baja
California Sur,
Autónoma de Baja California Sur, México.
2
Universidad Técnica Estatal de Quevedo. Av. Quito. Km 1
½ vía a Santo Domingo. Quevedo, Los Ríos, Ecuador.
3
Centro de Investigaciones Biológicas del Noroeste, S.C.
(BMA). Avenida Instituto Politécnico Nacional No. 195.
Colonia Playa Palo de Santa Rita Sur. La Paz, Baja California
Sur, México. C.P. 23096.
4
Facultad de Agronomía y Veterinaria-UASLP. Palma de la
Cruz, Soledad G.S. San Luis Potosí, México.
Received: 11-04-2023
Accepted: 09-05-2023
Published: 02-06-2023
Abstract
Legumes are used as fodder and green manures, because of x nitrogen
biologically. The objective of this study was to determine the emergence
capacity and the early growth of four legume species treated with dierent
NaCl-stress concentrations. The experiment was established in a completely
randomized design with a factorial arrangement, where the rst factor was
the four legumes’ species (Vigna unguiculata L. Walp., Lablab purpureus
(L.) Sweet, Clitoria ternatea L. and Canavalia ensiformis L. DC.) and the
second factor was NaCl concentrations (0.25, 50, and 75 mM) with 16
treatments and four replications. The variables evaluated were emergence
rate and percentage, stem and root length, fresh and dry weight of
stem+leaves and root, stem and root length, stem diameter and the ratio of
stems+leaves dry weight and roots dry weight (plant balance). The results
showed that all variables expressed signicant dierences between species,
NaCl and the species × NaCl interaction. A dierential response between
legumes to NaCl stress was observed. The most tolerant species to NaCl
were Vigna unguiculata and Canavalia ensiformis showed a higher tolerance
with respect to Lablab purpureus and Clitoria ternatea.
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Rev. Fac. Agron. (LUZ). 2023, 40(2): e234020. Abril-Junio. ISSN 2477-9407.
2-6 |
Resumen
Las leguminosas se utilizan como forraje y abonos verdes,
porque jan biológicamente el nitrógeno. El objetivo de este
estudio fue determinar la capacidad de emergencia y el crecimiento
inicial de cuatro especies de leguminosas tratadas con diferentes
concentraciones de NaCl. El experimento se estableció en un diseño
completamente al azar con arreglo factorial, donde el primer factor
fueron las cuatro especies de leguminosas (Vigna unguiculata L.
Walp., Lablab purpureus L. Sweet, Clitoria ternatea L. y Canavalia
ensiformis L. DC.) y el segundo factor las concentraciones de NaCl
(0, 25, 50 y 75 mM) con 16 tratamientos y cuatro repeticiones.
Las variables evaluadas fueron tasa y porcentaje de emergencia,
longitud de tallo y raíz, peso fresco y seco de tallo+hojas y de raíz,
longitud de tallo y de raíz, diámetro de tallo y la relación peso seco
de tallos+hojas y peso seco de raíces (balance de la planta). Los
resultados mostraron que, todas las variables expresaron diferencias
signicativas entre especies, NaCl y la interacción especies × NaCl.
Se observó una respuesta diferencial entre leguminosas al estrés por
NaCl. Las especies más tolerantes al NaCl fueron Vigna unguiculata
y Canavalia ensiformis mostraron una tolerancia mayor con respecto
a Lablab purpureus y Clitoria ternatea.
Palabras clave: biomasa, crecimiento, Vigna unguiculata L.
Walp., Lablab purpureus L. Sweet, Clitoria ternatea L., Canavalia
ensiformis L. DC.
Resumo
As leguminosas são utilizadas como forragens e adubos verdes,
por xarem o nitrogênio biologicamente. O objetivo deste estudo foi
determinar a capacidade de emergência e o crescimento inicial de
quatro espécies de leguminosas tratadas com diferentes concentrações
de NaCl-estresse. O experimento foi instalado em delineamento
inteiramente casualizado com arranjo fatorial, onde o primeiro fator
foram as quatro espécies de leguminosas (Vigna unguiculata L.
Walp., Lablab purpureus L. Sweet, Clitoria ternatea L. y Canavalia
ensiformis L. DC.) e o segundo fator foram as concentrações de
NaCl (0,25, 50, e 75 mM) com 16 tratamentos e quatro repetições.
As variáveis avaliadas foram taxa e porcentagem de emergência,
comprimento de caule e raiz, massa fresca e seca de caule+folhas e
raiz, comprimento de caule e raiz, diâmetro do caule e relação massa
seca de caule+folhas e massa seca de raízes (equilíbrio da planta). Os
resultados mostraram que todas as variáveis expressaram diferenças
signicativas entre as espécies, NaCl e a interação espécie × NaCl.
Observou-se uma resposta diferencial entre as leguminosas ao
estresse por NaCl. As espécies mais tolerantes ao NaCl foram Vigna
unguiculata e Canavalia ensiformis apresentaram maior tolerância
em relação a Lablab purpureus e Clitoria ternatea.
Palavras-chave: biomassa, crescimento, Vigna unguiculata L.
Walp., Lablab purpureus L. Sweet, Clitoria ternatea L., Canavalia
ensiformis L. DC.
Introduction
The saline-stress is one of the main limiting factors of productivity
in agricultural crops; therefore, going further in the study of saline
tolerance is a priority for sustainable agriculture. The salinity is a
complex abiotic stress based on ionic and osmotic phenomena (Gul
et al., 2022;). The plants under salinity are aected from germination
to more advanced development stages. The imbibition speed is
reduced due to an osmotic eect in the seeds while cellular division,
elongation, and mobilization of essential reserves for the germination
process can also shows variations (Narejo et al., 2023).
Soil salinity is one of the main degradation forms in arid and semi-
arid regions where precipitation is low to keep regular salt percolation
from the crop root system zone (Nachshon, 2018). The soils in arid
and semi-arid regions contain high amounts of soluble salts, mainly
NaCl and Na
2
SO
4
(Xu et al., 2020), which allows a high sodium
adsorption ratio (SAR) out of the soil solution. The excess of salts in
drainage is often associated with sodicity problems (Mohanavelu et
al., 2021) since sodium occupies the exchangeable spaces.
The water quality deteriorates progressively due to the salt excess
in addition to bad management of water and soil. The soil salinization
gets hastened and worse when the salt-promoting accumulation
factors are ignored. The recent studies show that, agricultural areas
are being salt-aected worldwide areas including Mexico, where the
distribution and extension of soils with salt problems have increased
particularly in irrigation areas of arid zones (Negacz et al., 2022).
The legumes used as green manure, besides their potential as
nutrient source of livestock, oer other important advantages when
are used in agriculture systems. The legumes promote biological
nitrogen xation (Mathesius, 2022) and this natural conversion of
atmospheric N into available forms for the plant enhances economical
and sustainable productivity (Daniel et al., 2022). The objective of
this study was to determine the emergence capacity and the early
growth of four legume species, treated with dierent NaCl-stress
concentrations.
Materials and Methods
Study area
The experiment was carried-out in the spring season of 2019 in
the Universidad Autonoma of Baja California Sur (UABCS) in La
Paz, Baja California Sur, Mexico, located at 24° 10’ North latitude
and 110° 19’ West longitude. The study area has a climate BW
(h’) HW (e), that is, dry desert, warm, according to the Köppen
climatic classication, modied by García (2004). The annual
temperatures mean, maximum, and minimum in the study site are
29.6, 36.0 (in July), and 18.1 °C (in January), respectively. The
annual precipitation is about 184.8 mm. The potential evaporation far
exceeds precipitation, resulting in a water decit of around 2472 mm
per year and an average relative humidity of 62 % per month, while
daily insolation is 8.5 h. The experiment was developed in a shadow
mesh structure (40 % of shading, black color, model 20 mesh). The
temperature inside the mesh structure ranged from 29 to 33 ºC. The
data of the climatological variables recorded during the study period
were obtained from a portable weather station (Vantage Pro2
®
Davis
Instruments, Hayward, CA, USA).
Legumes species
The species used were (Vigna unguiculata L. Walp., Lablab
purpureus L. Sweet, Clitoria ternatea L. and Canavalia ensiformis L.
DC.). The seeds of these species were obtained from an organic plot in
the experimental eld of UABCS. The seeds were stored in the seeds
collection bank at UABCS. The extract of Ocimum tenuiorum (holy
basil) was used to maintain the seeds free of insects and pathogens
and were maintained stored at 10 ºC.
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Ruiz-Espinoza et al. Rev. Fac. Agron. (LUZ). 2023 40(2): e234020
3-6 |
Experimental design
The experiment was developed using a completely randomized
design with a factorial arrangement being the rst factor, the four
legumes (Vigna unguiculata L. Walp., Lablab purpureus L. Sweet,
Clitoria ternatea L. and Canavalia ensiformis L. DC.)), and the
second factor, four NaCl concentrations (0, 25, 50 and 75 mM) using
distilled water as control (0 mM NaCl) with 16 treatments and four
replications per treatment.
Experimental management
The seeds of each species were sown in 200 cells germination
polystyrene trays containing Sunshine
®
an inert commercial substrate
of Canadian sphagnum peat moss (Sun Gro Horticulture Distribution
Inc. Agawam, MA, USA). The NaCl treatments were applied from
the beginning of the experiment. The trays were irrigated every third
day with 500 mL of water after the NaCl solutions treatments and
let to drain to avoid salt accumulation in the substrate. The electrical
conductivity (EC) readings were measured with a conductivity meter
(Hach
®
, Model Sension+, Loveland, CO, USA) and taken after the
preparation of the saline solution and subsequently to the drained
liquid to compare the values of EC (prepared and drained), according
with Murillo-Amador et al. (2007) No changes were detected in the
drained solution.
Emergence Rate (ER)
The seeds were considered to have emerged when the seedling
emerged through the substrate surface. The percentage of emerged
seeds was recorded daily (emergence rate), after the third day and
once the application of NaCl treatments, and the total emerged
seedlings counted after 11 and 21 days depending on the species. The
emergence rate (M) is the speed that a seed germinate over a period
(in days) was calculated using Maguire (1962) equation: M= n
1
/n
2
+
t
1
/t
2
+…n
100
/t
11 or 21
; where n
1
, n
2…
n
30
is the number of germinated seeds
in the times t
1
, t
2
…t
11 or 21
(in days).
Emergence Rate Index (ERI)
The number of emerged seedlings was recorded daily, considering
as the rst day when the rst emerged seedling was observed; the last
observation was performed fteen days after the establishment of the
experiment. The emergence rate index was calculated according to
the formula proposed by Maguire (1962):
Seedlings growth
The emerged seedlings were maintained for 13 days for L.
purpureus, 10 days for V. unguiculata, 11 days for C. ensiformis, and
21 days for C. ternatea and after this period, 10 seedlings per species,
treatments and replication were selected; then, the roots and stems
(stems+leaves) were separated, washed with running water and then
with distilled water.
The fresh (g) and dry weight (g) of all tissues were determined
using an analytical scale (Mettler Toledo
®
, model AG204, USA). The
dry weight of roots and stems (stems+leaves) were obtained after
being placed in paper bags and then in a drying oven (Shel-Lab
®
, FX-
5, series-1000203, USA) at 70 °C until constant weight (about 72 h).
The stems height (cm) was measured from the base to the apex
and after seedlings were harvested, while stem diameter (mm)
was measured every three days during the experimental period
using a digital Vernier (VWR
®
model 62379-531, S/N/61581129,
Manufacturer Control Company, USA).
The roots length (cm) was measured using a graduated ruler and
the measurements were taken from the base of the stem, where the
root hairs begin, to the apex of the main root. The biomass balance
plant was calculated dividing the stem+leaves dry weight by root dry
weight.
Statistical analysis
The data were subjected to analysis of variance using Statistica
v. 13.5 (TIBCO Software Inc., 2018). The homogeneity of variance
was determined using Bartlett’s Box-test. The means comparison test
was performed by Tukey HSD (p=0.05). The emergence percentage
data were transformed by arcsine according to Little and Hills (1989).
Results and discussion
Emergence rate and emergence percentage
The analysis of variance showed that emergence rate (Fig. 1) and
emergence percentage, were aected by species, NaCl, and species
× NaCl interaction. This interaction indicates that NaCl eects
were dierent between species. The NaCl concentrations aect the
emergence rate of the species by delaying the emergence rate being
more severely aected C. ternatea and less aected V. unguiculata
(Figure 1).
The decrease in both rate and emergence percentage is the result
of inhibition of embryo-axis growth because of delayed reserve
mobilization and membrane disturbance caused by NaCl-stress
and evidenced by increased leakage of materials from embryo-
axis (Ibrahim, 2019). The results of seed emergence, according to
the dierent NaCl concentrations, showed that the nal emergence
percentage (Table 1) of each species was inuenced by NaCl.
The seeds of Vigna unguiculata L. Walp. showed a higher
emergence percentage of 97.5 %, followed by C. ensiformis, L.
purpureus, and C. ternatea, in that order. The emergence percentage
was similar under 0 and 25 mM NaCl; nonetheless, an increment of
NaCl concentrations reduced the emergence. The NaCl concentrations
negatively aect the emergence of seeds of test plants. The salinity
inuences the germination percentage and the time in which this
process occurs (Dehnavi et al., 2020).
The results of the present study showed variability between
species in the response to NaCl-stress of the four legume and
therefore the germplasm can be considered for saline stress genetic
improvement in legume species. Hence, eorts to identify saline-
resistant germplasm are important goals to pursue. The results of
the present study showed that most of the variables at the emergence
stage exhibited a reduction as the salinity increased. Al-huraby et al.
(2022) reported similar results in P. vulgaris L. when the number of
germinated seeds decreased according to the media concentration.
Likewise, Praxedes et al. (2020), reported that V. unguiculata
seedlings were evaluated for emergence, vigor, salinity tolerance
index, and dissimilarity. Increased salinity of irrigation water reduced
emergence, vigor, and dry matter accumulation of cowpea varieties.
The results showed that some cowpea varieties are most tolerant
to salinity, while other varieties are most sensitive to salinity in
the emergency and initial growth phase. Ravelombola et al. (2018)
analyzed the salt tolerance index of 116 and 155 cowpea accessions at
germination and seedling stages and found a substantial variation in
salt tolerance index for germination rate, plant height reduction, fresh
and dry shoot biomass reduction, foliar leaf injury, and inhibition of
the rst trifoliate leaf. Deng et al. (2019) investigated the relationship
between osmotic regulators, stress resistance enzymes, and salt
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4-6 |
Figure 1. Eect of NaCl-stress in the emergence rate of four legumes, (A) Clitoria ternatea, (B) Lablab purpureus (C) Vigna unguiculata,
and (D) Canavalia ensiformis. The values represent the mean ± the error standard.
tolerance of leguminous plants (Vigna angularis variety ‘Yuhongdou
2’ and traditional Dolichos lablab) under NaCl stress and found that,
salinity stress inhibited the germination index of V. angularis. Then
germination percentage, germination potential, germination index,
and vigor index of V. angularis decreased with increasing NaCl stress
and was signicantly higher than that of D. lablab. 2) The relative salt
damage rate of V. angularis and D. lablab increased with the increase
in NaCl concentration.
Emergence Rate Index (ERI)
The analysis of variance showed that the emergence rate index was
aected by species, NaCl, and species × NaCl interaction. The table
1 shows that in general, the four species showed lower ERI values as
NaCl concentrations increased. The ERI was higher at 0 mM NaCl
except for C. ternatea which showed a high ERI at 25 mM NaCl;
while V. unguiculata showed the highest in all NaCl concentrations
followed by C. ensiformis whereas L. purpureus at 25, 50, and 75 mM
NaCl showed the lowest ERI.
Similar results were reported by Ruiz-Ramírez et al. (2012) who
evaluated the eect of dierent salinity levels with KCl in the ERI of
ve species of forage grasses, Cenchrus ciliaris L., Chloris gayana
L., Brachiaria brizantha (A.Rich.) Stapf, Brachiaria hybrid cv.
Mulato II and Panicum maximum Jacq cv. Tanzania concluded that
ERI and other variables decreased as KCl levels increased.
The imbibition is the rst stage of germination and aects the
germination because of depends on the seed’s chemical composition,
seed coat permeability, water potential dierence, and the thickness
of storage tissues (Fatokun et al., 2022).
There is a specic association for maize seeds between the level of
physiologic quality and imbibition in the sense that less germination
corresponds to a higher imbibition percentage (Li et al., 2022). In this
study, L. purpureus showed a similar response to maize seeds with the
lowest ERI under 75 mM NaCl.
Seedlings growth
The analysis of variance showed that the seedling’s stem height
and width, root length, stems+leaves fresh and dry-weight, root fresh
and dry-weight, and plant balance were aected by species, NaCl,
and species × NaCl interaction (Table 1).
The stem height was higher at 0 mM NaCl in C. ternatea followed
by the same specie at 50 and 25 mM NaCl. Vigna unguiculata at 0
mM also showed high stem height. The stem diameter was higher at
0, 25, 50, and 75 mM NaCl in C. ternatea followed by L. purpureus at
25, 50, and 75 mM NaCl. The lower stem diameter was at 50 mM in
C. ternatea. Canavalia ensiformis showed the longest roots at 0 mM
followed by V. unguiculata and C. ternatea. In general, V. unguiculata
showed longer roots in all NaCl treatments (Table 1). According to
Shelden and Munns (2023) in saline media, substrate, or soil, with
constant humidity through constant watering, salts are likely to stay
in deeper layers and therefore roots decreased their length activating
the formation of adventitious roots.
In the same sense, Muktadir et al. (2020) reported that high
salinity generates a physiologic drought in plants. In accordance
with this, the common bean doubles the number of secondary and
tertiary roots with a modied architecture due to drought. For this
reason, a system with widespread and deep roots is recommended
to increase the productivity of alimentary legumes in drought and
salinity conditions. Root length could be an important trait for in-
vitro selection of bean varieties resistant to salinity with enhanced
capacity to acquire water. Plant response to salinity varies according
to species, cultivar, and distribution. This is evidence of the diverse
strategies that plants have developed through their evolution. An
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Table 1. Eect of NaCl-stress in the emergence and seedlings growth of four legumes, Vigna unguiculata, Lablab purpureus, Clitoria
ternatea and Canavalia ensiformis.
Species
NaCl
(mM)
Stem height (cm) Stem diameter (mm) Root length (cm) Emergence (%)
Emergence rate
index
Clitoria ternatea
0 8.50±0.33 bc* 1.83±0.20 h 8.01±0.52 ab 77.5±14.14 b 7.79±1.32 b
25 6.32±0.45 ef 1.54±0.18 hi 6.85±0.40 bcd 80.0±12.58 a 7.90±1.68 b
50 5.35±0.39 fgh 1.45±0.21 i 6.13±0.47 bcde 77.5±5.00 b 6.91±2.25 c
75 4.10±0.74 h 1.59±0.27 hi 5.81±0.75 cde 82.5±5.00 a 6.68±1.57 c
Lablab purpureus
0 6.44±0.87def 2.96±0.13 fg 6.77±0.65 bcd 85.0±5.77 ab 7.85±1.13 bc
25 5.79±0.27 fg 3.34±0.04 cd 7.07±0.68 abcd 82.5±5.00 b 5.50±1.12 e
50 4.72±0.76 gh 3.29± 0.10cde 2.95±0.45 bcd 75.0±10.00 c 5.84±1.13 e
75 4.94±0.39 gh 3.45±0.39 bc 5.68±0.75 cde 67.5±18.92 d 5.19±1.30 e
Vigna unguiculata
0 9.95±0.48 a 2.64±0.11 g 9.11±0.35 a 97.5±9.57 a 12.72±2.33 a
25 8.26±0.23
c 2.96±0.23 efg 7.78±0.44 abc 87.5±5.00 a 9.75±0.30 b
50 7.32±0.39 cde 2.96±0.04 efg 7.58±0.36 abc 82.5±9.57 b 9.72±1.57 b
75 5.98±0.63 fg 3.07±0.12 def 6.61±0.65 bcd 82.5±9.57 b 9.46±1.30 b
Canavalia ensiformis
0 10.9±1.27 a 3.87±0.23 a 9.16±2.51 a 97.5±5.00 a 10.85±1.41 a
25 9.66±2.01 ab 3.75±0.28 ab 7.27±0.63 abcd 72.5±5.00 cd 7.40±1.45 bc
50 10.1±0.94 a 3.56±0.19 abc 4.57±0.23 e 70.0±18.25 d 7.75±0.81 bc
75 7.62±1.59 cd 3.55±0.21 abc 5.16±0.62 de 67.5±22.17 d 6.35±2.30 d
Stems + leaves
fresh weight (g)
Stems + leaves dry
weight (g)
Root fresh weight (g) Root dry weight (g) Plant balance
Clitoria ternatea
0 0.609±0.09 g 0.118±0.005 cdef 0.464±0.19 ab 0.052±0.005 b 0.254±0.017 a
25 0.501±0.05 g 0.082±0.011 def 0.171±0.07 ef 0.043±0.005 b
0.479±0.053 a
50 0.474±0.10 g 0.068±0.015 ef 0.097±0.049 fg 0.029±0.008 d 0.701±0.043 a
75 0.347±0.07 g 0.062±0.012 f 0.033±0.014 g 0.021±0.006 e 1.878±0.976 b
Lablab purpureus
0 1.060±0.14 def 0.156±0.020 c 0.194±0.039 ef 0.039±0.009 bc 0.804±0.086 a
25 0.967±0.09 ef 0.143±0.013 c 0.168±0.043 efg 0.035±0.005 c 0.851±0.092 a
50 0.966±0.07 ef 0.140±0.002 cd 0.397±0.104 abcd 0.035±0.005 c 0.352±0.012 a
75 0.898±0.11 f 0.126±0.017 cde 0.349±0.117 bcd 0.029±0.008 d 0.361±0.032 a
Vigna unguiculata
0 1.346±0.06 c 0.109±0.010 cdef 0.462±0.043 ab 0.046±0.006 b 0.235±0.054 a
25 1.291±0.07 cd 0.101±0.009 cdef 0.398
±2.053 abcd 0.033±0.001 c 0.253±0.065 a
50 1.269±0.07cd 0.103±0.008 cdef 0.414±0.077 abc 0.032±0.003 c 0.248±0.032 a
75 1.205±0.08 cde 0.101±0.014 cdef 0.300±0.093 cde 0.028±0.004 b 0.336±0.076 a
Canavalia ensiformis
0 3.695±0.25 b 0.612±0.017 b 0.522±1.29 a 0.099±0.021 a 1.172±0.983 a
25 4.093±0.33 a 0.642±0.048 ab 0.372±0.096 bcd 0.090±0.005 a 1.725±0.873 a
50 4.373±0.43 a 0.680±0.046 a 0.276±0.044 de 0.091±0.013 a 2.463±0.997 b
75 3.782±0.32 b 0.661±0.044 ab 0.302±0.163 cde 0.054±0.015 b 2.188±0.983 b
* The values represent the means ± standard deviation. Values with dierent letters in the same column are statistically dierent (Tukey HSD, p=0.05).
example of this is the higher salinity tolerances of the Poaceae family
compared to Leguminosae, mainly due to their origin (Grigore and
Vicente, 2023).
Plants that naturally inhabit saline soils tend to pose a higher
capacity to extract water from the soil; however, halophyte plants
not only need to be capable of absorbing water necessary to its
development from a saline solution but also to absorb it with enough
speed to maintain an adequate transpiration rate (Hasanuzzaman et al.,
2023). The NaCl treatments aected negatively stems and root fresh
and dry weight, as the NaCl concentrations increased, fresh and root
biomass decreased. Canavalia ensiformis L. DC. was less aected
because of showed the highest values of biomass (fresh and dry) in
the majority of NaCl treatments (Table 1). The reduction in biomass
is because of the reduction of cell wall synthesis during stress which
aects the stem and root tissues causing a decrease in fresh and dry
weight. Mubushar
et al. (2022) showed that using growth biomass
variables as indicator facilitate discriminate saline stress-tolerant
genotypes and cultivars.
In the same context, Khan et al. (2023), mentioned that saline stress
aects the structure and permeability of intracellular membranes,
cell homeostasis, energy exchange reactions, DNA structure and
functionality, and various enzymatic responses. These enzymes are
mainly the ones related to metabolism during stress conditions and
adaptive response, which protect from damage caused by stress.
Can-Chulim et al. (2014), reported that the emergence rate and
germination of P. vulgaris (pinto bean), decreased by 54.7% at 9
dS.m
-1
and azufrado bean decreased 30.3%. Moreover, the dierences
in stem length between the control (T
0
) and the highest concentration
This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.
Rev. Fac. Agron. (LUZ). 2023, 40(2): e234020. Abril-Junio. ISSN 2477-9407.
6-6 |
of salt treatment (T
6
) were 2.4, 4 y 3.2 cm for black, pinto, and
azufrado bean, respectively. Higher electric conductivities resulted in
germination reduction.
The smaller values of plant balance mean a better plant balance.
Plant balance consists of the relation of stem+leaves dry weight
over root dry weight. This relation was smaller for control plants
because the seedlings showed lower weights of stem+leaves dry
weight; however, with equal root weight as compared to the other
NaCl treatments and species. The plant balance is very important for
farmers because of has been observed that seedlings with a better
plant balance have better establishment and development when
transplanted to the eld.
Furthermore, by getting a better plant balance in the eld, better
radicular growth could be obtained, thus, achieving better crop
development. The NaCl salinity treatments reduced the plant balance
due to the increment of osmotic pressure in the substrate solution in
relation to the one in the root cells, aecting ion intake by the root hairs
and, consequently, aecting plant nutrition and development (Acosta-
Motos et al., 2017). On the other hand, Li et al. (2017) concluded that
a high concentration of Na is deleterious to the membrane selectivity
and favors the passive accumulation of Na in roots and stems.
Conclusions
This study showed a dierential response of four legumes to
NaCl concentrations. The species most tolerant to NaCl-stress were
Canavalia ensiformis L. DC. and Vigna unguiculata L. Walp. In
general, the emergence rate and emergence percentage, root length,
root dry weight and stem height decreased as NaCl concentrations
increased. Stem diameter, stem fresh and dry weight, and root
fresh weight increased from 0 mM to 25 and 50 mM but in other
case decreased from 50 to 75 mM, i.e., root fresh weight. Future
experiments are needed to obtain information about the enrichment
capacities of the legumes studied here; maybe, genotypes with lower
emergence under high salinity could x more atmospheric nitrogen
than the tolerant ones.
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