In a world urgently requiring more sustainable agriculture, food security and healthier
diets the demand for legume crops is on the rise. This growth is fostered by the increasing
need for plant protein and for sound agricultural practices that are more adaptable
and environmentally sensitive. Food, feed, fibers and even fuel are all products that
come from legumes—plants that grow with low nitrogen inputs and in harsh environmental
conditions.
To heighten the public awareness of the nutritional benefits of legumes as part of
sustainable food production aimed toward food security and nutrition, the 68th UN
General Assembly declared 2016 the International Year of Pulses. Timely, the International
Legume Society (http://ils.nsseme.com) organized the Second International Legume Society
Conference (ILS2) from 11 to 14th October 2016 in Portugal serving as an unique forum
to present and discuss the new research accomplishments on the legume biology, as
well as, seek for innovative scientific approaches intended to address these fundamental
questions on this important family of plants. The health and environment benefits,
as well as, the marketing of legumes were cross-cutting topics throughout the conference.
As a result of contributions made to that conference, the Research Topic “Advances
in legume research” (https://www.frontiersin.org/research-topics/4288/advances-in-legume-research)
was designed, being also open to spontaneous submissions.
Articles published in the Research topic will be now briefly presented in this editorial
introduction:
Evolution, conservation, and diversity characterization
Phaseolus spp. represents an interesting model of crop evolution where five closely
related species have been domesticated. Bitocchi et al. reviewed the origin of Phaseolus
genus, the geographical distribution of the wild species, the domestication process,
and the wide spread out of the center of origin. Based on this review, at least seven
independent domestication events occurred in the Phaseolus genus. This information
provides the possibility to unravel the genetic basis of the domestication process
not only among species of the same genus, but also between gene pools within the same
species. In particular for P. vulgaris, this resulted from the breaking of the spatial
isolation of the Mesoamerican and Andean gene pools, which allowed spontaneous hybridization,
and increasing the possibility of novel genotypes and phenotypes. Accordingly, Carović-Stanko
et al. performed a genetic diversity analysis on Croatian common bean landraces and
showed that about 27% were of Mesoamerican and 68% of Andean origin, while 4% of the
accessions were hybrids between both gene pools.
Understanding adaptive responses to stresses is the key to genetic risk mitigation,
by ensuring that crops with an appropriate assemblage of adaptive traits are grown
in fitting production niches. Harnessing the genetic diversity of crop plants can
be a way to achieve this goal. As a proof-of-concept, Berger et al. investigated wild
and domesticated Mediterranean annual reproductive strategies comparing Lupins spp.
collected along aridity gradients. Strong trade-offs between seed size, early vigor
and phenology were observed. Despite the large differences detected for all these
traits, natural and human selections have operated in very similar ways in all species.
Yellow sweet clover (Melilotus officinalis) is a legume species widely used as ground
cover or green manure. Likewise, this legume has also the potential to be used as
forage. However, this last application is not possible due to its inherent high coumarin
content. To tackle this limitation, Lou et al. studied the genetic variation for herbage
yield, key morphological traits, and coumarin content. Selected populations were polycrossed
providing a valuable breeding pool for M. officinalis cultivar development in China.
Environment and agronomy
By knowing the origin and geographic spread of a given crop it is possible to obtain
clues about its environmental interactions, including relative adaptation to biotic
and abiotic stresses. For instance, archaeobotanical studies have revealed that some
legumes (e.g., pea, chickpea, and lentil) are considered as ancient crops of the Fertile
Crescent and adjacent areas. However, it is not possible to know the history of legumes
in other areas in which data are scarce, like the Bronze Age Steppes. In this respect,
Dugan provided an opinion article paper suggesting that an accurate understanding
of grain legumes in Proto-Indo-European and Indo-European agriculture and language
will have positive consequences for our understanding of archeology, linguistics,
and crop biogeography.
There is a renewed interest on intercropping due to its positive effects on crop productivity
and resistance against different pathogens. In this line, Jeromela et al. reviewed
and highlighted the potential of autumn- and spring-sown intercrops of annual legumes
with brassicas for ruminant feeding and green manure.
Lentil producers in northern temperate regions usually apply pre-harvest desiccants
as harvest aids to accelerate the lentil crop drying process and facilitate harvesting
operations. Despite the beneficial effects of the different pre-harvest aids, there
is little information about the impact of the whole battery of harvest aids. Subedi
et al. filled this gap up by studying the effect of harvest aids alone or tank mixed
with glyphosate on seed germination, seedling vigor, milling, and splitting qualities.
This investigation not only confirmed the benefits of using pre-harvest aids, but
also showed that the application of diquat alone or in combination with glyphosate
improves lentil milling recovery yield.
Improving responses to biotic stresses
Vicilins are seed storage proteins involved in germination processes supplying amino
acids for seedling growth and plant development. Likewise, this type of proteins can
have some role in plant defense. To provide more evidence about this, Jimenez-Lopez
et al. studied the potential role of β-conglutins from narrow leaf lupin (Lupinus
angustifolius) in protection against necrotrophic fungal pathogens. Transient expression
of β1- and β6-conglutin proteins in Nicotiana benthamiana leaves demonstrated in vivo
growth suppression of Sclerotinia sclerotiorum and oomycete Phytophthora nicotianae.
The non-host resistance is probably more durable than the single dominant resistance
genes; this is because there are diverse types of effectors/elicitors and multiple
resistance traits involved. The non-host resistance model with chromatin as a receptor
offers flexibility to account for many plant-pathogen interactions. To prove this,
Hadwiger and Tanaka studied the aspects of legume defense stimulation by salicilic
acid (SA), an inducer of non-host resistance in pea tissue. Authors suggest that the
SA-induced PR gene activation may be attributed to the host pea genomic DNA damage.
Heat shock transcription factors (Hsfs) are important transcription factors (TFs)
in protecting plant cells from damages caused by various stresses. To increase evidence
about the relevance of these TFs in legumes, Wang et al. performed a genome-wide analysis
of Hsfs in Arachis duranensis and A. ipaensis. This analysis led to the identification
of at least 16 Hsfs genes in these two Arachis species. The identified Hsfs genes
were divided in three main groups: A, B, and C. A selection pressure analysis revealed
that genes bellowing to the group B underwent a positive selection, while genes bellowing
to the group A were affected by a purifying selection. Additionally, the presence
of fungal elicitor responsive elements in the promoter region of some of these genes
suggests their involvement in response to fungi infection.
Lectins that reside in the nucleocytoplasmic compartment are implicated in plant response
to biotic and abiotic stresses. The class of Nictaba-like lectins (NLL) groups all
proteins with homology to the tobacco (Nicotiana tabacum) lectin, known as stress-inducible
lectins. Accordingly, Van Holle et al. showed that soybean NLLs are implicated in
stress responses. Overexpression of two soybean NLLs homologs in Arabidopsis enhanced
tolerance to bacterial infection (Pseudomonas syringae), insect infestation (Myzus
persicae) and salinity.
Improving tolerance to abiotic stresses
In field conditions, plants are exposed to multiple types of stresses. In combined
stress scenario, drought can positively or negatively affect pathogen infection. To
evaluate this scenario, Sinha et al. investigated the effect of drought stress on
interaction of chickpea with Pseudomonas syringae pv. phaseolicola or Ralstonia solanacearum,
and the net-effect of combined stress on chlorophyll content and cell death. This
study demonstrated that, regardless of the pathogen, drought-stressed chickpea plants
showed a significant reduction in the infection levels. Authors propose that both
stress interaction and the net effect of combined stress could be mainly influenced
by first occurring stress. Likewise, authors suggest that the outcome of the two-stress
interaction in plant depends on both timing of stress occurrence and nature of infecting
pathogen.
Drought is one of the major constraints limiting plant growth and yield. Modifications
in the root architecture allow plants to increase their water extraction capacity
and drought resistance. Another adaptation that plants use to cope with drought is
an increase in the photosynthates remobilization to ensure seed production. Thus,
specific shoot and root traits seem to be the key in improved resistance to drought
in different crop plants. To support this, Polania et al. provide evidence indicating
that the resistance to drought stress in common bean (Phaseolus vulgaris) is positively
associated with a deeper and vigorous root system, better shoot growth, and superior
mobilization of photosynthates to pod and seed production. Authors propose that pod
harvest index, and seed number per area could serve as useful selection criteria for
assessing sink strength and for genetic improvement of drought resistance in common
bean.
Specific rooting patterns can be associated with drought avoidance mechanisms that
can be used in lentil breeding programs. Idrissi et al. identified QTLs associated
with root and shoot traits in a RIL of lentil. A QTL related to root-shoot ratio explained
the highest phenotypic variance.
The polyamines (PAs) are low-molecular-weight organic cations found in a wide range
of organisms, and perform diverse biological functions. For instance, Nahar et al.
studied the physiological roles of PAs for their ability to confer salt tolerance
in mung bean seedlings (Vigna radiata). This study revealed that exogenous PAs supplementation
reduced the salt-induced oxidative stress by increasing the contents of glutathione
and ascorbate as well as the activities of glyoxalase enzymes. The overall salt tolerance
was reflected through improved water and chlorophyll content, as well as, seedling
growth.
Improving forage and seed quality
Improved digestibility is a main objective in forage breeding. To achieve this goal,
different mapping and association approaches have been used to identify potential
trait-marker that can be used for the improvement of digestibility in forage crops.
For instance, Wang et al. performed an association mapping analysis in alfalfa (Medicago
sativa) by genotyping an alfalfa panel and phenotyping for five fiber-related traits
in four different environments. From this study, eight associations were predicted
in two environments, whereas 20 markers were predicted to be associated with multiple
traits. The identification of these trait-marker associations will help to breed alfalfa
cultivars with high forage quality.
Quinolizidine alkaloids are toxic secondary metabolites found within the genus Lupinus.
While they offer the plants protection against insect pests, their accumulation in
grains complicates its use for food purposes as high levels confer a bitter taste
and may result in acute anticholinergic toxicity. In this line, Frick et al. discuss
possibilities for further elucidation and manipulation of the quinolizidine alkaloids
pathway in lupin crops by using conventional and cutting-edge technologies.
Seed-coat cracking and undesirable seed coat color highly affect external appearance
and commercial value of peanuts (Arachis hypogaea). To face this issue, Wan et al.
performed a whole-genome transcriptome analysis on a peanut mutant with cracking and
brown colored seed coat (pscb). This analysis led to the identification of three candidate
genes for the trait, which can be used as marker genes for plant breeding.
High germination, nutritional quality, and yield potential under high heat and dryland
production conditions are priority seed traits in soybean (Glycine max). Bellaloui
et al. searched for these traits in exotic germplasm and identified three breeding
lines with consistently superior germination. The study also unveiled potential roles
of minerals, especially K, Ca, B, Cu, and Mo, in maintaining high seed quality.
Starch phosphorylase (PHO) catalyses the reversible transfer of glucosyl units from
glucose-1-phosphate to the non-reducing ends of α-1,4-D-glucan chains with the release
of phosphate. Qin et al. identified three PHO isoform (LjPHO) genes in the Lotus japonicus
genome. Overexpression studies suggested that LjPHO3 may participate in transitory
starch metabolism in L. japonicus leaves, but its catalytic properties remain to be
studied.
Improving plant nutrition
Legumes establish root symbioses with rhizobia that provide plants with nitrogen (N)
through biological N fixation (BNF), as well as with arbuscular mycorrhizal (AM) fungi
that mediate improved plant phosphorus (P) uptake. Püschel et al. studied the interplay
between BNF and AM symbioses in Medicago truncatula and M. sativa along a P-fertilization
gradient. The AM symbiosis generally improved P uptake by plants and considerably
stimulated the efficiency of BNF under low P availability. In contrast, under high
P availability the AM symbiosis brought no further benefits to the plants. Results
also suggested competition for limited C resource between the two microsymbionts.
The use of P-efficient genotypes is a sustainable management strategy for enhancing
yield and P use efficiency. Zhou et al. identified genetic variation for P use efficiency
in soybean genotypes under field conditions and studied hydroponically P assimilation
characteristics and the related mechanisms of P-efficient soybean genotypes.
Iron deficiency is a major problem in many countries raising interest in biofortification
of legumes. Tan et al. reviewed the current status of iron biofortification discussing
challenges and potential application of transgenic technology.
Multiple genes and TFs are involved in the uptake and translocation of iron in plants
from soil. Sen Gupta et al. developed molecular markers for iron metabolism related
genes using genome synteny with M. truncatula.
Understanding plant physiology
Plant hemoglobins (Hbs) are found in nodules of legumes and actinorhizal plants but
also in non-symbiotic organs of monocots and dicots. Non-symbiotic Hbs (nsHbs) have
been classified into two phylogenetic groups. Class 1 nsHbs show an extremely high
O2 affinity and are induced by hypoxia and nitric oxide (NO), whereas class 2 nsHbs
have moderate O2 affinity and are induced by cold and cytokinins. Using spectroscopic
analyses, Calvo-Begueria et al. showed major differences between the two phylogenetic
classes of nsHbs and also between the two members of the same class, strongly suggesting
that these three globins perform non-redundant functions.
Photoperiod is one of the major environmental factors determining time to flower initiation
and first flower appearance in plants. Daba et al. studied photoperiod sensitivity
in chickpea (Cicer arietinum). Photoperiod-sensitive and -insensitive phases were
identified by experiments in which individual plants were reciprocally transferred
in a time series from long to short days and vice versa in growth chambers. Results
from this research will help to develop cultivars with shorter pre-inductive photoperiod-insensitive
and photoperiod-sensitive phases to fit to regions with short growing seasons.
Light is essential for plant growth and development. Yuan et al. studied the response
of cultivated lentil and wild Lens germplasm to different light environments, showing
that days to flower of Lens genotypes were mainly influenced by changes in the red/far-red
ratio of the light quality but not by changes in the intensity of the photosynthetically
active radiation. The distinctly different responses between flowering time and elongation
under low red/far-red conditions among wild Lens genotypes suggest that flowering
and elongation are controls by discrete pathways. Three L. lamottei and one L. ervoides
genotypes were less sensitive to changes in light quality maintaining similar yield,
biomass, and harvest index across all three light environments; these are indications
of better adaptability toward changes in light environment.
The phytohormone auxin plays also a critical role in regulation of plant growth and
development as well as in plant responses to abiotic stresses. Auxin transporters
are major players in polar auxin transport. Chai et al. performed a genome-wide analysis
of the soybean GmLAX auxin transporter gene family. A total of 15 GmLAX genes were
identified in the soybean genome distributed on 10 out of the 20 soybean chromosomes.
GmLAXs showed very dynamic expression patterns, most of them responsive to drought,
salt and dehydration stresses, as well as, auxin and abscisic acid stimuli, in a tissue-
and/or time sensitive manner.
MADS-domain proteins are important TFs involved in many aspects of plant reproductive
development. Chi et al. found that GmAGL1 is specifically expressed in reproductive
tissues but not in roots, stems, and leaves of soybean. The ectopic overexpression
of GmAGL1 in Arabidopsis suggested a role for this MADS-box protein in floral organ
identity and fruit dehiscence.
Excessive flower and pod abscission represents an economic drawback for yellow lupine
(Lupinus luteus). Glazinska et al. studied transcriptional networks in the pods, flowers
and flower pedicels to identify genes playing key roles in generative organ abscission
in yellow lupine. Auxin, ethylene and gibberellins were some of the main factors engaged
in generative organ abscission. Identified differentially expressed genes common for
all library comparisons were involved in cell wall functioning, protein metabolism
and water homeostasis and stress response.
Improvement of seed quality requires deep insights into the genetic regulation of
seed development. The endosperm serves as a temporary source of nutrients that are
transported from maternal to filial tissues. It also generates signals for proper
embryo formation. Zhang et al. showed that soybean GmZOU-1 gene is an ortholog of
the Arabidopsis bHLH domain TF that may be responsible for endosperm breakdown and
embryo cuticle formation in soybean.
Adjusting plant growth and development
Plant morphology markedly affects its competitive ability and persistence in mixtures.
Faverjon et al. compared the patterns of shoot organogenesis and shoot organ growth
in contrasting forage species belonging to the four morphogenetic groups (i.e., stolon-formers,
rhizome-formers, crown-formers tolerant to defoliation and crown-formers intolerant
to defoliation). The consequences of this quantitative framework are discussed, along
with its possible applications regarding plant phenotyping and modeling.
Seed dispersal and germination are two key traits that have been selected to facilitate
cultivation and harvesting of crops. Hradilová et al. studied anatomical structure
of seed coat and pod, and identified metabolic compounds associated with water-impermeable
seed coat and differentially expressed genes involved in pea (Pisum spp.) seed dormancy
and pod dehiscence. This integrated analysis of seed coat in wild and cultivated pea
provides new insight as well as raises new questions associated with domestication,
seed dormancy and pod dehiscence.
Determinacy growth habit and accelerated flowering are adaptive traits in common bean.
Through a comparative mapping approach, González et al. detected additive and epistatic
QTLs regulating flowering time, vegetative growth, and rate of plant production. Further
QTL analysis coupled with previous results highlighted 001G189200 gene, homologous
to the Arabidopsis thaliana TFL1 gene, as a candidate gene for determinacy locus.
Mungbean (Vigna radiata) is a cleistogamous plant in which flowers are pollinated
before they open, which prevents yield improvements through heterosis. Chasmogamous
mutant (CM) plants are available. Chen et al. mapped the cha gene responsible for
the chasmogamous flower trait to a 277.1-kb segment on chromosome 6. Twelve candidate
genes were detected in this segment, including Vradi06g12650, which encodes a YUCCA
family protein associated with floral development. A single base pair deletion producing
a frame-shift mutation and a premature stop codon in Vradi06g12650 was detected only
in CM plants suggesting Vradi06g12650 as cha candidate gene.
The time of flowering has a major influence in both plant productivity and adaptation
to the changing environment. Hence, different efforts to understand the genic programs
underlying the flowering time in important crop plants have been made. For instance,
Srivastava et al. used a high-throughput multiple QTL-seq strategy to identify two
major QTL genomic regions governing flowering time on chickpea (Cicer arietinum) chromosome
4. The functionally relevant molecular tags delineated can be used for deciphering
the natural allelic diversity-based domestication pattern of flowering time and expediting
genomics-aided crop improvement to develop early flowering cultivars of chickpea.
The branching habit is an important descriptive and agronomic character of peanut
(Arachis hypogaea). Kayam et al. fine-mapped this trait by combining high-throughput
sequencing and bulk segregant analysis, providing a baseline for candidate gene discovery
and map-based cloning.
Proper phenotyping is becoming a bottleneck in breeding, being particularly difficult
for inherent root system architectures. To overcome this constrain, Zhao et al. provided
machine learning algorithms that were used for unbiased identification of most distinguishing
root traits and subsequent pairwise pea (Pisum sativum) cultivar differentiation.
Fine mapping of quantitative trait loci (QTL) and qualitative trait genes plays an
important role in gene cloning, molecular-marker-assisted selection (MAS), and trait
improvement. As a proof-of-concept, Li et al. mapped 26 agronomic QTLs and five qualitative
trait genes related to pigmentation in adzuki bean (Vigna angularis). For this mapping
analysis, authors used 1,571 polymorphic SNP markers generated via Restriction-site-Associated
DNA sequencing technology. The identification of these QTL and qualitative trait genes
will contribute to breed adzuki bean cultivars with desirables traits.
Another example about the relevance of the QTL analysis in plant breeding programs
is provided by Srivastava et al. who used a high-throughput whole genome next-generation
resequencing strategy to develop InDel markers in chickpea (Cicer arietinum) mapping
populations. By using this approach, Srivastava et al. identified three major QTLs
governing pod number and seed yield per plant. These functionally relevant molecular
tags can drive marker-assisted genetic enhancement to develop high-yielding cultivars
with increased seed/pod number and yield in chickpea.
Genomic tools for breeding
Genetic variation is the basis for plant breeding programs. Most conventional crop
improvement programs rely on natural genetic variation present among germplasm pools.
Alternatively, induced mutagenesis still offers the potential to create valuable genetic
variation for genetic enhancement and breeding. For instance, Horn et al. identified
agronomically desirable cowpea (Vigna unguiculata) mutants after gamma irradiation.
Ten phenotypically and agronomically stable novel mutants are described that constitute
a valuable genetic resource for cowpea genetic enhancement and breeding.
The large-scale mining and high-throughput genotyping of novel gene-based allelic
variants in natural mapping population are essential for association mapping to identify
functionally relevant molecular tags governing useful agronomic traits. For instance,
Bajaj et al. used an EcoTILLING approach coupled with agarose gel detection assay
to discover 1133 novel SNP allelic variants by genotyping in a desi and kabuli chickpea
collection constituting a seed weight association panel. Integrating genotyping and
phenotyping data identified eight SNP alleles in the eight TF genes regulating seed
weight of chickpea.
Ištvánek et al. used illumina paired-end sequencing of red clover (Trifolium pratense)
allowing the identification of large sets of SSRs and SNPs throughout that will be
key for implementing genome-based breeding approaches, for identifying genes underlying
key traits, and for genome-wide association studies.
Genotyping-by-Sequencing (GBS) may drastically reduce genotyping costs compared with
SNP array platforms. Annicchiarico et al. compared GBS protocols on legume species
that differ for genome size, ploidy, and breeding system, and showed successful applications
and challenges of GBS data on legume species. Authors devised a simple method for
comparing phenotypic vs. genomic selection in terms of predicted yield gain per year
for same evaluation costs, whose application to preliminary data for alfalfa and pea
in a hypothetical selection scenario for each crop indicated a distinct advantage
of genomic selection.
Author contributions
All authors listed have made a substantial, direct and intellectual contribution to
the work, and approved it for publication.
Conflict of interest statement
The authors declare that the research was conducted in the absence of any commercial
or financial relationships that could be construed as a potential conflict of interest.